#include "js-wasm.h" #include #include // These should be provided...somehow... void *memset(void *s, int c, size_t n); void *memcpy(void *dest, const void *src, size_t n); int memcmp(const void *s1, const void *s2, size_t n); void __attribute__((noreturn)) abort(void); static inline void assert(bool expression) { if (!expression) { abort(); } } void *malloc(size_t size); void free(void *ptr); #define MALLOC(a, _) malloc(a) #define FREE(p) if ((long)(p) > 1024) { free(p); } #define DO_ASSERT(a) (void)(a) #define CHECK(a) // We assume that CVec_u8Z and u8slice are the same size and layout (and thus pointers to the two can be mixed) _Static_assert(sizeof(LDKCVec_u8Z) == sizeof(LDKu8slice), "Vec and [u8] need to have been mapped identically"); _Static_assert(offsetof(LDKCVec_u8Z, data) == offsetof(LDKu8slice, data), "Vec and [u8] need to have been mapped identically"); _Static_assert(offsetof(LDKCVec_u8Z, datalen) == offsetof(LDKu8slice, datalen), "Vec and [u8] need to have been mapped identically"); _Static_assert(sizeof(void*) == 4, "Pointers mut be 32 bits"); typedef uint32_t int64_tArray; typedef uint32_t int8_tArray; typedef uint32_t uint32_tArray; typedef uint32_t ptrArray; typedef uint32_t jstring; static inline uint32_t init_arr(size_t arr_len, size_t elem_size, const char *type_desc) { uint32_t *elems = (uint32_t*)MALLOC(arr_len * elem_size + 4, type_desc); elems[0] = arr_len; return (uint32_t)elems; } static inline jstring str_ref_to_ts(const char* chars, size_t len) { char* err_buf = MALLOC(len + 4, "str conv buf"); *((uint32_t*)err_buf) = len; memcpy(err_buf + 4, chars, len); return (uint32_t) err_buf; } static inline LDKStr str_ref_to_owned_c(jstring str) { uint32_t *str_len = (uint32_t*)str; char* newchars = MALLOC(*str_len + 1, "String chars"); memcpy(newchars, (const char*)(str + 4), *str_len); newchars[*str_len] = 0; LDKStr res= { .chars = newchars, .len = *str_len, .chars_is_owned = true }; return res; } typedef bool jboolean; uint32_t __attribute__((visibility("default"))) TS_malloc(uint32_t size) { return (uint32_t)MALLOC(size, "JS-Called malloc"); } void __attribute__((visibility("default"))) TS_free(uint32_t ptr) { FREE((void*)ptr); } static inline struct LDKThirtyTwoBytes ThirtyTwoBytes_clone(const struct LDKThirtyTwoBytes *orig) { struct LDKThirtyTwoBytes ret; memcpy(ret.data, orig->data, 32); return ret; } static inline LDKAccessError LDKAccessError_from_js(int32_t ord) { switch (ord) { case 0: return LDKAccessError_UnknownChain; case 1: return LDKAccessError_UnknownTx; } abort(); } static inline int32_t LDKAccessError_to_js(LDKAccessError val) { switch (val) { case LDKAccessError_UnknownChain: return 0; case LDKAccessError_UnknownTx: return 1; default: abort(); } } static inline LDKChannelMonitorUpdateErr LDKChannelMonitorUpdateErr_from_js(int32_t ord) { switch (ord) { case 0: return LDKChannelMonitorUpdateErr_TemporaryFailure; case 1: return LDKChannelMonitorUpdateErr_PermanentFailure; } abort(); } static inline int32_t LDKChannelMonitorUpdateErr_to_js(LDKChannelMonitorUpdateErr val) { switch (val) { case LDKChannelMonitorUpdateErr_TemporaryFailure: return 0; case LDKChannelMonitorUpdateErr_PermanentFailure: return 1; default: abort(); } } static inline LDKConfirmationTarget LDKConfirmationTarget_from_js(int32_t ord) { switch (ord) { case 0: return LDKConfirmationTarget_Background; case 1: return LDKConfirmationTarget_Normal; case 2: return LDKConfirmationTarget_HighPriority; } abort(); } static inline int32_t LDKConfirmationTarget_to_js(LDKConfirmationTarget val) { switch (val) { case LDKConfirmationTarget_Background: return 0; case LDKConfirmationTarget_Normal: return 1; case LDKConfirmationTarget_HighPriority: return 2; default: abort(); } } static inline LDKCreationError LDKCreationError_from_js(int32_t ord) { switch (ord) { case 0: return LDKCreationError_DescriptionTooLong; case 1: return LDKCreationError_RouteTooLong; case 2: return LDKCreationError_TimestampOutOfBounds; case 3: return LDKCreationError_ExpiryTimeOutOfBounds; } abort(); } static inline int32_t LDKCreationError_to_js(LDKCreationError val) { switch (val) { case LDKCreationError_DescriptionTooLong: return 0; case LDKCreationError_RouteTooLong: return 1; case LDKCreationError_TimestampOutOfBounds: return 2; case LDKCreationError_ExpiryTimeOutOfBounds: return 3; default: abort(); } } static inline LDKCurrency LDKCurrency_from_js(int32_t ord) { switch (ord) { case 0: return LDKCurrency_Bitcoin; case 1: return LDKCurrency_BitcoinTestnet; case 2: return LDKCurrency_Regtest; case 3: return LDKCurrency_Simnet; case 4: return LDKCurrency_Signet; } abort(); } static inline int32_t LDKCurrency_to_js(LDKCurrency val) { switch (val) { case LDKCurrency_Bitcoin: return 0; case LDKCurrency_BitcoinTestnet: return 1; case LDKCurrency_Regtest: return 2; case LDKCurrency_Simnet: return 3; case LDKCurrency_Signet: return 4; default: abort(); } } static inline LDKIOError LDKIOError_from_js(int32_t ord) { switch (ord) { case 0: return LDKIOError_NotFound; case 1: return LDKIOError_PermissionDenied; case 2: return LDKIOError_ConnectionRefused; case 3: return LDKIOError_ConnectionReset; case 4: return LDKIOError_ConnectionAborted; case 5: return LDKIOError_NotConnected; case 6: return LDKIOError_AddrInUse; case 7: return LDKIOError_AddrNotAvailable; case 8: return LDKIOError_BrokenPipe; case 9: return LDKIOError_AlreadyExists; case 10: return LDKIOError_WouldBlock; case 11: return LDKIOError_InvalidInput; case 12: return LDKIOError_InvalidData; case 13: return LDKIOError_TimedOut; case 14: return LDKIOError_WriteZero; case 15: return LDKIOError_Interrupted; case 16: return LDKIOError_Other; case 17: return LDKIOError_UnexpectedEof; } abort(); } static inline int32_t LDKIOError_to_js(LDKIOError val) { switch (val) { case LDKIOError_NotFound: return 0; case LDKIOError_PermissionDenied: return 1; case LDKIOError_ConnectionRefused: return 2; case LDKIOError_ConnectionReset: return 3; case LDKIOError_ConnectionAborted: return 4; case LDKIOError_NotConnected: return 5; case LDKIOError_AddrInUse: return 6; case LDKIOError_AddrNotAvailable: return 7; case LDKIOError_BrokenPipe: return 8; case LDKIOError_AlreadyExists: return 9; case LDKIOError_WouldBlock: return 10; case LDKIOError_InvalidInput: return 11; case LDKIOError_InvalidData: return 12; case LDKIOError_TimedOut: return 13; case LDKIOError_WriteZero: return 14; case LDKIOError_Interrupted: return 15; case LDKIOError_Other: return 16; case LDKIOError_UnexpectedEof: return 17; default: abort(); } } static inline LDKLevel LDKLevel_from_js(int32_t ord) { switch (ord) { case 0: return LDKLevel_Trace; case 1: return LDKLevel_Debug; case 2: return LDKLevel_Info; case 3: return LDKLevel_Warn; case 4: return LDKLevel_Error; } abort(); } static inline int32_t LDKLevel_to_js(LDKLevel val) { switch (val) { case LDKLevel_Trace: return 0; case LDKLevel_Debug: return 1; case LDKLevel_Info: return 2; case LDKLevel_Warn: return 3; case LDKLevel_Error: return 4; default: abort(); } } static inline LDKNetwork LDKNetwork_from_js(int32_t ord) { switch (ord) { case 0: return LDKNetwork_Bitcoin; case 1: return LDKNetwork_Testnet; case 2: return LDKNetwork_Regtest; case 3: return LDKNetwork_Signet; } abort(); } static inline int32_t LDKNetwork_to_js(LDKNetwork val) { switch (val) { case LDKNetwork_Bitcoin: return 0; case LDKNetwork_Testnet: return 1; case LDKNetwork_Regtest: return 2; case LDKNetwork_Signet: return 3; default: abort(); } } static inline LDKSecp256k1Error LDKSecp256k1Error_from_js(int32_t ord) { switch (ord) { case 0: return LDKSecp256k1Error_IncorrectSignature; case 1: return LDKSecp256k1Error_InvalidMessage; case 2: return LDKSecp256k1Error_InvalidPublicKey; case 3: return LDKSecp256k1Error_InvalidSignature; case 4: return LDKSecp256k1Error_InvalidSecretKey; case 5: return LDKSecp256k1Error_InvalidRecoveryId; case 6: return LDKSecp256k1Error_InvalidTweak; case 7: return LDKSecp256k1Error_TweakCheckFailed; case 8: return LDKSecp256k1Error_NotEnoughMemory; } abort(); } static inline int32_t LDKSecp256k1Error_to_js(LDKSecp256k1Error val) { switch (val) { case LDKSecp256k1Error_IncorrectSignature: return 0; case LDKSecp256k1Error_InvalidMessage: return 1; case LDKSecp256k1Error_InvalidPublicKey: return 2; case LDKSecp256k1Error_InvalidSignature: return 3; case LDKSecp256k1Error_InvalidSecretKey: return 4; case LDKSecp256k1Error_InvalidRecoveryId: return 5; case LDKSecp256k1Error_InvalidTweak: return 6; case LDKSecp256k1Error_TweakCheckFailed: return 7; case LDKSecp256k1Error_NotEnoughMemory: return 8; default: abort(); } } static inline LDKSemanticError LDKSemanticError_from_js(int32_t ord) { switch (ord) { case 0: return LDKSemanticError_NoPaymentHash; case 1: return LDKSemanticError_MultiplePaymentHashes; case 2: return LDKSemanticError_NoDescription; case 3: return LDKSemanticError_MultipleDescriptions; case 4: return LDKSemanticError_NoPaymentSecret; case 5: return LDKSemanticError_MultiplePaymentSecrets; case 6: return LDKSemanticError_InvalidFeatures; case 7: return LDKSemanticError_InvalidRecoveryId; case 8: return LDKSemanticError_InvalidSignature; case 9: return LDKSemanticError_ImpreciseAmount; } abort(); } static inline int32_t LDKSemanticError_to_js(LDKSemanticError val) { switch (val) { case LDKSemanticError_NoPaymentHash: return 0; case LDKSemanticError_MultiplePaymentHashes: return 1; case LDKSemanticError_NoDescription: return 2; case LDKSemanticError_MultipleDescriptions: return 3; case LDKSemanticError_NoPaymentSecret: return 4; case LDKSemanticError_MultiplePaymentSecrets: return 5; case LDKSemanticError_InvalidFeatures: return 6; case LDKSemanticError_InvalidRecoveryId: return 7; case LDKSemanticError_InvalidSignature: return 8; case LDKSemanticError_ImpreciseAmount: return 9; default: abort(); } } static inline LDKSiPrefix LDKSiPrefix_from_js(int32_t ord) { switch (ord) { case 0: return LDKSiPrefix_Milli; case 1: return LDKSiPrefix_Micro; case 2: return LDKSiPrefix_Nano; case 3: return LDKSiPrefix_Pico; } abort(); } static inline int32_t LDKSiPrefix_to_js(LDKSiPrefix val) { switch (val) { case LDKSiPrefix_Milli: return 0; case LDKSiPrefix_Micro: return 1; case LDKSiPrefix_Nano: return 2; case LDKSiPrefix_Pico: return 3; default: abort(); } } uint32_t __attribute__((visibility("default"))) TS_LDKCVec_u8Z_new(int8_tArray elems) { LDKCVec_u8Z *ret = MALLOC(sizeof(LDKCVec_u8Z), "LDKCVec_u8Z"); ret->datalen = *((uint32_t*)elems); if (ret->datalen == 0) { ret->data = NULL; } else { ret->data = MALLOC(sizeof(uint8_t) * ret->datalen, "LDKCVec_u8Z Data"); int8_t *java_elems = (int8_t*)(elems + 4); for (size_t i = 0; i < ret->datalen; i++) { ret->data[i] = java_elems[i]; } } return (uint64_t)ret; } static inline LDKCVec_u8Z CVec_u8Z_clone(const LDKCVec_u8Z *orig) { LDKCVec_u8Z ret = { .data = MALLOC(sizeof(int8_t) * orig->datalen, "LDKCVec_u8Z clone bytes"), .datalen = orig->datalen }; memcpy(ret.data, orig->data, sizeof(int8_t) * ret.datalen); return ret; } struct LDKCVec_u8Z TxOut_get_script_pubkey (struct LDKTxOut* thing) { return CVec_u8Z_clone(&thing->script_pubkey);}int8_tArray __attribute__((visibility("default"))) TS_TxOut_get_script_pubkey(uint32_t thing) { LDKTxOut* thing_conv = (LDKTxOut*)(thing & ~1); LDKCVec_u8Z ret_var = TxOut_get_script_pubkey(thing_conv); int8_tArray ret_arr = init_arr(ret_var.datalen, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), ret_var.data, ret_var.datalen); CVec_u8Z_free(ret_var); return ret_arr; } uint64_t TxOut_get_value (struct LDKTxOut* thing) { return thing->value;}int64_t __attribute__((visibility("default"))) TS_TxOut_get_value(uint32_t thing) { LDKTxOut* thing_conv = (LDKTxOut*)(thing & ~1); int64_t ret_val = TxOut_get_value(thing_conv); return ret_val; } jboolean __attribute__((visibility("default"))) TS_LDKCResult_SecretKeyErrorZ_result_ok(uint32_t arg) { return ((LDKCResult_SecretKeyErrorZ*)arg)->result_ok; } int8_tArray __attribute__((visibility("default"))) TS_LDKCResult_SecretKeyErrorZ_get_ok(uint32_t arg) { LDKCResult_SecretKeyErrorZ *val = (LDKCResult_SecretKeyErrorZ*)(arg & ~1); CHECK(val->result_ok); int8_tArray res_arr = init_arr(32, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(res_arr + 4), (*val->contents.result).bytes, 32); return res_arr; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_SecretKeyErrorZ_get_err(uint32_t arg) { LDKCResult_SecretKeyErrorZ *val = (LDKCResult_SecretKeyErrorZ*)(arg & ~1); CHECK(!val->result_ok); uint32_t err_conv = LDKSecp256k1Error_to_js((*val->contents.err)); return err_conv; } jboolean __attribute__((visibility("default"))) TS_LDKCResult_PublicKeyErrorZ_result_ok(uint32_t arg) { return ((LDKCResult_PublicKeyErrorZ*)arg)->result_ok; } int8_tArray __attribute__((visibility("default"))) TS_LDKCResult_PublicKeyErrorZ_get_ok(uint32_t arg) { LDKCResult_PublicKeyErrorZ *val = (LDKCResult_PublicKeyErrorZ*)(arg & ~1); CHECK(val->result_ok); int8_tArray res_arr = init_arr(33, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(res_arr + 4), (*val->contents.result).compressed_form, 33); return res_arr; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_PublicKeyErrorZ_get_err(uint32_t arg) { LDKCResult_PublicKeyErrorZ *val = (LDKCResult_PublicKeyErrorZ*)(arg & ~1); CHECK(!val->result_ok); uint32_t err_conv = LDKSecp256k1Error_to_js((*val->contents.err)); return err_conv; } jboolean __attribute__((visibility("default"))) TS_LDKCResult_TxCreationKeysDecodeErrorZ_result_ok(uint32_t arg) { return ((LDKCResult_TxCreationKeysDecodeErrorZ*)arg)->result_ok; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_TxCreationKeysDecodeErrorZ_get_ok(uint32_t arg) { LDKCResult_TxCreationKeysDecodeErrorZ *val = (LDKCResult_TxCreationKeysDecodeErrorZ*)(arg & ~1); CHECK(val->result_ok); LDKTxCreationKeys res_var = (*val->contents.result); CHECK((((uint64_t)res_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&res_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t res_ref = (uint64_t)res_var.inner & ~1; return res_ref; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_TxCreationKeysDecodeErrorZ_get_err(uint32_t arg) { LDKCResult_TxCreationKeysDecodeErrorZ *val = (LDKCResult_TxCreationKeysDecodeErrorZ*)(arg & ~1); CHECK(!val->result_ok); LDKDecodeError err_var = (*val->contents.err); CHECK((((uint64_t)err_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&err_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t err_ref = (uint64_t)err_var.inner & ~1; return err_ref; } jboolean __attribute__((visibility("default"))) TS_LDKCResult_ChannelPublicKeysDecodeErrorZ_result_ok(uint32_t arg) { return ((LDKCResult_ChannelPublicKeysDecodeErrorZ*)arg)->result_ok; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_ChannelPublicKeysDecodeErrorZ_get_ok(uint32_t arg) { LDKCResult_ChannelPublicKeysDecodeErrorZ *val = (LDKCResult_ChannelPublicKeysDecodeErrorZ*)(arg & ~1); CHECK(val->result_ok); LDKChannelPublicKeys res_var = (*val->contents.result); CHECK((((uint64_t)res_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&res_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t res_ref = (uint64_t)res_var.inner & ~1; return res_ref; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_ChannelPublicKeysDecodeErrorZ_get_err(uint32_t arg) { LDKCResult_ChannelPublicKeysDecodeErrorZ *val = (LDKCResult_ChannelPublicKeysDecodeErrorZ*)(arg & ~1); CHECK(!val->result_ok); LDKDecodeError err_var = (*val->contents.err); CHECK((((uint64_t)err_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&err_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t err_ref = (uint64_t)err_var.inner & ~1; return err_ref; } jboolean __attribute__((visibility("default"))) TS_LDKCResult_TxCreationKeysErrorZ_result_ok(uint32_t arg) { return ((LDKCResult_TxCreationKeysErrorZ*)arg)->result_ok; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_TxCreationKeysErrorZ_get_ok(uint32_t arg) { LDKCResult_TxCreationKeysErrorZ *val = (LDKCResult_TxCreationKeysErrorZ*)(arg & ~1); CHECK(val->result_ok); LDKTxCreationKeys res_var = (*val->contents.result); CHECK((((uint64_t)res_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&res_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t res_ref = (uint64_t)res_var.inner & ~1; return res_ref; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_TxCreationKeysErrorZ_get_err(uint32_t arg) { LDKCResult_TxCreationKeysErrorZ *val = (LDKCResult_TxCreationKeysErrorZ*)(arg & ~1); CHECK(!val->result_ok); uint32_t err_conv = LDKSecp256k1Error_to_js((*val->contents.err)); return err_conv; } uint32_t __attribute__((visibility("default"))) TS_LDKCOption_u32Z_ref_from_ptr(uint32_t ptr) { LDKCOption_u32Z *obj = (LDKCOption_u32Z*)(ptr & ~1); switch(obj->tag) { case LDKCOption_u32Z_Some: { return 0 /* LDKCOption_u32Z - Some */; (void) obj->some; } case LDKCOption_u32Z_None: { return 0 /* LDKCOption_u32Z - None */; } default: abort(); } } jboolean __attribute__((visibility("default"))) TS_LDKCResult_HTLCOutputInCommitmentDecodeErrorZ_result_ok(uint32_t arg) { return ((LDKCResult_HTLCOutputInCommitmentDecodeErrorZ*)arg)->result_ok; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_HTLCOutputInCommitmentDecodeErrorZ_get_ok(uint32_t arg) { LDKCResult_HTLCOutputInCommitmentDecodeErrorZ *val = (LDKCResult_HTLCOutputInCommitmentDecodeErrorZ*)(arg & ~1); CHECK(val->result_ok); LDKHTLCOutputInCommitment res_var = (*val->contents.result); CHECK((((uint64_t)res_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&res_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t res_ref = (uint64_t)res_var.inner & ~1; return res_ref; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_HTLCOutputInCommitmentDecodeErrorZ_get_err(uint32_t arg) { LDKCResult_HTLCOutputInCommitmentDecodeErrorZ *val = (LDKCResult_HTLCOutputInCommitmentDecodeErrorZ*)(arg & ~1); CHECK(!val->result_ok); LDKDecodeError err_var = (*val->contents.err); CHECK((((uint64_t)err_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&err_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t err_ref = (uint64_t)err_var.inner & ~1; return err_ref; } jboolean __attribute__((visibility("default"))) TS_LDKCResult_CounterpartyChannelTransactionParametersDecodeErrorZ_result_ok(uint32_t arg) { return ((LDKCResult_CounterpartyChannelTransactionParametersDecodeErrorZ*)arg)->result_ok; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_CounterpartyChannelTransactionParametersDecodeErrorZ_get_ok(uint32_t arg) { LDKCResult_CounterpartyChannelTransactionParametersDecodeErrorZ *val = (LDKCResult_CounterpartyChannelTransactionParametersDecodeErrorZ*)(arg & ~1); CHECK(val->result_ok); LDKCounterpartyChannelTransactionParameters res_var = (*val->contents.result); CHECK((((uint64_t)res_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&res_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t res_ref = (uint64_t)res_var.inner & ~1; return res_ref; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_CounterpartyChannelTransactionParametersDecodeErrorZ_get_err(uint32_t arg) { LDKCResult_CounterpartyChannelTransactionParametersDecodeErrorZ *val = (LDKCResult_CounterpartyChannelTransactionParametersDecodeErrorZ*)(arg & ~1); CHECK(!val->result_ok); LDKDecodeError err_var = (*val->contents.err); CHECK((((uint64_t)err_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&err_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t err_ref = (uint64_t)err_var.inner & ~1; return err_ref; } jboolean __attribute__((visibility("default"))) TS_LDKCResult_ChannelTransactionParametersDecodeErrorZ_result_ok(uint32_t arg) { return ((LDKCResult_ChannelTransactionParametersDecodeErrorZ*)arg)->result_ok; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_ChannelTransactionParametersDecodeErrorZ_get_ok(uint32_t arg) { LDKCResult_ChannelTransactionParametersDecodeErrorZ *val = (LDKCResult_ChannelTransactionParametersDecodeErrorZ*)(arg & ~1); CHECK(val->result_ok); LDKChannelTransactionParameters res_var = (*val->contents.result); CHECK((((uint64_t)res_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&res_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t res_ref = (uint64_t)res_var.inner & ~1; return res_ref; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_ChannelTransactionParametersDecodeErrorZ_get_err(uint32_t arg) { LDKCResult_ChannelTransactionParametersDecodeErrorZ *val = (LDKCResult_ChannelTransactionParametersDecodeErrorZ*)(arg & ~1); CHECK(!val->result_ok); LDKDecodeError err_var = (*val->contents.err); CHECK((((uint64_t)err_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&err_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t err_ref = (uint64_t)err_var.inner & ~1; return err_ref; } jboolean __attribute__((visibility("default"))) TS_LDKCResult_HolderCommitmentTransactionDecodeErrorZ_result_ok(uint32_t arg) { return ((LDKCResult_HolderCommitmentTransactionDecodeErrorZ*)arg)->result_ok; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_HolderCommitmentTransactionDecodeErrorZ_get_ok(uint32_t arg) { LDKCResult_HolderCommitmentTransactionDecodeErrorZ *val = (LDKCResult_HolderCommitmentTransactionDecodeErrorZ*)(arg & ~1); CHECK(val->result_ok); LDKHolderCommitmentTransaction res_var = (*val->contents.result); CHECK((((uint64_t)res_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&res_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t res_ref = (uint64_t)res_var.inner & ~1; return res_ref; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_HolderCommitmentTransactionDecodeErrorZ_get_err(uint32_t arg) { LDKCResult_HolderCommitmentTransactionDecodeErrorZ *val = (LDKCResult_HolderCommitmentTransactionDecodeErrorZ*)(arg & ~1); CHECK(!val->result_ok); LDKDecodeError err_var = (*val->contents.err); CHECK((((uint64_t)err_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&err_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t err_ref = (uint64_t)err_var.inner & ~1; return err_ref; } jboolean __attribute__((visibility("default"))) TS_LDKCResult_BuiltCommitmentTransactionDecodeErrorZ_result_ok(uint32_t arg) { return ((LDKCResult_BuiltCommitmentTransactionDecodeErrorZ*)arg)->result_ok; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_BuiltCommitmentTransactionDecodeErrorZ_get_ok(uint32_t arg) { LDKCResult_BuiltCommitmentTransactionDecodeErrorZ *val = (LDKCResult_BuiltCommitmentTransactionDecodeErrorZ*)(arg & ~1); CHECK(val->result_ok); LDKBuiltCommitmentTransaction res_var = (*val->contents.result); CHECK((((uint64_t)res_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&res_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t res_ref = (uint64_t)res_var.inner & ~1; return res_ref; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_BuiltCommitmentTransactionDecodeErrorZ_get_err(uint32_t arg) { LDKCResult_BuiltCommitmentTransactionDecodeErrorZ *val = (LDKCResult_BuiltCommitmentTransactionDecodeErrorZ*)(arg & ~1); CHECK(!val->result_ok); LDKDecodeError err_var = (*val->contents.err); CHECK((((uint64_t)err_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&err_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t err_ref = (uint64_t)err_var.inner & ~1; return err_ref; } jboolean __attribute__((visibility("default"))) TS_LDKCResult_TrustedClosingTransactionNoneZ_result_ok(uint32_t arg) { return ((LDKCResult_TrustedClosingTransactionNoneZ*)arg)->result_ok; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_TrustedClosingTransactionNoneZ_get_ok(uint32_t arg) { LDKCResult_TrustedClosingTransactionNoneZ *val = (LDKCResult_TrustedClosingTransactionNoneZ*)(arg & ~1); CHECK(val->result_ok); LDKTrustedClosingTransaction res_var = (*val->contents.result); CHECK((((uint64_t)res_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&res_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t res_ref = (uint64_t)res_var.inner & ~1; return res_ref; } void __attribute__((visibility("default"))) TS_LDKCResult_TrustedClosingTransactionNoneZ_get_err(uint32_t arg) { LDKCResult_TrustedClosingTransactionNoneZ *val = (LDKCResult_TrustedClosingTransactionNoneZ*)(arg & ~1); CHECK(!val->result_ok); return *val->contents.err; } jboolean __attribute__((visibility("default"))) TS_LDKCResult_CommitmentTransactionDecodeErrorZ_result_ok(uint32_t arg) { return ((LDKCResult_CommitmentTransactionDecodeErrorZ*)arg)->result_ok; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_CommitmentTransactionDecodeErrorZ_get_ok(uint32_t arg) { LDKCResult_CommitmentTransactionDecodeErrorZ *val = (LDKCResult_CommitmentTransactionDecodeErrorZ*)(arg & ~1); CHECK(val->result_ok); LDKCommitmentTransaction res_var = (*val->contents.result); CHECK((((uint64_t)res_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&res_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t res_ref = (uint64_t)res_var.inner & ~1; return res_ref; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_CommitmentTransactionDecodeErrorZ_get_err(uint32_t arg) { LDKCResult_CommitmentTransactionDecodeErrorZ *val = (LDKCResult_CommitmentTransactionDecodeErrorZ*)(arg & ~1); CHECK(!val->result_ok); LDKDecodeError err_var = (*val->contents.err); CHECK((((uint64_t)err_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&err_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t err_ref = (uint64_t)err_var.inner & ~1; return err_ref; } jboolean __attribute__((visibility("default"))) TS_LDKCResult_TrustedCommitmentTransactionNoneZ_result_ok(uint32_t arg) { return ((LDKCResult_TrustedCommitmentTransactionNoneZ*)arg)->result_ok; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_TrustedCommitmentTransactionNoneZ_get_ok(uint32_t arg) { LDKCResult_TrustedCommitmentTransactionNoneZ *val = (LDKCResult_TrustedCommitmentTransactionNoneZ*)(arg & ~1); CHECK(val->result_ok); LDKTrustedCommitmentTransaction res_var = (*val->contents.result); CHECK((((uint64_t)res_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&res_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t res_ref = (uint64_t)res_var.inner & ~1; return res_ref; } void __attribute__((visibility("default"))) TS_LDKCResult_TrustedCommitmentTransactionNoneZ_get_err(uint32_t arg) { LDKCResult_TrustedCommitmentTransactionNoneZ *val = (LDKCResult_TrustedCommitmentTransactionNoneZ*)(arg & ~1); CHECK(!val->result_ok); return *val->contents.err; } jboolean __attribute__((visibility("default"))) TS_LDKCResult_CVec_SignatureZNoneZ_result_ok(uint32_t arg) { return ((LDKCResult_CVec_SignatureZNoneZ*)arg)->result_ok; } ptrArray __attribute__((visibility("default"))) TS_LDKCResult_CVec_SignatureZNoneZ_get_ok(uint32_t arg) { LDKCResult_CVec_SignatureZNoneZ *val = (LDKCResult_CVec_SignatureZNoneZ*)(arg & ~1); CHECK(val->result_ok); LDKCVec_SignatureZ res_var = (*val->contents.result); ptrArray res_arr = init_arr(res_var.datalen, sizeof(uint32_t), "Native ptrArray Bytes"); int8_tArray *res_arr_ptr = (int8_tArray*)(res_arr + 4); for (size_t m = 0; m < res_var.datalen; m++) { int8_tArray res_conv_12_arr = init_arr(64, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(res_conv_12_arr + 4), res_var.data[m].compact_form, 64); res_arr_ptr[m] = res_conv_12_arr; } return res_arr; } void __attribute__((visibility("default"))) TS_LDKCResult_CVec_SignatureZNoneZ_get_err(uint32_t arg) { LDKCResult_CVec_SignatureZNoneZ *val = (LDKCResult_CVec_SignatureZNoneZ*)(arg & ~1); CHECK(!val->result_ok); return *val->contents.err; } jboolean __attribute__((visibility("default"))) TS_LDKCResult_ShutdownScriptDecodeErrorZ_result_ok(uint32_t arg) { return ((LDKCResult_ShutdownScriptDecodeErrorZ*)arg)->result_ok; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_ShutdownScriptDecodeErrorZ_get_ok(uint32_t arg) { LDKCResult_ShutdownScriptDecodeErrorZ *val = (LDKCResult_ShutdownScriptDecodeErrorZ*)(arg & ~1); CHECK(val->result_ok); LDKShutdownScript res_var = (*val->contents.result); CHECK((((uint64_t)res_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&res_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t res_ref = (uint64_t)res_var.inner & ~1; return res_ref; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_ShutdownScriptDecodeErrorZ_get_err(uint32_t arg) { LDKCResult_ShutdownScriptDecodeErrorZ *val = (LDKCResult_ShutdownScriptDecodeErrorZ*)(arg & ~1); CHECK(!val->result_ok); LDKDecodeError err_var = (*val->contents.err); CHECK((((uint64_t)err_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&err_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t err_ref = (uint64_t)err_var.inner & ~1; return err_ref; } jboolean __attribute__((visibility("default"))) TS_LDKCResult_ShutdownScriptInvalidShutdownScriptZ_result_ok(uint32_t arg) { return ((LDKCResult_ShutdownScriptInvalidShutdownScriptZ*)arg)->result_ok; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_ShutdownScriptInvalidShutdownScriptZ_get_ok(uint32_t arg) { LDKCResult_ShutdownScriptInvalidShutdownScriptZ *val = (LDKCResult_ShutdownScriptInvalidShutdownScriptZ*)(arg & ~1); CHECK(val->result_ok); LDKShutdownScript res_var = (*val->contents.result); CHECK((((uint64_t)res_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&res_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t res_ref = (uint64_t)res_var.inner & ~1; return res_ref; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_ShutdownScriptInvalidShutdownScriptZ_get_err(uint32_t arg) { LDKCResult_ShutdownScriptInvalidShutdownScriptZ *val = (LDKCResult_ShutdownScriptInvalidShutdownScriptZ*)(arg & ~1); CHECK(!val->result_ok); LDKInvalidShutdownScript err_var = (*val->contents.err); CHECK((((uint64_t)err_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&err_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t err_ref = (uint64_t)err_var.inner & ~1; return err_ref; } jboolean __attribute__((visibility("default"))) TS_LDKCResult_NoneErrorZ_result_ok(uint32_t arg) { return ((LDKCResult_NoneErrorZ*)arg)->result_ok; } void __attribute__((visibility("default"))) TS_LDKCResult_NoneErrorZ_get_ok(uint32_t arg) { LDKCResult_NoneErrorZ *val = (LDKCResult_NoneErrorZ*)(arg & ~1); CHECK(val->result_ok); return *val->contents.result; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_NoneErrorZ_get_err(uint32_t arg) { LDKCResult_NoneErrorZ *val = (LDKCResult_NoneErrorZ*)(arg & ~1); CHECK(!val->result_ok); uint32_t err_conv = LDKIOError_to_js((*val->contents.err)); return err_conv; } jboolean __attribute__((visibility("default"))) TS_LDKCResult_RouteHopDecodeErrorZ_result_ok(uint32_t arg) { return ((LDKCResult_RouteHopDecodeErrorZ*)arg)->result_ok; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_RouteHopDecodeErrorZ_get_ok(uint32_t arg) { LDKCResult_RouteHopDecodeErrorZ *val = (LDKCResult_RouteHopDecodeErrorZ*)(arg & ~1); CHECK(val->result_ok); LDKRouteHop res_var = (*val->contents.result); CHECK((((uint64_t)res_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&res_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t res_ref = (uint64_t)res_var.inner & ~1; return res_ref; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_RouteHopDecodeErrorZ_get_err(uint32_t arg) { LDKCResult_RouteHopDecodeErrorZ *val = (LDKCResult_RouteHopDecodeErrorZ*)(arg & ~1); CHECK(!val->result_ok); LDKDecodeError err_var = (*val->contents.err); CHECK((((uint64_t)err_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&err_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t err_ref = (uint64_t)err_var.inner & ~1; return err_ref; } uint32_t __attribute__((visibility("default"))) TS_LDKCVec_RouteHopZ_new(uint32_tArray elems) { LDKCVec_RouteHopZ *ret = MALLOC(sizeof(LDKCVec_RouteHopZ), "LDKCVec_RouteHopZ"); ret->datalen = *((uint32_t*)elems); if (ret->datalen == 0) { ret->data = NULL; } else { ret->data = MALLOC(sizeof(LDKRouteHop) * ret->datalen, "LDKCVec_RouteHopZ Data"); uint32_t *java_elems = (uint32_t*)(elems + 4); for (size_t i = 0; i < ret->datalen; i++) { uint32_t arr_elem = java_elems[i]; LDKRouteHop arr_elem_conv; arr_elem_conv.inner = (void*)(arr_elem & (~1)); arr_elem_conv.is_owned = (arr_elem & 1) || (arr_elem == 0); arr_elem_conv = RouteHop_clone(&arr_elem_conv); ret->data[i] = arr_elem_conv; } } return (uint64_t)ret; } static inline LDKCVec_RouteHopZ CVec_RouteHopZ_clone(const LDKCVec_RouteHopZ *orig) { LDKCVec_RouteHopZ ret = { .data = MALLOC(sizeof(LDKRouteHop) * orig->datalen, "LDKCVec_RouteHopZ clone bytes"), .datalen = orig->datalen }; for (size_t i = 0; i < ret.datalen; i++) { ret.data[i] = RouteHop_clone(&orig->data[i]); } return ret; } static inline LDKCVec_CVec_RouteHopZZ CVec_CVec_RouteHopZZ_clone(const LDKCVec_CVec_RouteHopZZ *orig) { LDKCVec_CVec_RouteHopZZ ret = { .data = MALLOC(sizeof(LDKCVec_RouteHopZ) * orig->datalen, "LDKCVec_CVec_RouteHopZZ clone bytes"), .datalen = orig->datalen }; for (size_t i = 0; i < ret.datalen; i++) { ret.data[i] = CVec_RouteHopZ_clone(&orig->data[i]); } return ret; } jboolean __attribute__((visibility("default"))) TS_LDKCResult_RouteDecodeErrorZ_result_ok(uint32_t arg) { return ((LDKCResult_RouteDecodeErrorZ*)arg)->result_ok; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_RouteDecodeErrorZ_get_ok(uint32_t arg) { LDKCResult_RouteDecodeErrorZ *val = (LDKCResult_RouteDecodeErrorZ*)(arg & ~1); CHECK(val->result_ok); LDKRoute res_var = (*val->contents.result); CHECK((((uint64_t)res_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&res_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t res_ref = (uint64_t)res_var.inner & ~1; return res_ref; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_RouteDecodeErrorZ_get_err(uint32_t arg) { LDKCResult_RouteDecodeErrorZ *val = (LDKCResult_RouteDecodeErrorZ*)(arg & ~1); CHECK(!val->result_ok); LDKDecodeError err_var = (*val->contents.err); CHECK((((uint64_t)err_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&err_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t err_ref = (uint64_t)err_var.inner & ~1; return err_ref; } uint32_t __attribute__((visibility("default"))) TS_LDKCOption_u64Z_ref_from_ptr(uint32_t ptr) { LDKCOption_u64Z *obj = (LDKCOption_u64Z*)(ptr & ~1); switch(obj->tag) { case LDKCOption_u64Z_Some: { return 0 /* LDKCOption_u64Z - Some */; (void) obj->some; } case LDKCOption_u64Z_None: { return 0 /* LDKCOption_u64Z - None */; } default: abort(); } } uint32_t __attribute__((visibility("default"))) TS_LDKCVec_ChannelDetailsZ_new(uint32_tArray elems) { LDKCVec_ChannelDetailsZ *ret = MALLOC(sizeof(LDKCVec_ChannelDetailsZ), "LDKCVec_ChannelDetailsZ"); ret->datalen = *((uint32_t*)elems); if (ret->datalen == 0) { ret->data = NULL; } else { ret->data = MALLOC(sizeof(LDKChannelDetails) * ret->datalen, "LDKCVec_ChannelDetailsZ Data"); uint32_t *java_elems = (uint32_t*)(elems + 4); for (size_t i = 0; i < ret->datalen; i++) { uint32_t arr_elem = java_elems[i]; LDKChannelDetails arr_elem_conv; arr_elem_conv.inner = (void*)(arr_elem & (~1)); arr_elem_conv.is_owned = (arr_elem & 1) || (arr_elem == 0); arr_elem_conv = ChannelDetails_clone(&arr_elem_conv); ret->data[i] = arr_elem_conv; } } return (uint64_t)ret; } static inline LDKCVec_ChannelDetailsZ CVec_ChannelDetailsZ_clone(const LDKCVec_ChannelDetailsZ *orig) { LDKCVec_ChannelDetailsZ ret = { .data = MALLOC(sizeof(LDKChannelDetails) * orig->datalen, "LDKCVec_ChannelDetailsZ clone bytes"), .datalen = orig->datalen }; for (size_t i = 0; i < ret.datalen; i++) { ret.data[i] = ChannelDetails_clone(&orig->data[i]); } return ret; } uint32_t __attribute__((visibility("default"))) TS_LDKCVec_RouteHintZ_new(uint32_tArray elems) { LDKCVec_RouteHintZ *ret = MALLOC(sizeof(LDKCVec_RouteHintZ), "LDKCVec_RouteHintZ"); ret->datalen = *((uint32_t*)elems); if (ret->datalen == 0) { ret->data = NULL; } else { ret->data = MALLOC(sizeof(LDKRouteHint) * ret->datalen, "LDKCVec_RouteHintZ Data"); uint32_t *java_elems = (uint32_t*)(elems + 4); for (size_t i = 0; i < ret->datalen; i++) { uint32_t arr_elem = java_elems[i]; LDKRouteHint arr_elem_conv; arr_elem_conv.inner = (void*)(arr_elem & (~1)); arr_elem_conv.is_owned = (arr_elem & 1) || (arr_elem == 0); arr_elem_conv = RouteHint_clone(&arr_elem_conv); ret->data[i] = arr_elem_conv; } } return (uint64_t)ret; } static inline LDKCVec_RouteHintZ CVec_RouteHintZ_clone(const LDKCVec_RouteHintZ *orig) { LDKCVec_RouteHintZ ret = { .data = MALLOC(sizeof(LDKRouteHint) * orig->datalen, "LDKCVec_RouteHintZ clone bytes"), .datalen = orig->datalen }; for (size_t i = 0; i < ret.datalen; i++) { ret.data[i] = RouteHint_clone(&orig->data[i]); } return ret; } jboolean __attribute__((visibility("default"))) TS_LDKCResult_RouteLightningErrorZ_result_ok(uint32_t arg) { return ((LDKCResult_RouteLightningErrorZ*)arg)->result_ok; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_RouteLightningErrorZ_get_ok(uint32_t arg) { LDKCResult_RouteLightningErrorZ *val = (LDKCResult_RouteLightningErrorZ*)(arg & ~1); CHECK(val->result_ok); LDKRoute res_var = (*val->contents.result); CHECK((((uint64_t)res_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&res_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t res_ref = (uint64_t)res_var.inner & ~1; return res_ref; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_RouteLightningErrorZ_get_err(uint32_t arg) { LDKCResult_RouteLightningErrorZ *val = (LDKCResult_RouteLightningErrorZ*)(arg & ~1); CHECK(!val->result_ok); LDKLightningError err_var = (*val->contents.err); CHECK((((uint64_t)err_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&err_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t err_ref = (uint64_t)err_var.inner & ~1; return err_ref; } jboolean __attribute__((visibility("default"))) TS_LDKCResult_TxOutAccessErrorZ_result_ok(uint32_t arg) { return ((LDKCResult_TxOutAccessErrorZ*)arg)->result_ok; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_TxOutAccessErrorZ_get_ok(uint32_t arg) { LDKCResult_TxOutAccessErrorZ *val = (LDKCResult_TxOutAccessErrorZ*)(arg & ~1); CHECK(val->result_ok); uint64_t res_ref = ((uint64_t)&(*val->contents.result)) | 1; return (uint64_t)res_ref; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_TxOutAccessErrorZ_get_err(uint32_t arg) { LDKCResult_TxOutAccessErrorZ *val = (LDKCResult_TxOutAccessErrorZ*)(arg & ~1); CHECK(!val->result_ok); uint32_t err_conv = LDKAccessError_to_js((*val->contents.err)); return err_conv; } uint32_t __attribute__((visibility("default"))) TS_LDKC2Tuple_usizeTransactionZ_new(int64_t a, int8_tArray b) { LDKC2Tuple_usizeTransactionZ* ret = MALLOC(sizeof(LDKC2Tuple_usizeTransactionZ), "LDKC2Tuple_usizeTransactionZ"); ret->a = a; LDKTransaction b_ref; b_ref.datalen = *((uint32_t*)b); b_ref.data = MALLOC(b_ref.datalen, "LDKTransaction Bytes"); memcpy(b_ref.data, (uint8_t*)(b + 4), b_ref.datalen); b_ref.data_is_owned = false; ret->b = b_ref; return (uint64_t)ret; } int64_t __attribute__((visibility("default"))) TS_LDKC2Tuple_usizeTransactionZ_get_a(uint32_t ptr) { LDKC2Tuple_usizeTransactionZ *tuple = (LDKC2Tuple_usizeTransactionZ*)(ptr & ~1); return tuple->a; } int8_tArray __attribute__((visibility("default"))) TS_LDKC2Tuple_usizeTransactionZ_get_b(uint32_t ptr) { LDKC2Tuple_usizeTransactionZ *tuple = (LDKC2Tuple_usizeTransactionZ*)(ptr & ~1); LDKTransaction b_var = tuple->b; int8_tArray b_arr = init_arr(b_var.datalen, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(b_arr + 4), b_var.data, b_var.datalen); return b_arr; } uint32_t __attribute__((visibility("default"))) TS_LDKCVec_C2Tuple_usizeTransactionZZ_new(uint32_tArray elems) { LDKCVec_C2Tuple_usizeTransactionZZ *ret = MALLOC(sizeof(LDKCVec_C2Tuple_usizeTransactionZZ), "LDKCVec_C2Tuple_usizeTransactionZZ"); ret->datalen = *((uint32_t*)elems); if (ret->datalen == 0) { ret->data = NULL; } else { ret->data = MALLOC(sizeof(LDKC2Tuple_usizeTransactionZ) * ret->datalen, "LDKCVec_C2Tuple_usizeTransactionZZ Data"); uint32_t *java_elems = (uint32_t*)(elems + 4); for (size_t i = 0; i < ret->datalen; i++) { uint32_t arr_elem = java_elems[i]; LDKC2Tuple_usizeTransactionZ arr_elem_conv = *(LDKC2Tuple_usizeTransactionZ*)(((uint64_t)arr_elem) & ~1); arr_elem_conv = C2Tuple_usizeTransactionZ_clone((LDKC2Tuple_usizeTransactionZ*)(((uint64_t)arr_elem) & ~1)); ret->data[i] = arr_elem_conv; } } return (uint64_t)ret; } static inline LDKCVec_C2Tuple_usizeTransactionZZ CVec_C2Tuple_usizeTransactionZZ_clone(const LDKCVec_C2Tuple_usizeTransactionZZ *orig) { LDKCVec_C2Tuple_usizeTransactionZZ ret = { .data = MALLOC(sizeof(LDKC2Tuple_usizeTransactionZ) * orig->datalen, "LDKCVec_C2Tuple_usizeTransactionZZ clone bytes"), .datalen = orig->datalen }; for (size_t i = 0; i < ret.datalen; i++) { ret.data[i] = C2Tuple_usizeTransactionZ_clone(&orig->data[i]); } return ret; } static inline LDKCVec_TxidZ CVec_ThirtyTwoBytesZ_clone(const LDKCVec_TxidZ *orig) { LDKCVec_TxidZ ret = { .data = MALLOC(sizeof(LDKThirtyTwoBytes) * orig->datalen, "LDKCVec_TxidZ clone bytes"), .datalen = orig->datalen }; for (size_t i = 0; i < ret.datalen; i++) { ret.data[i] = ThirtyTwoBytes_clone(&orig->data[i]); } return ret; } jboolean __attribute__((visibility("default"))) TS_LDKCResult_NoneChannelMonitorUpdateErrZ_result_ok(uint32_t arg) { return ((LDKCResult_NoneChannelMonitorUpdateErrZ*)arg)->result_ok; } void __attribute__((visibility("default"))) TS_LDKCResult_NoneChannelMonitorUpdateErrZ_get_ok(uint32_t arg) { LDKCResult_NoneChannelMonitorUpdateErrZ *val = (LDKCResult_NoneChannelMonitorUpdateErrZ*)(arg & ~1); CHECK(val->result_ok); return *val->contents.result; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_NoneChannelMonitorUpdateErrZ_get_err(uint32_t arg) { LDKCResult_NoneChannelMonitorUpdateErrZ *val = (LDKCResult_NoneChannelMonitorUpdateErrZ*)(arg & ~1); CHECK(!val->result_ok); uint32_t err_conv = LDKChannelMonitorUpdateErr_to_js((*val->contents.err)); return err_conv; } uint32_t __attribute__((visibility("default"))) TS_LDKMonitorEvent_ref_from_ptr(uint32_t ptr) { LDKMonitorEvent *obj = (LDKMonitorEvent*)(ptr & ~1); switch(obj->tag) { case LDKMonitorEvent_HTLCEvent: { LDKHTLCUpdate htlc_event_var = obj->htlc_event; CHECK((((uint64_t)htlc_event_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&htlc_event_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t htlc_event_ref = (uint64_t)htlc_event_var.inner & ~1; return 0 /* LDKMonitorEvent - HTLCEvent */; (void) htlc_event_ref; } case LDKMonitorEvent_CommitmentTxConfirmed: { LDKOutPoint commitment_tx_confirmed_var = obj->commitment_tx_confirmed; CHECK((((uint64_t)commitment_tx_confirmed_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&commitment_tx_confirmed_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t commitment_tx_confirmed_ref = (uint64_t)commitment_tx_confirmed_var.inner & ~1; return 0 /* LDKMonitorEvent - CommitmentTxConfirmed */; (void) commitment_tx_confirmed_ref; } default: abort(); } } uint32_t __attribute__((visibility("default"))) TS_LDKCVec_MonitorEventZ_new(uint32_tArray elems) { LDKCVec_MonitorEventZ *ret = MALLOC(sizeof(LDKCVec_MonitorEventZ), "LDKCVec_MonitorEventZ"); ret->datalen = *((uint32_t*)elems); if (ret->datalen == 0) { ret->data = NULL; } else { ret->data = MALLOC(sizeof(LDKMonitorEvent) * ret->datalen, "LDKCVec_MonitorEventZ Data"); uint32_t *java_elems = (uint32_t*)(elems + 4); for (size_t i = 0; i < ret->datalen; i++) { uint32_t arr_elem = java_elems[i]; LDKMonitorEvent arr_elem_conv = *(LDKMonitorEvent*)(((uint64_t)arr_elem) & ~1); arr_elem_conv = MonitorEvent_clone((LDKMonitorEvent*)(((uint64_t)arr_elem) & ~1)); ret->data[i] = arr_elem_conv; } } return (uint64_t)ret; } static inline LDKCVec_MonitorEventZ CVec_MonitorEventZ_clone(const LDKCVec_MonitorEventZ *orig) { LDKCVec_MonitorEventZ ret = { .data = MALLOC(sizeof(LDKMonitorEvent) * orig->datalen, "LDKCVec_MonitorEventZ clone bytes"), .datalen = orig->datalen }; for (size_t i = 0; i < ret.datalen; i++) { ret.data[i] = MonitorEvent_clone(&orig->data[i]); } return ret; } uint32_t __attribute__((visibility("default"))) TS_LDKCOption_C2Tuple_usizeTransactionZZ_ref_from_ptr(uint32_t ptr) { LDKCOption_C2Tuple_usizeTransactionZZ *obj = (LDKCOption_C2Tuple_usizeTransactionZZ*)(ptr & ~1); switch(obj->tag) { case LDKCOption_C2Tuple_usizeTransactionZZ_Some: { uint64_t some_ref = (uint64_t)(&obj->some) | 1; return 0 /* LDKCOption_C2Tuple_usizeTransactionZZ - Some */; (void) some_ref; } case LDKCOption_C2Tuple_usizeTransactionZZ_None: { return 0 /* LDKCOption_C2Tuple_usizeTransactionZZ - None */; } default: abort(); } } uint32_t __attribute__((visibility("default"))) TS_LDKNetworkUpdate_ref_from_ptr(uint32_t ptr) { LDKNetworkUpdate *obj = (LDKNetworkUpdate*)(ptr & ~1); switch(obj->tag) { case LDKNetworkUpdate_ChannelUpdateMessage: { LDKChannelUpdate msg_var = obj->channel_update_message.msg; CHECK((((uint64_t)msg_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&msg_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t msg_ref = (uint64_t)msg_var.inner & ~1; return 0 /* LDKNetworkUpdate - ChannelUpdateMessage */; (void) msg_ref; } case LDKNetworkUpdate_ChannelClosed: { return 0 /* LDKNetworkUpdate - ChannelClosed */; (void) obj->channel_closed.short_channel_id; (void) obj->channel_closed.is_permanent; } case LDKNetworkUpdate_NodeFailure: { int8_tArray node_id_arr = init_arr(33, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(node_id_arr + 4), obj->node_failure.node_id.compressed_form, 33); return 0 /* LDKNetworkUpdate - NodeFailure */; (void) node_id_arr; (void) obj->node_failure.is_permanent; } default: abort(); } } uint32_t __attribute__((visibility("default"))) TS_LDKCOption_NetworkUpdateZ_ref_from_ptr(uint32_t ptr) { LDKCOption_NetworkUpdateZ *obj = (LDKCOption_NetworkUpdateZ*)(ptr & ~1); switch(obj->tag) { case LDKCOption_NetworkUpdateZ_Some: { uint64_t some_ref = ((uint64_t)&obj->some) | 1; return 0 /* LDKCOption_NetworkUpdateZ - Some */; (void) some_ref; } case LDKCOption_NetworkUpdateZ_None: { return 0 /* LDKCOption_NetworkUpdateZ - None */; } default: abort(); } } uint32_t __attribute__((visibility("default"))) TS_LDKSpendableOutputDescriptor_ref_from_ptr(uint32_t ptr) { LDKSpendableOutputDescriptor *obj = (LDKSpendableOutputDescriptor*)(ptr & ~1); switch(obj->tag) { case LDKSpendableOutputDescriptor_StaticOutput: { LDKOutPoint outpoint_var = obj->static_output.outpoint; CHECK((((uint64_t)outpoint_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&outpoint_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t outpoint_ref = (uint64_t)outpoint_var.inner & ~1; uint64_t output_ref = ((uint64_t)&obj->static_output.output) | 1; return 0 /* LDKSpendableOutputDescriptor - StaticOutput */; (void) outpoint_ref; (void) (uint64_t)output_ref; } case LDKSpendableOutputDescriptor_DelayedPaymentOutput: { LDKDelayedPaymentOutputDescriptor delayed_payment_output_var = obj->delayed_payment_output; CHECK((((uint64_t)delayed_payment_output_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&delayed_payment_output_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t delayed_payment_output_ref = (uint64_t)delayed_payment_output_var.inner & ~1; return 0 /* LDKSpendableOutputDescriptor - DelayedPaymentOutput */; (void) delayed_payment_output_ref; } case LDKSpendableOutputDescriptor_StaticPaymentOutput: { LDKStaticPaymentOutputDescriptor static_payment_output_var = obj->static_payment_output; CHECK((((uint64_t)static_payment_output_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&static_payment_output_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t static_payment_output_ref = (uint64_t)static_payment_output_var.inner & ~1; return 0 /* LDKSpendableOutputDescriptor - StaticPaymentOutput */; (void) static_payment_output_ref; } default: abort(); } } uint32_t __attribute__((visibility("default"))) TS_LDKCVec_SpendableOutputDescriptorZ_new(uint32_tArray elems) { LDKCVec_SpendableOutputDescriptorZ *ret = MALLOC(sizeof(LDKCVec_SpendableOutputDescriptorZ), "LDKCVec_SpendableOutputDescriptorZ"); ret->datalen = *((uint32_t*)elems); if (ret->datalen == 0) { ret->data = NULL; } else { ret->data = MALLOC(sizeof(LDKSpendableOutputDescriptor) * ret->datalen, "LDKCVec_SpendableOutputDescriptorZ Data"); uint32_t *java_elems = (uint32_t*)(elems + 4); for (size_t i = 0; i < ret->datalen; i++) { uint32_t arr_elem = java_elems[i]; LDKSpendableOutputDescriptor arr_elem_conv = *(LDKSpendableOutputDescriptor*)(((uint64_t)arr_elem) & ~1); arr_elem_conv = SpendableOutputDescriptor_clone((LDKSpendableOutputDescriptor*)(((uint64_t)arr_elem) & ~1)); ret->data[i] = arr_elem_conv; } } return (uint64_t)ret; } static inline LDKCVec_SpendableOutputDescriptorZ CVec_SpendableOutputDescriptorZ_clone(const LDKCVec_SpendableOutputDescriptorZ *orig) { LDKCVec_SpendableOutputDescriptorZ ret = { .data = MALLOC(sizeof(LDKSpendableOutputDescriptor) * orig->datalen, "LDKCVec_SpendableOutputDescriptorZ clone bytes"), .datalen = orig->datalen }; for (size_t i = 0; i < ret.datalen; i++) { ret.data[i] = SpendableOutputDescriptor_clone(&orig->data[i]); } return ret; } uint32_t __attribute__((visibility("default"))) TS_LDKErrorAction_ref_from_ptr(uint32_t ptr) { LDKErrorAction *obj = (LDKErrorAction*)(ptr & ~1); switch(obj->tag) { case LDKErrorAction_DisconnectPeer: { LDKErrorMessage msg_var = obj->disconnect_peer.msg; CHECK((((uint64_t)msg_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&msg_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t msg_ref = (uint64_t)msg_var.inner & ~1; return 0 /* LDKErrorAction - DisconnectPeer */; (void) msg_ref; } case LDKErrorAction_IgnoreError: { return 0 /* LDKErrorAction - IgnoreError */; } case LDKErrorAction_IgnoreAndLog: { uint32_t ignore_and_log_conv = LDKLevel_to_js(obj->ignore_and_log); return 0 /* LDKErrorAction - IgnoreAndLog */; (void) ignore_and_log_conv; } case LDKErrorAction_SendErrorMessage: { LDKErrorMessage msg_var = obj->send_error_message.msg; CHECK((((uint64_t)msg_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&msg_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t msg_ref = (uint64_t)msg_var.inner & ~1; return 0 /* LDKErrorAction - SendErrorMessage */; (void) msg_ref; } default: abort(); } } uint32_t __attribute__((visibility("default"))) TS_LDKMessageSendEvent_ref_from_ptr(uint32_t ptr) { LDKMessageSendEvent *obj = (LDKMessageSendEvent*)(ptr & ~1); switch(obj->tag) { case LDKMessageSendEvent_SendAcceptChannel: { int8_tArray node_id_arr = init_arr(33, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(node_id_arr + 4), obj->send_accept_channel.node_id.compressed_form, 33); LDKAcceptChannel msg_var = obj->send_accept_channel.msg; CHECK((((uint64_t)msg_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&msg_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t msg_ref = (uint64_t)msg_var.inner & ~1; return 0 /* LDKMessageSendEvent - SendAcceptChannel */; (void) node_id_arr; (void) msg_ref; } case LDKMessageSendEvent_SendOpenChannel: { int8_tArray node_id_arr = init_arr(33, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(node_id_arr + 4), obj->send_open_channel.node_id.compressed_form, 33); LDKOpenChannel msg_var = obj->send_open_channel.msg; CHECK((((uint64_t)msg_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&msg_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t msg_ref = (uint64_t)msg_var.inner & ~1; return 0 /* LDKMessageSendEvent - SendOpenChannel */; (void) node_id_arr; (void) msg_ref; } case LDKMessageSendEvent_SendFundingCreated: { int8_tArray node_id_arr = init_arr(33, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(node_id_arr + 4), obj->send_funding_created.node_id.compressed_form, 33); LDKFundingCreated msg_var = obj->send_funding_created.msg; CHECK((((uint64_t)msg_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&msg_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t msg_ref = (uint64_t)msg_var.inner & ~1; return 0 /* LDKMessageSendEvent - SendFundingCreated */; (void) node_id_arr; (void) msg_ref; } case LDKMessageSendEvent_SendFundingSigned: { int8_tArray node_id_arr = init_arr(33, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(node_id_arr + 4), obj->send_funding_signed.node_id.compressed_form, 33); LDKFundingSigned msg_var = obj->send_funding_signed.msg; CHECK((((uint64_t)msg_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&msg_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t msg_ref = (uint64_t)msg_var.inner & ~1; return 0 /* LDKMessageSendEvent - SendFundingSigned */; (void) node_id_arr; (void) msg_ref; } case LDKMessageSendEvent_SendFundingLocked: { int8_tArray node_id_arr = init_arr(33, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(node_id_arr + 4), obj->send_funding_locked.node_id.compressed_form, 33); LDKFundingLocked msg_var = obj->send_funding_locked.msg; CHECK((((uint64_t)msg_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&msg_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t msg_ref = (uint64_t)msg_var.inner & ~1; return 0 /* LDKMessageSendEvent - SendFundingLocked */; (void) node_id_arr; (void) msg_ref; } case LDKMessageSendEvent_SendAnnouncementSignatures: { int8_tArray node_id_arr = init_arr(33, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(node_id_arr + 4), obj->send_announcement_signatures.node_id.compressed_form, 33); LDKAnnouncementSignatures msg_var = obj->send_announcement_signatures.msg; CHECK((((uint64_t)msg_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&msg_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t msg_ref = (uint64_t)msg_var.inner & ~1; return 0 /* LDKMessageSendEvent - SendAnnouncementSignatures */; (void) node_id_arr; (void) msg_ref; } case LDKMessageSendEvent_UpdateHTLCs: { int8_tArray node_id_arr = init_arr(33, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(node_id_arr + 4), obj->update_htl_cs.node_id.compressed_form, 33); LDKCommitmentUpdate updates_var = obj->update_htl_cs.updates; CHECK((((uint64_t)updates_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&updates_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t updates_ref = (uint64_t)updates_var.inner & ~1; return 0 /* LDKMessageSendEvent - UpdateHTLCs */; (void) node_id_arr; (void) updates_ref; } case LDKMessageSendEvent_SendRevokeAndACK: { int8_tArray node_id_arr = init_arr(33, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(node_id_arr + 4), obj->send_revoke_and_ack.node_id.compressed_form, 33); LDKRevokeAndACK msg_var = obj->send_revoke_and_ack.msg; CHECK((((uint64_t)msg_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&msg_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t msg_ref = (uint64_t)msg_var.inner & ~1; return 0 /* LDKMessageSendEvent - SendRevokeAndACK */; (void) node_id_arr; (void) msg_ref; } case LDKMessageSendEvent_SendClosingSigned: { int8_tArray node_id_arr = init_arr(33, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(node_id_arr + 4), obj->send_closing_signed.node_id.compressed_form, 33); LDKClosingSigned msg_var = obj->send_closing_signed.msg; CHECK((((uint64_t)msg_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&msg_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t msg_ref = (uint64_t)msg_var.inner & ~1; return 0 /* LDKMessageSendEvent - SendClosingSigned */; (void) node_id_arr; (void) msg_ref; } case LDKMessageSendEvent_SendShutdown: { int8_tArray node_id_arr = init_arr(33, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(node_id_arr + 4), obj->send_shutdown.node_id.compressed_form, 33); LDKShutdown msg_var = obj->send_shutdown.msg; CHECK((((uint64_t)msg_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&msg_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t msg_ref = (uint64_t)msg_var.inner & ~1; return 0 /* LDKMessageSendEvent - SendShutdown */; (void) node_id_arr; (void) msg_ref; } case LDKMessageSendEvent_SendChannelReestablish: { int8_tArray node_id_arr = init_arr(33, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(node_id_arr + 4), obj->send_channel_reestablish.node_id.compressed_form, 33); LDKChannelReestablish msg_var = obj->send_channel_reestablish.msg; CHECK((((uint64_t)msg_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&msg_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t msg_ref = (uint64_t)msg_var.inner & ~1; return 0 /* LDKMessageSendEvent - SendChannelReestablish */; (void) node_id_arr; (void) msg_ref; } case LDKMessageSendEvent_BroadcastChannelAnnouncement: { LDKChannelAnnouncement msg_var = obj->broadcast_channel_announcement.msg; CHECK((((uint64_t)msg_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&msg_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t msg_ref = (uint64_t)msg_var.inner & ~1; LDKChannelUpdate update_msg_var = obj->broadcast_channel_announcement.update_msg; CHECK((((uint64_t)update_msg_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&update_msg_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t update_msg_ref = (uint64_t)update_msg_var.inner & ~1; return 0 /* LDKMessageSendEvent - BroadcastChannelAnnouncement */; (void) msg_ref; (void) update_msg_ref; } case LDKMessageSendEvent_BroadcastNodeAnnouncement: { LDKNodeAnnouncement msg_var = obj->broadcast_node_announcement.msg; CHECK((((uint64_t)msg_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&msg_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t msg_ref = (uint64_t)msg_var.inner & ~1; return 0 /* LDKMessageSendEvent - BroadcastNodeAnnouncement */; (void) msg_ref; } case LDKMessageSendEvent_BroadcastChannelUpdate: { LDKChannelUpdate msg_var = obj->broadcast_channel_update.msg; CHECK((((uint64_t)msg_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&msg_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t msg_ref = (uint64_t)msg_var.inner & ~1; return 0 /* LDKMessageSendEvent - BroadcastChannelUpdate */; (void) msg_ref; } case LDKMessageSendEvent_SendChannelUpdate: { int8_tArray node_id_arr = init_arr(33, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(node_id_arr + 4), obj->send_channel_update.node_id.compressed_form, 33); LDKChannelUpdate msg_var = obj->send_channel_update.msg; CHECK((((uint64_t)msg_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&msg_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t msg_ref = (uint64_t)msg_var.inner & ~1; return 0 /* LDKMessageSendEvent - SendChannelUpdate */; (void) node_id_arr; (void) msg_ref; } case LDKMessageSendEvent_HandleError: { int8_tArray node_id_arr = init_arr(33, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(node_id_arr + 4), obj->handle_error.node_id.compressed_form, 33); uint64_t action_ref = ((uint64_t)&obj->handle_error.action) | 1; return 0 /* LDKMessageSendEvent - HandleError */; (void) node_id_arr; (void) action_ref; } case LDKMessageSendEvent_SendChannelRangeQuery: { int8_tArray node_id_arr = init_arr(33, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(node_id_arr + 4), obj->send_channel_range_query.node_id.compressed_form, 33); LDKQueryChannelRange msg_var = obj->send_channel_range_query.msg; CHECK((((uint64_t)msg_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&msg_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t msg_ref = (uint64_t)msg_var.inner & ~1; return 0 /* LDKMessageSendEvent - SendChannelRangeQuery */; (void) node_id_arr; (void) msg_ref; } case LDKMessageSendEvent_SendShortIdsQuery: { int8_tArray node_id_arr = init_arr(33, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(node_id_arr + 4), obj->send_short_ids_query.node_id.compressed_form, 33); LDKQueryShortChannelIds msg_var = obj->send_short_ids_query.msg; CHECK((((uint64_t)msg_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&msg_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t msg_ref = (uint64_t)msg_var.inner & ~1; return 0 /* LDKMessageSendEvent - SendShortIdsQuery */; (void) node_id_arr; (void) msg_ref; } case LDKMessageSendEvent_SendReplyChannelRange: { int8_tArray node_id_arr = init_arr(33, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(node_id_arr + 4), obj->send_reply_channel_range.node_id.compressed_form, 33); LDKReplyChannelRange msg_var = obj->send_reply_channel_range.msg; CHECK((((uint64_t)msg_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&msg_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t msg_ref = (uint64_t)msg_var.inner & ~1; return 0 /* LDKMessageSendEvent - SendReplyChannelRange */; (void) node_id_arr; (void) msg_ref; } default: abort(); } } uint32_t __attribute__((visibility("default"))) TS_LDKCVec_MessageSendEventZ_new(uint32_tArray elems) { LDKCVec_MessageSendEventZ *ret = MALLOC(sizeof(LDKCVec_MessageSendEventZ), "LDKCVec_MessageSendEventZ"); ret->datalen = *((uint32_t*)elems); if (ret->datalen == 0) { ret->data = NULL; } else { ret->data = MALLOC(sizeof(LDKMessageSendEvent) * ret->datalen, "LDKCVec_MessageSendEventZ Data"); uint32_t *java_elems = (uint32_t*)(elems + 4); for (size_t i = 0; i < ret->datalen; i++) { uint32_t arr_elem = java_elems[i]; LDKMessageSendEvent arr_elem_conv = *(LDKMessageSendEvent*)(((uint64_t)arr_elem) & ~1); arr_elem_conv = MessageSendEvent_clone((LDKMessageSendEvent*)(((uint64_t)arr_elem) & ~1)); ret->data[i] = arr_elem_conv; } } return (uint64_t)ret; } static inline LDKCVec_MessageSendEventZ CVec_MessageSendEventZ_clone(const LDKCVec_MessageSendEventZ *orig) { LDKCVec_MessageSendEventZ ret = { .data = MALLOC(sizeof(LDKMessageSendEvent) * orig->datalen, "LDKCVec_MessageSendEventZ clone bytes"), .datalen = orig->datalen }; for (size_t i = 0; i < ret.datalen; i++) { ret.data[i] = MessageSendEvent_clone(&orig->data[i]); } return ret; } jboolean __attribute__((visibility("default"))) TS_LDKCResult_InitFeaturesDecodeErrorZ_result_ok(uint32_t arg) { return ((LDKCResult_InitFeaturesDecodeErrorZ*)arg)->result_ok; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_InitFeaturesDecodeErrorZ_get_ok(uint32_t arg) { LDKCResult_InitFeaturesDecodeErrorZ *val = (LDKCResult_InitFeaturesDecodeErrorZ*)(arg & ~1); CHECK(val->result_ok); LDKInitFeatures res_var = (*val->contents.result); CHECK((((uint64_t)res_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&res_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t res_ref = (uint64_t)res_var.inner & ~1; return res_ref; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_InitFeaturesDecodeErrorZ_get_err(uint32_t arg) { LDKCResult_InitFeaturesDecodeErrorZ *val = (LDKCResult_InitFeaturesDecodeErrorZ*)(arg & ~1); CHECK(!val->result_ok); LDKDecodeError err_var = (*val->contents.err); CHECK((((uint64_t)err_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&err_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t err_ref = (uint64_t)err_var.inner & ~1; return err_ref; } jboolean __attribute__((visibility("default"))) TS_LDKCResult_NodeFeaturesDecodeErrorZ_result_ok(uint32_t arg) { return ((LDKCResult_NodeFeaturesDecodeErrorZ*)arg)->result_ok; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_NodeFeaturesDecodeErrorZ_get_ok(uint32_t arg) { LDKCResult_NodeFeaturesDecodeErrorZ *val = (LDKCResult_NodeFeaturesDecodeErrorZ*)(arg & ~1); CHECK(val->result_ok); LDKNodeFeatures res_var = (*val->contents.result); CHECK((((uint64_t)res_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&res_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t res_ref = (uint64_t)res_var.inner & ~1; return res_ref; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_NodeFeaturesDecodeErrorZ_get_err(uint32_t arg) { LDKCResult_NodeFeaturesDecodeErrorZ *val = (LDKCResult_NodeFeaturesDecodeErrorZ*)(arg & ~1); CHECK(!val->result_ok); LDKDecodeError err_var = (*val->contents.err); CHECK((((uint64_t)err_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&err_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t err_ref = (uint64_t)err_var.inner & ~1; return err_ref; } jboolean __attribute__((visibility("default"))) TS_LDKCResult_ChannelFeaturesDecodeErrorZ_result_ok(uint32_t arg) { return ((LDKCResult_ChannelFeaturesDecodeErrorZ*)arg)->result_ok; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_ChannelFeaturesDecodeErrorZ_get_ok(uint32_t arg) { LDKCResult_ChannelFeaturesDecodeErrorZ *val = (LDKCResult_ChannelFeaturesDecodeErrorZ*)(arg & ~1); CHECK(val->result_ok); LDKChannelFeatures res_var = (*val->contents.result); CHECK((((uint64_t)res_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&res_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t res_ref = (uint64_t)res_var.inner & ~1; return res_ref; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_ChannelFeaturesDecodeErrorZ_get_err(uint32_t arg) { LDKCResult_ChannelFeaturesDecodeErrorZ *val = (LDKCResult_ChannelFeaturesDecodeErrorZ*)(arg & ~1); CHECK(!val->result_ok); LDKDecodeError err_var = (*val->contents.err); CHECK((((uint64_t)err_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&err_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t err_ref = (uint64_t)err_var.inner & ~1; return err_ref; } jboolean __attribute__((visibility("default"))) TS_LDKCResult_InvoiceFeaturesDecodeErrorZ_result_ok(uint32_t arg) { return ((LDKCResult_InvoiceFeaturesDecodeErrorZ*)arg)->result_ok; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_InvoiceFeaturesDecodeErrorZ_get_ok(uint32_t arg) { LDKCResult_InvoiceFeaturesDecodeErrorZ *val = (LDKCResult_InvoiceFeaturesDecodeErrorZ*)(arg & ~1); CHECK(val->result_ok); LDKInvoiceFeatures res_var = (*val->contents.result); CHECK((((uint64_t)res_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&res_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t res_ref = (uint64_t)res_var.inner & ~1; return res_ref; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_InvoiceFeaturesDecodeErrorZ_get_err(uint32_t arg) { LDKCResult_InvoiceFeaturesDecodeErrorZ *val = (LDKCResult_InvoiceFeaturesDecodeErrorZ*)(arg & ~1); CHECK(!val->result_ok); LDKDecodeError err_var = (*val->contents.err); CHECK((((uint64_t)err_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&err_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t err_ref = (uint64_t)err_var.inner & ~1; return err_ref; } jboolean __attribute__((visibility("default"))) TS_LDKCResult_DelayedPaymentOutputDescriptorDecodeErrorZ_result_ok(uint32_t arg) { return ((LDKCResult_DelayedPaymentOutputDescriptorDecodeErrorZ*)arg)->result_ok; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_DelayedPaymentOutputDescriptorDecodeErrorZ_get_ok(uint32_t arg) { LDKCResult_DelayedPaymentOutputDescriptorDecodeErrorZ *val = (LDKCResult_DelayedPaymentOutputDescriptorDecodeErrorZ*)(arg & ~1); CHECK(val->result_ok); LDKDelayedPaymentOutputDescriptor res_var = (*val->contents.result); CHECK((((uint64_t)res_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&res_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t res_ref = (uint64_t)res_var.inner & ~1; return res_ref; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_DelayedPaymentOutputDescriptorDecodeErrorZ_get_err(uint32_t arg) { LDKCResult_DelayedPaymentOutputDescriptorDecodeErrorZ *val = (LDKCResult_DelayedPaymentOutputDescriptorDecodeErrorZ*)(arg & ~1); CHECK(!val->result_ok); LDKDecodeError err_var = (*val->contents.err); CHECK((((uint64_t)err_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&err_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t err_ref = (uint64_t)err_var.inner & ~1; return err_ref; } jboolean __attribute__((visibility("default"))) TS_LDKCResult_StaticPaymentOutputDescriptorDecodeErrorZ_result_ok(uint32_t arg) { return ((LDKCResult_StaticPaymentOutputDescriptorDecodeErrorZ*)arg)->result_ok; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_StaticPaymentOutputDescriptorDecodeErrorZ_get_ok(uint32_t arg) { LDKCResult_StaticPaymentOutputDescriptorDecodeErrorZ *val = (LDKCResult_StaticPaymentOutputDescriptorDecodeErrorZ*)(arg & ~1); CHECK(val->result_ok); LDKStaticPaymentOutputDescriptor res_var = (*val->contents.result); CHECK((((uint64_t)res_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&res_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t res_ref = (uint64_t)res_var.inner & ~1; return res_ref; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_StaticPaymentOutputDescriptorDecodeErrorZ_get_err(uint32_t arg) { LDKCResult_StaticPaymentOutputDescriptorDecodeErrorZ *val = (LDKCResult_StaticPaymentOutputDescriptorDecodeErrorZ*)(arg & ~1); CHECK(!val->result_ok); LDKDecodeError err_var = (*val->contents.err); CHECK((((uint64_t)err_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&err_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t err_ref = (uint64_t)err_var.inner & ~1; return err_ref; } jboolean __attribute__((visibility("default"))) TS_LDKCResult_SpendableOutputDescriptorDecodeErrorZ_result_ok(uint32_t arg) { return ((LDKCResult_SpendableOutputDescriptorDecodeErrorZ*)arg)->result_ok; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_SpendableOutputDescriptorDecodeErrorZ_get_ok(uint32_t arg) { LDKCResult_SpendableOutputDescriptorDecodeErrorZ *val = (LDKCResult_SpendableOutputDescriptorDecodeErrorZ*)(arg & ~1); CHECK(val->result_ok); uint64_t res_ref = ((uint64_t)&(*val->contents.result)) | 1; return res_ref; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_SpendableOutputDescriptorDecodeErrorZ_get_err(uint32_t arg) { LDKCResult_SpendableOutputDescriptorDecodeErrorZ *val = (LDKCResult_SpendableOutputDescriptorDecodeErrorZ*)(arg & ~1); CHECK(!val->result_ok); LDKDecodeError err_var = (*val->contents.err); CHECK((((uint64_t)err_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&err_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t err_ref = (uint64_t)err_var.inner & ~1; return err_ref; } jboolean __attribute__((visibility("default"))) TS_LDKCResult_NoneNoneZ_result_ok(uint32_t arg) { return ((LDKCResult_NoneNoneZ*)arg)->result_ok; } void __attribute__((visibility("default"))) TS_LDKCResult_NoneNoneZ_get_ok(uint32_t arg) { LDKCResult_NoneNoneZ *val = (LDKCResult_NoneNoneZ*)(arg & ~1); CHECK(val->result_ok); return *val->contents.result; } void __attribute__((visibility("default"))) TS_LDKCResult_NoneNoneZ_get_err(uint32_t arg) { LDKCResult_NoneNoneZ *val = (LDKCResult_NoneNoneZ*)(arg & ~1); CHECK(!val->result_ok); return *val->contents.err; } uint32_t __attribute__((visibility("default"))) TS_LDKC2Tuple_SignatureCVec_SignatureZZ_new(int8_tArray a, ptrArray b) { LDKC2Tuple_SignatureCVec_SignatureZZ* ret = MALLOC(sizeof(LDKC2Tuple_SignatureCVec_SignatureZZ), "LDKC2Tuple_SignatureCVec_SignatureZZ"); LDKSignature a_ref; CHECK(*((uint32_t*)a) == 64); memcpy(a_ref.compact_form, (uint8_t*)(a + 4), 64); ret->a = a_ref; LDKCVec_SignatureZ b_constr; b_constr.datalen = *((uint32_t*)b); if (b_constr.datalen > 0) b_constr.data = MALLOC(b_constr.datalen * sizeof(LDKSignature), "LDKCVec_SignatureZ Elements"); else b_constr.data = NULL; int8_tArray* b_vals = (int8_tArray*)(b + 4); for (size_t m = 0; m < b_constr.datalen; m++) { int8_tArray b_conv_12 = b_vals[m]; LDKSignature b_conv_12_ref; CHECK(*((uint32_t*)b_conv_12) == 64); memcpy(b_conv_12_ref.compact_form, (uint8_t*)(b_conv_12 + 4), 64); b_constr.data[m] = b_conv_12_ref; } ret->b = b_constr; return (uint64_t)ret; } int8_tArray __attribute__((visibility("default"))) TS_LDKC2Tuple_SignatureCVec_SignatureZZ_get_a(uint32_t ptr) { LDKC2Tuple_SignatureCVec_SignatureZZ *tuple = (LDKC2Tuple_SignatureCVec_SignatureZZ*)(ptr & ~1); int8_tArray a_arr = init_arr(64, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(a_arr + 4), tuple->a.compact_form, 64); return a_arr; } ptrArray __attribute__((visibility("default"))) TS_LDKC2Tuple_SignatureCVec_SignatureZZ_get_b(uint32_t ptr) { LDKC2Tuple_SignatureCVec_SignatureZZ *tuple = (LDKC2Tuple_SignatureCVec_SignatureZZ*)(ptr & ~1); LDKCVec_SignatureZ b_var = tuple->b; ptrArray b_arr = init_arr(b_var.datalen, sizeof(uint32_t), "Native ptrArray Bytes"); int8_tArray *b_arr_ptr = (int8_tArray*)(b_arr + 4); for (size_t m = 0; m < b_var.datalen; m++) { int8_tArray b_conv_12_arr = init_arr(64, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(b_conv_12_arr + 4), b_var.data[m].compact_form, 64); b_arr_ptr[m] = b_conv_12_arr; } return b_arr; } jboolean __attribute__((visibility("default"))) TS_LDKCResult_C2Tuple_SignatureCVec_SignatureZZNoneZ_result_ok(uint32_t arg) { return ((LDKCResult_C2Tuple_SignatureCVec_SignatureZZNoneZ*)arg)->result_ok; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_C2Tuple_SignatureCVec_SignatureZZNoneZ_get_ok(uint32_t arg) { LDKCResult_C2Tuple_SignatureCVec_SignatureZZNoneZ *val = (LDKCResult_C2Tuple_SignatureCVec_SignatureZZNoneZ*)(arg & ~1); CHECK(val->result_ok); uint64_t res_ref = (uint64_t)(&(*val->contents.result)) | 1; return res_ref; } void __attribute__((visibility("default"))) TS_LDKCResult_C2Tuple_SignatureCVec_SignatureZZNoneZ_get_err(uint32_t arg) { LDKCResult_C2Tuple_SignatureCVec_SignatureZZNoneZ *val = (LDKCResult_C2Tuple_SignatureCVec_SignatureZZNoneZ*)(arg & ~1); CHECK(!val->result_ok); return *val->contents.err; } jboolean __attribute__((visibility("default"))) TS_LDKCResult_SignatureNoneZ_result_ok(uint32_t arg) { return ((LDKCResult_SignatureNoneZ*)arg)->result_ok; } int8_tArray __attribute__((visibility("default"))) TS_LDKCResult_SignatureNoneZ_get_ok(uint32_t arg) { LDKCResult_SignatureNoneZ *val = (LDKCResult_SignatureNoneZ*)(arg & ~1); CHECK(val->result_ok); int8_tArray res_arr = init_arr(64, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(res_arr + 4), (*val->contents.result).compact_form, 64); return res_arr; } void __attribute__((visibility("default"))) TS_LDKCResult_SignatureNoneZ_get_err(uint32_t arg) { LDKCResult_SignatureNoneZ *val = (LDKCResult_SignatureNoneZ*)(arg & ~1); CHECK(!val->result_ok); return *val->contents.err; } typedef struct LDKBaseSign_JCalls { atomic_size_t refcnt; uint32_t get_per_commitment_point_meth; uint32_t release_commitment_secret_meth; uint32_t validate_holder_commitment_meth; uint32_t channel_keys_id_meth; uint32_t sign_counterparty_commitment_meth; uint32_t validate_counterparty_revocation_meth; uint32_t sign_holder_commitment_and_htlcs_meth; uint32_t sign_justice_revoked_output_meth; uint32_t sign_justice_revoked_htlc_meth; uint32_t sign_counterparty_htlc_transaction_meth; uint32_t sign_closing_transaction_meth; uint32_t sign_channel_announcement_meth; uint32_t ready_channel_meth; } LDKBaseSign_JCalls; static void LDKBaseSign_JCalls_free(void* this_arg) { LDKBaseSign_JCalls *j_calls = (LDKBaseSign_JCalls*) this_arg; if (atomic_fetch_sub_explicit(&j_calls->refcnt, 1, memory_order_acquire) == 1) { js_free(j_calls->get_per_commitment_point_meth); js_free(j_calls->release_commitment_secret_meth); js_free(j_calls->validate_holder_commitment_meth); js_free(j_calls->channel_keys_id_meth); js_free(j_calls->sign_counterparty_commitment_meth); js_free(j_calls->validate_counterparty_revocation_meth); js_free(j_calls->sign_holder_commitment_and_htlcs_meth); js_free(j_calls->sign_justice_revoked_output_meth); js_free(j_calls->sign_justice_revoked_htlc_meth); js_free(j_calls->sign_counterparty_htlc_transaction_meth); js_free(j_calls->sign_closing_transaction_meth); js_free(j_calls->sign_channel_announcement_meth); js_free(j_calls->ready_channel_meth); FREE(j_calls); } } LDKPublicKey get_per_commitment_point_LDKBaseSign_jcall(const void* this_arg, uint64_t idx) { LDKBaseSign_JCalls *j_calls = (LDKBaseSign_JCalls*) this_arg; int8_tArray ret = js_invoke_function_1(j_calls->get_per_commitment_point_meth, idx); LDKPublicKey ret_ref; CHECK(*((uint32_t*)ret) == 33); memcpy(ret_ref.compressed_form, (uint8_t*)(ret + 4), 33); return ret_ref; } LDKThirtyTwoBytes release_commitment_secret_LDKBaseSign_jcall(const void* this_arg, uint64_t idx) { LDKBaseSign_JCalls *j_calls = (LDKBaseSign_JCalls*) this_arg; int8_tArray ret = js_invoke_function_1(j_calls->release_commitment_secret_meth, idx); LDKThirtyTwoBytes ret_ref; CHECK(*((uint32_t*)ret) == 32); memcpy(ret_ref.data, (uint8_t*)(ret + 4), 32); return ret_ref; } LDKCResult_NoneNoneZ validate_holder_commitment_LDKBaseSign_jcall(const void* this_arg, const LDKHolderCommitmentTransaction * holder_tx) { LDKBaseSign_JCalls *j_calls = (LDKBaseSign_JCalls*) this_arg; LDKHolderCommitmentTransaction holder_tx_var = *holder_tx; holder_tx_var = HolderCommitmentTransaction_clone(holder_tx); CHECK((((uint64_t)holder_tx_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&holder_tx_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t holder_tx_ref = (uint64_t)holder_tx_var.inner; if (holder_tx_var.is_owned) { holder_tx_ref |= 1; } uint32_t ret = js_invoke_function_1(j_calls->validate_holder_commitment_meth, holder_tx_ref); LDKCResult_NoneNoneZ ret_conv = *(LDKCResult_NoneNoneZ*)(((uint64_t)ret) & ~1); ret_conv = CResult_NoneNoneZ_clone((LDKCResult_NoneNoneZ*)(((uint64_t)ret) & ~1)); return ret_conv; } LDKThirtyTwoBytes channel_keys_id_LDKBaseSign_jcall(const void* this_arg) { LDKBaseSign_JCalls *j_calls = (LDKBaseSign_JCalls*) this_arg; int8_tArray ret = js_invoke_function_0(j_calls->channel_keys_id_meth); LDKThirtyTwoBytes ret_ref; CHECK(*((uint32_t*)ret) == 32); memcpy(ret_ref.data, (uint8_t*)(ret + 4), 32); return ret_ref; } LDKCResult_C2Tuple_SignatureCVec_SignatureZZNoneZ sign_counterparty_commitment_LDKBaseSign_jcall(const void* this_arg, const LDKCommitmentTransaction * commitment_tx) { LDKBaseSign_JCalls *j_calls = (LDKBaseSign_JCalls*) this_arg; LDKCommitmentTransaction commitment_tx_var = *commitment_tx; commitment_tx_var = CommitmentTransaction_clone(commitment_tx); CHECK((((uint64_t)commitment_tx_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&commitment_tx_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t commitment_tx_ref = (uint64_t)commitment_tx_var.inner; if (commitment_tx_var.is_owned) { commitment_tx_ref |= 1; } uint32_t ret = js_invoke_function_1(j_calls->sign_counterparty_commitment_meth, commitment_tx_ref); LDKCResult_C2Tuple_SignatureCVec_SignatureZZNoneZ ret_conv = *(LDKCResult_C2Tuple_SignatureCVec_SignatureZZNoneZ*)(((uint64_t)ret) & ~1); ret_conv = CResult_C2Tuple_SignatureCVec_SignatureZZNoneZ_clone((LDKCResult_C2Tuple_SignatureCVec_SignatureZZNoneZ*)(((uint64_t)ret) & ~1)); return ret_conv; } LDKCResult_NoneNoneZ validate_counterparty_revocation_LDKBaseSign_jcall(const void* this_arg, uint64_t idx, const uint8_t (* secret)[32]) { LDKBaseSign_JCalls *j_calls = (LDKBaseSign_JCalls*) this_arg; int8_tArray secret_arr = init_arr(32, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(secret_arr + 4), *secret, 32); uint32_t ret = js_invoke_function_2(j_calls->validate_counterparty_revocation_meth, idx, secret_arr); LDKCResult_NoneNoneZ ret_conv = *(LDKCResult_NoneNoneZ*)(((uint64_t)ret) & ~1); ret_conv = CResult_NoneNoneZ_clone((LDKCResult_NoneNoneZ*)(((uint64_t)ret) & ~1)); return ret_conv; } LDKCResult_C2Tuple_SignatureCVec_SignatureZZNoneZ sign_holder_commitment_and_htlcs_LDKBaseSign_jcall(const void* this_arg, const LDKHolderCommitmentTransaction * commitment_tx) { LDKBaseSign_JCalls *j_calls = (LDKBaseSign_JCalls*) this_arg; LDKHolderCommitmentTransaction commitment_tx_var = *commitment_tx; commitment_tx_var = HolderCommitmentTransaction_clone(commitment_tx); CHECK((((uint64_t)commitment_tx_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&commitment_tx_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t commitment_tx_ref = (uint64_t)commitment_tx_var.inner; if (commitment_tx_var.is_owned) { commitment_tx_ref |= 1; } uint32_t ret = js_invoke_function_1(j_calls->sign_holder_commitment_and_htlcs_meth, commitment_tx_ref); LDKCResult_C2Tuple_SignatureCVec_SignatureZZNoneZ ret_conv = *(LDKCResult_C2Tuple_SignatureCVec_SignatureZZNoneZ*)(((uint64_t)ret) & ~1); ret_conv = CResult_C2Tuple_SignatureCVec_SignatureZZNoneZ_clone((LDKCResult_C2Tuple_SignatureCVec_SignatureZZNoneZ*)(((uint64_t)ret) & ~1)); return ret_conv; } LDKCResult_SignatureNoneZ sign_justice_revoked_output_LDKBaseSign_jcall(const void* this_arg, LDKTransaction justice_tx, uintptr_t input, uint64_t amount, const uint8_t (* per_commitment_key)[32]) { LDKBaseSign_JCalls *j_calls = (LDKBaseSign_JCalls*) this_arg; LDKTransaction justice_tx_var = justice_tx; int8_tArray justice_tx_arr = init_arr(justice_tx_var.datalen, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(justice_tx_arr + 4), justice_tx_var.data, justice_tx_var.datalen); Transaction_free(justice_tx_var); int8_tArray per_commitment_key_arr = init_arr(32, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(per_commitment_key_arr + 4), *per_commitment_key, 32); uint32_t ret = js_invoke_function_4(j_calls->sign_justice_revoked_output_meth, justice_tx_arr, input, amount, per_commitment_key_arr); LDKCResult_SignatureNoneZ ret_conv = *(LDKCResult_SignatureNoneZ*)(((uint64_t)ret) & ~1); ret_conv = CResult_SignatureNoneZ_clone((LDKCResult_SignatureNoneZ*)(((uint64_t)ret) & ~1)); return ret_conv; } LDKCResult_SignatureNoneZ sign_justice_revoked_htlc_LDKBaseSign_jcall(const void* this_arg, LDKTransaction justice_tx, uintptr_t input, uint64_t amount, const uint8_t (* per_commitment_key)[32], const LDKHTLCOutputInCommitment * htlc) { LDKBaseSign_JCalls *j_calls = (LDKBaseSign_JCalls*) this_arg; LDKTransaction justice_tx_var = justice_tx; int8_tArray justice_tx_arr = init_arr(justice_tx_var.datalen, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(justice_tx_arr + 4), justice_tx_var.data, justice_tx_var.datalen); Transaction_free(justice_tx_var); int8_tArray per_commitment_key_arr = init_arr(32, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(per_commitment_key_arr + 4), *per_commitment_key, 32); LDKHTLCOutputInCommitment htlc_var = *htlc; htlc_var = HTLCOutputInCommitment_clone(htlc); CHECK((((uint64_t)htlc_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&htlc_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t htlc_ref = (uint64_t)htlc_var.inner; if (htlc_var.is_owned) { htlc_ref |= 1; } uint32_t ret = js_invoke_function_5(j_calls->sign_justice_revoked_htlc_meth, justice_tx_arr, input, amount, per_commitment_key_arr, htlc_ref); LDKCResult_SignatureNoneZ ret_conv = *(LDKCResult_SignatureNoneZ*)(((uint64_t)ret) & ~1); ret_conv = CResult_SignatureNoneZ_clone((LDKCResult_SignatureNoneZ*)(((uint64_t)ret) & ~1)); return ret_conv; } LDKCResult_SignatureNoneZ sign_counterparty_htlc_transaction_LDKBaseSign_jcall(const void* this_arg, LDKTransaction htlc_tx, uintptr_t input, uint64_t amount, LDKPublicKey per_commitment_point, const LDKHTLCOutputInCommitment * htlc) { LDKBaseSign_JCalls *j_calls = (LDKBaseSign_JCalls*) this_arg; LDKTransaction htlc_tx_var = htlc_tx; int8_tArray htlc_tx_arr = init_arr(htlc_tx_var.datalen, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(htlc_tx_arr + 4), htlc_tx_var.data, htlc_tx_var.datalen); Transaction_free(htlc_tx_var); int8_tArray per_commitment_point_arr = init_arr(33, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(per_commitment_point_arr + 4), per_commitment_point.compressed_form, 33); LDKHTLCOutputInCommitment htlc_var = *htlc; htlc_var = HTLCOutputInCommitment_clone(htlc); CHECK((((uint64_t)htlc_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&htlc_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t htlc_ref = (uint64_t)htlc_var.inner; if (htlc_var.is_owned) { htlc_ref |= 1; } uint32_t ret = js_invoke_function_5(j_calls->sign_counterparty_htlc_transaction_meth, htlc_tx_arr, input, amount, per_commitment_point_arr, htlc_ref); LDKCResult_SignatureNoneZ ret_conv = *(LDKCResult_SignatureNoneZ*)(((uint64_t)ret) & ~1); ret_conv = CResult_SignatureNoneZ_clone((LDKCResult_SignatureNoneZ*)(((uint64_t)ret) & ~1)); return ret_conv; } LDKCResult_SignatureNoneZ sign_closing_transaction_LDKBaseSign_jcall(const void* this_arg, const LDKClosingTransaction * closing_tx) { LDKBaseSign_JCalls *j_calls = (LDKBaseSign_JCalls*) this_arg; LDKClosingTransaction closing_tx_var = *closing_tx; // Warning: we may need a move here but no clone is available for LDKClosingTransaction CHECK((((uint64_t)closing_tx_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&closing_tx_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t closing_tx_ref = (uint64_t)closing_tx_var.inner; if (closing_tx_var.is_owned) { closing_tx_ref |= 1; } uint32_t ret = js_invoke_function_1(j_calls->sign_closing_transaction_meth, closing_tx_ref); LDKCResult_SignatureNoneZ ret_conv = *(LDKCResult_SignatureNoneZ*)(((uint64_t)ret) & ~1); ret_conv = CResult_SignatureNoneZ_clone((LDKCResult_SignatureNoneZ*)(((uint64_t)ret) & ~1)); return ret_conv; } LDKCResult_SignatureNoneZ sign_channel_announcement_LDKBaseSign_jcall(const void* this_arg, const LDKUnsignedChannelAnnouncement * msg) { LDKBaseSign_JCalls *j_calls = (LDKBaseSign_JCalls*) this_arg; LDKUnsignedChannelAnnouncement msg_var = *msg; msg_var = UnsignedChannelAnnouncement_clone(msg); CHECK((((uint64_t)msg_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&msg_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t msg_ref = (uint64_t)msg_var.inner; if (msg_var.is_owned) { msg_ref |= 1; } uint32_t ret = js_invoke_function_1(j_calls->sign_channel_announcement_meth, msg_ref); LDKCResult_SignatureNoneZ ret_conv = *(LDKCResult_SignatureNoneZ*)(((uint64_t)ret) & ~1); ret_conv = CResult_SignatureNoneZ_clone((LDKCResult_SignatureNoneZ*)(((uint64_t)ret) & ~1)); return ret_conv; } void ready_channel_LDKBaseSign_jcall(void* this_arg, const LDKChannelTransactionParameters * channel_parameters) { LDKBaseSign_JCalls *j_calls = (LDKBaseSign_JCalls*) this_arg; LDKChannelTransactionParameters channel_parameters_var = *channel_parameters; channel_parameters_var = ChannelTransactionParameters_clone(channel_parameters); CHECK((((uint64_t)channel_parameters_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&channel_parameters_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t channel_parameters_ref = (uint64_t)channel_parameters_var.inner; if (channel_parameters_var.is_owned) { channel_parameters_ref |= 1; } js_invoke_function_1(j_calls->ready_channel_meth, channel_parameters_ref); } static void LDKBaseSign_JCalls_cloned(LDKBaseSign* new_obj) { LDKBaseSign_JCalls *j_calls = (LDKBaseSign_JCalls*) new_obj->this_arg; atomic_fetch_add_explicit(&j_calls->refcnt, 1, memory_order_release); } static inline LDKBaseSign LDKBaseSign_init (/*TODO: JS Object Reference */void* o, uint32_t pubkeys) { LDKBaseSign_JCalls *calls = MALLOC(sizeof(LDKBaseSign_JCalls), "LDKBaseSign_JCalls"); atomic_init(&calls->refcnt, 1); //TODO: Assign calls->o from o LDKChannelPublicKeys pubkeys_conv; pubkeys_conv.inner = (void*)(pubkeys & (~1)); pubkeys_conv.is_owned = (pubkeys & 1) || (pubkeys == 0); pubkeys_conv = ChannelPublicKeys_clone(&pubkeys_conv); LDKBaseSign ret = { .this_arg = (void*) calls, .get_per_commitment_point = get_per_commitment_point_LDKBaseSign_jcall, .release_commitment_secret = release_commitment_secret_LDKBaseSign_jcall, .validate_holder_commitment = validate_holder_commitment_LDKBaseSign_jcall, .channel_keys_id = channel_keys_id_LDKBaseSign_jcall, .sign_counterparty_commitment = sign_counterparty_commitment_LDKBaseSign_jcall, .validate_counterparty_revocation = validate_counterparty_revocation_LDKBaseSign_jcall, .sign_holder_commitment_and_htlcs = sign_holder_commitment_and_htlcs_LDKBaseSign_jcall, .sign_justice_revoked_output = sign_justice_revoked_output_LDKBaseSign_jcall, .sign_justice_revoked_htlc = sign_justice_revoked_htlc_LDKBaseSign_jcall, .sign_counterparty_htlc_transaction = sign_counterparty_htlc_transaction_LDKBaseSign_jcall, .sign_closing_transaction = sign_closing_transaction_LDKBaseSign_jcall, .sign_channel_announcement = sign_channel_announcement_LDKBaseSign_jcall, .ready_channel = ready_channel_LDKBaseSign_jcall, .free = LDKBaseSign_JCalls_free, .pubkeys = pubkeys_conv, .set_pubkeys = NULL, }; return ret; } long __attribute__((visibility("default"))) TS_LDKBaseSign_new(/*TODO: JS Object Reference */void* o, uint32_t pubkeys) { LDKBaseSign *res_ptr = MALLOC(sizeof(LDKBaseSign), "LDKBaseSign"); *res_ptr = LDKBaseSign_init(o, pubkeys); return (long)res_ptr; } int8_tArray __attribute__((visibility("default"))) TS_BaseSign_get_per_commitment_point(uint32_t this_arg, int64_t idx) { LDKBaseSign* this_arg_conv = (LDKBaseSign*)(((uint64_t)this_arg) & ~1); int8_tArray ret_arr = init_arr(33, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), (this_arg_conv->get_per_commitment_point)(this_arg_conv->this_arg, idx).compressed_form, 33); return ret_arr; } int8_tArray __attribute__((visibility("default"))) TS_BaseSign_release_commitment_secret(uint32_t this_arg, int64_t idx) { LDKBaseSign* this_arg_conv = (LDKBaseSign*)(((uint64_t)this_arg) & ~1); int8_tArray ret_arr = init_arr(32, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), (this_arg_conv->release_commitment_secret)(this_arg_conv->this_arg, idx).data, 32); return ret_arr; } uint32_t __attribute__((visibility("default"))) TS_BaseSign_validate_holder_commitment(uint32_t this_arg, uint32_t holder_tx) { LDKBaseSign* this_arg_conv = (LDKBaseSign*)(((uint64_t)this_arg) & ~1); LDKHolderCommitmentTransaction holder_tx_conv; holder_tx_conv.inner = (void*)(holder_tx & (~1)); holder_tx_conv.is_owned = false; LDKCResult_NoneNoneZ* ret_conv = MALLOC(sizeof(LDKCResult_NoneNoneZ), "LDKCResult_NoneNoneZ"); *ret_conv = (this_arg_conv->validate_holder_commitment)(this_arg_conv->this_arg, &holder_tx_conv); return (uint64_t)ret_conv; } int8_tArray __attribute__((visibility("default"))) TS_BaseSign_channel_keys_id(uint32_t this_arg) { LDKBaseSign* this_arg_conv = (LDKBaseSign*)(((uint64_t)this_arg) & ~1); int8_tArray ret_arr = init_arr(32, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), (this_arg_conv->channel_keys_id)(this_arg_conv->this_arg).data, 32); return ret_arr; } uint32_t __attribute__((visibility("default"))) TS_BaseSign_sign_counterparty_commitment(uint32_t this_arg, uint32_t commitment_tx) { LDKBaseSign* this_arg_conv = (LDKBaseSign*)(((uint64_t)this_arg) & ~1); LDKCommitmentTransaction commitment_tx_conv; commitment_tx_conv.inner = (void*)(commitment_tx & (~1)); commitment_tx_conv.is_owned = false; LDKCResult_C2Tuple_SignatureCVec_SignatureZZNoneZ* ret_conv = MALLOC(sizeof(LDKCResult_C2Tuple_SignatureCVec_SignatureZZNoneZ), "LDKCResult_C2Tuple_SignatureCVec_SignatureZZNoneZ"); *ret_conv = (this_arg_conv->sign_counterparty_commitment)(this_arg_conv->this_arg, &commitment_tx_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_BaseSign_validate_counterparty_revocation(uint32_t this_arg, int64_t idx, int8_tArray secret) { LDKBaseSign* this_arg_conv = (LDKBaseSign*)(((uint64_t)this_arg) & ~1); unsigned char secret_arr[32]; CHECK(*((uint32_t*)secret) == 32); memcpy(secret_arr, (uint8_t*)(secret + 4), 32); unsigned char (*secret_ref)[32] = &secret_arr; LDKCResult_NoneNoneZ* ret_conv = MALLOC(sizeof(LDKCResult_NoneNoneZ), "LDKCResult_NoneNoneZ"); *ret_conv = (this_arg_conv->validate_counterparty_revocation)(this_arg_conv->this_arg, idx, secret_ref); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_BaseSign_sign_holder_commitment_and_htlcs(uint32_t this_arg, uint32_t commitment_tx) { LDKBaseSign* this_arg_conv = (LDKBaseSign*)(((uint64_t)this_arg) & ~1); LDKHolderCommitmentTransaction commitment_tx_conv; commitment_tx_conv.inner = (void*)(commitment_tx & (~1)); commitment_tx_conv.is_owned = false; LDKCResult_C2Tuple_SignatureCVec_SignatureZZNoneZ* ret_conv = MALLOC(sizeof(LDKCResult_C2Tuple_SignatureCVec_SignatureZZNoneZ), "LDKCResult_C2Tuple_SignatureCVec_SignatureZZNoneZ"); *ret_conv = (this_arg_conv->sign_holder_commitment_and_htlcs)(this_arg_conv->this_arg, &commitment_tx_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_BaseSign_sign_justice_revoked_output(uint32_t this_arg, int8_tArray justice_tx, int64_t input, int64_t amount, int8_tArray per_commitment_key) { LDKBaseSign* this_arg_conv = (LDKBaseSign*)(((uint64_t)this_arg) & ~1); LDKTransaction justice_tx_ref; justice_tx_ref.datalen = *((uint32_t*)justice_tx); justice_tx_ref.data = MALLOC(justice_tx_ref.datalen, "LDKTransaction Bytes"); memcpy(justice_tx_ref.data, (uint8_t*)(justice_tx + 4), justice_tx_ref.datalen); justice_tx_ref.data_is_owned = true; unsigned char per_commitment_key_arr[32]; CHECK(*((uint32_t*)per_commitment_key) == 32); memcpy(per_commitment_key_arr, (uint8_t*)(per_commitment_key + 4), 32); unsigned char (*per_commitment_key_ref)[32] = &per_commitment_key_arr; LDKCResult_SignatureNoneZ* ret_conv = MALLOC(sizeof(LDKCResult_SignatureNoneZ), "LDKCResult_SignatureNoneZ"); *ret_conv = (this_arg_conv->sign_justice_revoked_output)(this_arg_conv->this_arg, justice_tx_ref, input, amount, per_commitment_key_ref); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_BaseSign_sign_justice_revoked_htlc(uint32_t this_arg, int8_tArray justice_tx, int64_t input, int64_t amount, int8_tArray per_commitment_key, uint32_t htlc) { LDKBaseSign* this_arg_conv = (LDKBaseSign*)(((uint64_t)this_arg) & ~1); LDKTransaction justice_tx_ref; justice_tx_ref.datalen = *((uint32_t*)justice_tx); justice_tx_ref.data = MALLOC(justice_tx_ref.datalen, "LDKTransaction Bytes"); memcpy(justice_tx_ref.data, (uint8_t*)(justice_tx + 4), justice_tx_ref.datalen); justice_tx_ref.data_is_owned = true; unsigned char per_commitment_key_arr[32]; CHECK(*((uint32_t*)per_commitment_key) == 32); memcpy(per_commitment_key_arr, (uint8_t*)(per_commitment_key + 4), 32); unsigned char (*per_commitment_key_ref)[32] = &per_commitment_key_arr; LDKHTLCOutputInCommitment htlc_conv; htlc_conv.inner = (void*)(htlc & (~1)); htlc_conv.is_owned = false; LDKCResult_SignatureNoneZ* ret_conv = MALLOC(sizeof(LDKCResult_SignatureNoneZ), "LDKCResult_SignatureNoneZ"); *ret_conv = (this_arg_conv->sign_justice_revoked_htlc)(this_arg_conv->this_arg, justice_tx_ref, input, amount, per_commitment_key_ref, &htlc_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_BaseSign_sign_counterparty_htlc_transaction(uint32_t this_arg, int8_tArray htlc_tx, int64_t input, int64_t amount, int8_tArray per_commitment_point, uint32_t htlc) { LDKBaseSign* this_arg_conv = (LDKBaseSign*)(((uint64_t)this_arg) & ~1); LDKTransaction htlc_tx_ref; htlc_tx_ref.datalen = *((uint32_t*)htlc_tx); htlc_tx_ref.data = MALLOC(htlc_tx_ref.datalen, "LDKTransaction Bytes"); memcpy(htlc_tx_ref.data, (uint8_t*)(htlc_tx + 4), htlc_tx_ref.datalen); htlc_tx_ref.data_is_owned = true; LDKPublicKey per_commitment_point_ref; CHECK(*((uint32_t*)per_commitment_point) == 33); memcpy(per_commitment_point_ref.compressed_form, (uint8_t*)(per_commitment_point + 4), 33); LDKHTLCOutputInCommitment htlc_conv; htlc_conv.inner = (void*)(htlc & (~1)); htlc_conv.is_owned = false; LDKCResult_SignatureNoneZ* ret_conv = MALLOC(sizeof(LDKCResult_SignatureNoneZ), "LDKCResult_SignatureNoneZ"); *ret_conv = (this_arg_conv->sign_counterparty_htlc_transaction)(this_arg_conv->this_arg, htlc_tx_ref, input, amount, per_commitment_point_ref, &htlc_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_BaseSign_sign_closing_transaction(uint32_t this_arg, uint32_t closing_tx) { LDKBaseSign* this_arg_conv = (LDKBaseSign*)(((uint64_t)this_arg) & ~1); LDKClosingTransaction closing_tx_conv; closing_tx_conv.inner = (void*)(closing_tx & (~1)); closing_tx_conv.is_owned = false; LDKCResult_SignatureNoneZ* ret_conv = MALLOC(sizeof(LDKCResult_SignatureNoneZ), "LDKCResult_SignatureNoneZ"); *ret_conv = (this_arg_conv->sign_closing_transaction)(this_arg_conv->this_arg, &closing_tx_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_BaseSign_sign_channel_announcement(uint32_t this_arg, uint32_t msg) { LDKBaseSign* this_arg_conv = (LDKBaseSign*)(((uint64_t)this_arg) & ~1); LDKUnsignedChannelAnnouncement msg_conv; msg_conv.inner = (void*)(msg & (~1)); msg_conv.is_owned = false; LDKCResult_SignatureNoneZ* ret_conv = MALLOC(sizeof(LDKCResult_SignatureNoneZ), "LDKCResult_SignatureNoneZ"); *ret_conv = (this_arg_conv->sign_channel_announcement)(this_arg_conv->this_arg, &msg_conv); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_BaseSign_ready_channel(uint32_t this_arg, uint32_t channel_parameters) { LDKBaseSign* this_arg_conv = (LDKBaseSign*)(((uint64_t)this_arg) & ~1); LDKChannelTransactionParameters channel_parameters_conv; channel_parameters_conv.inner = (void*)(channel_parameters & (~1)); channel_parameters_conv.is_owned = false; (this_arg_conv->ready_channel)(this_arg_conv->this_arg, &channel_parameters_conv); } LDKChannelPublicKeys LDKBaseSign_set_get_pubkeys(LDKBaseSign* this_arg) { if (this_arg->set_pubkeys != NULL) this_arg->set_pubkeys(this_arg); return this_arg->pubkeys; } uint32_t __attribute__((visibility("default"))) TS_BaseSign_get_pubkeys(uint32_t this_arg) { LDKBaseSign* this_arg_conv = (LDKBaseSign*)(((uint64_t)this_arg) & ~1); LDKChannelPublicKeys ret_var = LDKBaseSign_set_get_pubkeys(this_arg_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } typedef struct LDKSign_JCalls { atomic_size_t refcnt; LDKBaseSign_JCalls* BaseSign; uint32_t write_meth; } LDKSign_JCalls; static void LDKSign_JCalls_free(void* this_arg) { LDKSign_JCalls *j_calls = (LDKSign_JCalls*) this_arg; if (atomic_fetch_sub_explicit(&j_calls->refcnt, 1, memory_order_acquire) == 1) { js_free(j_calls->write_meth); FREE(j_calls); } } LDKCVec_u8Z write_LDKSign_jcall(const void* this_arg) { LDKSign_JCalls *j_calls = (LDKSign_JCalls*) this_arg; int8_tArray ret = js_invoke_function_0(j_calls->write_meth); LDKCVec_u8Z ret_ref; ret_ref.datalen = *((uint32_t*)ret); ret_ref.data = MALLOC(ret_ref.datalen, "LDKCVec_u8Z Bytes"); memcpy(ret_ref.data, (uint8_t*)(ret + 4), ret_ref.datalen); return ret_ref; } static void LDKSign_JCalls_cloned(LDKSign* new_obj) { LDKSign_JCalls *j_calls = (LDKSign_JCalls*) new_obj->this_arg; atomic_fetch_add_explicit(&j_calls->refcnt, 1, memory_order_release); atomic_fetch_add_explicit(&j_calls->BaseSign->refcnt, 1, memory_order_release); } static inline LDKSign LDKSign_init (/*TODO: JS Object Reference */void* o, /*TODO: JS Object Reference */void* BaseSign, uint32_t pubkeys) { LDKSign_JCalls *calls = MALLOC(sizeof(LDKSign_JCalls), "LDKSign_JCalls"); atomic_init(&calls->refcnt, 1); //TODO: Assign calls->o from o LDKChannelPublicKeys pubkeys_conv; pubkeys_conv.inner = (void*)(pubkeys & (~1)); pubkeys_conv.is_owned = (pubkeys & 1) || (pubkeys == 0); pubkeys_conv = ChannelPublicKeys_clone(&pubkeys_conv); LDKSign ret = { .this_arg = (void*) calls, .write = write_LDKSign_jcall, .cloned = LDKSign_JCalls_cloned, .free = LDKSign_JCalls_free, .BaseSign = LDKBaseSign_init(BaseSign, pubkeys), }; calls->BaseSign = ret.BaseSign.this_arg; return ret; } long __attribute__((visibility("default"))) TS_LDKSign_new(/*TODO: JS Object Reference */void* o, /*TODO: JS Object Reference */ void* BaseSign, uint32_t pubkeys) { LDKSign *res_ptr = MALLOC(sizeof(LDKSign), "LDKSign"); *res_ptr = LDKSign_init(o, BaseSign, pubkeys); return (long)res_ptr; } int8_tArray __attribute__((visibility("default"))) TS_Sign_write(uint32_t this_arg) { LDKSign* this_arg_conv = (LDKSign*)(((uint64_t)this_arg) & ~1); LDKCVec_u8Z ret_var = (this_arg_conv->write)(this_arg_conv->this_arg); int8_tArray ret_arr = init_arr(ret_var.datalen, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), ret_var.data, ret_var.datalen); CVec_u8Z_free(ret_var); return ret_arr; } jboolean __attribute__((visibility("default"))) TS_LDKCResult_SignDecodeErrorZ_result_ok(uint32_t arg) { return ((LDKCResult_SignDecodeErrorZ*)arg)->result_ok; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_SignDecodeErrorZ_get_ok(uint32_t arg) { LDKCResult_SignDecodeErrorZ *val = (LDKCResult_SignDecodeErrorZ*)(arg & ~1); CHECK(val->result_ok); LDKSign* res_ret =MALLOC(sizeof(LDKSign), "LDKSign"); *res_ret = Sign_clone(&(*val->contents.result)); return (uint64_t)res_ret; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_SignDecodeErrorZ_get_err(uint32_t arg) { LDKCResult_SignDecodeErrorZ *val = (LDKCResult_SignDecodeErrorZ*)(arg & ~1); CHECK(!val->result_ok); LDKDecodeError err_var = (*val->contents.err); CHECK((((uint64_t)err_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&err_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t err_ref = (uint64_t)err_var.inner & ~1; return err_ref; } jboolean __attribute__((visibility("default"))) TS_LDKCResult_RecoverableSignatureNoneZ_result_ok(uint32_t arg) { return ((LDKCResult_RecoverableSignatureNoneZ*)arg)->result_ok; } int8_tArray __attribute__((visibility("default"))) TS_LDKCResult_RecoverableSignatureNoneZ_get_ok(uint32_t arg) { LDKCResult_RecoverableSignatureNoneZ *val = (LDKCResult_RecoverableSignatureNoneZ*)(arg & ~1); CHECK(val->result_ok); int8_tArray es_arr = init_arr(68, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(es_arr + 4), (*val->contents.result).serialized_form, 68); return es_arr; } void __attribute__((visibility("default"))) TS_LDKCResult_RecoverableSignatureNoneZ_get_err(uint32_t arg) { LDKCResult_RecoverableSignatureNoneZ *val = (LDKCResult_RecoverableSignatureNoneZ*)(arg & ~1); CHECK(!val->result_ok); return *val->contents.err; } static inline LDKCVec_CVec_u8ZZ CVec_CVec_u8ZZ_clone(const LDKCVec_CVec_u8ZZ *orig) { LDKCVec_CVec_u8ZZ ret = { .data = MALLOC(sizeof(LDKCVec_u8Z) * orig->datalen, "LDKCVec_CVec_u8ZZ clone bytes"), .datalen = orig->datalen }; for (size_t i = 0; i < ret.datalen; i++) { ret.data[i] = CVec_u8Z_clone(&orig->data[i]); } return ret; } jboolean __attribute__((visibility("default"))) TS_LDKCResult_CVec_CVec_u8ZZNoneZ_result_ok(uint32_t arg) { return ((LDKCResult_CVec_CVec_u8ZZNoneZ*)arg)->result_ok; } ptrArray __attribute__((visibility("default"))) TS_LDKCResult_CVec_CVec_u8ZZNoneZ_get_ok(uint32_t arg) { LDKCResult_CVec_CVec_u8ZZNoneZ *val = (LDKCResult_CVec_CVec_u8ZZNoneZ*)(arg & ~1); CHECK(val->result_ok); LDKCVec_CVec_u8ZZ res_var = (*val->contents.result); ptrArray res_arr = init_arr(res_var.datalen, sizeof(uint32_t), "Native ptrArray Bytes"); int8_tArray *res_arr_ptr = (int8_tArray*)(res_arr + 4); for (size_t m = 0; m < res_var.datalen; m++) { LDKCVec_u8Z res_conv_12_var = res_var.data[m]; int8_tArray res_conv_12_arr = init_arr(res_conv_12_var.datalen, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(res_conv_12_arr + 4), res_conv_12_var.data, res_conv_12_var.datalen); res_arr_ptr[m] = res_conv_12_arr; } return res_arr; } void __attribute__((visibility("default"))) TS_LDKCResult_CVec_CVec_u8ZZNoneZ_get_err(uint32_t arg) { LDKCResult_CVec_CVec_u8ZZNoneZ *val = (LDKCResult_CVec_CVec_u8ZZNoneZ*)(arg & ~1); CHECK(!val->result_ok); return *val->contents.err; } jboolean __attribute__((visibility("default"))) TS_LDKCResult_InMemorySignerDecodeErrorZ_result_ok(uint32_t arg) { return ((LDKCResult_InMemorySignerDecodeErrorZ*)arg)->result_ok; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_InMemorySignerDecodeErrorZ_get_ok(uint32_t arg) { LDKCResult_InMemorySignerDecodeErrorZ *val = (LDKCResult_InMemorySignerDecodeErrorZ*)(arg & ~1); CHECK(val->result_ok); LDKInMemorySigner res_var = (*val->contents.result); CHECK((((uint64_t)res_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&res_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t res_ref = (uint64_t)res_var.inner & ~1; return res_ref; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_InMemorySignerDecodeErrorZ_get_err(uint32_t arg) { LDKCResult_InMemorySignerDecodeErrorZ *val = (LDKCResult_InMemorySignerDecodeErrorZ*)(arg & ~1); CHECK(!val->result_ok); LDKDecodeError err_var = (*val->contents.err); CHECK((((uint64_t)err_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&err_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t err_ref = (uint64_t)err_var.inner & ~1; return err_ref; } uint32_t __attribute__((visibility("default"))) TS_LDKCVec_TxOutZ_new(uint32_tArray elems) { LDKCVec_TxOutZ *ret = MALLOC(sizeof(LDKCVec_TxOutZ), "LDKCVec_TxOutZ"); ret->datalen = *((uint32_t*)elems); if (ret->datalen == 0) { ret->data = NULL; } else { ret->data = MALLOC(sizeof(LDKTxOut) * ret->datalen, "LDKCVec_TxOutZ Data"); uint32_t *java_elems = (uint32_t*)(elems + 4); for (size_t i = 0; i < ret->datalen; i++) { uint32_t arr_elem = java_elems[i]; LDKTxOut arr_elem_conv = *(LDKTxOut*)(((uint64_t)arr_elem) & ~1); arr_elem_conv = TxOut_clone((LDKTxOut*)(((uint64_t)arr_elem) & ~1)); ret->data[i] = arr_elem_conv; } } return (uint64_t)ret; } static inline LDKCVec_TxOutZ CVec_TxOutZ_clone(const LDKCVec_TxOutZ *orig) { LDKCVec_TxOutZ ret = { .data = MALLOC(sizeof(LDKTxOut) * orig->datalen, "LDKCVec_TxOutZ clone bytes"), .datalen = orig->datalen }; for (size_t i = 0; i < ret.datalen; i++) { ret.data[i] = TxOut_clone(&orig->data[i]); } return ret; } jboolean __attribute__((visibility("default"))) TS_LDKCResult_TransactionNoneZ_result_ok(uint32_t arg) { return ((LDKCResult_TransactionNoneZ*)arg)->result_ok; } int8_tArray __attribute__((visibility("default"))) TS_LDKCResult_TransactionNoneZ_get_ok(uint32_t arg) { LDKCResult_TransactionNoneZ *val = (LDKCResult_TransactionNoneZ*)(arg & ~1); CHECK(val->result_ok); LDKTransaction res_var = (*val->contents.result); int8_tArray res_arr = init_arr(res_var.datalen, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(res_arr + 4), res_var.data, res_var.datalen); return res_arr; } void __attribute__((visibility("default"))) TS_LDKCResult_TransactionNoneZ_get_err(uint32_t arg) { LDKCResult_TransactionNoneZ *val = (LDKCResult_TransactionNoneZ*)(arg & ~1); CHECK(!val->result_ok); return *val->contents.err; } uint32_t __attribute__((visibility("default"))) TS_LDKC2Tuple_BlockHashChannelMonitorZ_new(int8_tArray a, uint32_t b) { LDKC2Tuple_BlockHashChannelMonitorZ* ret = MALLOC(sizeof(LDKC2Tuple_BlockHashChannelMonitorZ), "LDKC2Tuple_BlockHashChannelMonitorZ"); LDKThirtyTwoBytes a_ref; CHECK(*((uint32_t*)a) == 32); memcpy(a_ref.data, (uint8_t*)(a + 4), 32); ret->a = a_ref; LDKChannelMonitor b_conv; b_conv.inner = (void*)(b & (~1)); b_conv.is_owned = (b & 1) || (b == 0); b_conv = ChannelMonitor_clone(&b_conv); ret->b = b_conv; return (uint64_t)ret; } int8_tArray __attribute__((visibility("default"))) TS_LDKC2Tuple_BlockHashChannelMonitorZ_get_a(uint32_t ptr) { LDKC2Tuple_BlockHashChannelMonitorZ *tuple = (LDKC2Tuple_BlockHashChannelMonitorZ*)(ptr & ~1); int8_tArray a_arr = init_arr(32, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(a_arr + 4), tuple->a.data, 32); return a_arr; } uint32_t __attribute__((visibility("default"))) TS_LDKC2Tuple_BlockHashChannelMonitorZ_get_b(uint32_t ptr) { LDKC2Tuple_BlockHashChannelMonitorZ *tuple = (LDKC2Tuple_BlockHashChannelMonitorZ*)(ptr & ~1); LDKChannelMonitor b_var = tuple->b; CHECK((((uint64_t)b_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&b_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t b_ref = (uint64_t)b_var.inner & ~1; return b_ref; } uint32_t __attribute__((visibility("default"))) TS_LDKCVec_C2Tuple_BlockHashChannelMonitorZZ_new(uint32_tArray elems) { LDKCVec_C2Tuple_BlockHashChannelMonitorZZ *ret = MALLOC(sizeof(LDKCVec_C2Tuple_BlockHashChannelMonitorZZ), "LDKCVec_C2Tuple_BlockHashChannelMonitorZZ"); ret->datalen = *((uint32_t*)elems); if (ret->datalen == 0) { ret->data = NULL; } else { ret->data = MALLOC(sizeof(LDKC2Tuple_BlockHashChannelMonitorZ) * ret->datalen, "LDKCVec_C2Tuple_BlockHashChannelMonitorZZ Data"); uint32_t *java_elems = (uint32_t*)(elems + 4); for (size_t i = 0; i < ret->datalen; i++) { uint32_t arr_elem = java_elems[i]; LDKC2Tuple_BlockHashChannelMonitorZ arr_elem_conv = *(LDKC2Tuple_BlockHashChannelMonitorZ*)(((uint64_t)arr_elem) & ~1); // Warning: we may need a move here but no clone is available for LDKC2Tuple_BlockHashChannelMonitorZ ret->data[i] = arr_elem_conv; } } return (uint64_t)ret; } jboolean __attribute__((visibility("default"))) TS_LDKCResult_CVec_C2Tuple_BlockHashChannelMonitorZZErrorZ_result_ok(uint32_t arg) { return ((LDKCResult_CVec_C2Tuple_BlockHashChannelMonitorZZErrorZ*)arg)->result_ok; } uint32_tArray __attribute__((visibility("default"))) TS_LDKCResult_CVec_C2Tuple_BlockHashChannelMonitorZZErrorZ_get_ok(uint32_t arg) { LDKCResult_CVec_C2Tuple_BlockHashChannelMonitorZZErrorZ *val = (LDKCResult_CVec_C2Tuple_BlockHashChannelMonitorZZErrorZ*)(arg & ~1); CHECK(val->result_ok); LDKCVec_C2Tuple_BlockHashChannelMonitorZZ res_var = (*val->contents.result); uint32_tArray res_arr = init_arr(res_var.datalen, sizeof(uint32_t), "Native uint32_tArray Bytes"); uint32_t *res_arr_ptr = (uint32_t*)(res_arr + 4); for (size_t m = 0; m < res_var.datalen; m++) { uint64_t res_conv_38_ref = (uint64_t)(&res_var.data[m]) | 1; res_arr_ptr[m] = res_conv_38_ref; } return res_arr; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_CVec_C2Tuple_BlockHashChannelMonitorZZErrorZ_get_err(uint32_t arg) { LDKCResult_CVec_C2Tuple_BlockHashChannelMonitorZZErrorZ *val = (LDKCResult_CVec_C2Tuple_BlockHashChannelMonitorZZErrorZ*)(arg & ~1); CHECK(!val->result_ok); uint32_t err_conv = LDKIOError_to_js((*val->contents.err)); return err_conv; } uint32_t __attribute__((visibility("default"))) TS_LDKCOption_u16Z_ref_from_ptr(uint32_t ptr) { LDKCOption_u16Z *obj = (LDKCOption_u16Z*)(ptr & ~1); switch(obj->tag) { case LDKCOption_u16Z_Some: { return 0 /* LDKCOption_u16Z - Some */; (void) obj->some; } case LDKCOption_u16Z_None: { return 0 /* LDKCOption_u16Z - None */; } default: abort(); } } uint32_t __attribute__((visibility("default"))) TS_LDKAPIError_ref_from_ptr(uint32_t ptr) { LDKAPIError *obj = (LDKAPIError*)(ptr & ~1); switch(obj->tag) { case LDKAPIError_APIMisuseError: { LDKStr err_str = obj->api_misuse_error.err; jstring err_conv = str_ref_to_ts(err_str.chars, err_str.len); return 0 /* LDKAPIError - APIMisuseError */; (void) err_conv; } case LDKAPIError_FeeRateTooHigh: { LDKStr err_str = obj->fee_rate_too_high.err; jstring err_conv = str_ref_to_ts(err_str.chars, err_str.len); return 0 /* LDKAPIError - FeeRateTooHigh */; (void) err_conv; (void) obj->fee_rate_too_high.feerate; } case LDKAPIError_RouteError: { LDKStr err_str = obj->route_error.err; jstring err_conv = str_ref_to_ts(err_str.chars, err_str.len); return 0 /* LDKAPIError - RouteError */; (void) err_conv; } case LDKAPIError_ChannelUnavailable: { LDKStr err_str = obj->channel_unavailable.err; jstring err_conv = str_ref_to_ts(err_str.chars, err_str.len); return 0 /* LDKAPIError - ChannelUnavailable */; (void) err_conv; } case LDKAPIError_MonitorUpdateFailed: { return 0 /* LDKAPIError - MonitorUpdateFailed */; } case LDKAPIError_IncompatibleShutdownScript: { LDKShutdownScript script_var = obj->incompatible_shutdown_script.script; CHECK((((uint64_t)script_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&script_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t script_ref = (uint64_t)script_var.inner & ~1; return 0 /* LDKAPIError - IncompatibleShutdownScript */; (void) script_ref; } default: abort(); } } jboolean __attribute__((visibility("default"))) TS_LDKCResult_NoneAPIErrorZ_result_ok(uint32_t arg) { return ((LDKCResult_NoneAPIErrorZ*)arg)->result_ok; } void __attribute__((visibility("default"))) TS_LDKCResult_NoneAPIErrorZ_get_ok(uint32_t arg) { LDKCResult_NoneAPIErrorZ *val = (LDKCResult_NoneAPIErrorZ*)(arg & ~1); CHECK(val->result_ok); return *val->contents.result; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_NoneAPIErrorZ_get_err(uint32_t arg) { LDKCResult_NoneAPIErrorZ *val = (LDKCResult_NoneAPIErrorZ*)(arg & ~1); CHECK(!val->result_ok); uint64_t err_ref = ((uint64_t)&(*val->contents.err)) | 1; return err_ref; } uint32_t __attribute__((visibility("default"))) TS_LDKCVec_CResult_NoneAPIErrorZZ_new(uint32_tArray elems) { LDKCVec_CResult_NoneAPIErrorZZ *ret = MALLOC(sizeof(LDKCVec_CResult_NoneAPIErrorZZ), "LDKCVec_CResult_NoneAPIErrorZZ"); ret->datalen = *((uint32_t*)elems); if (ret->datalen == 0) { ret->data = NULL; } else { ret->data = MALLOC(sizeof(LDKCResult_NoneAPIErrorZ) * ret->datalen, "LDKCVec_CResult_NoneAPIErrorZZ Data"); uint32_t *java_elems = (uint32_t*)(elems + 4); for (size_t i = 0; i < ret->datalen; i++) { uint32_t arr_elem = java_elems[i]; LDKCResult_NoneAPIErrorZ arr_elem_conv = *(LDKCResult_NoneAPIErrorZ*)(((uint64_t)arr_elem) & ~1); arr_elem_conv = CResult_NoneAPIErrorZ_clone((LDKCResult_NoneAPIErrorZ*)(((uint64_t)arr_elem) & ~1)); ret->data[i] = arr_elem_conv; } } return (uint64_t)ret; } static inline LDKCVec_CResult_NoneAPIErrorZZ CVec_CResult_NoneAPIErrorZZ_clone(const LDKCVec_CResult_NoneAPIErrorZZ *orig) { LDKCVec_CResult_NoneAPIErrorZZ ret = { .data = MALLOC(sizeof(LDKCResult_NoneAPIErrorZ) * orig->datalen, "LDKCVec_CResult_NoneAPIErrorZZ clone bytes"), .datalen = orig->datalen }; for (size_t i = 0; i < ret.datalen; i++) { ret.data[i] = CResult_NoneAPIErrorZ_clone(&orig->data[i]); } return ret; } uint32_t __attribute__((visibility("default"))) TS_LDKCVec_APIErrorZ_new(uint32_tArray elems) { LDKCVec_APIErrorZ *ret = MALLOC(sizeof(LDKCVec_APIErrorZ), "LDKCVec_APIErrorZ"); ret->datalen = *((uint32_t*)elems); if (ret->datalen == 0) { ret->data = NULL; } else { ret->data = MALLOC(sizeof(LDKAPIError) * ret->datalen, "LDKCVec_APIErrorZ Data"); uint32_t *java_elems = (uint32_t*)(elems + 4); for (size_t i = 0; i < ret->datalen; i++) { uint32_t arr_elem = java_elems[i]; LDKAPIError arr_elem_conv = *(LDKAPIError*)(((uint64_t)arr_elem) & ~1); arr_elem_conv = APIError_clone((LDKAPIError*)(((uint64_t)arr_elem) & ~1)); ret->data[i] = arr_elem_conv; } } return (uint64_t)ret; } static inline LDKCVec_APIErrorZ CVec_APIErrorZ_clone(const LDKCVec_APIErrorZ *orig) { LDKCVec_APIErrorZ ret = { .data = MALLOC(sizeof(LDKAPIError) * orig->datalen, "LDKCVec_APIErrorZ clone bytes"), .datalen = orig->datalen }; for (size_t i = 0; i < ret.datalen; i++) { ret.data[i] = APIError_clone(&orig->data[i]); } return ret; } uint32_t __attribute__((visibility("default"))) TS_LDKPaymentSendFailure_ref_from_ptr(uint32_t ptr) { LDKPaymentSendFailure *obj = (LDKPaymentSendFailure*)(ptr & ~1); switch(obj->tag) { case LDKPaymentSendFailure_ParameterError: { uint64_t parameter_error_ref = ((uint64_t)&obj->parameter_error) | 1; return 0 /* LDKPaymentSendFailure - ParameterError */; (void) parameter_error_ref; } case LDKPaymentSendFailure_PathParameterError: { LDKCVec_CResult_NoneAPIErrorZZ path_parameter_error_var = obj->path_parameter_error; uint32_tArray path_parameter_error_arr = init_arr(path_parameter_error_var.datalen, sizeof(uint32_t), "Native uint32_tArray Bytes"); uint32_t *path_parameter_error_arr_ptr = (uint32_t*)(path_parameter_error_arr + 4); for (size_t w = 0; w < path_parameter_error_var.datalen; w++) { LDKCResult_NoneAPIErrorZ* path_parameter_error_conv_22_conv = MALLOC(sizeof(LDKCResult_NoneAPIErrorZ), "LDKCResult_NoneAPIErrorZ"); *path_parameter_error_conv_22_conv = path_parameter_error_var.data[w]; *path_parameter_error_conv_22_conv = CResult_NoneAPIErrorZ_clone(path_parameter_error_conv_22_conv); path_parameter_error_arr_ptr[w] = (uint64_t)path_parameter_error_conv_22_conv; } return 0 /* LDKPaymentSendFailure - PathParameterError */; (void) path_parameter_error_arr; } case LDKPaymentSendFailure_AllFailedRetrySafe: { LDKCVec_APIErrorZ all_failed_retry_safe_var = obj->all_failed_retry_safe; uint32_tArray all_failed_retry_safe_arr = init_arr(all_failed_retry_safe_var.datalen, sizeof(uint32_t), "Native uint32_tArray Bytes"); uint32_t *all_failed_retry_safe_arr_ptr = (uint32_t*)(all_failed_retry_safe_arr + 4); for (size_t k = 0; k < all_failed_retry_safe_var.datalen; k++) { uint64_t all_failed_retry_safe_conv_10_ref = ((uint64_t)&all_failed_retry_safe_var.data[k]) | 1; all_failed_retry_safe_arr_ptr[k] = all_failed_retry_safe_conv_10_ref; } return 0 /* LDKPaymentSendFailure - AllFailedRetrySafe */; (void) all_failed_retry_safe_arr; } case LDKPaymentSendFailure_PartialFailure: { LDKCVec_CResult_NoneAPIErrorZZ partial_failure_var = obj->partial_failure; uint32_tArray partial_failure_arr = init_arr(partial_failure_var.datalen, sizeof(uint32_t), "Native uint32_tArray Bytes"); uint32_t *partial_failure_arr_ptr = (uint32_t*)(partial_failure_arr + 4); for (size_t w = 0; w < partial_failure_var.datalen; w++) { LDKCResult_NoneAPIErrorZ* partial_failure_conv_22_conv = MALLOC(sizeof(LDKCResult_NoneAPIErrorZ), "LDKCResult_NoneAPIErrorZ"); *partial_failure_conv_22_conv = partial_failure_var.data[w]; *partial_failure_conv_22_conv = CResult_NoneAPIErrorZ_clone(partial_failure_conv_22_conv); partial_failure_arr_ptr[w] = (uint64_t)partial_failure_conv_22_conv; } return 0 /* LDKPaymentSendFailure - PartialFailure */; (void) partial_failure_arr; } default: abort(); } } jboolean __attribute__((visibility("default"))) TS_LDKCResult_NonePaymentSendFailureZ_result_ok(uint32_t arg) { return ((LDKCResult_NonePaymentSendFailureZ*)arg)->result_ok; } void __attribute__((visibility("default"))) TS_LDKCResult_NonePaymentSendFailureZ_get_ok(uint32_t arg) { LDKCResult_NonePaymentSendFailureZ *val = (LDKCResult_NonePaymentSendFailureZ*)(arg & ~1); CHECK(val->result_ok); return *val->contents.result; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_NonePaymentSendFailureZ_get_err(uint32_t arg) { LDKCResult_NonePaymentSendFailureZ *val = (LDKCResult_NonePaymentSendFailureZ*)(arg & ~1); CHECK(!val->result_ok); uint64_t err_ref = ((uint64_t)&(*val->contents.err)) | 1; return err_ref; } jboolean __attribute__((visibility("default"))) TS_LDKCResult_PaymentHashPaymentSendFailureZ_result_ok(uint32_t arg) { return ((LDKCResult_PaymentHashPaymentSendFailureZ*)arg)->result_ok; } int8_tArray __attribute__((visibility("default"))) TS_LDKCResult_PaymentHashPaymentSendFailureZ_get_ok(uint32_t arg) { LDKCResult_PaymentHashPaymentSendFailureZ *val = (LDKCResult_PaymentHashPaymentSendFailureZ*)(arg & ~1); CHECK(val->result_ok); int8_tArray res_arr = init_arr(32, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(res_arr + 4), (*val->contents.result).data, 32); return res_arr; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_PaymentHashPaymentSendFailureZ_get_err(uint32_t arg) { LDKCResult_PaymentHashPaymentSendFailureZ *val = (LDKCResult_PaymentHashPaymentSendFailureZ*)(arg & ~1); CHECK(!val->result_ok); uint64_t err_ref = ((uint64_t)&(*val->contents.err)) | 1; return err_ref; } uint32_t __attribute__((visibility("default"))) TS_LDKNetAddress_ref_from_ptr(uint32_t ptr) { LDKNetAddress *obj = (LDKNetAddress*)(ptr & ~1); switch(obj->tag) { case LDKNetAddress_IPv4: { int8_tArray addr_arr = init_arr(4, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(addr_arr + 4), obj->i_pv4.addr.data, 4); return 0 /* LDKNetAddress - IPv4 */; (void) addr_arr; (void) obj->i_pv4.port; } case LDKNetAddress_IPv6: { int8_tArray addr_arr = init_arr(16, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(addr_arr + 4), obj->i_pv6.addr.data, 16); return 0 /* LDKNetAddress - IPv6 */; (void) addr_arr; (void) obj->i_pv6.port; } case LDKNetAddress_OnionV2: { int8_tArray addr_arr = init_arr(10, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(addr_arr + 4), obj->onion_v2.addr.data, 10); return 0 /* LDKNetAddress - OnionV2 */; (void) addr_arr; (void) obj->onion_v2.port; } case LDKNetAddress_OnionV3: { int8_tArray ed25519_pubkey_arr = init_arr(32, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ed25519_pubkey_arr + 4), obj->onion_v3.ed25519_pubkey.data, 32); return 0 /* LDKNetAddress - OnionV3 */; (void) ed25519_pubkey_arr; (void) obj->onion_v3.checksum; (void) obj->onion_v3.version; (void) obj->onion_v3.port; } default: abort(); } } uint32_t __attribute__((visibility("default"))) TS_LDKCVec_NetAddressZ_new(uint32_tArray elems) { LDKCVec_NetAddressZ *ret = MALLOC(sizeof(LDKCVec_NetAddressZ), "LDKCVec_NetAddressZ"); ret->datalen = *((uint32_t*)elems); if (ret->datalen == 0) { ret->data = NULL; } else { ret->data = MALLOC(sizeof(LDKNetAddress) * ret->datalen, "LDKCVec_NetAddressZ Data"); uint32_t *java_elems = (uint32_t*)(elems + 4); for (size_t i = 0; i < ret->datalen; i++) { uint32_t arr_elem = java_elems[i]; LDKNetAddress arr_elem_conv = *(LDKNetAddress*)(((uint64_t)arr_elem) & ~1); arr_elem_conv = NetAddress_clone((LDKNetAddress*)(((uint64_t)arr_elem) & ~1)); ret->data[i] = arr_elem_conv; } } return (uint64_t)ret; } static inline LDKCVec_NetAddressZ CVec_NetAddressZ_clone(const LDKCVec_NetAddressZ *orig) { LDKCVec_NetAddressZ ret = { .data = MALLOC(sizeof(LDKNetAddress) * orig->datalen, "LDKCVec_NetAddressZ clone bytes"), .datalen = orig->datalen }; for (size_t i = 0; i < ret.datalen; i++) { ret.data[i] = NetAddress_clone(&orig->data[i]); } return ret; } uint32_t __attribute__((visibility("default"))) TS_LDKC2Tuple_PaymentHashPaymentSecretZ_new(int8_tArray a, int8_tArray b) { LDKC2Tuple_PaymentHashPaymentSecretZ* ret = MALLOC(sizeof(LDKC2Tuple_PaymentHashPaymentSecretZ), "LDKC2Tuple_PaymentHashPaymentSecretZ"); LDKThirtyTwoBytes a_ref; CHECK(*((uint32_t*)a) == 32); memcpy(a_ref.data, (uint8_t*)(a + 4), 32); ret->a = a_ref; LDKThirtyTwoBytes b_ref; CHECK(*((uint32_t*)b) == 32); memcpy(b_ref.data, (uint8_t*)(b + 4), 32); ret->b = b_ref; return (uint64_t)ret; } int8_tArray __attribute__((visibility("default"))) TS_LDKC2Tuple_PaymentHashPaymentSecretZ_get_a(uint32_t ptr) { LDKC2Tuple_PaymentHashPaymentSecretZ *tuple = (LDKC2Tuple_PaymentHashPaymentSecretZ*)(ptr & ~1); int8_tArray a_arr = init_arr(32, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(a_arr + 4), tuple->a.data, 32); return a_arr; } int8_tArray __attribute__((visibility("default"))) TS_LDKC2Tuple_PaymentHashPaymentSecretZ_get_b(uint32_t ptr) { LDKC2Tuple_PaymentHashPaymentSecretZ *tuple = (LDKC2Tuple_PaymentHashPaymentSecretZ*)(ptr & ~1); int8_tArray b_arr = init_arr(32, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(b_arr + 4), tuple->b.data, 32); return b_arr; } jboolean __attribute__((visibility("default"))) TS_LDKCResult_PaymentSecretAPIErrorZ_result_ok(uint32_t arg) { return ((LDKCResult_PaymentSecretAPIErrorZ*)arg)->result_ok; } int8_tArray __attribute__((visibility("default"))) TS_LDKCResult_PaymentSecretAPIErrorZ_get_ok(uint32_t arg) { LDKCResult_PaymentSecretAPIErrorZ *val = (LDKCResult_PaymentSecretAPIErrorZ*)(arg & ~1); CHECK(val->result_ok); int8_tArray res_arr = init_arr(32, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(res_arr + 4), (*val->contents.result).data, 32); return res_arr; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_PaymentSecretAPIErrorZ_get_err(uint32_t arg) { LDKCResult_PaymentSecretAPIErrorZ *val = (LDKCResult_PaymentSecretAPIErrorZ*)(arg & ~1); CHECK(!val->result_ok); uint64_t err_ref = ((uint64_t)&(*val->contents.err)) | 1; return err_ref; } uint32_t __attribute__((visibility("default"))) TS_LDKCVec_ChannelMonitorZ_new(uint32_tArray elems) { LDKCVec_ChannelMonitorZ *ret = MALLOC(sizeof(LDKCVec_ChannelMonitorZ), "LDKCVec_ChannelMonitorZ"); ret->datalen = *((uint32_t*)elems); if (ret->datalen == 0) { ret->data = NULL; } else { ret->data = MALLOC(sizeof(LDKChannelMonitor) * ret->datalen, "LDKCVec_ChannelMonitorZ Data"); uint32_t *java_elems = (uint32_t*)(elems + 4); for (size_t i = 0; i < ret->datalen; i++) { uint32_t arr_elem = java_elems[i]; LDKChannelMonitor arr_elem_conv; arr_elem_conv.inner = (void*)(arr_elem & (~1)); arr_elem_conv.is_owned = (arr_elem & 1) || (arr_elem == 0); arr_elem_conv = ChannelMonitor_clone(&arr_elem_conv); ret->data[i] = arr_elem_conv; } } return (uint64_t)ret; } static inline LDKCVec_ChannelMonitorZ CVec_ChannelMonitorZ_clone(const LDKCVec_ChannelMonitorZ *orig) { LDKCVec_ChannelMonitorZ ret = { .data = MALLOC(sizeof(LDKChannelMonitor) * orig->datalen, "LDKCVec_ChannelMonitorZ clone bytes"), .datalen = orig->datalen }; for (size_t i = 0; i < ret.datalen; i++) { ret.data[i] = ChannelMonitor_clone(&orig->data[i]); } return ret; } typedef struct LDKWatch_JCalls { atomic_size_t refcnt; uint32_t watch_channel_meth; uint32_t update_channel_meth; uint32_t release_pending_monitor_events_meth; } LDKWatch_JCalls; static void LDKWatch_JCalls_free(void* this_arg) { LDKWatch_JCalls *j_calls = (LDKWatch_JCalls*) this_arg; if (atomic_fetch_sub_explicit(&j_calls->refcnt, 1, memory_order_acquire) == 1) { js_free(j_calls->watch_channel_meth); js_free(j_calls->update_channel_meth); js_free(j_calls->release_pending_monitor_events_meth); FREE(j_calls); } } LDKCResult_NoneChannelMonitorUpdateErrZ watch_channel_LDKWatch_jcall(const void* this_arg, LDKOutPoint funding_txo, LDKChannelMonitor monitor) { LDKWatch_JCalls *j_calls = (LDKWatch_JCalls*) this_arg; LDKOutPoint funding_txo_var = funding_txo; CHECK((((uint64_t)funding_txo_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&funding_txo_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t funding_txo_ref = (uint64_t)funding_txo_var.inner; if (funding_txo_var.is_owned) { funding_txo_ref |= 1; } LDKChannelMonitor monitor_var = monitor; CHECK((((uint64_t)monitor_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&monitor_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t monitor_ref = (uint64_t)monitor_var.inner; if (monitor_var.is_owned) { monitor_ref |= 1; } uint32_t ret = js_invoke_function_2(j_calls->watch_channel_meth, funding_txo_ref, monitor_ref); LDKCResult_NoneChannelMonitorUpdateErrZ ret_conv = *(LDKCResult_NoneChannelMonitorUpdateErrZ*)(((uint64_t)ret) & ~1); ret_conv = CResult_NoneChannelMonitorUpdateErrZ_clone((LDKCResult_NoneChannelMonitorUpdateErrZ*)(((uint64_t)ret) & ~1)); return ret_conv; } LDKCResult_NoneChannelMonitorUpdateErrZ update_channel_LDKWatch_jcall(const void* this_arg, LDKOutPoint funding_txo, LDKChannelMonitorUpdate update) { LDKWatch_JCalls *j_calls = (LDKWatch_JCalls*) this_arg; LDKOutPoint funding_txo_var = funding_txo; CHECK((((uint64_t)funding_txo_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&funding_txo_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t funding_txo_ref = (uint64_t)funding_txo_var.inner; if (funding_txo_var.is_owned) { funding_txo_ref |= 1; } LDKChannelMonitorUpdate update_var = update; CHECK((((uint64_t)update_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&update_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t update_ref = (uint64_t)update_var.inner; if (update_var.is_owned) { update_ref |= 1; } uint32_t ret = js_invoke_function_2(j_calls->update_channel_meth, funding_txo_ref, update_ref); LDKCResult_NoneChannelMonitorUpdateErrZ ret_conv = *(LDKCResult_NoneChannelMonitorUpdateErrZ*)(((uint64_t)ret) & ~1); ret_conv = CResult_NoneChannelMonitorUpdateErrZ_clone((LDKCResult_NoneChannelMonitorUpdateErrZ*)(((uint64_t)ret) & ~1)); return ret_conv; } LDKCVec_MonitorEventZ release_pending_monitor_events_LDKWatch_jcall(const void* this_arg) { LDKWatch_JCalls *j_calls = (LDKWatch_JCalls*) this_arg; uint32_tArray ret = js_invoke_function_0(j_calls->release_pending_monitor_events_meth); LDKCVec_MonitorEventZ ret_constr; ret_constr.datalen = *((uint32_t*)ret); if (ret_constr.datalen > 0) ret_constr.data = MALLOC(ret_constr.datalen * sizeof(LDKMonitorEvent), "LDKCVec_MonitorEventZ Elements"); else ret_constr.data = NULL; uint32_t* ret_vals = (uint32_t*)(ret + 4); for (size_t o = 0; o < ret_constr.datalen; o++) { uint32_t ret_conv_14 = ret_vals[o]; LDKMonitorEvent ret_conv_14_conv = *(LDKMonitorEvent*)(((uint64_t)ret_conv_14) & ~1); ret_conv_14_conv = MonitorEvent_clone((LDKMonitorEvent*)(((uint64_t)ret_conv_14) & ~1)); ret_constr.data[o] = ret_conv_14_conv; } return ret_constr; } static void LDKWatch_JCalls_cloned(LDKWatch* new_obj) { LDKWatch_JCalls *j_calls = (LDKWatch_JCalls*) new_obj->this_arg; atomic_fetch_add_explicit(&j_calls->refcnt, 1, memory_order_release); } static inline LDKWatch LDKWatch_init (/*TODO: JS Object Reference */void* o) { LDKWatch_JCalls *calls = MALLOC(sizeof(LDKWatch_JCalls), "LDKWatch_JCalls"); atomic_init(&calls->refcnt, 1); //TODO: Assign calls->o from o LDKWatch ret = { .this_arg = (void*) calls, .watch_channel = watch_channel_LDKWatch_jcall, .update_channel = update_channel_LDKWatch_jcall, .release_pending_monitor_events = release_pending_monitor_events_LDKWatch_jcall, .free = LDKWatch_JCalls_free, }; return ret; } long __attribute__((visibility("default"))) TS_LDKWatch_new(/*TODO: JS Object Reference */void* o) { LDKWatch *res_ptr = MALLOC(sizeof(LDKWatch), "LDKWatch"); *res_ptr = LDKWatch_init(o); return (long)res_ptr; } uint32_t __attribute__((visibility("default"))) TS_Watch_watch_channel(uint32_t this_arg, uint32_t funding_txo, uint32_t monitor) { LDKWatch* this_arg_conv = (LDKWatch*)(((uint64_t)this_arg) & ~1); LDKOutPoint funding_txo_conv; funding_txo_conv.inner = (void*)(funding_txo & (~1)); funding_txo_conv.is_owned = (funding_txo & 1) || (funding_txo == 0); funding_txo_conv = OutPoint_clone(&funding_txo_conv); LDKChannelMonitor monitor_conv; monitor_conv.inner = (void*)(monitor & (~1)); monitor_conv.is_owned = (monitor & 1) || (monitor == 0); monitor_conv = ChannelMonitor_clone(&monitor_conv); LDKCResult_NoneChannelMonitorUpdateErrZ* ret_conv = MALLOC(sizeof(LDKCResult_NoneChannelMonitorUpdateErrZ), "LDKCResult_NoneChannelMonitorUpdateErrZ"); *ret_conv = (this_arg_conv->watch_channel)(this_arg_conv->this_arg, funding_txo_conv, monitor_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_Watch_update_channel(uint32_t this_arg, uint32_t funding_txo, uint32_t update) { LDKWatch* this_arg_conv = (LDKWatch*)(((uint64_t)this_arg) & ~1); LDKOutPoint funding_txo_conv; funding_txo_conv.inner = (void*)(funding_txo & (~1)); funding_txo_conv.is_owned = (funding_txo & 1) || (funding_txo == 0); funding_txo_conv = OutPoint_clone(&funding_txo_conv); LDKChannelMonitorUpdate update_conv; update_conv.inner = (void*)(update & (~1)); update_conv.is_owned = (update & 1) || (update == 0); update_conv = ChannelMonitorUpdate_clone(&update_conv); LDKCResult_NoneChannelMonitorUpdateErrZ* ret_conv = MALLOC(sizeof(LDKCResult_NoneChannelMonitorUpdateErrZ), "LDKCResult_NoneChannelMonitorUpdateErrZ"); *ret_conv = (this_arg_conv->update_channel)(this_arg_conv->this_arg, funding_txo_conv, update_conv); return (uint64_t)ret_conv; } uint32_tArray __attribute__((visibility("default"))) TS_Watch_release_pending_monitor_events(uint32_t this_arg) { LDKWatch* this_arg_conv = (LDKWatch*)(((uint64_t)this_arg) & ~1); LDKCVec_MonitorEventZ ret_var = (this_arg_conv->release_pending_monitor_events)(this_arg_conv->this_arg); uint32_tArray ret_arr = init_arr(ret_var.datalen, sizeof(uint32_t), "Native uint32_tArray Bytes"); uint32_t *ret_arr_ptr = (uint32_t*)(ret_arr + 4); for (size_t o = 0; o < ret_var.datalen; o++) { LDKMonitorEvent *ret_conv_14_copy = MALLOC(sizeof(LDKMonitorEvent), "LDKMonitorEvent"); *ret_conv_14_copy = MonitorEvent_clone(&ret_var.data[o]); uint64_t ret_conv_14_ref = (uint64_t)ret_conv_14_copy; ret_arr_ptr[o] = ret_conv_14_ref; } FREE(ret_var.data); return ret_arr; } typedef struct LDKBroadcasterInterface_JCalls { atomic_size_t refcnt; uint32_t broadcast_transaction_meth; } LDKBroadcasterInterface_JCalls; static void LDKBroadcasterInterface_JCalls_free(void* this_arg) { LDKBroadcasterInterface_JCalls *j_calls = (LDKBroadcasterInterface_JCalls*) this_arg; if (atomic_fetch_sub_explicit(&j_calls->refcnt, 1, memory_order_acquire) == 1) { js_free(j_calls->broadcast_transaction_meth); FREE(j_calls); } } void broadcast_transaction_LDKBroadcasterInterface_jcall(const void* this_arg, LDKTransaction tx) { LDKBroadcasterInterface_JCalls *j_calls = (LDKBroadcasterInterface_JCalls*) this_arg; LDKTransaction tx_var = tx; int8_tArray tx_arr = init_arr(tx_var.datalen, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(tx_arr + 4), tx_var.data, tx_var.datalen); Transaction_free(tx_var); js_invoke_function_1(j_calls->broadcast_transaction_meth, tx_arr); } static void LDKBroadcasterInterface_JCalls_cloned(LDKBroadcasterInterface* new_obj) { LDKBroadcasterInterface_JCalls *j_calls = (LDKBroadcasterInterface_JCalls*) new_obj->this_arg; atomic_fetch_add_explicit(&j_calls->refcnt, 1, memory_order_release); } static inline LDKBroadcasterInterface LDKBroadcasterInterface_init (/*TODO: JS Object Reference */void* o) { LDKBroadcasterInterface_JCalls *calls = MALLOC(sizeof(LDKBroadcasterInterface_JCalls), "LDKBroadcasterInterface_JCalls"); atomic_init(&calls->refcnt, 1); //TODO: Assign calls->o from o LDKBroadcasterInterface ret = { .this_arg = (void*) calls, .broadcast_transaction = broadcast_transaction_LDKBroadcasterInterface_jcall, .free = LDKBroadcasterInterface_JCalls_free, }; return ret; } long __attribute__((visibility("default"))) TS_LDKBroadcasterInterface_new(/*TODO: JS Object Reference */void* o) { LDKBroadcasterInterface *res_ptr = MALLOC(sizeof(LDKBroadcasterInterface), "LDKBroadcasterInterface"); *res_ptr = LDKBroadcasterInterface_init(o); return (long)res_ptr; } void __attribute__((visibility("default"))) TS_BroadcasterInterface_broadcast_transaction(uint32_t this_arg, int8_tArray tx) { LDKBroadcasterInterface* this_arg_conv = (LDKBroadcasterInterface*)(((uint64_t)this_arg) & ~1); LDKTransaction tx_ref; tx_ref.datalen = *((uint32_t*)tx); tx_ref.data = MALLOC(tx_ref.datalen, "LDKTransaction Bytes"); memcpy(tx_ref.data, (uint8_t*)(tx + 4), tx_ref.datalen); tx_ref.data_is_owned = true; (this_arg_conv->broadcast_transaction)(this_arg_conv->this_arg, tx_ref); } typedef struct LDKKeysInterface_JCalls { atomic_size_t refcnt; uint32_t get_node_secret_meth; uint32_t get_destination_script_meth; uint32_t get_shutdown_scriptpubkey_meth; uint32_t get_channel_signer_meth; uint32_t get_secure_random_bytes_meth; uint32_t read_chan_signer_meth; uint32_t sign_invoice_meth; } LDKKeysInterface_JCalls; static void LDKKeysInterface_JCalls_free(void* this_arg) { LDKKeysInterface_JCalls *j_calls = (LDKKeysInterface_JCalls*) this_arg; if (atomic_fetch_sub_explicit(&j_calls->refcnt, 1, memory_order_acquire) == 1) { js_free(j_calls->get_node_secret_meth); js_free(j_calls->get_destination_script_meth); js_free(j_calls->get_shutdown_scriptpubkey_meth); js_free(j_calls->get_channel_signer_meth); js_free(j_calls->get_secure_random_bytes_meth); js_free(j_calls->read_chan_signer_meth); js_free(j_calls->sign_invoice_meth); FREE(j_calls); } } LDKSecretKey get_node_secret_LDKKeysInterface_jcall(const void* this_arg) { LDKKeysInterface_JCalls *j_calls = (LDKKeysInterface_JCalls*) this_arg; int8_tArray ret = js_invoke_function_0(j_calls->get_node_secret_meth); LDKSecretKey ret_ref; CHECK(*((uint32_t*)ret) == 32); memcpy(ret_ref.bytes, (uint8_t*)(ret + 4), 32); return ret_ref; } LDKCVec_u8Z get_destination_script_LDKKeysInterface_jcall(const void* this_arg) { LDKKeysInterface_JCalls *j_calls = (LDKKeysInterface_JCalls*) this_arg; int8_tArray ret = js_invoke_function_0(j_calls->get_destination_script_meth); LDKCVec_u8Z ret_ref; ret_ref.datalen = *((uint32_t*)ret); ret_ref.data = MALLOC(ret_ref.datalen, "LDKCVec_u8Z Bytes"); memcpy(ret_ref.data, (uint8_t*)(ret + 4), ret_ref.datalen); return ret_ref; } LDKShutdownScript get_shutdown_scriptpubkey_LDKKeysInterface_jcall(const void* this_arg) { LDKKeysInterface_JCalls *j_calls = (LDKKeysInterface_JCalls*) this_arg; uint32_t ret = js_invoke_function_0(j_calls->get_shutdown_scriptpubkey_meth); LDKShutdownScript ret_conv; ret_conv.inner = (void*)(ret & (~1)); ret_conv.is_owned = (ret & 1) || (ret == 0); ret_conv = ShutdownScript_clone(&ret_conv); return ret_conv; } LDKSign get_channel_signer_LDKKeysInterface_jcall(const void* this_arg, bool inbound, uint64_t channel_value_satoshis) { LDKKeysInterface_JCalls *j_calls = (LDKKeysInterface_JCalls*) this_arg; uint32_t ret = js_invoke_function_2(j_calls->get_channel_signer_meth, inbound, channel_value_satoshis); LDKSign ret_conv = *(LDKSign*)(((uint64_t)ret) & ~1); ret_conv = Sign_clone(&ret_conv); return ret_conv; } LDKThirtyTwoBytes get_secure_random_bytes_LDKKeysInterface_jcall(const void* this_arg) { LDKKeysInterface_JCalls *j_calls = (LDKKeysInterface_JCalls*) this_arg; int8_tArray ret = js_invoke_function_0(j_calls->get_secure_random_bytes_meth); LDKThirtyTwoBytes ret_ref; CHECK(*((uint32_t*)ret) == 32); memcpy(ret_ref.data, (uint8_t*)(ret + 4), 32); return ret_ref; } LDKCResult_SignDecodeErrorZ read_chan_signer_LDKKeysInterface_jcall(const void* this_arg, LDKu8slice reader) { LDKKeysInterface_JCalls *j_calls = (LDKKeysInterface_JCalls*) this_arg; LDKu8slice reader_var = reader; int8_tArray reader_arr = init_arr(reader_var.datalen, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(reader_arr + 4), reader_var.data, reader_var.datalen); uint32_t ret = js_invoke_function_1(j_calls->read_chan_signer_meth, reader_arr); LDKCResult_SignDecodeErrorZ ret_conv = *(LDKCResult_SignDecodeErrorZ*)(((uint64_t)ret) & ~1); ret_conv = CResult_SignDecodeErrorZ_clone((LDKCResult_SignDecodeErrorZ*)(((uint64_t)ret) & ~1)); return ret_conv; } LDKCResult_RecoverableSignatureNoneZ sign_invoice_LDKKeysInterface_jcall(const void* this_arg, LDKCVec_u8Z invoice_preimage) { LDKKeysInterface_JCalls *j_calls = (LDKKeysInterface_JCalls*) this_arg; LDKCVec_u8Z invoice_preimage_var = invoice_preimage; int8_tArray invoice_preimage_arr = init_arr(invoice_preimage_var.datalen, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(invoice_preimage_arr + 4), invoice_preimage_var.data, invoice_preimage_var.datalen); CVec_u8Z_free(invoice_preimage_var); uint32_t ret = js_invoke_function_1(j_calls->sign_invoice_meth, invoice_preimage_arr); LDKCResult_RecoverableSignatureNoneZ ret_conv = *(LDKCResult_RecoverableSignatureNoneZ*)(((uint64_t)ret) & ~1); ret_conv = CResult_RecoverableSignatureNoneZ_clone((LDKCResult_RecoverableSignatureNoneZ*)(((uint64_t)ret) & ~1)); return ret_conv; } static void LDKKeysInterface_JCalls_cloned(LDKKeysInterface* new_obj) { LDKKeysInterface_JCalls *j_calls = (LDKKeysInterface_JCalls*) new_obj->this_arg; atomic_fetch_add_explicit(&j_calls->refcnt, 1, memory_order_release); } static inline LDKKeysInterface LDKKeysInterface_init (/*TODO: JS Object Reference */void* o) { LDKKeysInterface_JCalls *calls = MALLOC(sizeof(LDKKeysInterface_JCalls), "LDKKeysInterface_JCalls"); atomic_init(&calls->refcnt, 1); //TODO: Assign calls->o from o LDKKeysInterface ret = { .this_arg = (void*) calls, .get_node_secret = get_node_secret_LDKKeysInterface_jcall, .get_destination_script = get_destination_script_LDKKeysInterface_jcall, .get_shutdown_scriptpubkey = get_shutdown_scriptpubkey_LDKKeysInterface_jcall, .get_channel_signer = get_channel_signer_LDKKeysInterface_jcall, .get_secure_random_bytes = get_secure_random_bytes_LDKKeysInterface_jcall, .read_chan_signer = read_chan_signer_LDKKeysInterface_jcall, .sign_invoice = sign_invoice_LDKKeysInterface_jcall, .free = LDKKeysInterface_JCalls_free, }; return ret; } long __attribute__((visibility("default"))) TS_LDKKeysInterface_new(/*TODO: JS Object Reference */void* o) { LDKKeysInterface *res_ptr = MALLOC(sizeof(LDKKeysInterface), "LDKKeysInterface"); *res_ptr = LDKKeysInterface_init(o); return (long)res_ptr; } int8_tArray __attribute__((visibility("default"))) TS_KeysInterface_get_node_secret(uint32_t this_arg) { LDKKeysInterface* this_arg_conv = (LDKKeysInterface*)(((uint64_t)this_arg) & ~1); int8_tArray ret_arr = init_arr(32, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), (this_arg_conv->get_node_secret)(this_arg_conv->this_arg).bytes, 32); return ret_arr; } int8_tArray __attribute__((visibility("default"))) TS_KeysInterface_get_destination_script(uint32_t this_arg) { LDKKeysInterface* this_arg_conv = (LDKKeysInterface*)(((uint64_t)this_arg) & ~1); LDKCVec_u8Z ret_var = (this_arg_conv->get_destination_script)(this_arg_conv->this_arg); int8_tArray ret_arr = init_arr(ret_var.datalen, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), ret_var.data, ret_var.datalen); CVec_u8Z_free(ret_var); return ret_arr; } uint32_t __attribute__((visibility("default"))) TS_KeysInterface_get_shutdown_scriptpubkey(uint32_t this_arg) { LDKKeysInterface* this_arg_conv = (LDKKeysInterface*)(((uint64_t)this_arg) & ~1); LDKShutdownScript ret_var = (this_arg_conv->get_shutdown_scriptpubkey)(this_arg_conv->this_arg); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_KeysInterface_get_channel_signer(uint32_t this_arg, jboolean inbound, int64_t channel_value_satoshis) { LDKKeysInterface* this_arg_conv = (LDKKeysInterface*)(((uint64_t)this_arg) & ~1); LDKSign* ret_ret =MALLOC(sizeof(LDKSign), "LDKSign"); *ret_ret = (this_arg_conv->get_channel_signer)(this_arg_conv->this_arg, inbound, channel_value_satoshis); return (uint64_t)ret_ret; } int8_tArray __attribute__((visibility("default"))) TS_KeysInterface_get_secure_random_bytes(uint32_t this_arg) { LDKKeysInterface* this_arg_conv = (LDKKeysInterface*)(((uint64_t)this_arg) & ~1); int8_tArray ret_arr = init_arr(32, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), (this_arg_conv->get_secure_random_bytes)(this_arg_conv->this_arg).data, 32); return ret_arr; } uint32_t __attribute__((visibility("default"))) TS_KeysInterface_read_chan_signer(uint32_t this_arg, int8_tArray reader) { LDKKeysInterface* this_arg_conv = (LDKKeysInterface*)(((uint64_t)this_arg) & ~1); LDKu8slice reader_ref; reader_ref.datalen = *((uint32_t*)reader); reader_ref.data = (int8_t*)(reader + 4); LDKCResult_SignDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_SignDecodeErrorZ), "LDKCResult_SignDecodeErrorZ"); *ret_conv = (this_arg_conv->read_chan_signer)(this_arg_conv->this_arg, reader_ref); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_KeysInterface_sign_invoice(uint32_t this_arg, int8_tArray invoice_preimage) { LDKKeysInterface* this_arg_conv = (LDKKeysInterface*)(((uint64_t)this_arg) & ~1); LDKCVec_u8Z invoice_preimage_ref; invoice_preimage_ref.datalen = *((uint32_t*)invoice_preimage); invoice_preimage_ref.data = MALLOC(invoice_preimage_ref.datalen, "LDKCVec_u8Z Bytes"); memcpy(invoice_preimage_ref.data, (uint8_t*)(invoice_preimage + 4), invoice_preimage_ref.datalen); LDKCResult_RecoverableSignatureNoneZ* ret_conv = MALLOC(sizeof(LDKCResult_RecoverableSignatureNoneZ), "LDKCResult_RecoverableSignatureNoneZ"); *ret_conv = (this_arg_conv->sign_invoice)(this_arg_conv->this_arg, invoice_preimage_ref); return (uint64_t)ret_conv; } typedef struct LDKFeeEstimator_JCalls { atomic_size_t refcnt; uint32_t get_est_sat_per_1000_weight_meth; } LDKFeeEstimator_JCalls; static void LDKFeeEstimator_JCalls_free(void* this_arg) { LDKFeeEstimator_JCalls *j_calls = (LDKFeeEstimator_JCalls*) this_arg; if (atomic_fetch_sub_explicit(&j_calls->refcnt, 1, memory_order_acquire) == 1) { js_free(j_calls->get_est_sat_per_1000_weight_meth); FREE(j_calls); } } uint32_t get_est_sat_per_1000_weight_LDKFeeEstimator_jcall(const void* this_arg, LDKConfirmationTarget confirmation_target) { LDKFeeEstimator_JCalls *j_calls = (LDKFeeEstimator_JCalls*) this_arg; uint32_t confirmation_target_conv = LDKConfirmationTarget_to_js(confirmation_target); return js_invoke_function_1(j_calls->get_est_sat_per_1000_weight_meth, confirmation_target_conv); } static void LDKFeeEstimator_JCalls_cloned(LDKFeeEstimator* new_obj) { LDKFeeEstimator_JCalls *j_calls = (LDKFeeEstimator_JCalls*) new_obj->this_arg; atomic_fetch_add_explicit(&j_calls->refcnt, 1, memory_order_release); } static inline LDKFeeEstimator LDKFeeEstimator_init (/*TODO: JS Object Reference */void* o) { LDKFeeEstimator_JCalls *calls = MALLOC(sizeof(LDKFeeEstimator_JCalls), "LDKFeeEstimator_JCalls"); atomic_init(&calls->refcnt, 1); //TODO: Assign calls->o from o LDKFeeEstimator ret = { .this_arg = (void*) calls, .get_est_sat_per_1000_weight = get_est_sat_per_1000_weight_LDKFeeEstimator_jcall, .free = LDKFeeEstimator_JCalls_free, }; return ret; } long __attribute__((visibility("default"))) TS_LDKFeeEstimator_new(/*TODO: JS Object Reference */void* o) { LDKFeeEstimator *res_ptr = MALLOC(sizeof(LDKFeeEstimator), "LDKFeeEstimator"); *res_ptr = LDKFeeEstimator_init(o); return (long)res_ptr; } int32_t __attribute__((visibility("default"))) TS_FeeEstimator_get_est_sat_per_1000_weight(uint32_t this_arg, uint32_t confirmation_target) { LDKFeeEstimator* this_arg_conv = (LDKFeeEstimator*)(((uint64_t)this_arg) & ~1); LDKConfirmationTarget confirmation_target_conv = LDKConfirmationTarget_from_js(confirmation_target); int32_t ret_val = (this_arg_conv->get_est_sat_per_1000_weight)(this_arg_conv->this_arg, confirmation_target_conv); return ret_val; } typedef struct LDKLogger_JCalls { atomic_size_t refcnt; uint32_t log_meth; } LDKLogger_JCalls; static void LDKLogger_JCalls_free(void* this_arg) { LDKLogger_JCalls *j_calls = (LDKLogger_JCalls*) this_arg; if (atomic_fetch_sub_explicit(&j_calls->refcnt, 1, memory_order_acquire) == 1) { js_free(j_calls->log_meth); FREE(j_calls); } } void log_LDKLogger_jcall(const void* this_arg, const char* record) { LDKLogger_JCalls *j_calls = (LDKLogger_JCalls*) this_arg; const char* record_str = record; jstring record_conv = str_ref_to_ts(record_str, strlen(record_str)); js_invoke_function_1(j_calls->log_meth, record_conv); } static void LDKLogger_JCalls_cloned(LDKLogger* new_obj) { LDKLogger_JCalls *j_calls = (LDKLogger_JCalls*) new_obj->this_arg; atomic_fetch_add_explicit(&j_calls->refcnt, 1, memory_order_release); } static inline LDKLogger LDKLogger_init (/*TODO: JS Object Reference */void* o) { LDKLogger_JCalls *calls = MALLOC(sizeof(LDKLogger_JCalls), "LDKLogger_JCalls"); atomic_init(&calls->refcnt, 1); //TODO: Assign calls->o from o LDKLogger ret = { .this_arg = (void*) calls, .log = log_LDKLogger_jcall, .free = LDKLogger_JCalls_free, }; return ret; } long __attribute__((visibility("default"))) TS_LDKLogger_new(/*TODO: JS Object Reference */void* o) { LDKLogger *res_ptr = MALLOC(sizeof(LDKLogger), "LDKLogger"); *res_ptr = LDKLogger_init(o); return (long)res_ptr; } uint32_t __attribute__((visibility("default"))) TS_LDKC2Tuple_BlockHashChannelManagerZ_new(int8_tArray a, uint32_t b) { LDKC2Tuple_BlockHashChannelManagerZ* ret = MALLOC(sizeof(LDKC2Tuple_BlockHashChannelManagerZ), "LDKC2Tuple_BlockHashChannelManagerZ"); LDKThirtyTwoBytes a_ref; CHECK(*((uint32_t*)a) == 32); memcpy(a_ref.data, (uint8_t*)(a + 4), 32); ret->a = a_ref; LDKChannelManager b_conv; b_conv.inner = (void*)(b & (~1)); b_conv.is_owned = (b & 1) || (b == 0); // Warning: we need a move here but no clone is available for LDKChannelManager ret->b = b_conv; return (uint64_t)ret; } int8_tArray __attribute__((visibility("default"))) TS_LDKC2Tuple_BlockHashChannelManagerZ_get_a(uint32_t ptr) { LDKC2Tuple_BlockHashChannelManagerZ *tuple = (LDKC2Tuple_BlockHashChannelManagerZ*)(ptr & ~1); int8_tArray a_arr = init_arr(32, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(a_arr + 4), tuple->a.data, 32); return a_arr; } uint32_t __attribute__((visibility("default"))) TS_LDKC2Tuple_BlockHashChannelManagerZ_get_b(uint32_t ptr) { LDKC2Tuple_BlockHashChannelManagerZ *tuple = (LDKC2Tuple_BlockHashChannelManagerZ*)(ptr & ~1); LDKChannelManager b_var = tuple->b; CHECK((((uint64_t)b_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&b_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t b_ref = (uint64_t)b_var.inner & ~1; return b_ref; } jboolean __attribute__((visibility("default"))) TS_LDKCResult_C2Tuple_BlockHashChannelManagerZDecodeErrorZ_result_ok(uint32_t arg) { return ((LDKCResult_C2Tuple_BlockHashChannelManagerZDecodeErrorZ*)arg)->result_ok; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_C2Tuple_BlockHashChannelManagerZDecodeErrorZ_get_ok(uint32_t arg) { LDKCResult_C2Tuple_BlockHashChannelManagerZDecodeErrorZ *val = (LDKCResult_C2Tuple_BlockHashChannelManagerZDecodeErrorZ*)(arg & ~1); CHECK(val->result_ok); uint64_t res_ref = (uint64_t)(&(*val->contents.result)) | 1; return res_ref; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_C2Tuple_BlockHashChannelManagerZDecodeErrorZ_get_err(uint32_t arg) { LDKCResult_C2Tuple_BlockHashChannelManagerZDecodeErrorZ *val = (LDKCResult_C2Tuple_BlockHashChannelManagerZDecodeErrorZ*)(arg & ~1); CHECK(!val->result_ok); LDKDecodeError err_var = (*val->contents.err); CHECK((((uint64_t)err_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&err_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t err_ref = (uint64_t)err_var.inner & ~1; return err_ref; } jboolean __attribute__((visibility("default"))) TS_LDKCResult_ChannelConfigDecodeErrorZ_result_ok(uint32_t arg) { return ((LDKCResult_ChannelConfigDecodeErrorZ*)arg)->result_ok; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_ChannelConfigDecodeErrorZ_get_ok(uint32_t arg) { LDKCResult_ChannelConfigDecodeErrorZ *val = (LDKCResult_ChannelConfigDecodeErrorZ*)(arg & ~1); CHECK(val->result_ok); LDKChannelConfig res_var = (*val->contents.result); CHECK((((uint64_t)res_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&res_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t res_ref = (uint64_t)res_var.inner & ~1; return res_ref; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_ChannelConfigDecodeErrorZ_get_err(uint32_t arg) { LDKCResult_ChannelConfigDecodeErrorZ *val = (LDKCResult_ChannelConfigDecodeErrorZ*)(arg & ~1); CHECK(!val->result_ok); LDKDecodeError err_var = (*val->contents.err); CHECK((((uint64_t)err_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&err_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t err_ref = (uint64_t)err_var.inner & ~1; return err_ref; } jboolean __attribute__((visibility("default"))) TS_LDKCResult_OutPointDecodeErrorZ_result_ok(uint32_t arg) { return ((LDKCResult_OutPointDecodeErrorZ*)arg)->result_ok; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_OutPointDecodeErrorZ_get_ok(uint32_t arg) { LDKCResult_OutPointDecodeErrorZ *val = (LDKCResult_OutPointDecodeErrorZ*)(arg & ~1); CHECK(val->result_ok); LDKOutPoint res_var = (*val->contents.result); CHECK((((uint64_t)res_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&res_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t res_ref = (uint64_t)res_var.inner & ~1; return res_ref; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_OutPointDecodeErrorZ_get_err(uint32_t arg) { LDKCResult_OutPointDecodeErrorZ *val = (LDKCResult_OutPointDecodeErrorZ*)(arg & ~1); CHECK(!val->result_ok); LDKDecodeError err_var = (*val->contents.err); CHECK((((uint64_t)err_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&err_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t err_ref = (uint64_t)err_var.inner & ~1; return err_ref; } typedef struct LDKType_JCalls { atomic_size_t refcnt; uint32_t type_id_meth; uint32_t debug_str_meth; uint32_t write_meth; } LDKType_JCalls; static void LDKType_JCalls_free(void* this_arg) { LDKType_JCalls *j_calls = (LDKType_JCalls*) this_arg; if (atomic_fetch_sub_explicit(&j_calls->refcnt, 1, memory_order_acquire) == 1) { js_free(j_calls->type_id_meth); js_free(j_calls->debug_str_meth); js_free(j_calls->write_meth); FREE(j_calls); } } uint16_t type_id_LDKType_jcall(const void* this_arg) { LDKType_JCalls *j_calls = (LDKType_JCalls*) this_arg; return js_invoke_function_0(j_calls->type_id_meth); } LDKStr debug_str_LDKType_jcall(const void* this_arg) { LDKType_JCalls *j_calls = (LDKType_JCalls*) this_arg; uint32_t ret = js_invoke_function_0(j_calls->debug_str_meth); LDKStr ret_conv = str_ref_to_owned_c(ret); return ret_conv; } LDKCVec_u8Z write_LDKType_jcall(const void* this_arg) { LDKType_JCalls *j_calls = (LDKType_JCalls*) this_arg; int8_tArray ret = js_invoke_function_0(j_calls->write_meth); LDKCVec_u8Z ret_ref; ret_ref.datalen = *((uint32_t*)ret); ret_ref.data = MALLOC(ret_ref.datalen, "LDKCVec_u8Z Bytes"); memcpy(ret_ref.data, (uint8_t*)(ret + 4), ret_ref.datalen); return ret_ref; } static void LDKType_JCalls_cloned(LDKType* new_obj) { LDKType_JCalls *j_calls = (LDKType_JCalls*) new_obj->this_arg; atomic_fetch_add_explicit(&j_calls->refcnt, 1, memory_order_release); } static inline LDKType LDKType_init (/*TODO: JS Object Reference */void* o) { LDKType_JCalls *calls = MALLOC(sizeof(LDKType_JCalls), "LDKType_JCalls"); atomic_init(&calls->refcnt, 1); //TODO: Assign calls->o from o LDKType ret = { .this_arg = (void*) calls, .type_id = type_id_LDKType_jcall, .debug_str = debug_str_LDKType_jcall, .write = write_LDKType_jcall, .cloned = LDKType_JCalls_cloned, .free = LDKType_JCalls_free, }; return ret; } long __attribute__((visibility("default"))) TS_LDKType_new(/*TODO: JS Object Reference */void* o) { LDKType *res_ptr = MALLOC(sizeof(LDKType), "LDKType"); *res_ptr = LDKType_init(o); return (long)res_ptr; } int16_t __attribute__((visibility("default"))) TS_Type_type_id(uint32_t this_arg) { LDKType* this_arg_conv = (LDKType*)(((uint64_t)this_arg) & ~1); int16_t ret_val = (this_arg_conv->type_id)(this_arg_conv->this_arg); return ret_val; } jstring __attribute__((visibility("default"))) TS_Type_debug_str(uint32_t this_arg) { LDKType* this_arg_conv = (LDKType*)(((uint64_t)this_arg) & ~1); LDKStr ret_str = (this_arg_conv->debug_str)(this_arg_conv->this_arg); jstring ret_conv = str_ref_to_ts(ret_str.chars, ret_str.len); Str_free(ret_str); return ret_conv; } int8_tArray __attribute__((visibility("default"))) TS_Type_write(uint32_t this_arg) { LDKType* this_arg_conv = (LDKType*)(((uint64_t)this_arg) & ~1); LDKCVec_u8Z ret_var = (this_arg_conv->write)(this_arg_conv->this_arg); int8_tArray ret_arr = init_arr(ret_var.datalen, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), ret_var.data, ret_var.datalen); CVec_u8Z_free(ret_var); return ret_arr; } uint32_t __attribute__((visibility("default"))) TS_LDKCOption_TypeZ_ref_from_ptr(uint32_t ptr) { LDKCOption_TypeZ *obj = (LDKCOption_TypeZ*)(ptr & ~1); switch(obj->tag) { case LDKCOption_TypeZ_Some: { LDKType* some_ret =MALLOC(sizeof(LDKType), "LDKType"); *some_ret = Type_clone(&obj->some); return 0 /* LDKCOption_TypeZ - Some */; (void) (uint64_t)some_ret; } case LDKCOption_TypeZ_None: { return 0 /* LDKCOption_TypeZ - None */; } default: abort(); } } jboolean __attribute__((visibility("default"))) TS_LDKCResult_COption_TypeZDecodeErrorZ_result_ok(uint32_t arg) { return ((LDKCResult_COption_TypeZDecodeErrorZ*)arg)->result_ok; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_COption_TypeZDecodeErrorZ_get_ok(uint32_t arg) { LDKCResult_COption_TypeZDecodeErrorZ *val = (LDKCResult_COption_TypeZDecodeErrorZ*)(arg & ~1); CHECK(val->result_ok); uint64_t res_ref = ((uint64_t)&(*val->contents.result)) | 1; return res_ref; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_COption_TypeZDecodeErrorZ_get_err(uint32_t arg) { LDKCResult_COption_TypeZDecodeErrorZ *val = (LDKCResult_COption_TypeZDecodeErrorZ*)(arg & ~1); CHECK(!val->result_ok); LDKDecodeError err_var = (*val->contents.err); CHECK((((uint64_t)err_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&err_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t err_ref = (uint64_t)err_var.inner & ~1; return err_ref; } jboolean __attribute__((visibility("default"))) TS_LDKCResult_SiPrefixNoneZ_result_ok(uint32_t arg) { return ((LDKCResult_SiPrefixNoneZ*)arg)->result_ok; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_SiPrefixNoneZ_get_ok(uint32_t arg) { LDKCResult_SiPrefixNoneZ *val = (LDKCResult_SiPrefixNoneZ*)(arg & ~1); CHECK(val->result_ok); uint32_t res_conv = LDKSiPrefix_to_js((*val->contents.result)); return res_conv; } void __attribute__((visibility("default"))) TS_LDKCResult_SiPrefixNoneZ_get_err(uint32_t arg) { LDKCResult_SiPrefixNoneZ *val = (LDKCResult_SiPrefixNoneZ*)(arg & ~1); CHECK(!val->result_ok); return *val->contents.err; } jboolean __attribute__((visibility("default"))) TS_LDKCResult_InvoiceNoneZ_result_ok(uint32_t arg) { return ((LDKCResult_InvoiceNoneZ*)arg)->result_ok; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_InvoiceNoneZ_get_ok(uint32_t arg) { LDKCResult_InvoiceNoneZ *val = (LDKCResult_InvoiceNoneZ*)(arg & ~1); CHECK(val->result_ok); LDKInvoice res_var = (*val->contents.result); CHECK((((uint64_t)res_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&res_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t res_ref = (uint64_t)res_var.inner & ~1; return res_ref; } void __attribute__((visibility("default"))) TS_LDKCResult_InvoiceNoneZ_get_err(uint32_t arg) { LDKCResult_InvoiceNoneZ *val = (LDKCResult_InvoiceNoneZ*)(arg & ~1); CHECK(!val->result_ok); return *val->contents.err; } jboolean __attribute__((visibility("default"))) TS_LDKCResult_SignedRawInvoiceNoneZ_result_ok(uint32_t arg) { return ((LDKCResult_SignedRawInvoiceNoneZ*)arg)->result_ok; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_SignedRawInvoiceNoneZ_get_ok(uint32_t arg) { LDKCResult_SignedRawInvoiceNoneZ *val = (LDKCResult_SignedRawInvoiceNoneZ*)(arg & ~1); CHECK(val->result_ok); LDKSignedRawInvoice res_var = (*val->contents.result); CHECK((((uint64_t)res_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&res_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t res_ref = (uint64_t)res_var.inner & ~1; return res_ref; } void __attribute__((visibility("default"))) TS_LDKCResult_SignedRawInvoiceNoneZ_get_err(uint32_t arg) { LDKCResult_SignedRawInvoiceNoneZ *val = (LDKCResult_SignedRawInvoiceNoneZ*)(arg & ~1); CHECK(!val->result_ok); return *val->contents.err; } uint32_t __attribute__((visibility("default"))) TS_LDKC3Tuple_RawInvoice_u832InvoiceSignatureZ_new(uint32_t a, int8_tArray b, uint32_t c) { LDKC3Tuple_RawInvoice_u832InvoiceSignatureZ* ret = MALLOC(sizeof(LDKC3Tuple_RawInvoice_u832InvoiceSignatureZ), "LDKC3Tuple_RawInvoice_u832InvoiceSignatureZ"); LDKRawInvoice a_conv; a_conv.inner = (void*)(a & (~1)); a_conv.is_owned = (a & 1) || (a == 0); a_conv = RawInvoice_clone(&a_conv); ret->a = a_conv; LDKThirtyTwoBytes b_ref; CHECK(*((uint32_t*)b) == 32); memcpy(b_ref.data, (uint8_t*)(b + 4), 32); ret->b = b_ref; LDKInvoiceSignature c_conv; c_conv.inner = (void*)(c & (~1)); c_conv.is_owned = (c & 1) || (c == 0); c_conv = InvoiceSignature_clone(&c_conv); ret->c = c_conv; return (uint64_t)ret; } uint32_t __attribute__((visibility("default"))) TS_LDKC3Tuple_RawInvoice_u832InvoiceSignatureZ_get_a(uint32_t ptr) { LDKC3Tuple_RawInvoice_u832InvoiceSignatureZ *tuple = (LDKC3Tuple_RawInvoice_u832InvoiceSignatureZ*)(ptr & ~1); LDKRawInvoice a_var = tuple->a; CHECK((((uint64_t)a_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&a_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t a_ref = (uint64_t)a_var.inner & ~1; return a_ref; } int8_tArray __attribute__((visibility("default"))) TS_LDKC3Tuple_RawInvoice_u832InvoiceSignatureZ_get_b(uint32_t ptr) { LDKC3Tuple_RawInvoice_u832InvoiceSignatureZ *tuple = (LDKC3Tuple_RawInvoice_u832InvoiceSignatureZ*)(ptr & ~1); int8_tArray b_arr = init_arr(32, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(b_arr + 4), tuple->b.data, 32); return b_arr; } uint32_t __attribute__((visibility("default"))) TS_LDKC3Tuple_RawInvoice_u832InvoiceSignatureZ_get_c(uint32_t ptr) { LDKC3Tuple_RawInvoice_u832InvoiceSignatureZ *tuple = (LDKC3Tuple_RawInvoice_u832InvoiceSignatureZ*)(ptr & ~1); LDKInvoiceSignature c_var = tuple->c; CHECK((((uint64_t)c_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&c_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t c_ref = (uint64_t)c_var.inner & ~1; return c_ref; } jboolean __attribute__((visibility("default"))) TS_LDKCResult_PayeePubKeyErrorZ_result_ok(uint32_t arg) { return ((LDKCResult_PayeePubKeyErrorZ*)arg)->result_ok; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_PayeePubKeyErrorZ_get_ok(uint32_t arg) { LDKCResult_PayeePubKeyErrorZ *val = (LDKCResult_PayeePubKeyErrorZ*)(arg & ~1); CHECK(val->result_ok); LDKPayeePubKey res_var = (*val->contents.result); CHECK((((uint64_t)res_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&res_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t res_ref = (uint64_t)res_var.inner & ~1; return res_ref; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_PayeePubKeyErrorZ_get_err(uint32_t arg) { LDKCResult_PayeePubKeyErrorZ *val = (LDKCResult_PayeePubKeyErrorZ*)(arg & ~1); CHECK(!val->result_ok); uint32_t err_conv = LDKSecp256k1Error_to_js((*val->contents.err)); return err_conv; } uint32_t __attribute__((visibility("default"))) TS_LDKCVec_PrivateRouteZ_new(uint32_tArray elems) { LDKCVec_PrivateRouteZ *ret = MALLOC(sizeof(LDKCVec_PrivateRouteZ), "LDKCVec_PrivateRouteZ"); ret->datalen = *((uint32_t*)elems); if (ret->datalen == 0) { ret->data = NULL; } else { ret->data = MALLOC(sizeof(LDKPrivateRoute) * ret->datalen, "LDKCVec_PrivateRouteZ Data"); uint32_t *java_elems = (uint32_t*)(elems + 4); for (size_t i = 0; i < ret->datalen; i++) { uint32_t arr_elem = java_elems[i]; LDKPrivateRoute arr_elem_conv; arr_elem_conv.inner = (void*)(arr_elem & (~1)); arr_elem_conv.is_owned = (arr_elem & 1) || (arr_elem == 0); arr_elem_conv = PrivateRoute_clone(&arr_elem_conv); ret->data[i] = arr_elem_conv; } } return (uint64_t)ret; } static inline LDKCVec_PrivateRouteZ CVec_PrivateRouteZ_clone(const LDKCVec_PrivateRouteZ *orig) { LDKCVec_PrivateRouteZ ret = { .data = MALLOC(sizeof(LDKPrivateRoute) * orig->datalen, "LDKCVec_PrivateRouteZ clone bytes"), .datalen = orig->datalen }; for (size_t i = 0; i < ret.datalen; i++) { ret.data[i] = PrivateRoute_clone(&orig->data[i]); } return ret; } jboolean __attribute__((visibility("default"))) TS_LDKCResult_PositiveTimestampCreationErrorZ_result_ok(uint32_t arg) { return ((LDKCResult_PositiveTimestampCreationErrorZ*)arg)->result_ok; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_PositiveTimestampCreationErrorZ_get_ok(uint32_t arg) { LDKCResult_PositiveTimestampCreationErrorZ *val = (LDKCResult_PositiveTimestampCreationErrorZ*)(arg & ~1); CHECK(val->result_ok); LDKPositiveTimestamp res_var = (*val->contents.result); CHECK((((uint64_t)res_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&res_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t res_ref = (uint64_t)res_var.inner & ~1; return res_ref; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_PositiveTimestampCreationErrorZ_get_err(uint32_t arg) { LDKCResult_PositiveTimestampCreationErrorZ *val = (LDKCResult_PositiveTimestampCreationErrorZ*)(arg & ~1); CHECK(!val->result_ok); uint32_t err_conv = LDKCreationError_to_js((*val->contents.err)); return err_conv; } jboolean __attribute__((visibility("default"))) TS_LDKCResult_NoneSemanticErrorZ_result_ok(uint32_t arg) { return ((LDKCResult_NoneSemanticErrorZ*)arg)->result_ok; } void __attribute__((visibility("default"))) TS_LDKCResult_NoneSemanticErrorZ_get_ok(uint32_t arg) { LDKCResult_NoneSemanticErrorZ *val = (LDKCResult_NoneSemanticErrorZ*)(arg & ~1); CHECK(val->result_ok); return *val->contents.result; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_NoneSemanticErrorZ_get_err(uint32_t arg) { LDKCResult_NoneSemanticErrorZ *val = (LDKCResult_NoneSemanticErrorZ*)(arg & ~1); CHECK(!val->result_ok); uint32_t err_conv = LDKSemanticError_to_js((*val->contents.err)); return err_conv; } jboolean __attribute__((visibility("default"))) TS_LDKCResult_InvoiceSemanticErrorZ_result_ok(uint32_t arg) { return ((LDKCResult_InvoiceSemanticErrorZ*)arg)->result_ok; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_InvoiceSemanticErrorZ_get_ok(uint32_t arg) { LDKCResult_InvoiceSemanticErrorZ *val = (LDKCResult_InvoiceSemanticErrorZ*)(arg & ~1); CHECK(val->result_ok); LDKInvoice res_var = (*val->contents.result); CHECK((((uint64_t)res_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&res_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t res_ref = (uint64_t)res_var.inner & ~1; return res_ref; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_InvoiceSemanticErrorZ_get_err(uint32_t arg) { LDKCResult_InvoiceSemanticErrorZ *val = (LDKCResult_InvoiceSemanticErrorZ*)(arg & ~1); CHECK(!val->result_ok); uint32_t err_conv = LDKSemanticError_to_js((*val->contents.err)); return err_conv; } jboolean __attribute__((visibility("default"))) TS_LDKCResult_DescriptionCreationErrorZ_result_ok(uint32_t arg) { return ((LDKCResult_DescriptionCreationErrorZ*)arg)->result_ok; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_DescriptionCreationErrorZ_get_ok(uint32_t arg) { LDKCResult_DescriptionCreationErrorZ *val = (LDKCResult_DescriptionCreationErrorZ*)(arg & ~1); CHECK(val->result_ok); LDKDescription res_var = (*val->contents.result); CHECK((((uint64_t)res_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&res_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t res_ref = (uint64_t)res_var.inner & ~1; return res_ref; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_DescriptionCreationErrorZ_get_err(uint32_t arg) { LDKCResult_DescriptionCreationErrorZ *val = (LDKCResult_DescriptionCreationErrorZ*)(arg & ~1); CHECK(!val->result_ok); uint32_t err_conv = LDKCreationError_to_js((*val->contents.err)); return err_conv; } jboolean __attribute__((visibility("default"))) TS_LDKCResult_ExpiryTimeCreationErrorZ_result_ok(uint32_t arg) { return ((LDKCResult_ExpiryTimeCreationErrorZ*)arg)->result_ok; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_ExpiryTimeCreationErrorZ_get_ok(uint32_t arg) { LDKCResult_ExpiryTimeCreationErrorZ *val = (LDKCResult_ExpiryTimeCreationErrorZ*)(arg & ~1); CHECK(val->result_ok); LDKExpiryTime res_var = (*val->contents.result); CHECK((((uint64_t)res_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&res_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t res_ref = (uint64_t)res_var.inner & ~1; return res_ref; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_ExpiryTimeCreationErrorZ_get_err(uint32_t arg) { LDKCResult_ExpiryTimeCreationErrorZ *val = (LDKCResult_ExpiryTimeCreationErrorZ*)(arg & ~1); CHECK(!val->result_ok); uint32_t err_conv = LDKCreationError_to_js((*val->contents.err)); return err_conv; } jboolean __attribute__((visibility("default"))) TS_LDKCResult_PrivateRouteCreationErrorZ_result_ok(uint32_t arg) { return ((LDKCResult_PrivateRouteCreationErrorZ*)arg)->result_ok; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_PrivateRouteCreationErrorZ_get_ok(uint32_t arg) { LDKCResult_PrivateRouteCreationErrorZ *val = (LDKCResult_PrivateRouteCreationErrorZ*)(arg & ~1); CHECK(val->result_ok); LDKPrivateRoute res_var = (*val->contents.result); CHECK((((uint64_t)res_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&res_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t res_ref = (uint64_t)res_var.inner & ~1; return res_ref; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_PrivateRouteCreationErrorZ_get_err(uint32_t arg) { LDKCResult_PrivateRouteCreationErrorZ *val = (LDKCResult_PrivateRouteCreationErrorZ*)(arg & ~1); CHECK(!val->result_ok); uint32_t err_conv = LDKCreationError_to_js((*val->contents.err)); return err_conv; } jboolean __attribute__((visibility("default"))) TS_LDKCResult_StringErrorZ_result_ok(uint32_t arg) { return ((LDKCResult_StringErrorZ*)arg)->result_ok; } jstring __attribute__((visibility("default"))) TS_LDKCResult_StringErrorZ_get_ok(uint32_t arg) { LDKCResult_StringErrorZ *val = (LDKCResult_StringErrorZ*)(arg & ~1); CHECK(val->result_ok); LDKStr res_str = (*val->contents.result); jstring res_conv = str_ref_to_ts(res_str.chars, res_str.len); return res_conv; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_StringErrorZ_get_err(uint32_t arg) { LDKCResult_StringErrorZ *val = (LDKCResult_StringErrorZ*)(arg & ~1); CHECK(!val->result_ok); uint32_t err_conv = LDKSecp256k1Error_to_js((*val->contents.err)); return err_conv; } jboolean __attribute__((visibility("default"))) TS_LDKCResult_ChannelMonitorUpdateDecodeErrorZ_result_ok(uint32_t arg) { return ((LDKCResult_ChannelMonitorUpdateDecodeErrorZ*)arg)->result_ok; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_ChannelMonitorUpdateDecodeErrorZ_get_ok(uint32_t arg) { LDKCResult_ChannelMonitorUpdateDecodeErrorZ *val = (LDKCResult_ChannelMonitorUpdateDecodeErrorZ*)(arg & ~1); CHECK(val->result_ok); LDKChannelMonitorUpdate res_var = (*val->contents.result); CHECK((((uint64_t)res_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&res_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t res_ref = (uint64_t)res_var.inner & ~1; return res_ref; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_ChannelMonitorUpdateDecodeErrorZ_get_err(uint32_t arg) { LDKCResult_ChannelMonitorUpdateDecodeErrorZ *val = (LDKCResult_ChannelMonitorUpdateDecodeErrorZ*)(arg & ~1); CHECK(!val->result_ok); LDKDecodeError err_var = (*val->contents.err); CHECK((((uint64_t)err_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&err_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t err_ref = (uint64_t)err_var.inner & ~1; return err_ref; } jboolean __attribute__((visibility("default"))) TS_LDKCResult_HTLCUpdateDecodeErrorZ_result_ok(uint32_t arg) { return ((LDKCResult_HTLCUpdateDecodeErrorZ*)arg)->result_ok; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_HTLCUpdateDecodeErrorZ_get_ok(uint32_t arg) { LDKCResult_HTLCUpdateDecodeErrorZ *val = (LDKCResult_HTLCUpdateDecodeErrorZ*)(arg & ~1); CHECK(val->result_ok); LDKHTLCUpdate res_var = (*val->contents.result); CHECK((((uint64_t)res_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&res_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t res_ref = (uint64_t)res_var.inner & ~1; return res_ref; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_HTLCUpdateDecodeErrorZ_get_err(uint32_t arg) { LDKCResult_HTLCUpdateDecodeErrorZ *val = (LDKCResult_HTLCUpdateDecodeErrorZ*)(arg & ~1); CHECK(!val->result_ok); LDKDecodeError err_var = (*val->contents.err); CHECK((((uint64_t)err_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&err_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t err_ref = (uint64_t)err_var.inner & ~1; return err_ref; } jboolean __attribute__((visibility("default"))) TS_LDKCResult_NoneMonitorUpdateErrorZ_result_ok(uint32_t arg) { return ((LDKCResult_NoneMonitorUpdateErrorZ*)arg)->result_ok; } void __attribute__((visibility("default"))) TS_LDKCResult_NoneMonitorUpdateErrorZ_get_ok(uint32_t arg) { LDKCResult_NoneMonitorUpdateErrorZ *val = (LDKCResult_NoneMonitorUpdateErrorZ*)(arg & ~1); CHECK(val->result_ok); return *val->contents.result; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_NoneMonitorUpdateErrorZ_get_err(uint32_t arg) { LDKCResult_NoneMonitorUpdateErrorZ *val = (LDKCResult_NoneMonitorUpdateErrorZ*)(arg & ~1); CHECK(!val->result_ok); LDKMonitorUpdateError err_var = (*val->contents.err); CHECK((((uint64_t)err_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&err_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t err_ref = (uint64_t)err_var.inner & ~1; return err_ref; } uint32_t __attribute__((visibility("default"))) TS_LDKC2Tuple_OutPointScriptZ_new(uint32_t a, int8_tArray b) { LDKC2Tuple_OutPointScriptZ* ret = MALLOC(sizeof(LDKC2Tuple_OutPointScriptZ), "LDKC2Tuple_OutPointScriptZ"); LDKOutPoint a_conv; a_conv.inner = (void*)(a & (~1)); a_conv.is_owned = (a & 1) || (a == 0); a_conv = OutPoint_clone(&a_conv); ret->a = a_conv; LDKCVec_u8Z b_ref; b_ref.datalen = *((uint32_t*)b); b_ref.data = MALLOC(b_ref.datalen, "LDKCVec_u8Z Bytes"); memcpy(b_ref.data, (uint8_t*)(b + 4), b_ref.datalen); ret->b = b_ref; return (uint64_t)ret; } uint32_t __attribute__((visibility("default"))) TS_LDKC2Tuple_OutPointScriptZ_get_a(uint32_t ptr) { LDKC2Tuple_OutPointScriptZ *tuple = (LDKC2Tuple_OutPointScriptZ*)(ptr & ~1); LDKOutPoint a_var = tuple->a; CHECK((((uint64_t)a_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&a_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t a_ref = (uint64_t)a_var.inner & ~1; return a_ref; } int8_tArray __attribute__((visibility("default"))) TS_LDKC2Tuple_OutPointScriptZ_get_b(uint32_t ptr) { LDKC2Tuple_OutPointScriptZ *tuple = (LDKC2Tuple_OutPointScriptZ*)(ptr & ~1); LDKCVec_u8Z b_var = tuple->b; int8_tArray b_arr = init_arr(b_var.datalen, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(b_arr + 4), b_var.data, b_var.datalen); return b_arr; } uint32_t __attribute__((visibility("default"))) TS_LDKC2Tuple_u32ScriptZ_new(int32_t a, int8_tArray b) { LDKC2Tuple_u32ScriptZ* ret = MALLOC(sizeof(LDKC2Tuple_u32ScriptZ), "LDKC2Tuple_u32ScriptZ"); ret->a = a; LDKCVec_u8Z b_ref; b_ref.datalen = *((uint32_t*)b); b_ref.data = MALLOC(b_ref.datalen, "LDKCVec_u8Z Bytes"); memcpy(b_ref.data, (uint8_t*)(b + 4), b_ref.datalen); ret->b = b_ref; return (uint64_t)ret; } int32_t __attribute__((visibility("default"))) TS_LDKC2Tuple_u32ScriptZ_get_a(uint32_t ptr) { LDKC2Tuple_u32ScriptZ *tuple = (LDKC2Tuple_u32ScriptZ*)(ptr & ~1); return tuple->a; } int8_tArray __attribute__((visibility("default"))) TS_LDKC2Tuple_u32ScriptZ_get_b(uint32_t ptr) { LDKC2Tuple_u32ScriptZ *tuple = (LDKC2Tuple_u32ScriptZ*)(ptr & ~1); LDKCVec_u8Z b_var = tuple->b; int8_tArray b_arr = init_arr(b_var.datalen, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(b_arr + 4), b_var.data, b_var.datalen); return b_arr; } uint32_t __attribute__((visibility("default"))) TS_LDKCVec_C2Tuple_u32ScriptZZ_new(uint32_tArray elems) { LDKCVec_C2Tuple_u32ScriptZZ *ret = MALLOC(sizeof(LDKCVec_C2Tuple_u32ScriptZZ), "LDKCVec_C2Tuple_u32ScriptZZ"); ret->datalen = *((uint32_t*)elems); if (ret->datalen == 0) { ret->data = NULL; } else { ret->data = MALLOC(sizeof(LDKC2Tuple_u32ScriptZ) * ret->datalen, "LDKCVec_C2Tuple_u32ScriptZZ Data"); uint32_t *java_elems = (uint32_t*)(elems + 4); for (size_t i = 0; i < ret->datalen; i++) { uint32_t arr_elem = java_elems[i]; LDKC2Tuple_u32ScriptZ arr_elem_conv = *(LDKC2Tuple_u32ScriptZ*)(((uint64_t)arr_elem) & ~1); arr_elem_conv = C2Tuple_u32ScriptZ_clone((LDKC2Tuple_u32ScriptZ*)(((uint64_t)arr_elem) & ~1)); ret->data[i] = arr_elem_conv; } } return (uint64_t)ret; } static inline LDKCVec_C2Tuple_u32ScriptZZ CVec_C2Tuple_u32ScriptZZ_clone(const LDKCVec_C2Tuple_u32ScriptZZ *orig) { LDKCVec_C2Tuple_u32ScriptZZ ret = { .data = MALLOC(sizeof(LDKC2Tuple_u32ScriptZ) * orig->datalen, "LDKCVec_C2Tuple_u32ScriptZZ clone bytes"), .datalen = orig->datalen }; for (size_t i = 0; i < ret.datalen; i++) { ret.data[i] = C2Tuple_u32ScriptZ_clone(&orig->data[i]); } return ret; } uint32_t __attribute__((visibility("default"))) TS_LDKC2Tuple_TxidCVec_C2Tuple_u32ScriptZZZ_new(int8_tArray a, uint32_tArray b) { LDKC2Tuple_TxidCVec_C2Tuple_u32ScriptZZZ* ret = MALLOC(sizeof(LDKC2Tuple_TxidCVec_C2Tuple_u32ScriptZZZ), "LDKC2Tuple_TxidCVec_C2Tuple_u32ScriptZZZ"); LDKThirtyTwoBytes a_ref; CHECK(*((uint32_t*)a) == 32); memcpy(a_ref.data, (uint8_t*)(a + 4), 32); ret->a = a_ref; LDKCVec_C2Tuple_u32ScriptZZ b_constr; b_constr.datalen = *((uint32_t*)b); if (b_constr.datalen > 0) b_constr.data = MALLOC(b_constr.datalen * sizeof(LDKC2Tuple_u32ScriptZ), "LDKCVec_C2Tuple_u32ScriptZZ Elements"); else b_constr.data = NULL; uint32_t* b_vals = (uint32_t*)(b + 4); for (size_t e = 0; e < b_constr.datalen; e++) { uint32_t b_conv_30 = b_vals[e]; LDKC2Tuple_u32ScriptZ b_conv_30_conv = *(LDKC2Tuple_u32ScriptZ*)(((uint64_t)b_conv_30) & ~1); b_conv_30_conv = C2Tuple_u32ScriptZ_clone((LDKC2Tuple_u32ScriptZ*)(((uint64_t)b_conv_30) & ~1)); b_constr.data[e] = b_conv_30_conv; } ret->b = b_constr; return (uint64_t)ret; } int8_tArray __attribute__((visibility("default"))) TS_LDKC2Tuple_TxidCVec_C2Tuple_u32ScriptZZZ_get_a(uint32_t ptr) { LDKC2Tuple_TxidCVec_C2Tuple_u32ScriptZZZ *tuple = (LDKC2Tuple_TxidCVec_C2Tuple_u32ScriptZZZ*)(ptr & ~1); int8_tArray a_arr = init_arr(32, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(a_arr + 4), tuple->a.data, 32); return a_arr; } uint32_tArray __attribute__((visibility("default"))) TS_LDKC2Tuple_TxidCVec_C2Tuple_u32ScriptZZZ_get_b(uint32_t ptr) { LDKC2Tuple_TxidCVec_C2Tuple_u32ScriptZZZ *tuple = (LDKC2Tuple_TxidCVec_C2Tuple_u32ScriptZZZ*)(ptr & ~1); LDKCVec_C2Tuple_u32ScriptZZ b_var = tuple->b; uint32_tArray b_arr = init_arr(b_var.datalen, sizeof(uint32_t), "Native uint32_tArray Bytes"); uint32_t *b_arr_ptr = (uint32_t*)(b_arr + 4); for (size_t e = 0; e < b_var.datalen; e++) { uint64_t b_conv_30_ref = (uint64_t)(&b_var.data[e]) | 1; b_arr_ptr[e] = b_conv_30_ref; } return b_arr; } uint32_t __attribute__((visibility("default"))) TS_LDKCVec_C2Tuple_TxidCVec_C2Tuple_u32ScriptZZZZ_new(uint32_tArray elems) { LDKCVec_C2Tuple_TxidCVec_C2Tuple_u32ScriptZZZZ *ret = MALLOC(sizeof(LDKCVec_C2Tuple_TxidCVec_C2Tuple_u32ScriptZZZZ), "LDKCVec_C2Tuple_TxidCVec_C2Tuple_u32ScriptZZZZ"); ret->datalen = *((uint32_t*)elems); if (ret->datalen == 0) { ret->data = NULL; } else { ret->data = MALLOC(sizeof(LDKC2Tuple_TxidCVec_C2Tuple_u32ScriptZZZ) * ret->datalen, "LDKCVec_C2Tuple_TxidCVec_C2Tuple_u32ScriptZZZZ Data"); uint32_t *java_elems = (uint32_t*)(elems + 4); for (size_t i = 0; i < ret->datalen; i++) { uint32_t arr_elem = java_elems[i]; LDKC2Tuple_TxidCVec_C2Tuple_u32ScriptZZZ arr_elem_conv = *(LDKC2Tuple_TxidCVec_C2Tuple_u32ScriptZZZ*)(((uint64_t)arr_elem) & ~1); arr_elem_conv = C2Tuple_TxidCVec_C2Tuple_u32ScriptZZZ_clone((LDKC2Tuple_TxidCVec_C2Tuple_u32ScriptZZZ*)(((uint64_t)arr_elem) & ~1)); ret->data[i] = arr_elem_conv; } } return (uint64_t)ret; } static inline LDKCVec_C2Tuple_TxidCVec_C2Tuple_u32ScriptZZZZ CVec_C2Tuple_TxidCVec_C2Tuple_u32ScriptZZZZ_clone(const LDKCVec_C2Tuple_TxidCVec_C2Tuple_u32ScriptZZZZ *orig) { LDKCVec_C2Tuple_TxidCVec_C2Tuple_u32ScriptZZZZ ret = { .data = MALLOC(sizeof(LDKC2Tuple_TxidCVec_C2Tuple_u32ScriptZZZ) * orig->datalen, "LDKCVec_C2Tuple_TxidCVec_C2Tuple_u32ScriptZZZZ clone bytes"), .datalen = orig->datalen }; for (size_t i = 0; i < ret.datalen; i++) { ret.data[i] = C2Tuple_TxidCVec_C2Tuple_u32ScriptZZZ_clone(&orig->data[i]); } return ret; } uint32_t __attribute__((visibility("default"))) TS_LDKPaymentPurpose_ref_from_ptr(uint32_t ptr) { LDKPaymentPurpose *obj = (LDKPaymentPurpose*)(ptr & ~1); switch(obj->tag) { case LDKPaymentPurpose_InvoicePayment: { int8_tArray payment_preimage_arr = init_arr(32, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(payment_preimage_arr + 4), obj->invoice_payment.payment_preimage.data, 32); int8_tArray payment_secret_arr = init_arr(32, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(payment_secret_arr + 4), obj->invoice_payment.payment_secret.data, 32); return 0 /* LDKPaymentPurpose - InvoicePayment */; (void) payment_preimage_arr; (void) payment_secret_arr; (void) obj->invoice_payment.user_payment_id; } case LDKPaymentPurpose_SpontaneousPayment: { int8_tArray spontaneous_payment_arr = init_arr(32, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(spontaneous_payment_arr + 4), obj->spontaneous_payment.data, 32); return 0 /* LDKPaymentPurpose - SpontaneousPayment */; (void) spontaneous_payment_arr; } default: abort(); } } uint32_t __attribute__((visibility("default"))) TS_LDKClosureReason_ref_from_ptr(uint32_t ptr) { LDKClosureReason *obj = (LDKClosureReason*)(ptr & ~1); switch(obj->tag) { case LDKClosureReason_CounterpartyForceClosed: { LDKStr peer_msg_str = obj->counterparty_force_closed.peer_msg; jstring peer_msg_conv = str_ref_to_ts(peer_msg_str.chars, peer_msg_str.len); return 0 /* LDKClosureReason - CounterpartyForceClosed */; (void) peer_msg_conv; } case LDKClosureReason_HolderForceClosed: { return 0 /* LDKClosureReason - HolderForceClosed */; } case LDKClosureReason_CooperativeClosure: { return 0 /* LDKClosureReason - CooperativeClosure */; } case LDKClosureReason_CommitmentTxConfirmed: { return 0 /* LDKClosureReason - CommitmentTxConfirmed */; } case LDKClosureReason_ProcessingError: { LDKStr err_str = obj->processing_error.err; jstring err_conv = str_ref_to_ts(err_str.chars, err_str.len); return 0 /* LDKClosureReason - ProcessingError */; (void) err_conv; } case LDKClosureReason_DisconnectedPeer: { return 0 /* LDKClosureReason - DisconnectedPeer */; } case LDKClosureReason_OutdatedChannelManager: { return 0 /* LDKClosureReason - OutdatedChannelManager */; } default: abort(); } } uint32_t __attribute__((visibility("default"))) TS_LDKEvent_ref_from_ptr(uint32_t ptr) { LDKEvent *obj = (LDKEvent*)(ptr & ~1); switch(obj->tag) { case LDKEvent_FundingGenerationReady: { int8_tArray temporary_channel_id_arr = init_arr(32, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(temporary_channel_id_arr + 4), obj->funding_generation_ready.temporary_channel_id.data, 32); LDKCVec_u8Z output_script_var = obj->funding_generation_ready.output_script; int8_tArray output_script_arr = init_arr(output_script_var.datalen, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(output_script_arr + 4), output_script_var.data, output_script_var.datalen); return 0 /* LDKEvent - FundingGenerationReady */; (void) temporary_channel_id_arr; (void) obj->funding_generation_ready.channel_value_satoshis; (void) output_script_arr; (void) obj->funding_generation_ready.user_channel_id; } case LDKEvent_PaymentReceived: { int8_tArray payment_hash_arr = init_arr(32, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(payment_hash_arr + 4), obj->payment_received.payment_hash.data, 32); uint64_t purpose_ref = ((uint64_t)&obj->payment_received.purpose) | 1; return 0 /* LDKEvent - PaymentReceived */; (void) payment_hash_arr; (void) obj->payment_received.amt; (void) purpose_ref; } case LDKEvent_PaymentSent: { int8_tArray payment_preimage_arr = init_arr(32, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(payment_preimage_arr + 4), obj->payment_sent.payment_preimage.data, 32); return 0 /* LDKEvent - PaymentSent */; (void) payment_preimage_arr; } case LDKEvent_PaymentPathFailed: { int8_tArray payment_hash_arr = init_arr(32, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(payment_hash_arr + 4), obj->payment_path_failed.payment_hash.data, 32); uint64_t network_update_ref = ((uint64_t)&obj->payment_path_failed.network_update) | 1; LDKCVec_RouteHopZ path_var = obj->payment_path_failed.path; uint32_tArray path_arr = init_arr(path_var.datalen, sizeof(uint32_t), "Native uint32_tArray Bytes"); uint32_t *path_arr_ptr = (uint32_t*)(path_arr + 4); for (size_t k = 0; k < path_var.datalen; k++) { LDKRouteHop path_conv_10_var = path_var.data[k]; CHECK((((uint64_t)path_conv_10_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&path_conv_10_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t path_conv_10_ref = (uint64_t)path_conv_10_var.inner & ~1; path_arr_ptr[k] = path_conv_10_ref; } return 0 /* LDKEvent - PaymentPathFailed */; (void) payment_hash_arr; (void) obj->payment_path_failed.rejected_by_dest; (void) network_update_ref; (void) obj->payment_path_failed.all_paths_failed; (void) path_arr; } case LDKEvent_PendingHTLCsForwardable: { return 0 /* LDKEvent - PendingHTLCsForwardable */; (void) obj->pending_htl_cs_forwardable.time_forwardable; } case LDKEvent_SpendableOutputs: { LDKCVec_SpendableOutputDescriptorZ outputs_var = obj->spendable_outputs.outputs; uint32_tArray outputs_arr = init_arr(outputs_var.datalen, sizeof(uint32_t), "Native uint32_tArray Bytes"); uint32_t *outputs_arr_ptr = (uint32_t*)(outputs_arr + 4); for (size_t b = 0; b < outputs_var.datalen; b++) { uint64_t outputs_conv_27_ref = ((uint64_t)&outputs_var.data[b]) | 1; outputs_arr_ptr[b] = outputs_conv_27_ref; } return 0 /* LDKEvent - SpendableOutputs */; (void) outputs_arr; } case LDKEvent_PaymentForwarded: { uint64_t fee_earned_msat_ref = ((uint64_t)&obj->payment_forwarded.fee_earned_msat) | 1; return 0 /* LDKEvent - PaymentForwarded */; (void) fee_earned_msat_ref; (void) obj->payment_forwarded.claim_from_onchain_tx; } case LDKEvent_ChannelClosed: { int8_tArray channel_id_arr = init_arr(32, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(channel_id_arr + 4), obj->channel_closed.channel_id.data, 32); uint64_t reason_ref = ((uint64_t)&obj->channel_closed.reason) | 1; return 0 /* LDKEvent - ChannelClosed */; (void) channel_id_arr; (void) reason_ref; } default: abort(); } } uint32_t __attribute__((visibility("default"))) TS_LDKCVec_EventZ_new(uint32_tArray elems) { LDKCVec_EventZ *ret = MALLOC(sizeof(LDKCVec_EventZ), "LDKCVec_EventZ"); ret->datalen = *((uint32_t*)elems); if (ret->datalen == 0) { ret->data = NULL; } else { ret->data = MALLOC(sizeof(LDKEvent) * ret->datalen, "LDKCVec_EventZ Data"); uint32_t *java_elems = (uint32_t*)(elems + 4); for (size_t i = 0; i < ret->datalen; i++) { uint32_t arr_elem = java_elems[i]; LDKEvent arr_elem_conv = *(LDKEvent*)(((uint64_t)arr_elem) & ~1); arr_elem_conv = Event_clone((LDKEvent*)(((uint64_t)arr_elem) & ~1)); ret->data[i] = arr_elem_conv; } } return (uint64_t)ret; } static inline LDKCVec_EventZ CVec_EventZ_clone(const LDKCVec_EventZ *orig) { LDKCVec_EventZ ret = { .data = MALLOC(sizeof(LDKEvent) * orig->datalen, "LDKCVec_EventZ clone bytes"), .datalen = orig->datalen }; for (size_t i = 0; i < ret.datalen; i++) { ret.data[i] = Event_clone(&orig->data[i]); } return ret; } uint32_t __attribute__((visibility("default"))) TS_LDKC2Tuple_u32TxOutZ_new(int32_t a, uint32_t b) { LDKC2Tuple_u32TxOutZ* ret = MALLOC(sizeof(LDKC2Tuple_u32TxOutZ), "LDKC2Tuple_u32TxOutZ"); ret->a = a; LDKTxOut b_conv = *(LDKTxOut*)(((uint64_t)b) & ~1); b_conv = TxOut_clone((LDKTxOut*)(((uint64_t)b) & ~1)); ret->b = b_conv; return (uint64_t)ret; } int32_t __attribute__((visibility("default"))) TS_LDKC2Tuple_u32TxOutZ_get_a(uint32_t ptr) { LDKC2Tuple_u32TxOutZ *tuple = (LDKC2Tuple_u32TxOutZ*)(ptr & ~1); return tuple->a; } uint32_t __attribute__((visibility("default"))) TS_LDKC2Tuple_u32TxOutZ_get_b(uint32_t ptr) { LDKC2Tuple_u32TxOutZ *tuple = (LDKC2Tuple_u32TxOutZ*)(ptr & ~1); uint64_t b_ref = ((uint64_t)&tuple->b) | 1; return (uint64_t)b_ref; } uint32_t __attribute__((visibility("default"))) TS_LDKCVec_C2Tuple_u32TxOutZZ_new(uint32_tArray elems) { LDKCVec_C2Tuple_u32TxOutZZ *ret = MALLOC(sizeof(LDKCVec_C2Tuple_u32TxOutZZ), "LDKCVec_C2Tuple_u32TxOutZZ"); ret->datalen = *((uint32_t*)elems); if (ret->datalen == 0) { ret->data = NULL; } else { ret->data = MALLOC(sizeof(LDKC2Tuple_u32TxOutZ) * ret->datalen, "LDKCVec_C2Tuple_u32TxOutZZ Data"); uint32_t *java_elems = (uint32_t*)(elems + 4); for (size_t i = 0; i < ret->datalen; i++) { uint32_t arr_elem = java_elems[i]; LDKC2Tuple_u32TxOutZ arr_elem_conv = *(LDKC2Tuple_u32TxOutZ*)(((uint64_t)arr_elem) & ~1); arr_elem_conv = C2Tuple_u32TxOutZ_clone((LDKC2Tuple_u32TxOutZ*)(((uint64_t)arr_elem) & ~1)); ret->data[i] = arr_elem_conv; } } return (uint64_t)ret; } static inline LDKCVec_C2Tuple_u32TxOutZZ CVec_C2Tuple_u32TxOutZZ_clone(const LDKCVec_C2Tuple_u32TxOutZZ *orig) { LDKCVec_C2Tuple_u32TxOutZZ ret = { .data = MALLOC(sizeof(LDKC2Tuple_u32TxOutZ) * orig->datalen, "LDKCVec_C2Tuple_u32TxOutZZ clone bytes"), .datalen = orig->datalen }; for (size_t i = 0; i < ret.datalen; i++) { ret.data[i] = C2Tuple_u32TxOutZ_clone(&orig->data[i]); } return ret; } uint32_t __attribute__((visibility("default"))) TS_LDKC2Tuple_TxidCVec_C2Tuple_u32TxOutZZZ_new(int8_tArray a, uint32_tArray b) { LDKC2Tuple_TxidCVec_C2Tuple_u32TxOutZZZ* ret = MALLOC(sizeof(LDKC2Tuple_TxidCVec_C2Tuple_u32TxOutZZZ), "LDKC2Tuple_TxidCVec_C2Tuple_u32TxOutZZZ"); LDKThirtyTwoBytes a_ref; CHECK(*((uint32_t*)a) == 32); memcpy(a_ref.data, (uint8_t*)(a + 4), 32); ret->a = a_ref; LDKCVec_C2Tuple_u32TxOutZZ b_constr; b_constr.datalen = *((uint32_t*)b); if (b_constr.datalen > 0) b_constr.data = MALLOC(b_constr.datalen * sizeof(LDKC2Tuple_u32TxOutZ), "LDKCVec_C2Tuple_u32TxOutZZ Elements"); else b_constr.data = NULL; uint32_t* b_vals = (uint32_t*)(b + 4); for (size_t z = 0; z < b_constr.datalen; z++) { uint32_t b_conv_25 = b_vals[z]; LDKC2Tuple_u32TxOutZ b_conv_25_conv = *(LDKC2Tuple_u32TxOutZ*)(((uint64_t)b_conv_25) & ~1); b_conv_25_conv = C2Tuple_u32TxOutZ_clone((LDKC2Tuple_u32TxOutZ*)(((uint64_t)b_conv_25) & ~1)); b_constr.data[z] = b_conv_25_conv; } ret->b = b_constr; return (uint64_t)ret; } int8_tArray __attribute__((visibility("default"))) TS_LDKC2Tuple_TxidCVec_C2Tuple_u32TxOutZZZ_get_a(uint32_t ptr) { LDKC2Tuple_TxidCVec_C2Tuple_u32TxOutZZZ *tuple = (LDKC2Tuple_TxidCVec_C2Tuple_u32TxOutZZZ*)(ptr & ~1); int8_tArray a_arr = init_arr(32, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(a_arr + 4), tuple->a.data, 32); return a_arr; } uint32_tArray __attribute__((visibility("default"))) TS_LDKC2Tuple_TxidCVec_C2Tuple_u32TxOutZZZ_get_b(uint32_t ptr) { LDKC2Tuple_TxidCVec_C2Tuple_u32TxOutZZZ *tuple = (LDKC2Tuple_TxidCVec_C2Tuple_u32TxOutZZZ*)(ptr & ~1); LDKCVec_C2Tuple_u32TxOutZZ b_var = tuple->b; uint32_tArray b_arr = init_arr(b_var.datalen, sizeof(uint32_t), "Native uint32_tArray Bytes"); uint32_t *b_arr_ptr = (uint32_t*)(b_arr + 4); for (size_t z = 0; z < b_var.datalen; z++) { uint64_t b_conv_25_ref = (uint64_t)(&b_var.data[z]) | 1; b_arr_ptr[z] = b_conv_25_ref; } return b_arr; } uint32_t __attribute__((visibility("default"))) TS_LDKCVec_C2Tuple_TxidCVec_C2Tuple_u32TxOutZZZZ_new(uint32_tArray elems) { LDKCVec_C2Tuple_TxidCVec_C2Tuple_u32TxOutZZZZ *ret = MALLOC(sizeof(LDKCVec_C2Tuple_TxidCVec_C2Tuple_u32TxOutZZZZ), "LDKCVec_C2Tuple_TxidCVec_C2Tuple_u32TxOutZZZZ"); ret->datalen = *((uint32_t*)elems); if (ret->datalen == 0) { ret->data = NULL; } else { ret->data = MALLOC(sizeof(LDKC2Tuple_TxidCVec_C2Tuple_u32TxOutZZZ) * ret->datalen, "LDKCVec_C2Tuple_TxidCVec_C2Tuple_u32TxOutZZZZ Data"); uint32_t *java_elems = (uint32_t*)(elems + 4); for (size_t i = 0; i < ret->datalen; i++) { uint32_t arr_elem = java_elems[i]; LDKC2Tuple_TxidCVec_C2Tuple_u32TxOutZZZ arr_elem_conv = *(LDKC2Tuple_TxidCVec_C2Tuple_u32TxOutZZZ*)(((uint64_t)arr_elem) & ~1); arr_elem_conv = C2Tuple_TxidCVec_C2Tuple_u32TxOutZZZ_clone((LDKC2Tuple_TxidCVec_C2Tuple_u32TxOutZZZ*)(((uint64_t)arr_elem) & ~1)); ret->data[i] = arr_elem_conv; } } return (uint64_t)ret; } static inline LDKCVec_C2Tuple_TxidCVec_C2Tuple_u32TxOutZZZZ CVec_C2Tuple_TxidCVec_C2Tuple_u32TxOutZZZZ_clone(const LDKCVec_C2Tuple_TxidCVec_C2Tuple_u32TxOutZZZZ *orig) { LDKCVec_C2Tuple_TxidCVec_C2Tuple_u32TxOutZZZZ ret = { .data = MALLOC(sizeof(LDKC2Tuple_TxidCVec_C2Tuple_u32TxOutZZZ) * orig->datalen, "LDKCVec_C2Tuple_TxidCVec_C2Tuple_u32TxOutZZZZ clone bytes"), .datalen = orig->datalen }; for (size_t i = 0; i < ret.datalen; i++) { ret.data[i] = C2Tuple_TxidCVec_C2Tuple_u32TxOutZZZ_clone(&orig->data[i]); } return ret; } uint32_t __attribute__((visibility("default"))) TS_LDKBalance_ref_from_ptr(uint32_t ptr) { LDKBalance *obj = (LDKBalance*)(ptr & ~1); switch(obj->tag) { case LDKBalance_ClaimableOnChannelClose: { return 0 /* LDKBalance - ClaimableOnChannelClose */; (void) obj->claimable_on_channel_close.claimable_amount_satoshis; } case LDKBalance_ClaimableAwaitingConfirmations: { return 0 /* LDKBalance - ClaimableAwaitingConfirmations */; (void) obj->claimable_awaiting_confirmations.claimable_amount_satoshis; (void) obj->claimable_awaiting_confirmations.confirmation_height; } case LDKBalance_ContentiousClaimable: { return 0 /* LDKBalance - ContentiousClaimable */; (void) obj->contentious_claimable.claimable_amount_satoshis; (void) obj->contentious_claimable.timeout_height; } case LDKBalance_MaybeClaimableHTLCAwaitingTimeout: { return 0 /* LDKBalance - MaybeClaimableHTLCAwaitingTimeout */; (void) obj->maybe_claimable_htlc_awaiting_timeout.claimable_amount_satoshis; (void) obj->maybe_claimable_htlc_awaiting_timeout.claimable_height; } default: abort(); } } uint32_t __attribute__((visibility("default"))) TS_LDKCVec_BalanceZ_new(uint32_tArray elems) { LDKCVec_BalanceZ *ret = MALLOC(sizeof(LDKCVec_BalanceZ), "LDKCVec_BalanceZ"); ret->datalen = *((uint32_t*)elems); if (ret->datalen == 0) { ret->data = NULL; } else { ret->data = MALLOC(sizeof(LDKBalance) * ret->datalen, "LDKCVec_BalanceZ Data"); uint32_t *java_elems = (uint32_t*)(elems + 4); for (size_t i = 0; i < ret->datalen; i++) { uint32_t arr_elem = java_elems[i]; LDKBalance arr_elem_conv = *(LDKBalance*)(((uint64_t)arr_elem) & ~1); arr_elem_conv = Balance_clone((LDKBalance*)(((uint64_t)arr_elem) & ~1)); ret->data[i] = arr_elem_conv; } } return (uint64_t)ret; } static inline LDKCVec_BalanceZ CVec_BalanceZ_clone(const LDKCVec_BalanceZ *orig) { LDKCVec_BalanceZ ret = { .data = MALLOC(sizeof(LDKBalance) * orig->datalen, "LDKCVec_BalanceZ clone bytes"), .datalen = orig->datalen }; for (size_t i = 0; i < ret.datalen; i++) { ret.data[i] = Balance_clone(&orig->data[i]); } return ret; } jboolean __attribute__((visibility("default"))) TS_LDKCResult_C2Tuple_BlockHashChannelMonitorZDecodeErrorZ_result_ok(uint32_t arg) { return ((LDKCResult_C2Tuple_BlockHashChannelMonitorZDecodeErrorZ*)arg)->result_ok; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_C2Tuple_BlockHashChannelMonitorZDecodeErrorZ_get_ok(uint32_t arg) { LDKCResult_C2Tuple_BlockHashChannelMonitorZDecodeErrorZ *val = (LDKCResult_C2Tuple_BlockHashChannelMonitorZDecodeErrorZ*)(arg & ~1); CHECK(val->result_ok); uint64_t res_ref = (uint64_t)(&(*val->contents.result)) | 1; return res_ref; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_C2Tuple_BlockHashChannelMonitorZDecodeErrorZ_get_err(uint32_t arg) { LDKCResult_C2Tuple_BlockHashChannelMonitorZDecodeErrorZ *val = (LDKCResult_C2Tuple_BlockHashChannelMonitorZDecodeErrorZ*)(arg & ~1); CHECK(!val->result_ok); LDKDecodeError err_var = (*val->contents.err); CHECK((((uint64_t)err_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&err_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t err_ref = (uint64_t)err_var.inner & ~1; return err_ref; } jboolean __attribute__((visibility("default"))) TS_LDKCResult_NoneLightningErrorZ_result_ok(uint32_t arg) { return ((LDKCResult_NoneLightningErrorZ*)arg)->result_ok; } void __attribute__((visibility("default"))) TS_LDKCResult_NoneLightningErrorZ_get_ok(uint32_t arg) { LDKCResult_NoneLightningErrorZ *val = (LDKCResult_NoneLightningErrorZ*)(arg & ~1); CHECK(val->result_ok); return *val->contents.result; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_NoneLightningErrorZ_get_err(uint32_t arg) { LDKCResult_NoneLightningErrorZ *val = (LDKCResult_NoneLightningErrorZ*)(arg & ~1); CHECK(!val->result_ok); LDKLightningError err_var = (*val->contents.err); CHECK((((uint64_t)err_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&err_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t err_ref = (uint64_t)err_var.inner & ~1; return err_ref; } uint32_t __attribute__((visibility("default"))) TS_LDKC2Tuple_PublicKeyTypeZ_new(int8_tArray a, uint32_t b) { LDKC2Tuple_PublicKeyTypeZ* ret = MALLOC(sizeof(LDKC2Tuple_PublicKeyTypeZ), "LDKC2Tuple_PublicKeyTypeZ"); LDKPublicKey a_ref; CHECK(*((uint32_t*)a) == 33); memcpy(a_ref.compressed_form, (uint8_t*)(a + 4), 33); ret->a = a_ref; LDKType b_conv = *(LDKType*)(((uint64_t)b) & ~1); b_conv = Type_clone(&b_conv); ret->b = b_conv; return (uint64_t)ret; } int8_tArray __attribute__((visibility("default"))) TS_LDKC2Tuple_PublicKeyTypeZ_get_a(uint32_t ptr) { LDKC2Tuple_PublicKeyTypeZ *tuple = (LDKC2Tuple_PublicKeyTypeZ*)(ptr & ~1); int8_tArray a_arr = init_arr(33, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(a_arr + 4), tuple->a.compressed_form, 33); return a_arr; } uint32_t __attribute__((visibility("default"))) TS_LDKC2Tuple_PublicKeyTypeZ_get_b(uint32_t ptr) { LDKC2Tuple_PublicKeyTypeZ *tuple = (LDKC2Tuple_PublicKeyTypeZ*)(ptr & ~1); LDKType* b_ret =MALLOC(sizeof(LDKType), "LDKType"); *b_ret = Type_clone(&tuple->b); return (uint64_t)b_ret; } uint32_t __attribute__((visibility("default"))) TS_LDKCVec_C2Tuple_PublicKeyTypeZZ_new(uint32_tArray elems) { LDKCVec_C2Tuple_PublicKeyTypeZZ *ret = MALLOC(sizeof(LDKCVec_C2Tuple_PublicKeyTypeZZ), "LDKCVec_C2Tuple_PublicKeyTypeZZ"); ret->datalen = *((uint32_t*)elems); if (ret->datalen == 0) { ret->data = NULL; } else { ret->data = MALLOC(sizeof(LDKC2Tuple_PublicKeyTypeZ) * ret->datalen, "LDKCVec_C2Tuple_PublicKeyTypeZZ Data"); uint32_t *java_elems = (uint32_t*)(elems + 4); for (size_t i = 0; i < ret->datalen; i++) { uint32_t arr_elem = java_elems[i]; LDKC2Tuple_PublicKeyTypeZ arr_elem_conv = *(LDKC2Tuple_PublicKeyTypeZ*)(((uint64_t)arr_elem) & ~1); arr_elem_conv = C2Tuple_PublicKeyTypeZ_clone((LDKC2Tuple_PublicKeyTypeZ*)(((uint64_t)arr_elem) & ~1)); ret->data[i] = arr_elem_conv; } } return (uint64_t)ret; } static inline LDKCVec_C2Tuple_PublicKeyTypeZZ CVec_C2Tuple_PublicKeyTypeZZ_clone(const LDKCVec_C2Tuple_PublicKeyTypeZZ *orig) { LDKCVec_C2Tuple_PublicKeyTypeZZ ret = { .data = MALLOC(sizeof(LDKC2Tuple_PublicKeyTypeZ) * orig->datalen, "LDKCVec_C2Tuple_PublicKeyTypeZZ clone bytes"), .datalen = orig->datalen }; for (size_t i = 0; i < ret.datalen; i++) { ret.data[i] = C2Tuple_PublicKeyTypeZ_clone(&orig->data[i]); } return ret; } jboolean __attribute__((visibility("default"))) TS_LDKCResult_boolLightningErrorZ_result_ok(uint32_t arg) { return ((LDKCResult_boolLightningErrorZ*)arg)->result_ok; } jboolean __attribute__((visibility("default"))) TS_LDKCResult_boolLightningErrorZ_get_ok(uint32_t arg) { LDKCResult_boolLightningErrorZ *val = (LDKCResult_boolLightningErrorZ*)(arg & ~1); CHECK(val->result_ok); return *val->contents.result; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_boolLightningErrorZ_get_err(uint32_t arg) { LDKCResult_boolLightningErrorZ *val = (LDKCResult_boolLightningErrorZ*)(arg & ~1); CHECK(!val->result_ok); LDKLightningError err_var = (*val->contents.err); CHECK((((uint64_t)err_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&err_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t err_ref = (uint64_t)err_var.inner & ~1; return err_ref; } uint32_t __attribute__((visibility("default"))) TS_LDKC3Tuple_ChannelAnnouncementChannelUpdateChannelUpdateZ_new(uint32_t a, uint32_t b, uint32_t c) { LDKC3Tuple_ChannelAnnouncementChannelUpdateChannelUpdateZ* ret = MALLOC(sizeof(LDKC3Tuple_ChannelAnnouncementChannelUpdateChannelUpdateZ), "LDKC3Tuple_ChannelAnnouncementChannelUpdateChannelUpdateZ"); LDKChannelAnnouncement a_conv; a_conv.inner = (void*)(a & (~1)); a_conv.is_owned = (a & 1) || (a == 0); a_conv = ChannelAnnouncement_clone(&a_conv); ret->a = a_conv; LDKChannelUpdate b_conv; b_conv.inner = (void*)(b & (~1)); b_conv.is_owned = (b & 1) || (b == 0); b_conv = ChannelUpdate_clone(&b_conv); ret->b = b_conv; LDKChannelUpdate c_conv; c_conv.inner = (void*)(c & (~1)); c_conv.is_owned = (c & 1) || (c == 0); c_conv = ChannelUpdate_clone(&c_conv); ret->c = c_conv; return (uint64_t)ret; } uint32_t __attribute__((visibility("default"))) TS_LDKC3Tuple_ChannelAnnouncementChannelUpdateChannelUpdateZ_get_a(uint32_t ptr) { LDKC3Tuple_ChannelAnnouncementChannelUpdateChannelUpdateZ *tuple = (LDKC3Tuple_ChannelAnnouncementChannelUpdateChannelUpdateZ*)(ptr & ~1); LDKChannelAnnouncement a_var = tuple->a; CHECK((((uint64_t)a_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&a_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t a_ref = (uint64_t)a_var.inner & ~1; return a_ref; } uint32_t __attribute__((visibility("default"))) TS_LDKC3Tuple_ChannelAnnouncementChannelUpdateChannelUpdateZ_get_b(uint32_t ptr) { LDKC3Tuple_ChannelAnnouncementChannelUpdateChannelUpdateZ *tuple = (LDKC3Tuple_ChannelAnnouncementChannelUpdateChannelUpdateZ*)(ptr & ~1); LDKChannelUpdate b_var = tuple->b; CHECK((((uint64_t)b_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&b_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t b_ref = (uint64_t)b_var.inner & ~1; return b_ref; } uint32_t __attribute__((visibility("default"))) TS_LDKC3Tuple_ChannelAnnouncementChannelUpdateChannelUpdateZ_get_c(uint32_t ptr) { LDKC3Tuple_ChannelAnnouncementChannelUpdateChannelUpdateZ *tuple = (LDKC3Tuple_ChannelAnnouncementChannelUpdateChannelUpdateZ*)(ptr & ~1); LDKChannelUpdate c_var = tuple->c; CHECK((((uint64_t)c_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&c_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t c_ref = (uint64_t)c_var.inner & ~1; return c_ref; } uint32_t __attribute__((visibility("default"))) TS_LDKCVec_C3Tuple_ChannelAnnouncementChannelUpdateChannelUpdateZZ_new(uint32_tArray elems) { LDKCVec_C3Tuple_ChannelAnnouncementChannelUpdateChannelUpdateZZ *ret = MALLOC(sizeof(LDKCVec_C3Tuple_ChannelAnnouncementChannelUpdateChannelUpdateZZ), "LDKCVec_C3Tuple_ChannelAnnouncementChannelUpdateChannelUpdateZZ"); ret->datalen = *((uint32_t*)elems); if (ret->datalen == 0) { ret->data = NULL; } else { ret->data = MALLOC(sizeof(LDKC3Tuple_ChannelAnnouncementChannelUpdateChannelUpdateZ) * ret->datalen, "LDKCVec_C3Tuple_ChannelAnnouncementChannelUpdateChannelUpdateZZ Data"); uint32_t *java_elems = (uint32_t*)(elems + 4); for (size_t i = 0; i < ret->datalen; i++) { uint32_t arr_elem = java_elems[i]; LDKC3Tuple_ChannelAnnouncementChannelUpdateChannelUpdateZ arr_elem_conv = *(LDKC3Tuple_ChannelAnnouncementChannelUpdateChannelUpdateZ*)(((uint64_t)arr_elem) & ~1); arr_elem_conv = C3Tuple_ChannelAnnouncementChannelUpdateChannelUpdateZ_clone((LDKC3Tuple_ChannelAnnouncementChannelUpdateChannelUpdateZ*)(((uint64_t)arr_elem) & ~1)); ret->data[i] = arr_elem_conv; } } return (uint64_t)ret; } static inline LDKCVec_C3Tuple_ChannelAnnouncementChannelUpdateChannelUpdateZZ CVec_C3Tuple_ChannelAnnouncementChannelUpdateChannelUpdateZZ_clone(const LDKCVec_C3Tuple_ChannelAnnouncementChannelUpdateChannelUpdateZZ *orig) { LDKCVec_C3Tuple_ChannelAnnouncementChannelUpdateChannelUpdateZZ ret = { .data = MALLOC(sizeof(LDKC3Tuple_ChannelAnnouncementChannelUpdateChannelUpdateZ) * orig->datalen, "LDKCVec_C3Tuple_ChannelAnnouncementChannelUpdateChannelUpdateZZ clone bytes"), .datalen = orig->datalen }; for (size_t i = 0; i < ret.datalen; i++) { ret.data[i] = C3Tuple_ChannelAnnouncementChannelUpdateChannelUpdateZ_clone(&orig->data[i]); } return ret; } uint32_t __attribute__((visibility("default"))) TS_LDKCVec_NodeAnnouncementZ_new(uint32_tArray elems) { LDKCVec_NodeAnnouncementZ *ret = MALLOC(sizeof(LDKCVec_NodeAnnouncementZ), "LDKCVec_NodeAnnouncementZ"); ret->datalen = *((uint32_t*)elems); if (ret->datalen == 0) { ret->data = NULL; } else { ret->data = MALLOC(sizeof(LDKNodeAnnouncement) * ret->datalen, "LDKCVec_NodeAnnouncementZ Data"); uint32_t *java_elems = (uint32_t*)(elems + 4); for (size_t i = 0; i < ret->datalen; i++) { uint32_t arr_elem = java_elems[i]; LDKNodeAnnouncement arr_elem_conv; arr_elem_conv.inner = (void*)(arr_elem & (~1)); arr_elem_conv.is_owned = (arr_elem & 1) || (arr_elem == 0); arr_elem_conv = NodeAnnouncement_clone(&arr_elem_conv); ret->data[i] = arr_elem_conv; } } return (uint64_t)ret; } static inline LDKCVec_NodeAnnouncementZ CVec_NodeAnnouncementZ_clone(const LDKCVec_NodeAnnouncementZ *orig) { LDKCVec_NodeAnnouncementZ ret = { .data = MALLOC(sizeof(LDKNodeAnnouncement) * orig->datalen, "LDKCVec_NodeAnnouncementZ clone bytes"), .datalen = orig->datalen }; for (size_t i = 0; i < ret.datalen; i++) { ret.data[i] = NodeAnnouncement_clone(&orig->data[i]); } return ret; } jboolean __attribute__((visibility("default"))) TS_LDKCResult_CVec_u8ZPeerHandleErrorZ_result_ok(uint32_t arg) { return ((LDKCResult_CVec_u8ZPeerHandleErrorZ*)arg)->result_ok; } int8_tArray __attribute__((visibility("default"))) TS_LDKCResult_CVec_u8ZPeerHandleErrorZ_get_ok(uint32_t arg) { LDKCResult_CVec_u8ZPeerHandleErrorZ *val = (LDKCResult_CVec_u8ZPeerHandleErrorZ*)(arg & ~1); CHECK(val->result_ok); LDKCVec_u8Z res_var = (*val->contents.result); int8_tArray res_arr = init_arr(res_var.datalen, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(res_arr + 4), res_var.data, res_var.datalen); return res_arr; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_CVec_u8ZPeerHandleErrorZ_get_err(uint32_t arg) { LDKCResult_CVec_u8ZPeerHandleErrorZ *val = (LDKCResult_CVec_u8ZPeerHandleErrorZ*)(arg & ~1); CHECK(!val->result_ok); LDKPeerHandleError err_var = (*val->contents.err); CHECK((((uint64_t)err_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&err_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t err_ref = (uint64_t)err_var.inner & ~1; return err_ref; } jboolean __attribute__((visibility("default"))) TS_LDKCResult_NonePeerHandleErrorZ_result_ok(uint32_t arg) { return ((LDKCResult_NonePeerHandleErrorZ*)arg)->result_ok; } void __attribute__((visibility("default"))) TS_LDKCResult_NonePeerHandleErrorZ_get_ok(uint32_t arg) { LDKCResult_NonePeerHandleErrorZ *val = (LDKCResult_NonePeerHandleErrorZ*)(arg & ~1); CHECK(val->result_ok); return *val->contents.result; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_NonePeerHandleErrorZ_get_err(uint32_t arg) { LDKCResult_NonePeerHandleErrorZ *val = (LDKCResult_NonePeerHandleErrorZ*)(arg & ~1); CHECK(!val->result_ok); LDKPeerHandleError err_var = (*val->contents.err); CHECK((((uint64_t)err_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&err_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t err_ref = (uint64_t)err_var.inner & ~1; return err_ref; } jboolean __attribute__((visibility("default"))) TS_LDKCResult_boolPeerHandleErrorZ_result_ok(uint32_t arg) { return ((LDKCResult_boolPeerHandleErrorZ*)arg)->result_ok; } jboolean __attribute__((visibility("default"))) TS_LDKCResult_boolPeerHandleErrorZ_get_ok(uint32_t arg) { LDKCResult_boolPeerHandleErrorZ *val = (LDKCResult_boolPeerHandleErrorZ*)(arg & ~1); CHECK(val->result_ok); return *val->contents.result; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_boolPeerHandleErrorZ_get_err(uint32_t arg) { LDKCResult_boolPeerHandleErrorZ *val = (LDKCResult_boolPeerHandleErrorZ*)(arg & ~1); CHECK(!val->result_ok); LDKPeerHandleError err_var = (*val->contents.err); CHECK((((uint64_t)err_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&err_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t err_ref = (uint64_t)err_var.inner & ~1; return err_ref; } typedef struct LDKAccess_JCalls { atomic_size_t refcnt; uint32_t get_utxo_meth; } LDKAccess_JCalls; static void LDKAccess_JCalls_free(void* this_arg) { LDKAccess_JCalls *j_calls = (LDKAccess_JCalls*) this_arg; if (atomic_fetch_sub_explicit(&j_calls->refcnt, 1, memory_order_acquire) == 1) { js_free(j_calls->get_utxo_meth); FREE(j_calls); } } LDKCResult_TxOutAccessErrorZ get_utxo_LDKAccess_jcall(const void* this_arg, const uint8_t (* genesis_hash)[32], uint64_t short_channel_id) { LDKAccess_JCalls *j_calls = (LDKAccess_JCalls*) this_arg; int8_tArray genesis_hash_arr = init_arr(32, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(genesis_hash_arr + 4), *genesis_hash, 32); uint32_t ret = js_invoke_function_2(j_calls->get_utxo_meth, genesis_hash_arr, short_channel_id); LDKCResult_TxOutAccessErrorZ ret_conv = *(LDKCResult_TxOutAccessErrorZ*)(((uint64_t)ret) & ~1); ret_conv = CResult_TxOutAccessErrorZ_clone((LDKCResult_TxOutAccessErrorZ*)(((uint64_t)ret) & ~1)); return ret_conv; } static void LDKAccess_JCalls_cloned(LDKAccess* new_obj) { LDKAccess_JCalls *j_calls = (LDKAccess_JCalls*) new_obj->this_arg; atomic_fetch_add_explicit(&j_calls->refcnt, 1, memory_order_release); } static inline LDKAccess LDKAccess_init (/*TODO: JS Object Reference */void* o) { LDKAccess_JCalls *calls = MALLOC(sizeof(LDKAccess_JCalls), "LDKAccess_JCalls"); atomic_init(&calls->refcnt, 1); //TODO: Assign calls->o from o LDKAccess ret = { .this_arg = (void*) calls, .get_utxo = get_utxo_LDKAccess_jcall, .free = LDKAccess_JCalls_free, }; return ret; } long __attribute__((visibility("default"))) TS_LDKAccess_new(/*TODO: JS Object Reference */void* o) { LDKAccess *res_ptr = MALLOC(sizeof(LDKAccess), "LDKAccess"); *res_ptr = LDKAccess_init(o); return (long)res_ptr; } uint32_t __attribute__((visibility("default"))) TS_Access_get_utxo(uint32_t this_arg, int8_tArray genesis_hash, int64_t short_channel_id) { LDKAccess* this_arg_conv = (LDKAccess*)(((uint64_t)this_arg) & ~1); unsigned char genesis_hash_arr[32]; CHECK(*((uint32_t*)genesis_hash) == 32); memcpy(genesis_hash_arr, (uint8_t*)(genesis_hash + 4), 32); unsigned char (*genesis_hash_ref)[32] = &genesis_hash_arr; LDKCResult_TxOutAccessErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_TxOutAccessErrorZ), "LDKCResult_TxOutAccessErrorZ"); *ret_conv = (this_arg_conv->get_utxo)(this_arg_conv->this_arg, genesis_hash_ref, short_channel_id); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_LDKCOption_AccessZ_ref_from_ptr(uint32_t ptr) { LDKCOption_AccessZ *obj = (LDKCOption_AccessZ*)(ptr & ~1); switch(obj->tag) { case LDKCOption_AccessZ_Some: { LDKAccess* some_ret =MALLOC(sizeof(LDKAccess), "LDKAccess"); *some_ret = obj->some; // Warning: We likely need to clone here, but no clone is available, so we just do it for Java instances return 0 /* LDKCOption_AccessZ - Some */; (void) (uint64_t)some_ret; } case LDKCOption_AccessZ_None: { return 0 /* LDKCOption_AccessZ - None */; } default: abort(); } } jboolean __attribute__((visibility("default"))) TS_LDKCResult_DirectionalChannelInfoDecodeErrorZ_result_ok(uint32_t arg) { return ((LDKCResult_DirectionalChannelInfoDecodeErrorZ*)arg)->result_ok; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_DirectionalChannelInfoDecodeErrorZ_get_ok(uint32_t arg) { LDKCResult_DirectionalChannelInfoDecodeErrorZ *val = (LDKCResult_DirectionalChannelInfoDecodeErrorZ*)(arg & ~1); CHECK(val->result_ok); LDKDirectionalChannelInfo res_var = (*val->contents.result); CHECK((((uint64_t)res_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&res_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t res_ref = (uint64_t)res_var.inner & ~1; return res_ref; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_DirectionalChannelInfoDecodeErrorZ_get_err(uint32_t arg) { LDKCResult_DirectionalChannelInfoDecodeErrorZ *val = (LDKCResult_DirectionalChannelInfoDecodeErrorZ*)(arg & ~1); CHECK(!val->result_ok); LDKDecodeError err_var = (*val->contents.err); CHECK((((uint64_t)err_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&err_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t err_ref = (uint64_t)err_var.inner & ~1; return err_ref; } jboolean __attribute__((visibility("default"))) TS_LDKCResult_ChannelInfoDecodeErrorZ_result_ok(uint32_t arg) { return ((LDKCResult_ChannelInfoDecodeErrorZ*)arg)->result_ok; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_ChannelInfoDecodeErrorZ_get_ok(uint32_t arg) { LDKCResult_ChannelInfoDecodeErrorZ *val = (LDKCResult_ChannelInfoDecodeErrorZ*)(arg & ~1); CHECK(val->result_ok); LDKChannelInfo res_var = (*val->contents.result); CHECK((((uint64_t)res_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&res_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t res_ref = (uint64_t)res_var.inner & ~1; return res_ref; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_ChannelInfoDecodeErrorZ_get_err(uint32_t arg) { LDKCResult_ChannelInfoDecodeErrorZ *val = (LDKCResult_ChannelInfoDecodeErrorZ*)(arg & ~1); CHECK(!val->result_ok); LDKDecodeError err_var = (*val->contents.err); CHECK((((uint64_t)err_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&err_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t err_ref = (uint64_t)err_var.inner & ~1; return err_ref; } jboolean __attribute__((visibility("default"))) TS_LDKCResult_RoutingFeesDecodeErrorZ_result_ok(uint32_t arg) { return ((LDKCResult_RoutingFeesDecodeErrorZ*)arg)->result_ok; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_RoutingFeesDecodeErrorZ_get_ok(uint32_t arg) { LDKCResult_RoutingFeesDecodeErrorZ *val = (LDKCResult_RoutingFeesDecodeErrorZ*)(arg & ~1); CHECK(val->result_ok); LDKRoutingFees res_var = (*val->contents.result); CHECK((((uint64_t)res_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&res_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t res_ref = (uint64_t)res_var.inner & ~1; return res_ref; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_RoutingFeesDecodeErrorZ_get_err(uint32_t arg) { LDKCResult_RoutingFeesDecodeErrorZ *val = (LDKCResult_RoutingFeesDecodeErrorZ*)(arg & ~1); CHECK(!val->result_ok); LDKDecodeError err_var = (*val->contents.err); CHECK((((uint64_t)err_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&err_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t err_ref = (uint64_t)err_var.inner & ~1; return err_ref; } jboolean __attribute__((visibility("default"))) TS_LDKCResult_NodeAnnouncementInfoDecodeErrorZ_result_ok(uint32_t arg) { return ((LDKCResult_NodeAnnouncementInfoDecodeErrorZ*)arg)->result_ok; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_NodeAnnouncementInfoDecodeErrorZ_get_ok(uint32_t arg) { LDKCResult_NodeAnnouncementInfoDecodeErrorZ *val = (LDKCResult_NodeAnnouncementInfoDecodeErrorZ*)(arg & ~1); CHECK(val->result_ok); LDKNodeAnnouncementInfo res_var = (*val->contents.result); CHECK((((uint64_t)res_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&res_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t res_ref = (uint64_t)res_var.inner & ~1; return res_ref; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_NodeAnnouncementInfoDecodeErrorZ_get_err(uint32_t arg) { LDKCResult_NodeAnnouncementInfoDecodeErrorZ *val = (LDKCResult_NodeAnnouncementInfoDecodeErrorZ*)(arg & ~1); CHECK(!val->result_ok); LDKDecodeError err_var = (*val->contents.err); CHECK((((uint64_t)err_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&err_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t err_ref = (uint64_t)err_var.inner & ~1; return err_ref; } uint32_t __attribute__((visibility("default"))) TS_LDKCVec_u64Z_new(int64_tArray elems) { LDKCVec_u64Z *ret = MALLOC(sizeof(LDKCVec_u64Z), "LDKCVec_u64Z"); ret->datalen = *((uint32_t*)elems); if (ret->datalen == 0) { ret->data = NULL; } else { ret->data = MALLOC(sizeof(uint64_t) * ret->datalen, "LDKCVec_u64Z Data"); int64_t *java_elems = (int64_t*)(elems + 4); for (size_t i = 0; i < ret->datalen; i++) { ret->data[i] = java_elems[i]; } } return (uint64_t)ret; } static inline LDKCVec_u64Z CVec_u64Z_clone(const LDKCVec_u64Z *orig) { LDKCVec_u64Z ret = { .data = MALLOC(sizeof(int64_t) * orig->datalen, "LDKCVec_u64Z clone bytes"), .datalen = orig->datalen }; memcpy(ret.data, orig->data, sizeof(int64_t) * ret.datalen); return ret; } jboolean __attribute__((visibility("default"))) TS_LDKCResult_NodeInfoDecodeErrorZ_result_ok(uint32_t arg) { return ((LDKCResult_NodeInfoDecodeErrorZ*)arg)->result_ok; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_NodeInfoDecodeErrorZ_get_ok(uint32_t arg) { LDKCResult_NodeInfoDecodeErrorZ *val = (LDKCResult_NodeInfoDecodeErrorZ*)(arg & ~1); CHECK(val->result_ok); LDKNodeInfo res_var = (*val->contents.result); CHECK((((uint64_t)res_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&res_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t res_ref = (uint64_t)res_var.inner & ~1; return res_ref; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_NodeInfoDecodeErrorZ_get_err(uint32_t arg) { LDKCResult_NodeInfoDecodeErrorZ *val = (LDKCResult_NodeInfoDecodeErrorZ*)(arg & ~1); CHECK(!val->result_ok); LDKDecodeError err_var = (*val->contents.err); CHECK((((uint64_t)err_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&err_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t err_ref = (uint64_t)err_var.inner & ~1; return err_ref; } jboolean __attribute__((visibility("default"))) TS_LDKCResult_NetworkGraphDecodeErrorZ_result_ok(uint32_t arg) { return ((LDKCResult_NetworkGraphDecodeErrorZ*)arg)->result_ok; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_NetworkGraphDecodeErrorZ_get_ok(uint32_t arg) { LDKCResult_NetworkGraphDecodeErrorZ *val = (LDKCResult_NetworkGraphDecodeErrorZ*)(arg & ~1); CHECK(val->result_ok); LDKNetworkGraph res_var = (*val->contents.result); CHECK((((uint64_t)res_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&res_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t res_ref = (uint64_t)res_var.inner & ~1; return res_ref; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_NetworkGraphDecodeErrorZ_get_err(uint32_t arg) { LDKCResult_NetworkGraphDecodeErrorZ *val = (LDKCResult_NetworkGraphDecodeErrorZ*)(arg & ~1); CHECK(!val->result_ok); LDKDecodeError err_var = (*val->contents.err); CHECK((((uint64_t)err_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&err_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t err_ref = (uint64_t)err_var.inner & ~1; return err_ref; } jboolean __attribute__((visibility("default"))) TS_LDKCResult_NetAddressu8Z_result_ok(uint32_t arg) { return ((LDKCResult_NetAddressu8Z*)arg)->result_ok; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_NetAddressu8Z_get_ok(uint32_t arg) { LDKCResult_NetAddressu8Z *val = (LDKCResult_NetAddressu8Z*)(arg & ~1); CHECK(val->result_ok); uint64_t res_ref = ((uint64_t)&(*val->contents.result)) | 1; return res_ref; } int8_t __attribute__((visibility("default"))) TS_LDKCResult_NetAddressu8Z_get_err(uint32_t arg) { LDKCResult_NetAddressu8Z *val = (LDKCResult_NetAddressu8Z*)(arg & ~1); CHECK(!val->result_ok); return *val->contents.err; } jboolean __attribute__((visibility("default"))) TS_LDKCResult_CResult_NetAddressu8ZDecodeErrorZ_result_ok(uint32_t arg) { return ((LDKCResult_CResult_NetAddressu8ZDecodeErrorZ*)arg)->result_ok; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_CResult_NetAddressu8ZDecodeErrorZ_get_ok(uint32_t arg) { LDKCResult_CResult_NetAddressu8ZDecodeErrorZ *val = (LDKCResult_CResult_NetAddressu8ZDecodeErrorZ*)(arg & ~1); CHECK(val->result_ok); LDKCResult_NetAddressu8Z* res_conv = MALLOC(sizeof(LDKCResult_NetAddressu8Z), "LDKCResult_NetAddressu8Z"); *res_conv = (*val->contents.result); *res_conv = CResult_NetAddressu8Z_clone(res_conv); return (uint64_t)res_conv; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_CResult_NetAddressu8ZDecodeErrorZ_get_err(uint32_t arg) { LDKCResult_CResult_NetAddressu8ZDecodeErrorZ *val = (LDKCResult_CResult_NetAddressu8ZDecodeErrorZ*)(arg & ~1); CHECK(!val->result_ok); LDKDecodeError err_var = (*val->contents.err); CHECK((((uint64_t)err_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&err_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t err_ref = (uint64_t)err_var.inner & ~1; return err_ref; } jboolean __attribute__((visibility("default"))) TS_LDKCResult_NetAddressDecodeErrorZ_result_ok(uint32_t arg) { return ((LDKCResult_NetAddressDecodeErrorZ*)arg)->result_ok; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_NetAddressDecodeErrorZ_get_ok(uint32_t arg) { LDKCResult_NetAddressDecodeErrorZ *val = (LDKCResult_NetAddressDecodeErrorZ*)(arg & ~1); CHECK(val->result_ok); uint64_t res_ref = ((uint64_t)&(*val->contents.result)) | 1; return res_ref; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_NetAddressDecodeErrorZ_get_err(uint32_t arg) { LDKCResult_NetAddressDecodeErrorZ *val = (LDKCResult_NetAddressDecodeErrorZ*)(arg & ~1); CHECK(!val->result_ok); LDKDecodeError err_var = (*val->contents.err); CHECK((((uint64_t)err_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&err_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t err_ref = (uint64_t)err_var.inner & ~1; return err_ref; } uint32_t __attribute__((visibility("default"))) TS_LDKCVec_UpdateAddHTLCZ_new(uint32_tArray elems) { LDKCVec_UpdateAddHTLCZ *ret = MALLOC(sizeof(LDKCVec_UpdateAddHTLCZ), "LDKCVec_UpdateAddHTLCZ"); ret->datalen = *((uint32_t*)elems); if (ret->datalen == 0) { ret->data = NULL; } else { ret->data = MALLOC(sizeof(LDKUpdateAddHTLC) * ret->datalen, "LDKCVec_UpdateAddHTLCZ Data"); uint32_t *java_elems = (uint32_t*)(elems + 4); for (size_t i = 0; i < ret->datalen; i++) { uint32_t arr_elem = java_elems[i]; LDKUpdateAddHTLC arr_elem_conv; arr_elem_conv.inner = (void*)(arr_elem & (~1)); arr_elem_conv.is_owned = (arr_elem & 1) || (arr_elem == 0); arr_elem_conv = UpdateAddHTLC_clone(&arr_elem_conv); ret->data[i] = arr_elem_conv; } } return (uint64_t)ret; } static inline LDKCVec_UpdateAddHTLCZ CVec_UpdateAddHTLCZ_clone(const LDKCVec_UpdateAddHTLCZ *orig) { LDKCVec_UpdateAddHTLCZ ret = { .data = MALLOC(sizeof(LDKUpdateAddHTLC) * orig->datalen, "LDKCVec_UpdateAddHTLCZ clone bytes"), .datalen = orig->datalen }; for (size_t i = 0; i < ret.datalen; i++) { ret.data[i] = UpdateAddHTLC_clone(&orig->data[i]); } return ret; } uint32_t __attribute__((visibility("default"))) TS_LDKCVec_UpdateFulfillHTLCZ_new(uint32_tArray elems) { LDKCVec_UpdateFulfillHTLCZ *ret = MALLOC(sizeof(LDKCVec_UpdateFulfillHTLCZ), "LDKCVec_UpdateFulfillHTLCZ"); ret->datalen = *((uint32_t*)elems); if (ret->datalen == 0) { ret->data = NULL; } else { ret->data = MALLOC(sizeof(LDKUpdateFulfillHTLC) * ret->datalen, "LDKCVec_UpdateFulfillHTLCZ Data"); uint32_t *java_elems = (uint32_t*)(elems + 4); for (size_t i = 0; i < ret->datalen; i++) { uint32_t arr_elem = java_elems[i]; LDKUpdateFulfillHTLC arr_elem_conv; arr_elem_conv.inner = (void*)(arr_elem & (~1)); arr_elem_conv.is_owned = (arr_elem & 1) || (arr_elem == 0); arr_elem_conv = UpdateFulfillHTLC_clone(&arr_elem_conv); ret->data[i] = arr_elem_conv; } } return (uint64_t)ret; } static inline LDKCVec_UpdateFulfillHTLCZ CVec_UpdateFulfillHTLCZ_clone(const LDKCVec_UpdateFulfillHTLCZ *orig) { LDKCVec_UpdateFulfillHTLCZ ret = { .data = MALLOC(sizeof(LDKUpdateFulfillHTLC) * orig->datalen, "LDKCVec_UpdateFulfillHTLCZ clone bytes"), .datalen = orig->datalen }; for (size_t i = 0; i < ret.datalen; i++) { ret.data[i] = UpdateFulfillHTLC_clone(&orig->data[i]); } return ret; } uint32_t __attribute__((visibility("default"))) TS_LDKCVec_UpdateFailHTLCZ_new(uint32_tArray elems) { LDKCVec_UpdateFailHTLCZ *ret = MALLOC(sizeof(LDKCVec_UpdateFailHTLCZ), "LDKCVec_UpdateFailHTLCZ"); ret->datalen = *((uint32_t*)elems); if (ret->datalen == 0) { ret->data = NULL; } else { ret->data = MALLOC(sizeof(LDKUpdateFailHTLC) * ret->datalen, "LDKCVec_UpdateFailHTLCZ Data"); uint32_t *java_elems = (uint32_t*)(elems + 4); for (size_t i = 0; i < ret->datalen; i++) { uint32_t arr_elem = java_elems[i]; LDKUpdateFailHTLC arr_elem_conv; arr_elem_conv.inner = (void*)(arr_elem & (~1)); arr_elem_conv.is_owned = (arr_elem & 1) || (arr_elem == 0); arr_elem_conv = UpdateFailHTLC_clone(&arr_elem_conv); ret->data[i] = arr_elem_conv; } } return (uint64_t)ret; } static inline LDKCVec_UpdateFailHTLCZ CVec_UpdateFailHTLCZ_clone(const LDKCVec_UpdateFailHTLCZ *orig) { LDKCVec_UpdateFailHTLCZ ret = { .data = MALLOC(sizeof(LDKUpdateFailHTLC) * orig->datalen, "LDKCVec_UpdateFailHTLCZ clone bytes"), .datalen = orig->datalen }; for (size_t i = 0; i < ret.datalen; i++) { ret.data[i] = UpdateFailHTLC_clone(&orig->data[i]); } return ret; } uint32_t __attribute__((visibility("default"))) TS_LDKCVec_UpdateFailMalformedHTLCZ_new(uint32_tArray elems) { LDKCVec_UpdateFailMalformedHTLCZ *ret = MALLOC(sizeof(LDKCVec_UpdateFailMalformedHTLCZ), "LDKCVec_UpdateFailMalformedHTLCZ"); ret->datalen = *((uint32_t*)elems); if (ret->datalen == 0) { ret->data = NULL; } else { ret->data = MALLOC(sizeof(LDKUpdateFailMalformedHTLC) * ret->datalen, "LDKCVec_UpdateFailMalformedHTLCZ Data"); uint32_t *java_elems = (uint32_t*)(elems + 4); for (size_t i = 0; i < ret->datalen; i++) { uint32_t arr_elem = java_elems[i]; LDKUpdateFailMalformedHTLC arr_elem_conv; arr_elem_conv.inner = (void*)(arr_elem & (~1)); arr_elem_conv.is_owned = (arr_elem & 1) || (arr_elem == 0); arr_elem_conv = UpdateFailMalformedHTLC_clone(&arr_elem_conv); ret->data[i] = arr_elem_conv; } } return (uint64_t)ret; } static inline LDKCVec_UpdateFailMalformedHTLCZ CVec_UpdateFailMalformedHTLCZ_clone(const LDKCVec_UpdateFailMalformedHTLCZ *orig) { LDKCVec_UpdateFailMalformedHTLCZ ret = { .data = MALLOC(sizeof(LDKUpdateFailMalformedHTLC) * orig->datalen, "LDKCVec_UpdateFailMalformedHTLCZ clone bytes"), .datalen = orig->datalen }; for (size_t i = 0; i < ret.datalen; i++) { ret.data[i] = UpdateFailMalformedHTLC_clone(&orig->data[i]); } return ret; } jboolean __attribute__((visibility("default"))) TS_LDKCResult_AcceptChannelDecodeErrorZ_result_ok(uint32_t arg) { return ((LDKCResult_AcceptChannelDecodeErrorZ*)arg)->result_ok; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_AcceptChannelDecodeErrorZ_get_ok(uint32_t arg) { LDKCResult_AcceptChannelDecodeErrorZ *val = (LDKCResult_AcceptChannelDecodeErrorZ*)(arg & ~1); CHECK(val->result_ok); LDKAcceptChannel res_var = (*val->contents.result); CHECK((((uint64_t)res_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&res_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t res_ref = (uint64_t)res_var.inner & ~1; return res_ref; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_AcceptChannelDecodeErrorZ_get_err(uint32_t arg) { LDKCResult_AcceptChannelDecodeErrorZ *val = (LDKCResult_AcceptChannelDecodeErrorZ*)(arg & ~1); CHECK(!val->result_ok); LDKDecodeError err_var = (*val->contents.err); CHECK((((uint64_t)err_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&err_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t err_ref = (uint64_t)err_var.inner & ~1; return err_ref; } jboolean __attribute__((visibility("default"))) TS_LDKCResult_AnnouncementSignaturesDecodeErrorZ_result_ok(uint32_t arg) { return ((LDKCResult_AnnouncementSignaturesDecodeErrorZ*)arg)->result_ok; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_AnnouncementSignaturesDecodeErrorZ_get_ok(uint32_t arg) { LDKCResult_AnnouncementSignaturesDecodeErrorZ *val = (LDKCResult_AnnouncementSignaturesDecodeErrorZ*)(arg & ~1); CHECK(val->result_ok); LDKAnnouncementSignatures res_var = (*val->contents.result); CHECK((((uint64_t)res_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&res_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t res_ref = (uint64_t)res_var.inner & ~1; return res_ref; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_AnnouncementSignaturesDecodeErrorZ_get_err(uint32_t arg) { LDKCResult_AnnouncementSignaturesDecodeErrorZ *val = (LDKCResult_AnnouncementSignaturesDecodeErrorZ*)(arg & ~1); CHECK(!val->result_ok); LDKDecodeError err_var = (*val->contents.err); CHECK((((uint64_t)err_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&err_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t err_ref = (uint64_t)err_var.inner & ~1; return err_ref; } jboolean __attribute__((visibility("default"))) TS_LDKCResult_ChannelReestablishDecodeErrorZ_result_ok(uint32_t arg) { return ((LDKCResult_ChannelReestablishDecodeErrorZ*)arg)->result_ok; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_ChannelReestablishDecodeErrorZ_get_ok(uint32_t arg) { LDKCResult_ChannelReestablishDecodeErrorZ *val = (LDKCResult_ChannelReestablishDecodeErrorZ*)(arg & ~1); CHECK(val->result_ok); LDKChannelReestablish res_var = (*val->contents.result); CHECK((((uint64_t)res_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&res_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t res_ref = (uint64_t)res_var.inner & ~1; return res_ref; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_ChannelReestablishDecodeErrorZ_get_err(uint32_t arg) { LDKCResult_ChannelReestablishDecodeErrorZ *val = (LDKCResult_ChannelReestablishDecodeErrorZ*)(arg & ~1); CHECK(!val->result_ok); LDKDecodeError err_var = (*val->contents.err); CHECK((((uint64_t)err_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&err_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t err_ref = (uint64_t)err_var.inner & ~1; return err_ref; } jboolean __attribute__((visibility("default"))) TS_LDKCResult_ClosingSignedDecodeErrorZ_result_ok(uint32_t arg) { return ((LDKCResult_ClosingSignedDecodeErrorZ*)arg)->result_ok; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_ClosingSignedDecodeErrorZ_get_ok(uint32_t arg) { LDKCResult_ClosingSignedDecodeErrorZ *val = (LDKCResult_ClosingSignedDecodeErrorZ*)(arg & ~1); CHECK(val->result_ok); LDKClosingSigned res_var = (*val->contents.result); CHECK((((uint64_t)res_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&res_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t res_ref = (uint64_t)res_var.inner & ~1; return res_ref; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_ClosingSignedDecodeErrorZ_get_err(uint32_t arg) { LDKCResult_ClosingSignedDecodeErrorZ *val = (LDKCResult_ClosingSignedDecodeErrorZ*)(arg & ~1); CHECK(!val->result_ok); LDKDecodeError err_var = (*val->contents.err); CHECK((((uint64_t)err_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&err_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t err_ref = (uint64_t)err_var.inner & ~1; return err_ref; } jboolean __attribute__((visibility("default"))) TS_LDKCResult_ClosingSignedFeeRangeDecodeErrorZ_result_ok(uint32_t arg) { return ((LDKCResult_ClosingSignedFeeRangeDecodeErrorZ*)arg)->result_ok; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_ClosingSignedFeeRangeDecodeErrorZ_get_ok(uint32_t arg) { LDKCResult_ClosingSignedFeeRangeDecodeErrorZ *val = (LDKCResult_ClosingSignedFeeRangeDecodeErrorZ*)(arg & ~1); CHECK(val->result_ok); LDKClosingSignedFeeRange res_var = (*val->contents.result); CHECK((((uint64_t)res_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&res_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t res_ref = (uint64_t)res_var.inner & ~1; return res_ref; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_ClosingSignedFeeRangeDecodeErrorZ_get_err(uint32_t arg) { LDKCResult_ClosingSignedFeeRangeDecodeErrorZ *val = (LDKCResult_ClosingSignedFeeRangeDecodeErrorZ*)(arg & ~1); CHECK(!val->result_ok); LDKDecodeError err_var = (*val->contents.err); CHECK((((uint64_t)err_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&err_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t err_ref = (uint64_t)err_var.inner & ~1; return err_ref; } jboolean __attribute__((visibility("default"))) TS_LDKCResult_CommitmentSignedDecodeErrorZ_result_ok(uint32_t arg) { return ((LDKCResult_CommitmentSignedDecodeErrorZ*)arg)->result_ok; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_CommitmentSignedDecodeErrorZ_get_ok(uint32_t arg) { LDKCResult_CommitmentSignedDecodeErrorZ *val = (LDKCResult_CommitmentSignedDecodeErrorZ*)(arg & ~1); CHECK(val->result_ok); LDKCommitmentSigned res_var = (*val->contents.result); CHECK((((uint64_t)res_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&res_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t res_ref = (uint64_t)res_var.inner & ~1; return res_ref; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_CommitmentSignedDecodeErrorZ_get_err(uint32_t arg) { LDKCResult_CommitmentSignedDecodeErrorZ *val = (LDKCResult_CommitmentSignedDecodeErrorZ*)(arg & ~1); CHECK(!val->result_ok); LDKDecodeError err_var = (*val->contents.err); CHECK((((uint64_t)err_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&err_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t err_ref = (uint64_t)err_var.inner & ~1; return err_ref; } jboolean __attribute__((visibility("default"))) TS_LDKCResult_FundingCreatedDecodeErrorZ_result_ok(uint32_t arg) { return ((LDKCResult_FundingCreatedDecodeErrorZ*)arg)->result_ok; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_FundingCreatedDecodeErrorZ_get_ok(uint32_t arg) { LDKCResult_FundingCreatedDecodeErrorZ *val = (LDKCResult_FundingCreatedDecodeErrorZ*)(arg & ~1); CHECK(val->result_ok); LDKFundingCreated res_var = (*val->contents.result); CHECK((((uint64_t)res_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&res_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t res_ref = (uint64_t)res_var.inner & ~1; return res_ref; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_FundingCreatedDecodeErrorZ_get_err(uint32_t arg) { LDKCResult_FundingCreatedDecodeErrorZ *val = (LDKCResult_FundingCreatedDecodeErrorZ*)(arg & ~1); CHECK(!val->result_ok); LDKDecodeError err_var = (*val->contents.err); CHECK((((uint64_t)err_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&err_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t err_ref = (uint64_t)err_var.inner & ~1; return err_ref; } jboolean __attribute__((visibility("default"))) TS_LDKCResult_FundingSignedDecodeErrorZ_result_ok(uint32_t arg) { return ((LDKCResult_FundingSignedDecodeErrorZ*)arg)->result_ok; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_FundingSignedDecodeErrorZ_get_ok(uint32_t arg) { LDKCResult_FundingSignedDecodeErrorZ *val = (LDKCResult_FundingSignedDecodeErrorZ*)(arg & ~1); CHECK(val->result_ok); LDKFundingSigned res_var = (*val->contents.result); CHECK((((uint64_t)res_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&res_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t res_ref = (uint64_t)res_var.inner & ~1; return res_ref; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_FundingSignedDecodeErrorZ_get_err(uint32_t arg) { LDKCResult_FundingSignedDecodeErrorZ *val = (LDKCResult_FundingSignedDecodeErrorZ*)(arg & ~1); CHECK(!val->result_ok); LDKDecodeError err_var = (*val->contents.err); CHECK((((uint64_t)err_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&err_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t err_ref = (uint64_t)err_var.inner & ~1; return err_ref; } jboolean __attribute__((visibility("default"))) TS_LDKCResult_FundingLockedDecodeErrorZ_result_ok(uint32_t arg) { return ((LDKCResult_FundingLockedDecodeErrorZ*)arg)->result_ok; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_FundingLockedDecodeErrorZ_get_ok(uint32_t arg) { LDKCResult_FundingLockedDecodeErrorZ *val = (LDKCResult_FundingLockedDecodeErrorZ*)(arg & ~1); CHECK(val->result_ok); LDKFundingLocked res_var = (*val->contents.result); CHECK((((uint64_t)res_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&res_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t res_ref = (uint64_t)res_var.inner & ~1; return res_ref; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_FundingLockedDecodeErrorZ_get_err(uint32_t arg) { LDKCResult_FundingLockedDecodeErrorZ *val = (LDKCResult_FundingLockedDecodeErrorZ*)(arg & ~1); CHECK(!val->result_ok); LDKDecodeError err_var = (*val->contents.err); CHECK((((uint64_t)err_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&err_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t err_ref = (uint64_t)err_var.inner & ~1; return err_ref; } jboolean __attribute__((visibility("default"))) TS_LDKCResult_InitDecodeErrorZ_result_ok(uint32_t arg) { return ((LDKCResult_InitDecodeErrorZ*)arg)->result_ok; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_InitDecodeErrorZ_get_ok(uint32_t arg) { LDKCResult_InitDecodeErrorZ *val = (LDKCResult_InitDecodeErrorZ*)(arg & ~1); CHECK(val->result_ok); LDKInit res_var = (*val->contents.result); CHECK((((uint64_t)res_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&res_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t res_ref = (uint64_t)res_var.inner & ~1; return res_ref; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_InitDecodeErrorZ_get_err(uint32_t arg) { LDKCResult_InitDecodeErrorZ *val = (LDKCResult_InitDecodeErrorZ*)(arg & ~1); CHECK(!val->result_ok); LDKDecodeError err_var = (*val->contents.err); CHECK((((uint64_t)err_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&err_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t err_ref = (uint64_t)err_var.inner & ~1; return err_ref; } jboolean __attribute__((visibility("default"))) TS_LDKCResult_OpenChannelDecodeErrorZ_result_ok(uint32_t arg) { return ((LDKCResult_OpenChannelDecodeErrorZ*)arg)->result_ok; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_OpenChannelDecodeErrorZ_get_ok(uint32_t arg) { LDKCResult_OpenChannelDecodeErrorZ *val = (LDKCResult_OpenChannelDecodeErrorZ*)(arg & ~1); CHECK(val->result_ok); LDKOpenChannel res_var = (*val->contents.result); CHECK((((uint64_t)res_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&res_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t res_ref = (uint64_t)res_var.inner & ~1; return res_ref; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_OpenChannelDecodeErrorZ_get_err(uint32_t arg) { LDKCResult_OpenChannelDecodeErrorZ *val = (LDKCResult_OpenChannelDecodeErrorZ*)(arg & ~1); CHECK(!val->result_ok); LDKDecodeError err_var = (*val->contents.err); CHECK((((uint64_t)err_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&err_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t err_ref = (uint64_t)err_var.inner & ~1; return err_ref; } jboolean __attribute__((visibility("default"))) TS_LDKCResult_RevokeAndACKDecodeErrorZ_result_ok(uint32_t arg) { return ((LDKCResult_RevokeAndACKDecodeErrorZ*)arg)->result_ok; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_RevokeAndACKDecodeErrorZ_get_ok(uint32_t arg) { LDKCResult_RevokeAndACKDecodeErrorZ *val = (LDKCResult_RevokeAndACKDecodeErrorZ*)(arg & ~1); CHECK(val->result_ok); LDKRevokeAndACK res_var = (*val->contents.result); CHECK((((uint64_t)res_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&res_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t res_ref = (uint64_t)res_var.inner & ~1; return res_ref; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_RevokeAndACKDecodeErrorZ_get_err(uint32_t arg) { LDKCResult_RevokeAndACKDecodeErrorZ *val = (LDKCResult_RevokeAndACKDecodeErrorZ*)(arg & ~1); CHECK(!val->result_ok); LDKDecodeError err_var = (*val->contents.err); CHECK((((uint64_t)err_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&err_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t err_ref = (uint64_t)err_var.inner & ~1; return err_ref; } jboolean __attribute__((visibility("default"))) TS_LDKCResult_ShutdownDecodeErrorZ_result_ok(uint32_t arg) { return ((LDKCResult_ShutdownDecodeErrorZ*)arg)->result_ok; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_ShutdownDecodeErrorZ_get_ok(uint32_t arg) { LDKCResult_ShutdownDecodeErrorZ *val = (LDKCResult_ShutdownDecodeErrorZ*)(arg & ~1); CHECK(val->result_ok); LDKShutdown res_var = (*val->contents.result); CHECK((((uint64_t)res_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&res_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t res_ref = (uint64_t)res_var.inner & ~1; return res_ref; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_ShutdownDecodeErrorZ_get_err(uint32_t arg) { LDKCResult_ShutdownDecodeErrorZ *val = (LDKCResult_ShutdownDecodeErrorZ*)(arg & ~1); CHECK(!val->result_ok); LDKDecodeError err_var = (*val->contents.err); CHECK((((uint64_t)err_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&err_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t err_ref = (uint64_t)err_var.inner & ~1; return err_ref; } jboolean __attribute__((visibility("default"))) TS_LDKCResult_UpdateFailHTLCDecodeErrorZ_result_ok(uint32_t arg) { return ((LDKCResult_UpdateFailHTLCDecodeErrorZ*)arg)->result_ok; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_UpdateFailHTLCDecodeErrorZ_get_ok(uint32_t arg) { LDKCResult_UpdateFailHTLCDecodeErrorZ *val = (LDKCResult_UpdateFailHTLCDecodeErrorZ*)(arg & ~1); CHECK(val->result_ok); LDKUpdateFailHTLC res_var = (*val->contents.result); CHECK((((uint64_t)res_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&res_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t res_ref = (uint64_t)res_var.inner & ~1; return res_ref; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_UpdateFailHTLCDecodeErrorZ_get_err(uint32_t arg) { LDKCResult_UpdateFailHTLCDecodeErrorZ *val = (LDKCResult_UpdateFailHTLCDecodeErrorZ*)(arg & ~1); CHECK(!val->result_ok); LDKDecodeError err_var = (*val->contents.err); CHECK((((uint64_t)err_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&err_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t err_ref = (uint64_t)err_var.inner & ~1; return err_ref; } jboolean __attribute__((visibility("default"))) TS_LDKCResult_UpdateFailMalformedHTLCDecodeErrorZ_result_ok(uint32_t arg) { return ((LDKCResult_UpdateFailMalformedHTLCDecodeErrorZ*)arg)->result_ok; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_UpdateFailMalformedHTLCDecodeErrorZ_get_ok(uint32_t arg) { LDKCResult_UpdateFailMalformedHTLCDecodeErrorZ *val = (LDKCResult_UpdateFailMalformedHTLCDecodeErrorZ*)(arg & ~1); CHECK(val->result_ok); LDKUpdateFailMalformedHTLC res_var = (*val->contents.result); CHECK((((uint64_t)res_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&res_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t res_ref = (uint64_t)res_var.inner & ~1; return res_ref; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_UpdateFailMalformedHTLCDecodeErrorZ_get_err(uint32_t arg) { LDKCResult_UpdateFailMalformedHTLCDecodeErrorZ *val = (LDKCResult_UpdateFailMalformedHTLCDecodeErrorZ*)(arg & ~1); CHECK(!val->result_ok); LDKDecodeError err_var = (*val->contents.err); CHECK((((uint64_t)err_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&err_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t err_ref = (uint64_t)err_var.inner & ~1; return err_ref; } jboolean __attribute__((visibility("default"))) TS_LDKCResult_UpdateFeeDecodeErrorZ_result_ok(uint32_t arg) { return ((LDKCResult_UpdateFeeDecodeErrorZ*)arg)->result_ok; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_UpdateFeeDecodeErrorZ_get_ok(uint32_t arg) { LDKCResult_UpdateFeeDecodeErrorZ *val = (LDKCResult_UpdateFeeDecodeErrorZ*)(arg & ~1); CHECK(val->result_ok); LDKUpdateFee res_var = (*val->contents.result); CHECK((((uint64_t)res_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&res_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t res_ref = (uint64_t)res_var.inner & ~1; return res_ref; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_UpdateFeeDecodeErrorZ_get_err(uint32_t arg) { LDKCResult_UpdateFeeDecodeErrorZ *val = (LDKCResult_UpdateFeeDecodeErrorZ*)(arg & ~1); CHECK(!val->result_ok); LDKDecodeError err_var = (*val->contents.err); CHECK((((uint64_t)err_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&err_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t err_ref = (uint64_t)err_var.inner & ~1; return err_ref; } jboolean __attribute__((visibility("default"))) TS_LDKCResult_UpdateFulfillHTLCDecodeErrorZ_result_ok(uint32_t arg) { return ((LDKCResult_UpdateFulfillHTLCDecodeErrorZ*)arg)->result_ok; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_UpdateFulfillHTLCDecodeErrorZ_get_ok(uint32_t arg) { LDKCResult_UpdateFulfillHTLCDecodeErrorZ *val = (LDKCResult_UpdateFulfillHTLCDecodeErrorZ*)(arg & ~1); CHECK(val->result_ok); LDKUpdateFulfillHTLC res_var = (*val->contents.result); CHECK((((uint64_t)res_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&res_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t res_ref = (uint64_t)res_var.inner & ~1; return res_ref; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_UpdateFulfillHTLCDecodeErrorZ_get_err(uint32_t arg) { LDKCResult_UpdateFulfillHTLCDecodeErrorZ *val = (LDKCResult_UpdateFulfillHTLCDecodeErrorZ*)(arg & ~1); CHECK(!val->result_ok); LDKDecodeError err_var = (*val->contents.err); CHECK((((uint64_t)err_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&err_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t err_ref = (uint64_t)err_var.inner & ~1; return err_ref; } jboolean __attribute__((visibility("default"))) TS_LDKCResult_UpdateAddHTLCDecodeErrorZ_result_ok(uint32_t arg) { return ((LDKCResult_UpdateAddHTLCDecodeErrorZ*)arg)->result_ok; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_UpdateAddHTLCDecodeErrorZ_get_ok(uint32_t arg) { LDKCResult_UpdateAddHTLCDecodeErrorZ *val = (LDKCResult_UpdateAddHTLCDecodeErrorZ*)(arg & ~1); CHECK(val->result_ok); LDKUpdateAddHTLC res_var = (*val->contents.result); CHECK((((uint64_t)res_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&res_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t res_ref = (uint64_t)res_var.inner & ~1; return res_ref; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_UpdateAddHTLCDecodeErrorZ_get_err(uint32_t arg) { LDKCResult_UpdateAddHTLCDecodeErrorZ *val = (LDKCResult_UpdateAddHTLCDecodeErrorZ*)(arg & ~1); CHECK(!val->result_ok); LDKDecodeError err_var = (*val->contents.err); CHECK((((uint64_t)err_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&err_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t err_ref = (uint64_t)err_var.inner & ~1; return err_ref; } jboolean __attribute__((visibility("default"))) TS_LDKCResult_PingDecodeErrorZ_result_ok(uint32_t arg) { return ((LDKCResult_PingDecodeErrorZ*)arg)->result_ok; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_PingDecodeErrorZ_get_ok(uint32_t arg) { LDKCResult_PingDecodeErrorZ *val = (LDKCResult_PingDecodeErrorZ*)(arg & ~1); CHECK(val->result_ok); LDKPing res_var = (*val->contents.result); CHECK((((uint64_t)res_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&res_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t res_ref = (uint64_t)res_var.inner & ~1; return res_ref; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_PingDecodeErrorZ_get_err(uint32_t arg) { LDKCResult_PingDecodeErrorZ *val = (LDKCResult_PingDecodeErrorZ*)(arg & ~1); CHECK(!val->result_ok); LDKDecodeError err_var = (*val->contents.err); CHECK((((uint64_t)err_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&err_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t err_ref = (uint64_t)err_var.inner & ~1; return err_ref; } jboolean __attribute__((visibility("default"))) TS_LDKCResult_PongDecodeErrorZ_result_ok(uint32_t arg) { return ((LDKCResult_PongDecodeErrorZ*)arg)->result_ok; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_PongDecodeErrorZ_get_ok(uint32_t arg) { LDKCResult_PongDecodeErrorZ *val = (LDKCResult_PongDecodeErrorZ*)(arg & ~1); CHECK(val->result_ok); LDKPong res_var = (*val->contents.result); CHECK((((uint64_t)res_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&res_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t res_ref = (uint64_t)res_var.inner & ~1; return res_ref; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_PongDecodeErrorZ_get_err(uint32_t arg) { LDKCResult_PongDecodeErrorZ *val = (LDKCResult_PongDecodeErrorZ*)(arg & ~1); CHECK(!val->result_ok); LDKDecodeError err_var = (*val->contents.err); CHECK((((uint64_t)err_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&err_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t err_ref = (uint64_t)err_var.inner & ~1; return err_ref; } jboolean __attribute__((visibility("default"))) TS_LDKCResult_UnsignedChannelAnnouncementDecodeErrorZ_result_ok(uint32_t arg) { return ((LDKCResult_UnsignedChannelAnnouncementDecodeErrorZ*)arg)->result_ok; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_UnsignedChannelAnnouncementDecodeErrorZ_get_ok(uint32_t arg) { LDKCResult_UnsignedChannelAnnouncementDecodeErrorZ *val = (LDKCResult_UnsignedChannelAnnouncementDecodeErrorZ*)(arg & ~1); CHECK(val->result_ok); LDKUnsignedChannelAnnouncement res_var = (*val->contents.result); CHECK((((uint64_t)res_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&res_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t res_ref = (uint64_t)res_var.inner & ~1; return res_ref; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_UnsignedChannelAnnouncementDecodeErrorZ_get_err(uint32_t arg) { LDKCResult_UnsignedChannelAnnouncementDecodeErrorZ *val = (LDKCResult_UnsignedChannelAnnouncementDecodeErrorZ*)(arg & ~1); CHECK(!val->result_ok); LDKDecodeError err_var = (*val->contents.err); CHECK((((uint64_t)err_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&err_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t err_ref = (uint64_t)err_var.inner & ~1; return err_ref; } jboolean __attribute__((visibility("default"))) TS_LDKCResult_ChannelAnnouncementDecodeErrorZ_result_ok(uint32_t arg) { return ((LDKCResult_ChannelAnnouncementDecodeErrorZ*)arg)->result_ok; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_ChannelAnnouncementDecodeErrorZ_get_ok(uint32_t arg) { LDKCResult_ChannelAnnouncementDecodeErrorZ *val = (LDKCResult_ChannelAnnouncementDecodeErrorZ*)(arg & ~1); CHECK(val->result_ok); LDKChannelAnnouncement res_var = (*val->contents.result); CHECK((((uint64_t)res_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&res_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t res_ref = (uint64_t)res_var.inner & ~1; return res_ref; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_ChannelAnnouncementDecodeErrorZ_get_err(uint32_t arg) { LDKCResult_ChannelAnnouncementDecodeErrorZ *val = (LDKCResult_ChannelAnnouncementDecodeErrorZ*)(arg & ~1); CHECK(!val->result_ok); LDKDecodeError err_var = (*val->contents.err); CHECK((((uint64_t)err_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&err_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t err_ref = (uint64_t)err_var.inner & ~1; return err_ref; } jboolean __attribute__((visibility("default"))) TS_LDKCResult_UnsignedChannelUpdateDecodeErrorZ_result_ok(uint32_t arg) { return ((LDKCResult_UnsignedChannelUpdateDecodeErrorZ*)arg)->result_ok; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_UnsignedChannelUpdateDecodeErrorZ_get_ok(uint32_t arg) { LDKCResult_UnsignedChannelUpdateDecodeErrorZ *val = (LDKCResult_UnsignedChannelUpdateDecodeErrorZ*)(arg & ~1); CHECK(val->result_ok); LDKUnsignedChannelUpdate res_var = (*val->contents.result); CHECK((((uint64_t)res_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&res_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t res_ref = (uint64_t)res_var.inner & ~1; return res_ref; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_UnsignedChannelUpdateDecodeErrorZ_get_err(uint32_t arg) { LDKCResult_UnsignedChannelUpdateDecodeErrorZ *val = (LDKCResult_UnsignedChannelUpdateDecodeErrorZ*)(arg & ~1); CHECK(!val->result_ok); LDKDecodeError err_var = (*val->contents.err); CHECK((((uint64_t)err_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&err_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t err_ref = (uint64_t)err_var.inner & ~1; return err_ref; } jboolean __attribute__((visibility("default"))) TS_LDKCResult_ChannelUpdateDecodeErrorZ_result_ok(uint32_t arg) { return ((LDKCResult_ChannelUpdateDecodeErrorZ*)arg)->result_ok; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_ChannelUpdateDecodeErrorZ_get_ok(uint32_t arg) { LDKCResult_ChannelUpdateDecodeErrorZ *val = (LDKCResult_ChannelUpdateDecodeErrorZ*)(arg & ~1); CHECK(val->result_ok); LDKChannelUpdate res_var = (*val->contents.result); CHECK((((uint64_t)res_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&res_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t res_ref = (uint64_t)res_var.inner & ~1; return res_ref; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_ChannelUpdateDecodeErrorZ_get_err(uint32_t arg) { LDKCResult_ChannelUpdateDecodeErrorZ *val = (LDKCResult_ChannelUpdateDecodeErrorZ*)(arg & ~1); CHECK(!val->result_ok); LDKDecodeError err_var = (*val->contents.err); CHECK((((uint64_t)err_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&err_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t err_ref = (uint64_t)err_var.inner & ~1; return err_ref; } jboolean __attribute__((visibility("default"))) TS_LDKCResult_ErrorMessageDecodeErrorZ_result_ok(uint32_t arg) { return ((LDKCResult_ErrorMessageDecodeErrorZ*)arg)->result_ok; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_ErrorMessageDecodeErrorZ_get_ok(uint32_t arg) { LDKCResult_ErrorMessageDecodeErrorZ *val = (LDKCResult_ErrorMessageDecodeErrorZ*)(arg & ~1); CHECK(val->result_ok); LDKErrorMessage res_var = (*val->contents.result); CHECK((((uint64_t)res_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&res_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t res_ref = (uint64_t)res_var.inner & ~1; return res_ref; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_ErrorMessageDecodeErrorZ_get_err(uint32_t arg) { LDKCResult_ErrorMessageDecodeErrorZ *val = (LDKCResult_ErrorMessageDecodeErrorZ*)(arg & ~1); CHECK(!val->result_ok); LDKDecodeError err_var = (*val->contents.err); CHECK((((uint64_t)err_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&err_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t err_ref = (uint64_t)err_var.inner & ~1; return err_ref; } jboolean __attribute__((visibility("default"))) TS_LDKCResult_UnsignedNodeAnnouncementDecodeErrorZ_result_ok(uint32_t arg) { return ((LDKCResult_UnsignedNodeAnnouncementDecodeErrorZ*)arg)->result_ok; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_UnsignedNodeAnnouncementDecodeErrorZ_get_ok(uint32_t arg) { LDKCResult_UnsignedNodeAnnouncementDecodeErrorZ *val = (LDKCResult_UnsignedNodeAnnouncementDecodeErrorZ*)(arg & ~1); CHECK(val->result_ok); LDKUnsignedNodeAnnouncement res_var = (*val->contents.result); CHECK((((uint64_t)res_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&res_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t res_ref = (uint64_t)res_var.inner & ~1; return res_ref; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_UnsignedNodeAnnouncementDecodeErrorZ_get_err(uint32_t arg) { LDKCResult_UnsignedNodeAnnouncementDecodeErrorZ *val = (LDKCResult_UnsignedNodeAnnouncementDecodeErrorZ*)(arg & ~1); CHECK(!val->result_ok); LDKDecodeError err_var = (*val->contents.err); CHECK((((uint64_t)err_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&err_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t err_ref = (uint64_t)err_var.inner & ~1; return err_ref; } jboolean __attribute__((visibility("default"))) TS_LDKCResult_NodeAnnouncementDecodeErrorZ_result_ok(uint32_t arg) { return ((LDKCResult_NodeAnnouncementDecodeErrorZ*)arg)->result_ok; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_NodeAnnouncementDecodeErrorZ_get_ok(uint32_t arg) { LDKCResult_NodeAnnouncementDecodeErrorZ *val = (LDKCResult_NodeAnnouncementDecodeErrorZ*)(arg & ~1); CHECK(val->result_ok); LDKNodeAnnouncement res_var = (*val->contents.result); CHECK((((uint64_t)res_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&res_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t res_ref = (uint64_t)res_var.inner & ~1; return res_ref; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_NodeAnnouncementDecodeErrorZ_get_err(uint32_t arg) { LDKCResult_NodeAnnouncementDecodeErrorZ *val = (LDKCResult_NodeAnnouncementDecodeErrorZ*)(arg & ~1); CHECK(!val->result_ok); LDKDecodeError err_var = (*val->contents.err); CHECK((((uint64_t)err_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&err_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t err_ref = (uint64_t)err_var.inner & ~1; return err_ref; } jboolean __attribute__((visibility("default"))) TS_LDKCResult_QueryShortChannelIdsDecodeErrorZ_result_ok(uint32_t arg) { return ((LDKCResult_QueryShortChannelIdsDecodeErrorZ*)arg)->result_ok; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_QueryShortChannelIdsDecodeErrorZ_get_ok(uint32_t arg) { LDKCResult_QueryShortChannelIdsDecodeErrorZ *val = (LDKCResult_QueryShortChannelIdsDecodeErrorZ*)(arg & ~1); CHECK(val->result_ok); LDKQueryShortChannelIds res_var = (*val->contents.result); CHECK((((uint64_t)res_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&res_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t res_ref = (uint64_t)res_var.inner & ~1; return res_ref; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_QueryShortChannelIdsDecodeErrorZ_get_err(uint32_t arg) { LDKCResult_QueryShortChannelIdsDecodeErrorZ *val = (LDKCResult_QueryShortChannelIdsDecodeErrorZ*)(arg & ~1); CHECK(!val->result_ok); LDKDecodeError err_var = (*val->contents.err); CHECK((((uint64_t)err_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&err_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t err_ref = (uint64_t)err_var.inner & ~1; return err_ref; } jboolean __attribute__((visibility("default"))) TS_LDKCResult_ReplyShortChannelIdsEndDecodeErrorZ_result_ok(uint32_t arg) { return ((LDKCResult_ReplyShortChannelIdsEndDecodeErrorZ*)arg)->result_ok; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_ReplyShortChannelIdsEndDecodeErrorZ_get_ok(uint32_t arg) { LDKCResult_ReplyShortChannelIdsEndDecodeErrorZ *val = (LDKCResult_ReplyShortChannelIdsEndDecodeErrorZ*)(arg & ~1); CHECK(val->result_ok); LDKReplyShortChannelIdsEnd res_var = (*val->contents.result); CHECK((((uint64_t)res_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&res_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t res_ref = (uint64_t)res_var.inner & ~1; return res_ref; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_ReplyShortChannelIdsEndDecodeErrorZ_get_err(uint32_t arg) { LDKCResult_ReplyShortChannelIdsEndDecodeErrorZ *val = (LDKCResult_ReplyShortChannelIdsEndDecodeErrorZ*)(arg & ~1); CHECK(!val->result_ok); LDKDecodeError err_var = (*val->contents.err); CHECK((((uint64_t)err_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&err_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t err_ref = (uint64_t)err_var.inner & ~1; return err_ref; } jboolean __attribute__((visibility("default"))) TS_LDKCResult_QueryChannelRangeDecodeErrorZ_result_ok(uint32_t arg) { return ((LDKCResult_QueryChannelRangeDecodeErrorZ*)arg)->result_ok; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_QueryChannelRangeDecodeErrorZ_get_ok(uint32_t arg) { LDKCResult_QueryChannelRangeDecodeErrorZ *val = (LDKCResult_QueryChannelRangeDecodeErrorZ*)(arg & ~1); CHECK(val->result_ok); LDKQueryChannelRange res_var = (*val->contents.result); CHECK((((uint64_t)res_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&res_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t res_ref = (uint64_t)res_var.inner & ~1; return res_ref; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_QueryChannelRangeDecodeErrorZ_get_err(uint32_t arg) { LDKCResult_QueryChannelRangeDecodeErrorZ *val = (LDKCResult_QueryChannelRangeDecodeErrorZ*)(arg & ~1); CHECK(!val->result_ok); LDKDecodeError err_var = (*val->contents.err); CHECK((((uint64_t)err_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&err_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t err_ref = (uint64_t)err_var.inner & ~1; return err_ref; } jboolean __attribute__((visibility("default"))) TS_LDKCResult_ReplyChannelRangeDecodeErrorZ_result_ok(uint32_t arg) { return ((LDKCResult_ReplyChannelRangeDecodeErrorZ*)arg)->result_ok; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_ReplyChannelRangeDecodeErrorZ_get_ok(uint32_t arg) { LDKCResult_ReplyChannelRangeDecodeErrorZ *val = (LDKCResult_ReplyChannelRangeDecodeErrorZ*)(arg & ~1); CHECK(val->result_ok); LDKReplyChannelRange res_var = (*val->contents.result); CHECK((((uint64_t)res_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&res_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t res_ref = (uint64_t)res_var.inner & ~1; return res_ref; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_ReplyChannelRangeDecodeErrorZ_get_err(uint32_t arg) { LDKCResult_ReplyChannelRangeDecodeErrorZ *val = (LDKCResult_ReplyChannelRangeDecodeErrorZ*)(arg & ~1); CHECK(!val->result_ok); LDKDecodeError err_var = (*val->contents.err); CHECK((((uint64_t)err_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&err_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t err_ref = (uint64_t)err_var.inner & ~1; return err_ref; } jboolean __attribute__((visibility("default"))) TS_LDKCResult_GossipTimestampFilterDecodeErrorZ_result_ok(uint32_t arg) { return ((LDKCResult_GossipTimestampFilterDecodeErrorZ*)arg)->result_ok; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_GossipTimestampFilterDecodeErrorZ_get_ok(uint32_t arg) { LDKCResult_GossipTimestampFilterDecodeErrorZ *val = (LDKCResult_GossipTimestampFilterDecodeErrorZ*)(arg & ~1); CHECK(val->result_ok); LDKGossipTimestampFilter res_var = (*val->contents.result); CHECK((((uint64_t)res_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&res_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t res_ref = (uint64_t)res_var.inner & ~1; return res_ref; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_GossipTimestampFilterDecodeErrorZ_get_err(uint32_t arg) { LDKCResult_GossipTimestampFilterDecodeErrorZ *val = (LDKCResult_GossipTimestampFilterDecodeErrorZ*)(arg & ~1); CHECK(!val->result_ok); LDKDecodeError err_var = (*val->contents.err); CHECK((((uint64_t)err_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&err_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t err_ref = (uint64_t)err_var.inner & ~1; return err_ref; } uint32_t __attribute__((visibility("default"))) TS_LDKSignOrCreationError_ref_from_ptr(uint32_t ptr) { LDKSignOrCreationError *obj = (LDKSignOrCreationError*)(ptr & ~1); switch(obj->tag) { case LDKSignOrCreationError_SignError: { return 0 /* LDKSignOrCreationError - SignError */; } case LDKSignOrCreationError_CreationError: { uint32_t creation_error_conv = LDKCreationError_to_js(obj->creation_error); return 0 /* LDKSignOrCreationError - CreationError */; (void) creation_error_conv; } default: abort(); } } jboolean __attribute__((visibility("default"))) TS_LDKCResult_InvoiceSignOrCreationErrorZ_result_ok(uint32_t arg) { return ((LDKCResult_InvoiceSignOrCreationErrorZ*)arg)->result_ok; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_InvoiceSignOrCreationErrorZ_get_ok(uint32_t arg) { LDKCResult_InvoiceSignOrCreationErrorZ *val = (LDKCResult_InvoiceSignOrCreationErrorZ*)(arg & ~1); CHECK(val->result_ok); LDKInvoice res_var = (*val->contents.result); CHECK((((uint64_t)res_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&res_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t res_ref = (uint64_t)res_var.inner & ~1; return res_ref; } uint32_t __attribute__((visibility("default"))) TS_LDKCResult_InvoiceSignOrCreationErrorZ_get_err(uint32_t arg) { LDKCResult_InvoiceSignOrCreationErrorZ *val = (LDKCResult_InvoiceSignOrCreationErrorZ*)(arg & ~1); CHECK(!val->result_ok); uint64_t err_ref = ((uint64_t)&(*val->contents.err)) | 1; return err_ref; } typedef struct LDKFilter_JCalls { atomic_size_t refcnt; uint32_t register_tx_meth; uint32_t register_output_meth; } LDKFilter_JCalls; static void LDKFilter_JCalls_free(void* this_arg) { LDKFilter_JCalls *j_calls = (LDKFilter_JCalls*) this_arg; if (atomic_fetch_sub_explicit(&j_calls->refcnt, 1, memory_order_acquire) == 1) { js_free(j_calls->register_tx_meth); js_free(j_calls->register_output_meth); FREE(j_calls); } } void register_tx_LDKFilter_jcall(const void* this_arg, const uint8_t (* txid)[32], LDKu8slice script_pubkey) { LDKFilter_JCalls *j_calls = (LDKFilter_JCalls*) this_arg; int8_tArray txid_arr = init_arr(32, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(txid_arr + 4), *txid, 32); LDKu8slice script_pubkey_var = script_pubkey; int8_tArray script_pubkey_arr = init_arr(script_pubkey_var.datalen, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(script_pubkey_arr + 4), script_pubkey_var.data, script_pubkey_var.datalen); js_invoke_function_2(j_calls->register_tx_meth, txid_arr, script_pubkey_arr); } LDKCOption_C2Tuple_usizeTransactionZZ register_output_LDKFilter_jcall(const void* this_arg, LDKWatchedOutput output) { LDKFilter_JCalls *j_calls = (LDKFilter_JCalls*) this_arg; LDKWatchedOutput output_var = output; CHECK((((uint64_t)output_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&output_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t output_ref = (uint64_t)output_var.inner; if (output_var.is_owned) { output_ref |= 1; } uint32_t ret = js_invoke_function_1(j_calls->register_output_meth, output_ref); LDKCOption_C2Tuple_usizeTransactionZZ ret_conv = *(LDKCOption_C2Tuple_usizeTransactionZZ*)(((uint64_t)ret) & ~1); ret_conv = COption_C2Tuple_usizeTransactionZZ_clone((LDKCOption_C2Tuple_usizeTransactionZZ*)(((uint64_t)ret) & ~1)); return ret_conv; } static void LDKFilter_JCalls_cloned(LDKFilter* new_obj) { LDKFilter_JCalls *j_calls = (LDKFilter_JCalls*) new_obj->this_arg; atomic_fetch_add_explicit(&j_calls->refcnt, 1, memory_order_release); } static inline LDKFilter LDKFilter_init (/*TODO: JS Object Reference */void* o) { LDKFilter_JCalls *calls = MALLOC(sizeof(LDKFilter_JCalls), "LDKFilter_JCalls"); atomic_init(&calls->refcnt, 1); //TODO: Assign calls->o from o LDKFilter ret = { .this_arg = (void*) calls, .register_tx = register_tx_LDKFilter_jcall, .register_output = register_output_LDKFilter_jcall, .free = LDKFilter_JCalls_free, }; return ret; } long __attribute__((visibility("default"))) TS_LDKFilter_new(/*TODO: JS Object Reference */void* o) { LDKFilter *res_ptr = MALLOC(sizeof(LDKFilter), "LDKFilter"); *res_ptr = LDKFilter_init(o); return (long)res_ptr; } void __attribute__((visibility("default"))) TS_Filter_register_tx(uint32_t this_arg, int8_tArray txid, int8_tArray script_pubkey) { LDKFilter* this_arg_conv = (LDKFilter*)(((uint64_t)this_arg) & ~1); unsigned char txid_arr[32]; CHECK(*((uint32_t*)txid) == 32); memcpy(txid_arr, (uint8_t*)(txid + 4), 32); unsigned char (*txid_ref)[32] = &txid_arr; LDKu8slice script_pubkey_ref; script_pubkey_ref.datalen = *((uint32_t*)script_pubkey); script_pubkey_ref.data = (int8_t*)(script_pubkey + 4); (this_arg_conv->register_tx)(this_arg_conv->this_arg, txid_ref, script_pubkey_ref); } uint32_t __attribute__((visibility("default"))) TS_Filter_register_output(uint32_t this_arg, uint32_t output) { LDKFilter* this_arg_conv = (LDKFilter*)(((uint64_t)this_arg) & ~1); LDKWatchedOutput output_conv; output_conv.inner = (void*)(output & (~1)); output_conv.is_owned = (output & 1) || (output == 0); output_conv = WatchedOutput_clone(&output_conv); LDKCOption_C2Tuple_usizeTransactionZZ *ret_copy = MALLOC(sizeof(LDKCOption_C2Tuple_usizeTransactionZZ), "LDKCOption_C2Tuple_usizeTransactionZZ"); *ret_copy = (this_arg_conv->register_output)(this_arg_conv->this_arg, output_conv); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_LDKCOption_FilterZ_ref_from_ptr(uint32_t ptr) { LDKCOption_FilterZ *obj = (LDKCOption_FilterZ*)(ptr & ~1); switch(obj->tag) { case LDKCOption_FilterZ_Some: { LDKFilter* some_ret =MALLOC(sizeof(LDKFilter), "LDKFilter"); *some_ret = obj->some; // Warning: We likely need to clone here, but no clone is available, so we just do it for Java instances return 0 /* LDKCOption_FilterZ - Some */; (void) (uint64_t)some_ret; } case LDKCOption_FilterZ_None: { return 0 /* LDKCOption_FilterZ - None */; } default: abort(); } } typedef struct LDKMessageSendEventsProvider_JCalls { atomic_size_t refcnt; uint32_t get_and_clear_pending_msg_events_meth; } LDKMessageSendEventsProvider_JCalls; static void LDKMessageSendEventsProvider_JCalls_free(void* this_arg) { LDKMessageSendEventsProvider_JCalls *j_calls = (LDKMessageSendEventsProvider_JCalls*) this_arg; if (atomic_fetch_sub_explicit(&j_calls->refcnt, 1, memory_order_acquire) == 1) { js_free(j_calls->get_and_clear_pending_msg_events_meth); FREE(j_calls); } } LDKCVec_MessageSendEventZ get_and_clear_pending_msg_events_LDKMessageSendEventsProvider_jcall(const void* this_arg) { LDKMessageSendEventsProvider_JCalls *j_calls = (LDKMessageSendEventsProvider_JCalls*) this_arg; uint32_tArray ret = js_invoke_function_0(j_calls->get_and_clear_pending_msg_events_meth); LDKCVec_MessageSendEventZ ret_constr; ret_constr.datalen = *((uint32_t*)ret); if (ret_constr.datalen > 0) ret_constr.data = MALLOC(ret_constr.datalen * sizeof(LDKMessageSendEvent), "LDKCVec_MessageSendEventZ Elements"); else ret_constr.data = NULL; uint32_t* ret_vals = (uint32_t*)(ret + 4); for (size_t s = 0; s < ret_constr.datalen; s++) { uint32_t ret_conv_18 = ret_vals[s]; LDKMessageSendEvent ret_conv_18_conv = *(LDKMessageSendEvent*)(((uint64_t)ret_conv_18) & ~1); ret_conv_18_conv = MessageSendEvent_clone((LDKMessageSendEvent*)(((uint64_t)ret_conv_18) & ~1)); ret_constr.data[s] = ret_conv_18_conv; } return ret_constr; } static void LDKMessageSendEventsProvider_JCalls_cloned(LDKMessageSendEventsProvider* new_obj) { LDKMessageSendEventsProvider_JCalls *j_calls = (LDKMessageSendEventsProvider_JCalls*) new_obj->this_arg; atomic_fetch_add_explicit(&j_calls->refcnt, 1, memory_order_release); } static inline LDKMessageSendEventsProvider LDKMessageSendEventsProvider_init (/*TODO: JS Object Reference */void* o) { LDKMessageSendEventsProvider_JCalls *calls = MALLOC(sizeof(LDKMessageSendEventsProvider_JCalls), "LDKMessageSendEventsProvider_JCalls"); atomic_init(&calls->refcnt, 1); //TODO: Assign calls->o from o LDKMessageSendEventsProvider ret = { .this_arg = (void*) calls, .get_and_clear_pending_msg_events = get_and_clear_pending_msg_events_LDKMessageSendEventsProvider_jcall, .free = LDKMessageSendEventsProvider_JCalls_free, }; return ret; } long __attribute__((visibility("default"))) TS_LDKMessageSendEventsProvider_new(/*TODO: JS Object Reference */void* o) { LDKMessageSendEventsProvider *res_ptr = MALLOC(sizeof(LDKMessageSendEventsProvider), "LDKMessageSendEventsProvider"); *res_ptr = LDKMessageSendEventsProvider_init(o); return (long)res_ptr; } uint32_tArray __attribute__((visibility("default"))) TS_MessageSendEventsProvider_get_and_clear_pending_msg_events(uint32_t this_arg) { LDKMessageSendEventsProvider* this_arg_conv = (LDKMessageSendEventsProvider*)(((uint64_t)this_arg) & ~1); LDKCVec_MessageSendEventZ ret_var = (this_arg_conv->get_and_clear_pending_msg_events)(this_arg_conv->this_arg); uint32_tArray ret_arr = init_arr(ret_var.datalen, sizeof(uint32_t), "Native uint32_tArray Bytes"); uint32_t *ret_arr_ptr = (uint32_t*)(ret_arr + 4); for (size_t s = 0; s < ret_var.datalen; s++) { LDKMessageSendEvent *ret_conv_18_copy = MALLOC(sizeof(LDKMessageSendEvent), "LDKMessageSendEvent"); *ret_conv_18_copy = MessageSendEvent_clone(&ret_var.data[s]); uint64_t ret_conv_18_ref = (uint64_t)ret_conv_18_copy; ret_arr_ptr[s] = ret_conv_18_ref; } FREE(ret_var.data); return ret_arr; } typedef struct LDKEventHandler_JCalls { atomic_size_t refcnt; uint32_t handle_event_meth; } LDKEventHandler_JCalls; static void LDKEventHandler_JCalls_free(void* this_arg) { LDKEventHandler_JCalls *j_calls = (LDKEventHandler_JCalls*) this_arg; if (atomic_fetch_sub_explicit(&j_calls->refcnt, 1, memory_order_acquire) == 1) { js_free(j_calls->handle_event_meth); FREE(j_calls); } } void handle_event_LDKEventHandler_jcall(const void* this_arg, const LDKEvent * event) { LDKEventHandler_JCalls *j_calls = (LDKEventHandler_JCalls*) this_arg; LDKEvent *ret_event = MALLOC(sizeof(LDKEvent), "LDKEvent ret conversion"); *ret_event = Event_clone(event); js_invoke_function_1(j_calls->handle_event_meth, (uint64_t)ret_event); } static void LDKEventHandler_JCalls_cloned(LDKEventHandler* new_obj) { LDKEventHandler_JCalls *j_calls = (LDKEventHandler_JCalls*) new_obj->this_arg; atomic_fetch_add_explicit(&j_calls->refcnt, 1, memory_order_release); } static inline LDKEventHandler LDKEventHandler_init (/*TODO: JS Object Reference */void* o) { LDKEventHandler_JCalls *calls = MALLOC(sizeof(LDKEventHandler_JCalls), "LDKEventHandler_JCalls"); atomic_init(&calls->refcnt, 1); //TODO: Assign calls->o from o LDKEventHandler ret = { .this_arg = (void*) calls, .handle_event = handle_event_LDKEventHandler_jcall, .free = LDKEventHandler_JCalls_free, }; return ret; } long __attribute__((visibility("default"))) TS_LDKEventHandler_new(/*TODO: JS Object Reference */void* o) { LDKEventHandler *res_ptr = MALLOC(sizeof(LDKEventHandler), "LDKEventHandler"); *res_ptr = LDKEventHandler_init(o); return (long)res_ptr; } void __attribute__((visibility("default"))) TS_EventHandler_handle_event(uint32_t this_arg, uint32_t event) { LDKEventHandler* this_arg_conv = (LDKEventHandler*)(((uint64_t)this_arg) & ~1); LDKEvent* event_conv = (LDKEvent*)event; (this_arg_conv->handle_event)(this_arg_conv->this_arg, event_conv); } typedef struct LDKEventsProvider_JCalls { atomic_size_t refcnt; uint32_t process_pending_events_meth; } LDKEventsProvider_JCalls; static void LDKEventsProvider_JCalls_free(void* this_arg) { LDKEventsProvider_JCalls *j_calls = (LDKEventsProvider_JCalls*) this_arg; if (atomic_fetch_sub_explicit(&j_calls->refcnt, 1, memory_order_acquire) == 1) { js_free(j_calls->process_pending_events_meth); FREE(j_calls); } } void process_pending_events_LDKEventsProvider_jcall(const void* this_arg, LDKEventHandler handler) { LDKEventsProvider_JCalls *j_calls = (LDKEventsProvider_JCalls*) this_arg; LDKEventHandler* handler_ret =MALLOC(sizeof(LDKEventHandler), "LDKEventHandler"); *handler_ret = handler; js_invoke_function_1(j_calls->process_pending_events_meth, (uint64_t)handler_ret); } static void LDKEventsProvider_JCalls_cloned(LDKEventsProvider* new_obj) { LDKEventsProvider_JCalls *j_calls = (LDKEventsProvider_JCalls*) new_obj->this_arg; atomic_fetch_add_explicit(&j_calls->refcnt, 1, memory_order_release); } static inline LDKEventsProvider LDKEventsProvider_init (/*TODO: JS Object Reference */void* o) { LDKEventsProvider_JCalls *calls = MALLOC(sizeof(LDKEventsProvider_JCalls), "LDKEventsProvider_JCalls"); atomic_init(&calls->refcnt, 1); //TODO: Assign calls->o from o LDKEventsProvider ret = { .this_arg = (void*) calls, .process_pending_events = process_pending_events_LDKEventsProvider_jcall, .free = LDKEventsProvider_JCalls_free, }; return ret; } long __attribute__((visibility("default"))) TS_LDKEventsProvider_new(/*TODO: JS Object Reference */void* o) { LDKEventsProvider *res_ptr = MALLOC(sizeof(LDKEventsProvider), "LDKEventsProvider"); *res_ptr = LDKEventsProvider_init(o); return (long)res_ptr; } void __attribute__((visibility("default"))) TS_EventsProvider_process_pending_events(uint32_t this_arg, uint32_t handler) { LDKEventsProvider* this_arg_conv = (LDKEventsProvider*)(((uint64_t)this_arg) & ~1); LDKEventHandler handler_conv = *(LDKEventHandler*)(((uint64_t)handler) & ~1); (this_arg_conv->process_pending_events)(this_arg_conv->this_arg, handler_conv); } typedef struct LDKListen_JCalls { atomic_size_t refcnt; uint32_t block_connected_meth; uint32_t block_disconnected_meth; } LDKListen_JCalls; static void LDKListen_JCalls_free(void* this_arg) { LDKListen_JCalls *j_calls = (LDKListen_JCalls*) this_arg; if (atomic_fetch_sub_explicit(&j_calls->refcnt, 1, memory_order_acquire) == 1) { js_free(j_calls->block_connected_meth); js_free(j_calls->block_disconnected_meth); FREE(j_calls); } } void block_connected_LDKListen_jcall(const void* this_arg, LDKu8slice block, uint32_t height) { LDKListen_JCalls *j_calls = (LDKListen_JCalls*) this_arg; LDKu8slice block_var = block; int8_tArray block_arr = init_arr(block_var.datalen, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(block_arr + 4), block_var.data, block_var.datalen); js_invoke_function_2(j_calls->block_connected_meth, block_arr, height); } void block_disconnected_LDKListen_jcall(const void* this_arg, const uint8_t (* header)[80], uint32_t height) { LDKListen_JCalls *j_calls = (LDKListen_JCalls*) this_arg; int8_tArray header_arr = init_arr(80, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(header_arr + 4), *header, 80); js_invoke_function_2(j_calls->block_disconnected_meth, header_arr, height); } static void LDKListen_JCalls_cloned(LDKListen* new_obj) { LDKListen_JCalls *j_calls = (LDKListen_JCalls*) new_obj->this_arg; atomic_fetch_add_explicit(&j_calls->refcnt, 1, memory_order_release); } static inline LDKListen LDKListen_init (/*TODO: JS Object Reference */void* o) { LDKListen_JCalls *calls = MALLOC(sizeof(LDKListen_JCalls), "LDKListen_JCalls"); atomic_init(&calls->refcnt, 1); //TODO: Assign calls->o from o LDKListen ret = { .this_arg = (void*) calls, .block_connected = block_connected_LDKListen_jcall, .block_disconnected = block_disconnected_LDKListen_jcall, .free = LDKListen_JCalls_free, }; return ret; } long __attribute__((visibility("default"))) TS_LDKListen_new(/*TODO: JS Object Reference */void* o) { LDKListen *res_ptr = MALLOC(sizeof(LDKListen), "LDKListen"); *res_ptr = LDKListen_init(o); return (long)res_ptr; } void __attribute__((visibility("default"))) TS_Listen_block_connected(uint32_t this_arg, int8_tArray block, int32_t height) { LDKListen* this_arg_conv = (LDKListen*)(((uint64_t)this_arg) & ~1); LDKu8slice block_ref; block_ref.datalen = *((uint32_t*)block); block_ref.data = (int8_t*)(block + 4); (this_arg_conv->block_connected)(this_arg_conv->this_arg, block_ref, height); } void __attribute__((visibility("default"))) TS_Listen_block_disconnected(uint32_t this_arg, int8_tArray header, int32_t height) { LDKListen* this_arg_conv = (LDKListen*)(((uint64_t)this_arg) & ~1); unsigned char header_arr[80]; CHECK(*((uint32_t*)header) == 80); memcpy(header_arr, (uint8_t*)(header + 4), 80); unsigned char (*header_ref)[80] = &header_arr; (this_arg_conv->block_disconnected)(this_arg_conv->this_arg, header_ref, height); } typedef struct LDKConfirm_JCalls { atomic_size_t refcnt; uint32_t transactions_confirmed_meth; uint32_t transaction_unconfirmed_meth; uint32_t best_block_updated_meth; uint32_t get_relevant_txids_meth; } LDKConfirm_JCalls; static void LDKConfirm_JCalls_free(void* this_arg) { LDKConfirm_JCalls *j_calls = (LDKConfirm_JCalls*) this_arg; if (atomic_fetch_sub_explicit(&j_calls->refcnt, 1, memory_order_acquire) == 1) { js_free(j_calls->transactions_confirmed_meth); js_free(j_calls->transaction_unconfirmed_meth); js_free(j_calls->best_block_updated_meth); js_free(j_calls->get_relevant_txids_meth); FREE(j_calls); } } void transactions_confirmed_LDKConfirm_jcall(const void* this_arg, const uint8_t (* header)[80], LDKCVec_C2Tuple_usizeTransactionZZ txdata, uint32_t height) { LDKConfirm_JCalls *j_calls = (LDKConfirm_JCalls*) this_arg; int8_tArray header_arr = init_arr(80, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(header_arr + 4), *header, 80); LDKCVec_C2Tuple_usizeTransactionZZ txdata_var = txdata; uint32_tArray txdata_arr = init_arr(txdata_var.datalen, sizeof(uint32_t), "Native uint32_tArray Bytes"); uint32_t *txdata_arr_ptr = (uint32_t*)(txdata_arr + 4); for (size_t e = 0; e < txdata_var.datalen; e++) { LDKC2Tuple_usizeTransactionZ* txdata_conv_30_ref = MALLOC(sizeof(LDKC2Tuple_usizeTransactionZ), "LDKC2Tuple_usizeTransactionZ"); *txdata_conv_30_ref = txdata_var.data[e]; txdata_arr_ptr[e] = (uint64_t)txdata_conv_30_ref; } FREE(txdata_var.data); js_invoke_function_3(j_calls->transactions_confirmed_meth, header_arr, txdata_arr, height); } void transaction_unconfirmed_LDKConfirm_jcall(const void* this_arg, const uint8_t (* txid)[32]) { LDKConfirm_JCalls *j_calls = (LDKConfirm_JCalls*) this_arg; int8_tArray txid_arr = init_arr(32, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(txid_arr + 4), *txid, 32); js_invoke_function_1(j_calls->transaction_unconfirmed_meth, txid_arr); } void best_block_updated_LDKConfirm_jcall(const void* this_arg, const uint8_t (* header)[80], uint32_t height) { LDKConfirm_JCalls *j_calls = (LDKConfirm_JCalls*) this_arg; int8_tArray header_arr = init_arr(80, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(header_arr + 4), *header, 80); js_invoke_function_2(j_calls->best_block_updated_meth, header_arr, height); } LDKCVec_TxidZ get_relevant_txids_LDKConfirm_jcall(const void* this_arg) { LDKConfirm_JCalls *j_calls = (LDKConfirm_JCalls*) this_arg; ptrArray ret = js_invoke_function_0(j_calls->get_relevant_txids_meth); LDKCVec_TxidZ ret_constr; ret_constr.datalen = *((uint32_t*)ret); if (ret_constr.datalen > 0) ret_constr.data = MALLOC(ret_constr.datalen * sizeof(LDKThirtyTwoBytes), "LDKCVec_TxidZ Elements"); else ret_constr.data = NULL; int8_tArray* ret_vals = (int8_tArray*)(ret + 4); for (size_t m = 0; m < ret_constr.datalen; m++) { int8_tArray ret_conv_12 = ret_vals[m]; LDKThirtyTwoBytes ret_conv_12_ref; CHECK(*((uint32_t*)ret_conv_12) == 32); memcpy(ret_conv_12_ref.data, (uint8_t*)(ret_conv_12 + 4), 32); ret_constr.data[m] = ret_conv_12_ref; } return ret_constr; } static void LDKConfirm_JCalls_cloned(LDKConfirm* new_obj) { LDKConfirm_JCalls *j_calls = (LDKConfirm_JCalls*) new_obj->this_arg; atomic_fetch_add_explicit(&j_calls->refcnt, 1, memory_order_release); } static inline LDKConfirm LDKConfirm_init (/*TODO: JS Object Reference */void* o) { LDKConfirm_JCalls *calls = MALLOC(sizeof(LDKConfirm_JCalls), "LDKConfirm_JCalls"); atomic_init(&calls->refcnt, 1); //TODO: Assign calls->o from o LDKConfirm ret = { .this_arg = (void*) calls, .transactions_confirmed = transactions_confirmed_LDKConfirm_jcall, .transaction_unconfirmed = transaction_unconfirmed_LDKConfirm_jcall, .best_block_updated = best_block_updated_LDKConfirm_jcall, .get_relevant_txids = get_relevant_txids_LDKConfirm_jcall, .free = LDKConfirm_JCalls_free, }; return ret; } long __attribute__((visibility("default"))) TS_LDKConfirm_new(/*TODO: JS Object Reference */void* o) { LDKConfirm *res_ptr = MALLOC(sizeof(LDKConfirm), "LDKConfirm"); *res_ptr = LDKConfirm_init(o); return (long)res_ptr; } void __attribute__((visibility("default"))) TS_Confirm_transactions_confirmed(uint32_t this_arg, int8_tArray header, uint32_tArray txdata, int32_t height) { LDKConfirm* this_arg_conv = (LDKConfirm*)(((uint64_t)this_arg) & ~1); unsigned char header_arr[80]; CHECK(*((uint32_t*)header) == 80); memcpy(header_arr, (uint8_t*)(header + 4), 80); unsigned char (*header_ref)[80] = &header_arr; LDKCVec_C2Tuple_usizeTransactionZZ txdata_constr; txdata_constr.datalen = *((uint32_t*)txdata); if (txdata_constr.datalen > 0) txdata_constr.data = MALLOC(txdata_constr.datalen * sizeof(LDKC2Tuple_usizeTransactionZ), "LDKCVec_C2Tuple_usizeTransactionZZ Elements"); else txdata_constr.data = NULL; uint32_t* txdata_vals = (uint32_t*)(txdata + 4); for (size_t e = 0; e < txdata_constr.datalen; e++) { uint32_t txdata_conv_30 = txdata_vals[e]; LDKC2Tuple_usizeTransactionZ txdata_conv_30_conv = *(LDKC2Tuple_usizeTransactionZ*)(((uint64_t)txdata_conv_30) & ~1); txdata_conv_30_conv = C2Tuple_usizeTransactionZ_clone((LDKC2Tuple_usizeTransactionZ*)(((uint64_t)txdata_conv_30) & ~1)); txdata_constr.data[e] = txdata_conv_30_conv; } (this_arg_conv->transactions_confirmed)(this_arg_conv->this_arg, header_ref, txdata_constr, height); } void __attribute__((visibility("default"))) TS_Confirm_transaction_unconfirmed(uint32_t this_arg, int8_tArray txid) { LDKConfirm* this_arg_conv = (LDKConfirm*)(((uint64_t)this_arg) & ~1); unsigned char txid_arr[32]; CHECK(*((uint32_t*)txid) == 32); memcpy(txid_arr, (uint8_t*)(txid + 4), 32); unsigned char (*txid_ref)[32] = &txid_arr; (this_arg_conv->transaction_unconfirmed)(this_arg_conv->this_arg, txid_ref); } void __attribute__((visibility("default"))) TS_Confirm_best_block_updated(uint32_t this_arg, int8_tArray header, int32_t height) { LDKConfirm* this_arg_conv = (LDKConfirm*)(((uint64_t)this_arg) & ~1); unsigned char header_arr[80]; CHECK(*((uint32_t*)header) == 80); memcpy(header_arr, (uint8_t*)(header + 4), 80); unsigned char (*header_ref)[80] = &header_arr; (this_arg_conv->best_block_updated)(this_arg_conv->this_arg, header_ref, height); } ptrArray __attribute__((visibility("default"))) TS_Confirm_get_relevant_txids(uint32_t this_arg) { LDKConfirm* this_arg_conv = (LDKConfirm*)(((uint64_t)this_arg) & ~1); LDKCVec_TxidZ ret_var = (this_arg_conv->get_relevant_txids)(this_arg_conv->this_arg); ptrArray ret_arr = init_arr(ret_var.datalen, sizeof(uint32_t), "Native ptrArray Bytes"); int8_tArray *ret_arr_ptr = (int8_tArray*)(ret_arr + 4); for (size_t m = 0; m < ret_var.datalen; m++) { int8_tArray ret_conv_12_arr = init_arr(32, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_conv_12_arr + 4), ret_var.data[m].data, 32); ret_arr_ptr[m] = ret_conv_12_arr; } FREE(ret_var.data); return ret_arr; } typedef struct LDKPersist_JCalls { atomic_size_t refcnt; uint32_t persist_new_channel_meth; uint32_t update_persisted_channel_meth; } LDKPersist_JCalls; static void LDKPersist_JCalls_free(void* this_arg) { LDKPersist_JCalls *j_calls = (LDKPersist_JCalls*) this_arg; if (atomic_fetch_sub_explicit(&j_calls->refcnt, 1, memory_order_acquire) == 1) { js_free(j_calls->persist_new_channel_meth); js_free(j_calls->update_persisted_channel_meth); FREE(j_calls); } } LDKCResult_NoneChannelMonitorUpdateErrZ persist_new_channel_LDKPersist_jcall(const void* this_arg, LDKOutPoint id, const LDKChannelMonitor * data) { LDKPersist_JCalls *j_calls = (LDKPersist_JCalls*) this_arg; LDKOutPoint id_var = id; CHECK((((uint64_t)id_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&id_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t id_ref = (uint64_t)id_var.inner; if (id_var.is_owned) { id_ref |= 1; } LDKChannelMonitor data_var = *data; data_var = ChannelMonitor_clone(data); CHECK((((uint64_t)data_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&data_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t data_ref = (uint64_t)data_var.inner; if (data_var.is_owned) { data_ref |= 1; } uint32_t ret = js_invoke_function_2(j_calls->persist_new_channel_meth, id_ref, data_ref); LDKCResult_NoneChannelMonitorUpdateErrZ ret_conv = *(LDKCResult_NoneChannelMonitorUpdateErrZ*)(((uint64_t)ret) & ~1); ret_conv = CResult_NoneChannelMonitorUpdateErrZ_clone((LDKCResult_NoneChannelMonitorUpdateErrZ*)(((uint64_t)ret) & ~1)); return ret_conv; } LDKCResult_NoneChannelMonitorUpdateErrZ update_persisted_channel_LDKPersist_jcall(const void* this_arg, LDKOutPoint id, const LDKChannelMonitorUpdate * update, const LDKChannelMonitor * data) { LDKPersist_JCalls *j_calls = (LDKPersist_JCalls*) this_arg; LDKOutPoint id_var = id; CHECK((((uint64_t)id_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&id_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t id_ref = (uint64_t)id_var.inner; if (id_var.is_owned) { id_ref |= 1; } LDKChannelMonitorUpdate update_var = *update; update_var = ChannelMonitorUpdate_clone(update); CHECK((((uint64_t)update_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&update_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t update_ref = (uint64_t)update_var.inner; if (update_var.is_owned) { update_ref |= 1; } LDKChannelMonitor data_var = *data; data_var = ChannelMonitor_clone(data); CHECK((((uint64_t)data_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&data_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t data_ref = (uint64_t)data_var.inner; if (data_var.is_owned) { data_ref |= 1; } uint32_t ret = js_invoke_function_3(j_calls->update_persisted_channel_meth, id_ref, update_ref, data_ref); LDKCResult_NoneChannelMonitorUpdateErrZ ret_conv = *(LDKCResult_NoneChannelMonitorUpdateErrZ*)(((uint64_t)ret) & ~1); ret_conv = CResult_NoneChannelMonitorUpdateErrZ_clone((LDKCResult_NoneChannelMonitorUpdateErrZ*)(((uint64_t)ret) & ~1)); return ret_conv; } static void LDKPersist_JCalls_cloned(LDKPersist* new_obj) { LDKPersist_JCalls *j_calls = (LDKPersist_JCalls*) new_obj->this_arg; atomic_fetch_add_explicit(&j_calls->refcnt, 1, memory_order_release); } static inline LDKPersist LDKPersist_init (/*TODO: JS Object Reference */void* o) { LDKPersist_JCalls *calls = MALLOC(sizeof(LDKPersist_JCalls), "LDKPersist_JCalls"); atomic_init(&calls->refcnt, 1); //TODO: Assign calls->o from o LDKPersist ret = { .this_arg = (void*) calls, .persist_new_channel = persist_new_channel_LDKPersist_jcall, .update_persisted_channel = update_persisted_channel_LDKPersist_jcall, .free = LDKPersist_JCalls_free, }; return ret; } long __attribute__((visibility("default"))) TS_LDKPersist_new(/*TODO: JS Object Reference */void* o) { LDKPersist *res_ptr = MALLOC(sizeof(LDKPersist), "LDKPersist"); *res_ptr = LDKPersist_init(o); return (long)res_ptr; } uint32_t __attribute__((visibility("default"))) TS_Persist_persist_new_channel(uint32_t this_arg, uint32_t id, uint32_t data) { LDKPersist* this_arg_conv = (LDKPersist*)(((uint64_t)this_arg) & ~1); LDKOutPoint id_conv; id_conv.inner = (void*)(id & (~1)); id_conv.is_owned = (id & 1) || (id == 0); id_conv = OutPoint_clone(&id_conv); LDKChannelMonitor data_conv; data_conv.inner = (void*)(data & (~1)); data_conv.is_owned = false; LDKCResult_NoneChannelMonitorUpdateErrZ* ret_conv = MALLOC(sizeof(LDKCResult_NoneChannelMonitorUpdateErrZ), "LDKCResult_NoneChannelMonitorUpdateErrZ"); *ret_conv = (this_arg_conv->persist_new_channel)(this_arg_conv->this_arg, id_conv, &data_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_Persist_update_persisted_channel(uint32_t this_arg, uint32_t id, uint32_t update, uint32_t data) { LDKPersist* this_arg_conv = (LDKPersist*)(((uint64_t)this_arg) & ~1); LDKOutPoint id_conv; id_conv.inner = (void*)(id & (~1)); id_conv.is_owned = (id & 1) || (id == 0); id_conv = OutPoint_clone(&id_conv); LDKChannelMonitorUpdate update_conv; update_conv.inner = (void*)(update & (~1)); update_conv.is_owned = false; LDKChannelMonitor data_conv; data_conv.inner = (void*)(data & (~1)); data_conv.is_owned = false; LDKCResult_NoneChannelMonitorUpdateErrZ* ret_conv = MALLOC(sizeof(LDKCResult_NoneChannelMonitorUpdateErrZ), "LDKCResult_NoneChannelMonitorUpdateErrZ"); *ret_conv = (this_arg_conv->update_persisted_channel)(this_arg_conv->this_arg, id_conv, &update_conv, &data_conv); return (uint64_t)ret_conv; } typedef struct LDKChannelMessageHandler_JCalls { atomic_size_t refcnt; LDKMessageSendEventsProvider_JCalls* MessageSendEventsProvider; uint32_t handle_open_channel_meth; uint32_t handle_accept_channel_meth; uint32_t handle_funding_created_meth; uint32_t handle_funding_signed_meth; uint32_t handle_funding_locked_meth; uint32_t handle_shutdown_meth; uint32_t handle_closing_signed_meth; uint32_t handle_update_add_htlc_meth; uint32_t handle_update_fulfill_htlc_meth; uint32_t handle_update_fail_htlc_meth; uint32_t handle_update_fail_malformed_htlc_meth; uint32_t handle_commitment_signed_meth; uint32_t handle_revoke_and_ack_meth; uint32_t handle_update_fee_meth; uint32_t handle_announcement_signatures_meth; uint32_t peer_disconnected_meth; uint32_t peer_connected_meth; uint32_t handle_channel_reestablish_meth; uint32_t handle_channel_update_meth; uint32_t handle_error_meth; } LDKChannelMessageHandler_JCalls; static void LDKChannelMessageHandler_JCalls_free(void* this_arg) { LDKChannelMessageHandler_JCalls *j_calls = (LDKChannelMessageHandler_JCalls*) this_arg; if (atomic_fetch_sub_explicit(&j_calls->refcnt, 1, memory_order_acquire) == 1) { js_free(j_calls->handle_open_channel_meth); js_free(j_calls->handle_accept_channel_meth); js_free(j_calls->handle_funding_created_meth); js_free(j_calls->handle_funding_signed_meth); js_free(j_calls->handle_funding_locked_meth); js_free(j_calls->handle_shutdown_meth); js_free(j_calls->handle_closing_signed_meth); js_free(j_calls->handle_update_add_htlc_meth); js_free(j_calls->handle_update_fulfill_htlc_meth); js_free(j_calls->handle_update_fail_htlc_meth); js_free(j_calls->handle_update_fail_malformed_htlc_meth); js_free(j_calls->handle_commitment_signed_meth); js_free(j_calls->handle_revoke_and_ack_meth); js_free(j_calls->handle_update_fee_meth); js_free(j_calls->handle_announcement_signatures_meth); js_free(j_calls->peer_disconnected_meth); js_free(j_calls->peer_connected_meth); js_free(j_calls->handle_channel_reestablish_meth); js_free(j_calls->handle_channel_update_meth); js_free(j_calls->handle_error_meth); FREE(j_calls); } } void handle_open_channel_LDKChannelMessageHandler_jcall(const void* this_arg, LDKPublicKey their_node_id, LDKInitFeatures their_features, const LDKOpenChannel * msg) { LDKChannelMessageHandler_JCalls *j_calls = (LDKChannelMessageHandler_JCalls*) this_arg; int8_tArray their_node_id_arr = init_arr(33, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(their_node_id_arr + 4), their_node_id.compressed_form, 33); LDKInitFeatures their_features_var = their_features; CHECK((((uint64_t)their_features_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&their_features_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t their_features_ref = (uint64_t)their_features_var.inner; if (their_features_var.is_owned) { their_features_ref |= 1; } LDKOpenChannel msg_var = *msg; msg_var = OpenChannel_clone(msg); CHECK((((uint64_t)msg_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&msg_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t msg_ref = (uint64_t)msg_var.inner; if (msg_var.is_owned) { msg_ref |= 1; } js_invoke_function_3(j_calls->handle_open_channel_meth, their_node_id_arr, their_features_ref, msg_ref); } void handle_accept_channel_LDKChannelMessageHandler_jcall(const void* this_arg, LDKPublicKey their_node_id, LDKInitFeatures their_features, const LDKAcceptChannel * msg) { LDKChannelMessageHandler_JCalls *j_calls = (LDKChannelMessageHandler_JCalls*) this_arg; int8_tArray their_node_id_arr = init_arr(33, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(their_node_id_arr + 4), their_node_id.compressed_form, 33); LDKInitFeatures their_features_var = their_features; CHECK((((uint64_t)their_features_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&their_features_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t their_features_ref = (uint64_t)their_features_var.inner; if (their_features_var.is_owned) { their_features_ref |= 1; } LDKAcceptChannel msg_var = *msg; msg_var = AcceptChannel_clone(msg); CHECK((((uint64_t)msg_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&msg_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t msg_ref = (uint64_t)msg_var.inner; if (msg_var.is_owned) { msg_ref |= 1; } js_invoke_function_3(j_calls->handle_accept_channel_meth, their_node_id_arr, their_features_ref, msg_ref); } void handle_funding_created_LDKChannelMessageHandler_jcall(const void* this_arg, LDKPublicKey their_node_id, const LDKFundingCreated * msg) { LDKChannelMessageHandler_JCalls *j_calls = (LDKChannelMessageHandler_JCalls*) this_arg; int8_tArray their_node_id_arr = init_arr(33, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(their_node_id_arr + 4), their_node_id.compressed_form, 33); LDKFundingCreated msg_var = *msg; msg_var = FundingCreated_clone(msg); CHECK((((uint64_t)msg_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&msg_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t msg_ref = (uint64_t)msg_var.inner; if (msg_var.is_owned) { msg_ref |= 1; } js_invoke_function_2(j_calls->handle_funding_created_meth, their_node_id_arr, msg_ref); } void handle_funding_signed_LDKChannelMessageHandler_jcall(const void* this_arg, LDKPublicKey their_node_id, const LDKFundingSigned * msg) { LDKChannelMessageHandler_JCalls *j_calls = (LDKChannelMessageHandler_JCalls*) this_arg; int8_tArray their_node_id_arr = init_arr(33, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(their_node_id_arr + 4), their_node_id.compressed_form, 33); LDKFundingSigned msg_var = *msg; msg_var = FundingSigned_clone(msg); CHECK((((uint64_t)msg_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&msg_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t msg_ref = (uint64_t)msg_var.inner; if (msg_var.is_owned) { msg_ref |= 1; } js_invoke_function_2(j_calls->handle_funding_signed_meth, their_node_id_arr, msg_ref); } void handle_funding_locked_LDKChannelMessageHandler_jcall(const void* this_arg, LDKPublicKey their_node_id, const LDKFundingLocked * msg) { LDKChannelMessageHandler_JCalls *j_calls = (LDKChannelMessageHandler_JCalls*) this_arg; int8_tArray their_node_id_arr = init_arr(33, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(their_node_id_arr + 4), their_node_id.compressed_form, 33); LDKFundingLocked msg_var = *msg; msg_var = FundingLocked_clone(msg); CHECK((((uint64_t)msg_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&msg_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t msg_ref = (uint64_t)msg_var.inner; if (msg_var.is_owned) { msg_ref |= 1; } js_invoke_function_2(j_calls->handle_funding_locked_meth, their_node_id_arr, msg_ref); } void handle_shutdown_LDKChannelMessageHandler_jcall(const void* this_arg, LDKPublicKey their_node_id, const LDKInitFeatures * their_features, const LDKShutdown * msg) { LDKChannelMessageHandler_JCalls *j_calls = (LDKChannelMessageHandler_JCalls*) this_arg; int8_tArray their_node_id_arr = init_arr(33, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(their_node_id_arr + 4), their_node_id.compressed_form, 33); LDKInitFeatures their_features_var = *their_features; their_features_var = InitFeatures_clone(their_features); CHECK((((uint64_t)their_features_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&their_features_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t their_features_ref = (uint64_t)their_features_var.inner; if (their_features_var.is_owned) { their_features_ref |= 1; } LDKShutdown msg_var = *msg; msg_var = Shutdown_clone(msg); CHECK((((uint64_t)msg_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&msg_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t msg_ref = (uint64_t)msg_var.inner; if (msg_var.is_owned) { msg_ref |= 1; } js_invoke_function_3(j_calls->handle_shutdown_meth, their_node_id_arr, their_features_ref, msg_ref); } void handle_closing_signed_LDKChannelMessageHandler_jcall(const void* this_arg, LDKPublicKey their_node_id, const LDKClosingSigned * msg) { LDKChannelMessageHandler_JCalls *j_calls = (LDKChannelMessageHandler_JCalls*) this_arg; int8_tArray their_node_id_arr = init_arr(33, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(their_node_id_arr + 4), their_node_id.compressed_form, 33); LDKClosingSigned msg_var = *msg; msg_var = ClosingSigned_clone(msg); CHECK((((uint64_t)msg_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&msg_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t msg_ref = (uint64_t)msg_var.inner; if (msg_var.is_owned) { msg_ref |= 1; } js_invoke_function_2(j_calls->handle_closing_signed_meth, their_node_id_arr, msg_ref); } void handle_update_add_htlc_LDKChannelMessageHandler_jcall(const void* this_arg, LDKPublicKey their_node_id, const LDKUpdateAddHTLC * msg) { LDKChannelMessageHandler_JCalls *j_calls = (LDKChannelMessageHandler_JCalls*) this_arg; int8_tArray their_node_id_arr = init_arr(33, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(their_node_id_arr + 4), their_node_id.compressed_form, 33); LDKUpdateAddHTLC msg_var = *msg; msg_var = UpdateAddHTLC_clone(msg); CHECK((((uint64_t)msg_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&msg_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t msg_ref = (uint64_t)msg_var.inner; if (msg_var.is_owned) { msg_ref |= 1; } js_invoke_function_2(j_calls->handle_update_add_htlc_meth, their_node_id_arr, msg_ref); } void handle_update_fulfill_htlc_LDKChannelMessageHandler_jcall(const void* this_arg, LDKPublicKey their_node_id, const LDKUpdateFulfillHTLC * msg) { LDKChannelMessageHandler_JCalls *j_calls = (LDKChannelMessageHandler_JCalls*) this_arg; int8_tArray their_node_id_arr = init_arr(33, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(their_node_id_arr + 4), their_node_id.compressed_form, 33); LDKUpdateFulfillHTLC msg_var = *msg; msg_var = UpdateFulfillHTLC_clone(msg); CHECK((((uint64_t)msg_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&msg_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t msg_ref = (uint64_t)msg_var.inner; if (msg_var.is_owned) { msg_ref |= 1; } js_invoke_function_2(j_calls->handle_update_fulfill_htlc_meth, their_node_id_arr, msg_ref); } void handle_update_fail_htlc_LDKChannelMessageHandler_jcall(const void* this_arg, LDKPublicKey their_node_id, const LDKUpdateFailHTLC * msg) { LDKChannelMessageHandler_JCalls *j_calls = (LDKChannelMessageHandler_JCalls*) this_arg; int8_tArray their_node_id_arr = init_arr(33, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(their_node_id_arr + 4), their_node_id.compressed_form, 33); LDKUpdateFailHTLC msg_var = *msg; msg_var = UpdateFailHTLC_clone(msg); CHECK((((uint64_t)msg_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&msg_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t msg_ref = (uint64_t)msg_var.inner; if (msg_var.is_owned) { msg_ref |= 1; } js_invoke_function_2(j_calls->handle_update_fail_htlc_meth, their_node_id_arr, msg_ref); } void handle_update_fail_malformed_htlc_LDKChannelMessageHandler_jcall(const void* this_arg, LDKPublicKey their_node_id, const LDKUpdateFailMalformedHTLC * msg) { LDKChannelMessageHandler_JCalls *j_calls = (LDKChannelMessageHandler_JCalls*) this_arg; int8_tArray their_node_id_arr = init_arr(33, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(their_node_id_arr + 4), their_node_id.compressed_form, 33); LDKUpdateFailMalformedHTLC msg_var = *msg; msg_var = UpdateFailMalformedHTLC_clone(msg); CHECK((((uint64_t)msg_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&msg_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t msg_ref = (uint64_t)msg_var.inner; if (msg_var.is_owned) { msg_ref |= 1; } js_invoke_function_2(j_calls->handle_update_fail_malformed_htlc_meth, their_node_id_arr, msg_ref); } void handle_commitment_signed_LDKChannelMessageHandler_jcall(const void* this_arg, LDKPublicKey their_node_id, const LDKCommitmentSigned * msg) { LDKChannelMessageHandler_JCalls *j_calls = (LDKChannelMessageHandler_JCalls*) this_arg; int8_tArray their_node_id_arr = init_arr(33, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(their_node_id_arr + 4), their_node_id.compressed_form, 33); LDKCommitmentSigned msg_var = *msg; msg_var = CommitmentSigned_clone(msg); CHECK((((uint64_t)msg_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&msg_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t msg_ref = (uint64_t)msg_var.inner; if (msg_var.is_owned) { msg_ref |= 1; } js_invoke_function_2(j_calls->handle_commitment_signed_meth, their_node_id_arr, msg_ref); } void handle_revoke_and_ack_LDKChannelMessageHandler_jcall(const void* this_arg, LDKPublicKey their_node_id, const LDKRevokeAndACK * msg) { LDKChannelMessageHandler_JCalls *j_calls = (LDKChannelMessageHandler_JCalls*) this_arg; int8_tArray their_node_id_arr = init_arr(33, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(their_node_id_arr + 4), their_node_id.compressed_form, 33); LDKRevokeAndACK msg_var = *msg; msg_var = RevokeAndACK_clone(msg); CHECK((((uint64_t)msg_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&msg_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t msg_ref = (uint64_t)msg_var.inner; if (msg_var.is_owned) { msg_ref |= 1; } js_invoke_function_2(j_calls->handle_revoke_and_ack_meth, their_node_id_arr, msg_ref); } void handle_update_fee_LDKChannelMessageHandler_jcall(const void* this_arg, LDKPublicKey their_node_id, const LDKUpdateFee * msg) { LDKChannelMessageHandler_JCalls *j_calls = (LDKChannelMessageHandler_JCalls*) this_arg; int8_tArray their_node_id_arr = init_arr(33, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(their_node_id_arr + 4), their_node_id.compressed_form, 33); LDKUpdateFee msg_var = *msg; msg_var = UpdateFee_clone(msg); CHECK((((uint64_t)msg_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&msg_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t msg_ref = (uint64_t)msg_var.inner; if (msg_var.is_owned) { msg_ref |= 1; } js_invoke_function_2(j_calls->handle_update_fee_meth, their_node_id_arr, msg_ref); } void handle_announcement_signatures_LDKChannelMessageHandler_jcall(const void* this_arg, LDKPublicKey their_node_id, const LDKAnnouncementSignatures * msg) { LDKChannelMessageHandler_JCalls *j_calls = (LDKChannelMessageHandler_JCalls*) this_arg; int8_tArray their_node_id_arr = init_arr(33, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(their_node_id_arr + 4), their_node_id.compressed_form, 33); LDKAnnouncementSignatures msg_var = *msg; msg_var = AnnouncementSignatures_clone(msg); CHECK((((uint64_t)msg_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&msg_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t msg_ref = (uint64_t)msg_var.inner; if (msg_var.is_owned) { msg_ref |= 1; } js_invoke_function_2(j_calls->handle_announcement_signatures_meth, their_node_id_arr, msg_ref); } void peer_disconnected_LDKChannelMessageHandler_jcall(const void* this_arg, LDKPublicKey their_node_id, bool no_connection_possible) { LDKChannelMessageHandler_JCalls *j_calls = (LDKChannelMessageHandler_JCalls*) this_arg; int8_tArray their_node_id_arr = init_arr(33, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(their_node_id_arr + 4), their_node_id.compressed_form, 33); js_invoke_function_2(j_calls->peer_disconnected_meth, their_node_id_arr, no_connection_possible); } void peer_connected_LDKChannelMessageHandler_jcall(const void* this_arg, LDKPublicKey their_node_id, const LDKInit * msg) { LDKChannelMessageHandler_JCalls *j_calls = (LDKChannelMessageHandler_JCalls*) this_arg; int8_tArray their_node_id_arr = init_arr(33, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(their_node_id_arr + 4), their_node_id.compressed_form, 33); LDKInit msg_var = *msg; msg_var = Init_clone(msg); CHECK((((uint64_t)msg_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&msg_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t msg_ref = (uint64_t)msg_var.inner; if (msg_var.is_owned) { msg_ref |= 1; } js_invoke_function_2(j_calls->peer_connected_meth, their_node_id_arr, msg_ref); } void handle_channel_reestablish_LDKChannelMessageHandler_jcall(const void* this_arg, LDKPublicKey their_node_id, const LDKChannelReestablish * msg) { LDKChannelMessageHandler_JCalls *j_calls = (LDKChannelMessageHandler_JCalls*) this_arg; int8_tArray their_node_id_arr = init_arr(33, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(their_node_id_arr + 4), their_node_id.compressed_form, 33); LDKChannelReestablish msg_var = *msg; msg_var = ChannelReestablish_clone(msg); CHECK((((uint64_t)msg_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&msg_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t msg_ref = (uint64_t)msg_var.inner; if (msg_var.is_owned) { msg_ref |= 1; } js_invoke_function_2(j_calls->handle_channel_reestablish_meth, their_node_id_arr, msg_ref); } void handle_channel_update_LDKChannelMessageHandler_jcall(const void* this_arg, LDKPublicKey their_node_id, const LDKChannelUpdate * msg) { LDKChannelMessageHandler_JCalls *j_calls = (LDKChannelMessageHandler_JCalls*) this_arg; int8_tArray their_node_id_arr = init_arr(33, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(their_node_id_arr + 4), their_node_id.compressed_form, 33); LDKChannelUpdate msg_var = *msg; msg_var = ChannelUpdate_clone(msg); CHECK((((uint64_t)msg_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&msg_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t msg_ref = (uint64_t)msg_var.inner; if (msg_var.is_owned) { msg_ref |= 1; } js_invoke_function_2(j_calls->handle_channel_update_meth, their_node_id_arr, msg_ref); } void handle_error_LDKChannelMessageHandler_jcall(const void* this_arg, LDKPublicKey their_node_id, const LDKErrorMessage * msg) { LDKChannelMessageHandler_JCalls *j_calls = (LDKChannelMessageHandler_JCalls*) this_arg; int8_tArray their_node_id_arr = init_arr(33, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(their_node_id_arr + 4), their_node_id.compressed_form, 33); LDKErrorMessage msg_var = *msg; msg_var = ErrorMessage_clone(msg); CHECK((((uint64_t)msg_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&msg_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t msg_ref = (uint64_t)msg_var.inner; if (msg_var.is_owned) { msg_ref |= 1; } js_invoke_function_2(j_calls->handle_error_meth, their_node_id_arr, msg_ref); } static void LDKChannelMessageHandler_JCalls_cloned(LDKChannelMessageHandler* new_obj) { LDKChannelMessageHandler_JCalls *j_calls = (LDKChannelMessageHandler_JCalls*) new_obj->this_arg; atomic_fetch_add_explicit(&j_calls->refcnt, 1, memory_order_release); atomic_fetch_add_explicit(&j_calls->MessageSendEventsProvider->refcnt, 1, memory_order_release); } static inline LDKChannelMessageHandler LDKChannelMessageHandler_init (/*TODO: JS Object Reference */void* o, /*TODO: JS Object Reference */void* MessageSendEventsProvider) { LDKChannelMessageHandler_JCalls *calls = MALLOC(sizeof(LDKChannelMessageHandler_JCalls), "LDKChannelMessageHandler_JCalls"); atomic_init(&calls->refcnt, 1); //TODO: Assign calls->o from o LDKChannelMessageHandler ret = { .this_arg = (void*) calls, .handle_open_channel = handle_open_channel_LDKChannelMessageHandler_jcall, .handle_accept_channel = handle_accept_channel_LDKChannelMessageHandler_jcall, .handle_funding_created = handle_funding_created_LDKChannelMessageHandler_jcall, .handle_funding_signed = handle_funding_signed_LDKChannelMessageHandler_jcall, .handle_funding_locked = handle_funding_locked_LDKChannelMessageHandler_jcall, .handle_shutdown = handle_shutdown_LDKChannelMessageHandler_jcall, .handle_closing_signed = handle_closing_signed_LDKChannelMessageHandler_jcall, .handle_update_add_htlc = handle_update_add_htlc_LDKChannelMessageHandler_jcall, .handle_update_fulfill_htlc = handle_update_fulfill_htlc_LDKChannelMessageHandler_jcall, .handle_update_fail_htlc = handle_update_fail_htlc_LDKChannelMessageHandler_jcall, .handle_update_fail_malformed_htlc = handle_update_fail_malformed_htlc_LDKChannelMessageHandler_jcall, .handle_commitment_signed = handle_commitment_signed_LDKChannelMessageHandler_jcall, .handle_revoke_and_ack = handle_revoke_and_ack_LDKChannelMessageHandler_jcall, .handle_update_fee = handle_update_fee_LDKChannelMessageHandler_jcall, .handle_announcement_signatures = handle_announcement_signatures_LDKChannelMessageHandler_jcall, .peer_disconnected = peer_disconnected_LDKChannelMessageHandler_jcall, .peer_connected = peer_connected_LDKChannelMessageHandler_jcall, .handle_channel_reestablish = handle_channel_reestablish_LDKChannelMessageHandler_jcall, .handle_channel_update = handle_channel_update_LDKChannelMessageHandler_jcall, .handle_error = handle_error_LDKChannelMessageHandler_jcall, .free = LDKChannelMessageHandler_JCalls_free, .MessageSendEventsProvider = LDKMessageSendEventsProvider_init(MessageSendEventsProvider), }; calls->MessageSendEventsProvider = ret.MessageSendEventsProvider.this_arg; return ret; } long __attribute__((visibility("default"))) TS_LDKChannelMessageHandler_new(/*TODO: JS Object Reference */void* o, /*TODO: JS Object Reference */ void* MessageSendEventsProvider) { LDKChannelMessageHandler *res_ptr = MALLOC(sizeof(LDKChannelMessageHandler), "LDKChannelMessageHandler"); *res_ptr = LDKChannelMessageHandler_init(o, MessageSendEventsProvider); return (long)res_ptr; } void __attribute__((visibility("default"))) TS_ChannelMessageHandler_handle_open_channel(uint32_t this_arg, int8_tArray their_node_id, uint32_t their_features, uint32_t msg) { LDKChannelMessageHandler* this_arg_conv = (LDKChannelMessageHandler*)(((uint64_t)this_arg) & ~1); LDKPublicKey their_node_id_ref; CHECK(*((uint32_t*)their_node_id) == 33); memcpy(their_node_id_ref.compressed_form, (uint8_t*)(their_node_id + 4), 33); LDKInitFeatures their_features_conv; their_features_conv.inner = (void*)(their_features & (~1)); their_features_conv.is_owned = (their_features & 1) || (their_features == 0); their_features_conv = InitFeatures_clone(&their_features_conv); LDKOpenChannel msg_conv; msg_conv.inner = (void*)(msg & (~1)); msg_conv.is_owned = false; (this_arg_conv->handle_open_channel)(this_arg_conv->this_arg, their_node_id_ref, their_features_conv, &msg_conv); } void __attribute__((visibility("default"))) TS_ChannelMessageHandler_handle_accept_channel(uint32_t this_arg, int8_tArray their_node_id, uint32_t their_features, uint32_t msg) { LDKChannelMessageHandler* this_arg_conv = (LDKChannelMessageHandler*)(((uint64_t)this_arg) & ~1); LDKPublicKey their_node_id_ref; CHECK(*((uint32_t*)their_node_id) == 33); memcpy(their_node_id_ref.compressed_form, (uint8_t*)(their_node_id + 4), 33); LDKInitFeatures their_features_conv; their_features_conv.inner = (void*)(their_features & (~1)); their_features_conv.is_owned = (their_features & 1) || (their_features == 0); their_features_conv = InitFeatures_clone(&their_features_conv); LDKAcceptChannel msg_conv; msg_conv.inner = (void*)(msg & (~1)); msg_conv.is_owned = false; (this_arg_conv->handle_accept_channel)(this_arg_conv->this_arg, their_node_id_ref, their_features_conv, &msg_conv); } void __attribute__((visibility("default"))) TS_ChannelMessageHandler_handle_funding_created(uint32_t this_arg, int8_tArray their_node_id, uint32_t msg) { LDKChannelMessageHandler* this_arg_conv = (LDKChannelMessageHandler*)(((uint64_t)this_arg) & ~1); LDKPublicKey their_node_id_ref; CHECK(*((uint32_t*)their_node_id) == 33); memcpy(their_node_id_ref.compressed_form, (uint8_t*)(their_node_id + 4), 33); LDKFundingCreated msg_conv; msg_conv.inner = (void*)(msg & (~1)); msg_conv.is_owned = false; (this_arg_conv->handle_funding_created)(this_arg_conv->this_arg, their_node_id_ref, &msg_conv); } void __attribute__((visibility("default"))) TS_ChannelMessageHandler_handle_funding_signed(uint32_t this_arg, int8_tArray their_node_id, uint32_t msg) { LDKChannelMessageHandler* this_arg_conv = (LDKChannelMessageHandler*)(((uint64_t)this_arg) & ~1); LDKPublicKey their_node_id_ref; CHECK(*((uint32_t*)their_node_id) == 33); memcpy(their_node_id_ref.compressed_form, (uint8_t*)(their_node_id + 4), 33); LDKFundingSigned msg_conv; msg_conv.inner = (void*)(msg & (~1)); msg_conv.is_owned = false; (this_arg_conv->handle_funding_signed)(this_arg_conv->this_arg, their_node_id_ref, &msg_conv); } void __attribute__((visibility("default"))) TS_ChannelMessageHandler_handle_funding_locked(uint32_t this_arg, int8_tArray their_node_id, uint32_t msg) { LDKChannelMessageHandler* this_arg_conv = (LDKChannelMessageHandler*)(((uint64_t)this_arg) & ~1); LDKPublicKey their_node_id_ref; CHECK(*((uint32_t*)their_node_id) == 33); memcpy(their_node_id_ref.compressed_form, (uint8_t*)(their_node_id + 4), 33); LDKFundingLocked msg_conv; msg_conv.inner = (void*)(msg & (~1)); msg_conv.is_owned = false; (this_arg_conv->handle_funding_locked)(this_arg_conv->this_arg, their_node_id_ref, &msg_conv); } void __attribute__((visibility("default"))) TS_ChannelMessageHandler_handle_shutdown(uint32_t this_arg, int8_tArray their_node_id, uint32_t their_features, uint32_t msg) { LDKChannelMessageHandler* this_arg_conv = (LDKChannelMessageHandler*)(((uint64_t)this_arg) & ~1); LDKPublicKey their_node_id_ref; CHECK(*((uint32_t*)their_node_id) == 33); memcpy(their_node_id_ref.compressed_form, (uint8_t*)(their_node_id + 4), 33); LDKInitFeatures their_features_conv; their_features_conv.inner = (void*)(their_features & (~1)); their_features_conv.is_owned = false; LDKShutdown msg_conv; msg_conv.inner = (void*)(msg & (~1)); msg_conv.is_owned = false; (this_arg_conv->handle_shutdown)(this_arg_conv->this_arg, their_node_id_ref, &their_features_conv, &msg_conv); } void __attribute__((visibility("default"))) TS_ChannelMessageHandler_handle_closing_signed(uint32_t this_arg, int8_tArray their_node_id, uint32_t msg) { LDKChannelMessageHandler* this_arg_conv = (LDKChannelMessageHandler*)(((uint64_t)this_arg) & ~1); LDKPublicKey their_node_id_ref; CHECK(*((uint32_t*)their_node_id) == 33); memcpy(their_node_id_ref.compressed_form, (uint8_t*)(their_node_id + 4), 33); LDKClosingSigned msg_conv; msg_conv.inner = (void*)(msg & (~1)); msg_conv.is_owned = false; (this_arg_conv->handle_closing_signed)(this_arg_conv->this_arg, their_node_id_ref, &msg_conv); } void __attribute__((visibility("default"))) TS_ChannelMessageHandler_handle_update_add_htlc(uint32_t this_arg, int8_tArray their_node_id, uint32_t msg) { LDKChannelMessageHandler* this_arg_conv = (LDKChannelMessageHandler*)(((uint64_t)this_arg) & ~1); LDKPublicKey their_node_id_ref; CHECK(*((uint32_t*)their_node_id) == 33); memcpy(their_node_id_ref.compressed_form, (uint8_t*)(their_node_id + 4), 33); LDKUpdateAddHTLC msg_conv; msg_conv.inner = (void*)(msg & (~1)); msg_conv.is_owned = false; (this_arg_conv->handle_update_add_htlc)(this_arg_conv->this_arg, their_node_id_ref, &msg_conv); } void __attribute__((visibility("default"))) TS_ChannelMessageHandler_handle_update_fulfill_htlc(uint32_t this_arg, int8_tArray their_node_id, uint32_t msg) { LDKChannelMessageHandler* this_arg_conv = (LDKChannelMessageHandler*)(((uint64_t)this_arg) & ~1); LDKPublicKey their_node_id_ref; CHECK(*((uint32_t*)their_node_id) == 33); memcpy(their_node_id_ref.compressed_form, (uint8_t*)(their_node_id + 4), 33); LDKUpdateFulfillHTLC msg_conv; msg_conv.inner = (void*)(msg & (~1)); msg_conv.is_owned = false; (this_arg_conv->handle_update_fulfill_htlc)(this_arg_conv->this_arg, their_node_id_ref, &msg_conv); } void __attribute__((visibility("default"))) TS_ChannelMessageHandler_handle_update_fail_htlc(uint32_t this_arg, int8_tArray their_node_id, uint32_t msg) { LDKChannelMessageHandler* this_arg_conv = (LDKChannelMessageHandler*)(((uint64_t)this_arg) & ~1); LDKPublicKey their_node_id_ref; CHECK(*((uint32_t*)their_node_id) == 33); memcpy(their_node_id_ref.compressed_form, (uint8_t*)(their_node_id + 4), 33); LDKUpdateFailHTLC msg_conv; msg_conv.inner = (void*)(msg & (~1)); msg_conv.is_owned = false; (this_arg_conv->handle_update_fail_htlc)(this_arg_conv->this_arg, their_node_id_ref, &msg_conv); } void __attribute__((visibility("default"))) TS_ChannelMessageHandler_handle_update_fail_malformed_htlc(uint32_t this_arg, int8_tArray their_node_id, uint32_t msg) { LDKChannelMessageHandler* this_arg_conv = (LDKChannelMessageHandler*)(((uint64_t)this_arg) & ~1); LDKPublicKey their_node_id_ref; CHECK(*((uint32_t*)their_node_id) == 33); memcpy(their_node_id_ref.compressed_form, (uint8_t*)(their_node_id + 4), 33); LDKUpdateFailMalformedHTLC msg_conv; msg_conv.inner = (void*)(msg & (~1)); msg_conv.is_owned = false; (this_arg_conv->handle_update_fail_malformed_htlc)(this_arg_conv->this_arg, their_node_id_ref, &msg_conv); } void __attribute__((visibility("default"))) TS_ChannelMessageHandler_handle_commitment_signed(uint32_t this_arg, int8_tArray their_node_id, uint32_t msg) { LDKChannelMessageHandler* this_arg_conv = (LDKChannelMessageHandler*)(((uint64_t)this_arg) & ~1); LDKPublicKey their_node_id_ref; CHECK(*((uint32_t*)their_node_id) == 33); memcpy(their_node_id_ref.compressed_form, (uint8_t*)(their_node_id + 4), 33); LDKCommitmentSigned msg_conv; msg_conv.inner = (void*)(msg & (~1)); msg_conv.is_owned = false; (this_arg_conv->handle_commitment_signed)(this_arg_conv->this_arg, their_node_id_ref, &msg_conv); } void __attribute__((visibility("default"))) TS_ChannelMessageHandler_handle_revoke_and_ack(uint32_t this_arg, int8_tArray their_node_id, uint32_t msg) { LDKChannelMessageHandler* this_arg_conv = (LDKChannelMessageHandler*)(((uint64_t)this_arg) & ~1); LDKPublicKey their_node_id_ref; CHECK(*((uint32_t*)their_node_id) == 33); memcpy(their_node_id_ref.compressed_form, (uint8_t*)(their_node_id + 4), 33); LDKRevokeAndACK msg_conv; msg_conv.inner = (void*)(msg & (~1)); msg_conv.is_owned = false; (this_arg_conv->handle_revoke_and_ack)(this_arg_conv->this_arg, their_node_id_ref, &msg_conv); } void __attribute__((visibility("default"))) TS_ChannelMessageHandler_handle_update_fee(uint32_t this_arg, int8_tArray their_node_id, uint32_t msg) { LDKChannelMessageHandler* this_arg_conv = (LDKChannelMessageHandler*)(((uint64_t)this_arg) & ~1); LDKPublicKey their_node_id_ref; CHECK(*((uint32_t*)their_node_id) == 33); memcpy(their_node_id_ref.compressed_form, (uint8_t*)(their_node_id + 4), 33); LDKUpdateFee msg_conv; msg_conv.inner = (void*)(msg & (~1)); msg_conv.is_owned = false; (this_arg_conv->handle_update_fee)(this_arg_conv->this_arg, their_node_id_ref, &msg_conv); } void __attribute__((visibility("default"))) TS_ChannelMessageHandler_handle_announcement_signatures(uint32_t this_arg, int8_tArray their_node_id, uint32_t msg) { LDKChannelMessageHandler* this_arg_conv = (LDKChannelMessageHandler*)(((uint64_t)this_arg) & ~1); LDKPublicKey their_node_id_ref; CHECK(*((uint32_t*)their_node_id) == 33); memcpy(their_node_id_ref.compressed_form, (uint8_t*)(their_node_id + 4), 33); LDKAnnouncementSignatures msg_conv; msg_conv.inner = (void*)(msg & (~1)); msg_conv.is_owned = false; (this_arg_conv->handle_announcement_signatures)(this_arg_conv->this_arg, their_node_id_ref, &msg_conv); } void __attribute__((visibility("default"))) TS_ChannelMessageHandler_peer_disconnected(uint32_t this_arg, int8_tArray their_node_id, jboolean no_connection_possible) { LDKChannelMessageHandler* this_arg_conv = (LDKChannelMessageHandler*)(((uint64_t)this_arg) & ~1); LDKPublicKey their_node_id_ref; CHECK(*((uint32_t*)their_node_id) == 33); memcpy(their_node_id_ref.compressed_form, (uint8_t*)(their_node_id + 4), 33); (this_arg_conv->peer_disconnected)(this_arg_conv->this_arg, their_node_id_ref, no_connection_possible); } void __attribute__((visibility("default"))) TS_ChannelMessageHandler_peer_connected(uint32_t this_arg, int8_tArray their_node_id, uint32_t msg) { LDKChannelMessageHandler* this_arg_conv = (LDKChannelMessageHandler*)(((uint64_t)this_arg) & ~1); LDKPublicKey their_node_id_ref; CHECK(*((uint32_t*)their_node_id) == 33); memcpy(their_node_id_ref.compressed_form, (uint8_t*)(their_node_id + 4), 33); LDKInit msg_conv; msg_conv.inner = (void*)(msg & (~1)); msg_conv.is_owned = false; (this_arg_conv->peer_connected)(this_arg_conv->this_arg, their_node_id_ref, &msg_conv); } void __attribute__((visibility("default"))) TS_ChannelMessageHandler_handle_channel_reestablish(uint32_t this_arg, int8_tArray their_node_id, uint32_t msg) { LDKChannelMessageHandler* this_arg_conv = (LDKChannelMessageHandler*)(((uint64_t)this_arg) & ~1); LDKPublicKey their_node_id_ref; CHECK(*((uint32_t*)their_node_id) == 33); memcpy(their_node_id_ref.compressed_form, (uint8_t*)(their_node_id + 4), 33); LDKChannelReestablish msg_conv; msg_conv.inner = (void*)(msg & (~1)); msg_conv.is_owned = false; (this_arg_conv->handle_channel_reestablish)(this_arg_conv->this_arg, their_node_id_ref, &msg_conv); } void __attribute__((visibility("default"))) TS_ChannelMessageHandler_handle_channel_update(uint32_t this_arg, int8_tArray their_node_id, uint32_t msg) { LDKChannelMessageHandler* this_arg_conv = (LDKChannelMessageHandler*)(((uint64_t)this_arg) & ~1); LDKPublicKey their_node_id_ref; CHECK(*((uint32_t*)their_node_id) == 33); memcpy(their_node_id_ref.compressed_form, (uint8_t*)(their_node_id + 4), 33); LDKChannelUpdate msg_conv; msg_conv.inner = (void*)(msg & (~1)); msg_conv.is_owned = false; (this_arg_conv->handle_channel_update)(this_arg_conv->this_arg, their_node_id_ref, &msg_conv); } void __attribute__((visibility("default"))) TS_ChannelMessageHandler_handle_error(uint32_t this_arg, int8_tArray their_node_id, uint32_t msg) { LDKChannelMessageHandler* this_arg_conv = (LDKChannelMessageHandler*)(((uint64_t)this_arg) & ~1); LDKPublicKey their_node_id_ref; CHECK(*((uint32_t*)their_node_id) == 33); memcpy(their_node_id_ref.compressed_form, (uint8_t*)(their_node_id + 4), 33); LDKErrorMessage msg_conv; msg_conv.inner = (void*)(msg & (~1)); msg_conv.is_owned = false; (this_arg_conv->handle_error)(this_arg_conv->this_arg, their_node_id_ref, &msg_conv); } typedef struct LDKRoutingMessageHandler_JCalls { atomic_size_t refcnt; LDKMessageSendEventsProvider_JCalls* MessageSendEventsProvider; uint32_t handle_node_announcement_meth; uint32_t handle_channel_announcement_meth; uint32_t handle_channel_update_meth; uint32_t get_next_channel_announcements_meth; uint32_t get_next_node_announcements_meth; uint32_t sync_routing_table_meth; uint32_t handle_reply_channel_range_meth; uint32_t handle_reply_short_channel_ids_end_meth; uint32_t handle_query_channel_range_meth; uint32_t handle_query_short_channel_ids_meth; } LDKRoutingMessageHandler_JCalls; static void LDKRoutingMessageHandler_JCalls_free(void* this_arg) { LDKRoutingMessageHandler_JCalls *j_calls = (LDKRoutingMessageHandler_JCalls*) this_arg; if (atomic_fetch_sub_explicit(&j_calls->refcnt, 1, memory_order_acquire) == 1) { js_free(j_calls->handle_node_announcement_meth); js_free(j_calls->handle_channel_announcement_meth); js_free(j_calls->handle_channel_update_meth); js_free(j_calls->get_next_channel_announcements_meth); js_free(j_calls->get_next_node_announcements_meth); js_free(j_calls->sync_routing_table_meth); js_free(j_calls->handle_reply_channel_range_meth); js_free(j_calls->handle_reply_short_channel_ids_end_meth); js_free(j_calls->handle_query_channel_range_meth); js_free(j_calls->handle_query_short_channel_ids_meth); FREE(j_calls); } } LDKCResult_boolLightningErrorZ handle_node_announcement_LDKRoutingMessageHandler_jcall(const void* this_arg, const LDKNodeAnnouncement * msg) { LDKRoutingMessageHandler_JCalls *j_calls = (LDKRoutingMessageHandler_JCalls*) this_arg; LDKNodeAnnouncement msg_var = *msg; msg_var = NodeAnnouncement_clone(msg); CHECK((((uint64_t)msg_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&msg_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t msg_ref = (uint64_t)msg_var.inner; if (msg_var.is_owned) { msg_ref |= 1; } uint32_t ret = js_invoke_function_1(j_calls->handle_node_announcement_meth, msg_ref); LDKCResult_boolLightningErrorZ ret_conv = *(LDKCResult_boolLightningErrorZ*)(((uint64_t)ret) & ~1); ret_conv = CResult_boolLightningErrorZ_clone((LDKCResult_boolLightningErrorZ*)(((uint64_t)ret) & ~1)); return ret_conv; } LDKCResult_boolLightningErrorZ handle_channel_announcement_LDKRoutingMessageHandler_jcall(const void* this_arg, const LDKChannelAnnouncement * msg) { LDKRoutingMessageHandler_JCalls *j_calls = (LDKRoutingMessageHandler_JCalls*) this_arg; LDKChannelAnnouncement msg_var = *msg; msg_var = ChannelAnnouncement_clone(msg); CHECK((((uint64_t)msg_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&msg_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t msg_ref = (uint64_t)msg_var.inner; if (msg_var.is_owned) { msg_ref |= 1; } uint32_t ret = js_invoke_function_1(j_calls->handle_channel_announcement_meth, msg_ref); LDKCResult_boolLightningErrorZ ret_conv = *(LDKCResult_boolLightningErrorZ*)(((uint64_t)ret) & ~1); ret_conv = CResult_boolLightningErrorZ_clone((LDKCResult_boolLightningErrorZ*)(((uint64_t)ret) & ~1)); return ret_conv; } LDKCResult_boolLightningErrorZ handle_channel_update_LDKRoutingMessageHandler_jcall(const void* this_arg, const LDKChannelUpdate * msg) { LDKRoutingMessageHandler_JCalls *j_calls = (LDKRoutingMessageHandler_JCalls*) this_arg; LDKChannelUpdate msg_var = *msg; msg_var = ChannelUpdate_clone(msg); CHECK((((uint64_t)msg_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&msg_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t msg_ref = (uint64_t)msg_var.inner; if (msg_var.is_owned) { msg_ref |= 1; } uint32_t ret = js_invoke_function_1(j_calls->handle_channel_update_meth, msg_ref); LDKCResult_boolLightningErrorZ ret_conv = *(LDKCResult_boolLightningErrorZ*)(((uint64_t)ret) & ~1); ret_conv = CResult_boolLightningErrorZ_clone((LDKCResult_boolLightningErrorZ*)(((uint64_t)ret) & ~1)); return ret_conv; } LDKCVec_C3Tuple_ChannelAnnouncementChannelUpdateChannelUpdateZZ get_next_channel_announcements_LDKRoutingMessageHandler_jcall(const void* this_arg, uint64_t starting_point, uint8_t batch_amount) { LDKRoutingMessageHandler_JCalls *j_calls = (LDKRoutingMessageHandler_JCalls*) this_arg; uint32_tArray ret = js_invoke_function_2(j_calls->get_next_channel_announcements_meth, starting_point, batch_amount); LDKCVec_C3Tuple_ChannelAnnouncementChannelUpdateChannelUpdateZZ ret_constr; ret_constr.datalen = *((uint32_t*)ret); if (ret_constr.datalen > 0) ret_constr.data = MALLOC(ret_constr.datalen * sizeof(LDKC3Tuple_ChannelAnnouncementChannelUpdateChannelUpdateZ), "LDKCVec_C3Tuple_ChannelAnnouncementChannelUpdateChannelUpdateZZ Elements"); else ret_constr.data = NULL; uint32_t* ret_vals = (uint32_t*)(ret + 4); for (size_t l = 0; l < ret_constr.datalen; l++) { uint32_t ret_conv_63 = ret_vals[l]; LDKC3Tuple_ChannelAnnouncementChannelUpdateChannelUpdateZ ret_conv_63_conv = *(LDKC3Tuple_ChannelAnnouncementChannelUpdateChannelUpdateZ*)(((uint64_t)ret_conv_63) & ~1); ret_conv_63_conv = C3Tuple_ChannelAnnouncementChannelUpdateChannelUpdateZ_clone((LDKC3Tuple_ChannelAnnouncementChannelUpdateChannelUpdateZ*)(((uint64_t)ret_conv_63) & ~1)); ret_constr.data[l] = ret_conv_63_conv; } return ret_constr; } LDKCVec_NodeAnnouncementZ get_next_node_announcements_LDKRoutingMessageHandler_jcall(const void* this_arg, LDKPublicKey starting_point, uint8_t batch_amount) { LDKRoutingMessageHandler_JCalls *j_calls = (LDKRoutingMessageHandler_JCalls*) this_arg; int8_tArray starting_point_arr = init_arr(33, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(starting_point_arr + 4), starting_point.compressed_form, 33); uint32_tArray ret = js_invoke_function_2(j_calls->get_next_node_announcements_meth, starting_point_arr, batch_amount); LDKCVec_NodeAnnouncementZ ret_constr; ret_constr.datalen = *((uint32_t*)ret); if (ret_constr.datalen > 0) ret_constr.data = MALLOC(ret_constr.datalen * sizeof(LDKNodeAnnouncement), "LDKCVec_NodeAnnouncementZ Elements"); else ret_constr.data = NULL; uint32_t* ret_vals = (uint32_t*)(ret + 4); for (size_t s = 0; s < ret_constr.datalen; s++) { uint32_t ret_conv_18 = ret_vals[s]; LDKNodeAnnouncement ret_conv_18_conv; ret_conv_18_conv.inner = (void*)(ret_conv_18 & (~1)); ret_conv_18_conv.is_owned = (ret_conv_18 & 1) || (ret_conv_18 == 0); ret_conv_18_conv = NodeAnnouncement_clone(&ret_conv_18_conv); ret_constr.data[s] = ret_conv_18_conv; } return ret_constr; } void sync_routing_table_LDKRoutingMessageHandler_jcall(const void* this_arg, LDKPublicKey their_node_id, const LDKInit * init) { LDKRoutingMessageHandler_JCalls *j_calls = (LDKRoutingMessageHandler_JCalls*) this_arg; int8_tArray their_node_id_arr = init_arr(33, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(their_node_id_arr + 4), their_node_id.compressed_form, 33); LDKInit init_var = *init; init_var = Init_clone(init); CHECK((((uint64_t)init_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&init_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t init_ref = (uint64_t)init_var.inner; if (init_var.is_owned) { init_ref |= 1; } js_invoke_function_2(j_calls->sync_routing_table_meth, their_node_id_arr, init_ref); } LDKCResult_NoneLightningErrorZ handle_reply_channel_range_LDKRoutingMessageHandler_jcall(const void* this_arg, LDKPublicKey their_node_id, LDKReplyChannelRange msg) { LDKRoutingMessageHandler_JCalls *j_calls = (LDKRoutingMessageHandler_JCalls*) this_arg; int8_tArray their_node_id_arr = init_arr(33, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(their_node_id_arr + 4), their_node_id.compressed_form, 33); LDKReplyChannelRange msg_var = msg; CHECK((((uint64_t)msg_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&msg_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t msg_ref = (uint64_t)msg_var.inner; if (msg_var.is_owned) { msg_ref |= 1; } uint32_t ret = js_invoke_function_2(j_calls->handle_reply_channel_range_meth, their_node_id_arr, msg_ref); LDKCResult_NoneLightningErrorZ ret_conv = *(LDKCResult_NoneLightningErrorZ*)(((uint64_t)ret) & ~1); ret_conv = CResult_NoneLightningErrorZ_clone((LDKCResult_NoneLightningErrorZ*)(((uint64_t)ret) & ~1)); return ret_conv; } LDKCResult_NoneLightningErrorZ handle_reply_short_channel_ids_end_LDKRoutingMessageHandler_jcall(const void* this_arg, LDKPublicKey their_node_id, LDKReplyShortChannelIdsEnd msg) { LDKRoutingMessageHandler_JCalls *j_calls = (LDKRoutingMessageHandler_JCalls*) this_arg; int8_tArray their_node_id_arr = init_arr(33, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(their_node_id_arr + 4), their_node_id.compressed_form, 33); LDKReplyShortChannelIdsEnd msg_var = msg; CHECK((((uint64_t)msg_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&msg_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t msg_ref = (uint64_t)msg_var.inner; if (msg_var.is_owned) { msg_ref |= 1; } uint32_t ret = js_invoke_function_2(j_calls->handle_reply_short_channel_ids_end_meth, their_node_id_arr, msg_ref); LDKCResult_NoneLightningErrorZ ret_conv = *(LDKCResult_NoneLightningErrorZ*)(((uint64_t)ret) & ~1); ret_conv = CResult_NoneLightningErrorZ_clone((LDKCResult_NoneLightningErrorZ*)(((uint64_t)ret) & ~1)); return ret_conv; } LDKCResult_NoneLightningErrorZ handle_query_channel_range_LDKRoutingMessageHandler_jcall(const void* this_arg, LDKPublicKey their_node_id, LDKQueryChannelRange msg) { LDKRoutingMessageHandler_JCalls *j_calls = (LDKRoutingMessageHandler_JCalls*) this_arg; int8_tArray their_node_id_arr = init_arr(33, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(their_node_id_arr + 4), their_node_id.compressed_form, 33); LDKQueryChannelRange msg_var = msg; CHECK((((uint64_t)msg_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&msg_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t msg_ref = (uint64_t)msg_var.inner; if (msg_var.is_owned) { msg_ref |= 1; } uint32_t ret = js_invoke_function_2(j_calls->handle_query_channel_range_meth, their_node_id_arr, msg_ref); LDKCResult_NoneLightningErrorZ ret_conv = *(LDKCResult_NoneLightningErrorZ*)(((uint64_t)ret) & ~1); ret_conv = CResult_NoneLightningErrorZ_clone((LDKCResult_NoneLightningErrorZ*)(((uint64_t)ret) & ~1)); return ret_conv; } LDKCResult_NoneLightningErrorZ handle_query_short_channel_ids_LDKRoutingMessageHandler_jcall(const void* this_arg, LDKPublicKey their_node_id, LDKQueryShortChannelIds msg) { LDKRoutingMessageHandler_JCalls *j_calls = (LDKRoutingMessageHandler_JCalls*) this_arg; int8_tArray their_node_id_arr = init_arr(33, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(their_node_id_arr + 4), their_node_id.compressed_form, 33); LDKQueryShortChannelIds msg_var = msg; CHECK((((uint64_t)msg_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&msg_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t msg_ref = (uint64_t)msg_var.inner; if (msg_var.is_owned) { msg_ref |= 1; } uint32_t ret = js_invoke_function_2(j_calls->handle_query_short_channel_ids_meth, their_node_id_arr, msg_ref); LDKCResult_NoneLightningErrorZ ret_conv = *(LDKCResult_NoneLightningErrorZ*)(((uint64_t)ret) & ~1); ret_conv = CResult_NoneLightningErrorZ_clone((LDKCResult_NoneLightningErrorZ*)(((uint64_t)ret) & ~1)); return ret_conv; } static void LDKRoutingMessageHandler_JCalls_cloned(LDKRoutingMessageHandler* new_obj) { LDKRoutingMessageHandler_JCalls *j_calls = (LDKRoutingMessageHandler_JCalls*) new_obj->this_arg; atomic_fetch_add_explicit(&j_calls->refcnt, 1, memory_order_release); atomic_fetch_add_explicit(&j_calls->MessageSendEventsProvider->refcnt, 1, memory_order_release); } static inline LDKRoutingMessageHandler LDKRoutingMessageHandler_init (/*TODO: JS Object Reference */void* o, /*TODO: JS Object Reference */void* MessageSendEventsProvider) { LDKRoutingMessageHandler_JCalls *calls = MALLOC(sizeof(LDKRoutingMessageHandler_JCalls), "LDKRoutingMessageHandler_JCalls"); atomic_init(&calls->refcnt, 1); //TODO: Assign calls->o from o LDKRoutingMessageHandler ret = { .this_arg = (void*) calls, .handle_node_announcement = handle_node_announcement_LDKRoutingMessageHandler_jcall, .handle_channel_announcement = handle_channel_announcement_LDKRoutingMessageHandler_jcall, .handle_channel_update = handle_channel_update_LDKRoutingMessageHandler_jcall, .get_next_channel_announcements = get_next_channel_announcements_LDKRoutingMessageHandler_jcall, .get_next_node_announcements = get_next_node_announcements_LDKRoutingMessageHandler_jcall, .sync_routing_table = sync_routing_table_LDKRoutingMessageHandler_jcall, .handle_reply_channel_range = handle_reply_channel_range_LDKRoutingMessageHandler_jcall, .handle_reply_short_channel_ids_end = handle_reply_short_channel_ids_end_LDKRoutingMessageHandler_jcall, .handle_query_channel_range = handle_query_channel_range_LDKRoutingMessageHandler_jcall, .handle_query_short_channel_ids = handle_query_short_channel_ids_LDKRoutingMessageHandler_jcall, .free = LDKRoutingMessageHandler_JCalls_free, .MessageSendEventsProvider = LDKMessageSendEventsProvider_init(MessageSendEventsProvider), }; calls->MessageSendEventsProvider = ret.MessageSendEventsProvider.this_arg; return ret; } long __attribute__((visibility("default"))) TS_LDKRoutingMessageHandler_new(/*TODO: JS Object Reference */void* o, /*TODO: JS Object Reference */ void* MessageSendEventsProvider) { LDKRoutingMessageHandler *res_ptr = MALLOC(sizeof(LDKRoutingMessageHandler), "LDKRoutingMessageHandler"); *res_ptr = LDKRoutingMessageHandler_init(o, MessageSendEventsProvider); return (long)res_ptr; } uint32_t __attribute__((visibility("default"))) TS_RoutingMessageHandler_handle_node_announcement(uint32_t this_arg, uint32_t msg) { LDKRoutingMessageHandler* this_arg_conv = (LDKRoutingMessageHandler*)(((uint64_t)this_arg) & ~1); LDKNodeAnnouncement msg_conv; msg_conv.inner = (void*)(msg & (~1)); msg_conv.is_owned = false; LDKCResult_boolLightningErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_boolLightningErrorZ), "LDKCResult_boolLightningErrorZ"); *ret_conv = (this_arg_conv->handle_node_announcement)(this_arg_conv->this_arg, &msg_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_RoutingMessageHandler_handle_channel_announcement(uint32_t this_arg, uint32_t msg) { LDKRoutingMessageHandler* this_arg_conv = (LDKRoutingMessageHandler*)(((uint64_t)this_arg) & ~1); LDKChannelAnnouncement msg_conv; msg_conv.inner = (void*)(msg & (~1)); msg_conv.is_owned = false; LDKCResult_boolLightningErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_boolLightningErrorZ), "LDKCResult_boolLightningErrorZ"); *ret_conv = (this_arg_conv->handle_channel_announcement)(this_arg_conv->this_arg, &msg_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_RoutingMessageHandler_handle_channel_update(uint32_t this_arg, uint32_t msg) { LDKRoutingMessageHandler* this_arg_conv = (LDKRoutingMessageHandler*)(((uint64_t)this_arg) & ~1); LDKChannelUpdate msg_conv; msg_conv.inner = (void*)(msg & (~1)); msg_conv.is_owned = false; LDKCResult_boolLightningErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_boolLightningErrorZ), "LDKCResult_boolLightningErrorZ"); *ret_conv = (this_arg_conv->handle_channel_update)(this_arg_conv->this_arg, &msg_conv); return (uint64_t)ret_conv; } uint32_tArray __attribute__((visibility("default"))) TS_RoutingMessageHandler_get_next_channel_announcements(uint32_t this_arg, int64_t starting_point, int8_t batch_amount) { LDKRoutingMessageHandler* this_arg_conv = (LDKRoutingMessageHandler*)(((uint64_t)this_arg) & ~1); LDKCVec_C3Tuple_ChannelAnnouncementChannelUpdateChannelUpdateZZ ret_var = (this_arg_conv->get_next_channel_announcements)(this_arg_conv->this_arg, starting_point, batch_amount); uint32_tArray ret_arr = init_arr(ret_var.datalen, sizeof(uint32_t), "Native uint32_tArray Bytes"); uint32_t *ret_arr_ptr = (uint32_t*)(ret_arr + 4); for (size_t l = 0; l < ret_var.datalen; l++) { LDKC3Tuple_ChannelAnnouncementChannelUpdateChannelUpdateZ* ret_conv_63_ref = MALLOC(sizeof(LDKC3Tuple_ChannelAnnouncementChannelUpdateChannelUpdateZ), "LDKC3Tuple_ChannelAnnouncementChannelUpdateChannelUpdateZ"); *ret_conv_63_ref = ret_var.data[l]; ret_arr_ptr[l] = (uint64_t)ret_conv_63_ref; } FREE(ret_var.data); return ret_arr; } uint32_tArray __attribute__((visibility("default"))) TS_RoutingMessageHandler_get_next_node_announcements(uint32_t this_arg, int8_tArray starting_point, int8_t batch_amount) { LDKRoutingMessageHandler* this_arg_conv = (LDKRoutingMessageHandler*)(((uint64_t)this_arg) & ~1); LDKPublicKey starting_point_ref; CHECK(*((uint32_t*)starting_point) == 33); memcpy(starting_point_ref.compressed_form, (uint8_t*)(starting_point + 4), 33); LDKCVec_NodeAnnouncementZ ret_var = (this_arg_conv->get_next_node_announcements)(this_arg_conv->this_arg, starting_point_ref, batch_amount); uint32_tArray ret_arr = init_arr(ret_var.datalen, sizeof(uint32_t), "Native uint32_tArray Bytes"); uint32_t *ret_arr_ptr = (uint32_t*)(ret_arr + 4); for (size_t s = 0; s < ret_var.datalen; s++) { LDKNodeAnnouncement ret_conv_18_var = ret_var.data[s]; CHECK((((uint64_t)ret_conv_18_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_conv_18_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_conv_18_ref = (uint64_t)ret_conv_18_var.inner; if (ret_conv_18_var.is_owned) { ret_conv_18_ref |= 1; } ret_arr_ptr[s] = ret_conv_18_ref; } FREE(ret_var.data); return ret_arr; } void __attribute__((visibility("default"))) TS_RoutingMessageHandler_sync_routing_table(uint32_t this_arg, int8_tArray their_node_id, uint32_t init) { LDKRoutingMessageHandler* this_arg_conv = (LDKRoutingMessageHandler*)(((uint64_t)this_arg) & ~1); LDKPublicKey their_node_id_ref; CHECK(*((uint32_t*)their_node_id) == 33); memcpy(their_node_id_ref.compressed_form, (uint8_t*)(their_node_id + 4), 33); LDKInit init_conv; init_conv.inner = (void*)(init & (~1)); init_conv.is_owned = false; (this_arg_conv->sync_routing_table)(this_arg_conv->this_arg, their_node_id_ref, &init_conv); } uint32_t __attribute__((visibility("default"))) TS_RoutingMessageHandler_handle_reply_channel_range(uint32_t this_arg, int8_tArray their_node_id, uint32_t msg) { LDKRoutingMessageHandler* this_arg_conv = (LDKRoutingMessageHandler*)(((uint64_t)this_arg) & ~1); LDKPublicKey their_node_id_ref; CHECK(*((uint32_t*)their_node_id) == 33); memcpy(their_node_id_ref.compressed_form, (uint8_t*)(their_node_id + 4), 33); LDKReplyChannelRange msg_conv; msg_conv.inner = (void*)(msg & (~1)); msg_conv.is_owned = (msg & 1) || (msg == 0); msg_conv = ReplyChannelRange_clone(&msg_conv); LDKCResult_NoneLightningErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_NoneLightningErrorZ), "LDKCResult_NoneLightningErrorZ"); *ret_conv = (this_arg_conv->handle_reply_channel_range)(this_arg_conv->this_arg, their_node_id_ref, msg_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_RoutingMessageHandler_handle_reply_short_channel_ids_end(uint32_t this_arg, int8_tArray their_node_id, uint32_t msg) { LDKRoutingMessageHandler* this_arg_conv = (LDKRoutingMessageHandler*)(((uint64_t)this_arg) & ~1); LDKPublicKey their_node_id_ref; CHECK(*((uint32_t*)their_node_id) == 33); memcpy(their_node_id_ref.compressed_form, (uint8_t*)(their_node_id + 4), 33); LDKReplyShortChannelIdsEnd msg_conv; msg_conv.inner = (void*)(msg & (~1)); msg_conv.is_owned = (msg & 1) || (msg == 0); msg_conv = ReplyShortChannelIdsEnd_clone(&msg_conv); LDKCResult_NoneLightningErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_NoneLightningErrorZ), "LDKCResult_NoneLightningErrorZ"); *ret_conv = (this_arg_conv->handle_reply_short_channel_ids_end)(this_arg_conv->this_arg, their_node_id_ref, msg_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_RoutingMessageHandler_handle_query_channel_range(uint32_t this_arg, int8_tArray their_node_id, uint32_t msg) { LDKRoutingMessageHandler* this_arg_conv = (LDKRoutingMessageHandler*)(((uint64_t)this_arg) & ~1); LDKPublicKey their_node_id_ref; CHECK(*((uint32_t*)their_node_id) == 33); memcpy(their_node_id_ref.compressed_form, (uint8_t*)(their_node_id + 4), 33); LDKQueryChannelRange msg_conv; msg_conv.inner = (void*)(msg & (~1)); msg_conv.is_owned = (msg & 1) || (msg == 0); msg_conv = QueryChannelRange_clone(&msg_conv); LDKCResult_NoneLightningErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_NoneLightningErrorZ), "LDKCResult_NoneLightningErrorZ"); *ret_conv = (this_arg_conv->handle_query_channel_range)(this_arg_conv->this_arg, their_node_id_ref, msg_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_RoutingMessageHandler_handle_query_short_channel_ids(uint32_t this_arg, int8_tArray their_node_id, uint32_t msg) { LDKRoutingMessageHandler* this_arg_conv = (LDKRoutingMessageHandler*)(((uint64_t)this_arg) & ~1); LDKPublicKey their_node_id_ref; CHECK(*((uint32_t*)their_node_id) == 33); memcpy(their_node_id_ref.compressed_form, (uint8_t*)(their_node_id + 4), 33); LDKQueryShortChannelIds msg_conv; msg_conv.inner = (void*)(msg & (~1)); msg_conv.is_owned = (msg & 1) || (msg == 0); msg_conv = QueryShortChannelIds_clone(&msg_conv); LDKCResult_NoneLightningErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_NoneLightningErrorZ), "LDKCResult_NoneLightningErrorZ"); *ret_conv = (this_arg_conv->handle_query_short_channel_ids)(this_arg_conv->this_arg, their_node_id_ref, msg_conv); return (uint64_t)ret_conv; } typedef struct LDKCustomMessageReader_JCalls { atomic_size_t refcnt; uint32_t read_meth; } LDKCustomMessageReader_JCalls; static void LDKCustomMessageReader_JCalls_free(void* this_arg) { LDKCustomMessageReader_JCalls *j_calls = (LDKCustomMessageReader_JCalls*) this_arg; if (atomic_fetch_sub_explicit(&j_calls->refcnt, 1, memory_order_acquire) == 1) { js_free(j_calls->read_meth); FREE(j_calls); } } LDKCResult_COption_TypeZDecodeErrorZ read_LDKCustomMessageReader_jcall(const void* this_arg, uint16_t message_type, LDKu8slice buffer) { LDKCustomMessageReader_JCalls *j_calls = (LDKCustomMessageReader_JCalls*) this_arg; LDKu8slice buffer_var = buffer; int8_tArray buffer_arr = init_arr(buffer_var.datalen, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(buffer_arr + 4), buffer_var.data, buffer_var.datalen); uint32_t ret = js_invoke_function_2(j_calls->read_meth, message_type, buffer_arr); LDKCResult_COption_TypeZDecodeErrorZ ret_conv = *(LDKCResult_COption_TypeZDecodeErrorZ*)(((uint64_t)ret) & ~1); ret_conv = CResult_COption_TypeZDecodeErrorZ_clone((LDKCResult_COption_TypeZDecodeErrorZ*)(((uint64_t)ret) & ~1)); return ret_conv; } static void LDKCustomMessageReader_JCalls_cloned(LDKCustomMessageReader* new_obj) { LDKCustomMessageReader_JCalls *j_calls = (LDKCustomMessageReader_JCalls*) new_obj->this_arg; atomic_fetch_add_explicit(&j_calls->refcnt, 1, memory_order_release); } static inline LDKCustomMessageReader LDKCustomMessageReader_init (/*TODO: JS Object Reference */void* o) { LDKCustomMessageReader_JCalls *calls = MALLOC(sizeof(LDKCustomMessageReader_JCalls), "LDKCustomMessageReader_JCalls"); atomic_init(&calls->refcnt, 1); //TODO: Assign calls->o from o LDKCustomMessageReader ret = { .this_arg = (void*) calls, .read = read_LDKCustomMessageReader_jcall, .free = LDKCustomMessageReader_JCalls_free, }; return ret; } long __attribute__((visibility("default"))) TS_LDKCustomMessageReader_new(/*TODO: JS Object Reference */void* o) { LDKCustomMessageReader *res_ptr = MALLOC(sizeof(LDKCustomMessageReader), "LDKCustomMessageReader"); *res_ptr = LDKCustomMessageReader_init(o); return (long)res_ptr; } uint32_t __attribute__((visibility("default"))) TS_CustomMessageReader_read(uint32_t this_arg, int16_t message_type, int8_tArray buffer) { LDKCustomMessageReader* this_arg_conv = (LDKCustomMessageReader*)(((uint64_t)this_arg) & ~1); LDKu8slice buffer_ref; buffer_ref.datalen = *((uint32_t*)buffer); buffer_ref.data = (int8_t*)(buffer + 4); LDKCResult_COption_TypeZDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_COption_TypeZDecodeErrorZ), "LDKCResult_COption_TypeZDecodeErrorZ"); *ret_conv = (this_arg_conv->read)(this_arg_conv->this_arg, message_type, buffer_ref); return (uint64_t)ret_conv; } typedef struct LDKCustomMessageHandler_JCalls { atomic_size_t refcnt; LDKCustomMessageReader_JCalls* CustomMessageReader; uint32_t handle_custom_message_meth; uint32_t get_and_clear_pending_msg_meth; } LDKCustomMessageHandler_JCalls; static void LDKCustomMessageHandler_JCalls_free(void* this_arg) { LDKCustomMessageHandler_JCalls *j_calls = (LDKCustomMessageHandler_JCalls*) this_arg; if (atomic_fetch_sub_explicit(&j_calls->refcnt, 1, memory_order_acquire) == 1) { js_free(j_calls->handle_custom_message_meth); js_free(j_calls->get_and_clear_pending_msg_meth); FREE(j_calls); } } LDKCResult_NoneLightningErrorZ handle_custom_message_LDKCustomMessageHandler_jcall(const void* this_arg, LDKType msg, LDKPublicKey sender_node_id) { LDKCustomMessageHandler_JCalls *j_calls = (LDKCustomMessageHandler_JCalls*) this_arg; LDKType* msg_ret =MALLOC(sizeof(LDKType), "LDKType"); *msg_ret = msg; int8_tArray sender_node_id_arr = init_arr(33, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(sender_node_id_arr + 4), sender_node_id.compressed_form, 33); uint32_t ret = js_invoke_function_2(j_calls->handle_custom_message_meth, (uint64_t)msg_ret, sender_node_id_arr); LDKCResult_NoneLightningErrorZ ret_conv = *(LDKCResult_NoneLightningErrorZ*)(((uint64_t)ret) & ~1); ret_conv = CResult_NoneLightningErrorZ_clone((LDKCResult_NoneLightningErrorZ*)(((uint64_t)ret) & ~1)); return ret_conv; } LDKCVec_C2Tuple_PublicKeyTypeZZ get_and_clear_pending_msg_LDKCustomMessageHandler_jcall(const void* this_arg) { LDKCustomMessageHandler_JCalls *j_calls = (LDKCustomMessageHandler_JCalls*) this_arg; uint32_tArray ret = js_invoke_function_0(j_calls->get_and_clear_pending_msg_meth); LDKCVec_C2Tuple_PublicKeyTypeZZ ret_constr; ret_constr.datalen = *((uint32_t*)ret); if (ret_constr.datalen > 0) ret_constr.data = MALLOC(ret_constr.datalen * sizeof(LDKC2Tuple_PublicKeyTypeZ), "LDKCVec_C2Tuple_PublicKeyTypeZZ Elements"); else ret_constr.data = NULL; uint32_t* ret_vals = (uint32_t*)(ret + 4); for (size_t c = 0; c < ret_constr.datalen; c++) { uint32_t ret_conv_28 = ret_vals[c]; LDKC2Tuple_PublicKeyTypeZ ret_conv_28_conv = *(LDKC2Tuple_PublicKeyTypeZ*)(((uint64_t)ret_conv_28) & ~1); ret_conv_28_conv = C2Tuple_PublicKeyTypeZ_clone((LDKC2Tuple_PublicKeyTypeZ*)(((uint64_t)ret_conv_28) & ~1)); ret_constr.data[c] = ret_conv_28_conv; } return ret_constr; } static void LDKCustomMessageHandler_JCalls_cloned(LDKCustomMessageHandler* new_obj) { LDKCustomMessageHandler_JCalls *j_calls = (LDKCustomMessageHandler_JCalls*) new_obj->this_arg; atomic_fetch_add_explicit(&j_calls->refcnt, 1, memory_order_release); atomic_fetch_add_explicit(&j_calls->CustomMessageReader->refcnt, 1, memory_order_release); } static inline LDKCustomMessageHandler LDKCustomMessageHandler_init (/*TODO: JS Object Reference */void* o, /*TODO: JS Object Reference */void* CustomMessageReader) { LDKCustomMessageHandler_JCalls *calls = MALLOC(sizeof(LDKCustomMessageHandler_JCalls), "LDKCustomMessageHandler_JCalls"); atomic_init(&calls->refcnt, 1); //TODO: Assign calls->o from o LDKCustomMessageHandler ret = { .this_arg = (void*) calls, .handle_custom_message = handle_custom_message_LDKCustomMessageHandler_jcall, .get_and_clear_pending_msg = get_and_clear_pending_msg_LDKCustomMessageHandler_jcall, .free = LDKCustomMessageHandler_JCalls_free, .CustomMessageReader = LDKCustomMessageReader_init(CustomMessageReader), }; calls->CustomMessageReader = ret.CustomMessageReader.this_arg; return ret; } long __attribute__((visibility("default"))) TS_LDKCustomMessageHandler_new(/*TODO: JS Object Reference */void* o, /*TODO: JS Object Reference */ void* CustomMessageReader) { LDKCustomMessageHandler *res_ptr = MALLOC(sizeof(LDKCustomMessageHandler), "LDKCustomMessageHandler"); *res_ptr = LDKCustomMessageHandler_init(o, CustomMessageReader); return (long)res_ptr; } uint32_t __attribute__((visibility("default"))) TS_CustomMessageHandler_handle_custom_message(uint32_t this_arg, uint32_t msg, int8_tArray sender_node_id) { LDKCustomMessageHandler* this_arg_conv = (LDKCustomMessageHandler*)(((uint64_t)this_arg) & ~1); LDKType msg_conv = *(LDKType*)(((uint64_t)msg) & ~1); LDKPublicKey sender_node_id_ref; CHECK(*((uint32_t*)sender_node_id) == 33); memcpy(sender_node_id_ref.compressed_form, (uint8_t*)(sender_node_id + 4), 33); LDKCResult_NoneLightningErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_NoneLightningErrorZ), "LDKCResult_NoneLightningErrorZ"); *ret_conv = (this_arg_conv->handle_custom_message)(this_arg_conv->this_arg, msg_conv, sender_node_id_ref); return (uint64_t)ret_conv; } uint32_tArray __attribute__((visibility("default"))) TS_CustomMessageHandler_get_and_clear_pending_msg(uint32_t this_arg) { LDKCustomMessageHandler* this_arg_conv = (LDKCustomMessageHandler*)(((uint64_t)this_arg) & ~1); LDKCVec_C2Tuple_PublicKeyTypeZZ ret_var = (this_arg_conv->get_and_clear_pending_msg)(this_arg_conv->this_arg); uint32_tArray ret_arr = init_arr(ret_var.datalen, sizeof(uint32_t), "Native uint32_tArray Bytes"); uint32_t *ret_arr_ptr = (uint32_t*)(ret_arr + 4); for (size_t c = 0; c < ret_var.datalen; c++) { LDKC2Tuple_PublicKeyTypeZ* ret_conv_28_ref = MALLOC(sizeof(LDKC2Tuple_PublicKeyTypeZ), "LDKC2Tuple_PublicKeyTypeZ"); *ret_conv_28_ref = ret_var.data[c]; ret_arr_ptr[c] = (uint64_t)ret_conv_28_ref; } FREE(ret_var.data); return ret_arr; } typedef struct LDKSocketDescriptor_JCalls { atomic_size_t refcnt; uint32_t send_data_meth; uint32_t disconnect_socket_meth; uint32_t eq_meth; uint32_t hash_meth; } LDKSocketDescriptor_JCalls; static void LDKSocketDescriptor_JCalls_free(void* this_arg) { LDKSocketDescriptor_JCalls *j_calls = (LDKSocketDescriptor_JCalls*) this_arg; if (atomic_fetch_sub_explicit(&j_calls->refcnt, 1, memory_order_acquire) == 1) { js_free(j_calls->send_data_meth); js_free(j_calls->disconnect_socket_meth); js_free(j_calls->eq_meth); js_free(j_calls->hash_meth); FREE(j_calls); } } uintptr_t send_data_LDKSocketDescriptor_jcall(void* this_arg, LDKu8slice data, bool resume_read) { LDKSocketDescriptor_JCalls *j_calls = (LDKSocketDescriptor_JCalls*) this_arg; LDKu8slice data_var = data; int8_tArray data_arr = init_arr(data_var.datalen, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(data_arr + 4), data_var.data, data_var.datalen); return js_invoke_function_2(j_calls->send_data_meth, data_arr, resume_read); } void disconnect_socket_LDKSocketDescriptor_jcall(void* this_arg) { LDKSocketDescriptor_JCalls *j_calls = (LDKSocketDescriptor_JCalls*) this_arg; js_invoke_function_0(j_calls->disconnect_socket_meth); } bool eq_LDKSocketDescriptor_jcall(const void* this_arg, const LDKSocketDescriptor * other_arg) { LDKSocketDescriptor_JCalls *j_calls = (LDKSocketDescriptor_JCalls*) this_arg; LDKSocketDescriptor *other_arg_clone = MALLOC(sizeof(LDKSocketDescriptor), "LDKSocketDescriptor"); *other_arg_clone = SocketDescriptor_clone(other_arg); return js_invoke_function_1(j_calls->eq_meth, (uint64_t)other_arg_clone); } uint64_t hash_LDKSocketDescriptor_jcall(const void* this_arg) { LDKSocketDescriptor_JCalls *j_calls = (LDKSocketDescriptor_JCalls*) this_arg; return js_invoke_function_0(j_calls->hash_meth); } static void LDKSocketDescriptor_JCalls_cloned(LDKSocketDescriptor* new_obj) { LDKSocketDescriptor_JCalls *j_calls = (LDKSocketDescriptor_JCalls*) new_obj->this_arg; atomic_fetch_add_explicit(&j_calls->refcnt, 1, memory_order_release); } static inline LDKSocketDescriptor LDKSocketDescriptor_init (/*TODO: JS Object Reference */void* o) { LDKSocketDescriptor_JCalls *calls = MALLOC(sizeof(LDKSocketDescriptor_JCalls), "LDKSocketDescriptor_JCalls"); atomic_init(&calls->refcnt, 1); //TODO: Assign calls->o from o LDKSocketDescriptor ret = { .this_arg = (void*) calls, .send_data = send_data_LDKSocketDescriptor_jcall, .disconnect_socket = disconnect_socket_LDKSocketDescriptor_jcall, .eq = eq_LDKSocketDescriptor_jcall, .hash = hash_LDKSocketDescriptor_jcall, .cloned = LDKSocketDescriptor_JCalls_cloned, .free = LDKSocketDescriptor_JCalls_free, }; return ret; } long __attribute__((visibility("default"))) TS_LDKSocketDescriptor_new(/*TODO: JS Object Reference */void* o) { LDKSocketDescriptor *res_ptr = MALLOC(sizeof(LDKSocketDescriptor), "LDKSocketDescriptor"); *res_ptr = LDKSocketDescriptor_init(o); return (long)res_ptr; } int64_t __attribute__((visibility("default"))) TS_SocketDescriptor_send_data(uint32_t this_arg, int8_tArray data, jboolean resume_read) { LDKSocketDescriptor* this_arg_conv = (LDKSocketDescriptor*)(((uint64_t)this_arg) & ~1); LDKu8slice data_ref; data_ref.datalen = *((uint32_t*)data); data_ref.data = (int8_t*)(data + 4); int64_t ret_val = (this_arg_conv->send_data)(this_arg_conv->this_arg, data_ref, resume_read); return ret_val; } void __attribute__((visibility("default"))) TS_SocketDescriptor_disconnect_socket(uint32_t this_arg) { LDKSocketDescriptor* this_arg_conv = (LDKSocketDescriptor*)(((uint64_t)this_arg) & ~1); (this_arg_conv->disconnect_socket)(this_arg_conv->this_arg); } int64_t __attribute__((visibility("default"))) TS_SocketDescriptor_hash(uint32_t this_arg) { LDKSocketDescriptor* this_arg_conv = (LDKSocketDescriptor*)(((uint64_t)this_arg) & ~1); int64_t ret_val = (this_arg_conv->hash)(this_arg_conv->this_arg); return ret_val; } typedef struct LDKChannelManagerPersister_JCalls { atomic_size_t refcnt; uint32_t persist_manager_meth; } LDKChannelManagerPersister_JCalls; static void LDKChannelManagerPersister_JCalls_free(void* this_arg) { LDKChannelManagerPersister_JCalls *j_calls = (LDKChannelManagerPersister_JCalls*) this_arg; if (atomic_fetch_sub_explicit(&j_calls->refcnt, 1, memory_order_acquire) == 1) { js_free(j_calls->persist_manager_meth); FREE(j_calls); } } LDKCResult_NoneErrorZ persist_manager_LDKChannelManagerPersister_jcall(const void* this_arg, const LDKChannelManager * channel_manager) { LDKChannelManagerPersister_JCalls *j_calls = (LDKChannelManagerPersister_JCalls*) this_arg; LDKChannelManager channel_manager_var = *channel_manager; // Warning: we may need a move here but no clone is available for LDKChannelManager CHECK((((uint64_t)channel_manager_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&channel_manager_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t channel_manager_ref = (uint64_t)channel_manager_var.inner; if (channel_manager_var.is_owned) { channel_manager_ref |= 1; } uint32_t ret = js_invoke_function_1(j_calls->persist_manager_meth, channel_manager_ref); LDKCResult_NoneErrorZ ret_conv = *(LDKCResult_NoneErrorZ*)(((uint64_t)ret) & ~1); ret_conv = CResult_NoneErrorZ_clone((LDKCResult_NoneErrorZ*)(((uint64_t)ret) & ~1)); return ret_conv; } static void LDKChannelManagerPersister_JCalls_cloned(LDKChannelManagerPersister* new_obj) { LDKChannelManagerPersister_JCalls *j_calls = (LDKChannelManagerPersister_JCalls*) new_obj->this_arg; atomic_fetch_add_explicit(&j_calls->refcnt, 1, memory_order_release); } static inline LDKChannelManagerPersister LDKChannelManagerPersister_init (/*TODO: JS Object Reference */void* o) { LDKChannelManagerPersister_JCalls *calls = MALLOC(sizeof(LDKChannelManagerPersister_JCalls), "LDKChannelManagerPersister_JCalls"); atomic_init(&calls->refcnt, 1); //TODO: Assign calls->o from o LDKChannelManagerPersister ret = { .this_arg = (void*) calls, .persist_manager = persist_manager_LDKChannelManagerPersister_jcall, .free = LDKChannelManagerPersister_JCalls_free, }; return ret; } long __attribute__((visibility("default"))) TS_LDKChannelManagerPersister_new(/*TODO: JS Object Reference */void* o) { LDKChannelManagerPersister *res_ptr = MALLOC(sizeof(LDKChannelManagerPersister), "LDKChannelManagerPersister"); *res_ptr = LDKChannelManagerPersister_init(o); return (long)res_ptr; } uint32_t __attribute__((visibility("default"))) TS_ChannelManagerPersister_persist_manager(uint32_t this_arg, uint32_t channel_manager) { LDKChannelManagerPersister* this_arg_conv = (LDKChannelManagerPersister*)(((uint64_t)this_arg) & ~1); LDKChannelManager channel_manager_conv; channel_manager_conv.inner = (void*)(channel_manager & (~1)); channel_manager_conv.is_owned = false; LDKCResult_NoneErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_NoneErrorZ), "LDKCResult_NoneErrorZ"); *ret_conv = (this_arg_conv->persist_manager)(this_arg_conv->this_arg, &channel_manager_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_LDKFallback_ref_from_ptr(uint32_t ptr) { LDKFallback *obj = (LDKFallback*)(ptr & ~1); switch(obj->tag) { case LDKFallback_SegWitProgram: { uint8_t version_val = obj->seg_wit_program.version._0; LDKCVec_u8Z program_var = obj->seg_wit_program.program; int8_tArray program_arr = init_arr(program_var.datalen, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(program_arr + 4), program_var.data, program_var.datalen); return 0 /* LDKFallback - SegWitProgram */; (void) version_val; (void) program_arr; } case LDKFallback_PubKeyHash: { int8_tArray pub_key_hash_arr = init_arr(20, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(pub_key_hash_arr + 4), obj->pub_key_hash.data, 20); return 0 /* LDKFallback - PubKeyHash */; (void) pub_key_hash_arr; } case LDKFallback_ScriptHash: { int8_tArray script_hash_arr = init_arr(20, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(script_hash_arr + 4), obj->script_hash.data, 20); return 0 /* LDKFallback - ScriptHash */; (void) script_hash_arr; } default: abort(); } } jstring __attribute__((visibility("default"))) TS__ldk_get_compiled_version() { LDKStr ret_str = _ldk_get_compiled_version(); jstring ret_conv = str_ref_to_ts(ret_str.chars, ret_str.len); Str_free(ret_str); return ret_conv; } jstring __attribute__((visibility("default"))) TS__ldk_c_bindings_get_compiled_version() { LDKStr ret_str = _ldk_c_bindings_get_compiled_version(); jstring ret_conv = str_ref_to_ts(ret_str.chars, ret_str.len); Str_free(ret_str); return ret_conv; } void __attribute__((visibility("default"))) TS_Transaction_free(int8_tArray _res) { LDKTransaction _res_ref; _res_ref.datalen = *((uint32_t*)_res); _res_ref.data = MALLOC(_res_ref.datalen, "LDKTransaction Bytes"); memcpy(_res_ref.data, (uint8_t*)(_res + 4), _res_ref.datalen); _res_ref.data_is_owned = true; Transaction_free(_res_ref); } uint32_t __attribute__((visibility("default"))) TS_TxOut_new(int8_tArray script_pubkey, int64_t value) { LDKCVec_u8Z script_pubkey_ref; script_pubkey_ref.datalen = *((uint32_t*)script_pubkey); script_pubkey_ref.data = MALLOC(script_pubkey_ref.datalen, "LDKCVec_u8Z Bytes"); memcpy(script_pubkey_ref.data, (uint8_t*)(script_pubkey + 4), script_pubkey_ref.datalen); LDKTxOut* ret_ref = MALLOC(sizeof(LDKTxOut), "LDKTxOut"); *ret_ref = TxOut_new(script_pubkey_ref, value); return (uint64_t)ret_ref; } void __attribute__((visibility("default"))) TS_TxOut_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKTxOut _res_conv = *(LDKTxOut*)(((uint64_t)_res) & ~1); FREE((void*)_res); TxOut_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_TxOut_clone(uint32_t orig) { LDKTxOut* orig_conv = (LDKTxOut*)(orig & ~1); LDKTxOut* ret_ref = MALLOC(sizeof(LDKTxOut), "LDKTxOut"); *ret_ref = TxOut_clone(orig_conv); return (uint64_t)ret_ref; } void __attribute__((visibility("default"))) TS_Str_free(jstring _res) { LDKStr dummy = { .chars = NULL, .len = 0, .chars_is_owned = false }; Str_free(dummy); } uint32_t __attribute__((visibility("default"))) TS_CResult_SecretKeyErrorZ_ok(int8_tArray o) { LDKSecretKey o_ref; CHECK(*((uint32_t*)o) == 32); memcpy(o_ref.bytes, (uint8_t*)(o + 4), 32); LDKCResult_SecretKeyErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_SecretKeyErrorZ), "LDKCResult_SecretKeyErrorZ"); *ret_conv = CResult_SecretKeyErrorZ_ok(o_ref); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_SecretKeyErrorZ_err(uint32_t e) { LDKSecp256k1Error e_conv = LDKSecp256k1Error_from_js(e); LDKCResult_SecretKeyErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_SecretKeyErrorZ), "LDKCResult_SecretKeyErrorZ"); *ret_conv = CResult_SecretKeyErrorZ_err(e_conv); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CResult_SecretKeyErrorZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCResult_SecretKeyErrorZ _res_conv = *(LDKCResult_SecretKeyErrorZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); CResult_SecretKeyErrorZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_CResult_PublicKeyErrorZ_ok(int8_tArray o) { LDKPublicKey o_ref; CHECK(*((uint32_t*)o) == 33); memcpy(o_ref.compressed_form, (uint8_t*)(o + 4), 33); LDKCResult_PublicKeyErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_PublicKeyErrorZ), "LDKCResult_PublicKeyErrorZ"); *ret_conv = CResult_PublicKeyErrorZ_ok(o_ref); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_PublicKeyErrorZ_err(uint32_t e) { LDKSecp256k1Error e_conv = LDKSecp256k1Error_from_js(e); LDKCResult_PublicKeyErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_PublicKeyErrorZ), "LDKCResult_PublicKeyErrorZ"); *ret_conv = CResult_PublicKeyErrorZ_err(e_conv); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CResult_PublicKeyErrorZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCResult_PublicKeyErrorZ _res_conv = *(LDKCResult_PublicKeyErrorZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); CResult_PublicKeyErrorZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_CResult_PublicKeyErrorZ_clone(uint32_t orig) { LDKCResult_PublicKeyErrorZ* orig_conv = (LDKCResult_PublicKeyErrorZ*)(orig & ~1); LDKCResult_PublicKeyErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_PublicKeyErrorZ), "LDKCResult_PublicKeyErrorZ"); *ret_conv = CResult_PublicKeyErrorZ_clone(orig_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_TxCreationKeysDecodeErrorZ_ok(uint32_t o) { LDKTxCreationKeys o_conv; o_conv.inner = (void*)(o & (~1)); o_conv.is_owned = (o & 1) || (o == 0); o_conv = TxCreationKeys_clone(&o_conv); LDKCResult_TxCreationKeysDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_TxCreationKeysDecodeErrorZ), "LDKCResult_TxCreationKeysDecodeErrorZ"); *ret_conv = CResult_TxCreationKeysDecodeErrorZ_ok(o_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_TxCreationKeysDecodeErrorZ_err(uint32_t e) { LDKDecodeError e_conv; e_conv.inner = (void*)(e & (~1)); e_conv.is_owned = (e & 1) || (e == 0); e_conv = DecodeError_clone(&e_conv); LDKCResult_TxCreationKeysDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_TxCreationKeysDecodeErrorZ), "LDKCResult_TxCreationKeysDecodeErrorZ"); *ret_conv = CResult_TxCreationKeysDecodeErrorZ_err(e_conv); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CResult_TxCreationKeysDecodeErrorZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCResult_TxCreationKeysDecodeErrorZ _res_conv = *(LDKCResult_TxCreationKeysDecodeErrorZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); CResult_TxCreationKeysDecodeErrorZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_CResult_TxCreationKeysDecodeErrorZ_clone(uint32_t orig) { LDKCResult_TxCreationKeysDecodeErrorZ* orig_conv = (LDKCResult_TxCreationKeysDecodeErrorZ*)(orig & ~1); LDKCResult_TxCreationKeysDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_TxCreationKeysDecodeErrorZ), "LDKCResult_TxCreationKeysDecodeErrorZ"); *ret_conv = CResult_TxCreationKeysDecodeErrorZ_clone(orig_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_ChannelPublicKeysDecodeErrorZ_ok(uint32_t o) { LDKChannelPublicKeys o_conv; o_conv.inner = (void*)(o & (~1)); o_conv.is_owned = (o & 1) || (o == 0); o_conv = ChannelPublicKeys_clone(&o_conv); LDKCResult_ChannelPublicKeysDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_ChannelPublicKeysDecodeErrorZ), "LDKCResult_ChannelPublicKeysDecodeErrorZ"); *ret_conv = CResult_ChannelPublicKeysDecodeErrorZ_ok(o_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_ChannelPublicKeysDecodeErrorZ_err(uint32_t e) { LDKDecodeError e_conv; e_conv.inner = (void*)(e & (~1)); e_conv.is_owned = (e & 1) || (e == 0); e_conv = DecodeError_clone(&e_conv); LDKCResult_ChannelPublicKeysDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_ChannelPublicKeysDecodeErrorZ), "LDKCResult_ChannelPublicKeysDecodeErrorZ"); *ret_conv = CResult_ChannelPublicKeysDecodeErrorZ_err(e_conv); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CResult_ChannelPublicKeysDecodeErrorZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCResult_ChannelPublicKeysDecodeErrorZ _res_conv = *(LDKCResult_ChannelPublicKeysDecodeErrorZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); CResult_ChannelPublicKeysDecodeErrorZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_CResult_ChannelPublicKeysDecodeErrorZ_clone(uint32_t orig) { LDKCResult_ChannelPublicKeysDecodeErrorZ* orig_conv = (LDKCResult_ChannelPublicKeysDecodeErrorZ*)(orig & ~1); LDKCResult_ChannelPublicKeysDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_ChannelPublicKeysDecodeErrorZ), "LDKCResult_ChannelPublicKeysDecodeErrorZ"); *ret_conv = CResult_ChannelPublicKeysDecodeErrorZ_clone(orig_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_TxCreationKeysErrorZ_ok(uint32_t o) { LDKTxCreationKeys o_conv; o_conv.inner = (void*)(o & (~1)); o_conv.is_owned = (o & 1) || (o == 0); o_conv = TxCreationKeys_clone(&o_conv); LDKCResult_TxCreationKeysErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_TxCreationKeysErrorZ), "LDKCResult_TxCreationKeysErrorZ"); *ret_conv = CResult_TxCreationKeysErrorZ_ok(o_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_TxCreationKeysErrorZ_err(uint32_t e) { LDKSecp256k1Error e_conv = LDKSecp256k1Error_from_js(e); LDKCResult_TxCreationKeysErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_TxCreationKeysErrorZ), "LDKCResult_TxCreationKeysErrorZ"); *ret_conv = CResult_TxCreationKeysErrorZ_err(e_conv); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CResult_TxCreationKeysErrorZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCResult_TxCreationKeysErrorZ _res_conv = *(LDKCResult_TxCreationKeysErrorZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); CResult_TxCreationKeysErrorZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_CResult_TxCreationKeysErrorZ_clone(uint32_t orig) { LDKCResult_TxCreationKeysErrorZ* orig_conv = (LDKCResult_TxCreationKeysErrorZ*)(orig & ~1); LDKCResult_TxCreationKeysErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_TxCreationKeysErrorZ), "LDKCResult_TxCreationKeysErrorZ"); *ret_conv = CResult_TxCreationKeysErrorZ_clone(orig_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_COption_u32Z_some(int32_t o) { LDKCOption_u32Z *ret_copy = MALLOC(sizeof(LDKCOption_u32Z), "LDKCOption_u32Z"); *ret_copy = COption_u32Z_some(o); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_COption_u32Z_none() { LDKCOption_u32Z *ret_copy = MALLOC(sizeof(LDKCOption_u32Z), "LDKCOption_u32Z"); *ret_copy = COption_u32Z_none(); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } void __attribute__((visibility("default"))) TS_COption_u32Z_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCOption_u32Z _res_conv = *(LDKCOption_u32Z*)(((uint64_t)_res) & ~1); FREE((void*)_res); COption_u32Z_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_COption_u32Z_clone(uint32_t orig) { LDKCOption_u32Z* orig_conv = (LDKCOption_u32Z*)orig; LDKCOption_u32Z *ret_copy = MALLOC(sizeof(LDKCOption_u32Z), "LDKCOption_u32Z"); *ret_copy = COption_u32Z_clone(orig_conv); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_CResult_HTLCOutputInCommitmentDecodeErrorZ_ok(uint32_t o) { LDKHTLCOutputInCommitment o_conv; o_conv.inner = (void*)(o & (~1)); o_conv.is_owned = (o & 1) || (o == 0); o_conv = HTLCOutputInCommitment_clone(&o_conv); LDKCResult_HTLCOutputInCommitmentDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_HTLCOutputInCommitmentDecodeErrorZ), "LDKCResult_HTLCOutputInCommitmentDecodeErrorZ"); *ret_conv = CResult_HTLCOutputInCommitmentDecodeErrorZ_ok(o_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_HTLCOutputInCommitmentDecodeErrorZ_err(uint32_t e) { LDKDecodeError e_conv; e_conv.inner = (void*)(e & (~1)); e_conv.is_owned = (e & 1) || (e == 0); e_conv = DecodeError_clone(&e_conv); LDKCResult_HTLCOutputInCommitmentDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_HTLCOutputInCommitmentDecodeErrorZ), "LDKCResult_HTLCOutputInCommitmentDecodeErrorZ"); *ret_conv = CResult_HTLCOutputInCommitmentDecodeErrorZ_err(e_conv); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CResult_HTLCOutputInCommitmentDecodeErrorZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCResult_HTLCOutputInCommitmentDecodeErrorZ _res_conv = *(LDKCResult_HTLCOutputInCommitmentDecodeErrorZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); CResult_HTLCOutputInCommitmentDecodeErrorZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_CResult_HTLCOutputInCommitmentDecodeErrorZ_clone(uint32_t orig) { LDKCResult_HTLCOutputInCommitmentDecodeErrorZ* orig_conv = (LDKCResult_HTLCOutputInCommitmentDecodeErrorZ*)(orig & ~1); LDKCResult_HTLCOutputInCommitmentDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_HTLCOutputInCommitmentDecodeErrorZ), "LDKCResult_HTLCOutputInCommitmentDecodeErrorZ"); *ret_conv = CResult_HTLCOutputInCommitmentDecodeErrorZ_clone(orig_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_CounterpartyChannelTransactionParametersDecodeErrorZ_ok(uint32_t o) { LDKCounterpartyChannelTransactionParameters o_conv; o_conv.inner = (void*)(o & (~1)); o_conv.is_owned = (o & 1) || (o == 0); o_conv = CounterpartyChannelTransactionParameters_clone(&o_conv); LDKCResult_CounterpartyChannelTransactionParametersDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_CounterpartyChannelTransactionParametersDecodeErrorZ), "LDKCResult_CounterpartyChannelTransactionParametersDecodeErrorZ"); *ret_conv = CResult_CounterpartyChannelTransactionParametersDecodeErrorZ_ok(o_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_CounterpartyChannelTransactionParametersDecodeErrorZ_err(uint32_t e) { LDKDecodeError e_conv; e_conv.inner = (void*)(e & (~1)); e_conv.is_owned = (e & 1) || (e == 0); e_conv = DecodeError_clone(&e_conv); LDKCResult_CounterpartyChannelTransactionParametersDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_CounterpartyChannelTransactionParametersDecodeErrorZ), "LDKCResult_CounterpartyChannelTransactionParametersDecodeErrorZ"); *ret_conv = CResult_CounterpartyChannelTransactionParametersDecodeErrorZ_err(e_conv); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CResult_CounterpartyChannelTransactionParametersDecodeErrorZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCResult_CounterpartyChannelTransactionParametersDecodeErrorZ _res_conv = *(LDKCResult_CounterpartyChannelTransactionParametersDecodeErrorZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); CResult_CounterpartyChannelTransactionParametersDecodeErrorZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_CResult_CounterpartyChannelTransactionParametersDecodeErrorZ_clone(uint32_t orig) { LDKCResult_CounterpartyChannelTransactionParametersDecodeErrorZ* orig_conv = (LDKCResult_CounterpartyChannelTransactionParametersDecodeErrorZ*)(orig & ~1); LDKCResult_CounterpartyChannelTransactionParametersDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_CounterpartyChannelTransactionParametersDecodeErrorZ), "LDKCResult_CounterpartyChannelTransactionParametersDecodeErrorZ"); *ret_conv = CResult_CounterpartyChannelTransactionParametersDecodeErrorZ_clone(orig_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_ChannelTransactionParametersDecodeErrorZ_ok(uint32_t o) { LDKChannelTransactionParameters o_conv; o_conv.inner = (void*)(o & (~1)); o_conv.is_owned = (o & 1) || (o == 0); o_conv = ChannelTransactionParameters_clone(&o_conv); LDKCResult_ChannelTransactionParametersDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_ChannelTransactionParametersDecodeErrorZ), "LDKCResult_ChannelTransactionParametersDecodeErrorZ"); *ret_conv = CResult_ChannelTransactionParametersDecodeErrorZ_ok(o_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_ChannelTransactionParametersDecodeErrorZ_err(uint32_t e) { LDKDecodeError e_conv; e_conv.inner = (void*)(e & (~1)); e_conv.is_owned = (e & 1) || (e == 0); e_conv = DecodeError_clone(&e_conv); LDKCResult_ChannelTransactionParametersDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_ChannelTransactionParametersDecodeErrorZ), "LDKCResult_ChannelTransactionParametersDecodeErrorZ"); *ret_conv = CResult_ChannelTransactionParametersDecodeErrorZ_err(e_conv); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CResult_ChannelTransactionParametersDecodeErrorZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCResult_ChannelTransactionParametersDecodeErrorZ _res_conv = *(LDKCResult_ChannelTransactionParametersDecodeErrorZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); CResult_ChannelTransactionParametersDecodeErrorZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_CResult_ChannelTransactionParametersDecodeErrorZ_clone(uint32_t orig) { LDKCResult_ChannelTransactionParametersDecodeErrorZ* orig_conv = (LDKCResult_ChannelTransactionParametersDecodeErrorZ*)(orig & ~1); LDKCResult_ChannelTransactionParametersDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_ChannelTransactionParametersDecodeErrorZ), "LDKCResult_ChannelTransactionParametersDecodeErrorZ"); *ret_conv = CResult_ChannelTransactionParametersDecodeErrorZ_clone(orig_conv); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CVec_SignatureZ_free(ptrArray _res) { LDKCVec_SignatureZ _res_constr; _res_constr.datalen = *((uint32_t*)_res); if (_res_constr.datalen > 0) _res_constr.data = MALLOC(_res_constr.datalen * sizeof(LDKSignature), "LDKCVec_SignatureZ Elements"); else _res_constr.data = NULL; int8_tArray* _res_vals = (int8_tArray*)(_res + 4); for (size_t m = 0; m < _res_constr.datalen; m++) { int8_tArray _res_conv_12 = _res_vals[m]; LDKSignature _res_conv_12_ref; CHECK(*((uint32_t*)_res_conv_12) == 64); memcpy(_res_conv_12_ref.compact_form, (uint8_t*)(_res_conv_12 + 4), 64); _res_constr.data[m] = _res_conv_12_ref; } CVec_SignatureZ_free(_res_constr); } uint32_t __attribute__((visibility("default"))) TS_CResult_HolderCommitmentTransactionDecodeErrorZ_ok(uint32_t o) { LDKHolderCommitmentTransaction o_conv; o_conv.inner = (void*)(o & (~1)); o_conv.is_owned = (o & 1) || (o == 0); o_conv = HolderCommitmentTransaction_clone(&o_conv); LDKCResult_HolderCommitmentTransactionDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_HolderCommitmentTransactionDecodeErrorZ), "LDKCResult_HolderCommitmentTransactionDecodeErrorZ"); *ret_conv = CResult_HolderCommitmentTransactionDecodeErrorZ_ok(o_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_HolderCommitmentTransactionDecodeErrorZ_err(uint32_t e) { LDKDecodeError e_conv; e_conv.inner = (void*)(e & (~1)); e_conv.is_owned = (e & 1) || (e == 0); e_conv = DecodeError_clone(&e_conv); LDKCResult_HolderCommitmentTransactionDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_HolderCommitmentTransactionDecodeErrorZ), "LDKCResult_HolderCommitmentTransactionDecodeErrorZ"); *ret_conv = CResult_HolderCommitmentTransactionDecodeErrorZ_err(e_conv); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CResult_HolderCommitmentTransactionDecodeErrorZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCResult_HolderCommitmentTransactionDecodeErrorZ _res_conv = *(LDKCResult_HolderCommitmentTransactionDecodeErrorZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); CResult_HolderCommitmentTransactionDecodeErrorZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_CResult_HolderCommitmentTransactionDecodeErrorZ_clone(uint32_t orig) { LDKCResult_HolderCommitmentTransactionDecodeErrorZ* orig_conv = (LDKCResult_HolderCommitmentTransactionDecodeErrorZ*)(orig & ~1); LDKCResult_HolderCommitmentTransactionDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_HolderCommitmentTransactionDecodeErrorZ), "LDKCResult_HolderCommitmentTransactionDecodeErrorZ"); *ret_conv = CResult_HolderCommitmentTransactionDecodeErrorZ_clone(orig_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_BuiltCommitmentTransactionDecodeErrorZ_ok(uint32_t o) { LDKBuiltCommitmentTransaction o_conv; o_conv.inner = (void*)(o & (~1)); o_conv.is_owned = (o & 1) || (o == 0); o_conv = BuiltCommitmentTransaction_clone(&o_conv); LDKCResult_BuiltCommitmentTransactionDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_BuiltCommitmentTransactionDecodeErrorZ), "LDKCResult_BuiltCommitmentTransactionDecodeErrorZ"); *ret_conv = CResult_BuiltCommitmentTransactionDecodeErrorZ_ok(o_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_BuiltCommitmentTransactionDecodeErrorZ_err(uint32_t e) { LDKDecodeError e_conv; e_conv.inner = (void*)(e & (~1)); e_conv.is_owned = (e & 1) || (e == 0); e_conv = DecodeError_clone(&e_conv); LDKCResult_BuiltCommitmentTransactionDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_BuiltCommitmentTransactionDecodeErrorZ), "LDKCResult_BuiltCommitmentTransactionDecodeErrorZ"); *ret_conv = CResult_BuiltCommitmentTransactionDecodeErrorZ_err(e_conv); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CResult_BuiltCommitmentTransactionDecodeErrorZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCResult_BuiltCommitmentTransactionDecodeErrorZ _res_conv = *(LDKCResult_BuiltCommitmentTransactionDecodeErrorZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); CResult_BuiltCommitmentTransactionDecodeErrorZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_CResult_BuiltCommitmentTransactionDecodeErrorZ_clone(uint32_t orig) { LDKCResult_BuiltCommitmentTransactionDecodeErrorZ* orig_conv = (LDKCResult_BuiltCommitmentTransactionDecodeErrorZ*)(orig & ~1); LDKCResult_BuiltCommitmentTransactionDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_BuiltCommitmentTransactionDecodeErrorZ), "LDKCResult_BuiltCommitmentTransactionDecodeErrorZ"); *ret_conv = CResult_BuiltCommitmentTransactionDecodeErrorZ_clone(orig_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_TrustedClosingTransactionNoneZ_ok(uint32_t o) { LDKTrustedClosingTransaction o_conv; o_conv.inner = (void*)(o & (~1)); o_conv.is_owned = (o & 1) || (o == 0); // Warning: we need a move here but no clone is available for LDKTrustedClosingTransaction LDKCResult_TrustedClosingTransactionNoneZ* ret_conv = MALLOC(sizeof(LDKCResult_TrustedClosingTransactionNoneZ), "LDKCResult_TrustedClosingTransactionNoneZ"); *ret_conv = CResult_TrustedClosingTransactionNoneZ_ok(o_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_TrustedClosingTransactionNoneZ_err() { LDKCResult_TrustedClosingTransactionNoneZ* ret_conv = MALLOC(sizeof(LDKCResult_TrustedClosingTransactionNoneZ), "LDKCResult_TrustedClosingTransactionNoneZ"); *ret_conv = CResult_TrustedClosingTransactionNoneZ_err(); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CResult_TrustedClosingTransactionNoneZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCResult_TrustedClosingTransactionNoneZ _res_conv = *(LDKCResult_TrustedClosingTransactionNoneZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); CResult_TrustedClosingTransactionNoneZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_CResult_CommitmentTransactionDecodeErrorZ_ok(uint32_t o) { LDKCommitmentTransaction o_conv; o_conv.inner = (void*)(o & (~1)); o_conv.is_owned = (o & 1) || (o == 0); o_conv = CommitmentTransaction_clone(&o_conv); LDKCResult_CommitmentTransactionDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_CommitmentTransactionDecodeErrorZ), "LDKCResult_CommitmentTransactionDecodeErrorZ"); *ret_conv = CResult_CommitmentTransactionDecodeErrorZ_ok(o_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_CommitmentTransactionDecodeErrorZ_err(uint32_t e) { LDKDecodeError e_conv; e_conv.inner = (void*)(e & (~1)); e_conv.is_owned = (e & 1) || (e == 0); e_conv = DecodeError_clone(&e_conv); LDKCResult_CommitmentTransactionDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_CommitmentTransactionDecodeErrorZ), "LDKCResult_CommitmentTransactionDecodeErrorZ"); *ret_conv = CResult_CommitmentTransactionDecodeErrorZ_err(e_conv); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CResult_CommitmentTransactionDecodeErrorZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCResult_CommitmentTransactionDecodeErrorZ _res_conv = *(LDKCResult_CommitmentTransactionDecodeErrorZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); CResult_CommitmentTransactionDecodeErrorZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_CResult_CommitmentTransactionDecodeErrorZ_clone(uint32_t orig) { LDKCResult_CommitmentTransactionDecodeErrorZ* orig_conv = (LDKCResult_CommitmentTransactionDecodeErrorZ*)(orig & ~1); LDKCResult_CommitmentTransactionDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_CommitmentTransactionDecodeErrorZ), "LDKCResult_CommitmentTransactionDecodeErrorZ"); *ret_conv = CResult_CommitmentTransactionDecodeErrorZ_clone(orig_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_TrustedCommitmentTransactionNoneZ_ok(uint32_t o) { LDKTrustedCommitmentTransaction o_conv; o_conv.inner = (void*)(o & (~1)); o_conv.is_owned = (o & 1) || (o == 0); // Warning: we need a move here but no clone is available for LDKTrustedCommitmentTransaction LDKCResult_TrustedCommitmentTransactionNoneZ* ret_conv = MALLOC(sizeof(LDKCResult_TrustedCommitmentTransactionNoneZ), "LDKCResult_TrustedCommitmentTransactionNoneZ"); *ret_conv = CResult_TrustedCommitmentTransactionNoneZ_ok(o_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_TrustedCommitmentTransactionNoneZ_err() { LDKCResult_TrustedCommitmentTransactionNoneZ* ret_conv = MALLOC(sizeof(LDKCResult_TrustedCommitmentTransactionNoneZ), "LDKCResult_TrustedCommitmentTransactionNoneZ"); *ret_conv = CResult_TrustedCommitmentTransactionNoneZ_err(); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CResult_TrustedCommitmentTransactionNoneZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCResult_TrustedCommitmentTransactionNoneZ _res_conv = *(LDKCResult_TrustedCommitmentTransactionNoneZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); CResult_TrustedCommitmentTransactionNoneZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_CResult_CVec_SignatureZNoneZ_ok(ptrArray o) { LDKCVec_SignatureZ o_constr; o_constr.datalen = *((uint32_t*)o); if (o_constr.datalen > 0) o_constr.data = MALLOC(o_constr.datalen * sizeof(LDKSignature), "LDKCVec_SignatureZ Elements"); else o_constr.data = NULL; int8_tArray* o_vals = (int8_tArray*)(o + 4); for (size_t m = 0; m < o_constr.datalen; m++) { int8_tArray o_conv_12 = o_vals[m]; LDKSignature o_conv_12_ref; CHECK(*((uint32_t*)o_conv_12) == 64); memcpy(o_conv_12_ref.compact_form, (uint8_t*)(o_conv_12 + 4), 64); o_constr.data[m] = o_conv_12_ref; } LDKCResult_CVec_SignatureZNoneZ* ret_conv = MALLOC(sizeof(LDKCResult_CVec_SignatureZNoneZ), "LDKCResult_CVec_SignatureZNoneZ"); *ret_conv = CResult_CVec_SignatureZNoneZ_ok(o_constr); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_CVec_SignatureZNoneZ_err() { LDKCResult_CVec_SignatureZNoneZ* ret_conv = MALLOC(sizeof(LDKCResult_CVec_SignatureZNoneZ), "LDKCResult_CVec_SignatureZNoneZ"); *ret_conv = CResult_CVec_SignatureZNoneZ_err(); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CResult_CVec_SignatureZNoneZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCResult_CVec_SignatureZNoneZ _res_conv = *(LDKCResult_CVec_SignatureZNoneZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); CResult_CVec_SignatureZNoneZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_CResult_CVec_SignatureZNoneZ_clone(uint32_t orig) { LDKCResult_CVec_SignatureZNoneZ* orig_conv = (LDKCResult_CVec_SignatureZNoneZ*)(orig & ~1); LDKCResult_CVec_SignatureZNoneZ* ret_conv = MALLOC(sizeof(LDKCResult_CVec_SignatureZNoneZ), "LDKCResult_CVec_SignatureZNoneZ"); *ret_conv = CResult_CVec_SignatureZNoneZ_clone(orig_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_ShutdownScriptDecodeErrorZ_ok(uint32_t o) { LDKShutdownScript o_conv; o_conv.inner = (void*)(o & (~1)); o_conv.is_owned = (o & 1) || (o == 0); o_conv = ShutdownScript_clone(&o_conv); LDKCResult_ShutdownScriptDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_ShutdownScriptDecodeErrorZ), "LDKCResult_ShutdownScriptDecodeErrorZ"); *ret_conv = CResult_ShutdownScriptDecodeErrorZ_ok(o_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_ShutdownScriptDecodeErrorZ_err(uint32_t e) { LDKDecodeError e_conv; e_conv.inner = (void*)(e & (~1)); e_conv.is_owned = (e & 1) || (e == 0); e_conv = DecodeError_clone(&e_conv); LDKCResult_ShutdownScriptDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_ShutdownScriptDecodeErrorZ), "LDKCResult_ShutdownScriptDecodeErrorZ"); *ret_conv = CResult_ShutdownScriptDecodeErrorZ_err(e_conv); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CResult_ShutdownScriptDecodeErrorZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCResult_ShutdownScriptDecodeErrorZ _res_conv = *(LDKCResult_ShutdownScriptDecodeErrorZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); CResult_ShutdownScriptDecodeErrorZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_CResult_ShutdownScriptDecodeErrorZ_clone(uint32_t orig) { LDKCResult_ShutdownScriptDecodeErrorZ* orig_conv = (LDKCResult_ShutdownScriptDecodeErrorZ*)(orig & ~1); LDKCResult_ShutdownScriptDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_ShutdownScriptDecodeErrorZ), "LDKCResult_ShutdownScriptDecodeErrorZ"); *ret_conv = CResult_ShutdownScriptDecodeErrorZ_clone(orig_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_ShutdownScriptInvalidShutdownScriptZ_ok(uint32_t o) { LDKShutdownScript o_conv; o_conv.inner = (void*)(o & (~1)); o_conv.is_owned = (o & 1) || (o == 0); o_conv = ShutdownScript_clone(&o_conv); LDKCResult_ShutdownScriptInvalidShutdownScriptZ* ret_conv = MALLOC(sizeof(LDKCResult_ShutdownScriptInvalidShutdownScriptZ), "LDKCResult_ShutdownScriptInvalidShutdownScriptZ"); *ret_conv = CResult_ShutdownScriptInvalidShutdownScriptZ_ok(o_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_ShutdownScriptInvalidShutdownScriptZ_err(uint32_t e) { LDKInvalidShutdownScript e_conv; e_conv.inner = (void*)(e & (~1)); e_conv.is_owned = (e & 1) || (e == 0); // Warning: we need a move here but no clone is available for LDKInvalidShutdownScript LDKCResult_ShutdownScriptInvalidShutdownScriptZ* ret_conv = MALLOC(sizeof(LDKCResult_ShutdownScriptInvalidShutdownScriptZ), "LDKCResult_ShutdownScriptInvalidShutdownScriptZ"); *ret_conv = CResult_ShutdownScriptInvalidShutdownScriptZ_err(e_conv); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CResult_ShutdownScriptInvalidShutdownScriptZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCResult_ShutdownScriptInvalidShutdownScriptZ _res_conv = *(LDKCResult_ShutdownScriptInvalidShutdownScriptZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); CResult_ShutdownScriptInvalidShutdownScriptZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_CResult_NoneErrorZ_ok() { LDKCResult_NoneErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_NoneErrorZ), "LDKCResult_NoneErrorZ"); *ret_conv = CResult_NoneErrorZ_ok(); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_NoneErrorZ_err(uint32_t e) { LDKIOError e_conv = LDKIOError_from_js(e); LDKCResult_NoneErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_NoneErrorZ), "LDKCResult_NoneErrorZ"); *ret_conv = CResult_NoneErrorZ_err(e_conv); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CResult_NoneErrorZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCResult_NoneErrorZ _res_conv = *(LDKCResult_NoneErrorZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); CResult_NoneErrorZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_CResult_NoneErrorZ_clone(uint32_t orig) { LDKCResult_NoneErrorZ* orig_conv = (LDKCResult_NoneErrorZ*)(orig & ~1); LDKCResult_NoneErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_NoneErrorZ), "LDKCResult_NoneErrorZ"); *ret_conv = CResult_NoneErrorZ_clone(orig_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_RouteHopDecodeErrorZ_ok(uint32_t o) { LDKRouteHop o_conv; o_conv.inner = (void*)(o & (~1)); o_conv.is_owned = (o & 1) || (o == 0); o_conv = RouteHop_clone(&o_conv); LDKCResult_RouteHopDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_RouteHopDecodeErrorZ), "LDKCResult_RouteHopDecodeErrorZ"); *ret_conv = CResult_RouteHopDecodeErrorZ_ok(o_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_RouteHopDecodeErrorZ_err(uint32_t e) { LDKDecodeError e_conv; e_conv.inner = (void*)(e & (~1)); e_conv.is_owned = (e & 1) || (e == 0); e_conv = DecodeError_clone(&e_conv); LDKCResult_RouteHopDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_RouteHopDecodeErrorZ), "LDKCResult_RouteHopDecodeErrorZ"); *ret_conv = CResult_RouteHopDecodeErrorZ_err(e_conv); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CResult_RouteHopDecodeErrorZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCResult_RouteHopDecodeErrorZ _res_conv = *(LDKCResult_RouteHopDecodeErrorZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); CResult_RouteHopDecodeErrorZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_CResult_RouteHopDecodeErrorZ_clone(uint32_t orig) { LDKCResult_RouteHopDecodeErrorZ* orig_conv = (LDKCResult_RouteHopDecodeErrorZ*)(orig & ~1); LDKCResult_RouteHopDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_RouteHopDecodeErrorZ), "LDKCResult_RouteHopDecodeErrorZ"); *ret_conv = CResult_RouteHopDecodeErrorZ_clone(orig_conv); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CVec_RouteHopZ_free(uint32_tArray _res) { LDKCVec_RouteHopZ _res_constr; _res_constr.datalen = *((uint32_t*)_res); if (_res_constr.datalen > 0) _res_constr.data = MALLOC(_res_constr.datalen * sizeof(LDKRouteHop), "LDKCVec_RouteHopZ Elements"); else _res_constr.data = NULL; uint32_t* _res_vals = (uint32_t*)(_res + 4); for (size_t k = 0; k < _res_constr.datalen; k++) { uint32_t _res_conv_10 = _res_vals[k]; LDKRouteHop _res_conv_10_conv; _res_conv_10_conv.inner = (void*)(_res_conv_10 & (~1)); _res_conv_10_conv.is_owned = (_res_conv_10 & 1) || (_res_conv_10 == 0); _res_constr.data[k] = _res_conv_10_conv; } CVec_RouteHopZ_free(_res_constr); } void __attribute__((visibility("default"))) TS_CVec_CVec_RouteHopZZ_free(ptrArray _res) { LDKCVec_CVec_RouteHopZZ _res_constr; _res_constr.datalen = *((uint32_t*)_res); if (_res_constr.datalen > 0) _res_constr.data = MALLOC(_res_constr.datalen * sizeof(LDKCVec_RouteHopZ), "LDKCVec_CVec_RouteHopZZ Elements"); else _res_constr.data = NULL; uint32_tArray* _res_vals = (uint32_tArray*)(_res + 4); for (size_t m = 0; m < _res_constr.datalen; m++) { uint32_tArray _res_conv_12 = _res_vals[m]; LDKCVec_RouteHopZ _res_conv_12_constr; _res_conv_12_constr.datalen = *((uint32_t*)_res_conv_12); if (_res_conv_12_constr.datalen > 0) _res_conv_12_constr.data = MALLOC(_res_conv_12_constr.datalen * sizeof(LDKRouteHop), "LDKCVec_RouteHopZ Elements"); else _res_conv_12_constr.data = NULL; uint32_t* _res_conv_12_vals = (uint32_t*)(_res_conv_12 + 4); for (size_t k = 0; k < _res_conv_12_constr.datalen; k++) { uint32_t _res_conv_12_conv_10 = _res_conv_12_vals[k]; LDKRouteHop _res_conv_12_conv_10_conv; _res_conv_12_conv_10_conv.inner = (void*)(_res_conv_12_conv_10 & (~1)); _res_conv_12_conv_10_conv.is_owned = (_res_conv_12_conv_10 & 1) || (_res_conv_12_conv_10 == 0); _res_conv_12_constr.data[k] = _res_conv_12_conv_10_conv; } _res_constr.data[m] = _res_conv_12_constr; } CVec_CVec_RouteHopZZ_free(_res_constr); } uint32_t __attribute__((visibility("default"))) TS_CResult_RouteDecodeErrorZ_ok(uint32_t o) { LDKRoute o_conv; o_conv.inner = (void*)(o & (~1)); o_conv.is_owned = (o & 1) || (o == 0); o_conv = Route_clone(&o_conv); LDKCResult_RouteDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_RouteDecodeErrorZ), "LDKCResult_RouteDecodeErrorZ"); *ret_conv = CResult_RouteDecodeErrorZ_ok(o_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_RouteDecodeErrorZ_err(uint32_t e) { LDKDecodeError e_conv; e_conv.inner = (void*)(e & (~1)); e_conv.is_owned = (e & 1) || (e == 0); e_conv = DecodeError_clone(&e_conv); LDKCResult_RouteDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_RouteDecodeErrorZ), "LDKCResult_RouteDecodeErrorZ"); *ret_conv = CResult_RouteDecodeErrorZ_err(e_conv); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CResult_RouteDecodeErrorZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCResult_RouteDecodeErrorZ _res_conv = *(LDKCResult_RouteDecodeErrorZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); CResult_RouteDecodeErrorZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_CResult_RouteDecodeErrorZ_clone(uint32_t orig) { LDKCResult_RouteDecodeErrorZ* orig_conv = (LDKCResult_RouteDecodeErrorZ*)(orig & ~1); LDKCResult_RouteDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_RouteDecodeErrorZ), "LDKCResult_RouteDecodeErrorZ"); *ret_conv = CResult_RouteDecodeErrorZ_clone(orig_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_COption_u64Z_some(int64_t o) { LDKCOption_u64Z *ret_copy = MALLOC(sizeof(LDKCOption_u64Z), "LDKCOption_u64Z"); *ret_copy = COption_u64Z_some(o); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_COption_u64Z_none() { LDKCOption_u64Z *ret_copy = MALLOC(sizeof(LDKCOption_u64Z), "LDKCOption_u64Z"); *ret_copy = COption_u64Z_none(); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } void __attribute__((visibility("default"))) TS_COption_u64Z_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCOption_u64Z _res_conv = *(LDKCOption_u64Z*)(((uint64_t)_res) & ~1); FREE((void*)_res); COption_u64Z_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_COption_u64Z_clone(uint32_t orig) { LDKCOption_u64Z* orig_conv = (LDKCOption_u64Z*)orig; LDKCOption_u64Z *ret_copy = MALLOC(sizeof(LDKCOption_u64Z), "LDKCOption_u64Z"); *ret_copy = COption_u64Z_clone(orig_conv); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } void __attribute__((visibility("default"))) TS_CVec_ChannelDetailsZ_free(uint32_tArray _res) { LDKCVec_ChannelDetailsZ _res_constr; _res_constr.datalen = *((uint32_t*)_res); if (_res_constr.datalen > 0) _res_constr.data = MALLOC(_res_constr.datalen * sizeof(LDKChannelDetails), "LDKCVec_ChannelDetailsZ Elements"); else _res_constr.data = NULL; uint32_t* _res_vals = (uint32_t*)(_res + 4); for (size_t q = 0; q < _res_constr.datalen; q++) { uint32_t _res_conv_16 = _res_vals[q]; LDKChannelDetails _res_conv_16_conv; _res_conv_16_conv.inner = (void*)(_res_conv_16 & (~1)); _res_conv_16_conv.is_owned = (_res_conv_16 & 1) || (_res_conv_16 == 0); _res_constr.data[q] = _res_conv_16_conv; } CVec_ChannelDetailsZ_free(_res_constr); } void __attribute__((visibility("default"))) TS_CVec_RouteHintZ_free(uint32_tArray _res) { LDKCVec_RouteHintZ _res_constr; _res_constr.datalen = *((uint32_t*)_res); if (_res_constr.datalen > 0) _res_constr.data = MALLOC(_res_constr.datalen * sizeof(LDKRouteHint), "LDKCVec_RouteHintZ Elements"); else _res_constr.data = NULL; uint32_t* _res_vals = (uint32_t*)(_res + 4); for (size_t l = 0; l < _res_constr.datalen; l++) { uint32_t _res_conv_11 = _res_vals[l]; LDKRouteHint _res_conv_11_conv; _res_conv_11_conv.inner = (void*)(_res_conv_11 & (~1)); _res_conv_11_conv.is_owned = (_res_conv_11 & 1) || (_res_conv_11 == 0); _res_constr.data[l] = _res_conv_11_conv; } CVec_RouteHintZ_free(_res_constr); } uint32_t __attribute__((visibility("default"))) TS_CResult_RouteLightningErrorZ_ok(uint32_t o) { LDKRoute o_conv; o_conv.inner = (void*)(o & (~1)); o_conv.is_owned = (o & 1) || (o == 0); o_conv = Route_clone(&o_conv); LDKCResult_RouteLightningErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_RouteLightningErrorZ), "LDKCResult_RouteLightningErrorZ"); *ret_conv = CResult_RouteLightningErrorZ_ok(o_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_RouteLightningErrorZ_err(uint32_t e) { LDKLightningError e_conv; e_conv.inner = (void*)(e & (~1)); e_conv.is_owned = (e & 1) || (e == 0); e_conv = LightningError_clone(&e_conv); LDKCResult_RouteLightningErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_RouteLightningErrorZ), "LDKCResult_RouteLightningErrorZ"); *ret_conv = CResult_RouteLightningErrorZ_err(e_conv); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CResult_RouteLightningErrorZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCResult_RouteLightningErrorZ _res_conv = *(LDKCResult_RouteLightningErrorZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); CResult_RouteLightningErrorZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_CResult_RouteLightningErrorZ_clone(uint32_t orig) { LDKCResult_RouteLightningErrorZ* orig_conv = (LDKCResult_RouteLightningErrorZ*)(orig & ~1); LDKCResult_RouteLightningErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_RouteLightningErrorZ), "LDKCResult_RouteLightningErrorZ"); *ret_conv = CResult_RouteLightningErrorZ_clone(orig_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_TxOutAccessErrorZ_ok(uint32_t o) { LDKTxOut o_conv = *(LDKTxOut*)(((uint64_t)o) & ~1); o_conv = TxOut_clone((LDKTxOut*)(((uint64_t)o) & ~1)); LDKCResult_TxOutAccessErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_TxOutAccessErrorZ), "LDKCResult_TxOutAccessErrorZ"); *ret_conv = CResult_TxOutAccessErrorZ_ok(o_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_TxOutAccessErrorZ_err(uint32_t e) { LDKAccessError e_conv = LDKAccessError_from_js(e); LDKCResult_TxOutAccessErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_TxOutAccessErrorZ), "LDKCResult_TxOutAccessErrorZ"); *ret_conv = CResult_TxOutAccessErrorZ_err(e_conv); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CResult_TxOutAccessErrorZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCResult_TxOutAccessErrorZ _res_conv = *(LDKCResult_TxOutAccessErrorZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); CResult_TxOutAccessErrorZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_CResult_TxOutAccessErrorZ_clone(uint32_t orig) { LDKCResult_TxOutAccessErrorZ* orig_conv = (LDKCResult_TxOutAccessErrorZ*)(orig & ~1); LDKCResult_TxOutAccessErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_TxOutAccessErrorZ), "LDKCResult_TxOutAccessErrorZ"); *ret_conv = CResult_TxOutAccessErrorZ_clone(orig_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_C2Tuple_usizeTransactionZ_clone(uint32_t orig) { LDKC2Tuple_usizeTransactionZ* orig_conv = (LDKC2Tuple_usizeTransactionZ*)(orig & ~1); LDKC2Tuple_usizeTransactionZ* ret_ref = MALLOC(sizeof(LDKC2Tuple_usizeTransactionZ), "LDKC2Tuple_usizeTransactionZ"); *ret_ref = C2Tuple_usizeTransactionZ_clone(orig_conv); return (uint64_t)ret_ref; } uint32_t __attribute__((visibility("default"))) TS_C2Tuple_usizeTransactionZ_new(int64_t a, int8_tArray b) { LDKTransaction b_ref; b_ref.datalen = *((uint32_t*)b); b_ref.data = MALLOC(b_ref.datalen, "LDKTransaction Bytes"); memcpy(b_ref.data, (uint8_t*)(b + 4), b_ref.datalen); b_ref.data_is_owned = true; LDKC2Tuple_usizeTransactionZ* ret_ref = MALLOC(sizeof(LDKC2Tuple_usizeTransactionZ), "LDKC2Tuple_usizeTransactionZ"); *ret_ref = C2Tuple_usizeTransactionZ_new(a, b_ref); return (uint64_t)ret_ref; } void __attribute__((visibility("default"))) TS_C2Tuple_usizeTransactionZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKC2Tuple_usizeTransactionZ _res_conv = *(LDKC2Tuple_usizeTransactionZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); C2Tuple_usizeTransactionZ_free(_res_conv); } void __attribute__((visibility("default"))) TS_CVec_C2Tuple_usizeTransactionZZ_free(uint32_tArray _res) { LDKCVec_C2Tuple_usizeTransactionZZ _res_constr; _res_constr.datalen = *((uint32_t*)_res); if (_res_constr.datalen > 0) _res_constr.data = MALLOC(_res_constr.datalen * sizeof(LDKC2Tuple_usizeTransactionZ), "LDKCVec_C2Tuple_usizeTransactionZZ Elements"); else _res_constr.data = NULL; uint32_t* _res_vals = (uint32_t*)(_res + 4); for (size_t e = 0; e < _res_constr.datalen; e++) { uint32_t _res_conv_30 = _res_vals[e]; LDKC2Tuple_usizeTransactionZ _res_conv_30_conv = *(LDKC2Tuple_usizeTransactionZ*)(((uint64_t)_res_conv_30) & ~1); FREE((void*)_res_conv_30); _res_constr.data[e] = _res_conv_30_conv; } CVec_C2Tuple_usizeTransactionZZ_free(_res_constr); } void __attribute__((visibility("default"))) TS_CVec_TxidZ_free(ptrArray _res) { LDKCVec_TxidZ _res_constr; _res_constr.datalen = *((uint32_t*)_res); if (_res_constr.datalen > 0) _res_constr.data = MALLOC(_res_constr.datalen * sizeof(LDKThirtyTwoBytes), "LDKCVec_TxidZ Elements"); else _res_constr.data = NULL; int8_tArray* _res_vals = (int8_tArray*)(_res + 4); for (size_t m = 0; m < _res_constr.datalen; m++) { int8_tArray _res_conv_12 = _res_vals[m]; LDKThirtyTwoBytes _res_conv_12_ref; CHECK(*((uint32_t*)_res_conv_12) == 32); memcpy(_res_conv_12_ref.data, (uint8_t*)(_res_conv_12 + 4), 32); _res_constr.data[m] = _res_conv_12_ref; } CVec_TxidZ_free(_res_constr); } uint32_t __attribute__((visibility("default"))) TS_CResult_NoneChannelMonitorUpdateErrZ_ok() { LDKCResult_NoneChannelMonitorUpdateErrZ* ret_conv = MALLOC(sizeof(LDKCResult_NoneChannelMonitorUpdateErrZ), "LDKCResult_NoneChannelMonitorUpdateErrZ"); *ret_conv = CResult_NoneChannelMonitorUpdateErrZ_ok(); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_NoneChannelMonitorUpdateErrZ_err(uint32_t e) { LDKChannelMonitorUpdateErr e_conv = LDKChannelMonitorUpdateErr_from_js(e); LDKCResult_NoneChannelMonitorUpdateErrZ* ret_conv = MALLOC(sizeof(LDKCResult_NoneChannelMonitorUpdateErrZ), "LDKCResult_NoneChannelMonitorUpdateErrZ"); *ret_conv = CResult_NoneChannelMonitorUpdateErrZ_err(e_conv); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CResult_NoneChannelMonitorUpdateErrZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCResult_NoneChannelMonitorUpdateErrZ _res_conv = *(LDKCResult_NoneChannelMonitorUpdateErrZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); CResult_NoneChannelMonitorUpdateErrZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_CResult_NoneChannelMonitorUpdateErrZ_clone(uint32_t orig) { LDKCResult_NoneChannelMonitorUpdateErrZ* orig_conv = (LDKCResult_NoneChannelMonitorUpdateErrZ*)(orig & ~1); LDKCResult_NoneChannelMonitorUpdateErrZ* ret_conv = MALLOC(sizeof(LDKCResult_NoneChannelMonitorUpdateErrZ), "LDKCResult_NoneChannelMonitorUpdateErrZ"); *ret_conv = CResult_NoneChannelMonitorUpdateErrZ_clone(orig_conv); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CVec_MonitorEventZ_free(uint32_tArray _res) { LDKCVec_MonitorEventZ _res_constr; _res_constr.datalen = *((uint32_t*)_res); if (_res_constr.datalen > 0) _res_constr.data = MALLOC(_res_constr.datalen * sizeof(LDKMonitorEvent), "LDKCVec_MonitorEventZ Elements"); else _res_constr.data = NULL; uint32_t* _res_vals = (uint32_t*)(_res + 4); for (size_t o = 0; o < _res_constr.datalen; o++) { uint32_t _res_conv_14 = _res_vals[o]; LDKMonitorEvent _res_conv_14_conv = *(LDKMonitorEvent*)(((uint64_t)_res_conv_14) & ~1); FREE((void*)_res_conv_14); _res_constr.data[o] = _res_conv_14_conv; } CVec_MonitorEventZ_free(_res_constr); } uint32_t __attribute__((visibility("default"))) TS_COption_C2Tuple_usizeTransactionZZ_some(uint32_t o) { LDKC2Tuple_usizeTransactionZ o_conv = *(LDKC2Tuple_usizeTransactionZ*)(((uint64_t)o) & ~1); o_conv = C2Tuple_usizeTransactionZ_clone((LDKC2Tuple_usizeTransactionZ*)(((uint64_t)o) & ~1)); LDKCOption_C2Tuple_usizeTransactionZZ *ret_copy = MALLOC(sizeof(LDKCOption_C2Tuple_usizeTransactionZZ), "LDKCOption_C2Tuple_usizeTransactionZZ"); *ret_copy = COption_C2Tuple_usizeTransactionZZ_some(o_conv); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_COption_C2Tuple_usizeTransactionZZ_none() { LDKCOption_C2Tuple_usizeTransactionZZ *ret_copy = MALLOC(sizeof(LDKCOption_C2Tuple_usizeTransactionZZ), "LDKCOption_C2Tuple_usizeTransactionZZ"); *ret_copy = COption_C2Tuple_usizeTransactionZZ_none(); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } void __attribute__((visibility("default"))) TS_COption_C2Tuple_usizeTransactionZZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCOption_C2Tuple_usizeTransactionZZ _res_conv = *(LDKCOption_C2Tuple_usizeTransactionZZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); COption_C2Tuple_usizeTransactionZZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_COption_C2Tuple_usizeTransactionZZ_clone(uint32_t orig) { LDKCOption_C2Tuple_usizeTransactionZZ* orig_conv = (LDKCOption_C2Tuple_usizeTransactionZZ*)orig; LDKCOption_C2Tuple_usizeTransactionZZ *ret_copy = MALLOC(sizeof(LDKCOption_C2Tuple_usizeTransactionZZ), "LDKCOption_C2Tuple_usizeTransactionZZ"); *ret_copy = COption_C2Tuple_usizeTransactionZZ_clone(orig_conv); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_COption_NetworkUpdateZ_some(uint32_t o) { LDKNetworkUpdate o_conv = *(LDKNetworkUpdate*)(((uint64_t)o) & ~1); o_conv = NetworkUpdate_clone((LDKNetworkUpdate*)(((uint64_t)o) & ~1)); LDKCOption_NetworkUpdateZ *ret_copy = MALLOC(sizeof(LDKCOption_NetworkUpdateZ), "LDKCOption_NetworkUpdateZ"); *ret_copy = COption_NetworkUpdateZ_some(o_conv); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_COption_NetworkUpdateZ_none() { LDKCOption_NetworkUpdateZ *ret_copy = MALLOC(sizeof(LDKCOption_NetworkUpdateZ), "LDKCOption_NetworkUpdateZ"); *ret_copy = COption_NetworkUpdateZ_none(); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } void __attribute__((visibility("default"))) TS_COption_NetworkUpdateZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCOption_NetworkUpdateZ _res_conv = *(LDKCOption_NetworkUpdateZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); COption_NetworkUpdateZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_COption_NetworkUpdateZ_clone(uint32_t orig) { LDKCOption_NetworkUpdateZ* orig_conv = (LDKCOption_NetworkUpdateZ*)orig; LDKCOption_NetworkUpdateZ *ret_copy = MALLOC(sizeof(LDKCOption_NetworkUpdateZ), "LDKCOption_NetworkUpdateZ"); *ret_copy = COption_NetworkUpdateZ_clone(orig_conv); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } void __attribute__((visibility("default"))) TS_CVec_SpendableOutputDescriptorZ_free(uint32_tArray _res) { LDKCVec_SpendableOutputDescriptorZ _res_constr; _res_constr.datalen = *((uint32_t*)_res); if (_res_constr.datalen > 0) _res_constr.data = MALLOC(_res_constr.datalen * sizeof(LDKSpendableOutputDescriptor), "LDKCVec_SpendableOutputDescriptorZ Elements"); else _res_constr.data = NULL; uint32_t* _res_vals = (uint32_t*)(_res + 4); for (size_t b = 0; b < _res_constr.datalen; b++) { uint32_t _res_conv_27 = _res_vals[b]; LDKSpendableOutputDescriptor _res_conv_27_conv = *(LDKSpendableOutputDescriptor*)(((uint64_t)_res_conv_27) & ~1); FREE((void*)_res_conv_27); _res_constr.data[b] = _res_conv_27_conv; } CVec_SpendableOutputDescriptorZ_free(_res_constr); } void __attribute__((visibility("default"))) TS_CVec_MessageSendEventZ_free(uint32_tArray _res) { LDKCVec_MessageSendEventZ _res_constr; _res_constr.datalen = *((uint32_t*)_res); if (_res_constr.datalen > 0) _res_constr.data = MALLOC(_res_constr.datalen * sizeof(LDKMessageSendEvent), "LDKCVec_MessageSendEventZ Elements"); else _res_constr.data = NULL; uint32_t* _res_vals = (uint32_t*)(_res + 4); for (size_t s = 0; s < _res_constr.datalen; s++) { uint32_t _res_conv_18 = _res_vals[s]; LDKMessageSendEvent _res_conv_18_conv = *(LDKMessageSendEvent*)(((uint64_t)_res_conv_18) & ~1); FREE((void*)_res_conv_18); _res_constr.data[s] = _res_conv_18_conv; } CVec_MessageSendEventZ_free(_res_constr); } uint32_t __attribute__((visibility("default"))) TS_CResult_InitFeaturesDecodeErrorZ_ok(uint32_t o) { LDKInitFeatures o_conv; o_conv.inner = (void*)(o & (~1)); o_conv.is_owned = (o & 1) || (o == 0); o_conv = InitFeatures_clone(&o_conv); LDKCResult_InitFeaturesDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_InitFeaturesDecodeErrorZ), "LDKCResult_InitFeaturesDecodeErrorZ"); *ret_conv = CResult_InitFeaturesDecodeErrorZ_ok(o_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_InitFeaturesDecodeErrorZ_err(uint32_t e) { LDKDecodeError e_conv; e_conv.inner = (void*)(e & (~1)); e_conv.is_owned = (e & 1) || (e == 0); e_conv = DecodeError_clone(&e_conv); LDKCResult_InitFeaturesDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_InitFeaturesDecodeErrorZ), "LDKCResult_InitFeaturesDecodeErrorZ"); *ret_conv = CResult_InitFeaturesDecodeErrorZ_err(e_conv); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CResult_InitFeaturesDecodeErrorZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCResult_InitFeaturesDecodeErrorZ _res_conv = *(LDKCResult_InitFeaturesDecodeErrorZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); CResult_InitFeaturesDecodeErrorZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_CResult_NodeFeaturesDecodeErrorZ_ok(uint32_t o) { LDKNodeFeatures o_conv; o_conv.inner = (void*)(o & (~1)); o_conv.is_owned = (o & 1) || (o == 0); o_conv = NodeFeatures_clone(&o_conv); LDKCResult_NodeFeaturesDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_NodeFeaturesDecodeErrorZ), "LDKCResult_NodeFeaturesDecodeErrorZ"); *ret_conv = CResult_NodeFeaturesDecodeErrorZ_ok(o_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_NodeFeaturesDecodeErrorZ_err(uint32_t e) { LDKDecodeError e_conv; e_conv.inner = (void*)(e & (~1)); e_conv.is_owned = (e & 1) || (e == 0); e_conv = DecodeError_clone(&e_conv); LDKCResult_NodeFeaturesDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_NodeFeaturesDecodeErrorZ), "LDKCResult_NodeFeaturesDecodeErrorZ"); *ret_conv = CResult_NodeFeaturesDecodeErrorZ_err(e_conv); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CResult_NodeFeaturesDecodeErrorZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCResult_NodeFeaturesDecodeErrorZ _res_conv = *(LDKCResult_NodeFeaturesDecodeErrorZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); CResult_NodeFeaturesDecodeErrorZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_CResult_ChannelFeaturesDecodeErrorZ_ok(uint32_t o) { LDKChannelFeatures o_conv; o_conv.inner = (void*)(o & (~1)); o_conv.is_owned = (o & 1) || (o == 0); o_conv = ChannelFeatures_clone(&o_conv); LDKCResult_ChannelFeaturesDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_ChannelFeaturesDecodeErrorZ), "LDKCResult_ChannelFeaturesDecodeErrorZ"); *ret_conv = CResult_ChannelFeaturesDecodeErrorZ_ok(o_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_ChannelFeaturesDecodeErrorZ_err(uint32_t e) { LDKDecodeError e_conv; e_conv.inner = (void*)(e & (~1)); e_conv.is_owned = (e & 1) || (e == 0); e_conv = DecodeError_clone(&e_conv); LDKCResult_ChannelFeaturesDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_ChannelFeaturesDecodeErrorZ), "LDKCResult_ChannelFeaturesDecodeErrorZ"); *ret_conv = CResult_ChannelFeaturesDecodeErrorZ_err(e_conv); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CResult_ChannelFeaturesDecodeErrorZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCResult_ChannelFeaturesDecodeErrorZ _res_conv = *(LDKCResult_ChannelFeaturesDecodeErrorZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); CResult_ChannelFeaturesDecodeErrorZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_CResult_InvoiceFeaturesDecodeErrorZ_ok(uint32_t o) { LDKInvoiceFeatures o_conv; o_conv.inner = (void*)(o & (~1)); o_conv.is_owned = (o & 1) || (o == 0); o_conv = InvoiceFeatures_clone(&o_conv); LDKCResult_InvoiceFeaturesDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_InvoiceFeaturesDecodeErrorZ), "LDKCResult_InvoiceFeaturesDecodeErrorZ"); *ret_conv = CResult_InvoiceFeaturesDecodeErrorZ_ok(o_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_InvoiceFeaturesDecodeErrorZ_err(uint32_t e) { LDKDecodeError e_conv; e_conv.inner = (void*)(e & (~1)); e_conv.is_owned = (e & 1) || (e == 0); e_conv = DecodeError_clone(&e_conv); LDKCResult_InvoiceFeaturesDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_InvoiceFeaturesDecodeErrorZ), "LDKCResult_InvoiceFeaturesDecodeErrorZ"); *ret_conv = CResult_InvoiceFeaturesDecodeErrorZ_err(e_conv); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CResult_InvoiceFeaturesDecodeErrorZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCResult_InvoiceFeaturesDecodeErrorZ _res_conv = *(LDKCResult_InvoiceFeaturesDecodeErrorZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); CResult_InvoiceFeaturesDecodeErrorZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_CResult_DelayedPaymentOutputDescriptorDecodeErrorZ_ok(uint32_t o) { LDKDelayedPaymentOutputDescriptor o_conv; o_conv.inner = (void*)(o & (~1)); o_conv.is_owned = (o & 1) || (o == 0); o_conv = DelayedPaymentOutputDescriptor_clone(&o_conv); LDKCResult_DelayedPaymentOutputDescriptorDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_DelayedPaymentOutputDescriptorDecodeErrorZ), "LDKCResult_DelayedPaymentOutputDescriptorDecodeErrorZ"); *ret_conv = CResult_DelayedPaymentOutputDescriptorDecodeErrorZ_ok(o_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_DelayedPaymentOutputDescriptorDecodeErrorZ_err(uint32_t e) { LDKDecodeError e_conv; e_conv.inner = (void*)(e & (~1)); e_conv.is_owned = (e & 1) || (e == 0); e_conv = DecodeError_clone(&e_conv); LDKCResult_DelayedPaymentOutputDescriptorDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_DelayedPaymentOutputDescriptorDecodeErrorZ), "LDKCResult_DelayedPaymentOutputDescriptorDecodeErrorZ"); *ret_conv = CResult_DelayedPaymentOutputDescriptorDecodeErrorZ_err(e_conv); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CResult_DelayedPaymentOutputDescriptorDecodeErrorZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCResult_DelayedPaymentOutputDescriptorDecodeErrorZ _res_conv = *(LDKCResult_DelayedPaymentOutputDescriptorDecodeErrorZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); CResult_DelayedPaymentOutputDescriptorDecodeErrorZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_CResult_DelayedPaymentOutputDescriptorDecodeErrorZ_clone(uint32_t orig) { LDKCResult_DelayedPaymentOutputDescriptorDecodeErrorZ* orig_conv = (LDKCResult_DelayedPaymentOutputDescriptorDecodeErrorZ*)(orig & ~1); LDKCResult_DelayedPaymentOutputDescriptorDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_DelayedPaymentOutputDescriptorDecodeErrorZ), "LDKCResult_DelayedPaymentOutputDescriptorDecodeErrorZ"); *ret_conv = CResult_DelayedPaymentOutputDescriptorDecodeErrorZ_clone(orig_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_StaticPaymentOutputDescriptorDecodeErrorZ_ok(uint32_t o) { LDKStaticPaymentOutputDescriptor o_conv; o_conv.inner = (void*)(o & (~1)); o_conv.is_owned = (o & 1) || (o == 0); o_conv = StaticPaymentOutputDescriptor_clone(&o_conv); LDKCResult_StaticPaymentOutputDescriptorDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_StaticPaymentOutputDescriptorDecodeErrorZ), "LDKCResult_StaticPaymentOutputDescriptorDecodeErrorZ"); *ret_conv = CResult_StaticPaymentOutputDescriptorDecodeErrorZ_ok(o_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_StaticPaymentOutputDescriptorDecodeErrorZ_err(uint32_t e) { LDKDecodeError e_conv; e_conv.inner = (void*)(e & (~1)); e_conv.is_owned = (e & 1) || (e == 0); e_conv = DecodeError_clone(&e_conv); LDKCResult_StaticPaymentOutputDescriptorDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_StaticPaymentOutputDescriptorDecodeErrorZ), "LDKCResult_StaticPaymentOutputDescriptorDecodeErrorZ"); *ret_conv = CResult_StaticPaymentOutputDescriptorDecodeErrorZ_err(e_conv); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CResult_StaticPaymentOutputDescriptorDecodeErrorZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCResult_StaticPaymentOutputDescriptorDecodeErrorZ _res_conv = *(LDKCResult_StaticPaymentOutputDescriptorDecodeErrorZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); CResult_StaticPaymentOutputDescriptorDecodeErrorZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_CResult_StaticPaymentOutputDescriptorDecodeErrorZ_clone(uint32_t orig) { LDKCResult_StaticPaymentOutputDescriptorDecodeErrorZ* orig_conv = (LDKCResult_StaticPaymentOutputDescriptorDecodeErrorZ*)(orig & ~1); LDKCResult_StaticPaymentOutputDescriptorDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_StaticPaymentOutputDescriptorDecodeErrorZ), "LDKCResult_StaticPaymentOutputDescriptorDecodeErrorZ"); *ret_conv = CResult_StaticPaymentOutputDescriptorDecodeErrorZ_clone(orig_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_SpendableOutputDescriptorDecodeErrorZ_ok(uint32_t o) { LDKSpendableOutputDescriptor o_conv = *(LDKSpendableOutputDescriptor*)(((uint64_t)o) & ~1); o_conv = SpendableOutputDescriptor_clone((LDKSpendableOutputDescriptor*)(((uint64_t)o) & ~1)); LDKCResult_SpendableOutputDescriptorDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_SpendableOutputDescriptorDecodeErrorZ), "LDKCResult_SpendableOutputDescriptorDecodeErrorZ"); *ret_conv = CResult_SpendableOutputDescriptorDecodeErrorZ_ok(o_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_SpendableOutputDescriptorDecodeErrorZ_err(uint32_t e) { LDKDecodeError e_conv; e_conv.inner = (void*)(e & (~1)); e_conv.is_owned = (e & 1) || (e == 0); e_conv = DecodeError_clone(&e_conv); LDKCResult_SpendableOutputDescriptorDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_SpendableOutputDescriptorDecodeErrorZ), "LDKCResult_SpendableOutputDescriptorDecodeErrorZ"); *ret_conv = CResult_SpendableOutputDescriptorDecodeErrorZ_err(e_conv); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CResult_SpendableOutputDescriptorDecodeErrorZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCResult_SpendableOutputDescriptorDecodeErrorZ _res_conv = *(LDKCResult_SpendableOutputDescriptorDecodeErrorZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); CResult_SpendableOutputDescriptorDecodeErrorZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_CResult_SpendableOutputDescriptorDecodeErrorZ_clone(uint32_t orig) { LDKCResult_SpendableOutputDescriptorDecodeErrorZ* orig_conv = (LDKCResult_SpendableOutputDescriptorDecodeErrorZ*)(orig & ~1); LDKCResult_SpendableOutputDescriptorDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_SpendableOutputDescriptorDecodeErrorZ), "LDKCResult_SpendableOutputDescriptorDecodeErrorZ"); *ret_conv = CResult_SpendableOutputDescriptorDecodeErrorZ_clone(orig_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_NoneNoneZ_ok() { LDKCResult_NoneNoneZ* ret_conv = MALLOC(sizeof(LDKCResult_NoneNoneZ), "LDKCResult_NoneNoneZ"); *ret_conv = CResult_NoneNoneZ_ok(); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_NoneNoneZ_err() { LDKCResult_NoneNoneZ* ret_conv = MALLOC(sizeof(LDKCResult_NoneNoneZ), "LDKCResult_NoneNoneZ"); *ret_conv = CResult_NoneNoneZ_err(); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CResult_NoneNoneZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCResult_NoneNoneZ _res_conv = *(LDKCResult_NoneNoneZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); CResult_NoneNoneZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_CResult_NoneNoneZ_clone(uint32_t orig) { LDKCResult_NoneNoneZ* orig_conv = (LDKCResult_NoneNoneZ*)(orig & ~1); LDKCResult_NoneNoneZ* ret_conv = MALLOC(sizeof(LDKCResult_NoneNoneZ), "LDKCResult_NoneNoneZ"); *ret_conv = CResult_NoneNoneZ_clone(orig_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_C2Tuple_SignatureCVec_SignatureZZ_clone(uint32_t orig) { LDKC2Tuple_SignatureCVec_SignatureZZ* orig_conv = (LDKC2Tuple_SignatureCVec_SignatureZZ*)(orig & ~1); LDKC2Tuple_SignatureCVec_SignatureZZ* ret_ref = MALLOC(sizeof(LDKC2Tuple_SignatureCVec_SignatureZZ), "LDKC2Tuple_SignatureCVec_SignatureZZ"); *ret_ref = C2Tuple_SignatureCVec_SignatureZZ_clone(orig_conv); return (uint64_t)ret_ref; } uint32_t __attribute__((visibility("default"))) TS_C2Tuple_SignatureCVec_SignatureZZ_new(int8_tArray a, ptrArray b) { LDKSignature a_ref; CHECK(*((uint32_t*)a) == 64); memcpy(a_ref.compact_form, (uint8_t*)(a + 4), 64); LDKCVec_SignatureZ b_constr; b_constr.datalen = *((uint32_t*)b); if (b_constr.datalen > 0) b_constr.data = MALLOC(b_constr.datalen * sizeof(LDKSignature), "LDKCVec_SignatureZ Elements"); else b_constr.data = NULL; int8_tArray* b_vals = (int8_tArray*)(b + 4); for (size_t m = 0; m < b_constr.datalen; m++) { int8_tArray b_conv_12 = b_vals[m]; LDKSignature b_conv_12_ref; CHECK(*((uint32_t*)b_conv_12) == 64); memcpy(b_conv_12_ref.compact_form, (uint8_t*)(b_conv_12 + 4), 64); b_constr.data[m] = b_conv_12_ref; } LDKC2Tuple_SignatureCVec_SignatureZZ* ret_ref = MALLOC(sizeof(LDKC2Tuple_SignatureCVec_SignatureZZ), "LDKC2Tuple_SignatureCVec_SignatureZZ"); *ret_ref = C2Tuple_SignatureCVec_SignatureZZ_new(a_ref, b_constr); return (uint64_t)ret_ref; } void __attribute__((visibility("default"))) TS_C2Tuple_SignatureCVec_SignatureZZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKC2Tuple_SignatureCVec_SignatureZZ _res_conv = *(LDKC2Tuple_SignatureCVec_SignatureZZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); C2Tuple_SignatureCVec_SignatureZZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_CResult_C2Tuple_SignatureCVec_SignatureZZNoneZ_ok(uint32_t o) { LDKC2Tuple_SignatureCVec_SignatureZZ o_conv = *(LDKC2Tuple_SignatureCVec_SignatureZZ*)(((uint64_t)o) & ~1); o_conv = C2Tuple_SignatureCVec_SignatureZZ_clone((LDKC2Tuple_SignatureCVec_SignatureZZ*)(((uint64_t)o) & ~1)); LDKCResult_C2Tuple_SignatureCVec_SignatureZZNoneZ* ret_conv = MALLOC(sizeof(LDKCResult_C2Tuple_SignatureCVec_SignatureZZNoneZ), "LDKCResult_C2Tuple_SignatureCVec_SignatureZZNoneZ"); *ret_conv = CResult_C2Tuple_SignatureCVec_SignatureZZNoneZ_ok(o_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_C2Tuple_SignatureCVec_SignatureZZNoneZ_err() { LDKCResult_C2Tuple_SignatureCVec_SignatureZZNoneZ* ret_conv = MALLOC(sizeof(LDKCResult_C2Tuple_SignatureCVec_SignatureZZNoneZ), "LDKCResult_C2Tuple_SignatureCVec_SignatureZZNoneZ"); *ret_conv = CResult_C2Tuple_SignatureCVec_SignatureZZNoneZ_err(); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CResult_C2Tuple_SignatureCVec_SignatureZZNoneZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCResult_C2Tuple_SignatureCVec_SignatureZZNoneZ _res_conv = *(LDKCResult_C2Tuple_SignatureCVec_SignatureZZNoneZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); CResult_C2Tuple_SignatureCVec_SignatureZZNoneZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_CResult_C2Tuple_SignatureCVec_SignatureZZNoneZ_clone(uint32_t orig) { LDKCResult_C2Tuple_SignatureCVec_SignatureZZNoneZ* orig_conv = (LDKCResult_C2Tuple_SignatureCVec_SignatureZZNoneZ*)(orig & ~1); LDKCResult_C2Tuple_SignatureCVec_SignatureZZNoneZ* ret_conv = MALLOC(sizeof(LDKCResult_C2Tuple_SignatureCVec_SignatureZZNoneZ), "LDKCResult_C2Tuple_SignatureCVec_SignatureZZNoneZ"); *ret_conv = CResult_C2Tuple_SignatureCVec_SignatureZZNoneZ_clone(orig_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_SignatureNoneZ_ok(int8_tArray o) { LDKSignature o_ref; CHECK(*((uint32_t*)o) == 64); memcpy(o_ref.compact_form, (uint8_t*)(o + 4), 64); LDKCResult_SignatureNoneZ* ret_conv = MALLOC(sizeof(LDKCResult_SignatureNoneZ), "LDKCResult_SignatureNoneZ"); *ret_conv = CResult_SignatureNoneZ_ok(o_ref); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_SignatureNoneZ_err() { LDKCResult_SignatureNoneZ* ret_conv = MALLOC(sizeof(LDKCResult_SignatureNoneZ), "LDKCResult_SignatureNoneZ"); *ret_conv = CResult_SignatureNoneZ_err(); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CResult_SignatureNoneZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCResult_SignatureNoneZ _res_conv = *(LDKCResult_SignatureNoneZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); CResult_SignatureNoneZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_CResult_SignatureNoneZ_clone(uint32_t orig) { LDKCResult_SignatureNoneZ* orig_conv = (LDKCResult_SignatureNoneZ*)(orig & ~1); LDKCResult_SignatureNoneZ* ret_conv = MALLOC(sizeof(LDKCResult_SignatureNoneZ), "LDKCResult_SignatureNoneZ"); *ret_conv = CResult_SignatureNoneZ_clone(orig_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_SignDecodeErrorZ_ok(uint32_t o) { LDKSign o_conv = *(LDKSign*)(((uint64_t)o) & ~1); LDKCResult_SignDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_SignDecodeErrorZ), "LDKCResult_SignDecodeErrorZ"); *ret_conv = CResult_SignDecodeErrorZ_ok(o_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_SignDecodeErrorZ_err(uint32_t e) { LDKDecodeError e_conv; e_conv.inner = (void*)(e & (~1)); e_conv.is_owned = (e & 1) || (e == 0); e_conv = DecodeError_clone(&e_conv); LDKCResult_SignDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_SignDecodeErrorZ), "LDKCResult_SignDecodeErrorZ"); *ret_conv = CResult_SignDecodeErrorZ_err(e_conv); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CResult_SignDecodeErrorZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCResult_SignDecodeErrorZ _res_conv = *(LDKCResult_SignDecodeErrorZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); CResult_SignDecodeErrorZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_CResult_SignDecodeErrorZ_clone(uint32_t orig) { LDKCResult_SignDecodeErrorZ* orig_conv = (LDKCResult_SignDecodeErrorZ*)(orig & ~1); LDKCResult_SignDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_SignDecodeErrorZ), "LDKCResult_SignDecodeErrorZ"); *ret_conv = CResult_SignDecodeErrorZ_clone(orig_conv); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CVec_u8Z_free(int8_tArray _res) { LDKCVec_u8Z _res_ref; _res_ref.datalen = *((uint32_t*)_res); _res_ref.data = MALLOC(_res_ref.datalen, "LDKCVec_u8Z Bytes"); memcpy(_res_ref.data, (uint8_t*)(_res + 4), _res_ref.datalen); CVec_u8Z_free(_res_ref); } uint32_t __attribute__((visibility("default"))) TS_CResult_RecoverableSignatureNoneZ_ok(int8_tArray arg) { LDKRecoverableSignature arg_ref; CHECK(*((uint32_t*)arg) == 68); memcpy(arg_ref.serialized_form, (uint8_t*)(arg + 4), 68); LDKCResult_RecoverableSignatureNoneZ* ret_conv = MALLOC(sizeof(LDKCResult_RecoverableSignatureNoneZ), "LDKCResult_RecoverableSignatureNoneZ"); *ret_conv = CResult_RecoverableSignatureNoneZ_ok(arg_ref); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_RecoverableSignatureNoneZ_err() { LDKCResult_RecoverableSignatureNoneZ* ret_conv = MALLOC(sizeof(LDKCResult_RecoverableSignatureNoneZ), "LDKCResult_RecoverableSignatureNoneZ"); *ret_conv = CResult_RecoverableSignatureNoneZ_err(); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CResult_RecoverableSignatureNoneZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCResult_RecoverableSignatureNoneZ _res_conv = *(LDKCResult_RecoverableSignatureNoneZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); CResult_RecoverableSignatureNoneZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_CResult_RecoverableSignatureNoneZ_clone(uint32_t orig) { LDKCResult_RecoverableSignatureNoneZ* orig_conv = (LDKCResult_RecoverableSignatureNoneZ*)(orig & ~1); LDKCResult_RecoverableSignatureNoneZ* ret_conv = MALLOC(sizeof(LDKCResult_RecoverableSignatureNoneZ), "LDKCResult_RecoverableSignatureNoneZ"); *ret_conv = CResult_RecoverableSignatureNoneZ_clone(orig_conv); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CVec_CVec_u8ZZ_free(ptrArray _res) { LDKCVec_CVec_u8ZZ _res_constr; _res_constr.datalen = *((uint32_t*)_res); if (_res_constr.datalen > 0) _res_constr.data = MALLOC(_res_constr.datalen * sizeof(LDKCVec_u8Z), "LDKCVec_CVec_u8ZZ Elements"); else _res_constr.data = NULL; int8_tArray* _res_vals = (int8_tArray*)(_res + 4); for (size_t m = 0; m < _res_constr.datalen; m++) { int8_tArray _res_conv_12 = _res_vals[m]; LDKCVec_u8Z _res_conv_12_ref; _res_conv_12_ref.datalen = *((uint32_t*)_res_conv_12); _res_conv_12_ref.data = MALLOC(_res_conv_12_ref.datalen, "LDKCVec_u8Z Bytes"); memcpy(_res_conv_12_ref.data, (uint8_t*)(_res_conv_12 + 4), _res_conv_12_ref.datalen); _res_constr.data[m] = _res_conv_12_ref; } CVec_CVec_u8ZZ_free(_res_constr); } uint32_t __attribute__((visibility("default"))) TS_CResult_CVec_CVec_u8ZZNoneZ_ok(ptrArray o) { LDKCVec_CVec_u8ZZ o_constr; o_constr.datalen = *((uint32_t*)o); if (o_constr.datalen > 0) o_constr.data = MALLOC(o_constr.datalen * sizeof(LDKCVec_u8Z), "LDKCVec_CVec_u8ZZ Elements"); else o_constr.data = NULL; int8_tArray* o_vals = (int8_tArray*)(o + 4); for (size_t m = 0; m < o_constr.datalen; m++) { int8_tArray o_conv_12 = o_vals[m]; LDKCVec_u8Z o_conv_12_ref; o_conv_12_ref.datalen = *((uint32_t*)o_conv_12); o_conv_12_ref.data = MALLOC(o_conv_12_ref.datalen, "LDKCVec_u8Z Bytes"); memcpy(o_conv_12_ref.data, (uint8_t*)(o_conv_12 + 4), o_conv_12_ref.datalen); o_constr.data[m] = o_conv_12_ref; } LDKCResult_CVec_CVec_u8ZZNoneZ* ret_conv = MALLOC(sizeof(LDKCResult_CVec_CVec_u8ZZNoneZ), "LDKCResult_CVec_CVec_u8ZZNoneZ"); *ret_conv = CResult_CVec_CVec_u8ZZNoneZ_ok(o_constr); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_CVec_CVec_u8ZZNoneZ_err() { LDKCResult_CVec_CVec_u8ZZNoneZ* ret_conv = MALLOC(sizeof(LDKCResult_CVec_CVec_u8ZZNoneZ), "LDKCResult_CVec_CVec_u8ZZNoneZ"); *ret_conv = CResult_CVec_CVec_u8ZZNoneZ_err(); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CResult_CVec_CVec_u8ZZNoneZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCResult_CVec_CVec_u8ZZNoneZ _res_conv = *(LDKCResult_CVec_CVec_u8ZZNoneZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); CResult_CVec_CVec_u8ZZNoneZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_CResult_CVec_CVec_u8ZZNoneZ_clone(uint32_t orig) { LDKCResult_CVec_CVec_u8ZZNoneZ* orig_conv = (LDKCResult_CVec_CVec_u8ZZNoneZ*)(orig & ~1); LDKCResult_CVec_CVec_u8ZZNoneZ* ret_conv = MALLOC(sizeof(LDKCResult_CVec_CVec_u8ZZNoneZ), "LDKCResult_CVec_CVec_u8ZZNoneZ"); *ret_conv = CResult_CVec_CVec_u8ZZNoneZ_clone(orig_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_InMemorySignerDecodeErrorZ_ok(uint32_t o) { LDKInMemorySigner o_conv; o_conv.inner = (void*)(o & (~1)); o_conv.is_owned = (o & 1) || (o == 0); o_conv = InMemorySigner_clone(&o_conv); LDKCResult_InMemorySignerDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_InMemorySignerDecodeErrorZ), "LDKCResult_InMemorySignerDecodeErrorZ"); *ret_conv = CResult_InMemorySignerDecodeErrorZ_ok(o_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_InMemorySignerDecodeErrorZ_err(uint32_t e) { LDKDecodeError e_conv; e_conv.inner = (void*)(e & (~1)); e_conv.is_owned = (e & 1) || (e == 0); e_conv = DecodeError_clone(&e_conv); LDKCResult_InMemorySignerDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_InMemorySignerDecodeErrorZ), "LDKCResult_InMemorySignerDecodeErrorZ"); *ret_conv = CResult_InMemorySignerDecodeErrorZ_err(e_conv); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CResult_InMemorySignerDecodeErrorZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCResult_InMemorySignerDecodeErrorZ _res_conv = *(LDKCResult_InMemorySignerDecodeErrorZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); CResult_InMemorySignerDecodeErrorZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_CResult_InMemorySignerDecodeErrorZ_clone(uint32_t orig) { LDKCResult_InMemorySignerDecodeErrorZ* orig_conv = (LDKCResult_InMemorySignerDecodeErrorZ*)(orig & ~1); LDKCResult_InMemorySignerDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_InMemorySignerDecodeErrorZ), "LDKCResult_InMemorySignerDecodeErrorZ"); *ret_conv = CResult_InMemorySignerDecodeErrorZ_clone(orig_conv); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CVec_TxOutZ_free(uint32_tArray _res) { LDKCVec_TxOutZ _res_constr; _res_constr.datalen = *((uint32_t*)_res); if (_res_constr.datalen > 0) _res_constr.data = MALLOC(_res_constr.datalen * sizeof(LDKTxOut), "LDKCVec_TxOutZ Elements"); else _res_constr.data = NULL; uint32_t* _res_vals = (uint32_t*)(_res + 4); for (size_t h = 0; h < _res_constr.datalen; h++) { uint32_t _res_conv_7 = _res_vals[h]; LDKTxOut _res_conv_7_conv = *(LDKTxOut*)(((uint64_t)_res_conv_7) & ~1); FREE((void*)_res_conv_7); _res_constr.data[h] = _res_conv_7_conv; } CVec_TxOutZ_free(_res_constr); } uint32_t __attribute__((visibility("default"))) TS_CResult_TransactionNoneZ_ok(int8_tArray o) { LDKTransaction o_ref; o_ref.datalen = *((uint32_t*)o); o_ref.data = MALLOC(o_ref.datalen, "LDKTransaction Bytes"); memcpy(o_ref.data, (uint8_t*)(o + 4), o_ref.datalen); o_ref.data_is_owned = true; LDKCResult_TransactionNoneZ* ret_conv = MALLOC(sizeof(LDKCResult_TransactionNoneZ), "LDKCResult_TransactionNoneZ"); *ret_conv = CResult_TransactionNoneZ_ok(o_ref); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_TransactionNoneZ_err() { LDKCResult_TransactionNoneZ* ret_conv = MALLOC(sizeof(LDKCResult_TransactionNoneZ), "LDKCResult_TransactionNoneZ"); *ret_conv = CResult_TransactionNoneZ_err(); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CResult_TransactionNoneZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCResult_TransactionNoneZ _res_conv = *(LDKCResult_TransactionNoneZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); CResult_TransactionNoneZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_CResult_TransactionNoneZ_clone(uint32_t orig) { LDKCResult_TransactionNoneZ* orig_conv = (LDKCResult_TransactionNoneZ*)(orig & ~1); LDKCResult_TransactionNoneZ* ret_conv = MALLOC(sizeof(LDKCResult_TransactionNoneZ), "LDKCResult_TransactionNoneZ"); *ret_conv = CResult_TransactionNoneZ_clone(orig_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_C2Tuple_BlockHashChannelMonitorZ_new(int8_tArray a, uint32_t b) { LDKThirtyTwoBytes a_ref; CHECK(*((uint32_t*)a) == 32); memcpy(a_ref.data, (uint8_t*)(a + 4), 32); LDKChannelMonitor b_conv; b_conv.inner = (void*)(b & (~1)); b_conv.is_owned = (b & 1) || (b == 0); b_conv = ChannelMonitor_clone(&b_conv); LDKC2Tuple_BlockHashChannelMonitorZ* ret_ref = MALLOC(sizeof(LDKC2Tuple_BlockHashChannelMonitorZ), "LDKC2Tuple_BlockHashChannelMonitorZ"); *ret_ref = C2Tuple_BlockHashChannelMonitorZ_new(a_ref, b_conv); return (uint64_t)ret_ref; } void __attribute__((visibility("default"))) TS_C2Tuple_BlockHashChannelMonitorZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKC2Tuple_BlockHashChannelMonitorZ _res_conv = *(LDKC2Tuple_BlockHashChannelMonitorZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); C2Tuple_BlockHashChannelMonitorZ_free(_res_conv); } void __attribute__((visibility("default"))) TS_CVec_C2Tuple_BlockHashChannelMonitorZZ_free(uint32_tArray _res) { LDKCVec_C2Tuple_BlockHashChannelMonitorZZ _res_constr; _res_constr.datalen = *((uint32_t*)_res); if (_res_constr.datalen > 0) _res_constr.data = MALLOC(_res_constr.datalen * sizeof(LDKC2Tuple_BlockHashChannelMonitorZ), "LDKCVec_C2Tuple_BlockHashChannelMonitorZZ Elements"); else _res_constr.data = NULL; uint32_t* _res_vals = (uint32_t*)(_res + 4); for (size_t m = 0; m < _res_constr.datalen; m++) { uint32_t _res_conv_38 = _res_vals[m]; LDKC2Tuple_BlockHashChannelMonitorZ _res_conv_38_conv = *(LDKC2Tuple_BlockHashChannelMonitorZ*)(((uint64_t)_res_conv_38) & ~1); FREE((void*)_res_conv_38); _res_constr.data[m] = _res_conv_38_conv; } CVec_C2Tuple_BlockHashChannelMonitorZZ_free(_res_constr); } uint32_t __attribute__((visibility("default"))) TS_CResult_CVec_C2Tuple_BlockHashChannelMonitorZZErrorZ_ok(uint32_tArray o) { LDKCVec_C2Tuple_BlockHashChannelMonitorZZ o_constr; o_constr.datalen = *((uint32_t*)o); if (o_constr.datalen > 0) o_constr.data = MALLOC(o_constr.datalen * sizeof(LDKC2Tuple_BlockHashChannelMonitorZ), "LDKCVec_C2Tuple_BlockHashChannelMonitorZZ Elements"); else o_constr.data = NULL; uint32_t* o_vals = (uint32_t*)(o + 4); for (size_t m = 0; m < o_constr.datalen; m++) { uint32_t o_conv_38 = o_vals[m]; LDKC2Tuple_BlockHashChannelMonitorZ o_conv_38_conv = *(LDKC2Tuple_BlockHashChannelMonitorZ*)(((uint64_t)o_conv_38) & ~1); // Warning: we may need a move here but no clone is available for LDKC2Tuple_BlockHashChannelMonitorZ o_constr.data[m] = o_conv_38_conv; } LDKCResult_CVec_C2Tuple_BlockHashChannelMonitorZZErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_CVec_C2Tuple_BlockHashChannelMonitorZZErrorZ), "LDKCResult_CVec_C2Tuple_BlockHashChannelMonitorZZErrorZ"); *ret_conv = CResult_CVec_C2Tuple_BlockHashChannelMonitorZZErrorZ_ok(o_constr); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_CVec_C2Tuple_BlockHashChannelMonitorZZErrorZ_err(uint32_t e) { LDKIOError e_conv = LDKIOError_from_js(e); LDKCResult_CVec_C2Tuple_BlockHashChannelMonitorZZErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_CVec_C2Tuple_BlockHashChannelMonitorZZErrorZ), "LDKCResult_CVec_C2Tuple_BlockHashChannelMonitorZZErrorZ"); *ret_conv = CResult_CVec_C2Tuple_BlockHashChannelMonitorZZErrorZ_err(e_conv); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CResult_CVec_C2Tuple_BlockHashChannelMonitorZZErrorZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCResult_CVec_C2Tuple_BlockHashChannelMonitorZZErrorZ _res_conv = *(LDKCResult_CVec_C2Tuple_BlockHashChannelMonitorZZErrorZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); CResult_CVec_C2Tuple_BlockHashChannelMonitorZZErrorZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_COption_u16Z_some(int16_t o) { LDKCOption_u16Z *ret_copy = MALLOC(sizeof(LDKCOption_u16Z), "LDKCOption_u16Z"); *ret_copy = COption_u16Z_some(o); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_COption_u16Z_none() { LDKCOption_u16Z *ret_copy = MALLOC(sizeof(LDKCOption_u16Z), "LDKCOption_u16Z"); *ret_copy = COption_u16Z_none(); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } void __attribute__((visibility("default"))) TS_COption_u16Z_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCOption_u16Z _res_conv = *(LDKCOption_u16Z*)(((uint64_t)_res) & ~1); FREE((void*)_res); COption_u16Z_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_COption_u16Z_clone(uint32_t orig) { LDKCOption_u16Z* orig_conv = (LDKCOption_u16Z*)orig; LDKCOption_u16Z *ret_copy = MALLOC(sizeof(LDKCOption_u16Z), "LDKCOption_u16Z"); *ret_copy = COption_u16Z_clone(orig_conv); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_CResult_NoneAPIErrorZ_ok() { LDKCResult_NoneAPIErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_NoneAPIErrorZ), "LDKCResult_NoneAPIErrorZ"); *ret_conv = CResult_NoneAPIErrorZ_ok(); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_NoneAPIErrorZ_err(uint32_t e) { LDKAPIError e_conv = *(LDKAPIError*)(((uint64_t)e) & ~1); e_conv = APIError_clone((LDKAPIError*)(((uint64_t)e) & ~1)); LDKCResult_NoneAPIErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_NoneAPIErrorZ), "LDKCResult_NoneAPIErrorZ"); *ret_conv = CResult_NoneAPIErrorZ_err(e_conv); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CResult_NoneAPIErrorZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCResult_NoneAPIErrorZ _res_conv = *(LDKCResult_NoneAPIErrorZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); CResult_NoneAPIErrorZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_CResult_NoneAPIErrorZ_clone(uint32_t orig) { LDKCResult_NoneAPIErrorZ* orig_conv = (LDKCResult_NoneAPIErrorZ*)(orig & ~1); LDKCResult_NoneAPIErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_NoneAPIErrorZ), "LDKCResult_NoneAPIErrorZ"); *ret_conv = CResult_NoneAPIErrorZ_clone(orig_conv); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CVec_CResult_NoneAPIErrorZZ_free(uint32_tArray _res) { LDKCVec_CResult_NoneAPIErrorZZ _res_constr; _res_constr.datalen = *((uint32_t*)_res); if (_res_constr.datalen > 0) _res_constr.data = MALLOC(_res_constr.datalen * sizeof(LDKCResult_NoneAPIErrorZ), "LDKCVec_CResult_NoneAPIErrorZZ Elements"); else _res_constr.data = NULL; uint32_t* _res_vals = (uint32_t*)(_res + 4); for (size_t w = 0; w < _res_constr.datalen; w++) { uint32_t _res_conv_22 = _res_vals[w]; LDKCResult_NoneAPIErrorZ _res_conv_22_conv = *(LDKCResult_NoneAPIErrorZ*)(((uint64_t)_res_conv_22) & ~1); FREE((void*)_res_conv_22); _res_constr.data[w] = _res_conv_22_conv; } CVec_CResult_NoneAPIErrorZZ_free(_res_constr); } void __attribute__((visibility("default"))) TS_CVec_APIErrorZ_free(uint32_tArray _res) { LDKCVec_APIErrorZ _res_constr; _res_constr.datalen = *((uint32_t*)_res); if (_res_constr.datalen > 0) _res_constr.data = MALLOC(_res_constr.datalen * sizeof(LDKAPIError), "LDKCVec_APIErrorZ Elements"); else _res_constr.data = NULL; uint32_t* _res_vals = (uint32_t*)(_res + 4); for (size_t k = 0; k < _res_constr.datalen; k++) { uint32_t _res_conv_10 = _res_vals[k]; LDKAPIError _res_conv_10_conv = *(LDKAPIError*)(((uint64_t)_res_conv_10) & ~1); FREE((void*)_res_conv_10); _res_constr.data[k] = _res_conv_10_conv; } CVec_APIErrorZ_free(_res_constr); } uint32_t __attribute__((visibility("default"))) TS_CResult_NonePaymentSendFailureZ_ok() { LDKCResult_NonePaymentSendFailureZ* ret_conv = MALLOC(sizeof(LDKCResult_NonePaymentSendFailureZ), "LDKCResult_NonePaymentSendFailureZ"); *ret_conv = CResult_NonePaymentSendFailureZ_ok(); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_NonePaymentSendFailureZ_err(uint32_t e) { LDKPaymentSendFailure e_conv = *(LDKPaymentSendFailure*)(((uint64_t)e) & ~1); e_conv = PaymentSendFailure_clone((LDKPaymentSendFailure*)(((uint64_t)e) & ~1)); LDKCResult_NonePaymentSendFailureZ* ret_conv = MALLOC(sizeof(LDKCResult_NonePaymentSendFailureZ), "LDKCResult_NonePaymentSendFailureZ"); *ret_conv = CResult_NonePaymentSendFailureZ_err(e_conv); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CResult_NonePaymentSendFailureZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCResult_NonePaymentSendFailureZ _res_conv = *(LDKCResult_NonePaymentSendFailureZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); CResult_NonePaymentSendFailureZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_CResult_NonePaymentSendFailureZ_clone(uint32_t orig) { LDKCResult_NonePaymentSendFailureZ* orig_conv = (LDKCResult_NonePaymentSendFailureZ*)(orig & ~1); LDKCResult_NonePaymentSendFailureZ* ret_conv = MALLOC(sizeof(LDKCResult_NonePaymentSendFailureZ), "LDKCResult_NonePaymentSendFailureZ"); *ret_conv = CResult_NonePaymentSendFailureZ_clone(orig_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_PaymentHashPaymentSendFailureZ_ok(int8_tArray o) { LDKThirtyTwoBytes o_ref; CHECK(*((uint32_t*)o) == 32); memcpy(o_ref.data, (uint8_t*)(o + 4), 32); LDKCResult_PaymentHashPaymentSendFailureZ* ret_conv = MALLOC(sizeof(LDKCResult_PaymentHashPaymentSendFailureZ), "LDKCResult_PaymentHashPaymentSendFailureZ"); *ret_conv = CResult_PaymentHashPaymentSendFailureZ_ok(o_ref); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_PaymentHashPaymentSendFailureZ_err(uint32_t e) { LDKPaymentSendFailure e_conv = *(LDKPaymentSendFailure*)(((uint64_t)e) & ~1); e_conv = PaymentSendFailure_clone((LDKPaymentSendFailure*)(((uint64_t)e) & ~1)); LDKCResult_PaymentHashPaymentSendFailureZ* ret_conv = MALLOC(sizeof(LDKCResult_PaymentHashPaymentSendFailureZ), "LDKCResult_PaymentHashPaymentSendFailureZ"); *ret_conv = CResult_PaymentHashPaymentSendFailureZ_err(e_conv); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CResult_PaymentHashPaymentSendFailureZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCResult_PaymentHashPaymentSendFailureZ _res_conv = *(LDKCResult_PaymentHashPaymentSendFailureZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); CResult_PaymentHashPaymentSendFailureZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_CResult_PaymentHashPaymentSendFailureZ_clone(uint32_t orig) { LDKCResult_PaymentHashPaymentSendFailureZ* orig_conv = (LDKCResult_PaymentHashPaymentSendFailureZ*)(orig & ~1); LDKCResult_PaymentHashPaymentSendFailureZ* ret_conv = MALLOC(sizeof(LDKCResult_PaymentHashPaymentSendFailureZ), "LDKCResult_PaymentHashPaymentSendFailureZ"); *ret_conv = CResult_PaymentHashPaymentSendFailureZ_clone(orig_conv); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CVec_NetAddressZ_free(uint32_tArray _res) { LDKCVec_NetAddressZ _res_constr; _res_constr.datalen = *((uint32_t*)_res); if (_res_constr.datalen > 0) _res_constr.data = MALLOC(_res_constr.datalen * sizeof(LDKNetAddress), "LDKCVec_NetAddressZ Elements"); else _res_constr.data = NULL; uint32_t* _res_vals = (uint32_t*)(_res + 4); for (size_t m = 0; m < _res_constr.datalen; m++) { uint32_t _res_conv_12 = _res_vals[m]; LDKNetAddress _res_conv_12_conv = *(LDKNetAddress*)(((uint64_t)_res_conv_12) & ~1); FREE((void*)_res_conv_12); _res_constr.data[m] = _res_conv_12_conv; } CVec_NetAddressZ_free(_res_constr); } uint32_t __attribute__((visibility("default"))) TS_C2Tuple_PaymentHashPaymentSecretZ_clone(uint32_t orig) { LDKC2Tuple_PaymentHashPaymentSecretZ* orig_conv = (LDKC2Tuple_PaymentHashPaymentSecretZ*)(orig & ~1); LDKC2Tuple_PaymentHashPaymentSecretZ* ret_ref = MALLOC(sizeof(LDKC2Tuple_PaymentHashPaymentSecretZ), "LDKC2Tuple_PaymentHashPaymentSecretZ"); *ret_ref = C2Tuple_PaymentHashPaymentSecretZ_clone(orig_conv); return (uint64_t)ret_ref; } uint32_t __attribute__((visibility("default"))) TS_C2Tuple_PaymentHashPaymentSecretZ_new(int8_tArray a, int8_tArray b) { LDKThirtyTwoBytes a_ref; CHECK(*((uint32_t*)a) == 32); memcpy(a_ref.data, (uint8_t*)(a + 4), 32); LDKThirtyTwoBytes b_ref; CHECK(*((uint32_t*)b) == 32); memcpy(b_ref.data, (uint8_t*)(b + 4), 32); LDKC2Tuple_PaymentHashPaymentSecretZ* ret_ref = MALLOC(sizeof(LDKC2Tuple_PaymentHashPaymentSecretZ), "LDKC2Tuple_PaymentHashPaymentSecretZ"); *ret_ref = C2Tuple_PaymentHashPaymentSecretZ_new(a_ref, b_ref); return (uint64_t)ret_ref; } void __attribute__((visibility("default"))) TS_C2Tuple_PaymentHashPaymentSecretZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKC2Tuple_PaymentHashPaymentSecretZ _res_conv = *(LDKC2Tuple_PaymentHashPaymentSecretZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); C2Tuple_PaymentHashPaymentSecretZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_CResult_PaymentSecretAPIErrorZ_ok(int8_tArray o) { LDKThirtyTwoBytes o_ref; CHECK(*((uint32_t*)o) == 32); memcpy(o_ref.data, (uint8_t*)(o + 4), 32); LDKCResult_PaymentSecretAPIErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_PaymentSecretAPIErrorZ), "LDKCResult_PaymentSecretAPIErrorZ"); *ret_conv = CResult_PaymentSecretAPIErrorZ_ok(o_ref); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_PaymentSecretAPIErrorZ_err(uint32_t e) { LDKAPIError e_conv = *(LDKAPIError*)(((uint64_t)e) & ~1); e_conv = APIError_clone((LDKAPIError*)(((uint64_t)e) & ~1)); LDKCResult_PaymentSecretAPIErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_PaymentSecretAPIErrorZ), "LDKCResult_PaymentSecretAPIErrorZ"); *ret_conv = CResult_PaymentSecretAPIErrorZ_err(e_conv); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CResult_PaymentSecretAPIErrorZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCResult_PaymentSecretAPIErrorZ _res_conv = *(LDKCResult_PaymentSecretAPIErrorZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); CResult_PaymentSecretAPIErrorZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_CResult_PaymentSecretAPIErrorZ_clone(uint32_t orig) { LDKCResult_PaymentSecretAPIErrorZ* orig_conv = (LDKCResult_PaymentSecretAPIErrorZ*)(orig & ~1); LDKCResult_PaymentSecretAPIErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_PaymentSecretAPIErrorZ), "LDKCResult_PaymentSecretAPIErrorZ"); *ret_conv = CResult_PaymentSecretAPIErrorZ_clone(orig_conv); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CVec_ChannelMonitorZ_free(uint32_tArray _res) { LDKCVec_ChannelMonitorZ _res_constr; _res_constr.datalen = *((uint32_t*)_res); if (_res_constr.datalen > 0) _res_constr.data = MALLOC(_res_constr.datalen * sizeof(LDKChannelMonitor), "LDKCVec_ChannelMonitorZ Elements"); else _res_constr.data = NULL; uint32_t* _res_vals = (uint32_t*)(_res + 4); for (size_t q = 0; q < _res_constr.datalen; q++) { uint32_t _res_conv_16 = _res_vals[q]; LDKChannelMonitor _res_conv_16_conv; _res_conv_16_conv.inner = (void*)(_res_conv_16 & (~1)); _res_conv_16_conv.is_owned = (_res_conv_16 & 1) || (_res_conv_16 == 0); _res_constr.data[q] = _res_conv_16_conv; } CVec_ChannelMonitorZ_free(_res_constr); } uint32_t __attribute__((visibility("default"))) TS_C2Tuple_BlockHashChannelManagerZ_new(int8_tArray a, uint32_t b) { LDKThirtyTwoBytes a_ref; CHECK(*((uint32_t*)a) == 32); memcpy(a_ref.data, (uint8_t*)(a + 4), 32); LDKChannelManager b_conv; b_conv.inner = (void*)(b & (~1)); b_conv.is_owned = (b & 1) || (b == 0); // Warning: we need a move here but no clone is available for LDKChannelManager LDKC2Tuple_BlockHashChannelManagerZ* ret_ref = MALLOC(sizeof(LDKC2Tuple_BlockHashChannelManagerZ), "LDKC2Tuple_BlockHashChannelManagerZ"); *ret_ref = C2Tuple_BlockHashChannelManagerZ_new(a_ref, b_conv); return (uint64_t)ret_ref; } void __attribute__((visibility("default"))) TS_C2Tuple_BlockHashChannelManagerZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKC2Tuple_BlockHashChannelManagerZ _res_conv = *(LDKC2Tuple_BlockHashChannelManagerZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); C2Tuple_BlockHashChannelManagerZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_CResult_C2Tuple_BlockHashChannelManagerZDecodeErrorZ_ok(uint32_t o) { LDKC2Tuple_BlockHashChannelManagerZ o_conv = *(LDKC2Tuple_BlockHashChannelManagerZ*)(((uint64_t)o) & ~1); // Warning: we may need a move here but no clone is available for LDKC2Tuple_BlockHashChannelManagerZ LDKCResult_C2Tuple_BlockHashChannelManagerZDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_C2Tuple_BlockHashChannelManagerZDecodeErrorZ), "LDKCResult_C2Tuple_BlockHashChannelManagerZDecodeErrorZ"); *ret_conv = CResult_C2Tuple_BlockHashChannelManagerZDecodeErrorZ_ok(o_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_C2Tuple_BlockHashChannelManagerZDecodeErrorZ_err(uint32_t e) { LDKDecodeError e_conv; e_conv.inner = (void*)(e & (~1)); e_conv.is_owned = (e & 1) || (e == 0); e_conv = DecodeError_clone(&e_conv); LDKCResult_C2Tuple_BlockHashChannelManagerZDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_C2Tuple_BlockHashChannelManagerZDecodeErrorZ), "LDKCResult_C2Tuple_BlockHashChannelManagerZDecodeErrorZ"); *ret_conv = CResult_C2Tuple_BlockHashChannelManagerZDecodeErrorZ_err(e_conv); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CResult_C2Tuple_BlockHashChannelManagerZDecodeErrorZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCResult_C2Tuple_BlockHashChannelManagerZDecodeErrorZ _res_conv = *(LDKCResult_C2Tuple_BlockHashChannelManagerZDecodeErrorZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); CResult_C2Tuple_BlockHashChannelManagerZDecodeErrorZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_CResult_ChannelConfigDecodeErrorZ_ok(uint32_t o) { LDKChannelConfig o_conv; o_conv.inner = (void*)(o & (~1)); o_conv.is_owned = (o & 1) || (o == 0); o_conv = ChannelConfig_clone(&o_conv); LDKCResult_ChannelConfigDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_ChannelConfigDecodeErrorZ), "LDKCResult_ChannelConfigDecodeErrorZ"); *ret_conv = CResult_ChannelConfigDecodeErrorZ_ok(o_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_ChannelConfigDecodeErrorZ_err(uint32_t e) { LDKDecodeError e_conv; e_conv.inner = (void*)(e & (~1)); e_conv.is_owned = (e & 1) || (e == 0); e_conv = DecodeError_clone(&e_conv); LDKCResult_ChannelConfigDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_ChannelConfigDecodeErrorZ), "LDKCResult_ChannelConfigDecodeErrorZ"); *ret_conv = CResult_ChannelConfigDecodeErrorZ_err(e_conv); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CResult_ChannelConfigDecodeErrorZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCResult_ChannelConfigDecodeErrorZ _res_conv = *(LDKCResult_ChannelConfigDecodeErrorZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); CResult_ChannelConfigDecodeErrorZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_CResult_ChannelConfigDecodeErrorZ_clone(uint32_t orig) { LDKCResult_ChannelConfigDecodeErrorZ* orig_conv = (LDKCResult_ChannelConfigDecodeErrorZ*)(orig & ~1); LDKCResult_ChannelConfigDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_ChannelConfigDecodeErrorZ), "LDKCResult_ChannelConfigDecodeErrorZ"); *ret_conv = CResult_ChannelConfigDecodeErrorZ_clone(orig_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_OutPointDecodeErrorZ_ok(uint32_t o) { LDKOutPoint o_conv; o_conv.inner = (void*)(o & (~1)); o_conv.is_owned = (o & 1) || (o == 0); o_conv = OutPoint_clone(&o_conv); LDKCResult_OutPointDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_OutPointDecodeErrorZ), "LDKCResult_OutPointDecodeErrorZ"); *ret_conv = CResult_OutPointDecodeErrorZ_ok(o_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_OutPointDecodeErrorZ_err(uint32_t e) { LDKDecodeError e_conv; e_conv.inner = (void*)(e & (~1)); e_conv.is_owned = (e & 1) || (e == 0); e_conv = DecodeError_clone(&e_conv); LDKCResult_OutPointDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_OutPointDecodeErrorZ), "LDKCResult_OutPointDecodeErrorZ"); *ret_conv = CResult_OutPointDecodeErrorZ_err(e_conv); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CResult_OutPointDecodeErrorZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCResult_OutPointDecodeErrorZ _res_conv = *(LDKCResult_OutPointDecodeErrorZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); CResult_OutPointDecodeErrorZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_CResult_OutPointDecodeErrorZ_clone(uint32_t orig) { LDKCResult_OutPointDecodeErrorZ* orig_conv = (LDKCResult_OutPointDecodeErrorZ*)(orig & ~1); LDKCResult_OutPointDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_OutPointDecodeErrorZ), "LDKCResult_OutPointDecodeErrorZ"); *ret_conv = CResult_OutPointDecodeErrorZ_clone(orig_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_COption_TypeZ_some(uint32_t o) { LDKType o_conv = *(LDKType*)(((uint64_t)o) & ~1); LDKCOption_TypeZ *ret_copy = MALLOC(sizeof(LDKCOption_TypeZ), "LDKCOption_TypeZ"); *ret_copy = COption_TypeZ_some(o_conv); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_COption_TypeZ_none() { LDKCOption_TypeZ *ret_copy = MALLOC(sizeof(LDKCOption_TypeZ), "LDKCOption_TypeZ"); *ret_copy = COption_TypeZ_none(); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } void __attribute__((visibility("default"))) TS_COption_TypeZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCOption_TypeZ _res_conv = *(LDKCOption_TypeZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); COption_TypeZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_COption_TypeZ_clone(uint32_t orig) { LDKCOption_TypeZ* orig_conv = (LDKCOption_TypeZ*)orig; LDKCOption_TypeZ *ret_copy = MALLOC(sizeof(LDKCOption_TypeZ), "LDKCOption_TypeZ"); *ret_copy = COption_TypeZ_clone(orig_conv); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_CResult_COption_TypeZDecodeErrorZ_ok(uint32_t o) { LDKCOption_TypeZ o_conv = *(LDKCOption_TypeZ*)(((uint64_t)o) & ~1); o_conv = COption_TypeZ_clone((LDKCOption_TypeZ*)(((uint64_t)o) & ~1)); LDKCResult_COption_TypeZDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_COption_TypeZDecodeErrorZ), "LDKCResult_COption_TypeZDecodeErrorZ"); *ret_conv = CResult_COption_TypeZDecodeErrorZ_ok(o_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_COption_TypeZDecodeErrorZ_err(uint32_t e) { LDKDecodeError e_conv; e_conv.inner = (void*)(e & (~1)); e_conv.is_owned = (e & 1) || (e == 0); e_conv = DecodeError_clone(&e_conv); LDKCResult_COption_TypeZDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_COption_TypeZDecodeErrorZ), "LDKCResult_COption_TypeZDecodeErrorZ"); *ret_conv = CResult_COption_TypeZDecodeErrorZ_err(e_conv); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CResult_COption_TypeZDecodeErrorZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCResult_COption_TypeZDecodeErrorZ _res_conv = *(LDKCResult_COption_TypeZDecodeErrorZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); CResult_COption_TypeZDecodeErrorZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_CResult_COption_TypeZDecodeErrorZ_clone(uint32_t orig) { LDKCResult_COption_TypeZDecodeErrorZ* orig_conv = (LDKCResult_COption_TypeZDecodeErrorZ*)(orig & ~1); LDKCResult_COption_TypeZDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_COption_TypeZDecodeErrorZ), "LDKCResult_COption_TypeZDecodeErrorZ"); *ret_conv = CResult_COption_TypeZDecodeErrorZ_clone(orig_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_SiPrefixNoneZ_ok(uint32_t o) { LDKSiPrefix o_conv = LDKSiPrefix_from_js(o); LDKCResult_SiPrefixNoneZ* ret_conv = MALLOC(sizeof(LDKCResult_SiPrefixNoneZ), "LDKCResult_SiPrefixNoneZ"); *ret_conv = CResult_SiPrefixNoneZ_ok(o_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_SiPrefixNoneZ_err() { LDKCResult_SiPrefixNoneZ* ret_conv = MALLOC(sizeof(LDKCResult_SiPrefixNoneZ), "LDKCResult_SiPrefixNoneZ"); *ret_conv = CResult_SiPrefixNoneZ_err(); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CResult_SiPrefixNoneZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCResult_SiPrefixNoneZ _res_conv = *(LDKCResult_SiPrefixNoneZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); CResult_SiPrefixNoneZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_CResult_SiPrefixNoneZ_clone(uint32_t orig) { LDKCResult_SiPrefixNoneZ* orig_conv = (LDKCResult_SiPrefixNoneZ*)(orig & ~1); LDKCResult_SiPrefixNoneZ* ret_conv = MALLOC(sizeof(LDKCResult_SiPrefixNoneZ), "LDKCResult_SiPrefixNoneZ"); *ret_conv = CResult_SiPrefixNoneZ_clone(orig_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_InvoiceNoneZ_ok(uint32_t o) { LDKInvoice o_conv; o_conv.inner = (void*)(o & (~1)); o_conv.is_owned = (o & 1) || (o == 0); o_conv = Invoice_clone(&o_conv); LDKCResult_InvoiceNoneZ* ret_conv = MALLOC(sizeof(LDKCResult_InvoiceNoneZ), "LDKCResult_InvoiceNoneZ"); *ret_conv = CResult_InvoiceNoneZ_ok(o_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_InvoiceNoneZ_err() { LDKCResult_InvoiceNoneZ* ret_conv = MALLOC(sizeof(LDKCResult_InvoiceNoneZ), "LDKCResult_InvoiceNoneZ"); *ret_conv = CResult_InvoiceNoneZ_err(); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CResult_InvoiceNoneZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCResult_InvoiceNoneZ _res_conv = *(LDKCResult_InvoiceNoneZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); CResult_InvoiceNoneZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_CResult_InvoiceNoneZ_clone(uint32_t orig) { LDKCResult_InvoiceNoneZ* orig_conv = (LDKCResult_InvoiceNoneZ*)(orig & ~1); LDKCResult_InvoiceNoneZ* ret_conv = MALLOC(sizeof(LDKCResult_InvoiceNoneZ), "LDKCResult_InvoiceNoneZ"); *ret_conv = CResult_InvoiceNoneZ_clone(orig_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_SignedRawInvoiceNoneZ_ok(uint32_t o) { LDKSignedRawInvoice o_conv; o_conv.inner = (void*)(o & (~1)); o_conv.is_owned = (o & 1) || (o == 0); o_conv = SignedRawInvoice_clone(&o_conv); LDKCResult_SignedRawInvoiceNoneZ* ret_conv = MALLOC(sizeof(LDKCResult_SignedRawInvoiceNoneZ), "LDKCResult_SignedRawInvoiceNoneZ"); *ret_conv = CResult_SignedRawInvoiceNoneZ_ok(o_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_SignedRawInvoiceNoneZ_err() { LDKCResult_SignedRawInvoiceNoneZ* ret_conv = MALLOC(sizeof(LDKCResult_SignedRawInvoiceNoneZ), "LDKCResult_SignedRawInvoiceNoneZ"); *ret_conv = CResult_SignedRawInvoiceNoneZ_err(); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CResult_SignedRawInvoiceNoneZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCResult_SignedRawInvoiceNoneZ _res_conv = *(LDKCResult_SignedRawInvoiceNoneZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); CResult_SignedRawInvoiceNoneZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_CResult_SignedRawInvoiceNoneZ_clone(uint32_t orig) { LDKCResult_SignedRawInvoiceNoneZ* orig_conv = (LDKCResult_SignedRawInvoiceNoneZ*)(orig & ~1); LDKCResult_SignedRawInvoiceNoneZ* ret_conv = MALLOC(sizeof(LDKCResult_SignedRawInvoiceNoneZ), "LDKCResult_SignedRawInvoiceNoneZ"); *ret_conv = CResult_SignedRawInvoiceNoneZ_clone(orig_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_C3Tuple_RawInvoice_u832InvoiceSignatureZ_clone(uint32_t orig) { LDKC3Tuple_RawInvoice_u832InvoiceSignatureZ* orig_conv = (LDKC3Tuple_RawInvoice_u832InvoiceSignatureZ*)(orig & ~1); LDKC3Tuple_RawInvoice_u832InvoiceSignatureZ* ret_ref = MALLOC(sizeof(LDKC3Tuple_RawInvoice_u832InvoiceSignatureZ), "LDKC3Tuple_RawInvoice_u832InvoiceSignatureZ"); *ret_ref = C3Tuple_RawInvoice_u832InvoiceSignatureZ_clone(orig_conv); return (uint64_t)ret_ref; } uint32_t __attribute__((visibility("default"))) TS_C3Tuple_RawInvoice_u832InvoiceSignatureZ_new(uint32_t a, int8_tArray b, uint32_t c) { LDKRawInvoice a_conv; a_conv.inner = (void*)(a & (~1)); a_conv.is_owned = (a & 1) || (a == 0); a_conv = RawInvoice_clone(&a_conv); LDKThirtyTwoBytes b_ref; CHECK(*((uint32_t*)b) == 32); memcpy(b_ref.data, (uint8_t*)(b + 4), 32); LDKInvoiceSignature c_conv; c_conv.inner = (void*)(c & (~1)); c_conv.is_owned = (c & 1) || (c == 0); c_conv = InvoiceSignature_clone(&c_conv); LDKC3Tuple_RawInvoice_u832InvoiceSignatureZ* ret_ref = MALLOC(sizeof(LDKC3Tuple_RawInvoice_u832InvoiceSignatureZ), "LDKC3Tuple_RawInvoice_u832InvoiceSignatureZ"); *ret_ref = C3Tuple_RawInvoice_u832InvoiceSignatureZ_new(a_conv, b_ref, c_conv); return (uint64_t)ret_ref; } void __attribute__((visibility("default"))) TS_C3Tuple_RawInvoice_u832InvoiceSignatureZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKC3Tuple_RawInvoice_u832InvoiceSignatureZ _res_conv = *(LDKC3Tuple_RawInvoice_u832InvoiceSignatureZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); C3Tuple_RawInvoice_u832InvoiceSignatureZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_CResult_PayeePubKeyErrorZ_ok(uint32_t o) { LDKPayeePubKey o_conv; o_conv.inner = (void*)(o & (~1)); o_conv.is_owned = (o & 1) || (o == 0); o_conv = PayeePubKey_clone(&o_conv); LDKCResult_PayeePubKeyErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_PayeePubKeyErrorZ), "LDKCResult_PayeePubKeyErrorZ"); *ret_conv = CResult_PayeePubKeyErrorZ_ok(o_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_PayeePubKeyErrorZ_err(uint32_t e) { LDKSecp256k1Error e_conv = LDKSecp256k1Error_from_js(e); LDKCResult_PayeePubKeyErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_PayeePubKeyErrorZ), "LDKCResult_PayeePubKeyErrorZ"); *ret_conv = CResult_PayeePubKeyErrorZ_err(e_conv); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CResult_PayeePubKeyErrorZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCResult_PayeePubKeyErrorZ _res_conv = *(LDKCResult_PayeePubKeyErrorZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); CResult_PayeePubKeyErrorZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_CResult_PayeePubKeyErrorZ_clone(uint32_t orig) { LDKCResult_PayeePubKeyErrorZ* orig_conv = (LDKCResult_PayeePubKeyErrorZ*)(orig & ~1); LDKCResult_PayeePubKeyErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_PayeePubKeyErrorZ), "LDKCResult_PayeePubKeyErrorZ"); *ret_conv = CResult_PayeePubKeyErrorZ_clone(orig_conv); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CVec_PrivateRouteZ_free(uint32_tArray _res) { LDKCVec_PrivateRouteZ _res_constr; _res_constr.datalen = *((uint32_t*)_res); if (_res_constr.datalen > 0) _res_constr.data = MALLOC(_res_constr.datalen * sizeof(LDKPrivateRoute), "LDKCVec_PrivateRouteZ Elements"); else _res_constr.data = NULL; uint32_t* _res_vals = (uint32_t*)(_res + 4); for (size_t o = 0; o < _res_constr.datalen; o++) { uint32_t _res_conv_14 = _res_vals[o]; LDKPrivateRoute _res_conv_14_conv; _res_conv_14_conv.inner = (void*)(_res_conv_14 & (~1)); _res_conv_14_conv.is_owned = (_res_conv_14 & 1) || (_res_conv_14 == 0); _res_constr.data[o] = _res_conv_14_conv; } CVec_PrivateRouteZ_free(_res_constr); } uint32_t __attribute__((visibility("default"))) TS_CResult_PositiveTimestampCreationErrorZ_ok(uint32_t o) { LDKPositiveTimestamp o_conv; o_conv.inner = (void*)(o & (~1)); o_conv.is_owned = (o & 1) || (o == 0); o_conv = PositiveTimestamp_clone(&o_conv); LDKCResult_PositiveTimestampCreationErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_PositiveTimestampCreationErrorZ), "LDKCResult_PositiveTimestampCreationErrorZ"); *ret_conv = CResult_PositiveTimestampCreationErrorZ_ok(o_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_PositiveTimestampCreationErrorZ_err(uint32_t e) { LDKCreationError e_conv = LDKCreationError_from_js(e); LDKCResult_PositiveTimestampCreationErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_PositiveTimestampCreationErrorZ), "LDKCResult_PositiveTimestampCreationErrorZ"); *ret_conv = CResult_PositiveTimestampCreationErrorZ_err(e_conv); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CResult_PositiveTimestampCreationErrorZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCResult_PositiveTimestampCreationErrorZ _res_conv = *(LDKCResult_PositiveTimestampCreationErrorZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); CResult_PositiveTimestampCreationErrorZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_CResult_PositiveTimestampCreationErrorZ_clone(uint32_t orig) { LDKCResult_PositiveTimestampCreationErrorZ* orig_conv = (LDKCResult_PositiveTimestampCreationErrorZ*)(orig & ~1); LDKCResult_PositiveTimestampCreationErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_PositiveTimestampCreationErrorZ), "LDKCResult_PositiveTimestampCreationErrorZ"); *ret_conv = CResult_PositiveTimestampCreationErrorZ_clone(orig_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_NoneSemanticErrorZ_ok() { LDKCResult_NoneSemanticErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_NoneSemanticErrorZ), "LDKCResult_NoneSemanticErrorZ"); *ret_conv = CResult_NoneSemanticErrorZ_ok(); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_NoneSemanticErrorZ_err(uint32_t e) { LDKSemanticError e_conv = LDKSemanticError_from_js(e); LDKCResult_NoneSemanticErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_NoneSemanticErrorZ), "LDKCResult_NoneSemanticErrorZ"); *ret_conv = CResult_NoneSemanticErrorZ_err(e_conv); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CResult_NoneSemanticErrorZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCResult_NoneSemanticErrorZ _res_conv = *(LDKCResult_NoneSemanticErrorZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); CResult_NoneSemanticErrorZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_CResult_NoneSemanticErrorZ_clone(uint32_t orig) { LDKCResult_NoneSemanticErrorZ* orig_conv = (LDKCResult_NoneSemanticErrorZ*)(orig & ~1); LDKCResult_NoneSemanticErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_NoneSemanticErrorZ), "LDKCResult_NoneSemanticErrorZ"); *ret_conv = CResult_NoneSemanticErrorZ_clone(orig_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_InvoiceSemanticErrorZ_ok(uint32_t o) { LDKInvoice o_conv; o_conv.inner = (void*)(o & (~1)); o_conv.is_owned = (o & 1) || (o == 0); o_conv = Invoice_clone(&o_conv); LDKCResult_InvoiceSemanticErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_InvoiceSemanticErrorZ), "LDKCResult_InvoiceSemanticErrorZ"); *ret_conv = CResult_InvoiceSemanticErrorZ_ok(o_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_InvoiceSemanticErrorZ_err(uint32_t e) { LDKSemanticError e_conv = LDKSemanticError_from_js(e); LDKCResult_InvoiceSemanticErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_InvoiceSemanticErrorZ), "LDKCResult_InvoiceSemanticErrorZ"); *ret_conv = CResult_InvoiceSemanticErrorZ_err(e_conv); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CResult_InvoiceSemanticErrorZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCResult_InvoiceSemanticErrorZ _res_conv = *(LDKCResult_InvoiceSemanticErrorZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); CResult_InvoiceSemanticErrorZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_CResult_InvoiceSemanticErrorZ_clone(uint32_t orig) { LDKCResult_InvoiceSemanticErrorZ* orig_conv = (LDKCResult_InvoiceSemanticErrorZ*)(orig & ~1); LDKCResult_InvoiceSemanticErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_InvoiceSemanticErrorZ), "LDKCResult_InvoiceSemanticErrorZ"); *ret_conv = CResult_InvoiceSemanticErrorZ_clone(orig_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_DescriptionCreationErrorZ_ok(uint32_t o) { LDKDescription o_conv; o_conv.inner = (void*)(o & (~1)); o_conv.is_owned = (o & 1) || (o == 0); o_conv = Description_clone(&o_conv); LDKCResult_DescriptionCreationErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_DescriptionCreationErrorZ), "LDKCResult_DescriptionCreationErrorZ"); *ret_conv = CResult_DescriptionCreationErrorZ_ok(o_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_DescriptionCreationErrorZ_err(uint32_t e) { LDKCreationError e_conv = LDKCreationError_from_js(e); LDKCResult_DescriptionCreationErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_DescriptionCreationErrorZ), "LDKCResult_DescriptionCreationErrorZ"); *ret_conv = CResult_DescriptionCreationErrorZ_err(e_conv); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CResult_DescriptionCreationErrorZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCResult_DescriptionCreationErrorZ _res_conv = *(LDKCResult_DescriptionCreationErrorZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); CResult_DescriptionCreationErrorZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_CResult_DescriptionCreationErrorZ_clone(uint32_t orig) { LDKCResult_DescriptionCreationErrorZ* orig_conv = (LDKCResult_DescriptionCreationErrorZ*)(orig & ~1); LDKCResult_DescriptionCreationErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_DescriptionCreationErrorZ), "LDKCResult_DescriptionCreationErrorZ"); *ret_conv = CResult_DescriptionCreationErrorZ_clone(orig_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_ExpiryTimeCreationErrorZ_ok(uint32_t o) { LDKExpiryTime o_conv; o_conv.inner = (void*)(o & (~1)); o_conv.is_owned = (o & 1) || (o == 0); o_conv = ExpiryTime_clone(&o_conv); LDKCResult_ExpiryTimeCreationErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_ExpiryTimeCreationErrorZ), "LDKCResult_ExpiryTimeCreationErrorZ"); *ret_conv = CResult_ExpiryTimeCreationErrorZ_ok(o_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_ExpiryTimeCreationErrorZ_err(uint32_t e) { LDKCreationError e_conv = LDKCreationError_from_js(e); LDKCResult_ExpiryTimeCreationErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_ExpiryTimeCreationErrorZ), "LDKCResult_ExpiryTimeCreationErrorZ"); *ret_conv = CResult_ExpiryTimeCreationErrorZ_err(e_conv); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CResult_ExpiryTimeCreationErrorZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCResult_ExpiryTimeCreationErrorZ _res_conv = *(LDKCResult_ExpiryTimeCreationErrorZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); CResult_ExpiryTimeCreationErrorZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_CResult_ExpiryTimeCreationErrorZ_clone(uint32_t orig) { LDKCResult_ExpiryTimeCreationErrorZ* orig_conv = (LDKCResult_ExpiryTimeCreationErrorZ*)(orig & ~1); LDKCResult_ExpiryTimeCreationErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_ExpiryTimeCreationErrorZ), "LDKCResult_ExpiryTimeCreationErrorZ"); *ret_conv = CResult_ExpiryTimeCreationErrorZ_clone(orig_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_PrivateRouteCreationErrorZ_ok(uint32_t o) { LDKPrivateRoute o_conv; o_conv.inner = (void*)(o & (~1)); o_conv.is_owned = (o & 1) || (o == 0); o_conv = PrivateRoute_clone(&o_conv); LDKCResult_PrivateRouteCreationErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_PrivateRouteCreationErrorZ), "LDKCResult_PrivateRouteCreationErrorZ"); *ret_conv = CResult_PrivateRouteCreationErrorZ_ok(o_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_PrivateRouteCreationErrorZ_err(uint32_t e) { LDKCreationError e_conv = LDKCreationError_from_js(e); LDKCResult_PrivateRouteCreationErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_PrivateRouteCreationErrorZ), "LDKCResult_PrivateRouteCreationErrorZ"); *ret_conv = CResult_PrivateRouteCreationErrorZ_err(e_conv); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CResult_PrivateRouteCreationErrorZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCResult_PrivateRouteCreationErrorZ _res_conv = *(LDKCResult_PrivateRouteCreationErrorZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); CResult_PrivateRouteCreationErrorZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_CResult_PrivateRouteCreationErrorZ_clone(uint32_t orig) { LDKCResult_PrivateRouteCreationErrorZ* orig_conv = (LDKCResult_PrivateRouteCreationErrorZ*)(orig & ~1); LDKCResult_PrivateRouteCreationErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_PrivateRouteCreationErrorZ), "LDKCResult_PrivateRouteCreationErrorZ"); *ret_conv = CResult_PrivateRouteCreationErrorZ_clone(orig_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_StringErrorZ_ok(jstring o) { LDKStr o_conv = str_ref_to_owned_c(o); LDKCResult_StringErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_StringErrorZ), "LDKCResult_StringErrorZ"); *ret_conv = CResult_StringErrorZ_ok(o_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_StringErrorZ_err(uint32_t e) { LDKSecp256k1Error e_conv = LDKSecp256k1Error_from_js(e); LDKCResult_StringErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_StringErrorZ), "LDKCResult_StringErrorZ"); *ret_conv = CResult_StringErrorZ_err(e_conv); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CResult_StringErrorZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCResult_StringErrorZ _res_conv = *(LDKCResult_StringErrorZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); CResult_StringErrorZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_CResult_ChannelMonitorUpdateDecodeErrorZ_ok(uint32_t o) { LDKChannelMonitorUpdate o_conv; o_conv.inner = (void*)(o & (~1)); o_conv.is_owned = (o & 1) || (o == 0); o_conv = ChannelMonitorUpdate_clone(&o_conv); LDKCResult_ChannelMonitorUpdateDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_ChannelMonitorUpdateDecodeErrorZ), "LDKCResult_ChannelMonitorUpdateDecodeErrorZ"); *ret_conv = CResult_ChannelMonitorUpdateDecodeErrorZ_ok(o_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_ChannelMonitorUpdateDecodeErrorZ_err(uint32_t e) { LDKDecodeError e_conv; e_conv.inner = (void*)(e & (~1)); e_conv.is_owned = (e & 1) || (e == 0); e_conv = DecodeError_clone(&e_conv); LDKCResult_ChannelMonitorUpdateDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_ChannelMonitorUpdateDecodeErrorZ), "LDKCResult_ChannelMonitorUpdateDecodeErrorZ"); *ret_conv = CResult_ChannelMonitorUpdateDecodeErrorZ_err(e_conv); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CResult_ChannelMonitorUpdateDecodeErrorZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCResult_ChannelMonitorUpdateDecodeErrorZ _res_conv = *(LDKCResult_ChannelMonitorUpdateDecodeErrorZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); CResult_ChannelMonitorUpdateDecodeErrorZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_CResult_ChannelMonitorUpdateDecodeErrorZ_clone(uint32_t orig) { LDKCResult_ChannelMonitorUpdateDecodeErrorZ* orig_conv = (LDKCResult_ChannelMonitorUpdateDecodeErrorZ*)(orig & ~1); LDKCResult_ChannelMonitorUpdateDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_ChannelMonitorUpdateDecodeErrorZ), "LDKCResult_ChannelMonitorUpdateDecodeErrorZ"); *ret_conv = CResult_ChannelMonitorUpdateDecodeErrorZ_clone(orig_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_HTLCUpdateDecodeErrorZ_ok(uint32_t o) { LDKHTLCUpdate o_conv; o_conv.inner = (void*)(o & (~1)); o_conv.is_owned = (o & 1) || (o == 0); o_conv = HTLCUpdate_clone(&o_conv); LDKCResult_HTLCUpdateDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_HTLCUpdateDecodeErrorZ), "LDKCResult_HTLCUpdateDecodeErrorZ"); *ret_conv = CResult_HTLCUpdateDecodeErrorZ_ok(o_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_HTLCUpdateDecodeErrorZ_err(uint32_t e) { LDKDecodeError e_conv; e_conv.inner = (void*)(e & (~1)); e_conv.is_owned = (e & 1) || (e == 0); e_conv = DecodeError_clone(&e_conv); LDKCResult_HTLCUpdateDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_HTLCUpdateDecodeErrorZ), "LDKCResult_HTLCUpdateDecodeErrorZ"); *ret_conv = CResult_HTLCUpdateDecodeErrorZ_err(e_conv); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CResult_HTLCUpdateDecodeErrorZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCResult_HTLCUpdateDecodeErrorZ _res_conv = *(LDKCResult_HTLCUpdateDecodeErrorZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); CResult_HTLCUpdateDecodeErrorZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_CResult_HTLCUpdateDecodeErrorZ_clone(uint32_t orig) { LDKCResult_HTLCUpdateDecodeErrorZ* orig_conv = (LDKCResult_HTLCUpdateDecodeErrorZ*)(orig & ~1); LDKCResult_HTLCUpdateDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_HTLCUpdateDecodeErrorZ), "LDKCResult_HTLCUpdateDecodeErrorZ"); *ret_conv = CResult_HTLCUpdateDecodeErrorZ_clone(orig_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_NoneMonitorUpdateErrorZ_ok() { LDKCResult_NoneMonitorUpdateErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_NoneMonitorUpdateErrorZ), "LDKCResult_NoneMonitorUpdateErrorZ"); *ret_conv = CResult_NoneMonitorUpdateErrorZ_ok(); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_NoneMonitorUpdateErrorZ_err(uint32_t e) { LDKMonitorUpdateError e_conv; e_conv.inner = (void*)(e & (~1)); e_conv.is_owned = (e & 1) || (e == 0); e_conv = MonitorUpdateError_clone(&e_conv); LDKCResult_NoneMonitorUpdateErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_NoneMonitorUpdateErrorZ), "LDKCResult_NoneMonitorUpdateErrorZ"); *ret_conv = CResult_NoneMonitorUpdateErrorZ_err(e_conv); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CResult_NoneMonitorUpdateErrorZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCResult_NoneMonitorUpdateErrorZ _res_conv = *(LDKCResult_NoneMonitorUpdateErrorZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); CResult_NoneMonitorUpdateErrorZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_CResult_NoneMonitorUpdateErrorZ_clone(uint32_t orig) { LDKCResult_NoneMonitorUpdateErrorZ* orig_conv = (LDKCResult_NoneMonitorUpdateErrorZ*)(orig & ~1); LDKCResult_NoneMonitorUpdateErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_NoneMonitorUpdateErrorZ), "LDKCResult_NoneMonitorUpdateErrorZ"); *ret_conv = CResult_NoneMonitorUpdateErrorZ_clone(orig_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_C2Tuple_OutPointScriptZ_clone(uint32_t orig) { LDKC2Tuple_OutPointScriptZ* orig_conv = (LDKC2Tuple_OutPointScriptZ*)(orig & ~1); LDKC2Tuple_OutPointScriptZ* ret_ref = MALLOC(sizeof(LDKC2Tuple_OutPointScriptZ), "LDKC2Tuple_OutPointScriptZ"); *ret_ref = C2Tuple_OutPointScriptZ_clone(orig_conv); return (uint64_t)ret_ref; } uint32_t __attribute__((visibility("default"))) TS_C2Tuple_OutPointScriptZ_new(uint32_t a, int8_tArray b) { LDKOutPoint a_conv; a_conv.inner = (void*)(a & (~1)); a_conv.is_owned = (a & 1) || (a == 0); a_conv = OutPoint_clone(&a_conv); LDKCVec_u8Z b_ref; b_ref.datalen = *((uint32_t*)b); b_ref.data = MALLOC(b_ref.datalen, "LDKCVec_u8Z Bytes"); memcpy(b_ref.data, (uint8_t*)(b + 4), b_ref.datalen); LDKC2Tuple_OutPointScriptZ* ret_ref = MALLOC(sizeof(LDKC2Tuple_OutPointScriptZ), "LDKC2Tuple_OutPointScriptZ"); *ret_ref = C2Tuple_OutPointScriptZ_new(a_conv, b_ref); return (uint64_t)ret_ref; } void __attribute__((visibility("default"))) TS_C2Tuple_OutPointScriptZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKC2Tuple_OutPointScriptZ _res_conv = *(LDKC2Tuple_OutPointScriptZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); C2Tuple_OutPointScriptZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_C2Tuple_u32ScriptZ_clone(uint32_t orig) { LDKC2Tuple_u32ScriptZ* orig_conv = (LDKC2Tuple_u32ScriptZ*)(orig & ~1); LDKC2Tuple_u32ScriptZ* ret_ref = MALLOC(sizeof(LDKC2Tuple_u32ScriptZ), "LDKC2Tuple_u32ScriptZ"); *ret_ref = C2Tuple_u32ScriptZ_clone(orig_conv); return (uint64_t)ret_ref; } uint32_t __attribute__((visibility("default"))) TS_C2Tuple_u32ScriptZ_new(int32_t a, int8_tArray b) { LDKCVec_u8Z b_ref; b_ref.datalen = *((uint32_t*)b); b_ref.data = MALLOC(b_ref.datalen, "LDKCVec_u8Z Bytes"); memcpy(b_ref.data, (uint8_t*)(b + 4), b_ref.datalen); LDKC2Tuple_u32ScriptZ* ret_ref = MALLOC(sizeof(LDKC2Tuple_u32ScriptZ), "LDKC2Tuple_u32ScriptZ"); *ret_ref = C2Tuple_u32ScriptZ_new(a, b_ref); return (uint64_t)ret_ref; } void __attribute__((visibility("default"))) TS_C2Tuple_u32ScriptZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKC2Tuple_u32ScriptZ _res_conv = *(LDKC2Tuple_u32ScriptZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); C2Tuple_u32ScriptZ_free(_res_conv); } void __attribute__((visibility("default"))) TS_CVec_C2Tuple_u32ScriptZZ_free(uint32_tArray _res) { LDKCVec_C2Tuple_u32ScriptZZ _res_constr; _res_constr.datalen = *((uint32_t*)_res); if (_res_constr.datalen > 0) _res_constr.data = MALLOC(_res_constr.datalen * sizeof(LDKC2Tuple_u32ScriptZ), "LDKCVec_C2Tuple_u32ScriptZZ Elements"); else _res_constr.data = NULL; uint32_t* _res_vals = (uint32_t*)(_res + 4); for (size_t e = 0; e < _res_constr.datalen; e++) { uint32_t _res_conv_30 = _res_vals[e]; LDKC2Tuple_u32ScriptZ _res_conv_30_conv = *(LDKC2Tuple_u32ScriptZ*)(((uint64_t)_res_conv_30) & ~1); FREE((void*)_res_conv_30); _res_constr.data[e] = _res_conv_30_conv; } CVec_C2Tuple_u32ScriptZZ_free(_res_constr); } uint32_t __attribute__((visibility("default"))) TS_C2Tuple_TxidCVec_C2Tuple_u32ScriptZZZ_clone(uint32_t orig) { LDKC2Tuple_TxidCVec_C2Tuple_u32ScriptZZZ* orig_conv = (LDKC2Tuple_TxidCVec_C2Tuple_u32ScriptZZZ*)(orig & ~1); LDKC2Tuple_TxidCVec_C2Tuple_u32ScriptZZZ* ret_ref = MALLOC(sizeof(LDKC2Tuple_TxidCVec_C2Tuple_u32ScriptZZZ), "LDKC2Tuple_TxidCVec_C2Tuple_u32ScriptZZZ"); *ret_ref = C2Tuple_TxidCVec_C2Tuple_u32ScriptZZZ_clone(orig_conv); return (uint64_t)ret_ref; } uint32_t __attribute__((visibility("default"))) TS_C2Tuple_TxidCVec_C2Tuple_u32ScriptZZZ_new(int8_tArray a, uint32_tArray b) { LDKThirtyTwoBytes a_ref; CHECK(*((uint32_t*)a) == 32); memcpy(a_ref.data, (uint8_t*)(a + 4), 32); LDKCVec_C2Tuple_u32ScriptZZ b_constr; b_constr.datalen = *((uint32_t*)b); if (b_constr.datalen > 0) b_constr.data = MALLOC(b_constr.datalen * sizeof(LDKC2Tuple_u32ScriptZ), "LDKCVec_C2Tuple_u32ScriptZZ Elements"); else b_constr.data = NULL; uint32_t* b_vals = (uint32_t*)(b + 4); for (size_t e = 0; e < b_constr.datalen; e++) { uint32_t b_conv_30 = b_vals[e]; LDKC2Tuple_u32ScriptZ b_conv_30_conv = *(LDKC2Tuple_u32ScriptZ*)(((uint64_t)b_conv_30) & ~1); b_conv_30_conv = C2Tuple_u32ScriptZ_clone((LDKC2Tuple_u32ScriptZ*)(((uint64_t)b_conv_30) & ~1)); b_constr.data[e] = b_conv_30_conv; } LDKC2Tuple_TxidCVec_C2Tuple_u32ScriptZZZ* ret_ref = MALLOC(sizeof(LDKC2Tuple_TxidCVec_C2Tuple_u32ScriptZZZ), "LDKC2Tuple_TxidCVec_C2Tuple_u32ScriptZZZ"); *ret_ref = C2Tuple_TxidCVec_C2Tuple_u32ScriptZZZ_new(a_ref, b_constr); return (uint64_t)ret_ref; } void __attribute__((visibility("default"))) TS_C2Tuple_TxidCVec_C2Tuple_u32ScriptZZZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKC2Tuple_TxidCVec_C2Tuple_u32ScriptZZZ _res_conv = *(LDKC2Tuple_TxidCVec_C2Tuple_u32ScriptZZZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); C2Tuple_TxidCVec_C2Tuple_u32ScriptZZZ_free(_res_conv); } void __attribute__((visibility("default"))) TS_CVec_C2Tuple_TxidCVec_C2Tuple_u32ScriptZZZZ_free(uint32_tArray _res) { LDKCVec_C2Tuple_TxidCVec_C2Tuple_u32ScriptZZZZ _res_constr; _res_constr.datalen = *((uint32_t*)_res); if (_res_constr.datalen > 0) _res_constr.data = MALLOC(_res_constr.datalen * sizeof(LDKC2Tuple_TxidCVec_C2Tuple_u32ScriptZZZ), "LDKCVec_C2Tuple_TxidCVec_C2Tuple_u32ScriptZZZZ Elements"); else _res_constr.data = NULL; uint32_t* _res_vals = (uint32_t*)(_res + 4); for (size_t c = 0; c < _res_constr.datalen; c++) { uint32_t _res_conv_54 = _res_vals[c]; LDKC2Tuple_TxidCVec_C2Tuple_u32ScriptZZZ _res_conv_54_conv = *(LDKC2Tuple_TxidCVec_C2Tuple_u32ScriptZZZ*)(((uint64_t)_res_conv_54) & ~1); FREE((void*)_res_conv_54); _res_constr.data[c] = _res_conv_54_conv; } CVec_C2Tuple_TxidCVec_C2Tuple_u32ScriptZZZZ_free(_res_constr); } void __attribute__((visibility("default"))) TS_CVec_EventZ_free(uint32_tArray _res) { LDKCVec_EventZ _res_constr; _res_constr.datalen = *((uint32_t*)_res); if (_res_constr.datalen > 0) _res_constr.data = MALLOC(_res_constr.datalen * sizeof(LDKEvent), "LDKCVec_EventZ Elements"); else _res_constr.data = NULL; uint32_t* _res_vals = (uint32_t*)(_res + 4); for (size_t h = 0; h < _res_constr.datalen; h++) { uint32_t _res_conv_7 = _res_vals[h]; LDKEvent _res_conv_7_conv = *(LDKEvent*)(((uint64_t)_res_conv_7) & ~1); FREE((void*)_res_conv_7); _res_constr.data[h] = _res_conv_7_conv; } CVec_EventZ_free(_res_constr); } void __attribute__((visibility("default"))) TS_CVec_TransactionZ_free(ptrArray _res) { LDKCVec_TransactionZ _res_constr; _res_constr.datalen = *((uint32_t*)_res); if (_res_constr.datalen > 0) _res_constr.data = MALLOC(_res_constr.datalen * sizeof(LDKTransaction), "LDKCVec_TransactionZ Elements"); else _res_constr.data = NULL; int8_tArray* _res_vals = (int8_tArray*)(_res + 4); for (size_t m = 0; m < _res_constr.datalen; m++) { int8_tArray _res_conv_12 = _res_vals[m]; LDKTransaction _res_conv_12_ref; _res_conv_12_ref.datalen = *((uint32_t*)_res_conv_12); _res_conv_12_ref.data = MALLOC(_res_conv_12_ref.datalen, "LDKTransaction Bytes"); memcpy(_res_conv_12_ref.data, (uint8_t*)(_res_conv_12 + 4), _res_conv_12_ref.datalen); _res_conv_12_ref.data_is_owned = true; _res_constr.data[m] = _res_conv_12_ref; } CVec_TransactionZ_free(_res_constr); } uint32_t __attribute__((visibility("default"))) TS_C2Tuple_u32TxOutZ_clone(uint32_t orig) { LDKC2Tuple_u32TxOutZ* orig_conv = (LDKC2Tuple_u32TxOutZ*)(orig & ~1); LDKC2Tuple_u32TxOutZ* ret_ref = MALLOC(sizeof(LDKC2Tuple_u32TxOutZ), "LDKC2Tuple_u32TxOutZ"); *ret_ref = C2Tuple_u32TxOutZ_clone(orig_conv); return (uint64_t)ret_ref; } uint32_t __attribute__((visibility("default"))) TS_C2Tuple_u32TxOutZ_new(int32_t a, uint32_t b) { LDKTxOut b_conv = *(LDKTxOut*)(((uint64_t)b) & ~1); b_conv = TxOut_clone((LDKTxOut*)(((uint64_t)b) & ~1)); LDKC2Tuple_u32TxOutZ* ret_ref = MALLOC(sizeof(LDKC2Tuple_u32TxOutZ), "LDKC2Tuple_u32TxOutZ"); *ret_ref = C2Tuple_u32TxOutZ_new(a, b_conv); return (uint64_t)ret_ref; } void __attribute__((visibility("default"))) TS_C2Tuple_u32TxOutZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKC2Tuple_u32TxOutZ _res_conv = *(LDKC2Tuple_u32TxOutZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); C2Tuple_u32TxOutZ_free(_res_conv); } void __attribute__((visibility("default"))) TS_CVec_C2Tuple_u32TxOutZZ_free(uint32_tArray _res) { LDKCVec_C2Tuple_u32TxOutZZ _res_constr; _res_constr.datalen = *((uint32_t*)_res); if (_res_constr.datalen > 0) _res_constr.data = MALLOC(_res_constr.datalen * sizeof(LDKC2Tuple_u32TxOutZ), "LDKCVec_C2Tuple_u32TxOutZZ Elements"); else _res_constr.data = NULL; uint32_t* _res_vals = (uint32_t*)(_res + 4); for (size_t z = 0; z < _res_constr.datalen; z++) { uint32_t _res_conv_25 = _res_vals[z]; LDKC2Tuple_u32TxOutZ _res_conv_25_conv = *(LDKC2Tuple_u32TxOutZ*)(((uint64_t)_res_conv_25) & ~1); FREE((void*)_res_conv_25); _res_constr.data[z] = _res_conv_25_conv; } CVec_C2Tuple_u32TxOutZZ_free(_res_constr); } uint32_t __attribute__((visibility("default"))) TS_C2Tuple_TxidCVec_C2Tuple_u32TxOutZZZ_clone(uint32_t orig) { LDKC2Tuple_TxidCVec_C2Tuple_u32TxOutZZZ* orig_conv = (LDKC2Tuple_TxidCVec_C2Tuple_u32TxOutZZZ*)(orig & ~1); LDKC2Tuple_TxidCVec_C2Tuple_u32TxOutZZZ* ret_ref = MALLOC(sizeof(LDKC2Tuple_TxidCVec_C2Tuple_u32TxOutZZZ), "LDKC2Tuple_TxidCVec_C2Tuple_u32TxOutZZZ"); *ret_ref = C2Tuple_TxidCVec_C2Tuple_u32TxOutZZZ_clone(orig_conv); return (uint64_t)ret_ref; } uint32_t __attribute__((visibility("default"))) TS_C2Tuple_TxidCVec_C2Tuple_u32TxOutZZZ_new(int8_tArray a, uint32_tArray b) { LDKThirtyTwoBytes a_ref; CHECK(*((uint32_t*)a) == 32); memcpy(a_ref.data, (uint8_t*)(a + 4), 32); LDKCVec_C2Tuple_u32TxOutZZ b_constr; b_constr.datalen = *((uint32_t*)b); if (b_constr.datalen > 0) b_constr.data = MALLOC(b_constr.datalen * sizeof(LDKC2Tuple_u32TxOutZ), "LDKCVec_C2Tuple_u32TxOutZZ Elements"); else b_constr.data = NULL; uint32_t* b_vals = (uint32_t*)(b + 4); for (size_t z = 0; z < b_constr.datalen; z++) { uint32_t b_conv_25 = b_vals[z]; LDKC2Tuple_u32TxOutZ b_conv_25_conv = *(LDKC2Tuple_u32TxOutZ*)(((uint64_t)b_conv_25) & ~1); b_conv_25_conv = C2Tuple_u32TxOutZ_clone((LDKC2Tuple_u32TxOutZ*)(((uint64_t)b_conv_25) & ~1)); b_constr.data[z] = b_conv_25_conv; } LDKC2Tuple_TxidCVec_C2Tuple_u32TxOutZZZ* ret_ref = MALLOC(sizeof(LDKC2Tuple_TxidCVec_C2Tuple_u32TxOutZZZ), "LDKC2Tuple_TxidCVec_C2Tuple_u32TxOutZZZ"); *ret_ref = C2Tuple_TxidCVec_C2Tuple_u32TxOutZZZ_new(a_ref, b_constr); return (uint64_t)ret_ref; } void __attribute__((visibility("default"))) TS_C2Tuple_TxidCVec_C2Tuple_u32TxOutZZZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKC2Tuple_TxidCVec_C2Tuple_u32TxOutZZZ _res_conv = *(LDKC2Tuple_TxidCVec_C2Tuple_u32TxOutZZZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); C2Tuple_TxidCVec_C2Tuple_u32TxOutZZZ_free(_res_conv); } void __attribute__((visibility("default"))) TS_CVec_C2Tuple_TxidCVec_C2Tuple_u32TxOutZZZZ_free(uint32_tArray _res) { LDKCVec_C2Tuple_TxidCVec_C2Tuple_u32TxOutZZZZ _res_constr; _res_constr.datalen = *((uint32_t*)_res); if (_res_constr.datalen > 0) _res_constr.data = MALLOC(_res_constr.datalen * sizeof(LDKC2Tuple_TxidCVec_C2Tuple_u32TxOutZZZ), "LDKCVec_C2Tuple_TxidCVec_C2Tuple_u32TxOutZZZZ Elements"); else _res_constr.data = NULL; uint32_t* _res_vals = (uint32_t*)(_res + 4); for (size_t x = 0; x < _res_constr.datalen; x++) { uint32_t _res_conv_49 = _res_vals[x]; LDKC2Tuple_TxidCVec_C2Tuple_u32TxOutZZZ _res_conv_49_conv = *(LDKC2Tuple_TxidCVec_C2Tuple_u32TxOutZZZ*)(((uint64_t)_res_conv_49) & ~1); FREE((void*)_res_conv_49); _res_constr.data[x] = _res_conv_49_conv; } CVec_C2Tuple_TxidCVec_C2Tuple_u32TxOutZZZZ_free(_res_constr); } void __attribute__((visibility("default"))) TS_CVec_BalanceZ_free(uint32_tArray _res) { LDKCVec_BalanceZ _res_constr; _res_constr.datalen = *((uint32_t*)_res); if (_res_constr.datalen > 0) _res_constr.data = MALLOC(_res_constr.datalen * sizeof(LDKBalance), "LDKCVec_BalanceZ Elements"); else _res_constr.data = NULL; uint32_t* _res_vals = (uint32_t*)(_res + 4); for (size_t j = 0; j < _res_constr.datalen; j++) { uint32_t _res_conv_9 = _res_vals[j]; LDKBalance _res_conv_9_conv = *(LDKBalance*)(((uint64_t)_res_conv_9) & ~1); FREE((void*)_res_conv_9); _res_constr.data[j] = _res_conv_9_conv; } CVec_BalanceZ_free(_res_constr); } uint32_t __attribute__((visibility("default"))) TS_CResult_C2Tuple_BlockHashChannelMonitorZDecodeErrorZ_ok(uint32_t o) { LDKC2Tuple_BlockHashChannelMonitorZ o_conv = *(LDKC2Tuple_BlockHashChannelMonitorZ*)(((uint64_t)o) & ~1); // Warning: we may need a move here but no clone is available for LDKC2Tuple_BlockHashChannelMonitorZ LDKCResult_C2Tuple_BlockHashChannelMonitorZDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_C2Tuple_BlockHashChannelMonitorZDecodeErrorZ), "LDKCResult_C2Tuple_BlockHashChannelMonitorZDecodeErrorZ"); *ret_conv = CResult_C2Tuple_BlockHashChannelMonitorZDecodeErrorZ_ok(o_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_C2Tuple_BlockHashChannelMonitorZDecodeErrorZ_err(uint32_t e) { LDKDecodeError e_conv; e_conv.inner = (void*)(e & (~1)); e_conv.is_owned = (e & 1) || (e == 0); e_conv = DecodeError_clone(&e_conv); LDKCResult_C2Tuple_BlockHashChannelMonitorZDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_C2Tuple_BlockHashChannelMonitorZDecodeErrorZ), "LDKCResult_C2Tuple_BlockHashChannelMonitorZDecodeErrorZ"); *ret_conv = CResult_C2Tuple_BlockHashChannelMonitorZDecodeErrorZ_err(e_conv); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CResult_C2Tuple_BlockHashChannelMonitorZDecodeErrorZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCResult_C2Tuple_BlockHashChannelMonitorZDecodeErrorZ _res_conv = *(LDKCResult_C2Tuple_BlockHashChannelMonitorZDecodeErrorZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); CResult_C2Tuple_BlockHashChannelMonitorZDecodeErrorZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_CResult_NoneLightningErrorZ_ok() { LDKCResult_NoneLightningErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_NoneLightningErrorZ), "LDKCResult_NoneLightningErrorZ"); *ret_conv = CResult_NoneLightningErrorZ_ok(); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_NoneLightningErrorZ_err(uint32_t e) { LDKLightningError e_conv; e_conv.inner = (void*)(e & (~1)); e_conv.is_owned = (e & 1) || (e == 0); e_conv = LightningError_clone(&e_conv); LDKCResult_NoneLightningErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_NoneLightningErrorZ), "LDKCResult_NoneLightningErrorZ"); *ret_conv = CResult_NoneLightningErrorZ_err(e_conv); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CResult_NoneLightningErrorZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCResult_NoneLightningErrorZ _res_conv = *(LDKCResult_NoneLightningErrorZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); CResult_NoneLightningErrorZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_CResult_NoneLightningErrorZ_clone(uint32_t orig) { LDKCResult_NoneLightningErrorZ* orig_conv = (LDKCResult_NoneLightningErrorZ*)(orig & ~1); LDKCResult_NoneLightningErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_NoneLightningErrorZ), "LDKCResult_NoneLightningErrorZ"); *ret_conv = CResult_NoneLightningErrorZ_clone(orig_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_C2Tuple_PublicKeyTypeZ_clone(uint32_t orig) { LDKC2Tuple_PublicKeyTypeZ* orig_conv = (LDKC2Tuple_PublicKeyTypeZ*)(orig & ~1); LDKC2Tuple_PublicKeyTypeZ* ret_ref = MALLOC(sizeof(LDKC2Tuple_PublicKeyTypeZ), "LDKC2Tuple_PublicKeyTypeZ"); *ret_ref = C2Tuple_PublicKeyTypeZ_clone(orig_conv); return (uint64_t)ret_ref; } uint32_t __attribute__((visibility("default"))) TS_C2Tuple_PublicKeyTypeZ_new(int8_tArray a, uint32_t b) { LDKPublicKey a_ref; CHECK(*((uint32_t*)a) == 33); memcpy(a_ref.compressed_form, (uint8_t*)(a + 4), 33); LDKType b_conv = *(LDKType*)(((uint64_t)b) & ~1); LDKC2Tuple_PublicKeyTypeZ* ret_ref = MALLOC(sizeof(LDKC2Tuple_PublicKeyTypeZ), "LDKC2Tuple_PublicKeyTypeZ"); *ret_ref = C2Tuple_PublicKeyTypeZ_new(a_ref, b_conv); return (uint64_t)ret_ref; } void __attribute__((visibility("default"))) TS_C2Tuple_PublicKeyTypeZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKC2Tuple_PublicKeyTypeZ _res_conv = *(LDKC2Tuple_PublicKeyTypeZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); C2Tuple_PublicKeyTypeZ_free(_res_conv); } void __attribute__((visibility("default"))) TS_CVec_C2Tuple_PublicKeyTypeZZ_free(uint32_tArray _res) { LDKCVec_C2Tuple_PublicKeyTypeZZ _res_constr; _res_constr.datalen = *((uint32_t*)_res); if (_res_constr.datalen > 0) _res_constr.data = MALLOC(_res_constr.datalen * sizeof(LDKC2Tuple_PublicKeyTypeZ), "LDKCVec_C2Tuple_PublicKeyTypeZZ Elements"); else _res_constr.data = NULL; uint32_t* _res_vals = (uint32_t*)(_res + 4); for (size_t c = 0; c < _res_constr.datalen; c++) { uint32_t _res_conv_28 = _res_vals[c]; LDKC2Tuple_PublicKeyTypeZ _res_conv_28_conv = *(LDKC2Tuple_PublicKeyTypeZ*)(((uint64_t)_res_conv_28) & ~1); FREE((void*)_res_conv_28); _res_constr.data[c] = _res_conv_28_conv; } CVec_C2Tuple_PublicKeyTypeZZ_free(_res_constr); } uint32_t __attribute__((visibility("default"))) TS_CResult_boolLightningErrorZ_ok(jboolean o) { LDKCResult_boolLightningErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_boolLightningErrorZ), "LDKCResult_boolLightningErrorZ"); *ret_conv = CResult_boolLightningErrorZ_ok(o); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_boolLightningErrorZ_err(uint32_t e) { LDKLightningError e_conv; e_conv.inner = (void*)(e & (~1)); e_conv.is_owned = (e & 1) || (e == 0); e_conv = LightningError_clone(&e_conv); LDKCResult_boolLightningErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_boolLightningErrorZ), "LDKCResult_boolLightningErrorZ"); *ret_conv = CResult_boolLightningErrorZ_err(e_conv); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CResult_boolLightningErrorZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCResult_boolLightningErrorZ _res_conv = *(LDKCResult_boolLightningErrorZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); CResult_boolLightningErrorZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_CResult_boolLightningErrorZ_clone(uint32_t orig) { LDKCResult_boolLightningErrorZ* orig_conv = (LDKCResult_boolLightningErrorZ*)(orig & ~1); LDKCResult_boolLightningErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_boolLightningErrorZ), "LDKCResult_boolLightningErrorZ"); *ret_conv = CResult_boolLightningErrorZ_clone(orig_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_C3Tuple_ChannelAnnouncementChannelUpdateChannelUpdateZ_clone(uint32_t orig) { LDKC3Tuple_ChannelAnnouncementChannelUpdateChannelUpdateZ* orig_conv = (LDKC3Tuple_ChannelAnnouncementChannelUpdateChannelUpdateZ*)(orig & ~1); LDKC3Tuple_ChannelAnnouncementChannelUpdateChannelUpdateZ* ret_ref = MALLOC(sizeof(LDKC3Tuple_ChannelAnnouncementChannelUpdateChannelUpdateZ), "LDKC3Tuple_ChannelAnnouncementChannelUpdateChannelUpdateZ"); *ret_ref = C3Tuple_ChannelAnnouncementChannelUpdateChannelUpdateZ_clone(orig_conv); return (uint64_t)ret_ref; } uint32_t __attribute__((visibility("default"))) TS_C3Tuple_ChannelAnnouncementChannelUpdateChannelUpdateZ_new(uint32_t a, uint32_t b, uint32_t c) { LDKChannelAnnouncement a_conv; a_conv.inner = (void*)(a & (~1)); a_conv.is_owned = (a & 1) || (a == 0); a_conv = ChannelAnnouncement_clone(&a_conv); LDKChannelUpdate b_conv; b_conv.inner = (void*)(b & (~1)); b_conv.is_owned = (b & 1) || (b == 0); b_conv = ChannelUpdate_clone(&b_conv); LDKChannelUpdate c_conv; c_conv.inner = (void*)(c & (~1)); c_conv.is_owned = (c & 1) || (c == 0); c_conv = ChannelUpdate_clone(&c_conv); LDKC3Tuple_ChannelAnnouncementChannelUpdateChannelUpdateZ* ret_ref = MALLOC(sizeof(LDKC3Tuple_ChannelAnnouncementChannelUpdateChannelUpdateZ), "LDKC3Tuple_ChannelAnnouncementChannelUpdateChannelUpdateZ"); *ret_ref = C3Tuple_ChannelAnnouncementChannelUpdateChannelUpdateZ_new(a_conv, b_conv, c_conv); return (uint64_t)ret_ref; } void __attribute__((visibility("default"))) TS_C3Tuple_ChannelAnnouncementChannelUpdateChannelUpdateZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKC3Tuple_ChannelAnnouncementChannelUpdateChannelUpdateZ _res_conv = *(LDKC3Tuple_ChannelAnnouncementChannelUpdateChannelUpdateZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); C3Tuple_ChannelAnnouncementChannelUpdateChannelUpdateZ_free(_res_conv); } void __attribute__((visibility("default"))) TS_CVec_C3Tuple_ChannelAnnouncementChannelUpdateChannelUpdateZZ_free(uint32_tArray _res) { LDKCVec_C3Tuple_ChannelAnnouncementChannelUpdateChannelUpdateZZ _res_constr; _res_constr.datalen = *((uint32_t*)_res); if (_res_constr.datalen > 0) _res_constr.data = MALLOC(_res_constr.datalen * sizeof(LDKC3Tuple_ChannelAnnouncementChannelUpdateChannelUpdateZ), "LDKCVec_C3Tuple_ChannelAnnouncementChannelUpdateChannelUpdateZZ Elements"); else _res_constr.data = NULL; uint32_t* _res_vals = (uint32_t*)(_res + 4); for (size_t l = 0; l < _res_constr.datalen; l++) { uint32_t _res_conv_63 = _res_vals[l]; LDKC3Tuple_ChannelAnnouncementChannelUpdateChannelUpdateZ _res_conv_63_conv = *(LDKC3Tuple_ChannelAnnouncementChannelUpdateChannelUpdateZ*)(((uint64_t)_res_conv_63) & ~1); FREE((void*)_res_conv_63); _res_constr.data[l] = _res_conv_63_conv; } CVec_C3Tuple_ChannelAnnouncementChannelUpdateChannelUpdateZZ_free(_res_constr); } void __attribute__((visibility("default"))) TS_CVec_NodeAnnouncementZ_free(uint32_tArray _res) { LDKCVec_NodeAnnouncementZ _res_constr; _res_constr.datalen = *((uint32_t*)_res); if (_res_constr.datalen > 0) _res_constr.data = MALLOC(_res_constr.datalen * sizeof(LDKNodeAnnouncement), "LDKCVec_NodeAnnouncementZ Elements"); else _res_constr.data = NULL; uint32_t* _res_vals = (uint32_t*)(_res + 4); for (size_t s = 0; s < _res_constr.datalen; s++) { uint32_t _res_conv_18 = _res_vals[s]; LDKNodeAnnouncement _res_conv_18_conv; _res_conv_18_conv.inner = (void*)(_res_conv_18 & (~1)); _res_conv_18_conv.is_owned = (_res_conv_18 & 1) || (_res_conv_18 == 0); _res_constr.data[s] = _res_conv_18_conv; } CVec_NodeAnnouncementZ_free(_res_constr); } void __attribute__((visibility("default"))) TS_CVec_PublicKeyZ_free(ptrArray _res) { LDKCVec_PublicKeyZ _res_constr; _res_constr.datalen = *((uint32_t*)_res); if (_res_constr.datalen > 0) _res_constr.data = MALLOC(_res_constr.datalen * sizeof(LDKPublicKey), "LDKCVec_PublicKeyZ Elements"); else _res_constr.data = NULL; int8_tArray* _res_vals = (int8_tArray*)(_res + 4); for (size_t m = 0; m < _res_constr.datalen; m++) { int8_tArray _res_conv_12 = _res_vals[m]; LDKPublicKey _res_conv_12_ref; CHECK(*((uint32_t*)_res_conv_12) == 33); memcpy(_res_conv_12_ref.compressed_form, (uint8_t*)(_res_conv_12 + 4), 33); _res_constr.data[m] = _res_conv_12_ref; } CVec_PublicKeyZ_free(_res_constr); } uint32_t __attribute__((visibility("default"))) TS_CResult_CVec_u8ZPeerHandleErrorZ_ok(int8_tArray o) { LDKCVec_u8Z o_ref; o_ref.datalen = *((uint32_t*)o); o_ref.data = MALLOC(o_ref.datalen, "LDKCVec_u8Z Bytes"); memcpy(o_ref.data, (uint8_t*)(o + 4), o_ref.datalen); LDKCResult_CVec_u8ZPeerHandleErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_CVec_u8ZPeerHandleErrorZ), "LDKCResult_CVec_u8ZPeerHandleErrorZ"); *ret_conv = CResult_CVec_u8ZPeerHandleErrorZ_ok(o_ref); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_CVec_u8ZPeerHandleErrorZ_err(uint32_t e) { LDKPeerHandleError e_conv; e_conv.inner = (void*)(e & (~1)); e_conv.is_owned = (e & 1) || (e == 0); e_conv = PeerHandleError_clone(&e_conv); LDKCResult_CVec_u8ZPeerHandleErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_CVec_u8ZPeerHandleErrorZ), "LDKCResult_CVec_u8ZPeerHandleErrorZ"); *ret_conv = CResult_CVec_u8ZPeerHandleErrorZ_err(e_conv); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CResult_CVec_u8ZPeerHandleErrorZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCResult_CVec_u8ZPeerHandleErrorZ _res_conv = *(LDKCResult_CVec_u8ZPeerHandleErrorZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); CResult_CVec_u8ZPeerHandleErrorZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_CResult_CVec_u8ZPeerHandleErrorZ_clone(uint32_t orig) { LDKCResult_CVec_u8ZPeerHandleErrorZ* orig_conv = (LDKCResult_CVec_u8ZPeerHandleErrorZ*)(orig & ~1); LDKCResult_CVec_u8ZPeerHandleErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_CVec_u8ZPeerHandleErrorZ), "LDKCResult_CVec_u8ZPeerHandleErrorZ"); *ret_conv = CResult_CVec_u8ZPeerHandleErrorZ_clone(orig_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_NonePeerHandleErrorZ_ok() { LDKCResult_NonePeerHandleErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_NonePeerHandleErrorZ), "LDKCResult_NonePeerHandleErrorZ"); *ret_conv = CResult_NonePeerHandleErrorZ_ok(); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_NonePeerHandleErrorZ_err(uint32_t e) { LDKPeerHandleError e_conv; e_conv.inner = (void*)(e & (~1)); e_conv.is_owned = (e & 1) || (e == 0); e_conv = PeerHandleError_clone(&e_conv); LDKCResult_NonePeerHandleErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_NonePeerHandleErrorZ), "LDKCResult_NonePeerHandleErrorZ"); *ret_conv = CResult_NonePeerHandleErrorZ_err(e_conv); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CResult_NonePeerHandleErrorZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCResult_NonePeerHandleErrorZ _res_conv = *(LDKCResult_NonePeerHandleErrorZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); CResult_NonePeerHandleErrorZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_CResult_NonePeerHandleErrorZ_clone(uint32_t orig) { LDKCResult_NonePeerHandleErrorZ* orig_conv = (LDKCResult_NonePeerHandleErrorZ*)(orig & ~1); LDKCResult_NonePeerHandleErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_NonePeerHandleErrorZ), "LDKCResult_NonePeerHandleErrorZ"); *ret_conv = CResult_NonePeerHandleErrorZ_clone(orig_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_boolPeerHandleErrorZ_ok(jboolean o) { LDKCResult_boolPeerHandleErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_boolPeerHandleErrorZ), "LDKCResult_boolPeerHandleErrorZ"); *ret_conv = CResult_boolPeerHandleErrorZ_ok(o); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_boolPeerHandleErrorZ_err(uint32_t e) { LDKPeerHandleError e_conv; e_conv.inner = (void*)(e & (~1)); e_conv.is_owned = (e & 1) || (e == 0); e_conv = PeerHandleError_clone(&e_conv); LDKCResult_boolPeerHandleErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_boolPeerHandleErrorZ), "LDKCResult_boolPeerHandleErrorZ"); *ret_conv = CResult_boolPeerHandleErrorZ_err(e_conv); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CResult_boolPeerHandleErrorZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCResult_boolPeerHandleErrorZ _res_conv = *(LDKCResult_boolPeerHandleErrorZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); CResult_boolPeerHandleErrorZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_CResult_boolPeerHandleErrorZ_clone(uint32_t orig) { LDKCResult_boolPeerHandleErrorZ* orig_conv = (LDKCResult_boolPeerHandleErrorZ*)(orig & ~1); LDKCResult_boolPeerHandleErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_boolPeerHandleErrorZ), "LDKCResult_boolPeerHandleErrorZ"); *ret_conv = CResult_boolPeerHandleErrorZ_clone(orig_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_COption_AccessZ_some(uint32_t o) { LDKAccess o_conv = *(LDKAccess*)(((uint64_t)o) & ~1); LDKCOption_AccessZ *ret_copy = MALLOC(sizeof(LDKCOption_AccessZ), "LDKCOption_AccessZ"); *ret_copy = COption_AccessZ_some(o_conv); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_COption_AccessZ_none() { LDKCOption_AccessZ *ret_copy = MALLOC(sizeof(LDKCOption_AccessZ), "LDKCOption_AccessZ"); *ret_copy = COption_AccessZ_none(); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } void __attribute__((visibility("default"))) TS_COption_AccessZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCOption_AccessZ _res_conv = *(LDKCOption_AccessZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); COption_AccessZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_CResult_DirectionalChannelInfoDecodeErrorZ_ok(uint32_t o) { LDKDirectionalChannelInfo o_conv; o_conv.inner = (void*)(o & (~1)); o_conv.is_owned = (o & 1) || (o == 0); o_conv = DirectionalChannelInfo_clone(&o_conv); LDKCResult_DirectionalChannelInfoDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_DirectionalChannelInfoDecodeErrorZ), "LDKCResult_DirectionalChannelInfoDecodeErrorZ"); *ret_conv = CResult_DirectionalChannelInfoDecodeErrorZ_ok(o_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_DirectionalChannelInfoDecodeErrorZ_err(uint32_t e) { LDKDecodeError e_conv; e_conv.inner = (void*)(e & (~1)); e_conv.is_owned = (e & 1) || (e == 0); e_conv = DecodeError_clone(&e_conv); LDKCResult_DirectionalChannelInfoDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_DirectionalChannelInfoDecodeErrorZ), "LDKCResult_DirectionalChannelInfoDecodeErrorZ"); *ret_conv = CResult_DirectionalChannelInfoDecodeErrorZ_err(e_conv); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CResult_DirectionalChannelInfoDecodeErrorZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCResult_DirectionalChannelInfoDecodeErrorZ _res_conv = *(LDKCResult_DirectionalChannelInfoDecodeErrorZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); CResult_DirectionalChannelInfoDecodeErrorZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_CResult_DirectionalChannelInfoDecodeErrorZ_clone(uint32_t orig) { LDKCResult_DirectionalChannelInfoDecodeErrorZ* orig_conv = (LDKCResult_DirectionalChannelInfoDecodeErrorZ*)(orig & ~1); LDKCResult_DirectionalChannelInfoDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_DirectionalChannelInfoDecodeErrorZ), "LDKCResult_DirectionalChannelInfoDecodeErrorZ"); *ret_conv = CResult_DirectionalChannelInfoDecodeErrorZ_clone(orig_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_ChannelInfoDecodeErrorZ_ok(uint32_t o) { LDKChannelInfo o_conv; o_conv.inner = (void*)(o & (~1)); o_conv.is_owned = (o & 1) || (o == 0); o_conv = ChannelInfo_clone(&o_conv); LDKCResult_ChannelInfoDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_ChannelInfoDecodeErrorZ), "LDKCResult_ChannelInfoDecodeErrorZ"); *ret_conv = CResult_ChannelInfoDecodeErrorZ_ok(o_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_ChannelInfoDecodeErrorZ_err(uint32_t e) { LDKDecodeError e_conv; e_conv.inner = (void*)(e & (~1)); e_conv.is_owned = (e & 1) || (e == 0); e_conv = DecodeError_clone(&e_conv); LDKCResult_ChannelInfoDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_ChannelInfoDecodeErrorZ), "LDKCResult_ChannelInfoDecodeErrorZ"); *ret_conv = CResult_ChannelInfoDecodeErrorZ_err(e_conv); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CResult_ChannelInfoDecodeErrorZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCResult_ChannelInfoDecodeErrorZ _res_conv = *(LDKCResult_ChannelInfoDecodeErrorZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); CResult_ChannelInfoDecodeErrorZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_CResult_ChannelInfoDecodeErrorZ_clone(uint32_t orig) { LDKCResult_ChannelInfoDecodeErrorZ* orig_conv = (LDKCResult_ChannelInfoDecodeErrorZ*)(orig & ~1); LDKCResult_ChannelInfoDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_ChannelInfoDecodeErrorZ), "LDKCResult_ChannelInfoDecodeErrorZ"); *ret_conv = CResult_ChannelInfoDecodeErrorZ_clone(orig_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_RoutingFeesDecodeErrorZ_ok(uint32_t o) { LDKRoutingFees o_conv; o_conv.inner = (void*)(o & (~1)); o_conv.is_owned = (o & 1) || (o == 0); o_conv = RoutingFees_clone(&o_conv); LDKCResult_RoutingFeesDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_RoutingFeesDecodeErrorZ), "LDKCResult_RoutingFeesDecodeErrorZ"); *ret_conv = CResult_RoutingFeesDecodeErrorZ_ok(o_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_RoutingFeesDecodeErrorZ_err(uint32_t e) { LDKDecodeError e_conv; e_conv.inner = (void*)(e & (~1)); e_conv.is_owned = (e & 1) || (e == 0); e_conv = DecodeError_clone(&e_conv); LDKCResult_RoutingFeesDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_RoutingFeesDecodeErrorZ), "LDKCResult_RoutingFeesDecodeErrorZ"); *ret_conv = CResult_RoutingFeesDecodeErrorZ_err(e_conv); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CResult_RoutingFeesDecodeErrorZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCResult_RoutingFeesDecodeErrorZ _res_conv = *(LDKCResult_RoutingFeesDecodeErrorZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); CResult_RoutingFeesDecodeErrorZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_CResult_RoutingFeesDecodeErrorZ_clone(uint32_t orig) { LDKCResult_RoutingFeesDecodeErrorZ* orig_conv = (LDKCResult_RoutingFeesDecodeErrorZ*)(orig & ~1); LDKCResult_RoutingFeesDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_RoutingFeesDecodeErrorZ), "LDKCResult_RoutingFeesDecodeErrorZ"); *ret_conv = CResult_RoutingFeesDecodeErrorZ_clone(orig_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_NodeAnnouncementInfoDecodeErrorZ_ok(uint32_t o) { LDKNodeAnnouncementInfo o_conv; o_conv.inner = (void*)(o & (~1)); o_conv.is_owned = (o & 1) || (o == 0); o_conv = NodeAnnouncementInfo_clone(&o_conv); LDKCResult_NodeAnnouncementInfoDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_NodeAnnouncementInfoDecodeErrorZ), "LDKCResult_NodeAnnouncementInfoDecodeErrorZ"); *ret_conv = CResult_NodeAnnouncementInfoDecodeErrorZ_ok(o_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_NodeAnnouncementInfoDecodeErrorZ_err(uint32_t e) { LDKDecodeError e_conv; e_conv.inner = (void*)(e & (~1)); e_conv.is_owned = (e & 1) || (e == 0); e_conv = DecodeError_clone(&e_conv); LDKCResult_NodeAnnouncementInfoDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_NodeAnnouncementInfoDecodeErrorZ), "LDKCResult_NodeAnnouncementInfoDecodeErrorZ"); *ret_conv = CResult_NodeAnnouncementInfoDecodeErrorZ_err(e_conv); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CResult_NodeAnnouncementInfoDecodeErrorZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCResult_NodeAnnouncementInfoDecodeErrorZ _res_conv = *(LDKCResult_NodeAnnouncementInfoDecodeErrorZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); CResult_NodeAnnouncementInfoDecodeErrorZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_CResult_NodeAnnouncementInfoDecodeErrorZ_clone(uint32_t orig) { LDKCResult_NodeAnnouncementInfoDecodeErrorZ* orig_conv = (LDKCResult_NodeAnnouncementInfoDecodeErrorZ*)(orig & ~1); LDKCResult_NodeAnnouncementInfoDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_NodeAnnouncementInfoDecodeErrorZ), "LDKCResult_NodeAnnouncementInfoDecodeErrorZ"); *ret_conv = CResult_NodeAnnouncementInfoDecodeErrorZ_clone(orig_conv); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CVec_u64Z_free(int64_tArray _res) { LDKCVec_u64Z _res_constr; _res_constr.datalen = *((uint32_t*)_res); if (_res_constr.datalen > 0) _res_constr.data = MALLOC(_res_constr.datalen * sizeof(int64_t), "LDKCVec_u64Z Elements"); else _res_constr.data = NULL; int64_t* _res_vals = (int64_t*)(_res + 4); for (size_t i = 0; i < _res_constr.datalen; i++) { int64_t _res_conv_8 = _res_vals[i]; _res_constr.data[i] = _res_conv_8; } CVec_u64Z_free(_res_constr); } uint32_t __attribute__((visibility("default"))) TS_CResult_NodeInfoDecodeErrorZ_ok(uint32_t o) { LDKNodeInfo o_conv; o_conv.inner = (void*)(o & (~1)); o_conv.is_owned = (o & 1) || (o == 0); o_conv = NodeInfo_clone(&o_conv); LDKCResult_NodeInfoDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_NodeInfoDecodeErrorZ), "LDKCResult_NodeInfoDecodeErrorZ"); *ret_conv = CResult_NodeInfoDecodeErrorZ_ok(o_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_NodeInfoDecodeErrorZ_err(uint32_t e) { LDKDecodeError e_conv; e_conv.inner = (void*)(e & (~1)); e_conv.is_owned = (e & 1) || (e == 0); e_conv = DecodeError_clone(&e_conv); LDKCResult_NodeInfoDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_NodeInfoDecodeErrorZ), "LDKCResult_NodeInfoDecodeErrorZ"); *ret_conv = CResult_NodeInfoDecodeErrorZ_err(e_conv); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CResult_NodeInfoDecodeErrorZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCResult_NodeInfoDecodeErrorZ _res_conv = *(LDKCResult_NodeInfoDecodeErrorZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); CResult_NodeInfoDecodeErrorZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_CResult_NodeInfoDecodeErrorZ_clone(uint32_t orig) { LDKCResult_NodeInfoDecodeErrorZ* orig_conv = (LDKCResult_NodeInfoDecodeErrorZ*)(orig & ~1); LDKCResult_NodeInfoDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_NodeInfoDecodeErrorZ), "LDKCResult_NodeInfoDecodeErrorZ"); *ret_conv = CResult_NodeInfoDecodeErrorZ_clone(orig_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_NetworkGraphDecodeErrorZ_ok(uint32_t o) { LDKNetworkGraph o_conv; o_conv.inner = (void*)(o & (~1)); o_conv.is_owned = (o & 1) || (o == 0); // Warning: we need a move here but no clone is available for LDKNetworkGraph LDKCResult_NetworkGraphDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_NetworkGraphDecodeErrorZ), "LDKCResult_NetworkGraphDecodeErrorZ"); *ret_conv = CResult_NetworkGraphDecodeErrorZ_ok(o_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_NetworkGraphDecodeErrorZ_err(uint32_t e) { LDKDecodeError e_conv; e_conv.inner = (void*)(e & (~1)); e_conv.is_owned = (e & 1) || (e == 0); e_conv = DecodeError_clone(&e_conv); LDKCResult_NetworkGraphDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_NetworkGraphDecodeErrorZ), "LDKCResult_NetworkGraphDecodeErrorZ"); *ret_conv = CResult_NetworkGraphDecodeErrorZ_err(e_conv); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CResult_NetworkGraphDecodeErrorZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCResult_NetworkGraphDecodeErrorZ _res_conv = *(LDKCResult_NetworkGraphDecodeErrorZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); CResult_NetworkGraphDecodeErrorZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_CResult_NetAddressu8Z_ok(uint32_t o) { LDKNetAddress o_conv = *(LDKNetAddress*)(((uint64_t)o) & ~1); o_conv = NetAddress_clone((LDKNetAddress*)(((uint64_t)o) & ~1)); LDKCResult_NetAddressu8Z* ret_conv = MALLOC(sizeof(LDKCResult_NetAddressu8Z), "LDKCResult_NetAddressu8Z"); *ret_conv = CResult_NetAddressu8Z_ok(o_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_NetAddressu8Z_err(int8_t e) { LDKCResult_NetAddressu8Z* ret_conv = MALLOC(sizeof(LDKCResult_NetAddressu8Z), "LDKCResult_NetAddressu8Z"); *ret_conv = CResult_NetAddressu8Z_err(e); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CResult_NetAddressu8Z_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCResult_NetAddressu8Z _res_conv = *(LDKCResult_NetAddressu8Z*)(((uint64_t)_res) & ~1); FREE((void*)_res); CResult_NetAddressu8Z_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_CResult_NetAddressu8Z_clone(uint32_t orig) { LDKCResult_NetAddressu8Z* orig_conv = (LDKCResult_NetAddressu8Z*)(orig & ~1); LDKCResult_NetAddressu8Z* ret_conv = MALLOC(sizeof(LDKCResult_NetAddressu8Z), "LDKCResult_NetAddressu8Z"); *ret_conv = CResult_NetAddressu8Z_clone(orig_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_CResult_NetAddressu8ZDecodeErrorZ_ok(uint32_t o) { LDKCResult_NetAddressu8Z o_conv = *(LDKCResult_NetAddressu8Z*)(((uint64_t)o) & ~1); o_conv = CResult_NetAddressu8Z_clone((LDKCResult_NetAddressu8Z*)(((uint64_t)o) & ~1)); LDKCResult_CResult_NetAddressu8ZDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_CResult_NetAddressu8ZDecodeErrorZ), "LDKCResult_CResult_NetAddressu8ZDecodeErrorZ"); *ret_conv = CResult_CResult_NetAddressu8ZDecodeErrorZ_ok(o_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_CResult_NetAddressu8ZDecodeErrorZ_err(uint32_t e) { LDKDecodeError e_conv; e_conv.inner = (void*)(e & (~1)); e_conv.is_owned = (e & 1) || (e == 0); e_conv = DecodeError_clone(&e_conv); LDKCResult_CResult_NetAddressu8ZDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_CResult_NetAddressu8ZDecodeErrorZ), "LDKCResult_CResult_NetAddressu8ZDecodeErrorZ"); *ret_conv = CResult_CResult_NetAddressu8ZDecodeErrorZ_err(e_conv); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CResult_CResult_NetAddressu8ZDecodeErrorZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCResult_CResult_NetAddressu8ZDecodeErrorZ _res_conv = *(LDKCResult_CResult_NetAddressu8ZDecodeErrorZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); CResult_CResult_NetAddressu8ZDecodeErrorZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_CResult_CResult_NetAddressu8ZDecodeErrorZ_clone(uint32_t orig) { LDKCResult_CResult_NetAddressu8ZDecodeErrorZ* orig_conv = (LDKCResult_CResult_NetAddressu8ZDecodeErrorZ*)(orig & ~1); LDKCResult_CResult_NetAddressu8ZDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_CResult_NetAddressu8ZDecodeErrorZ), "LDKCResult_CResult_NetAddressu8ZDecodeErrorZ"); *ret_conv = CResult_CResult_NetAddressu8ZDecodeErrorZ_clone(orig_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_NetAddressDecodeErrorZ_ok(uint32_t o) { LDKNetAddress o_conv = *(LDKNetAddress*)(((uint64_t)o) & ~1); o_conv = NetAddress_clone((LDKNetAddress*)(((uint64_t)o) & ~1)); LDKCResult_NetAddressDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_NetAddressDecodeErrorZ), "LDKCResult_NetAddressDecodeErrorZ"); *ret_conv = CResult_NetAddressDecodeErrorZ_ok(o_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_NetAddressDecodeErrorZ_err(uint32_t e) { LDKDecodeError e_conv; e_conv.inner = (void*)(e & (~1)); e_conv.is_owned = (e & 1) || (e == 0); e_conv = DecodeError_clone(&e_conv); LDKCResult_NetAddressDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_NetAddressDecodeErrorZ), "LDKCResult_NetAddressDecodeErrorZ"); *ret_conv = CResult_NetAddressDecodeErrorZ_err(e_conv); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CResult_NetAddressDecodeErrorZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCResult_NetAddressDecodeErrorZ _res_conv = *(LDKCResult_NetAddressDecodeErrorZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); CResult_NetAddressDecodeErrorZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_CResult_NetAddressDecodeErrorZ_clone(uint32_t orig) { LDKCResult_NetAddressDecodeErrorZ* orig_conv = (LDKCResult_NetAddressDecodeErrorZ*)(orig & ~1); LDKCResult_NetAddressDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_NetAddressDecodeErrorZ), "LDKCResult_NetAddressDecodeErrorZ"); *ret_conv = CResult_NetAddressDecodeErrorZ_clone(orig_conv); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CVec_UpdateAddHTLCZ_free(uint32_tArray _res) { LDKCVec_UpdateAddHTLCZ _res_constr; _res_constr.datalen = *((uint32_t*)_res); if (_res_constr.datalen > 0) _res_constr.data = MALLOC(_res_constr.datalen * sizeof(LDKUpdateAddHTLC), "LDKCVec_UpdateAddHTLCZ Elements"); else _res_constr.data = NULL; uint32_t* _res_vals = (uint32_t*)(_res + 4); for (size_t p = 0; p < _res_constr.datalen; p++) { uint32_t _res_conv_15 = _res_vals[p]; LDKUpdateAddHTLC _res_conv_15_conv; _res_conv_15_conv.inner = (void*)(_res_conv_15 & (~1)); _res_conv_15_conv.is_owned = (_res_conv_15 & 1) || (_res_conv_15 == 0); _res_constr.data[p] = _res_conv_15_conv; } CVec_UpdateAddHTLCZ_free(_res_constr); } void __attribute__((visibility("default"))) TS_CVec_UpdateFulfillHTLCZ_free(uint32_tArray _res) { LDKCVec_UpdateFulfillHTLCZ _res_constr; _res_constr.datalen = *((uint32_t*)_res); if (_res_constr.datalen > 0) _res_constr.data = MALLOC(_res_constr.datalen * sizeof(LDKUpdateFulfillHTLC), "LDKCVec_UpdateFulfillHTLCZ Elements"); else _res_constr.data = NULL; uint32_t* _res_vals = (uint32_t*)(_res + 4); for (size_t t = 0; t < _res_constr.datalen; t++) { uint32_t _res_conv_19 = _res_vals[t]; LDKUpdateFulfillHTLC _res_conv_19_conv; _res_conv_19_conv.inner = (void*)(_res_conv_19 & (~1)); _res_conv_19_conv.is_owned = (_res_conv_19 & 1) || (_res_conv_19 == 0); _res_constr.data[t] = _res_conv_19_conv; } CVec_UpdateFulfillHTLCZ_free(_res_constr); } void __attribute__((visibility("default"))) TS_CVec_UpdateFailHTLCZ_free(uint32_tArray _res) { LDKCVec_UpdateFailHTLCZ _res_constr; _res_constr.datalen = *((uint32_t*)_res); if (_res_constr.datalen > 0) _res_constr.data = MALLOC(_res_constr.datalen * sizeof(LDKUpdateFailHTLC), "LDKCVec_UpdateFailHTLCZ Elements"); else _res_constr.data = NULL; uint32_t* _res_vals = (uint32_t*)(_res + 4); for (size_t q = 0; q < _res_constr.datalen; q++) { uint32_t _res_conv_16 = _res_vals[q]; LDKUpdateFailHTLC _res_conv_16_conv; _res_conv_16_conv.inner = (void*)(_res_conv_16 & (~1)); _res_conv_16_conv.is_owned = (_res_conv_16 & 1) || (_res_conv_16 == 0); _res_constr.data[q] = _res_conv_16_conv; } CVec_UpdateFailHTLCZ_free(_res_constr); } void __attribute__((visibility("default"))) TS_CVec_UpdateFailMalformedHTLCZ_free(uint32_tArray _res) { LDKCVec_UpdateFailMalformedHTLCZ _res_constr; _res_constr.datalen = *((uint32_t*)_res); if (_res_constr.datalen > 0) _res_constr.data = MALLOC(_res_constr.datalen * sizeof(LDKUpdateFailMalformedHTLC), "LDKCVec_UpdateFailMalformedHTLCZ Elements"); else _res_constr.data = NULL; uint32_t* _res_vals = (uint32_t*)(_res + 4); for (size_t z = 0; z < _res_constr.datalen; z++) { uint32_t _res_conv_25 = _res_vals[z]; LDKUpdateFailMalformedHTLC _res_conv_25_conv; _res_conv_25_conv.inner = (void*)(_res_conv_25 & (~1)); _res_conv_25_conv.is_owned = (_res_conv_25 & 1) || (_res_conv_25 == 0); _res_constr.data[z] = _res_conv_25_conv; } CVec_UpdateFailMalformedHTLCZ_free(_res_constr); } uint32_t __attribute__((visibility("default"))) TS_CResult_AcceptChannelDecodeErrorZ_ok(uint32_t o) { LDKAcceptChannel o_conv; o_conv.inner = (void*)(o & (~1)); o_conv.is_owned = (o & 1) || (o == 0); o_conv = AcceptChannel_clone(&o_conv); LDKCResult_AcceptChannelDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_AcceptChannelDecodeErrorZ), "LDKCResult_AcceptChannelDecodeErrorZ"); *ret_conv = CResult_AcceptChannelDecodeErrorZ_ok(o_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_AcceptChannelDecodeErrorZ_err(uint32_t e) { LDKDecodeError e_conv; e_conv.inner = (void*)(e & (~1)); e_conv.is_owned = (e & 1) || (e == 0); e_conv = DecodeError_clone(&e_conv); LDKCResult_AcceptChannelDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_AcceptChannelDecodeErrorZ), "LDKCResult_AcceptChannelDecodeErrorZ"); *ret_conv = CResult_AcceptChannelDecodeErrorZ_err(e_conv); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CResult_AcceptChannelDecodeErrorZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCResult_AcceptChannelDecodeErrorZ _res_conv = *(LDKCResult_AcceptChannelDecodeErrorZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); CResult_AcceptChannelDecodeErrorZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_CResult_AcceptChannelDecodeErrorZ_clone(uint32_t orig) { LDKCResult_AcceptChannelDecodeErrorZ* orig_conv = (LDKCResult_AcceptChannelDecodeErrorZ*)(orig & ~1); LDKCResult_AcceptChannelDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_AcceptChannelDecodeErrorZ), "LDKCResult_AcceptChannelDecodeErrorZ"); *ret_conv = CResult_AcceptChannelDecodeErrorZ_clone(orig_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_AnnouncementSignaturesDecodeErrorZ_ok(uint32_t o) { LDKAnnouncementSignatures o_conv; o_conv.inner = (void*)(o & (~1)); o_conv.is_owned = (o & 1) || (o == 0); o_conv = AnnouncementSignatures_clone(&o_conv); LDKCResult_AnnouncementSignaturesDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_AnnouncementSignaturesDecodeErrorZ), "LDKCResult_AnnouncementSignaturesDecodeErrorZ"); *ret_conv = CResult_AnnouncementSignaturesDecodeErrorZ_ok(o_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_AnnouncementSignaturesDecodeErrorZ_err(uint32_t e) { LDKDecodeError e_conv; e_conv.inner = (void*)(e & (~1)); e_conv.is_owned = (e & 1) || (e == 0); e_conv = DecodeError_clone(&e_conv); LDKCResult_AnnouncementSignaturesDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_AnnouncementSignaturesDecodeErrorZ), "LDKCResult_AnnouncementSignaturesDecodeErrorZ"); *ret_conv = CResult_AnnouncementSignaturesDecodeErrorZ_err(e_conv); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CResult_AnnouncementSignaturesDecodeErrorZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCResult_AnnouncementSignaturesDecodeErrorZ _res_conv = *(LDKCResult_AnnouncementSignaturesDecodeErrorZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); CResult_AnnouncementSignaturesDecodeErrorZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_CResult_AnnouncementSignaturesDecodeErrorZ_clone(uint32_t orig) { LDKCResult_AnnouncementSignaturesDecodeErrorZ* orig_conv = (LDKCResult_AnnouncementSignaturesDecodeErrorZ*)(orig & ~1); LDKCResult_AnnouncementSignaturesDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_AnnouncementSignaturesDecodeErrorZ), "LDKCResult_AnnouncementSignaturesDecodeErrorZ"); *ret_conv = CResult_AnnouncementSignaturesDecodeErrorZ_clone(orig_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_ChannelReestablishDecodeErrorZ_ok(uint32_t o) { LDKChannelReestablish o_conv; o_conv.inner = (void*)(o & (~1)); o_conv.is_owned = (o & 1) || (o == 0); o_conv = ChannelReestablish_clone(&o_conv); LDKCResult_ChannelReestablishDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_ChannelReestablishDecodeErrorZ), "LDKCResult_ChannelReestablishDecodeErrorZ"); *ret_conv = CResult_ChannelReestablishDecodeErrorZ_ok(o_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_ChannelReestablishDecodeErrorZ_err(uint32_t e) { LDKDecodeError e_conv; e_conv.inner = (void*)(e & (~1)); e_conv.is_owned = (e & 1) || (e == 0); e_conv = DecodeError_clone(&e_conv); LDKCResult_ChannelReestablishDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_ChannelReestablishDecodeErrorZ), "LDKCResult_ChannelReestablishDecodeErrorZ"); *ret_conv = CResult_ChannelReestablishDecodeErrorZ_err(e_conv); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CResult_ChannelReestablishDecodeErrorZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCResult_ChannelReestablishDecodeErrorZ _res_conv = *(LDKCResult_ChannelReestablishDecodeErrorZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); CResult_ChannelReestablishDecodeErrorZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_CResult_ChannelReestablishDecodeErrorZ_clone(uint32_t orig) { LDKCResult_ChannelReestablishDecodeErrorZ* orig_conv = (LDKCResult_ChannelReestablishDecodeErrorZ*)(orig & ~1); LDKCResult_ChannelReestablishDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_ChannelReestablishDecodeErrorZ), "LDKCResult_ChannelReestablishDecodeErrorZ"); *ret_conv = CResult_ChannelReestablishDecodeErrorZ_clone(orig_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_ClosingSignedDecodeErrorZ_ok(uint32_t o) { LDKClosingSigned o_conv; o_conv.inner = (void*)(o & (~1)); o_conv.is_owned = (o & 1) || (o == 0); o_conv = ClosingSigned_clone(&o_conv); LDKCResult_ClosingSignedDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_ClosingSignedDecodeErrorZ), "LDKCResult_ClosingSignedDecodeErrorZ"); *ret_conv = CResult_ClosingSignedDecodeErrorZ_ok(o_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_ClosingSignedDecodeErrorZ_err(uint32_t e) { LDKDecodeError e_conv; e_conv.inner = (void*)(e & (~1)); e_conv.is_owned = (e & 1) || (e == 0); e_conv = DecodeError_clone(&e_conv); LDKCResult_ClosingSignedDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_ClosingSignedDecodeErrorZ), "LDKCResult_ClosingSignedDecodeErrorZ"); *ret_conv = CResult_ClosingSignedDecodeErrorZ_err(e_conv); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CResult_ClosingSignedDecodeErrorZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCResult_ClosingSignedDecodeErrorZ _res_conv = *(LDKCResult_ClosingSignedDecodeErrorZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); CResult_ClosingSignedDecodeErrorZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_CResult_ClosingSignedDecodeErrorZ_clone(uint32_t orig) { LDKCResult_ClosingSignedDecodeErrorZ* orig_conv = (LDKCResult_ClosingSignedDecodeErrorZ*)(orig & ~1); LDKCResult_ClosingSignedDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_ClosingSignedDecodeErrorZ), "LDKCResult_ClosingSignedDecodeErrorZ"); *ret_conv = CResult_ClosingSignedDecodeErrorZ_clone(orig_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_ClosingSignedFeeRangeDecodeErrorZ_ok(uint32_t o) { LDKClosingSignedFeeRange o_conv; o_conv.inner = (void*)(o & (~1)); o_conv.is_owned = (o & 1) || (o == 0); o_conv = ClosingSignedFeeRange_clone(&o_conv); LDKCResult_ClosingSignedFeeRangeDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_ClosingSignedFeeRangeDecodeErrorZ), "LDKCResult_ClosingSignedFeeRangeDecodeErrorZ"); *ret_conv = CResult_ClosingSignedFeeRangeDecodeErrorZ_ok(o_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_ClosingSignedFeeRangeDecodeErrorZ_err(uint32_t e) { LDKDecodeError e_conv; e_conv.inner = (void*)(e & (~1)); e_conv.is_owned = (e & 1) || (e == 0); e_conv = DecodeError_clone(&e_conv); LDKCResult_ClosingSignedFeeRangeDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_ClosingSignedFeeRangeDecodeErrorZ), "LDKCResult_ClosingSignedFeeRangeDecodeErrorZ"); *ret_conv = CResult_ClosingSignedFeeRangeDecodeErrorZ_err(e_conv); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CResult_ClosingSignedFeeRangeDecodeErrorZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCResult_ClosingSignedFeeRangeDecodeErrorZ _res_conv = *(LDKCResult_ClosingSignedFeeRangeDecodeErrorZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); CResult_ClosingSignedFeeRangeDecodeErrorZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_CResult_ClosingSignedFeeRangeDecodeErrorZ_clone(uint32_t orig) { LDKCResult_ClosingSignedFeeRangeDecodeErrorZ* orig_conv = (LDKCResult_ClosingSignedFeeRangeDecodeErrorZ*)(orig & ~1); LDKCResult_ClosingSignedFeeRangeDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_ClosingSignedFeeRangeDecodeErrorZ), "LDKCResult_ClosingSignedFeeRangeDecodeErrorZ"); *ret_conv = CResult_ClosingSignedFeeRangeDecodeErrorZ_clone(orig_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_CommitmentSignedDecodeErrorZ_ok(uint32_t o) { LDKCommitmentSigned o_conv; o_conv.inner = (void*)(o & (~1)); o_conv.is_owned = (o & 1) || (o == 0); o_conv = CommitmentSigned_clone(&o_conv); LDKCResult_CommitmentSignedDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_CommitmentSignedDecodeErrorZ), "LDKCResult_CommitmentSignedDecodeErrorZ"); *ret_conv = CResult_CommitmentSignedDecodeErrorZ_ok(o_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_CommitmentSignedDecodeErrorZ_err(uint32_t e) { LDKDecodeError e_conv; e_conv.inner = (void*)(e & (~1)); e_conv.is_owned = (e & 1) || (e == 0); e_conv = DecodeError_clone(&e_conv); LDKCResult_CommitmentSignedDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_CommitmentSignedDecodeErrorZ), "LDKCResult_CommitmentSignedDecodeErrorZ"); *ret_conv = CResult_CommitmentSignedDecodeErrorZ_err(e_conv); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CResult_CommitmentSignedDecodeErrorZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCResult_CommitmentSignedDecodeErrorZ _res_conv = *(LDKCResult_CommitmentSignedDecodeErrorZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); CResult_CommitmentSignedDecodeErrorZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_CResult_CommitmentSignedDecodeErrorZ_clone(uint32_t orig) { LDKCResult_CommitmentSignedDecodeErrorZ* orig_conv = (LDKCResult_CommitmentSignedDecodeErrorZ*)(orig & ~1); LDKCResult_CommitmentSignedDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_CommitmentSignedDecodeErrorZ), "LDKCResult_CommitmentSignedDecodeErrorZ"); *ret_conv = CResult_CommitmentSignedDecodeErrorZ_clone(orig_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_FundingCreatedDecodeErrorZ_ok(uint32_t o) { LDKFundingCreated o_conv; o_conv.inner = (void*)(o & (~1)); o_conv.is_owned = (o & 1) || (o == 0); o_conv = FundingCreated_clone(&o_conv); LDKCResult_FundingCreatedDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_FundingCreatedDecodeErrorZ), "LDKCResult_FundingCreatedDecodeErrorZ"); *ret_conv = CResult_FundingCreatedDecodeErrorZ_ok(o_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_FundingCreatedDecodeErrorZ_err(uint32_t e) { LDKDecodeError e_conv; e_conv.inner = (void*)(e & (~1)); e_conv.is_owned = (e & 1) || (e == 0); e_conv = DecodeError_clone(&e_conv); LDKCResult_FundingCreatedDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_FundingCreatedDecodeErrorZ), "LDKCResult_FundingCreatedDecodeErrorZ"); *ret_conv = CResult_FundingCreatedDecodeErrorZ_err(e_conv); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CResult_FundingCreatedDecodeErrorZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCResult_FundingCreatedDecodeErrorZ _res_conv = *(LDKCResult_FundingCreatedDecodeErrorZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); CResult_FundingCreatedDecodeErrorZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_CResult_FundingCreatedDecodeErrorZ_clone(uint32_t orig) { LDKCResult_FundingCreatedDecodeErrorZ* orig_conv = (LDKCResult_FundingCreatedDecodeErrorZ*)(orig & ~1); LDKCResult_FundingCreatedDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_FundingCreatedDecodeErrorZ), "LDKCResult_FundingCreatedDecodeErrorZ"); *ret_conv = CResult_FundingCreatedDecodeErrorZ_clone(orig_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_FundingSignedDecodeErrorZ_ok(uint32_t o) { LDKFundingSigned o_conv; o_conv.inner = (void*)(o & (~1)); o_conv.is_owned = (o & 1) || (o == 0); o_conv = FundingSigned_clone(&o_conv); LDKCResult_FundingSignedDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_FundingSignedDecodeErrorZ), "LDKCResult_FundingSignedDecodeErrorZ"); *ret_conv = CResult_FundingSignedDecodeErrorZ_ok(o_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_FundingSignedDecodeErrorZ_err(uint32_t e) { LDKDecodeError e_conv; e_conv.inner = (void*)(e & (~1)); e_conv.is_owned = (e & 1) || (e == 0); e_conv = DecodeError_clone(&e_conv); LDKCResult_FundingSignedDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_FundingSignedDecodeErrorZ), "LDKCResult_FundingSignedDecodeErrorZ"); *ret_conv = CResult_FundingSignedDecodeErrorZ_err(e_conv); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CResult_FundingSignedDecodeErrorZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCResult_FundingSignedDecodeErrorZ _res_conv = *(LDKCResult_FundingSignedDecodeErrorZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); CResult_FundingSignedDecodeErrorZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_CResult_FundingSignedDecodeErrorZ_clone(uint32_t orig) { LDKCResult_FundingSignedDecodeErrorZ* orig_conv = (LDKCResult_FundingSignedDecodeErrorZ*)(orig & ~1); LDKCResult_FundingSignedDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_FundingSignedDecodeErrorZ), "LDKCResult_FundingSignedDecodeErrorZ"); *ret_conv = CResult_FundingSignedDecodeErrorZ_clone(orig_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_FundingLockedDecodeErrorZ_ok(uint32_t o) { LDKFundingLocked o_conv; o_conv.inner = (void*)(o & (~1)); o_conv.is_owned = (o & 1) || (o == 0); o_conv = FundingLocked_clone(&o_conv); LDKCResult_FundingLockedDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_FundingLockedDecodeErrorZ), "LDKCResult_FundingLockedDecodeErrorZ"); *ret_conv = CResult_FundingLockedDecodeErrorZ_ok(o_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_FundingLockedDecodeErrorZ_err(uint32_t e) { LDKDecodeError e_conv; e_conv.inner = (void*)(e & (~1)); e_conv.is_owned = (e & 1) || (e == 0); e_conv = DecodeError_clone(&e_conv); LDKCResult_FundingLockedDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_FundingLockedDecodeErrorZ), "LDKCResult_FundingLockedDecodeErrorZ"); *ret_conv = CResult_FundingLockedDecodeErrorZ_err(e_conv); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CResult_FundingLockedDecodeErrorZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCResult_FundingLockedDecodeErrorZ _res_conv = *(LDKCResult_FundingLockedDecodeErrorZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); CResult_FundingLockedDecodeErrorZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_CResult_FundingLockedDecodeErrorZ_clone(uint32_t orig) { LDKCResult_FundingLockedDecodeErrorZ* orig_conv = (LDKCResult_FundingLockedDecodeErrorZ*)(orig & ~1); LDKCResult_FundingLockedDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_FundingLockedDecodeErrorZ), "LDKCResult_FundingLockedDecodeErrorZ"); *ret_conv = CResult_FundingLockedDecodeErrorZ_clone(orig_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_InitDecodeErrorZ_ok(uint32_t o) { LDKInit o_conv; o_conv.inner = (void*)(o & (~1)); o_conv.is_owned = (o & 1) || (o == 0); o_conv = Init_clone(&o_conv); LDKCResult_InitDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_InitDecodeErrorZ), "LDKCResult_InitDecodeErrorZ"); *ret_conv = CResult_InitDecodeErrorZ_ok(o_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_InitDecodeErrorZ_err(uint32_t e) { LDKDecodeError e_conv; e_conv.inner = (void*)(e & (~1)); e_conv.is_owned = (e & 1) || (e == 0); e_conv = DecodeError_clone(&e_conv); LDKCResult_InitDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_InitDecodeErrorZ), "LDKCResult_InitDecodeErrorZ"); *ret_conv = CResult_InitDecodeErrorZ_err(e_conv); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CResult_InitDecodeErrorZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCResult_InitDecodeErrorZ _res_conv = *(LDKCResult_InitDecodeErrorZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); CResult_InitDecodeErrorZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_CResult_InitDecodeErrorZ_clone(uint32_t orig) { LDKCResult_InitDecodeErrorZ* orig_conv = (LDKCResult_InitDecodeErrorZ*)(orig & ~1); LDKCResult_InitDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_InitDecodeErrorZ), "LDKCResult_InitDecodeErrorZ"); *ret_conv = CResult_InitDecodeErrorZ_clone(orig_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_OpenChannelDecodeErrorZ_ok(uint32_t o) { LDKOpenChannel o_conv; o_conv.inner = (void*)(o & (~1)); o_conv.is_owned = (o & 1) || (o == 0); o_conv = OpenChannel_clone(&o_conv); LDKCResult_OpenChannelDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_OpenChannelDecodeErrorZ), "LDKCResult_OpenChannelDecodeErrorZ"); *ret_conv = CResult_OpenChannelDecodeErrorZ_ok(o_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_OpenChannelDecodeErrorZ_err(uint32_t e) { LDKDecodeError e_conv; e_conv.inner = (void*)(e & (~1)); e_conv.is_owned = (e & 1) || (e == 0); e_conv = DecodeError_clone(&e_conv); LDKCResult_OpenChannelDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_OpenChannelDecodeErrorZ), "LDKCResult_OpenChannelDecodeErrorZ"); *ret_conv = CResult_OpenChannelDecodeErrorZ_err(e_conv); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CResult_OpenChannelDecodeErrorZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCResult_OpenChannelDecodeErrorZ _res_conv = *(LDKCResult_OpenChannelDecodeErrorZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); CResult_OpenChannelDecodeErrorZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_CResult_OpenChannelDecodeErrorZ_clone(uint32_t orig) { LDKCResult_OpenChannelDecodeErrorZ* orig_conv = (LDKCResult_OpenChannelDecodeErrorZ*)(orig & ~1); LDKCResult_OpenChannelDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_OpenChannelDecodeErrorZ), "LDKCResult_OpenChannelDecodeErrorZ"); *ret_conv = CResult_OpenChannelDecodeErrorZ_clone(orig_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_RevokeAndACKDecodeErrorZ_ok(uint32_t o) { LDKRevokeAndACK o_conv; o_conv.inner = (void*)(o & (~1)); o_conv.is_owned = (o & 1) || (o == 0); o_conv = RevokeAndACK_clone(&o_conv); LDKCResult_RevokeAndACKDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_RevokeAndACKDecodeErrorZ), "LDKCResult_RevokeAndACKDecodeErrorZ"); *ret_conv = CResult_RevokeAndACKDecodeErrorZ_ok(o_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_RevokeAndACKDecodeErrorZ_err(uint32_t e) { LDKDecodeError e_conv; e_conv.inner = (void*)(e & (~1)); e_conv.is_owned = (e & 1) || (e == 0); e_conv = DecodeError_clone(&e_conv); LDKCResult_RevokeAndACKDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_RevokeAndACKDecodeErrorZ), "LDKCResult_RevokeAndACKDecodeErrorZ"); *ret_conv = CResult_RevokeAndACKDecodeErrorZ_err(e_conv); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CResult_RevokeAndACKDecodeErrorZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCResult_RevokeAndACKDecodeErrorZ _res_conv = *(LDKCResult_RevokeAndACKDecodeErrorZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); CResult_RevokeAndACKDecodeErrorZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_CResult_RevokeAndACKDecodeErrorZ_clone(uint32_t orig) { LDKCResult_RevokeAndACKDecodeErrorZ* orig_conv = (LDKCResult_RevokeAndACKDecodeErrorZ*)(orig & ~1); LDKCResult_RevokeAndACKDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_RevokeAndACKDecodeErrorZ), "LDKCResult_RevokeAndACKDecodeErrorZ"); *ret_conv = CResult_RevokeAndACKDecodeErrorZ_clone(orig_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_ShutdownDecodeErrorZ_ok(uint32_t o) { LDKShutdown o_conv; o_conv.inner = (void*)(o & (~1)); o_conv.is_owned = (o & 1) || (o == 0); o_conv = Shutdown_clone(&o_conv); LDKCResult_ShutdownDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_ShutdownDecodeErrorZ), "LDKCResult_ShutdownDecodeErrorZ"); *ret_conv = CResult_ShutdownDecodeErrorZ_ok(o_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_ShutdownDecodeErrorZ_err(uint32_t e) { LDKDecodeError e_conv; e_conv.inner = (void*)(e & (~1)); e_conv.is_owned = (e & 1) || (e == 0); e_conv = DecodeError_clone(&e_conv); LDKCResult_ShutdownDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_ShutdownDecodeErrorZ), "LDKCResult_ShutdownDecodeErrorZ"); *ret_conv = CResult_ShutdownDecodeErrorZ_err(e_conv); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CResult_ShutdownDecodeErrorZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCResult_ShutdownDecodeErrorZ _res_conv = *(LDKCResult_ShutdownDecodeErrorZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); CResult_ShutdownDecodeErrorZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_CResult_ShutdownDecodeErrorZ_clone(uint32_t orig) { LDKCResult_ShutdownDecodeErrorZ* orig_conv = (LDKCResult_ShutdownDecodeErrorZ*)(orig & ~1); LDKCResult_ShutdownDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_ShutdownDecodeErrorZ), "LDKCResult_ShutdownDecodeErrorZ"); *ret_conv = CResult_ShutdownDecodeErrorZ_clone(orig_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_UpdateFailHTLCDecodeErrorZ_ok(uint32_t o) { LDKUpdateFailHTLC o_conv; o_conv.inner = (void*)(o & (~1)); o_conv.is_owned = (o & 1) || (o == 0); o_conv = UpdateFailHTLC_clone(&o_conv); LDKCResult_UpdateFailHTLCDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_UpdateFailHTLCDecodeErrorZ), "LDKCResult_UpdateFailHTLCDecodeErrorZ"); *ret_conv = CResult_UpdateFailHTLCDecodeErrorZ_ok(o_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_UpdateFailHTLCDecodeErrorZ_err(uint32_t e) { LDKDecodeError e_conv; e_conv.inner = (void*)(e & (~1)); e_conv.is_owned = (e & 1) || (e == 0); e_conv = DecodeError_clone(&e_conv); LDKCResult_UpdateFailHTLCDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_UpdateFailHTLCDecodeErrorZ), "LDKCResult_UpdateFailHTLCDecodeErrorZ"); *ret_conv = CResult_UpdateFailHTLCDecodeErrorZ_err(e_conv); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CResult_UpdateFailHTLCDecodeErrorZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCResult_UpdateFailHTLCDecodeErrorZ _res_conv = *(LDKCResult_UpdateFailHTLCDecodeErrorZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); CResult_UpdateFailHTLCDecodeErrorZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_CResult_UpdateFailHTLCDecodeErrorZ_clone(uint32_t orig) { LDKCResult_UpdateFailHTLCDecodeErrorZ* orig_conv = (LDKCResult_UpdateFailHTLCDecodeErrorZ*)(orig & ~1); LDKCResult_UpdateFailHTLCDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_UpdateFailHTLCDecodeErrorZ), "LDKCResult_UpdateFailHTLCDecodeErrorZ"); *ret_conv = CResult_UpdateFailHTLCDecodeErrorZ_clone(orig_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_UpdateFailMalformedHTLCDecodeErrorZ_ok(uint32_t o) { LDKUpdateFailMalformedHTLC o_conv; o_conv.inner = (void*)(o & (~1)); o_conv.is_owned = (o & 1) || (o == 0); o_conv = UpdateFailMalformedHTLC_clone(&o_conv); LDKCResult_UpdateFailMalformedHTLCDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_UpdateFailMalformedHTLCDecodeErrorZ), "LDKCResult_UpdateFailMalformedHTLCDecodeErrorZ"); *ret_conv = CResult_UpdateFailMalformedHTLCDecodeErrorZ_ok(o_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_UpdateFailMalformedHTLCDecodeErrorZ_err(uint32_t e) { LDKDecodeError e_conv; e_conv.inner = (void*)(e & (~1)); e_conv.is_owned = (e & 1) || (e == 0); e_conv = DecodeError_clone(&e_conv); LDKCResult_UpdateFailMalformedHTLCDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_UpdateFailMalformedHTLCDecodeErrorZ), "LDKCResult_UpdateFailMalformedHTLCDecodeErrorZ"); *ret_conv = CResult_UpdateFailMalformedHTLCDecodeErrorZ_err(e_conv); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CResult_UpdateFailMalformedHTLCDecodeErrorZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCResult_UpdateFailMalformedHTLCDecodeErrorZ _res_conv = *(LDKCResult_UpdateFailMalformedHTLCDecodeErrorZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); CResult_UpdateFailMalformedHTLCDecodeErrorZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_CResult_UpdateFailMalformedHTLCDecodeErrorZ_clone(uint32_t orig) { LDKCResult_UpdateFailMalformedHTLCDecodeErrorZ* orig_conv = (LDKCResult_UpdateFailMalformedHTLCDecodeErrorZ*)(orig & ~1); LDKCResult_UpdateFailMalformedHTLCDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_UpdateFailMalformedHTLCDecodeErrorZ), "LDKCResult_UpdateFailMalformedHTLCDecodeErrorZ"); *ret_conv = CResult_UpdateFailMalformedHTLCDecodeErrorZ_clone(orig_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_UpdateFeeDecodeErrorZ_ok(uint32_t o) { LDKUpdateFee o_conv; o_conv.inner = (void*)(o & (~1)); o_conv.is_owned = (o & 1) || (o == 0); o_conv = UpdateFee_clone(&o_conv); LDKCResult_UpdateFeeDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_UpdateFeeDecodeErrorZ), "LDKCResult_UpdateFeeDecodeErrorZ"); *ret_conv = CResult_UpdateFeeDecodeErrorZ_ok(o_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_UpdateFeeDecodeErrorZ_err(uint32_t e) { LDKDecodeError e_conv; e_conv.inner = (void*)(e & (~1)); e_conv.is_owned = (e & 1) || (e == 0); e_conv = DecodeError_clone(&e_conv); LDKCResult_UpdateFeeDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_UpdateFeeDecodeErrorZ), "LDKCResult_UpdateFeeDecodeErrorZ"); *ret_conv = CResult_UpdateFeeDecodeErrorZ_err(e_conv); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CResult_UpdateFeeDecodeErrorZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCResult_UpdateFeeDecodeErrorZ _res_conv = *(LDKCResult_UpdateFeeDecodeErrorZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); CResult_UpdateFeeDecodeErrorZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_CResult_UpdateFeeDecodeErrorZ_clone(uint32_t orig) { LDKCResult_UpdateFeeDecodeErrorZ* orig_conv = (LDKCResult_UpdateFeeDecodeErrorZ*)(orig & ~1); LDKCResult_UpdateFeeDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_UpdateFeeDecodeErrorZ), "LDKCResult_UpdateFeeDecodeErrorZ"); *ret_conv = CResult_UpdateFeeDecodeErrorZ_clone(orig_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_UpdateFulfillHTLCDecodeErrorZ_ok(uint32_t o) { LDKUpdateFulfillHTLC o_conv; o_conv.inner = (void*)(o & (~1)); o_conv.is_owned = (o & 1) || (o == 0); o_conv = UpdateFulfillHTLC_clone(&o_conv); LDKCResult_UpdateFulfillHTLCDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_UpdateFulfillHTLCDecodeErrorZ), "LDKCResult_UpdateFulfillHTLCDecodeErrorZ"); *ret_conv = CResult_UpdateFulfillHTLCDecodeErrorZ_ok(o_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_UpdateFulfillHTLCDecodeErrorZ_err(uint32_t e) { LDKDecodeError e_conv; e_conv.inner = (void*)(e & (~1)); e_conv.is_owned = (e & 1) || (e == 0); e_conv = DecodeError_clone(&e_conv); LDKCResult_UpdateFulfillHTLCDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_UpdateFulfillHTLCDecodeErrorZ), "LDKCResult_UpdateFulfillHTLCDecodeErrorZ"); *ret_conv = CResult_UpdateFulfillHTLCDecodeErrorZ_err(e_conv); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CResult_UpdateFulfillHTLCDecodeErrorZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCResult_UpdateFulfillHTLCDecodeErrorZ _res_conv = *(LDKCResult_UpdateFulfillHTLCDecodeErrorZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); CResult_UpdateFulfillHTLCDecodeErrorZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_CResult_UpdateFulfillHTLCDecodeErrorZ_clone(uint32_t orig) { LDKCResult_UpdateFulfillHTLCDecodeErrorZ* orig_conv = (LDKCResult_UpdateFulfillHTLCDecodeErrorZ*)(orig & ~1); LDKCResult_UpdateFulfillHTLCDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_UpdateFulfillHTLCDecodeErrorZ), "LDKCResult_UpdateFulfillHTLCDecodeErrorZ"); *ret_conv = CResult_UpdateFulfillHTLCDecodeErrorZ_clone(orig_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_UpdateAddHTLCDecodeErrorZ_ok(uint32_t o) { LDKUpdateAddHTLC o_conv; o_conv.inner = (void*)(o & (~1)); o_conv.is_owned = (o & 1) || (o == 0); o_conv = UpdateAddHTLC_clone(&o_conv); LDKCResult_UpdateAddHTLCDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_UpdateAddHTLCDecodeErrorZ), "LDKCResult_UpdateAddHTLCDecodeErrorZ"); *ret_conv = CResult_UpdateAddHTLCDecodeErrorZ_ok(o_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_UpdateAddHTLCDecodeErrorZ_err(uint32_t e) { LDKDecodeError e_conv; e_conv.inner = (void*)(e & (~1)); e_conv.is_owned = (e & 1) || (e == 0); e_conv = DecodeError_clone(&e_conv); LDKCResult_UpdateAddHTLCDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_UpdateAddHTLCDecodeErrorZ), "LDKCResult_UpdateAddHTLCDecodeErrorZ"); *ret_conv = CResult_UpdateAddHTLCDecodeErrorZ_err(e_conv); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CResult_UpdateAddHTLCDecodeErrorZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCResult_UpdateAddHTLCDecodeErrorZ _res_conv = *(LDKCResult_UpdateAddHTLCDecodeErrorZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); CResult_UpdateAddHTLCDecodeErrorZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_CResult_UpdateAddHTLCDecodeErrorZ_clone(uint32_t orig) { LDKCResult_UpdateAddHTLCDecodeErrorZ* orig_conv = (LDKCResult_UpdateAddHTLCDecodeErrorZ*)(orig & ~1); LDKCResult_UpdateAddHTLCDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_UpdateAddHTLCDecodeErrorZ), "LDKCResult_UpdateAddHTLCDecodeErrorZ"); *ret_conv = CResult_UpdateAddHTLCDecodeErrorZ_clone(orig_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_PingDecodeErrorZ_ok(uint32_t o) { LDKPing o_conv; o_conv.inner = (void*)(o & (~1)); o_conv.is_owned = (o & 1) || (o == 0); o_conv = Ping_clone(&o_conv); LDKCResult_PingDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_PingDecodeErrorZ), "LDKCResult_PingDecodeErrorZ"); *ret_conv = CResult_PingDecodeErrorZ_ok(o_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_PingDecodeErrorZ_err(uint32_t e) { LDKDecodeError e_conv; e_conv.inner = (void*)(e & (~1)); e_conv.is_owned = (e & 1) || (e == 0); e_conv = DecodeError_clone(&e_conv); LDKCResult_PingDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_PingDecodeErrorZ), "LDKCResult_PingDecodeErrorZ"); *ret_conv = CResult_PingDecodeErrorZ_err(e_conv); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CResult_PingDecodeErrorZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCResult_PingDecodeErrorZ _res_conv = *(LDKCResult_PingDecodeErrorZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); CResult_PingDecodeErrorZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_CResult_PingDecodeErrorZ_clone(uint32_t orig) { LDKCResult_PingDecodeErrorZ* orig_conv = (LDKCResult_PingDecodeErrorZ*)(orig & ~1); LDKCResult_PingDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_PingDecodeErrorZ), "LDKCResult_PingDecodeErrorZ"); *ret_conv = CResult_PingDecodeErrorZ_clone(orig_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_PongDecodeErrorZ_ok(uint32_t o) { LDKPong o_conv; o_conv.inner = (void*)(o & (~1)); o_conv.is_owned = (o & 1) || (o == 0); o_conv = Pong_clone(&o_conv); LDKCResult_PongDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_PongDecodeErrorZ), "LDKCResult_PongDecodeErrorZ"); *ret_conv = CResult_PongDecodeErrorZ_ok(o_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_PongDecodeErrorZ_err(uint32_t e) { LDKDecodeError e_conv; e_conv.inner = (void*)(e & (~1)); e_conv.is_owned = (e & 1) || (e == 0); e_conv = DecodeError_clone(&e_conv); LDKCResult_PongDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_PongDecodeErrorZ), "LDKCResult_PongDecodeErrorZ"); *ret_conv = CResult_PongDecodeErrorZ_err(e_conv); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CResult_PongDecodeErrorZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCResult_PongDecodeErrorZ _res_conv = *(LDKCResult_PongDecodeErrorZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); CResult_PongDecodeErrorZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_CResult_PongDecodeErrorZ_clone(uint32_t orig) { LDKCResult_PongDecodeErrorZ* orig_conv = (LDKCResult_PongDecodeErrorZ*)(orig & ~1); LDKCResult_PongDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_PongDecodeErrorZ), "LDKCResult_PongDecodeErrorZ"); *ret_conv = CResult_PongDecodeErrorZ_clone(orig_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_UnsignedChannelAnnouncementDecodeErrorZ_ok(uint32_t o) { LDKUnsignedChannelAnnouncement o_conv; o_conv.inner = (void*)(o & (~1)); o_conv.is_owned = (o & 1) || (o == 0); o_conv = UnsignedChannelAnnouncement_clone(&o_conv); LDKCResult_UnsignedChannelAnnouncementDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_UnsignedChannelAnnouncementDecodeErrorZ), "LDKCResult_UnsignedChannelAnnouncementDecodeErrorZ"); *ret_conv = CResult_UnsignedChannelAnnouncementDecodeErrorZ_ok(o_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_UnsignedChannelAnnouncementDecodeErrorZ_err(uint32_t e) { LDKDecodeError e_conv; e_conv.inner = (void*)(e & (~1)); e_conv.is_owned = (e & 1) || (e == 0); e_conv = DecodeError_clone(&e_conv); LDKCResult_UnsignedChannelAnnouncementDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_UnsignedChannelAnnouncementDecodeErrorZ), "LDKCResult_UnsignedChannelAnnouncementDecodeErrorZ"); *ret_conv = CResult_UnsignedChannelAnnouncementDecodeErrorZ_err(e_conv); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CResult_UnsignedChannelAnnouncementDecodeErrorZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCResult_UnsignedChannelAnnouncementDecodeErrorZ _res_conv = *(LDKCResult_UnsignedChannelAnnouncementDecodeErrorZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); CResult_UnsignedChannelAnnouncementDecodeErrorZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_CResult_UnsignedChannelAnnouncementDecodeErrorZ_clone(uint32_t orig) { LDKCResult_UnsignedChannelAnnouncementDecodeErrorZ* orig_conv = (LDKCResult_UnsignedChannelAnnouncementDecodeErrorZ*)(orig & ~1); LDKCResult_UnsignedChannelAnnouncementDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_UnsignedChannelAnnouncementDecodeErrorZ), "LDKCResult_UnsignedChannelAnnouncementDecodeErrorZ"); *ret_conv = CResult_UnsignedChannelAnnouncementDecodeErrorZ_clone(orig_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_ChannelAnnouncementDecodeErrorZ_ok(uint32_t o) { LDKChannelAnnouncement o_conv; o_conv.inner = (void*)(o & (~1)); o_conv.is_owned = (o & 1) || (o == 0); o_conv = ChannelAnnouncement_clone(&o_conv); LDKCResult_ChannelAnnouncementDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_ChannelAnnouncementDecodeErrorZ), "LDKCResult_ChannelAnnouncementDecodeErrorZ"); *ret_conv = CResult_ChannelAnnouncementDecodeErrorZ_ok(o_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_ChannelAnnouncementDecodeErrorZ_err(uint32_t e) { LDKDecodeError e_conv; e_conv.inner = (void*)(e & (~1)); e_conv.is_owned = (e & 1) || (e == 0); e_conv = DecodeError_clone(&e_conv); LDKCResult_ChannelAnnouncementDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_ChannelAnnouncementDecodeErrorZ), "LDKCResult_ChannelAnnouncementDecodeErrorZ"); *ret_conv = CResult_ChannelAnnouncementDecodeErrorZ_err(e_conv); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CResult_ChannelAnnouncementDecodeErrorZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCResult_ChannelAnnouncementDecodeErrorZ _res_conv = *(LDKCResult_ChannelAnnouncementDecodeErrorZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); CResult_ChannelAnnouncementDecodeErrorZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_CResult_ChannelAnnouncementDecodeErrorZ_clone(uint32_t orig) { LDKCResult_ChannelAnnouncementDecodeErrorZ* orig_conv = (LDKCResult_ChannelAnnouncementDecodeErrorZ*)(orig & ~1); LDKCResult_ChannelAnnouncementDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_ChannelAnnouncementDecodeErrorZ), "LDKCResult_ChannelAnnouncementDecodeErrorZ"); *ret_conv = CResult_ChannelAnnouncementDecodeErrorZ_clone(orig_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_UnsignedChannelUpdateDecodeErrorZ_ok(uint32_t o) { LDKUnsignedChannelUpdate o_conv; o_conv.inner = (void*)(o & (~1)); o_conv.is_owned = (o & 1) || (o == 0); o_conv = UnsignedChannelUpdate_clone(&o_conv); LDKCResult_UnsignedChannelUpdateDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_UnsignedChannelUpdateDecodeErrorZ), "LDKCResult_UnsignedChannelUpdateDecodeErrorZ"); *ret_conv = CResult_UnsignedChannelUpdateDecodeErrorZ_ok(o_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_UnsignedChannelUpdateDecodeErrorZ_err(uint32_t e) { LDKDecodeError e_conv; e_conv.inner = (void*)(e & (~1)); e_conv.is_owned = (e & 1) || (e == 0); e_conv = DecodeError_clone(&e_conv); LDKCResult_UnsignedChannelUpdateDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_UnsignedChannelUpdateDecodeErrorZ), "LDKCResult_UnsignedChannelUpdateDecodeErrorZ"); *ret_conv = CResult_UnsignedChannelUpdateDecodeErrorZ_err(e_conv); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CResult_UnsignedChannelUpdateDecodeErrorZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCResult_UnsignedChannelUpdateDecodeErrorZ _res_conv = *(LDKCResult_UnsignedChannelUpdateDecodeErrorZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); CResult_UnsignedChannelUpdateDecodeErrorZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_CResult_UnsignedChannelUpdateDecodeErrorZ_clone(uint32_t orig) { LDKCResult_UnsignedChannelUpdateDecodeErrorZ* orig_conv = (LDKCResult_UnsignedChannelUpdateDecodeErrorZ*)(orig & ~1); LDKCResult_UnsignedChannelUpdateDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_UnsignedChannelUpdateDecodeErrorZ), "LDKCResult_UnsignedChannelUpdateDecodeErrorZ"); *ret_conv = CResult_UnsignedChannelUpdateDecodeErrorZ_clone(orig_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_ChannelUpdateDecodeErrorZ_ok(uint32_t o) { LDKChannelUpdate o_conv; o_conv.inner = (void*)(o & (~1)); o_conv.is_owned = (o & 1) || (o == 0); o_conv = ChannelUpdate_clone(&o_conv); LDKCResult_ChannelUpdateDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_ChannelUpdateDecodeErrorZ), "LDKCResult_ChannelUpdateDecodeErrorZ"); *ret_conv = CResult_ChannelUpdateDecodeErrorZ_ok(o_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_ChannelUpdateDecodeErrorZ_err(uint32_t e) { LDKDecodeError e_conv; e_conv.inner = (void*)(e & (~1)); e_conv.is_owned = (e & 1) || (e == 0); e_conv = DecodeError_clone(&e_conv); LDKCResult_ChannelUpdateDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_ChannelUpdateDecodeErrorZ), "LDKCResult_ChannelUpdateDecodeErrorZ"); *ret_conv = CResult_ChannelUpdateDecodeErrorZ_err(e_conv); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CResult_ChannelUpdateDecodeErrorZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCResult_ChannelUpdateDecodeErrorZ _res_conv = *(LDKCResult_ChannelUpdateDecodeErrorZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); CResult_ChannelUpdateDecodeErrorZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_CResult_ChannelUpdateDecodeErrorZ_clone(uint32_t orig) { LDKCResult_ChannelUpdateDecodeErrorZ* orig_conv = (LDKCResult_ChannelUpdateDecodeErrorZ*)(orig & ~1); LDKCResult_ChannelUpdateDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_ChannelUpdateDecodeErrorZ), "LDKCResult_ChannelUpdateDecodeErrorZ"); *ret_conv = CResult_ChannelUpdateDecodeErrorZ_clone(orig_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_ErrorMessageDecodeErrorZ_ok(uint32_t o) { LDKErrorMessage o_conv; o_conv.inner = (void*)(o & (~1)); o_conv.is_owned = (o & 1) || (o == 0); o_conv = ErrorMessage_clone(&o_conv); LDKCResult_ErrorMessageDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_ErrorMessageDecodeErrorZ), "LDKCResult_ErrorMessageDecodeErrorZ"); *ret_conv = CResult_ErrorMessageDecodeErrorZ_ok(o_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_ErrorMessageDecodeErrorZ_err(uint32_t e) { LDKDecodeError e_conv; e_conv.inner = (void*)(e & (~1)); e_conv.is_owned = (e & 1) || (e == 0); e_conv = DecodeError_clone(&e_conv); LDKCResult_ErrorMessageDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_ErrorMessageDecodeErrorZ), "LDKCResult_ErrorMessageDecodeErrorZ"); *ret_conv = CResult_ErrorMessageDecodeErrorZ_err(e_conv); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CResult_ErrorMessageDecodeErrorZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCResult_ErrorMessageDecodeErrorZ _res_conv = *(LDKCResult_ErrorMessageDecodeErrorZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); CResult_ErrorMessageDecodeErrorZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_CResult_ErrorMessageDecodeErrorZ_clone(uint32_t orig) { LDKCResult_ErrorMessageDecodeErrorZ* orig_conv = (LDKCResult_ErrorMessageDecodeErrorZ*)(orig & ~1); LDKCResult_ErrorMessageDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_ErrorMessageDecodeErrorZ), "LDKCResult_ErrorMessageDecodeErrorZ"); *ret_conv = CResult_ErrorMessageDecodeErrorZ_clone(orig_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_UnsignedNodeAnnouncementDecodeErrorZ_ok(uint32_t o) { LDKUnsignedNodeAnnouncement o_conv; o_conv.inner = (void*)(o & (~1)); o_conv.is_owned = (o & 1) || (o == 0); o_conv = UnsignedNodeAnnouncement_clone(&o_conv); LDKCResult_UnsignedNodeAnnouncementDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_UnsignedNodeAnnouncementDecodeErrorZ), "LDKCResult_UnsignedNodeAnnouncementDecodeErrorZ"); *ret_conv = CResult_UnsignedNodeAnnouncementDecodeErrorZ_ok(o_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_UnsignedNodeAnnouncementDecodeErrorZ_err(uint32_t e) { LDKDecodeError e_conv; e_conv.inner = (void*)(e & (~1)); e_conv.is_owned = (e & 1) || (e == 0); e_conv = DecodeError_clone(&e_conv); LDKCResult_UnsignedNodeAnnouncementDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_UnsignedNodeAnnouncementDecodeErrorZ), "LDKCResult_UnsignedNodeAnnouncementDecodeErrorZ"); *ret_conv = CResult_UnsignedNodeAnnouncementDecodeErrorZ_err(e_conv); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CResult_UnsignedNodeAnnouncementDecodeErrorZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCResult_UnsignedNodeAnnouncementDecodeErrorZ _res_conv = *(LDKCResult_UnsignedNodeAnnouncementDecodeErrorZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); CResult_UnsignedNodeAnnouncementDecodeErrorZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_CResult_UnsignedNodeAnnouncementDecodeErrorZ_clone(uint32_t orig) { LDKCResult_UnsignedNodeAnnouncementDecodeErrorZ* orig_conv = (LDKCResult_UnsignedNodeAnnouncementDecodeErrorZ*)(orig & ~1); LDKCResult_UnsignedNodeAnnouncementDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_UnsignedNodeAnnouncementDecodeErrorZ), "LDKCResult_UnsignedNodeAnnouncementDecodeErrorZ"); *ret_conv = CResult_UnsignedNodeAnnouncementDecodeErrorZ_clone(orig_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_NodeAnnouncementDecodeErrorZ_ok(uint32_t o) { LDKNodeAnnouncement o_conv; o_conv.inner = (void*)(o & (~1)); o_conv.is_owned = (o & 1) || (o == 0); o_conv = NodeAnnouncement_clone(&o_conv); LDKCResult_NodeAnnouncementDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_NodeAnnouncementDecodeErrorZ), "LDKCResult_NodeAnnouncementDecodeErrorZ"); *ret_conv = CResult_NodeAnnouncementDecodeErrorZ_ok(o_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_NodeAnnouncementDecodeErrorZ_err(uint32_t e) { LDKDecodeError e_conv; e_conv.inner = (void*)(e & (~1)); e_conv.is_owned = (e & 1) || (e == 0); e_conv = DecodeError_clone(&e_conv); LDKCResult_NodeAnnouncementDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_NodeAnnouncementDecodeErrorZ), "LDKCResult_NodeAnnouncementDecodeErrorZ"); *ret_conv = CResult_NodeAnnouncementDecodeErrorZ_err(e_conv); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CResult_NodeAnnouncementDecodeErrorZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCResult_NodeAnnouncementDecodeErrorZ _res_conv = *(LDKCResult_NodeAnnouncementDecodeErrorZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); CResult_NodeAnnouncementDecodeErrorZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_CResult_NodeAnnouncementDecodeErrorZ_clone(uint32_t orig) { LDKCResult_NodeAnnouncementDecodeErrorZ* orig_conv = (LDKCResult_NodeAnnouncementDecodeErrorZ*)(orig & ~1); LDKCResult_NodeAnnouncementDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_NodeAnnouncementDecodeErrorZ), "LDKCResult_NodeAnnouncementDecodeErrorZ"); *ret_conv = CResult_NodeAnnouncementDecodeErrorZ_clone(orig_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_QueryShortChannelIdsDecodeErrorZ_ok(uint32_t o) { LDKQueryShortChannelIds o_conv; o_conv.inner = (void*)(o & (~1)); o_conv.is_owned = (o & 1) || (o == 0); o_conv = QueryShortChannelIds_clone(&o_conv); LDKCResult_QueryShortChannelIdsDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_QueryShortChannelIdsDecodeErrorZ), "LDKCResult_QueryShortChannelIdsDecodeErrorZ"); *ret_conv = CResult_QueryShortChannelIdsDecodeErrorZ_ok(o_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_QueryShortChannelIdsDecodeErrorZ_err(uint32_t e) { LDKDecodeError e_conv; e_conv.inner = (void*)(e & (~1)); e_conv.is_owned = (e & 1) || (e == 0); e_conv = DecodeError_clone(&e_conv); LDKCResult_QueryShortChannelIdsDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_QueryShortChannelIdsDecodeErrorZ), "LDKCResult_QueryShortChannelIdsDecodeErrorZ"); *ret_conv = CResult_QueryShortChannelIdsDecodeErrorZ_err(e_conv); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CResult_QueryShortChannelIdsDecodeErrorZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCResult_QueryShortChannelIdsDecodeErrorZ _res_conv = *(LDKCResult_QueryShortChannelIdsDecodeErrorZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); CResult_QueryShortChannelIdsDecodeErrorZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_CResult_QueryShortChannelIdsDecodeErrorZ_clone(uint32_t orig) { LDKCResult_QueryShortChannelIdsDecodeErrorZ* orig_conv = (LDKCResult_QueryShortChannelIdsDecodeErrorZ*)(orig & ~1); LDKCResult_QueryShortChannelIdsDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_QueryShortChannelIdsDecodeErrorZ), "LDKCResult_QueryShortChannelIdsDecodeErrorZ"); *ret_conv = CResult_QueryShortChannelIdsDecodeErrorZ_clone(orig_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_ReplyShortChannelIdsEndDecodeErrorZ_ok(uint32_t o) { LDKReplyShortChannelIdsEnd o_conv; o_conv.inner = (void*)(o & (~1)); o_conv.is_owned = (o & 1) || (o == 0); o_conv = ReplyShortChannelIdsEnd_clone(&o_conv); LDKCResult_ReplyShortChannelIdsEndDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_ReplyShortChannelIdsEndDecodeErrorZ), "LDKCResult_ReplyShortChannelIdsEndDecodeErrorZ"); *ret_conv = CResult_ReplyShortChannelIdsEndDecodeErrorZ_ok(o_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_ReplyShortChannelIdsEndDecodeErrorZ_err(uint32_t e) { LDKDecodeError e_conv; e_conv.inner = (void*)(e & (~1)); e_conv.is_owned = (e & 1) || (e == 0); e_conv = DecodeError_clone(&e_conv); LDKCResult_ReplyShortChannelIdsEndDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_ReplyShortChannelIdsEndDecodeErrorZ), "LDKCResult_ReplyShortChannelIdsEndDecodeErrorZ"); *ret_conv = CResult_ReplyShortChannelIdsEndDecodeErrorZ_err(e_conv); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CResult_ReplyShortChannelIdsEndDecodeErrorZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCResult_ReplyShortChannelIdsEndDecodeErrorZ _res_conv = *(LDKCResult_ReplyShortChannelIdsEndDecodeErrorZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); CResult_ReplyShortChannelIdsEndDecodeErrorZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_CResult_ReplyShortChannelIdsEndDecodeErrorZ_clone(uint32_t orig) { LDKCResult_ReplyShortChannelIdsEndDecodeErrorZ* orig_conv = (LDKCResult_ReplyShortChannelIdsEndDecodeErrorZ*)(orig & ~1); LDKCResult_ReplyShortChannelIdsEndDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_ReplyShortChannelIdsEndDecodeErrorZ), "LDKCResult_ReplyShortChannelIdsEndDecodeErrorZ"); *ret_conv = CResult_ReplyShortChannelIdsEndDecodeErrorZ_clone(orig_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_QueryChannelRangeDecodeErrorZ_ok(uint32_t o) { LDKQueryChannelRange o_conv; o_conv.inner = (void*)(o & (~1)); o_conv.is_owned = (o & 1) || (o == 0); o_conv = QueryChannelRange_clone(&o_conv); LDKCResult_QueryChannelRangeDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_QueryChannelRangeDecodeErrorZ), "LDKCResult_QueryChannelRangeDecodeErrorZ"); *ret_conv = CResult_QueryChannelRangeDecodeErrorZ_ok(o_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_QueryChannelRangeDecodeErrorZ_err(uint32_t e) { LDKDecodeError e_conv; e_conv.inner = (void*)(e & (~1)); e_conv.is_owned = (e & 1) || (e == 0); e_conv = DecodeError_clone(&e_conv); LDKCResult_QueryChannelRangeDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_QueryChannelRangeDecodeErrorZ), "LDKCResult_QueryChannelRangeDecodeErrorZ"); *ret_conv = CResult_QueryChannelRangeDecodeErrorZ_err(e_conv); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CResult_QueryChannelRangeDecodeErrorZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCResult_QueryChannelRangeDecodeErrorZ _res_conv = *(LDKCResult_QueryChannelRangeDecodeErrorZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); CResult_QueryChannelRangeDecodeErrorZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_CResult_QueryChannelRangeDecodeErrorZ_clone(uint32_t orig) { LDKCResult_QueryChannelRangeDecodeErrorZ* orig_conv = (LDKCResult_QueryChannelRangeDecodeErrorZ*)(orig & ~1); LDKCResult_QueryChannelRangeDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_QueryChannelRangeDecodeErrorZ), "LDKCResult_QueryChannelRangeDecodeErrorZ"); *ret_conv = CResult_QueryChannelRangeDecodeErrorZ_clone(orig_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_ReplyChannelRangeDecodeErrorZ_ok(uint32_t o) { LDKReplyChannelRange o_conv; o_conv.inner = (void*)(o & (~1)); o_conv.is_owned = (o & 1) || (o == 0); o_conv = ReplyChannelRange_clone(&o_conv); LDKCResult_ReplyChannelRangeDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_ReplyChannelRangeDecodeErrorZ), "LDKCResult_ReplyChannelRangeDecodeErrorZ"); *ret_conv = CResult_ReplyChannelRangeDecodeErrorZ_ok(o_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_ReplyChannelRangeDecodeErrorZ_err(uint32_t e) { LDKDecodeError e_conv; e_conv.inner = (void*)(e & (~1)); e_conv.is_owned = (e & 1) || (e == 0); e_conv = DecodeError_clone(&e_conv); LDKCResult_ReplyChannelRangeDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_ReplyChannelRangeDecodeErrorZ), "LDKCResult_ReplyChannelRangeDecodeErrorZ"); *ret_conv = CResult_ReplyChannelRangeDecodeErrorZ_err(e_conv); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CResult_ReplyChannelRangeDecodeErrorZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCResult_ReplyChannelRangeDecodeErrorZ _res_conv = *(LDKCResult_ReplyChannelRangeDecodeErrorZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); CResult_ReplyChannelRangeDecodeErrorZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_CResult_ReplyChannelRangeDecodeErrorZ_clone(uint32_t orig) { LDKCResult_ReplyChannelRangeDecodeErrorZ* orig_conv = (LDKCResult_ReplyChannelRangeDecodeErrorZ*)(orig & ~1); LDKCResult_ReplyChannelRangeDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_ReplyChannelRangeDecodeErrorZ), "LDKCResult_ReplyChannelRangeDecodeErrorZ"); *ret_conv = CResult_ReplyChannelRangeDecodeErrorZ_clone(orig_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_GossipTimestampFilterDecodeErrorZ_ok(uint32_t o) { LDKGossipTimestampFilter o_conv; o_conv.inner = (void*)(o & (~1)); o_conv.is_owned = (o & 1) || (o == 0); o_conv = GossipTimestampFilter_clone(&o_conv); LDKCResult_GossipTimestampFilterDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_GossipTimestampFilterDecodeErrorZ), "LDKCResult_GossipTimestampFilterDecodeErrorZ"); *ret_conv = CResult_GossipTimestampFilterDecodeErrorZ_ok(o_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_GossipTimestampFilterDecodeErrorZ_err(uint32_t e) { LDKDecodeError e_conv; e_conv.inner = (void*)(e & (~1)); e_conv.is_owned = (e & 1) || (e == 0); e_conv = DecodeError_clone(&e_conv); LDKCResult_GossipTimestampFilterDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_GossipTimestampFilterDecodeErrorZ), "LDKCResult_GossipTimestampFilterDecodeErrorZ"); *ret_conv = CResult_GossipTimestampFilterDecodeErrorZ_err(e_conv); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CResult_GossipTimestampFilterDecodeErrorZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCResult_GossipTimestampFilterDecodeErrorZ _res_conv = *(LDKCResult_GossipTimestampFilterDecodeErrorZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); CResult_GossipTimestampFilterDecodeErrorZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_CResult_GossipTimestampFilterDecodeErrorZ_clone(uint32_t orig) { LDKCResult_GossipTimestampFilterDecodeErrorZ* orig_conv = (LDKCResult_GossipTimestampFilterDecodeErrorZ*)(orig & ~1); LDKCResult_GossipTimestampFilterDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_GossipTimestampFilterDecodeErrorZ), "LDKCResult_GossipTimestampFilterDecodeErrorZ"); *ret_conv = CResult_GossipTimestampFilterDecodeErrorZ_clone(orig_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_InvoiceSignOrCreationErrorZ_ok(uint32_t o) { LDKInvoice o_conv; o_conv.inner = (void*)(o & (~1)); o_conv.is_owned = (o & 1) || (o == 0); o_conv = Invoice_clone(&o_conv); LDKCResult_InvoiceSignOrCreationErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_InvoiceSignOrCreationErrorZ), "LDKCResult_InvoiceSignOrCreationErrorZ"); *ret_conv = CResult_InvoiceSignOrCreationErrorZ_ok(o_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CResult_InvoiceSignOrCreationErrorZ_err(uint32_t e) { LDKSignOrCreationError e_conv = *(LDKSignOrCreationError*)(((uint64_t)e) & ~1); e_conv = SignOrCreationError_clone((LDKSignOrCreationError*)(((uint64_t)e) & ~1)); LDKCResult_InvoiceSignOrCreationErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_InvoiceSignOrCreationErrorZ), "LDKCResult_InvoiceSignOrCreationErrorZ"); *ret_conv = CResult_InvoiceSignOrCreationErrorZ_err(e_conv); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CResult_InvoiceSignOrCreationErrorZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCResult_InvoiceSignOrCreationErrorZ _res_conv = *(LDKCResult_InvoiceSignOrCreationErrorZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); CResult_InvoiceSignOrCreationErrorZ_free(_res_conv); } uint32_t __attribute__((visibility("default"))) TS_CResult_InvoiceSignOrCreationErrorZ_clone(uint32_t orig) { LDKCResult_InvoiceSignOrCreationErrorZ* orig_conv = (LDKCResult_InvoiceSignOrCreationErrorZ*)(orig & ~1); LDKCResult_InvoiceSignOrCreationErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_InvoiceSignOrCreationErrorZ), "LDKCResult_InvoiceSignOrCreationErrorZ"); *ret_conv = CResult_InvoiceSignOrCreationErrorZ_clone(orig_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_COption_FilterZ_some(uint32_t o) { LDKFilter o_conv = *(LDKFilter*)(((uint64_t)o) & ~1); LDKCOption_FilterZ *ret_copy = MALLOC(sizeof(LDKCOption_FilterZ), "LDKCOption_FilterZ"); *ret_copy = COption_FilterZ_some(o_conv); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_COption_FilterZ_none() { LDKCOption_FilterZ *ret_copy = MALLOC(sizeof(LDKCOption_FilterZ), "LDKCOption_FilterZ"); *ret_copy = COption_FilterZ_none(); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } void __attribute__((visibility("default"))) TS_COption_FilterZ_free(uint32_t _res) { if ((_res & 1) != 0) return; LDKCOption_FilterZ _res_conv = *(LDKCOption_FilterZ*)(((uint64_t)_res) & ~1); FREE((void*)_res); COption_FilterZ_free(_res_conv); } void __attribute__((visibility("default"))) TS_PaymentPurpose_free(uint32_t this_ptr) { if ((this_ptr & 1) != 0) return; LDKPaymentPurpose this_ptr_conv = *(LDKPaymentPurpose*)(((uint64_t)this_ptr) & ~1); FREE((void*)this_ptr); PaymentPurpose_free(this_ptr_conv); } uint32_t __attribute__((visibility("default"))) TS_PaymentPurpose_clone(uint32_t orig) { LDKPaymentPurpose* orig_conv = (LDKPaymentPurpose*)orig; LDKPaymentPurpose *ret_copy = MALLOC(sizeof(LDKPaymentPurpose), "LDKPaymentPurpose"); *ret_copy = PaymentPurpose_clone(orig_conv); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_PaymentPurpose_invoice_payment(int8_tArray payment_preimage, int8_tArray payment_secret, int64_t user_payment_id) { LDKThirtyTwoBytes payment_preimage_ref; CHECK(*((uint32_t*)payment_preimage) == 32); memcpy(payment_preimage_ref.data, (uint8_t*)(payment_preimage + 4), 32); LDKThirtyTwoBytes payment_secret_ref; CHECK(*((uint32_t*)payment_secret) == 32); memcpy(payment_secret_ref.data, (uint8_t*)(payment_secret + 4), 32); LDKPaymentPurpose *ret_copy = MALLOC(sizeof(LDKPaymentPurpose), "LDKPaymentPurpose"); *ret_copy = PaymentPurpose_invoice_payment(payment_preimage_ref, payment_secret_ref, user_payment_id); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_PaymentPurpose_spontaneous_payment(int8_tArray a) { LDKThirtyTwoBytes a_ref; CHECK(*((uint32_t*)a) == 32); memcpy(a_ref.data, (uint8_t*)(a + 4), 32); LDKPaymentPurpose *ret_copy = MALLOC(sizeof(LDKPaymentPurpose), "LDKPaymentPurpose"); *ret_copy = PaymentPurpose_spontaneous_payment(a_ref); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } void __attribute__((visibility("default"))) TS_ClosureReason_free(uint32_t this_ptr) { if ((this_ptr & 1) != 0) return; LDKClosureReason this_ptr_conv = *(LDKClosureReason*)(((uint64_t)this_ptr) & ~1); FREE((void*)this_ptr); ClosureReason_free(this_ptr_conv); } uint32_t __attribute__((visibility("default"))) TS_ClosureReason_clone(uint32_t orig) { LDKClosureReason* orig_conv = (LDKClosureReason*)orig; LDKClosureReason *ret_copy = MALLOC(sizeof(LDKClosureReason), "LDKClosureReason"); *ret_copy = ClosureReason_clone(orig_conv); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_ClosureReason_counterparty_force_closed(jstring peer_msg) { LDKStr peer_msg_conv = str_ref_to_owned_c(peer_msg); LDKClosureReason *ret_copy = MALLOC(sizeof(LDKClosureReason), "LDKClosureReason"); *ret_copy = ClosureReason_counterparty_force_closed(peer_msg_conv); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_ClosureReason_holder_force_closed() { LDKClosureReason *ret_copy = MALLOC(sizeof(LDKClosureReason), "LDKClosureReason"); *ret_copy = ClosureReason_holder_force_closed(); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_ClosureReason_cooperative_closure() { LDKClosureReason *ret_copy = MALLOC(sizeof(LDKClosureReason), "LDKClosureReason"); *ret_copy = ClosureReason_cooperative_closure(); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_ClosureReason_commitment_tx_confirmed() { LDKClosureReason *ret_copy = MALLOC(sizeof(LDKClosureReason), "LDKClosureReason"); *ret_copy = ClosureReason_commitment_tx_confirmed(); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_ClosureReason_processing_error(jstring err) { LDKStr err_conv = str_ref_to_owned_c(err); LDKClosureReason *ret_copy = MALLOC(sizeof(LDKClosureReason), "LDKClosureReason"); *ret_copy = ClosureReason_processing_error(err_conv); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_ClosureReason_disconnected_peer() { LDKClosureReason *ret_copy = MALLOC(sizeof(LDKClosureReason), "LDKClosureReason"); *ret_copy = ClosureReason_disconnected_peer(); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_ClosureReason_outdated_channel_manager() { LDKClosureReason *ret_copy = MALLOC(sizeof(LDKClosureReason), "LDKClosureReason"); *ret_copy = ClosureReason_outdated_channel_manager(); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } int8_tArray __attribute__((visibility("default"))) TS_ClosureReason_write(uint32_t obj) { LDKClosureReason* obj_conv = (LDKClosureReason*)obj; LDKCVec_u8Z ret_var = ClosureReason_write(obj_conv); int8_tArray ret_arr = init_arr(ret_var.datalen, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), ret_var.data, ret_var.datalen); CVec_u8Z_free(ret_var); return ret_arr; } void __attribute__((visibility("default"))) TS_Event_free(uint32_t this_ptr) { if ((this_ptr & 1) != 0) return; LDKEvent this_ptr_conv = *(LDKEvent*)(((uint64_t)this_ptr) & ~1); FREE((void*)this_ptr); Event_free(this_ptr_conv); } uint32_t __attribute__((visibility("default"))) TS_Event_clone(uint32_t orig) { LDKEvent* orig_conv = (LDKEvent*)orig; LDKEvent *ret_copy = MALLOC(sizeof(LDKEvent), "LDKEvent"); *ret_copy = Event_clone(orig_conv); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_Event_funding_generation_ready(int8_tArray temporary_channel_id, int64_t channel_value_satoshis, int8_tArray output_script, int64_t user_channel_id) { LDKThirtyTwoBytes temporary_channel_id_ref; CHECK(*((uint32_t*)temporary_channel_id) == 32); memcpy(temporary_channel_id_ref.data, (uint8_t*)(temporary_channel_id + 4), 32); LDKCVec_u8Z output_script_ref; output_script_ref.datalen = *((uint32_t*)output_script); output_script_ref.data = MALLOC(output_script_ref.datalen, "LDKCVec_u8Z Bytes"); memcpy(output_script_ref.data, (uint8_t*)(output_script + 4), output_script_ref.datalen); LDKEvent *ret_copy = MALLOC(sizeof(LDKEvent), "LDKEvent"); *ret_copy = Event_funding_generation_ready(temporary_channel_id_ref, channel_value_satoshis, output_script_ref, user_channel_id); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_Event_payment_received(int8_tArray payment_hash, int64_t amt, uint32_t purpose) { LDKThirtyTwoBytes payment_hash_ref; CHECK(*((uint32_t*)payment_hash) == 32); memcpy(payment_hash_ref.data, (uint8_t*)(payment_hash + 4), 32); LDKPaymentPurpose purpose_conv = *(LDKPaymentPurpose*)(((uint64_t)purpose) & ~1); purpose_conv = PaymentPurpose_clone((LDKPaymentPurpose*)(((uint64_t)purpose) & ~1)); LDKEvent *ret_copy = MALLOC(sizeof(LDKEvent), "LDKEvent"); *ret_copy = Event_payment_received(payment_hash_ref, amt, purpose_conv); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_Event_payment_sent(int8_tArray payment_preimage) { LDKThirtyTwoBytes payment_preimage_ref; CHECK(*((uint32_t*)payment_preimage) == 32); memcpy(payment_preimage_ref.data, (uint8_t*)(payment_preimage + 4), 32); LDKEvent *ret_copy = MALLOC(sizeof(LDKEvent), "LDKEvent"); *ret_copy = Event_payment_sent(payment_preimage_ref); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_Event_payment_path_failed(int8_tArray payment_hash, jboolean rejected_by_dest, uint32_t network_update, jboolean all_paths_failed, uint32_tArray path) { LDKThirtyTwoBytes payment_hash_ref; CHECK(*((uint32_t*)payment_hash) == 32); memcpy(payment_hash_ref.data, (uint8_t*)(payment_hash + 4), 32); LDKCOption_NetworkUpdateZ network_update_conv = *(LDKCOption_NetworkUpdateZ*)(((uint64_t)network_update) & ~1); network_update_conv = COption_NetworkUpdateZ_clone((LDKCOption_NetworkUpdateZ*)(((uint64_t)network_update) & ~1)); LDKCVec_RouteHopZ path_constr; path_constr.datalen = *((uint32_t*)path); if (path_constr.datalen > 0) path_constr.data = MALLOC(path_constr.datalen * sizeof(LDKRouteHop), "LDKCVec_RouteHopZ Elements"); else path_constr.data = NULL; uint32_t* path_vals = (uint32_t*)(path + 4); for (size_t k = 0; k < path_constr.datalen; k++) { uint32_t path_conv_10 = path_vals[k]; LDKRouteHop path_conv_10_conv; path_conv_10_conv.inner = (void*)(path_conv_10 & (~1)); path_conv_10_conv.is_owned = (path_conv_10 & 1) || (path_conv_10 == 0); path_conv_10_conv = RouteHop_clone(&path_conv_10_conv); path_constr.data[k] = path_conv_10_conv; } LDKEvent *ret_copy = MALLOC(sizeof(LDKEvent), "LDKEvent"); *ret_copy = Event_payment_path_failed(payment_hash_ref, rejected_by_dest, network_update_conv, all_paths_failed, path_constr); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_Event_pending_htlcs_forwardable(int64_t time_forwardable) { LDKEvent *ret_copy = MALLOC(sizeof(LDKEvent), "LDKEvent"); *ret_copy = Event_pending_htlcs_forwardable(time_forwardable); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_Event_spendable_outputs(uint32_tArray outputs) { LDKCVec_SpendableOutputDescriptorZ outputs_constr; outputs_constr.datalen = *((uint32_t*)outputs); if (outputs_constr.datalen > 0) outputs_constr.data = MALLOC(outputs_constr.datalen * sizeof(LDKSpendableOutputDescriptor), "LDKCVec_SpendableOutputDescriptorZ Elements"); else outputs_constr.data = NULL; uint32_t* outputs_vals = (uint32_t*)(outputs + 4); for (size_t b = 0; b < outputs_constr.datalen; b++) { uint32_t outputs_conv_27 = outputs_vals[b]; LDKSpendableOutputDescriptor outputs_conv_27_conv = *(LDKSpendableOutputDescriptor*)(((uint64_t)outputs_conv_27) & ~1); outputs_conv_27_conv = SpendableOutputDescriptor_clone((LDKSpendableOutputDescriptor*)(((uint64_t)outputs_conv_27) & ~1)); outputs_constr.data[b] = outputs_conv_27_conv; } LDKEvent *ret_copy = MALLOC(sizeof(LDKEvent), "LDKEvent"); *ret_copy = Event_spendable_outputs(outputs_constr); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_Event_payment_forwarded(uint32_t fee_earned_msat, jboolean claim_from_onchain_tx) { LDKCOption_u64Z fee_earned_msat_conv = *(LDKCOption_u64Z*)(((uint64_t)fee_earned_msat) & ~1); fee_earned_msat_conv = COption_u64Z_clone((LDKCOption_u64Z*)(((uint64_t)fee_earned_msat) & ~1)); LDKEvent *ret_copy = MALLOC(sizeof(LDKEvent), "LDKEvent"); *ret_copy = Event_payment_forwarded(fee_earned_msat_conv, claim_from_onchain_tx); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_Event_channel_closed(int8_tArray channel_id, uint32_t reason) { LDKThirtyTwoBytes channel_id_ref; CHECK(*((uint32_t*)channel_id) == 32); memcpy(channel_id_ref.data, (uint8_t*)(channel_id + 4), 32); LDKClosureReason reason_conv = *(LDKClosureReason*)(((uint64_t)reason) & ~1); reason_conv = ClosureReason_clone((LDKClosureReason*)(((uint64_t)reason) & ~1)); LDKEvent *ret_copy = MALLOC(sizeof(LDKEvent), "LDKEvent"); *ret_copy = Event_channel_closed(channel_id_ref, reason_conv); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } int8_tArray __attribute__((visibility("default"))) TS_Event_write(uint32_t obj) { LDKEvent* obj_conv = (LDKEvent*)obj; LDKCVec_u8Z ret_var = Event_write(obj_conv); int8_tArray ret_arr = init_arr(ret_var.datalen, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), ret_var.data, ret_var.datalen); CVec_u8Z_free(ret_var); return ret_arr; } void __attribute__((visibility("default"))) TS_MessageSendEvent_free(uint32_t this_ptr) { if ((this_ptr & 1) != 0) return; LDKMessageSendEvent this_ptr_conv = *(LDKMessageSendEvent*)(((uint64_t)this_ptr) & ~1); FREE((void*)this_ptr); MessageSendEvent_free(this_ptr_conv); } uint32_t __attribute__((visibility("default"))) TS_MessageSendEvent_clone(uint32_t orig) { LDKMessageSendEvent* orig_conv = (LDKMessageSendEvent*)orig; LDKMessageSendEvent *ret_copy = MALLOC(sizeof(LDKMessageSendEvent), "LDKMessageSendEvent"); *ret_copy = MessageSendEvent_clone(orig_conv); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_MessageSendEvent_send_accept_channel(int8_tArray node_id, uint32_t msg) { LDKPublicKey node_id_ref; CHECK(*((uint32_t*)node_id) == 33); memcpy(node_id_ref.compressed_form, (uint8_t*)(node_id + 4), 33); LDKAcceptChannel msg_conv; msg_conv.inner = (void*)(msg & (~1)); msg_conv.is_owned = (msg & 1) || (msg == 0); msg_conv = AcceptChannel_clone(&msg_conv); LDKMessageSendEvent *ret_copy = MALLOC(sizeof(LDKMessageSendEvent), "LDKMessageSendEvent"); *ret_copy = MessageSendEvent_send_accept_channel(node_id_ref, msg_conv); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_MessageSendEvent_send_open_channel(int8_tArray node_id, uint32_t msg) { LDKPublicKey node_id_ref; CHECK(*((uint32_t*)node_id) == 33); memcpy(node_id_ref.compressed_form, (uint8_t*)(node_id + 4), 33); LDKOpenChannel msg_conv; msg_conv.inner = (void*)(msg & (~1)); msg_conv.is_owned = (msg & 1) || (msg == 0); msg_conv = OpenChannel_clone(&msg_conv); LDKMessageSendEvent *ret_copy = MALLOC(sizeof(LDKMessageSendEvent), "LDKMessageSendEvent"); *ret_copy = MessageSendEvent_send_open_channel(node_id_ref, msg_conv); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_MessageSendEvent_send_funding_created(int8_tArray node_id, uint32_t msg) { LDKPublicKey node_id_ref; CHECK(*((uint32_t*)node_id) == 33); memcpy(node_id_ref.compressed_form, (uint8_t*)(node_id + 4), 33); LDKFundingCreated msg_conv; msg_conv.inner = (void*)(msg & (~1)); msg_conv.is_owned = (msg & 1) || (msg == 0); msg_conv = FundingCreated_clone(&msg_conv); LDKMessageSendEvent *ret_copy = MALLOC(sizeof(LDKMessageSendEvent), "LDKMessageSendEvent"); *ret_copy = MessageSendEvent_send_funding_created(node_id_ref, msg_conv); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_MessageSendEvent_send_funding_signed(int8_tArray node_id, uint32_t msg) { LDKPublicKey node_id_ref; CHECK(*((uint32_t*)node_id) == 33); memcpy(node_id_ref.compressed_form, (uint8_t*)(node_id + 4), 33); LDKFundingSigned msg_conv; msg_conv.inner = (void*)(msg & (~1)); msg_conv.is_owned = (msg & 1) || (msg == 0); msg_conv = FundingSigned_clone(&msg_conv); LDKMessageSendEvent *ret_copy = MALLOC(sizeof(LDKMessageSendEvent), "LDKMessageSendEvent"); *ret_copy = MessageSendEvent_send_funding_signed(node_id_ref, msg_conv); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_MessageSendEvent_send_funding_locked(int8_tArray node_id, uint32_t msg) { LDKPublicKey node_id_ref; CHECK(*((uint32_t*)node_id) == 33); memcpy(node_id_ref.compressed_form, (uint8_t*)(node_id + 4), 33); LDKFundingLocked msg_conv; msg_conv.inner = (void*)(msg & (~1)); msg_conv.is_owned = (msg & 1) || (msg == 0); msg_conv = FundingLocked_clone(&msg_conv); LDKMessageSendEvent *ret_copy = MALLOC(sizeof(LDKMessageSendEvent), "LDKMessageSendEvent"); *ret_copy = MessageSendEvent_send_funding_locked(node_id_ref, msg_conv); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_MessageSendEvent_send_announcement_signatures(int8_tArray node_id, uint32_t msg) { LDKPublicKey node_id_ref; CHECK(*((uint32_t*)node_id) == 33); memcpy(node_id_ref.compressed_form, (uint8_t*)(node_id + 4), 33); LDKAnnouncementSignatures msg_conv; msg_conv.inner = (void*)(msg & (~1)); msg_conv.is_owned = (msg & 1) || (msg == 0); msg_conv = AnnouncementSignatures_clone(&msg_conv); LDKMessageSendEvent *ret_copy = MALLOC(sizeof(LDKMessageSendEvent), "LDKMessageSendEvent"); *ret_copy = MessageSendEvent_send_announcement_signatures(node_id_ref, msg_conv); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_MessageSendEvent_update_htlcs(int8_tArray node_id, uint32_t updates) { LDKPublicKey node_id_ref; CHECK(*((uint32_t*)node_id) == 33); memcpy(node_id_ref.compressed_form, (uint8_t*)(node_id + 4), 33); LDKCommitmentUpdate updates_conv; updates_conv.inner = (void*)(updates & (~1)); updates_conv.is_owned = (updates & 1) || (updates == 0); updates_conv = CommitmentUpdate_clone(&updates_conv); LDKMessageSendEvent *ret_copy = MALLOC(sizeof(LDKMessageSendEvent), "LDKMessageSendEvent"); *ret_copy = MessageSendEvent_update_htlcs(node_id_ref, updates_conv); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_MessageSendEvent_send_revoke_and_ack(int8_tArray node_id, uint32_t msg) { LDKPublicKey node_id_ref; CHECK(*((uint32_t*)node_id) == 33); memcpy(node_id_ref.compressed_form, (uint8_t*)(node_id + 4), 33); LDKRevokeAndACK msg_conv; msg_conv.inner = (void*)(msg & (~1)); msg_conv.is_owned = (msg & 1) || (msg == 0); msg_conv = RevokeAndACK_clone(&msg_conv); LDKMessageSendEvent *ret_copy = MALLOC(sizeof(LDKMessageSendEvent), "LDKMessageSendEvent"); *ret_copy = MessageSendEvent_send_revoke_and_ack(node_id_ref, msg_conv); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_MessageSendEvent_send_closing_signed(int8_tArray node_id, uint32_t msg) { LDKPublicKey node_id_ref; CHECK(*((uint32_t*)node_id) == 33); memcpy(node_id_ref.compressed_form, (uint8_t*)(node_id + 4), 33); LDKClosingSigned msg_conv; msg_conv.inner = (void*)(msg & (~1)); msg_conv.is_owned = (msg & 1) || (msg == 0); msg_conv = ClosingSigned_clone(&msg_conv); LDKMessageSendEvent *ret_copy = MALLOC(sizeof(LDKMessageSendEvent), "LDKMessageSendEvent"); *ret_copy = MessageSendEvent_send_closing_signed(node_id_ref, msg_conv); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_MessageSendEvent_send_shutdown(int8_tArray node_id, uint32_t msg) { LDKPublicKey node_id_ref; CHECK(*((uint32_t*)node_id) == 33); memcpy(node_id_ref.compressed_form, (uint8_t*)(node_id + 4), 33); LDKShutdown msg_conv; msg_conv.inner = (void*)(msg & (~1)); msg_conv.is_owned = (msg & 1) || (msg == 0); msg_conv = Shutdown_clone(&msg_conv); LDKMessageSendEvent *ret_copy = MALLOC(sizeof(LDKMessageSendEvent), "LDKMessageSendEvent"); *ret_copy = MessageSendEvent_send_shutdown(node_id_ref, msg_conv); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_MessageSendEvent_send_channel_reestablish(int8_tArray node_id, uint32_t msg) { LDKPublicKey node_id_ref; CHECK(*((uint32_t*)node_id) == 33); memcpy(node_id_ref.compressed_form, (uint8_t*)(node_id + 4), 33); LDKChannelReestablish msg_conv; msg_conv.inner = (void*)(msg & (~1)); msg_conv.is_owned = (msg & 1) || (msg == 0); msg_conv = ChannelReestablish_clone(&msg_conv); LDKMessageSendEvent *ret_copy = MALLOC(sizeof(LDKMessageSendEvent), "LDKMessageSendEvent"); *ret_copy = MessageSendEvent_send_channel_reestablish(node_id_ref, msg_conv); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_MessageSendEvent_broadcast_channel_announcement(uint32_t msg, uint32_t update_msg) { LDKChannelAnnouncement msg_conv; msg_conv.inner = (void*)(msg & (~1)); msg_conv.is_owned = (msg & 1) || (msg == 0); msg_conv = ChannelAnnouncement_clone(&msg_conv); LDKChannelUpdate update_msg_conv; update_msg_conv.inner = (void*)(update_msg & (~1)); update_msg_conv.is_owned = (update_msg & 1) || (update_msg == 0); update_msg_conv = ChannelUpdate_clone(&update_msg_conv); LDKMessageSendEvent *ret_copy = MALLOC(sizeof(LDKMessageSendEvent), "LDKMessageSendEvent"); *ret_copy = MessageSendEvent_broadcast_channel_announcement(msg_conv, update_msg_conv); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_MessageSendEvent_broadcast_node_announcement(uint32_t msg) { LDKNodeAnnouncement msg_conv; msg_conv.inner = (void*)(msg & (~1)); msg_conv.is_owned = (msg & 1) || (msg == 0); msg_conv = NodeAnnouncement_clone(&msg_conv); LDKMessageSendEvent *ret_copy = MALLOC(sizeof(LDKMessageSendEvent), "LDKMessageSendEvent"); *ret_copy = MessageSendEvent_broadcast_node_announcement(msg_conv); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_MessageSendEvent_broadcast_channel_update(uint32_t msg) { LDKChannelUpdate msg_conv; msg_conv.inner = (void*)(msg & (~1)); msg_conv.is_owned = (msg & 1) || (msg == 0); msg_conv = ChannelUpdate_clone(&msg_conv); LDKMessageSendEvent *ret_copy = MALLOC(sizeof(LDKMessageSendEvent), "LDKMessageSendEvent"); *ret_copy = MessageSendEvent_broadcast_channel_update(msg_conv); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_MessageSendEvent_send_channel_update(int8_tArray node_id, uint32_t msg) { LDKPublicKey node_id_ref; CHECK(*((uint32_t*)node_id) == 33); memcpy(node_id_ref.compressed_form, (uint8_t*)(node_id + 4), 33); LDKChannelUpdate msg_conv; msg_conv.inner = (void*)(msg & (~1)); msg_conv.is_owned = (msg & 1) || (msg == 0); msg_conv = ChannelUpdate_clone(&msg_conv); LDKMessageSendEvent *ret_copy = MALLOC(sizeof(LDKMessageSendEvent), "LDKMessageSendEvent"); *ret_copy = MessageSendEvent_send_channel_update(node_id_ref, msg_conv); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_MessageSendEvent_handle_error(int8_tArray node_id, uint32_t action) { LDKPublicKey node_id_ref; CHECK(*((uint32_t*)node_id) == 33); memcpy(node_id_ref.compressed_form, (uint8_t*)(node_id + 4), 33); LDKErrorAction action_conv = *(LDKErrorAction*)(((uint64_t)action) & ~1); action_conv = ErrorAction_clone((LDKErrorAction*)(((uint64_t)action) & ~1)); LDKMessageSendEvent *ret_copy = MALLOC(sizeof(LDKMessageSendEvent), "LDKMessageSendEvent"); *ret_copy = MessageSendEvent_handle_error(node_id_ref, action_conv); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_MessageSendEvent_send_channel_range_query(int8_tArray node_id, uint32_t msg) { LDKPublicKey node_id_ref; CHECK(*((uint32_t*)node_id) == 33); memcpy(node_id_ref.compressed_form, (uint8_t*)(node_id + 4), 33); LDKQueryChannelRange msg_conv; msg_conv.inner = (void*)(msg & (~1)); msg_conv.is_owned = (msg & 1) || (msg == 0); msg_conv = QueryChannelRange_clone(&msg_conv); LDKMessageSendEvent *ret_copy = MALLOC(sizeof(LDKMessageSendEvent), "LDKMessageSendEvent"); *ret_copy = MessageSendEvent_send_channel_range_query(node_id_ref, msg_conv); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_MessageSendEvent_send_short_ids_query(int8_tArray node_id, uint32_t msg) { LDKPublicKey node_id_ref; CHECK(*((uint32_t*)node_id) == 33); memcpy(node_id_ref.compressed_form, (uint8_t*)(node_id + 4), 33); LDKQueryShortChannelIds msg_conv; msg_conv.inner = (void*)(msg & (~1)); msg_conv.is_owned = (msg & 1) || (msg == 0); msg_conv = QueryShortChannelIds_clone(&msg_conv); LDKMessageSendEvent *ret_copy = MALLOC(sizeof(LDKMessageSendEvent), "LDKMessageSendEvent"); *ret_copy = MessageSendEvent_send_short_ids_query(node_id_ref, msg_conv); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_MessageSendEvent_send_reply_channel_range(int8_tArray node_id, uint32_t msg) { LDKPublicKey node_id_ref; CHECK(*((uint32_t*)node_id) == 33); memcpy(node_id_ref.compressed_form, (uint8_t*)(node_id + 4), 33); LDKReplyChannelRange msg_conv; msg_conv.inner = (void*)(msg & (~1)); msg_conv.is_owned = (msg & 1) || (msg == 0); msg_conv = ReplyChannelRange_clone(&msg_conv); LDKMessageSendEvent *ret_copy = MALLOC(sizeof(LDKMessageSendEvent), "LDKMessageSendEvent"); *ret_copy = MessageSendEvent_send_reply_channel_range(node_id_ref, msg_conv); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } void __attribute__((visibility("default"))) TS_MessageSendEventsProvider_free(uint32_t this_ptr) { if ((this_ptr & 1) != 0) return; LDKMessageSendEventsProvider this_ptr_conv = *(LDKMessageSendEventsProvider*)(((uint64_t)this_ptr) & ~1); FREE((void*)this_ptr); MessageSendEventsProvider_free(this_ptr_conv); } void __attribute__((visibility("default"))) TS_EventsProvider_free(uint32_t this_ptr) { if ((this_ptr & 1) != 0) return; LDKEventsProvider this_ptr_conv = *(LDKEventsProvider*)(((uint64_t)this_ptr) & ~1); FREE((void*)this_ptr); EventsProvider_free(this_ptr_conv); } void __attribute__((visibility("default"))) TS_EventHandler_free(uint32_t this_ptr) { if ((this_ptr & 1) != 0) return; LDKEventHandler this_ptr_conv = *(LDKEventHandler*)(((uint64_t)this_ptr) & ~1); FREE((void*)this_ptr); EventHandler_free(this_ptr_conv); } void __attribute__((visibility("default"))) TS_APIError_free(uint32_t this_ptr) { if ((this_ptr & 1) != 0) return; LDKAPIError this_ptr_conv = *(LDKAPIError*)(((uint64_t)this_ptr) & ~1); FREE((void*)this_ptr); APIError_free(this_ptr_conv); } uint32_t __attribute__((visibility("default"))) TS_APIError_clone(uint32_t orig) { LDKAPIError* orig_conv = (LDKAPIError*)orig; LDKAPIError *ret_copy = MALLOC(sizeof(LDKAPIError), "LDKAPIError"); *ret_copy = APIError_clone(orig_conv); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_APIError_apimisuse_error(jstring err) { LDKStr err_conv = str_ref_to_owned_c(err); LDKAPIError *ret_copy = MALLOC(sizeof(LDKAPIError), "LDKAPIError"); *ret_copy = APIError_apimisuse_error(err_conv); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_APIError_fee_rate_too_high(jstring err, int32_t feerate) { LDKStr err_conv = str_ref_to_owned_c(err); LDKAPIError *ret_copy = MALLOC(sizeof(LDKAPIError), "LDKAPIError"); *ret_copy = APIError_fee_rate_too_high(err_conv, feerate); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_APIError_route_error(jstring err) { LDKStr err_conv = str_ref_to_owned_c(err); LDKAPIError *ret_copy = MALLOC(sizeof(LDKAPIError), "LDKAPIError"); *ret_copy = APIError_route_error(err_conv); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_APIError_channel_unavailable(jstring err) { LDKStr err_conv = str_ref_to_owned_c(err); LDKAPIError *ret_copy = MALLOC(sizeof(LDKAPIError), "LDKAPIError"); *ret_copy = APIError_channel_unavailable(err_conv); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_APIError_monitor_update_failed() { LDKAPIError *ret_copy = MALLOC(sizeof(LDKAPIError), "LDKAPIError"); *ret_copy = APIError_monitor_update_failed(); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_APIError_incompatible_shutdown_script(uint32_t script) { LDKShutdownScript script_conv; script_conv.inner = (void*)(script & (~1)); script_conv.is_owned = (script & 1) || (script == 0); script_conv = ShutdownScript_clone(&script_conv); LDKAPIError *ret_copy = MALLOC(sizeof(LDKAPIError), "LDKAPIError"); *ret_copy = APIError_incompatible_shutdown_script(script_conv); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_sign(int8_tArray msg, int8_tArray sk) { LDKu8slice msg_ref; msg_ref.datalen = *((uint32_t*)msg); msg_ref.data = (int8_t*)(msg + 4); unsigned char sk_arr[32]; CHECK(*((uint32_t*)sk) == 32); memcpy(sk_arr, (uint8_t*)(sk + 4), 32); unsigned char (*sk_ref)[32] = &sk_arr; LDKCResult_StringErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_StringErrorZ), "LDKCResult_StringErrorZ"); *ret_conv = sign(msg_ref, sk_ref); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_recover_pk(int8_tArray msg, jstring sig) { LDKu8slice msg_ref; msg_ref.datalen = *((uint32_t*)msg); msg_ref.data = (int8_t*)(msg + 4); LDKStr sig_conv = str_ref_to_owned_c(sig); LDKCResult_PublicKeyErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_PublicKeyErrorZ), "LDKCResult_PublicKeyErrorZ"); *ret_conv = recover_pk(msg_ref, sig_conv); return (uint64_t)ret_conv; } jboolean __attribute__((visibility("default"))) TS_verify(int8_tArray msg, jstring sig, int8_tArray pk) { LDKu8slice msg_ref; msg_ref.datalen = *((uint32_t*)msg); msg_ref.data = (int8_t*)(msg + 4); LDKStr sig_conv = str_ref_to_owned_c(sig); LDKPublicKey pk_ref; CHECK(*((uint32_t*)pk) == 33); memcpy(pk_ref.compressed_form, (uint8_t*)(pk + 4), 33); jboolean ret_val = verify(msg_ref, sig_conv, pk_ref); return ret_val; } uint32_t __attribute__((visibility("default"))) TS_Level_clone(uint32_t orig) { LDKLevel* orig_conv = (LDKLevel*)(orig & ~1); uint32_t ret_conv = LDKLevel_to_js(Level_clone(orig_conv)); return ret_conv; } uint32_t __attribute__((visibility("default"))) TS_Level_trace() { uint32_t ret_conv = LDKLevel_to_js(Level_trace()); return ret_conv; } uint32_t __attribute__((visibility("default"))) TS_Level_debug() { uint32_t ret_conv = LDKLevel_to_js(Level_debug()); return ret_conv; } uint32_t __attribute__((visibility("default"))) TS_Level_info() { uint32_t ret_conv = LDKLevel_to_js(Level_info()); return ret_conv; } uint32_t __attribute__((visibility("default"))) TS_Level_warn() { uint32_t ret_conv = LDKLevel_to_js(Level_warn()); return ret_conv; } uint32_t __attribute__((visibility("default"))) TS_Level_error() { uint32_t ret_conv = LDKLevel_to_js(Level_error()); return ret_conv; } jboolean __attribute__((visibility("default"))) TS_Level_eq(uint32_t a, uint32_t b) { LDKLevel* a_conv = (LDKLevel*)(a & ~1); LDKLevel* b_conv = (LDKLevel*)(b & ~1); jboolean ret_val = Level_eq(a_conv, b_conv); return ret_val; } int64_t __attribute__((visibility("default"))) TS_Level_hash(uint32_t o) { LDKLevel* o_conv = (LDKLevel*)(o & ~1); int64_t ret_val = Level_hash(o_conv); return ret_val; } uint32_t __attribute__((visibility("default"))) TS_Level_max() { uint32_t ret_conv = LDKLevel_to_js(Level_max()); return ret_conv; } void __attribute__((visibility("default"))) TS_Logger_free(uint32_t this_ptr) { if ((this_ptr & 1) != 0) return; LDKLogger this_ptr_conv = *(LDKLogger*)(((uint64_t)this_ptr) & ~1); FREE((void*)this_ptr); Logger_free(this_ptr_conv); } void __attribute__((visibility("default"))) TS_ChannelHandshakeConfig_free(uint32_t this_obj) { LDKChannelHandshakeConfig this_obj_conv; this_obj_conv.inner = (void*)(this_obj & (~1)); this_obj_conv.is_owned = (this_obj & 1) || (this_obj == 0); ChannelHandshakeConfig_free(this_obj_conv); } int32_t __attribute__((visibility("default"))) TS_ChannelHandshakeConfig_get_minimum_depth(uint32_t this_ptr) { LDKChannelHandshakeConfig this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int32_t ret_val = ChannelHandshakeConfig_get_minimum_depth(&this_ptr_conv); return ret_val; } void __attribute__((visibility("default"))) TS_ChannelHandshakeConfig_set_minimum_depth(uint32_t this_ptr, int32_t val) { LDKChannelHandshakeConfig this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; ChannelHandshakeConfig_set_minimum_depth(&this_ptr_conv, val); } int16_t __attribute__((visibility("default"))) TS_ChannelHandshakeConfig_get_our_to_self_delay(uint32_t this_ptr) { LDKChannelHandshakeConfig this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int16_t ret_val = ChannelHandshakeConfig_get_our_to_self_delay(&this_ptr_conv); return ret_val; } void __attribute__((visibility("default"))) TS_ChannelHandshakeConfig_set_our_to_self_delay(uint32_t this_ptr, int16_t val) { LDKChannelHandshakeConfig this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; ChannelHandshakeConfig_set_our_to_self_delay(&this_ptr_conv, val); } int64_t __attribute__((visibility("default"))) TS_ChannelHandshakeConfig_get_our_htlc_minimum_msat(uint32_t this_ptr) { LDKChannelHandshakeConfig this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int64_t ret_val = ChannelHandshakeConfig_get_our_htlc_minimum_msat(&this_ptr_conv); return ret_val; } void __attribute__((visibility("default"))) TS_ChannelHandshakeConfig_set_our_htlc_minimum_msat(uint32_t this_ptr, int64_t val) { LDKChannelHandshakeConfig this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; ChannelHandshakeConfig_set_our_htlc_minimum_msat(&this_ptr_conv, val); } uint32_t __attribute__((visibility("default"))) TS_ChannelHandshakeConfig_new(int32_t minimum_depth_arg, int16_t our_to_self_delay_arg, int64_t our_htlc_minimum_msat_arg) { LDKChannelHandshakeConfig ret_var = ChannelHandshakeConfig_new(minimum_depth_arg, our_to_self_delay_arg, our_htlc_minimum_msat_arg); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_ChannelHandshakeConfig_clone(uint32_t orig) { LDKChannelHandshakeConfig orig_conv; orig_conv.inner = (void*)(orig & (~1)); orig_conv.is_owned = false; LDKChannelHandshakeConfig ret_var = ChannelHandshakeConfig_clone(&orig_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_ChannelHandshakeConfig_default() { LDKChannelHandshakeConfig ret_var = ChannelHandshakeConfig_default(); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } void __attribute__((visibility("default"))) TS_ChannelHandshakeLimits_free(uint32_t this_obj) { LDKChannelHandshakeLimits this_obj_conv; this_obj_conv.inner = (void*)(this_obj & (~1)); this_obj_conv.is_owned = (this_obj & 1) || (this_obj == 0); ChannelHandshakeLimits_free(this_obj_conv); } int64_t __attribute__((visibility("default"))) TS_ChannelHandshakeLimits_get_min_funding_satoshis(uint32_t this_ptr) { LDKChannelHandshakeLimits this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int64_t ret_val = ChannelHandshakeLimits_get_min_funding_satoshis(&this_ptr_conv); return ret_val; } void __attribute__((visibility("default"))) TS_ChannelHandshakeLimits_set_min_funding_satoshis(uint32_t this_ptr, int64_t val) { LDKChannelHandshakeLimits this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; ChannelHandshakeLimits_set_min_funding_satoshis(&this_ptr_conv, val); } int64_t __attribute__((visibility("default"))) TS_ChannelHandshakeLimits_get_max_htlc_minimum_msat(uint32_t this_ptr) { LDKChannelHandshakeLimits this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int64_t ret_val = ChannelHandshakeLimits_get_max_htlc_minimum_msat(&this_ptr_conv); return ret_val; } void __attribute__((visibility("default"))) TS_ChannelHandshakeLimits_set_max_htlc_minimum_msat(uint32_t this_ptr, int64_t val) { LDKChannelHandshakeLimits this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; ChannelHandshakeLimits_set_max_htlc_minimum_msat(&this_ptr_conv, val); } int64_t __attribute__((visibility("default"))) TS_ChannelHandshakeLimits_get_min_max_htlc_value_in_flight_msat(uint32_t this_ptr) { LDKChannelHandshakeLimits this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int64_t ret_val = ChannelHandshakeLimits_get_min_max_htlc_value_in_flight_msat(&this_ptr_conv); return ret_val; } void __attribute__((visibility("default"))) TS_ChannelHandshakeLimits_set_min_max_htlc_value_in_flight_msat(uint32_t this_ptr, int64_t val) { LDKChannelHandshakeLimits this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; ChannelHandshakeLimits_set_min_max_htlc_value_in_flight_msat(&this_ptr_conv, val); } int64_t __attribute__((visibility("default"))) TS_ChannelHandshakeLimits_get_max_channel_reserve_satoshis(uint32_t this_ptr) { LDKChannelHandshakeLimits this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int64_t ret_val = ChannelHandshakeLimits_get_max_channel_reserve_satoshis(&this_ptr_conv); return ret_val; } void __attribute__((visibility("default"))) TS_ChannelHandshakeLimits_set_max_channel_reserve_satoshis(uint32_t this_ptr, int64_t val) { LDKChannelHandshakeLimits this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; ChannelHandshakeLimits_set_max_channel_reserve_satoshis(&this_ptr_conv, val); } int16_t __attribute__((visibility("default"))) TS_ChannelHandshakeLimits_get_min_max_accepted_htlcs(uint32_t this_ptr) { LDKChannelHandshakeLimits this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int16_t ret_val = ChannelHandshakeLimits_get_min_max_accepted_htlcs(&this_ptr_conv); return ret_val; } void __attribute__((visibility("default"))) TS_ChannelHandshakeLimits_set_min_max_accepted_htlcs(uint32_t this_ptr, int16_t val) { LDKChannelHandshakeLimits this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; ChannelHandshakeLimits_set_min_max_accepted_htlcs(&this_ptr_conv, val); } int32_t __attribute__((visibility("default"))) TS_ChannelHandshakeLimits_get_max_minimum_depth(uint32_t this_ptr) { LDKChannelHandshakeLimits this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int32_t ret_val = ChannelHandshakeLimits_get_max_minimum_depth(&this_ptr_conv); return ret_val; } void __attribute__((visibility("default"))) TS_ChannelHandshakeLimits_set_max_minimum_depth(uint32_t this_ptr, int32_t val) { LDKChannelHandshakeLimits this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; ChannelHandshakeLimits_set_max_minimum_depth(&this_ptr_conv, val); } jboolean __attribute__((visibility("default"))) TS_ChannelHandshakeLimits_get_force_announced_channel_preference(uint32_t this_ptr) { LDKChannelHandshakeLimits this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; jboolean ret_val = ChannelHandshakeLimits_get_force_announced_channel_preference(&this_ptr_conv); return ret_val; } void __attribute__((visibility("default"))) TS_ChannelHandshakeLimits_set_force_announced_channel_preference(uint32_t this_ptr, jboolean val) { LDKChannelHandshakeLimits this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; ChannelHandshakeLimits_set_force_announced_channel_preference(&this_ptr_conv, val); } int16_t __attribute__((visibility("default"))) TS_ChannelHandshakeLimits_get_their_to_self_delay(uint32_t this_ptr) { LDKChannelHandshakeLimits this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int16_t ret_val = ChannelHandshakeLimits_get_their_to_self_delay(&this_ptr_conv); return ret_val; } void __attribute__((visibility("default"))) TS_ChannelHandshakeLimits_set_their_to_self_delay(uint32_t this_ptr, int16_t val) { LDKChannelHandshakeLimits this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; ChannelHandshakeLimits_set_their_to_self_delay(&this_ptr_conv, val); } uint32_t __attribute__((visibility("default"))) TS_ChannelHandshakeLimits_new(int64_t min_funding_satoshis_arg, int64_t max_htlc_minimum_msat_arg, int64_t min_max_htlc_value_in_flight_msat_arg, int64_t max_channel_reserve_satoshis_arg, int16_t min_max_accepted_htlcs_arg, int32_t max_minimum_depth_arg, jboolean force_announced_channel_preference_arg, int16_t their_to_self_delay_arg) { LDKChannelHandshakeLimits ret_var = ChannelHandshakeLimits_new(min_funding_satoshis_arg, max_htlc_minimum_msat_arg, min_max_htlc_value_in_flight_msat_arg, max_channel_reserve_satoshis_arg, min_max_accepted_htlcs_arg, max_minimum_depth_arg, force_announced_channel_preference_arg, their_to_self_delay_arg); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_ChannelHandshakeLimits_clone(uint32_t orig) { LDKChannelHandshakeLimits orig_conv; orig_conv.inner = (void*)(orig & (~1)); orig_conv.is_owned = false; LDKChannelHandshakeLimits ret_var = ChannelHandshakeLimits_clone(&orig_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_ChannelHandshakeLimits_default() { LDKChannelHandshakeLimits ret_var = ChannelHandshakeLimits_default(); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } void __attribute__((visibility("default"))) TS_ChannelConfig_free(uint32_t this_obj) { LDKChannelConfig this_obj_conv; this_obj_conv.inner = (void*)(this_obj & (~1)); this_obj_conv.is_owned = (this_obj & 1) || (this_obj == 0); ChannelConfig_free(this_obj_conv); } int32_t __attribute__((visibility("default"))) TS_ChannelConfig_get_forwarding_fee_proportional_millionths(uint32_t this_ptr) { LDKChannelConfig this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int32_t ret_val = ChannelConfig_get_forwarding_fee_proportional_millionths(&this_ptr_conv); return ret_val; } void __attribute__((visibility("default"))) TS_ChannelConfig_set_forwarding_fee_proportional_millionths(uint32_t this_ptr, int32_t val) { LDKChannelConfig this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; ChannelConfig_set_forwarding_fee_proportional_millionths(&this_ptr_conv, val); } int32_t __attribute__((visibility("default"))) TS_ChannelConfig_get_forwarding_fee_base_msat(uint32_t this_ptr) { LDKChannelConfig this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int32_t ret_val = ChannelConfig_get_forwarding_fee_base_msat(&this_ptr_conv); return ret_val; } void __attribute__((visibility("default"))) TS_ChannelConfig_set_forwarding_fee_base_msat(uint32_t this_ptr, int32_t val) { LDKChannelConfig this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; ChannelConfig_set_forwarding_fee_base_msat(&this_ptr_conv, val); } int16_t __attribute__((visibility("default"))) TS_ChannelConfig_get_cltv_expiry_delta(uint32_t this_ptr) { LDKChannelConfig this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int16_t ret_val = ChannelConfig_get_cltv_expiry_delta(&this_ptr_conv); return ret_val; } void __attribute__((visibility("default"))) TS_ChannelConfig_set_cltv_expiry_delta(uint32_t this_ptr, int16_t val) { LDKChannelConfig this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; ChannelConfig_set_cltv_expiry_delta(&this_ptr_conv, val); } jboolean __attribute__((visibility("default"))) TS_ChannelConfig_get_announced_channel(uint32_t this_ptr) { LDKChannelConfig this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; jboolean ret_val = ChannelConfig_get_announced_channel(&this_ptr_conv); return ret_val; } void __attribute__((visibility("default"))) TS_ChannelConfig_set_announced_channel(uint32_t this_ptr, jboolean val) { LDKChannelConfig this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; ChannelConfig_set_announced_channel(&this_ptr_conv, val); } jboolean __attribute__((visibility("default"))) TS_ChannelConfig_get_commit_upfront_shutdown_pubkey(uint32_t this_ptr) { LDKChannelConfig this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; jboolean ret_val = ChannelConfig_get_commit_upfront_shutdown_pubkey(&this_ptr_conv); return ret_val; } void __attribute__((visibility("default"))) TS_ChannelConfig_set_commit_upfront_shutdown_pubkey(uint32_t this_ptr, jboolean val) { LDKChannelConfig this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; ChannelConfig_set_commit_upfront_shutdown_pubkey(&this_ptr_conv, val); } int64_t __attribute__((visibility("default"))) TS_ChannelConfig_get_max_dust_htlc_exposure_msat(uint32_t this_ptr) { LDKChannelConfig this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int64_t ret_val = ChannelConfig_get_max_dust_htlc_exposure_msat(&this_ptr_conv); return ret_val; } void __attribute__((visibility("default"))) TS_ChannelConfig_set_max_dust_htlc_exposure_msat(uint32_t this_ptr, int64_t val) { LDKChannelConfig this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; ChannelConfig_set_max_dust_htlc_exposure_msat(&this_ptr_conv, val); } int64_t __attribute__((visibility("default"))) TS_ChannelConfig_get_force_close_avoidance_max_fee_satoshis(uint32_t this_ptr) { LDKChannelConfig this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int64_t ret_val = ChannelConfig_get_force_close_avoidance_max_fee_satoshis(&this_ptr_conv); return ret_val; } void __attribute__((visibility("default"))) TS_ChannelConfig_set_force_close_avoidance_max_fee_satoshis(uint32_t this_ptr, int64_t val) { LDKChannelConfig this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; ChannelConfig_set_force_close_avoidance_max_fee_satoshis(&this_ptr_conv, val); } uint32_t __attribute__((visibility("default"))) TS_ChannelConfig_new(int32_t forwarding_fee_proportional_millionths_arg, int32_t forwarding_fee_base_msat_arg, int16_t cltv_expiry_delta_arg, jboolean announced_channel_arg, jboolean commit_upfront_shutdown_pubkey_arg, int64_t max_dust_htlc_exposure_msat_arg, int64_t force_close_avoidance_max_fee_satoshis_arg) { LDKChannelConfig ret_var = ChannelConfig_new(forwarding_fee_proportional_millionths_arg, forwarding_fee_base_msat_arg, cltv_expiry_delta_arg, announced_channel_arg, commit_upfront_shutdown_pubkey_arg, max_dust_htlc_exposure_msat_arg, force_close_avoidance_max_fee_satoshis_arg); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_ChannelConfig_clone(uint32_t orig) { LDKChannelConfig orig_conv; orig_conv.inner = (void*)(orig & (~1)); orig_conv.is_owned = false; LDKChannelConfig ret_var = ChannelConfig_clone(&orig_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_ChannelConfig_default() { LDKChannelConfig ret_var = ChannelConfig_default(); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } int8_tArray __attribute__((visibility("default"))) TS_ChannelConfig_write(uint32_t obj) { LDKChannelConfig obj_conv; obj_conv.inner = (void*)(obj & (~1)); obj_conv.is_owned = false; LDKCVec_u8Z ret_var = ChannelConfig_write(&obj_conv); int8_tArray ret_arr = init_arr(ret_var.datalen, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), ret_var.data, ret_var.datalen); CVec_u8Z_free(ret_var); return ret_arr; } uint32_t __attribute__((visibility("default"))) TS_ChannelConfig_read(int8_tArray ser) { LDKu8slice ser_ref; ser_ref.datalen = *((uint32_t*)ser); ser_ref.data = (int8_t*)(ser + 4); LDKCResult_ChannelConfigDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_ChannelConfigDecodeErrorZ), "LDKCResult_ChannelConfigDecodeErrorZ"); *ret_conv = ChannelConfig_read(ser_ref); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_UserConfig_free(uint32_t this_obj) { LDKUserConfig this_obj_conv; this_obj_conv.inner = (void*)(this_obj & (~1)); this_obj_conv.is_owned = (this_obj & 1) || (this_obj == 0); UserConfig_free(this_obj_conv); } uint32_t __attribute__((visibility("default"))) TS_UserConfig_get_own_channel_config(uint32_t this_ptr) { LDKUserConfig this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKChannelHandshakeConfig ret_var = UserConfig_get_own_channel_config(&this_ptr_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } void __attribute__((visibility("default"))) TS_UserConfig_set_own_channel_config(uint32_t this_ptr, uint32_t val) { LDKUserConfig this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKChannelHandshakeConfig val_conv; val_conv.inner = (void*)(val & (~1)); val_conv.is_owned = (val & 1) || (val == 0); val_conv = ChannelHandshakeConfig_clone(&val_conv); UserConfig_set_own_channel_config(&this_ptr_conv, val_conv); } uint32_t __attribute__((visibility("default"))) TS_UserConfig_get_peer_channel_config_limits(uint32_t this_ptr) { LDKUserConfig this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKChannelHandshakeLimits ret_var = UserConfig_get_peer_channel_config_limits(&this_ptr_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } void __attribute__((visibility("default"))) TS_UserConfig_set_peer_channel_config_limits(uint32_t this_ptr, uint32_t val) { LDKUserConfig this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKChannelHandshakeLimits val_conv; val_conv.inner = (void*)(val & (~1)); val_conv.is_owned = (val & 1) || (val == 0); val_conv = ChannelHandshakeLimits_clone(&val_conv); UserConfig_set_peer_channel_config_limits(&this_ptr_conv, val_conv); } uint32_t __attribute__((visibility("default"))) TS_UserConfig_get_channel_options(uint32_t this_ptr) { LDKUserConfig this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKChannelConfig ret_var = UserConfig_get_channel_options(&this_ptr_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } void __attribute__((visibility("default"))) TS_UserConfig_set_channel_options(uint32_t this_ptr, uint32_t val) { LDKUserConfig this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKChannelConfig val_conv; val_conv.inner = (void*)(val & (~1)); val_conv.is_owned = (val & 1) || (val == 0); val_conv = ChannelConfig_clone(&val_conv); UserConfig_set_channel_options(&this_ptr_conv, val_conv); } jboolean __attribute__((visibility("default"))) TS_UserConfig_get_accept_forwards_to_priv_channels(uint32_t this_ptr) { LDKUserConfig this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; jboolean ret_val = UserConfig_get_accept_forwards_to_priv_channels(&this_ptr_conv); return ret_val; } void __attribute__((visibility("default"))) TS_UserConfig_set_accept_forwards_to_priv_channels(uint32_t this_ptr, jboolean val) { LDKUserConfig this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; UserConfig_set_accept_forwards_to_priv_channels(&this_ptr_conv, val); } uint32_t __attribute__((visibility("default"))) TS_UserConfig_new(uint32_t own_channel_config_arg, uint32_t peer_channel_config_limits_arg, uint32_t channel_options_arg, jboolean accept_forwards_to_priv_channels_arg) { LDKChannelHandshakeConfig own_channel_config_arg_conv; own_channel_config_arg_conv.inner = (void*)(own_channel_config_arg & (~1)); own_channel_config_arg_conv.is_owned = (own_channel_config_arg & 1) || (own_channel_config_arg == 0); own_channel_config_arg_conv = ChannelHandshakeConfig_clone(&own_channel_config_arg_conv); LDKChannelHandshakeLimits peer_channel_config_limits_arg_conv; peer_channel_config_limits_arg_conv.inner = (void*)(peer_channel_config_limits_arg & (~1)); peer_channel_config_limits_arg_conv.is_owned = (peer_channel_config_limits_arg & 1) || (peer_channel_config_limits_arg == 0); peer_channel_config_limits_arg_conv = ChannelHandshakeLimits_clone(&peer_channel_config_limits_arg_conv); LDKChannelConfig channel_options_arg_conv; channel_options_arg_conv.inner = (void*)(channel_options_arg & (~1)); channel_options_arg_conv.is_owned = (channel_options_arg & 1) || (channel_options_arg == 0); channel_options_arg_conv = ChannelConfig_clone(&channel_options_arg_conv); LDKUserConfig ret_var = UserConfig_new(own_channel_config_arg_conv, peer_channel_config_limits_arg_conv, channel_options_arg_conv, accept_forwards_to_priv_channels_arg); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_UserConfig_clone(uint32_t orig) { LDKUserConfig orig_conv; orig_conv.inner = (void*)(orig & (~1)); orig_conv.is_owned = false; LDKUserConfig ret_var = UserConfig_clone(&orig_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_UserConfig_default() { LDKUserConfig ret_var = UserConfig_default(); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } void __attribute__((visibility("default"))) TS_BestBlock_free(uint32_t this_obj) { LDKBestBlock this_obj_conv; this_obj_conv.inner = (void*)(this_obj & (~1)); this_obj_conv.is_owned = (this_obj & 1) || (this_obj == 0); BestBlock_free(this_obj_conv); } uint32_t __attribute__((visibility("default"))) TS_BestBlock_clone(uint32_t orig) { LDKBestBlock orig_conv; orig_conv.inner = (void*)(orig & (~1)); orig_conv.is_owned = false; LDKBestBlock ret_var = BestBlock_clone(&orig_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_BestBlock_from_genesis(uint32_t network) { LDKNetwork network_conv = LDKNetwork_from_js(network); LDKBestBlock ret_var = BestBlock_from_genesis(network_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_BestBlock_new(int8_tArray block_hash, int32_t height) { LDKThirtyTwoBytes block_hash_ref; CHECK(*((uint32_t*)block_hash) == 32); memcpy(block_hash_ref.data, (uint8_t*)(block_hash + 4), 32); LDKBestBlock ret_var = BestBlock_new(block_hash_ref, height); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } int8_tArray __attribute__((visibility("default"))) TS_BestBlock_block_hash(uint32_t this_arg) { LDKBestBlock this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; int8_tArray ret_arr = init_arr(32, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), BestBlock_block_hash(&this_arg_conv).data, 32); return ret_arr; } int32_t __attribute__((visibility("default"))) TS_BestBlock_height(uint32_t this_arg) { LDKBestBlock this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; int32_t ret_val = BestBlock_height(&this_arg_conv); return ret_val; } uint32_t __attribute__((visibility("default"))) TS_AccessError_clone(uint32_t orig) { LDKAccessError* orig_conv = (LDKAccessError*)(orig & ~1); uint32_t ret_conv = LDKAccessError_to_js(AccessError_clone(orig_conv)); return ret_conv; } uint32_t __attribute__((visibility("default"))) TS_AccessError_unknown_chain() { uint32_t ret_conv = LDKAccessError_to_js(AccessError_unknown_chain()); return ret_conv; } uint32_t __attribute__((visibility("default"))) TS_AccessError_unknown_tx() { uint32_t ret_conv = LDKAccessError_to_js(AccessError_unknown_tx()); return ret_conv; } void __attribute__((visibility("default"))) TS_Access_free(uint32_t this_ptr) { if ((this_ptr & 1) != 0) return; LDKAccess this_ptr_conv = *(LDKAccess*)(((uint64_t)this_ptr) & ~1); FREE((void*)this_ptr); Access_free(this_ptr_conv); } void __attribute__((visibility("default"))) TS_Listen_free(uint32_t this_ptr) { if ((this_ptr & 1) != 0) return; LDKListen this_ptr_conv = *(LDKListen*)(((uint64_t)this_ptr) & ~1); FREE((void*)this_ptr); Listen_free(this_ptr_conv); } void __attribute__((visibility("default"))) TS_Confirm_free(uint32_t this_ptr) { if ((this_ptr & 1) != 0) return; LDKConfirm this_ptr_conv = *(LDKConfirm*)(((uint64_t)this_ptr) & ~1); FREE((void*)this_ptr); Confirm_free(this_ptr_conv); } void __attribute__((visibility("default"))) TS_Watch_free(uint32_t this_ptr) { if ((this_ptr & 1) != 0) return; LDKWatch this_ptr_conv = *(LDKWatch*)(((uint64_t)this_ptr) & ~1); FREE((void*)this_ptr); Watch_free(this_ptr_conv); } void __attribute__((visibility("default"))) TS_Filter_free(uint32_t this_ptr) { if ((this_ptr & 1) != 0) return; LDKFilter this_ptr_conv = *(LDKFilter*)(((uint64_t)this_ptr) & ~1); FREE((void*)this_ptr); Filter_free(this_ptr_conv); } void __attribute__((visibility("default"))) TS_WatchedOutput_free(uint32_t this_obj) { LDKWatchedOutput this_obj_conv; this_obj_conv.inner = (void*)(this_obj & (~1)); this_obj_conv.is_owned = (this_obj & 1) || (this_obj == 0); WatchedOutput_free(this_obj_conv); } int8_tArray __attribute__((visibility("default"))) TS_WatchedOutput_get_block_hash(uint32_t this_ptr) { LDKWatchedOutput this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int8_tArray ret_arr = init_arr(32, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), WatchedOutput_get_block_hash(&this_ptr_conv).data, 32); return ret_arr; } void __attribute__((visibility("default"))) TS_WatchedOutput_set_block_hash(uint32_t this_ptr, int8_tArray val) { LDKWatchedOutput this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKThirtyTwoBytes val_ref; CHECK(*((uint32_t*)val) == 32); memcpy(val_ref.data, (uint8_t*)(val + 4), 32); WatchedOutput_set_block_hash(&this_ptr_conv, val_ref); } uint32_t __attribute__((visibility("default"))) TS_WatchedOutput_get_outpoint(uint32_t this_ptr) { LDKWatchedOutput this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKOutPoint ret_var = WatchedOutput_get_outpoint(&this_ptr_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } void __attribute__((visibility("default"))) TS_WatchedOutput_set_outpoint(uint32_t this_ptr, uint32_t val) { LDKWatchedOutput this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKOutPoint val_conv; val_conv.inner = (void*)(val & (~1)); val_conv.is_owned = (val & 1) || (val == 0); val_conv = OutPoint_clone(&val_conv); WatchedOutput_set_outpoint(&this_ptr_conv, val_conv); } int8_tArray __attribute__((visibility("default"))) TS_WatchedOutput_get_script_pubkey(uint32_t this_ptr) { LDKWatchedOutput this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKu8slice ret_var = WatchedOutput_get_script_pubkey(&this_ptr_conv); int8_tArray ret_arr = init_arr(ret_var.datalen, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), ret_var.data, ret_var.datalen); return ret_arr; } void __attribute__((visibility("default"))) TS_WatchedOutput_set_script_pubkey(uint32_t this_ptr, int8_tArray val) { LDKWatchedOutput this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKCVec_u8Z val_ref; val_ref.datalen = *((uint32_t*)val); val_ref.data = MALLOC(val_ref.datalen, "LDKCVec_u8Z Bytes"); memcpy(val_ref.data, (uint8_t*)(val + 4), val_ref.datalen); WatchedOutput_set_script_pubkey(&this_ptr_conv, val_ref); } uint32_t __attribute__((visibility("default"))) TS_WatchedOutput_new(int8_tArray block_hash_arg, uint32_t outpoint_arg, int8_tArray script_pubkey_arg) { LDKThirtyTwoBytes block_hash_arg_ref; CHECK(*((uint32_t*)block_hash_arg) == 32); memcpy(block_hash_arg_ref.data, (uint8_t*)(block_hash_arg + 4), 32); LDKOutPoint outpoint_arg_conv; outpoint_arg_conv.inner = (void*)(outpoint_arg & (~1)); outpoint_arg_conv.is_owned = (outpoint_arg & 1) || (outpoint_arg == 0); outpoint_arg_conv = OutPoint_clone(&outpoint_arg_conv); LDKCVec_u8Z script_pubkey_arg_ref; script_pubkey_arg_ref.datalen = *((uint32_t*)script_pubkey_arg); script_pubkey_arg_ref.data = MALLOC(script_pubkey_arg_ref.datalen, "LDKCVec_u8Z Bytes"); memcpy(script_pubkey_arg_ref.data, (uint8_t*)(script_pubkey_arg + 4), script_pubkey_arg_ref.datalen); LDKWatchedOutput ret_var = WatchedOutput_new(block_hash_arg_ref, outpoint_arg_conv, script_pubkey_arg_ref); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_WatchedOutput_clone(uint32_t orig) { LDKWatchedOutput orig_conv; orig_conv.inner = (void*)(orig & (~1)); orig_conv.is_owned = false; LDKWatchedOutput ret_var = WatchedOutput_clone(&orig_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } int64_t __attribute__((visibility("default"))) TS_WatchedOutput_hash(uint32_t o) { LDKWatchedOutput o_conv; o_conv.inner = (void*)(o & (~1)); o_conv.is_owned = false; int64_t ret_val = WatchedOutput_hash(&o_conv); return ret_val; } void __attribute__((visibility("default"))) TS_BroadcasterInterface_free(uint32_t this_ptr) { if ((this_ptr & 1) != 0) return; LDKBroadcasterInterface this_ptr_conv = *(LDKBroadcasterInterface*)(((uint64_t)this_ptr) & ~1); FREE((void*)this_ptr); BroadcasterInterface_free(this_ptr_conv); } uint32_t __attribute__((visibility("default"))) TS_ConfirmationTarget_clone(uint32_t orig) { LDKConfirmationTarget* orig_conv = (LDKConfirmationTarget*)(orig & ~1); uint32_t ret_conv = LDKConfirmationTarget_to_js(ConfirmationTarget_clone(orig_conv)); return ret_conv; } uint32_t __attribute__((visibility("default"))) TS_ConfirmationTarget_background() { uint32_t ret_conv = LDKConfirmationTarget_to_js(ConfirmationTarget_background()); return ret_conv; } uint32_t __attribute__((visibility("default"))) TS_ConfirmationTarget_normal() { uint32_t ret_conv = LDKConfirmationTarget_to_js(ConfirmationTarget_normal()); return ret_conv; } uint32_t __attribute__((visibility("default"))) TS_ConfirmationTarget_high_priority() { uint32_t ret_conv = LDKConfirmationTarget_to_js(ConfirmationTarget_high_priority()); return ret_conv; } jboolean __attribute__((visibility("default"))) TS_ConfirmationTarget_eq(uint32_t a, uint32_t b) { LDKConfirmationTarget* a_conv = (LDKConfirmationTarget*)(a & ~1); LDKConfirmationTarget* b_conv = (LDKConfirmationTarget*)(b & ~1); jboolean ret_val = ConfirmationTarget_eq(a_conv, b_conv); return ret_val; } void __attribute__((visibility("default"))) TS_FeeEstimator_free(uint32_t this_ptr) { if ((this_ptr & 1) != 0) return; LDKFeeEstimator this_ptr_conv = *(LDKFeeEstimator*)(((uint64_t)this_ptr) & ~1); FREE((void*)this_ptr); FeeEstimator_free(this_ptr_conv); } void __attribute__((visibility("default"))) TS_ChainMonitor_free(uint32_t this_obj) { LDKChainMonitor this_obj_conv; this_obj_conv.inner = (void*)(this_obj & (~1)); this_obj_conv.is_owned = (this_obj & 1) || (this_obj == 0); ChainMonitor_free(this_obj_conv); } uint32_t __attribute__((visibility("default"))) TS_ChainMonitor_new(uint32_t chain_source, uint32_t broadcaster, uint32_t logger, uint32_t feeest, uint32_t persister) { LDKCOption_FilterZ chain_source_conv = *(LDKCOption_FilterZ*)(((uint64_t)chain_source) & ~1); // Warning: we may need a move here but no clone is available for LDKCOption_FilterZ if (chain_source_conv.tag == LDKCOption_FilterZ_Some) { // Manually implement clone for Java trait instances } LDKBroadcasterInterface broadcaster_conv = *(LDKBroadcasterInterface*)(((uint64_t)broadcaster) & ~1); LDKLogger logger_conv = *(LDKLogger*)(((uint64_t)logger) & ~1); LDKFeeEstimator feeest_conv = *(LDKFeeEstimator*)(((uint64_t)feeest) & ~1); LDKPersist persister_conv = *(LDKPersist*)(((uint64_t)persister) & ~1); LDKChainMonitor ret_var = ChainMonitor_new(chain_source_conv, broadcaster_conv, logger_conv, feeest_conv, persister_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } uint32_tArray __attribute__((visibility("default"))) TS_ChainMonitor_get_claimable_balances(uint32_t this_arg, uint32_tArray ignored_channels) { LDKChainMonitor this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; LDKCVec_ChannelDetailsZ ignored_channels_constr; ignored_channels_constr.datalen = *((uint32_t*)ignored_channels); if (ignored_channels_constr.datalen > 0) ignored_channels_constr.data = MALLOC(ignored_channels_constr.datalen * sizeof(LDKChannelDetails), "LDKCVec_ChannelDetailsZ Elements"); else ignored_channels_constr.data = NULL; uint32_t* ignored_channels_vals = (uint32_t*)(ignored_channels + 4); for (size_t q = 0; q < ignored_channels_constr.datalen; q++) { uint32_t ignored_channels_conv_16 = ignored_channels_vals[q]; LDKChannelDetails ignored_channels_conv_16_conv; ignored_channels_conv_16_conv.inner = (void*)(ignored_channels_conv_16 & (~1)); ignored_channels_conv_16_conv.is_owned = (ignored_channels_conv_16 & 1) || (ignored_channels_conv_16 == 0); ignored_channels_conv_16_conv = ChannelDetails_clone(&ignored_channels_conv_16_conv); ignored_channels_constr.data[q] = ignored_channels_conv_16_conv; } LDKCVec_BalanceZ ret_var = ChainMonitor_get_claimable_balances(&this_arg_conv, ignored_channels_constr); uint32_tArray ret_arr = init_arr(ret_var.datalen, sizeof(uint32_t), "Native uint32_tArray Bytes"); uint32_t *ret_arr_ptr = (uint32_t*)(ret_arr + 4); for (size_t j = 0; j < ret_var.datalen; j++) { LDKBalance *ret_conv_9_copy = MALLOC(sizeof(LDKBalance), "LDKBalance"); *ret_conv_9_copy = Balance_clone(&ret_var.data[j]); uint64_t ret_conv_9_ref = (uint64_t)ret_conv_9_copy; ret_arr_ptr[j] = ret_conv_9_ref; } FREE(ret_var.data); return ret_arr; } uint32_t __attribute__((visibility("default"))) TS_ChainMonitor_as_Listen(uint32_t this_arg) { LDKChainMonitor this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; LDKListen* ret_ret =MALLOC(sizeof(LDKListen), "LDKListen"); *ret_ret = ChainMonitor_as_Listen(&this_arg_conv); return (uint64_t)ret_ret; } uint32_t __attribute__((visibility("default"))) TS_ChainMonitor_as_Confirm(uint32_t this_arg) { LDKChainMonitor this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; LDKConfirm* ret_ret =MALLOC(sizeof(LDKConfirm), "LDKConfirm"); *ret_ret = ChainMonitor_as_Confirm(&this_arg_conv); return (uint64_t)ret_ret; } uint32_t __attribute__((visibility("default"))) TS_ChainMonitor_as_Watch(uint32_t this_arg) { LDKChainMonitor this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; LDKWatch* ret_ret =MALLOC(sizeof(LDKWatch), "LDKWatch"); *ret_ret = ChainMonitor_as_Watch(&this_arg_conv); return (uint64_t)ret_ret; } uint32_t __attribute__((visibility("default"))) TS_ChainMonitor_as_EventsProvider(uint32_t this_arg) { LDKChainMonitor this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; LDKEventsProvider* ret_ret =MALLOC(sizeof(LDKEventsProvider), "LDKEventsProvider"); *ret_ret = ChainMonitor_as_EventsProvider(&this_arg_conv); return (uint64_t)ret_ret; } void __attribute__((visibility("default"))) TS_ChannelMonitorUpdate_free(uint32_t this_obj) { LDKChannelMonitorUpdate this_obj_conv; this_obj_conv.inner = (void*)(this_obj & (~1)); this_obj_conv.is_owned = (this_obj & 1) || (this_obj == 0); ChannelMonitorUpdate_free(this_obj_conv); } int64_t __attribute__((visibility("default"))) TS_ChannelMonitorUpdate_get_update_id(uint32_t this_ptr) { LDKChannelMonitorUpdate this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int64_t ret_val = ChannelMonitorUpdate_get_update_id(&this_ptr_conv); return ret_val; } void __attribute__((visibility("default"))) TS_ChannelMonitorUpdate_set_update_id(uint32_t this_ptr, int64_t val) { LDKChannelMonitorUpdate this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; ChannelMonitorUpdate_set_update_id(&this_ptr_conv, val); } uint32_t __attribute__((visibility("default"))) TS_ChannelMonitorUpdate_clone(uint32_t orig) { LDKChannelMonitorUpdate orig_conv; orig_conv.inner = (void*)(orig & (~1)); orig_conv.is_owned = false; LDKChannelMonitorUpdate ret_var = ChannelMonitorUpdate_clone(&orig_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } int8_tArray __attribute__((visibility("default"))) TS_ChannelMonitorUpdate_write(uint32_t obj) { LDKChannelMonitorUpdate obj_conv; obj_conv.inner = (void*)(obj & (~1)); obj_conv.is_owned = false; LDKCVec_u8Z ret_var = ChannelMonitorUpdate_write(&obj_conv); int8_tArray ret_arr = init_arr(ret_var.datalen, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), ret_var.data, ret_var.datalen); CVec_u8Z_free(ret_var); return ret_arr; } uint32_t __attribute__((visibility("default"))) TS_ChannelMonitorUpdate_read(int8_tArray ser) { LDKu8slice ser_ref; ser_ref.datalen = *((uint32_t*)ser); ser_ref.data = (int8_t*)(ser + 4); LDKCResult_ChannelMonitorUpdateDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_ChannelMonitorUpdateDecodeErrorZ), "LDKCResult_ChannelMonitorUpdateDecodeErrorZ"); *ret_conv = ChannelMonitorUpdate_read(ser_ref); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_ChannelMonitorUpdateErr_clone(uint32_t orig) { LDKChannelMonitorUpdateErr* orig_conv = (LDKChannelMonitorUpdateErr*)(orig & ~1); uint32_t ret_conv = LDKChannelMonitorUpdateErr_to_js(ChannelMonitorUpdateErr_clone(orig_conv)); return ret_conv; } uint32_t __attribute__((visibility("default"))) TS_ChannelMonitorUpdateErr_temporary_failure() { uint32_t ret_conv = LDKChannelMonitorUpdateErr_to_js(ChannelMonitorUpdateErr_temporary_failure()); return ret_conv; } uint32_t __attribute__((visibility("default"))) TS_ChannelMonitorUpdateErr_permanent_failure() { uint32_t ret_conv = LDKChannelMonitorUpdateErr_to_js(ChannelMonitorUpdateErr_permanent_failure()); return ret_conv; } void __attribute__((visibility("default"))) TS_MonitorUpdateError_free(uint32_t this_obj) { LDKMonitorUpdateError this_obj_conv; this_obj_conv.inner = (void*)(this_obj & (~1)); this_obj_conv.is_owned = (this_obj & 1) || (this_obj == 0); MonitorUpdateError_free(this_obj_conv); } uint32_t __attribute__((visibility("default"))) TS_MonitorUpdateError_clone(uint32_t orig) { LDKMonitorUpdateError orig_conv; orig_conv.inner = (void*)(orig & (~1)); orig_conv.is_owned = false; LDKMonitorUpdateError ret_var = MonitorUpdateError_clone(&orig_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } void __attribute__((visibility("default"))) TS_MonitorEvent_free(uint32_t this_ptr) { if ((this_ptr & 1) != 0) return; LDKMonitorEvent this_ptr_conv = *(LDKMonitorEvent*)(((uint64_t)this_ptr) & ~1); FREE((void*)this_ptr); MonitorEvent_free(this_ptr_conv); } uint32_t __attribute__((visibility("default"))) TS_MonitorEvent_clone(uint32_t orig) { LDKMonitorEvent* orig_conv = (LDKMonitorEvent*)orig; LDKMonitorEvent *ret_copy = MALLOC(sizeof(LDKMonitorEvent), "LDKMonitorEvent"); *ret_copy = MonitorEvent_clone(orig_conv); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_MonitorEvent_htlcevent(uint32_t a) { LDKHTLCUpdate a_conv; a_conv.inner = (void*)(a & (~1)); a_conv.is_owned = (a & 1) || (a == 0); a_conv = HTLCUpdate_clone(&a_conv); LDKMonitorEvent *ret_copy = MALLOC(sizeof(LDKMonitorEvent), "LDKMonitorEvent"); *ret_copy = MonitorEvent_htlcevent(a_conv); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_MonitorEvent_commitment_tx_confirmed(uint32_t a) { LDKOutPoint a_conv; a_conv.inner = (void*)(a & (~1)); a_conv.is_owned = (a & 1) || (a == 0); a_conv = OutPoint_clone(&a_conv); LDKMonitorEvent *ret_copy = MALLOC(sizeof(LDKMonitorEvent), "LDKMonitorEvent"); *ret_copy = MonitorEvent_commitment_tx_confirmed(a_conv); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } void __attribute__((visibility("default"))) TS_HTLCUpdate_free(uint32_t this_obj) { LDKHTLCUpdate this_obj_conv; this_obj_conv.inner = (void*)(this_obj & (~1)); this_obj_conv.is_owned = (this_obj & 1) || (this_obj == 0); HTLCUpdate_free(this_obj_conv); } uint32_t __attribute__((visibility("default"))) TS_HTLCUpdate_clone(uint32_t orig) { LDKHTLCUpdate orig_conv; orig_conv.inner = (void*)(orig & (~1)); orig_conv.is_owned = false; LDKHTLCUpdate ret_var = HTLCUpdate_clone(&orig_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } int8_tArray __attribute__((visibility("default"))) TS_HTLCUpdate_write(uint32_t obj) { LDKHTLCUpdate obj_conv; obj_conv.inner = (void*)(obj & (~1)); obj_conv.is_owned = false; LDKCVec_u8Z ret_var = HTLCUpdate_write(&obj_conv); int8_tArray ret_arr = init_arr(ret_var.datalen, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), ret_var.data, ret_var.datalen); CVec_u8Z_free(ret_var); return ret_arr; } uint32_t __attribute__((visibility("default"))) TS_HTLCUpdate_read(int8_tArray ser) { LDKu8slice ser_ref; ser_ref.datalen = *((uint32_t*)ser); ser_ref.data = (int8_t*)(ser + 4); LDKCResult_HTLCUpdateDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_HTLCUpdateDecodeErrorZ), "LDKCResult_HTLCUpdateDecodeErrorZ"); *ret_conv = HTLCUpdate_read(ser_ref); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_Balance_free(uint32_t this_ptr) { if ((this_ptr & 1) != 0) return; LDKBalance this_ptr_conv = *(LDKBalance*)(((uint64_t)this_ptr) & ~1); FREE((void*)this_ptr); Balance_free(this_ptr_conv); } uint32_t __attribute__((visibility("default"))) TS_Balance_clone(uint32_t orig) { LDKBalance* orig_conv = (LDKBalance*)orig; LDKBalance *ret_copy = MALLOC(sizeof(LDKBalance), "LDKBalance"); *ret_copy = Balance_clone(orig_conv); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_Balance_claimable_on_channel_close(int64_t claimable_amount_satoshis) { LDKBalance *ret_copy = MALLOC(sizeof(LDKBalance), "LDKBalance"); *ret_copy = Balance_claimable_on_channel_close(claimable_amount_satoshis); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_Balance_claimable_awaiting_confirmations(int64_t claimable_amount_satoshis, int32_t confirmation_height) { LDKBalance *ret_copy = MALLOC(sizeof(LDKBalance), "LDKBalance"); *ret_copy = Balance_claimable_awaiting_confirmations(claimable_amount_satoshis, confirmation_height); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_Balance_contentious_claimable(int64_t claimable_amount_satoshis, int32_t timeout_height) { LDKBalance *ret_copy = MALLOC(sizeof(LDKBalance), "LDKBalance"); *ret_copy = Balance_contentious_claimable(claimable_amount_satoshis, timeout_height); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_Balance_maybe_claimable_htlcawaiting_timeout(int64_t claimable_amount_satoshis, int32_t claimable_height) { LDKBalance *ret_copy = MALLOC(sizeof(LDKBalance), "LDKBalance"); *ret_copy = Balance_maybe_claimable_htlcawaiting_timeout(claimable_amount_satoshis, claimable_height); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } jboolean __attribute__((visibility("default"))) TS_Balance_eq(uint32_t a, uint32_t b) { LDKBalance* a_conv = (LDKBalance*)a; LDKBalance* b_conv = (LDKBalance*)b; jboolean ret_val = Balance_eq(a_conv, b_conv); return ret_val; } void __attribute__((visibility("default"))) TS_ChannelMonitor_free(uint32_t this_obj) { LDKChannelMonitor this_obj_conv; this_obj_conv.inner = (void*)(this_obj & (~1)); this_obj_conv.is_owned = (this_obj & 1) || (this_obj == 0); ChannelMonitor_free(this_obj_conv); } uint32_t __attribute__((visibility("default"))) TS_ChannelMonitor_clone(uint32_t orig) { LDKChannelMonitor orig_conv; orig_conv.inner = (void*)(orig & (~1)); orig_conv.is_owned = false; LDKChannelMonitor ret_var = ChannelMonitor_clone(&orig_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } int8_tArray __attribute__((visibility("default"))) TS_ChannelMonitor_write(uint32_t obj) { LDKChannelMonitor obj_conv; obj_conv.inner = (void*)(obj & (~1)); obj_conv.is_owned = false; LDKCVec_u8Z ret_var = ChannelMonitor_write(&obj_conv); int8_tArray ret_arr = init_arr(ret_var.datalen, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), ret_var.data, ret_var.datalen); CVec_u8Z_free(ret_var); return ret_arr; } uint32_t __attribute__((visibility("default"))) TS_ChannelMonitor_update_monitor(uint32_t this_arg, uint32_t updates, uint32_t broadcaster, uint32_t fee_estimator, uint32_t logger) { LDKChannelMonitor this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; LDKChannelMonitorUpdate updates_conv; updates_conv.inner = (void*)(updates & (~1)); updates_conv.is_owned = false; LDKBroadcasterInterface* broadcaster_conv = (LDKBroadcasterInterface*)(((uint64_t)broadcaster) & ~1); LDKFeeEstimator* fee_estimator_conv = (LDKFeeEstimator*)(((uint64_t)fee_estimator) & ~1); LDKLogger* logger_conv = (LDKLogger*)(((uint64_t)logger) & ~1); LDKCResult_NoneMonitorUpdateErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_NoneMonitorUpdateErrorZ), "LDKCResult_NoneMonitorUpdateErrorZ"); *ret_conv = ChannelMonitor_update_monitor(&this_arg_conv, &updates_conv, broadcaster_conv, fee_estimator_conv, logger_conv); return (uint64_t)ret_conv; } int64_t __attribute__((visibility("default"))) TS_ChannelMonitor_get_latest_update_id(uint32_t this_arg) { LDKChannelMonitor this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; int64_t ret_val = ChannelMonitor_get_latest_update_id(&this_arg_conv); return ret_val; } uint32_t __attribute__((visibility("default"))) TS_ChannelMonitor_get_funding_txo(uint32_t this_arg) { LDKChannelMonitor this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; LDKC2Tuple_OutPointScriptZ* ret_ref = MALLOC(sizeof(LDKC2Tuple_OutPointScriptZ), "LDKC2Tuple_OutPointScriptZ"); *ret_ref = ChannelMonitor_get_funding_txo(&this_arg_conv); return (uint64_t)ret_ref; } uint32_tArray __attribute__((visibility("default"))) TS_ChannelMonitor_get_outputs_to_watch(uint32_t this_arg) { LDKChannelMonitor this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; LDKCVec_C2Tuple_TxidCVec_C2Tuple_u32ScriptZZZZ ret_var = ChannelMonitor_get_outputs_to_watch(&this_arg_conv); uint32_tArray ret_arr = init_arr(ret_var.datalen, sizeof(uint32_t), "Native uint32_tArray Bytes"); uint32_t *ret_arr_ptr = (uint32_t*)(ret_arr + 4); for (size_t c = 0; c < ret_var.datalen; c++) { LDKC2Tuple_TxidCVec_C2Tuple_u32ScriptZZZ* ret_conv_54_ref = MALLOC(sizeof(LDKC2Tuple_TxidCVec_C2Tuple_u32ScriptZZZ), "LDKC2Tuple_TxidCVec_C2Tuple_u32ScriptZZZ"); *ret_conv_54_ref = ret_var.data[c]; ret_arr_ptr[c] = (uint64_t)ret_conv_54_ref; } FREE(ret_var.data); return ret_arr; } void __attribute__((visibility("default"))) TS_ChannelMonitor_load_outputs_to_watch(uint32_t this_arg, uint32_t filter) { LDKChannelMonitor this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; LDKFilter* filter_conv = (LDKFilter*)(((uint64_t)filter) & ~1); ChannelMonitor_load_outputs_to_watch(&this_arg_conv, filter_conv); } uint32_tArray __attribute__((visibility("default"))) TS_ChannelMonitor_get_and_clear_pending_monitor_events(uint32_t this_arg) { LDKChannelMonitor this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; LDKCVec_MonitorEventZ ret_var = ChannelMonitor_get_and_clear_pending_monitor_events(&this_arg_conv); uint32_tArray ret_arr = init_arr(ret_var.datalen, sizeof(uint32_t), "Native uint32_tArray Bytes"); uint32_t *ret_arr_ptr = (uint32_t*)(ret_arr + 4); for (size_t o = 0; o < ret_var.datalen; o++) { LDKMonitorEvent *ret_conv_14_copy = MALLOC(sizeof(LDKMonitorEvent), "LDKMonitorEvent"); *ret_conv_14_copy = MonitorEvent_clone(&ret_var.data[o]); uint64_t ret_conv_14_ref = (uint64_t)ret_conv_14_copy; ret_arr_ptr[o] = ret_conv_14_ref; } FREE(ret_var.data); return ret_arr; } uint32_tArray __attribute__((visibility("default"))) TS_ChannelMonitor_get_and_clear_pending_events(uint32_t this_arg) { LDKChannelMonitor this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; LDKCVec_EventZ ret_var = ChannelMonitor_get_and_clear_pending_events(&this_arg_conv); uint32_tArray ret_arr = init_arr(ret_var.datalen, sizeof(uint32_t), "Native uint32_tArray Bytes"); uint32_t *ret_arr_ptr = (uint32_t*)(ret_arr + 4); for (size_t h = 0; h < ret_var.datalen; h++) { LDKEvent *ret_conv_7_copy = MALLOC(sizeof(LDKEvent), "LDKEvent"); *ret_conv_7_copy = Event_clone(&ret_var.data[h]); uint64_t ret_conv_7_ref = (uint64_t)ret_conv_7_copy; ret_arr_ptr[h] = ret_conv_7_ref; } FREE(ret_var.data); return ret_arr; } ptrArray __attribute__((visibility("default"))) TS_ChannelMonitor_get_latest_holder_commitment_txn(uint32_t this_arg, uint32_t logger) { LDKChannelMonitor this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; LDKLogger* logger_conv = (LDKLogger*)(((uint64_t)logger) & ~1); LDKCVec_TransactionZ ret_var = ChannelMonitor_get_latest_holder_commitment_txn(&this_arg_conv, logger_conv); ptrArray ret_arr = init_arr(ret_var.datalen, sizeof(uint32_t), "Native ptrArray Bytes"); int8_tArray *ret_arr_ptr = (int8_tArray*)(ret_arr + 4); for (size_t m = 0; m < ret_var.datalen; m++) { LDKTransaction ret_conv_12_var = ret_var.data[m]; int8_tArray ret_conv_12_arr = init_arr(ret_conv_12_var.datalen, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_conv_12_arr + 4), ret_conv_12_var.data, ret_conv_12_var.datalen); Transaction_free(ret_conv_12_var); ret_arr_ptr[m] = ret_conv_12_arr; } FREE(ret_var.data); return ret_arr; } uint32_tArray __attribute__((visibility("default"))) TS_ChannelMonitor_block_connected(uint32_t this_arg, int8_tArray header, uint32_tArray txdata, int32_t height, uint32_t broadcaster, uint32_t fee_estimator, uint32_t logger) { LDKChannelMonitor this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; unsigned char header_arr[80]; CHECK(*((uint32_t*)header) == 80); memcpy(header_arr, (uint8_t*)(header + 4), 80); unsigned char (*header_ref)[80] = &header_arr; LDKCVec_C2Tuple_usizeTransactionZZ txdata_constr; txdata_constr.datalen = *((uint32_t*)txdata); if (txdata_constr.datalen > 0) txdata_constr.data = MALLOC(txdata_constr.datalen * sizeof(LDKC2Tuple_usizeTransactionZ), "LDKCVec_C2Tuple_usizeTransactionZZ Elements"); else txdata_constr.data = NULL; uint32_t* txdata_vals = (uint32_t*)(txdata + 4); for (size_t e = 0; e < txdata_constr.datalen; e++) { uint32_t txdata_conv_30 = txdata_vals[e]; LDKC2Tuple_usizeTransactionZ txdata_conv_30_conv = *(LDKC2Tuple_usizeTransactionZ*)(((uint64_t)txdata_conv_30) & ~1); txdata_conv_30_conv = C2Tuple_usizeTransactionZ_clone((LDKC2Tuple_usizeTransactionZ*)(((uint64_t)txdata_conv_30) & ~1)); txdata_constr.data[e] = txdata_conv_30_conv; } LDKBroadcasterInterface broadcaster_conv = *(LDKBroadcasterInterface*)(((uint64_t)broadcaster) & ~1); LDKFeeEstimator fee_estimator_conv = *(LDKFeeEstimator*)(((uint64_t)fee_estimator) & ~1); LDKLogger logger_conv = *(LDKLogger*)(((uint64_t)logger) & ~1); LDKCVec_C2Tuple_TxidCVec_C2Tuple_u32TxOutZZZZ ret_var = ChannelMonitor_block_connected(&this_arg_conv, header_ref, txdata_constr, height, broadcaster_conv, fee_estimator_conv, logger_conv); uint32_tArray ret_arr = init_arr(ret_var.datalen, sizeof(uint32_t), "Native uint32_tArray Bytes"); uint32_t *ret_arr_ptr = (uint32_t*)(ret_arr + 4); for (size_t x = 0; x < ret_var.datalen; x++) { LDKC2Tuple_TxidCVec_C2Tuple_u32TxOutZZZ* ret_conv_49_ref = MALLOC(sizeof(LDKC2Tuple_TxidCVec_C2Tuple_u32TxOutZZZ), "LDKC2Tuple_TxidCVec_C2Tuple_u32TxOutZZZ"); *ret_conv_49_ref = ret_var.data[x]; ret_arr_ptr[x] = (uint64_t)ret_conv_49_ref; } FREE(ret_var.data); return ret_arr; } void __attribute__((visibility("default"))) TS_ChannelMonitor_block_disconnected(uint32_t this_arg, int8_tArray header, int32_t height, uint32_t broadcaster, uint32_t fee_estimator, uint32_t logger) { LDKChannelMonitor this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; unsigned char header_arr[80]; CHECK(*((uint32_t*)header) == 80); memcpy(header_arr, (uint8_t*)(header + 4), 80); unsigned char (*header_ref)[80] = &header_arr; LDKBroadcasterInterface broadcaster_conv = *(LDKBroadcasterInterface*)(((uint64_t)broadcaster) & ~1); LDKFeeEstimator fee_estimator_conv = *(LDKFeeEstimator*)(((uint64_t)fee_estimator) & ~1); LDKLogger logger_conv = *(LDKLogger*)(((uint64_t)logger) & ~1); ChannelMonitor_block_disconnected(&this_arg_conv, header_ref, height, broadcaster_conv, fee_estimator_conv, logger_conv); } uint32_tArray __attribute__((visibility("default"))) TS_ChannelMonitor_transactions_confirmed(uint32_t this_arg, int8_tArray header, uint32_tArray txdata, int32_t height, uint32_t broadcaster, uint32_t fee_estimator, uint32_t logger) { LDKChannelMonitor this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; unsigned char header_arr[80]; CHECK(*((uint32_t*)header) == 80); memcpy(header_arr, (uint8_t*)(header + 4), 80); unsigned char (*header_ref)[80] = &header_arr; LDKCVec_C2Tuple_usizeTransactionZZ txdata_constr; txdata_constr.datalen = *((uint32_t*)txdata); if (txdata_constr.datalen > 0) txdata_constr.data = MALLOC(txdata_constr.datalen * sizeof(LDKC2Tuple_usizeTransactionZ), "LDKCVec_C2Tuple_usizeTransactionZZ Elements"); else txdata_constr.data = NULL; uint32_t* txdata_vals = (uint32_t*)(txdata + 4); for (size_t e = 0; e < txdata_constr.datalen; e++) { uint32_t txdata_conv_30 = txdata_vals[e]; LDKC2Tuple_usizeTransactionZ txdata_conv_30_conv = *(LDKC2Tuple_usizeTransactionZ*)(((uint64_t)txdata_conv_30) & ~1); txdata_conv_30_conv = C2Tuple_usizeTransactionZ_clone((LDKC2Tuple_usizeTransactionZ*)(((uint64_t)txdata_conv_30) & ~1)); txdata_constr.data[e] = txdata_conv_30_conv; } LDKBroadcasterInterface broadcaster_conv = *(LDKBroadcasterInterface*)(((uint64_t)broadcaster) & ~1); LDKFeeEstimator fee_estimator_conv = *(LDKFeeEstimator*)(((uint64_t)fee_estimator) & ~1); LDKLogger logger_conv = *(LDKLogger*)(((uint64_t)logger) & ~1); LDKCVec_C2Tuple_TxidCVec_C2Tuple_u32TxOutZZZZ ret_var = ChannelMonitor_transactions_confirmed(&this_arg_conv, header_ref, txdata_constr, height, broadcaster_conv, fee_estimator_conv, logger_conv); uint32_tArray ret_arr = init_arr(ret_var.datalen, sizeof(uint32_t), "Native uint32_tArray Bytes"); uint32_t *ret_arr_ptr = (uint32_t*)(ret_arr + 4); for (size_t x = 0; x < ret_var.datalen; x++) { LDKC2Tuple_TxidCVec_C2Tuple_u32TxOutZZZ* ret_conv_49_ref = MALLOC(sizeof(LDKC2Tuple_TxidCVec_C2Tuple_u32TxOutZZZ), "LDKC2Tuple_TxidCVec_C2Tuple_u32TxOutZZZ"); *ret_conv_49_ref = ret_var.data[x]; ret_arr_ptr[x] = (uint64_t)ret_conv_49_ref; } FREE(ret_var.data); return ret_arr; } void __attribute__((visibility("default"))) TS_ChannelMonitor_transaction_unconfirmed(uint32_t this_arg, int8_tArray txid, uint32_t broadcaster, uint32_t fee_estimator, uint32_t logger) { LDKChannelMonitor this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; unsigned char txid_arr[32]; CHECK(*((uint32_t*)txid) == 32); memcpy(txid_arr, (uint8_t*)(txid + 4), 32); unsigned char (*txid_ref)[32] = &txid_arr; LDKBroadcasterInterface broadcaster_conv = *(LDKBroadcasterInterface*)(((uint64_t)broadcaster) & ~1); LDKFeeEstimator fee_estimator_conv = *(LDKFeeEstimator*)(((uint64_t)fee_estimator) & ~1); LDKLogger logger_conv = *(LDKLogger*)(((uint64_t)logger) & ~1); ChannelMonitor_transaction_unconfirmed(&this_arg_conv, txid_ref, broadcaster_conv, fee_estimator_conv, logger_conv); } uint32_tArray __attribute__((visibility("default"))) TS_ChannelMonitor_best_block_updated(uint32_t this_arg, int8_tArray header, int32_t height, uint32_t broadcaster, uint32_t fee_estimator, uint32_t logger) { LDKChannelMonitor this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; unsigned char header_arr[80]; CHECK(*((uint32_t*)header) == 80); memcpy(header_arr, (uint8_t*)(header + 4), 80); unsigned char (*header_ref)[80] = &header_arr; LDKBroadcasterInterface broadcaster_conv = *(LDKBroadcasterInterface*)(((uint64_t)broadcaster) & ~1); LDKFeeEstimator fee_estimator_conv = *(LDKFeeEstimator*)(((uint64_t)fee_estimator) & ~1); LDKLogger logger_conv = *(LDKLogger*)(((uint64_t)logger) & ~1); LDKCVec_C2Tuple_TxidCVec_C2Tuple_u32TxOutZZZZ ret_var = ChannelMonitor_best_block_updated(&this_arg_conv, header_ref, height, broadcaster_conv, fee_estimator_conv, logger_conv); uint32_tArray ret_arr = init_arr(ret_var.datalen, sizeof(uint32_t), "Native uint32_tArray Bytes"); uint32_t *ret_arr_ptr = (uint32_t*)(ret_arr + 4); for (size_t x = 0; x < ret_var.datalen; x++) { LDKC2Tuple_TxidCVec_C2Tuple_u32TxOutZZZ* ret_conv_49_ref = MALLOC(sizeof(LDKC2Tuple_TxidCVec_C2Tuple_u32TxOutZZZ), "LDKC2Tuple_TxidCVec_C2Tuple_u32TxOutZZZ"); *ret_conv_49_ref = ret_var.data[x]; ret_arr_ptr[x] = (uint64_t)ret_conv_49_ref; } FREE(ret_var.data); return ret_arr; } ptrArray __attribute__((visibility("default"))) TS_ChannelMonitor_get_relevant_txids(uint32_t this_arg) { LDKChannelMonitor this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; LDKCVec_TxidZ ret_var = ChannelMonitor_get_relevant_txids(&this_arg_conv); ptrArray ret_arr = init_arr(ret_var.datalen, sizeof(uint32_t), "Native ptrArray Bytes"); int8_tArray *ret_arr_ptr = (int8_tArray*)(ret_arr + 4); for (size_t m = 0; m < ret_var.datalen; m++) { int8_tArray ret_conv_12_arr = init_arr(32, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_conv_12_arr + 4), ret_var.data[m].data, 32); ret_arr_ptr[m] = ret_conv_12_arr; } FREE(ret_var.data); return ret_arr; } uint32_t __attribute__((visibility("default"))) TS_ChannelMonitor_current_best_block(uint32_t this_arg) { LDKChannelMonitor this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; LDKBestBlock ret_var = ChannelMonitor_current_best_block(&this_arg_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } uint32_tArray __attribute__((visibility("default"))) TS_ChannelMonitor_get_claimable_balances(uint32_t this_arg) { LDKChannelMonitor this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; LDKCVec_BalanceZ ret_var = ChannelMonitor_get_claimable_balances(&this_arg_conv); uint32_tArray ret_arr = init_arr(ret_var.datalen, sizeof(uint32_t), "Native uint32_tArray Bytes"); uint32_t *ret_arr_ptr = (uint32_t*)(ret_arr + 4); for (size_t j = 0; j < ret_var.datalen; j++) { LDKBalance *ret_conv_9_copy = MALLOC(sizeof(LDKBalance), "LDKBalance"); *ret_conv_9_copy = Balance_clone(&ret_var.data[j]); uint64_t ret_conv_9_ref = (uint64_t)ret_conv_9_copy; ret_arr_ptr[j] = ret_conv_9_ref; } FREE(ret_var.data); return ret_arr; } void __attribute__((visibility("default"))) TS_Persist_free(uint32_t this_ptr) { if ((this_ptr & 1) != 0) return; LDKPersist this_ptr_conv = *(LDKPersist*)(((uint64_t)this_ptr) & ~1); FREE((void*)this_ptr); Persist_free(this_ptr_conv); } uint32_t __attribute__((visibility("default"))) TS_C2Tuple_BlockHashChannelMonitorZ_read(int8_tArray ser, uint32_t arg) { LDKu8slice ser_ref; ser_ref.datalen = *((uint32_t*)ser); ser_ref.data = (int8_t*)(ser + 4); LDKKeysInterface* arg_conv = (LDKKeysInterface*)(((uint64_t)arg) & ~1); LDKCResult_C2Tuple_BlockHashChannelMonitorZDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_C2Tuple_BlockHashChannelMonitorZDecodeErrorZ), "LDKCResult_C2Tuple_BlockHashChannelMonitorZDecodeErrorZ"); *ret_conv = C2Tuple_BlockHashChannelMonitorZ_read(ser_ref, arg_conv); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_OutPoint_free(uint32_t this_obj) { LDKOutPoint this_obj_conv; this_obj_conv.inner = (void*)(this_obj & (~1)); this_obj_conv.is_owned = (this_obj & 1) || (this_obj == 0); OutPoint_free(this_obj_conv); } int8_tArray __attribute__((visibility("default"))) TS_OutPoint_get_txid(uint32_t this_ptr) { LDKOutPoint this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int8_tArray ret_arr = init_arr(32, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), *OutPoint_get_txid(&this_ptr_conv), 32); return ret_arr; } void __attribute__((visibility("default"))) TS_OutPoint_set_txid(uint32_t this_ptr, int8_tArray val) { LDKOutPoint this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKThirtyTwoBytes val_ref; CHECK(*((uint32_t*)val) == 32); memcpy(val_ref.data, (uint8_t*)(val + 4), 32); OutPoint_set_txid(&this_ptr_conv, val_ref); } int16_t __attribute__((visibility("default"))) TS_OutPoint_get_index(uint32_t this_ptr) { LDKOutPoint this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int16_t ret_val = OutPoint_get_index(&this_ptr_conv); return ret_val; } void __attribute__((visibility("default"))) TS_OutPoint_set_index(uint32_t this_ptr, int16_t val) { LDKOutPoint this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; OutPoint_set_index(&this_ptr_conv, val); } uint32_t __attribute__((visibility("default"))) TS_OutPoint_new(int8_tArray txid_arg, int16_t index_arg) { LDKThirtyTwoBytes txid_arg_ref; CHECK(*((uint32_t*)txid_arg) == 32); memcpy(txid_arg_ref.data, (uint8_t*)(txid_arg + 4), 32); LDKOutPoint ret_var = OutPoint_new(txid_arg_ref, index_arg); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_OutPoint_clone(uint32_t orig) { LDKOutPoint orig_conv; orig_conv.inner = (void*)(orig & (~1)); orig_conv.is_owned = false; LDKOutPoint ret_var = OutPoint_clone(&orig_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } jboolean __attribute__((visibility("default"))) TS_OutPoint_eq(uint32_t a, uint32_t b) { LDKOutPoint a_conv; a_conv.inner = (void*)(a & (~1)); a_conv.is_owned = false; LDKOutPoint b_conv; b_conv.inner = (void*)(b & (~1)); b_conv.is_owned = false; jboolean ret_val = OutPoint_eq(&a_conv, &b_conv); return ret_val; } int64_t __attribute__((visibility("default"))) TS_OutPoint_hash(uint32_t o) { LDKOutPoint o_conv; o_conv.inner = (void*)(o & (~1)); o_conv.is_owned = false; int64_t ret_val = OutPoint_hash(&o_conv); return ret_val; } int8_tArray __attribute__((visibility("default"))) TS_OutPoint_to_channel_id(uint32_t this_arg) { LDKOutPoint this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; int8_tArray ret_arr = init_arr(32, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), OutPoint_to_channel_id(&this_arg_conv).data, 32); return ret_arr; } int8_tArray __attribute__((visibility("default"))) TS_OutPoint_write(uint32_t obj) { LDKOutPoint obj_conv; obj_conv.inner = (void*)(obj & (~1)); obj_conv.is_owned = false; LDKCVec_u8Z ret_var = OutPoint_write(&obj_conv); int8_tArray ret_arr = init_arr(ret_var.datalen, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), ret_var.data, ret_var.datalen); CVec_u8Z_free(ret_var); return ret_arr; } uint32_t __attribute__((visibility("default"))) TS_OutPoint_read(int8_tArray ser) { LDKu8slice ser_ref; ser_ref.datalen = *((uint32_t*)ser); ser_ref.data = (int8_t*)(ser + 4); LDKCResult_OutPointDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_OutPointDecodeErrorZ), "LDKCResult_OutPointDecodeErrorZ"); *ret_conv = OutPoint_read(ser_ref); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_DelayedPaymentOutputDescriptor_free(uint32_t this_obj) { LDKDelayedPaymentOutputDescriptor this_obj_conv; this_obj_conv.inner = (void*)(this_obj & (~1)); this_obj_conv.is_owned = (this_obj & 1) || (this_obj == 0); DelayedPaymentOutputDescriptor_free(this_obj_conv); } uint32_t __attribute__((visibility("default"))) TS_DelayedPaymentOutputDescriptor_get_outpoint(uint32_t this_ptr) { LDKDelayedPaymentOutputDescriptor this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKOutPoint ret_var = DelayedPaymentOutputDescriptor_get_outpoint(&this_ptr_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } void __attribute__((visibility("default"))) TS_DelayedPaymentOutputDescriptor_set_outpoint(uint32_t this_ptr, uint32_t val) { LDKDelayedPaymentOutputDescriptor this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKOutPoint val_conv; val_conv.inner = (void*)(val & (~1)); val_conv.is_owned = (val & 1) || (val == 0); val_conv = OutPoint_clone(&val_conv); DelayedPaymentOutputDescriptor_set_outpoint(&this_ptr_conv, val_conv); } int8_tArray __attribute__((visibility("default"))) TS_DelayedPaymentOutputDescriptor_get_per_commitment_point(uint32_t this_ptr) { LDKDelayedPaymentOutputDescriptor this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int8_tArray ret_arr = init_arr(33, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), DelayedPaymentOutputDescriptor_get_per_commitment_point(&this_ptr_conv).compressed_form, 33); return ret_arr; } void __attribute__((visibility("default"))) TS_DelayedPaymentOutputDescriptor_set_per_commitment_point(uint32_t this_ptr, int8_tArray val) { LDKDelayedPaymentOutputDescriptor this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKPublicKey val_ref; CHECK(*((uint32_t*)val) == 33); memcpy(val_ref.compressed_form, (uint8_t*)(val + 4), 33); DelayedPaymentOutputDescriptor_set_per_commitment_point(&this_ptr_conv, val_ref); } int16_t __attribute__((visibility("default"))) TS_DelayedPaymentOutputDescriptor_get_to_self_delay(uint32_t this_ptr) { LDKDelayedPaymentOutputDescriptor this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int16_t ret_val = DelayedPaymentOutputDescriptor_get_to_self_delay(&this_ptr_conv); return ret_val; } void __attribute__((visibility("default"))) TS_DelayedPaymentOutputDescriptor_set_to_self_delay(uint32_t this_ptr, int16_t val) { LDKDelayedPaymentOutputDescriptor this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; DelayedPaymentOutputDescriptor_set_to_self_delay(&this_ptr_conv, val); } void __attribute__((visibility("default"))) TS_DelayedPaymentOutputDescriptor_set_output(uint32_t this_ptr, uint32_t val) { LDKDelayedPaymentOutputDescriptor this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKTxOut val_conv = *(LDKTxOut*)(((uint64_t)val) & ~1); val_conv = TxOut_clone((LDKTxOut*)(((uint64_t)val) & ~1)); DelayedPaymentOutputDescriptor_set_output(&this_ptr_conv, val_conv); } int8_tArray __attribute__((visibility("default"))) TS_DelayedPaymentOutputDescriptor_get_revocation_pubkey(uint32_t this_ptr) { LDKDelayedPaymentOutputDescriptor this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int8_tArray ret_arr = init_arr(33, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), DelayedPaymentOutputDescriptor_get_revocation_pubkey(&this_ptr_conv).compressed_form, 33); return ret_arr; } void __attribute__((visibility("default"))) TS_DelayedPaymentOutputDescriptor_set_revocation_pubkey(uint32_t this_ptr, int8_tArray val) { LDKDelayedPaymentOutputDescriptor this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKPublicKey val_ref; CHECK(*((uint32_t*)val) == 33); memcpy(val_ref.compressed_form, (uint8_t*)(val + 4), 33); DelayedPaymentOutputDescriptor_set_revocation_pubkey(&this_ptr_conv, val_ref); } int8_tArray __attribute__((visibility("default"))) TS_DelayedPaymentOutputDescriptor_get_channel_keys_id(uint32_t this_ptr) { LDKDelayedPaymentOutputDescriptor this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int8_tArray ret_arr = init_arr(32, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), *DelayedPaymentOutputDescriptor_get_channel_keys_id(&this_ptr_conv), 32); return ret_arr; } void __attribute__((visibility("default"))) TS_DelayedPaymentOutputDescriptor_set_channel_keys_id(uint32_t this_ptr, int8_tArray val) { LDKDelayedPaymentOutputDescriptor this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKThirtyTwoBytes val_ref; CHECK(*((uint32_t*)val) == 32); memcpy(val_ref.data, (uint8_t*)(val + 4), 32); DelayedPaymentOutputDescriptor_set_channel_keys_id(&this_ptr_conv, val_ref); } int64_t __attribute__((visibility("default"))) TS_DelayedPaymentOutputDescriptor_get_channel_value_satoshis(uint32_t this_ptr) { LDKDelayedPaymentOutputDescriptor this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int64_t ret_val = DelayedPaymentOutputDescriptor_get_channel_value_satoshis(&this_ptr_conv); return ret_val; } void __attribute__((visibility("default"))) TS_DelayedPaymentOutputDescriptor_set_channel_value_satoshis(uint32_t this_ptr, int64_t val) { LDKDelayedPaymentOutputDescriptor this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; DelayedPaymentOutputDescriptor_set_channel_value_satoshis(&this_ptr_conv, val); } uint32_t __attribute__((visibility("default"))) TS_DelayedPaymentOutputDescriptor_new(uint32_t outpoint_arg, int8_tArray per_commitment_point_arg, int16_t to_self_delay_arg, uint32_t output_arg, int8_tArray revocation_pubkey_arg, int8_tArray channel_keys_id_arg, int64_t channel_value_satoshis_arg) { LDKOutPoint outpoint_arg_conv; outpoint_arg_conv.inner = (void*)(outpoint_arg & (~1)); outpoint_arg_conv.is_owned = (outpoint_arg & 1) || (outpoint_arg == 0); outpoint_arg_conv = OutPoint_clone(&outpoint_arg_conv); LDKPublicKey per_commitment_point_arg_ref; CHECK(*((uint32_t*)per_commitment_point_arg) == 33); memcpy(per_commitment_point_arg_ref.compressed_form, (uint8_t*)(per_commitment_point_arg + 4), 33); LDKTxOut output_arg_conv = *(LDKTxOut*)(((uint64_t)output_arg) & ~1); output_arg_conv = TxOut_clone((LDKTxOut*)(((uint64_t)output_arg) & ~1)); LDKPublicKey revocation_pubkey_arg_ref; CHECK(*((uint32_t*)revocation_pubkey_arg) == 33); memcpy(revocation_pubkey_arg_ref.compressed_form, (uint8_t*)(revocation_pubkey_arg + 4), 33); LDKThirtyTwoBytes channel_keys_id_arg_ref; CHECK(*((uint32_t*)channel_keys_id_arg) == 32); memcpy(channel_keys_id_arg_ref.data, (uint8_t*)(channel_keys_id_arg + 4), 32); LDKDelayedPaymentOutputDescriptor ret_var = DelayedPaymentOutputDescriptor_new(outpoint_arg_conv, per_commitment_point_arg_ref, to_self_delay_arg, output_arg_conv, revocation_pubkey_arg_ref, channel_keys_id_arg_ref, channel_value_satoshis_arg); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_DelayedPaymentOutputDescriptor_clone(uint32_t orig) { LDKDelayedPaymentOutputDescriptor orig_conv; orig_conv.inner = (void*)(orig & (~1)); orig_conv.is_owned = false; LDKDelayedPaymentOutputDescriptor ret_var = DelayedPaymentOutputDescriptor_clone(&orig_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } int8_tArray __attribute__((visibility("default"))) TS_DelayedPaymentOutputDescriptor_write(uint32_t obj) { LDKDelayedPaymentOutputDescriptor obj_conv; obj_conv.inner = (void*)(obj & (~1)); obj_conv.is_owned = false; LDKCVec_u8Z ret_var = DelayedPaymentOutputDescriptor_write(&obj_conv); int8_tArray ret_arr = init_arr(ret_var.datalen, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), ret_var.data, ret_var.datalen); CVec_u8Z_free(ret_var); return ret_arr; } uint32_t __attribute__((visibility("default"))) TS_DelayedPaymentOutputDescriptor_read(int8_tArray ser) { LDKu8slice ser_ref; ser_ref.datalen = *((uint32_t*)ser); ser_ref.data = (int8_t*)(ser + 4); LDKCResult_DelayedPaymentOutputDescriptorDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_DelayedPaymentOutputDescriptorDecodeErrorZ), "LDKCResult_DelayedPaymentOutputDescriptorDecodeErrorZ"); *ret_conv = DelayedPaymentOutputDescriptor_read(ser_ref); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_StaticPaymentOutputDescriptor_free(uint32_t this_obj) { LDKStaticPaymentOutputDescriptor this_obj_conv; this_obj_conv.inner = (void*)(this_obj & (~1)); this_obj_conv.is_owned = (this_obj & 1) || (this_obj == 0); StaticPaymentOutputDescriptor_free(this_obj_conv); } uint32_t __attribute__((visibility("default"))) TS_StaticPaymentOutputDescriptor_get_outpoint(uint32_t this_ptr) { LDKStaticPaymentOutputDescriptor this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKOutPoint ret_var = StaticPaymentOutputDescriptor_get_outpoint(&this_ptr_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } void __attribute__((visibility("default"))) TS_StaticPaymentOutputDescriptor_set_outpoint(uint32_t this_ptr, uint32_t val) { LDKStaticPaymentOutputDescriptor this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKOutPoint val_conv; val_conv.inner = (void*)(val & (~1)); val_conv.is_owned = (val & 1) || (val == 0); val_conv = OutPoint_clone(&val_conv); StaticPaymentOutputDescriptor_set_outpoint(&this_ptr_conv, val_conv); } void __attribute__((visibility("default"))) TS_StaticPaymentOutputDescriptor_set_output(uint32_t this_ptr, uint32_t val) { LDKStaticPaymentOutputDescriptor this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKTxOut val_conv = *(LDKTxOut*)(((uint64_t)val) & ~1); val_conv = TxOut_clone((LDKTxOut*)(((uint64_t)val) & ~1)); StaticPaymentOutputDescriptor_set_output(&this_ptr_conv, val_conv); } int8_tArray __attribute__((visibility("default"))) TS_StaticPaymentOutputDescriptor_get_channel_keys_id(uint32_t this_ptr) { LDKStaticPaymentOutputDescriptor this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int8_tArray ret_arr = init_arr(32, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), *StaticPaymentOutputDescriptor_get_channel_keys_id(&this_ptr_conv), 32); return ret_arr; } void __attribute__((visibility("default"))) TS_StaticPaymentOutputDescriptor_set_channel_keys_id(uint32_t this_ptr, int8_tArray val) { LDKStaticPaymentOutputDescriptor this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKThirtyTwoBytes val_ref; CHECK(*((uint32_t*)val) == 32); memcpy(val_ref.data, (uint8_t*)(val + 4), 32); StaticPaymentOutputDescriptor_set_channel_keys_id(&this_ptr_conv, val_ref); } int64_t __attribute__((visibility("default"))) TS_StaticPaymentOutputDescriptor_get_channel_value_satoshis(uint32_t this_ptr) { LDKStaticPaymentOutputDescriptor this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int64_t ret_val = StaticPaymentOutputDescriptor_get_channel_value_satoshis(&this_ptr_conv); return ret_val; } void __attribute__((visibility("default"))) TS_StaticPaymentOutputDescriptor_set_channel_value_satoshis(uint32_t this_ptr, int64_t val) { LDKStaticPaymentOutputDescriptor this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; StaticPaymentOutputDescriptor_set_channel_value_satoshis(&this_ptr_conv, val); } uint32_t __attribute__((visibility("default"))) TS_StaticPaymentOutputDescriptor_new(uint32_t outpoint_arg, uint32_t output_arg, int8_tArray channel_keys_id_arg, int64_t channel_value_satoshis_arg) { LDKOutPoint outpoint_arg_conv; outpoint_arg_conv.inner = (void*)(outpoint_arg & (~1)); outpoint_arg_conv.is_owned = (outpoint_arg & 1) || (outpoint_arg == 0); outpoint_arg_conv = OutPoint_clone(&outpoint_arg_conv); LDKTxOut output_arg_conv = *(LDKTxOut*)(((uint64_t)output_arg) & ~1); output_arg_conv = TxOut_clone((LDKTxOut*)(((uint64_t)output_arg) & ~1)); LDKThirtyTwoBytes channel_keys_id_arg_ref; CHECK(*((uint32_t*)channel_keys_id_arg) == 32); memcpy(channel_keys_id_arg_ref.data, (uint8_t*)(channel_keys_id_arg + 4), 32); LDKStaticPaymentOutputDescriptor ret_var = StaticPaymentOutputDescriptor_new(outpoint_arg_conv, output_arg_conv, channel_keys_id_arg_ref, channel_value_satoshis_arg); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_StaticPaymentOutputDescriptor_clone(uint32_t orig) { LDKStaticPaymentOutputDescriptor orig_conv; orig_conv.inner = (void*)(orig & (~1)); orig_conv.is_owned = false; LDKStaticPaymentOutputDescriptor ret_var = StaticPaymentOutputDescriptor_clone(&orig_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } int8_tArray __attribute__((visibility("default"))) TS_StaticPaymentOutputDescriptor_write(uint32_t obj) { LDKStaticPaymentOutputDescriptor obj_conv; obj_conv.inner = (void*)(obj & (~1)); obj_conv.is_owned = false; LDKCVec_u8Z ret_var = StaticPaymentOutputDescriptor_write(&obj_conv); int8_tArray ret_arr = init_arr(ret_var.datalen, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), ret_var.data, ret_var.datalen); CVec_u8Z_free(ret_var); return ret_arr; } uint32_t __attribute__((visibility("default"))) TS_StaticPaymentOutputDescriptor_read(int8_tArray ser) { LDKu8slice ser_ref; ser_ref.datalen = *((uint32_t*)ser); ser_ref.data = (int8_t*)(ser + 4); LDKCResult_StaticPaymentOutputDescriptorDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_StaticPaymentOutputDescriptorDecodeErrorZ), "LDKCResult_StaticPaymentOutputDescriptorDecodeErrorZ"); *ret_conv = StaticPaymentOutputDescriptor_read(ser_ref); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_SpendableOutputDescriptor_free(uint32_t this_ptr) { if ((this_ptr & 1) != 0) return; LDKSpendableOutputDescriptor this_ptr_conv = *(LDKSpendableOutputDescriptor*)(((uint64_t)this_ptr) & ~1); FREE((void*)this_ptr); SpendableOutputDescriptor_free(this_ptr_conv); } uint32_t __attribute__((visibility("default"))) TS_SpendableOutputDescriptor_clone(uint32_t orig) { LDKSpendableOutputDescriptor* orig_conv = (LDKSpendableOutputDescriptor*)orig; LDKSpendableOutputDescriptor *ret_copy = MALLOC(sizeof(LDKSpendableOutputDescriptor), "LDKSpendableOutputDescriptor"); *ret_copy = SpendableOutputDescriptor_clone(orig_conv); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_SpendableOutputDescriptor_static_output(uint32_t outpoint, uint32_t output) { LDKOutPoint outpoint_conv; outpoint_conv.inner = (void*)(outpoint & (~1)); outpoint_conv.is_owned = (outpoint & 1) || (outpoint == 0); outpoint_conv = OutPoint_clone(&outpoint_conv); LDKTxOut output_conv = *(LDKTxOut*)(((uint64_t)output) & ~1); output_conv = TxOut_clone((LDKTxOut*)(((uint64_t)output) & ~1)); LDKSpendableOutputDescriptor *ret_copy = MALLOC(sizeof(LDKSpendableOutputDescriptor), "LDKSpendableOutputDescriptor"); *ret_copy = SpendableOutputDescriptor_static_output(outpoint_conv, output_conv); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_SpendableOutputDescriptor_delayed_payment_output(uint32_t a) { LDKDelayedPaymentOutputDescriptor a_conv; a_conv.inner = (void*)(a & (~1)); a_conv.is_owned = (a & 1) || (a == 0); a_conv = DelayedPaymentOutputDescriptor_clone(&a_conv); LDKSpendableOutputDescriptor *ret_copy = MALLOC(sizeof(LDKSpendableOutputDescriptor), "LDKSpendableOutputDescriptor"); *ret_copy = SpendableOutputDescriptor_delayed_payment_output(a_conv); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_SpendableOutputDescriptor_static_payment_output(uint32_t a) { LDKStaticPaymentOutputDescriptor a_conv; a_conv.inner = (void*)(a & (~1)); a_conv.is_owned = (a & 1) || (a == 0); a_conv = StaticPaymentOutputDescriptor_clone(&a_conv); LDKSpendableOutputDescriptor *ret_copy = MALLOC(sizeof(LDKSpendableOutputDescriptor), "LDKSpendableOutputDescriptor"); *ret_copy = SpendableOutputDescriptor_static_payment_output(a_conv); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } int8_tArray __attribute__((visibility("default"))) TS_SpendableOutputDescriptor_write(uint32_t obj) { LDKSpendableOutputDescriptor* obj_conv = (LDKSpendableOutputDescriptor*)obj; LDKCVec_u8Z ret_var = SpendableOutputDescriptor_write(obj_conv); int8_tArray ret_arr = init_arr(ret_var.datalen, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), ret_var.data, ret_var.datalen); CVec_u8Z_free(ret_var); return ret_arr; } uint32_t __attribute__((visibility("default"))) TS_SpendableOutputDescriptor_read(int8_tArray ser) { LDKu8slice ser_ref; ser_ref.datalen = *((uint32_t*)ser); ser_ref.data = (int8_t*)(ser + 4); LDKCResult_SpendableOutputDescriptorDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_SpendableOutputDescriptorDecodeErrorZ), "LDKCResult_SpendableOutputDescriptorDecodeErrorZ"); *ret_conv = SpendableOutputDescriptor_read(ser_ref); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_BaseSign_free(uint32_t this_ptr) { if ((this_ptr & 1) != 0) return; LDKBaseSign this_ptr_conv = *(LDKBaseSign*)(((uint64_t)this_ptr) & ~1); FREE((void*)this_ptr); BaseSign_free(this_ptr_conv); } uint32_t __attribute__((visibility("default"))) TS_Sign_clone(uint32_t orig) { LDKSign* orig_conv = (LDKSign*)(((uint64_t)orig) & ~1); LDKSign* ret_ret =MALLOC(sizeof(LDKSign), "LDKSign"); *ret_ret = Sign_clone(orig_conv); return (uint64_t)ret_ret; } void __attribute__((visibility("default"))) TS_Sign_free(uint32_t this_ptr) { if ((this_ptr & 1) != 0) return; LDKSign this_ptr_conv = *(LDKSign*)(((uint64_t)this_ptr) & ~1); FREE((void*)this_ptr); Sign_free(this_ptr_conv); } void __attribute__((visibility("default"))) TS_KeysInterface_free(uint32_t this_ptr) { if ((this_ptr & 1) != 0) return; LDKKeysInterface this_ptr_conv = *(LDKKeysInterface*)(((uint64_t)this_ptr) & ~1); FREE((void*)this_ptr); KeysInterface_free(this_ptr_conv); } void __attribute__((visibility("default"))) TS_InMemorySigner_free(uint32_t this_obj) { LDKInMemorySigner this_obj_conv; this_obj_conv.inner = (void*)(this_obj & (~1)); this_obj_conv.is_owned = (this_obj & 1) || (this_obj == 0); InMemorySigner_free(this_obj_conv); } int8_tArray __attribute__((visibility("default"))) TS_InMemorySigner_get_funding_key(uint32_t this_ptr) { LDKInMemorySigner this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int8_tArray ret_arr = init_arr(32, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), *InMemorySigner_get_funding_key(&this_ptr_conv), 32); return ret_arr; } void __attribute__((visibility("default"))) TS_InMemorySigner_set_funding_key(uint32_t this_ptr, int8_tArray val) { LDKInMemorySigner this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKSecretKey val_ref; CHECK(*((uint32_t*)val) == 32); memcpy(val_ref.bytes, (uint8_t*)(val + 4), 32); InMemorySigner_set_funding_key(&this_ptr_conv, val_ref); } int8_tArray __attribute__((visibility("default"))) TS_InMemorySigner_get_revocation_base_key(uint32_t this_ptr) { LDKInMemorySigner this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int8_tArray ret_arr = init_arr(32, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), *InMemorySigner_get_revocation_base_key(&this_ptr_conv), 32); return ret_arr; } void __attribute__((visibility("default"))) TS_InMemorySigner_set_revocation_base_key(uint32_t this_ptr, int8_tArray val) { LDKInMemorySigner this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKSecretKey val_ref; CHECK(*((uint32_t*)val) == 32); memcpy(val_ref.bytes, (uint8_t*)(val + 4), 32); InMemorySigner_set_revocation_base_key(&this_ptr_conv, val_ref); } int8_tArray __attribute__((visibility("default"))) TS_InMemorySigner_get_payment_key(uint32_t this_ptr) { LDKInMemorySigner this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int8_tArray ret_arr = init_arr(32, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), *InMemorySigner_get_payment_key(&this_ptr_conv), 32); return ret_arr; } void __attribute__((visibility("default"))) TS_InMemorySigner_set_payment_key(uint32_t this_ptr, int8_tArray val) { LDKInMemorySigner this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKSecretKey val_ref; CHECK(*((uint32_t*)val) == 32); memcpy(val_ref.bytes, (uint8_t*)(val + 4), 32); InMemorySigner_set_payment_key(&this_ptr_conv, val_ref); } int8_tArray __attribute__((visibility("default"))) TS_InMemorySigner_get_delayed_payment_base_key(uint32_t this_ptr) { LDKInMemorySigner this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int8_tArray ret_arr = init_arr(32, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), *InMemorySigner_get_delayed_payment_base_key(&this_ptr_conv), 32); return ret_arr; } void __attribute__((visibility("default"))) TS_InMemorySigner_set_delayed_payment_base_key(uint32_t this_ptr, int8_tArray val) { LDKInMemorySigner this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKSecretKey val_ref; CHECK(*((uint32_t*)val) == 32); memcpy(val_ref.bytes, (uint8_t*)(val + 4), 32); InMemorySigner_set_delayed_payment_base_key(&this_ptr_conv, val_ref); } int8_tArray __attribute__((visibility("default"))) TS_InMemorySigner_get_htlc_base_key(uint32_t this_ptr) { LDKInMemorySigner this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int8_tArray ret_arr = init_arr(32, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), *InMemorySigner_get_htlc_base_key(&this_ptr_conv), 32); return ret_arr; } void __attribute__((visibility("default"))) TS_InMemorySigner_set_htlc_base_key(uint32_t this_ptr, int8_tArray val) { LDKInMemorySigner this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKSecretKey val_ref; CHECK(*((uint32_t*)val) == 32); memcpy(val_ref.bytes, (uint8_t*)(val + 4), 32); InMemorySigner_set_htlc_base_key(&this_ptr_conv, val_ref); } int8_tArray __attribute__((visibility("default"))) TS_InMemorySigner_get_commitment_seed(uint32_t this_ptr) { LDKInMemorySigner this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int8_tArray ret_arr = init_arr(32, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), *InMemorySigner_get_commitment_seed(&this_ptr_conv), 32); return ret_arr; } void __attribute__((visibility("default"))) TS_InMemorySigner_set_commitment_seed(uint32_t this_ptr, int8_tArray val) { LDKInMemorySigner this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKThirtyTwoBytes val_ref; CHECK(*((uint32_t*)val) == 32); memcpy(val_ref.data, (uint8_t*)(val + 4), 32); InMemorySigner_set_commitment_seed(&this_ptr_conv, val_ref); } uint32_t __attribute__((visibility("default"))) TS_InMemorySigner_clone(uint32_t orig) { LDKInMemorySigner orig_conv; orig_conv.inner = (void*)(orig & (~1)); orig_conv.is_owned = false; LDKInMemorySigner ret_var = InMemorySigner_clone(&orig_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_InMemorySigner_new(int8_tArray funding_key, int8_tArray revocation_base_key, int8_tArray payment_key, int8_tArray delayed_payment_base_key, int8_tArray htlc_base_key, int8_tArray commitment_seed, int64_t channel_value_satoshis, int8_tArray channel_keys_id) { LDKSecretKey funding_key_ref; CHECK(*((uint32_t*)funding_key) == 32); memcpy(funding_key_ref.bytes, (uint8_t*)(funding_key + 4), 32); LDKSecretKey revocation_base_key_ref; CHECK(*((uint32_t*)revocation_base_key) == 32); memcpy(revocation_base_key_ref.bytes, (uint8_t*)(revocation_base_key + 4), 32); LDKSecretKey payment_key_ref; CHECK(*((uint32_t*)payment_key) == 32); memcpy(payment_key_ref.bytes, (uint8_t*)(payment_key + 4), 32); LDKSecretKey delayed_payment_base_key_ref; CHECK(*((uint32_t*)delayed_payment_base_key) == 32); memcpy(delayed_payment_base_key_ref.bytes, (uint8_t*)(delayed_payment_base_key + 4), 32); LDKSecretKey htlc_base_key_ref; CHECK(*((uint32_t*)htlc_base_key) == 32); memcpy(htlc_base_key_ref.bytes, (uint8_t*)(htlc_base_key + 4), 32); LDKThirtyTwoBytes commitment_seed_ref; CHECK(*((uint32_t*)commitment_seed) == 32); memcpy(commitment_seed_ref.data, (uint8_t*)(commitment_seed + 4), 32); LDKThirtyTwoBytes channel_keys_id_ref; CHECK(*((uint32_t*)channel_keys_id) == 32); memcpy(channel_keys_id_ref.data, (uint8_t*)(channel_keys_id + 4), 32); LDKInMemorySigner ret_var = InMemorySigner_new(funding_key_ref, revocation_base_key_ref, payment_key_ref, delayed_payment_base_key_ref, htlc_base_key_ref, commitment_seed_ref, channel_value_satoshis, channel_keys_id_ref); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_InMemorySigner_counterparty_pubkeys(uint32_t this_arg) { LDKInMemorySigner this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; LDKChannelPublicKeys ret_var = InMemorySigner_counterparty_pubkeys(&this_arg_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } int16_t __attribute__((visibility("default"))) TS_InMemorySigner_counterparty_selected_contest_delay(uint32_t this_arg) { LDKInMemorySigner this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; int16_t ret_val = InMemorySigner_counterparty_selected_contest_delay(&this_arg_conv); return ret_val; } int16_t __attribute__((visibility("default"))) TS_InMemorySigner_holder_selected_contest_delay(uint32_t this_arg) { LDKInMemorySigner this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; int16_t ret_val = InMemorySigner_holder_selected_contest_delay(&this_arg_conv); return ret_val; } jboolean __attribute__((visibility("default"))) TS_InMemorySigner_is_outbound(uint32_t this_arg) { LDKInMemorySigner this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; jboolean ret_val = InMemorySigner_is_outbound(&this_arg_conv); return ret_val; } uint32_t __attribute__((visibility("default"))) TS_InMemorySigner_funding_outpoint(uint32_t this_arg) { LDKInMemorySigner this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; LDKOutPoint ret_var = InMemorySigner_funding_outpoint(&this_arg_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_InMemorySigner_get_channel_parameters(uint32_t this_arg) { LDKInMemorySigner this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; LDKChannelTransactionParameters ret_var = InMemorySigner_get_channel_parameters(&this_arg_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_InMemorySigner_sign_counterparty_payment_input(uint32_t this_arg, int8_tArray spend_tx, int64_t input_idx, uint32_t descriptor) { LDKInMemorySigner this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; LDKTransaction spend_tx_ref; spend_tx_ref.datalen = *((uint32_t*)spend_tx); spend_tx_ref.data = MALLOC(spend_tx_ref.datalen, "LDKTransaction Bytes"); memcpy(spend_tx_ref.data, (uint8_t*)(spend_tx + 4), spend_tx_ref.datalen); spend_tx_ref.data_is_owned = true; LDKStaticPaymentOutputDescriptor descriptor_conv; descriptor_conv.inner = (void*)(descriptor & (~1)); descriptor_conv.is_owned = false; LDKCResult_CVec_CVec_u8ZZNoneZ* ret_conv = MALLOC(sizeof(LDKCResult_CVec_CVec_u8ZZNoneZ), "LDKCResult_CVec_CVec_u8ZZNoneZ"); *ret_conv = InMemorySigner_sign_counterparty_payment_input(&this_arg_conv, spend_tx_ref, input_idx, &descriptor_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_InMemorySigner_sign_dynamic_p2wsh_input(uint32_t this_arg, int8_tArray spend_tx, int64_t input_idx, uint32_t descriptor) { LDKInMemorySigner this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; LDKTransaction spend_tx_ref; spend_tx_ref.datalen = *((uint32_t*)spend_tx); spend_tx_ref.data = MALLOC(spend_tx_ref.datalen, "LDKTransaction Bytes"); memcpy(spend_tx_ref.data, (uint8_t*)(spend_tx + 4), spend_tx_ref.datalen); spend_tx_ref.data_is_owned = true; LDKDelayedPaymentOutputDescriptor descriptor_conv; descriptor_conv.inner = (void*)(descriptor & (~1)); descriptor_conv.is_owned = false; LDKCResult_CVec_CVec_u8ZZNoneZ* ret_conv = MALLOC(sizeof(LDKCResult_CVec_CVec_u8ZZNoneZ), "LDKCResult_CVec_CVec_u8ZZNoneZ"); *ret_conv = InMemorySigner_sign_dynamic_p2wsh_input(&this_arg_conv, spend_tx_ref, input_idx, &descriptor_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_InMemorySigner_as_BaseSign(uint32_t this_arg) { LDKInMemorySigner this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; LDKBaseSign* ret_ret =MALLOC(sizeof(LDKBaseSign), "LDKBaseSign"); *ret_ret = InMemorySigner_as_BaseSign(&this_arg_conv); return (uint64_t)ret_ret; } uint32_t __attribute__((visibility("default"))) TS_InMemorySigner_as_Sign(uint32_t this_arg) { LDKInMemorySigner this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; LDKSign* ret_ret =MALLOC(sizeof(LDKSign), "LDKSign"); *ret_ret = InMemorySigner_as_Sign(&this_arg_conv); return (uint64_t)ret_ret; } int8_tArray __attribute__((visibility("default"))) TS_InMemorySigner_write(uint32_t obj) { LDKInMemorySigner obj_conv; obj_conv.inner = (void*)(obj & (~1)); obj_conv.is_owned = false; LDKCVec_u8Z ret_var = InMemorySigner_write(&obj_conv); int8_tArray ret_arr = init_arr(ret_var.datalen, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), ret_var.data, ret_var.datalen); CVec_u8Z_free(ret_var); return ret_arr; } uint32_t __attribute__((visibility("default"))) TS_InMemorySigner_read(int8_tArray ser) { LDKu8slice ser_ref; ser_ref.datalen = *((uint32_t*)ser); ser_ref.data = (int8_t*)(ser + 4); LDKCResult_InMemorySignerDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_InMemorySignerDecodeErrorZ), "LDKCResult_InMemorySignerDecodeErrorZ"); *ret_conv = InMemorySigner_read(ser_ref); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_KeysManager_free(uint32_t this_obj) { LDKKeysManager this_obj_conv; this_obj_conv.inner = (void*)(this_obj & (~1)); this_obj_conv.is_owned = (this_obj & 1) || (this_obj == 0); KeysManager_free(this_obj_conv); } uint32_t __attribute__((visibility("default"))) TS_KeysManager_new(int8_tArray seed, int64_t starting_time_secs, int32_t starting_time_nanos) { unsigned char seed_arr[32]; CHECK(*((uint32_t*)seed) == 32); memcpy(seed_arr, (uint8_t*)(seed + 4), 32); unsigned char (*seed_ref)[32] = &seed_arr; LDKKeysManager ret_var = KeysManager_new(seed_ref, starting_time_secs, starting_time_nanos); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_KeysManager_derive_channel_keys(uint32_t this_arg, int64_t channel_value_satoshis, int8_tArray params) { LDKKeysManager this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; unsigned char params_arr[32]; CHECK(*((uint32_t*)params) == 32); memcpy(params_arr, (uint8_t*)(params + 4), 32); unsigned char (*params_ref)[32] = ¶ms_arr; LDKInMemorySigner ret_var = KeysManager_derive_channel_keys(&this_arg_conv, channel_value_satoshis, params_ref); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_KeysManager_spend_spendable_outputs(uint32_t this_arg, uint32_tArray descriptors, uint32_tArray outputs, int8_tArray change_destination_script, int32_t feerate_sat_per_1000_weight) { LDKKeysManager this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; LDKCVec_SpendableOutputDescriptorZ descriptors_constr; descriptors_constr.datalen = *((uint32_t*)descriptors); if (descriptors_constr.datalen > 0) descriptors_constr.data = MALLOC(descriptors_constr.datalen * sizeof(LDKSpendableOutputDescriptor), "LDKCVec_SpendableOutputDescriptorZ Elements"); else descriptors_constr.data = NULL; uint32_t* descriptors_vals = (uint32_t*)(descriptors + 4); for (size_t b = 0; b < descriptors_constr.datalen; b++) { uint32_t descriptors_conv_27 = descriptors_vals[b]; LDKSpendableOutputDescriptor descriptors_conv_27_conv = *(LDKSpendableOutputDescriptor*)(((uint64_t)descriptors_conv_27) & ~1); descriptors_conv_27_conv = SpendableOutputDescriptor_clone((LDKSpendableOutputDescriptor*)(((uint64_t)descriptors_conv_27) & ~1)); descriptors_constr.data[b] = descriptors_conv_27_conv; } LDKCVec_TxOutZ outputs_constr; outputs_constr.datalen = *((uint32_t*)outputs); if (outputs_constr.datalen > 0) outputs_constr.data = MALLOC(outputs_constr.datalen * sizeof(LDKTxOut), "LDKCVec_TxOutZ Elements"); else outputs_constr.data = NULL; uint32_t* outputs_vals = (uint32_t*)(outputs + 4); for (size_t h = 0; h < outputs_constr.datalen; h++) { uint32_t outputs_conv_7 = outputs_vals[h]; LDKTxOut outputs_conv_7_conv = *(LDKTxOut*)(((uint64_t)outputs_conv_7) & ~1); outputs_conv_7_conv = TxOut_clone((LDKTxOut*)(((uint64_t)outputs_conv_7) & ~1)); outputs_constr.data[h] = outputs_conv_7_conv; } LDKCVec_u8Z change_destination_script_ref; change_destination_script_ref.datalen = *((uint32_t*)change_destination_script); change_destination_script_ref.data = MALLOC(change_destination_script_ref.datalen, "LDKCVec_u8Z Bytes"); memcpy(change_destination_script_ref.data, (uint8_t*)(change_destination_script + 4), change_destination_script_ref.datalen); LDKCResult_TransactionNoneZ* ret_conv = MALLOC(sizeof(LDKCResult_TransactionNoneZ), "LDKCResult_TransactionNoneZ"); *ret_conv = KeysManager_spend_spendable_outputs(&this_arg_conv, descriptors_constr, outputs_constr, change_destination_script_ref, feerate_sat_per_1000_weight); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_KeysManager_as_KeysInterface(uint32_t this_arg) { LDKKeysManager this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; LDKKeysInterface* ret_ret =MALLOC(sizeof(LDKKeysInterface), "LDKKeysInterface"); *ret_ret = KeysManager_as_KeysInterface(&this_arg_conv); return (uint64_t)ret_ret; } void __attribute__((visibility("default"))) TS_ChannelManager_free(uint32_t this_obj) { LDKChannelManager this_obj_conv; this_obj_conv.inner = (void*)(this_obj & (~1)); this_obj_conv.is_owned = (this_obj & 1) || (this_obj == 0); ChannelManager_free(this_obj_conv); } void __attribute__((visibility("default"))) TS_ChainParameters_free(uint32_t this_obj) { LDKChainParameters this_obj_conv; this_obj_conv.inner = (void*)(this_obj & (~1)); this_obj_conv.is_owned = (this_obj & 1) || (this_obj == 0); ChainParameters_free(this_obj_conv); } uint32_t __attribute__((visibility("default"))) TS_ChainParameters_get_network(uint32_t this_ptr) { LDKChainParameters this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; uint32_t ret_conv = LDKNetwork_to_js(ChainParameters_get_network(&this_ptr_conv)); return ret_conv; } void __attribute__((visibility("default"))) TS_ChainParameters_set_network(uint32_t this_ptr, uint32_t val) { LDKChainParameters this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKNetwork val_conv = LDKNetwork_from_js(val); ChainParameters_set_network(&this_ptr_conv, val_conv); } uint32_t __attribute__((visibility("default"))) TS_ChainParameters_get_best_block(uint32_t this_ptr) { LDKChainParameters this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKBestBlock ret_var = ChainParameters_get_best_block(&this_ptr_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } void __attribute__((visibility("default"))) TS_ChainParameters_set_best_block(uint32_t this_ptr, uint32_t val) { LDKChainParameters this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKBestBlock val_conv; val_conv.inner = (void*)(val & (~1)); val_conv.is_owned = (val & 1) || (val == 0); val_conv = BestBlock_clone(&val_conv); ChainParameters_set_best_block(&this_ptr_conv, val_conv); } uint32_t __attribute__((visibility("default"))) TS_ChainParameters_new(uint32_t network_arg, uint32_t best_block_arg) { LDKNetwork network_arg_conv = LDKNetwork_from_js(network_arg); LDKBestBlock best_block_arg_conv; best_block_arg_conv.inner = (void*)(best_block_arg & (~1)); best_block_arg_conv.is_owned = (best_block_arg & 1) || (best_block_arg == 0); best_block_arg_conv = BestBlock_clone(&best_block_arg_conv); LDKChainParameters ret_var = ChainParameters_new(network_arg_conv, best_block_arg_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_ChainParameters_clone(uint32_t orig) { LDKChainParameters orig_conv; orig_conv.inner = (void*)(orig & (~1)); orig_conv.is_owned = false; LDKChainParameters ret_var = ChainParameters_clone(&orig_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } void __attribute__((visibility("default"))) TS_CounterpartyForwardingInfo_free(uint32_t this_obj) { LDKCounterpartyForwardingInfo this_obj_conv; this_obj_conv.inner = (void*)(this_obj & (~1)); this_obj_conv.is_owned = (this_obj & 1) || (this_obj == 0); CounterpartyForwardingInfo_free(this_obj_conv); } int32_t __attribute__((visibility("default"))) TS_CounterpartyForwardingInfo_get_fee_base_msat(uint32_t this_ptr) { LDKCounterpartyForwardingInfo this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int32_t ret_val = CounterpartyForwardingInfo_get_fee_base_msat(&this_ptr_conv); return ret_val; } void __attribute__((visibility("default"))) TS_CounterpartyForwardingInfo_set_fee_base_msat(uint32_t this_ptr, int32_t val) { LDKCounterpartyForwardingInfo this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; CounterpartyForwardingInfo_set_fee_base_msat(&this_ptr_conv, val); } int32_t __attribute__((visibility("default"))) TS_CounterpartyForwardingInfo_get_fee_proportional_millionths(uint32_t this_ptr) { LDKCounterpartyForwardingInfo this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int32_t ret_val = CounterpartyForwardingInfo_get_fee_proportional_millionths(&this_ptr_conv); return ret_val; } void __attribute__((visibility("default"))) TS_CounterpartyForwardingInfo_set_fee_proportional_millionths(uint32_t this_ptr, int32_t val) { LDKCounterpartyForwardingInfo this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; CounterpartyForwardingInfo_set_fee_proportional_millionths(&this_ptr_conv, val); } int16_t __attribute__((visibility("default"))) TS_CounterpartyForwardingInfo_get_cltv_expiry_delta(uint32_t this_ptr) { LDKCounterpartyForwardingInfo this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int16_t ret_val = CounterpartyForwardingInfo_get_cltv_expiry_delta(&this_ptr_conv); return ret_val; } void __attribute__((visibility("default"))) TS_CounterpartyForwardingInfo_set_cltv_expiry_delta(uint32_t this_ptr, int16_t val) { LDKCounterpartyForwardingInfo this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; CounterpartyForwardingInfo_set_cltv_expiry_delta(&this_ptr_conv, val); } uint32_t __attribute__((visibility("default"))) TS_CounterpartyForwardingInfo_new(int32_t fee_base_msat_arg, int32_t fee_proportional_millionths_arg, int16_t cltv_expiry_delta_arg) { LDKCounterpartyForwardingInfo ret_var = CounterpartyForwardingInfo_new(fee_base_msat_arg, fee_proportional_millionths_arg, cltv_expiry_delta_arg); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_CounterpartyForwardingInfo_clone(uint32_t orig) { LDKCounterpartyForwardingInfo orig_conv; orig_conv.inner = (void*)(orig & (~1)); orig_conv.is_owned = false; LDKCounterpartyForwardingInfo ret_var = CounterpartyForwardingInfo_clone(&orig_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } void __attribute__((visibility("default"))) TS_ChannelCounterparty_free(uint32_t this_obj) { LDKChannelCounterparty this_obj_conv; this_obj_conv.inner = (void*)(this_obj & (~1)); this_obj_conv.is_owned = (this_obj & 1) || (this_obj == 0); ChannelCounterparty_free(this_obj_conv); } int8_tArray __attribute__((visibility("default"))) TS_ChannelCounterparty_get_node_id(uint32_t this_ptr) { LDKChannelCounterparty this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int8_tArray ret_arr = init_arr(33, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), ChannelCounterparty_get_node_id(&this_ptr_conv).compressed_form, 33); return ret_arr; } void __attribute__((visibility("default"))) TS_ChannelCounterparty_set_node_id(uint32_t this_ptr, int8_tArray val) { LDKChannelCounterparty this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKPublicKey val_ref; CHECK(*((uint32_t*)val) == 33); memcpy(val_ref.compressed_form, (uint8_t*)(val + 4), 33); ChannelCounterparty_set_node_id(&this_ptr_conv, val_ref); } uint32_t __attribute__((visibility("default"))) TS_ChannelCounterparty_get_features(uint32_t this_ptr) { LDKChannelCounterparty this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKInitFeatures ret_var = ChannelCounterparty_get_features(&this_ptr_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } void __attribute__((visibility("default"))) TS_ChannelCounterparty_set_features(uint32_t this_ptr, uint32_t val) { LDKChannelCounterparty this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKInitFeatures val_conv; val_conv.inner = (void*)(val & (~1)); val_conv.is_owned = (val & 1) || (val == 0); val_conv = InitFeatures_clone(&val_conv); ChannelCounterparty_set_features(&this_ptr_conv, val_conv); } int64_t __attribute__((visibility("default"))) TS_ChannelCounterparty_get_unspendable_punishment_reserve(uint32_t this_ptr) { LDKChannelCounterparty this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int64_t ret_val = ChannelCounterparty_get_unspendable_punishment_reserve(&this_ptr_conv); return ret_val; } void __attribute__((visibility("default"))) TS_ChannelCounterparty_set_unspendable_punishment_reserve(uint32_t this_ptr, int64_t val) { LDKChannelCounterparty this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; ChannelCounterparty_set_unspendable_punishment_reserve(&this_ptr_conv, val); } uint32_t __attribute__((visibility("default"))) TS_ChannelCounterparty_get_forwarding_info(uint32_t this_ptr) { LDKChannelCounterparty this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKCounterpartyForwardingInfo ret_var = ChannelCounterparty_get_forwarding_info(&this_ptr_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } void __attribute__((visibility("default"))) TS_ChannelCounterparty_set_forwarding_info(uint32_t this_ptr, uint32_t val) { LDKChannelCounterparty this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKCounterpartyForwardingInfo val_conv; val_conv.inner = (void*)(val & (~1)); val_conv.is_owned = (val & 1) || (val == 0); val_conv = CounterpartyForwardingInfo_clone(&val_conv); ChannelCounterparty_set_forwarding_info(&this_ptr_conv, val_conv); } uint32_t __attribute__((visibility("default"))) TS_ChannelCounterparty_new(int8_tArray node_id_arg, uint32_t features_arg, int64_t unspendable_punishment_reserve_arg, uint32_t forwarding_info_arg) { LDKPublicKey node_id_arg_ref; CHECK(*((uint32_t*)node_id_arg) == 33); memcpy(node_id_arg_ref.compressed_form, (uint8_t*)(node_id_arg + 4), 33); LDKInitFeatures features_arg_conv; features_arg_conv.inner = (void*)(features_arg & (~1)); features_arg_conv.is_owned = (features_arg & 1) || (features_arg == 0); features_arg_conv = InitFeatures_clone(&features_arg_conv); LDKCounterpartyForwardingInfo forwarding_info_arg_conv; forwarding_info_arg_conv.inner = (void*)(forwarding_info_arg & (~1)); forwarding_info_arg_conv.is_owned = (forwarding_info_arg & 1) || (forwarding_info_arg == 0); forwarding_info_arg_conv = CounterpartyForwardingInfo_clone(&forwarding_info_arg_conv); LDKChannelCounterparty ret_var = ChannelCounterparty_new(node_id_arg_ref, features_arg_conv, unspendable_punishment_reserve_arg, forwarding_info_arg_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_ChannelCounterparty_clone(uint32_t orig) { LDKChannelCounterparty orig_conv; orig_conv.inner = (void*)(orig & (~1)); orig_conv.is_owned = false; LDKChannelCounterparty ret_var = ChannelCounterparty_clone(&orig_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } void __attribute__((visibility("default"))) TS_ChannelDetails_free(uint32_t this_obj) { LDKChannelDetails this_obj_conv; this_obj_conv.inner = (void*)(this_obj & (~1)); this_obj_conv.is_owned = (this_obj & 1) || (this_obj == 0); ChannelDetails_free(this_obj_conv); } int8_tArray __attribute__((visibility("default"))) TS_ChannelDetails_get_channel_id(uint32_t this_ptr) { LDKChannelDetails this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int8_tArray ret_arr = init_arr(32, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), *ChannelDetails_get_channel_id(&this_ptr_conv), 32); return ret_arr; } void __attribute__((visibility("default"))) TS_ChannelDetails_set_channel_id(uint32_t this_ptr, int8_tArray val) { LDKChannelDetails this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKThirtyTwoBytes val_ref; CHECK(*((uint32_t*)val) == 32); memcpy(val_ref.data, (uint8_t*)(val + 4), 32); ChannelDetails_set_channel_id(&this_ptr_conv, val_ref); } uint32_t __attribute__((visibility("default"))) TS_ChannelDetails_get_counterparty(uint32_t this_ptr) { LDKChannelDetails this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKChannelCounterparty ret_var = ChannelDetails_get_counterparty(&this_ptr_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } void __attribute__((visibility("default"))) TS_ChannelDetails_set_counterparty(uint32_t this_ptr, uint32_t val) { LDKChannelDetails this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKChannelCounterparty val_conv; val_conv.inner = (void*)(val & (~1)); val_conv.is_owned = (val & 1) || (val == 0); val_conv = ChannelCounterparty_clone(&val_conv); ChannelDetails_set_counterparty(&this_ptr_conv, val_conv); } uint32_t __attribute__((visibility("default"))) TS_ChannelDetails_get_funding_txo(uint32_t this_ptr) { LDKChannelDetails this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKOutPoint ret_var = ChannelDetails_get_funding_txo(&this_ptr_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } void __attribute__((visibility("default"))) TS_ChannelDetails_set_funding_txo(uint32_t this_ptr, uint32_t val) { LDKChannelDetails this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKOutPoint val_conv; val_conv.inner = (void*)(val & (~1)); val_conv.is_owned = (val & 1) || (val == 0); val_conv = OutPoint_clone(&val_conv); ChannelDetails_set_funding_txo(&this_ptr_conv, val_conv); } uint32_t __attribute__((visibility("default"))) TS_ChannelDetails_get_short_channel_id(uint32_t this_ptr) { LDKChannelDetails this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKCOption_u64Z *ret_copy = MALLOC(sizeof(LDKCOption_u64Z), "LDKCOption_u64Z"); *ret_copy = ChannelDetails_get_short_channel_id(&this_ptr_conv); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } void __attribute__((visibility("default"))) TS_ChannelDetails_set_short_channel_id(uint32_t this_ptr, uint32_t val) { LDKChannelDetails this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKCOption_u64Z val_conv = *(LDKCOption_u64Z*)(((uint64_t)val) & ~1); val_conv = COption_u64Z_clone((LDKCOption_u64Z*)(((uint64_t)val) & ~1)); ChannelDetails_set_short_channel_id(&this_ptr_conv, val_conv); } int64_t __attribute__((visibility("default"))) TS_ChannelDetails_get_channel_value_satoshis(uint32_t this_ptr) { LDKChannelDetails this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int64_t ret_val = ChannelDetails_get_channel_value_satoshis(&this_ptr_conv); return ret_val; } void __attribute__((visibility("default"))) TS_ChannelDetails_set_channel_value_satoshis(uint32_t this_ptr, int64_t val) { LDKChannelDetails this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; ChannelDetails_set_channel_value_satoshis(&this_ptr_conv, val); } uint32_t __attribute__((visibility("default"))) TS_ChannelDetails_get_unspendable_punishment_reserve(uint32_t this_ptr) { LDKChannelDetails this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKCOption_u64Z *ret_copy = MALLOC(sizeof(LDKCOption_u64Z), "LDKCOption_u64Z"); *ret_copy = ChannelDetails_get_unspendable_punishment_reserve(&this_ptr_conv); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } void __attribute__((visibility("default"))) TS_ChannelDetails_set_unspendable_punishment_reserve(uint32_t this_ptr, uint32_t val) { LDKChannelDetails this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKCOption_u64Z val_conv = *(LDKCOption_u64Z*)(((uint64_t)val) & ~1); val_conv = COption_u64Z_clone((LDKCOption_u64Z*)(((uint64_t)val) & ~1)); ChannelDetails_set_unspendable_punishment_reserve(&this_ptr_conv, val_conv); } int64_t __attribute__((visibility("default"))) TS_ChannelDetails_get_user_id(uint32_t this_ptr) { LDKChannelDetails this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int64_t ret_val = ChannelDetails_get_user_id(&this_ptr_conv); return ret_val; } void __attribute__((visibility("default"))) TS_ChannelDetails_set_user_id(uint32_t this_ptr, int64_t val) { LDKChannelDetails this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; ChannelDetails_set_user_id(&this_ptr_conv, val); } int64_t __attribute__((visibility("default"))) TS_ChannelDetails_get_outbound_capacity_msat(uint32_t this_ptr) { LDKChannelDetails this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int64_t ret_val = ChannelDetails_get_outbound_capacity_msat(&this_ptr_conv); return ret_val; } void __attribute__((visibility("default"))) TS_ChannelDetails_set_outbound_capacity_msat(uint32_t this_ptr, int64_t val) { LDKChannelDetails this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; ChannelDetails_set_outbound_capacity_msat(&this_ptr_conv, val); } int64_t __attribute__((visibility("default"))) TS_ChannelDetails_get_inbound_capacity_msat(uint32_t this_ptr) { LDKChannelDetails this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int64_t ret_val = ChannelDetails_get_inbound_capacity_msat(&this_ptr_conv); return ret_val; } void __attribute__((visibility("default"))) TS_ChannelDetails_set_inbound_capacity_msat(uint32_t this_ptr, int64_t val) { LDKChannelDetails this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; ChannelDetails_set_inbound_capacity_msat(&this_ptr_conv, val); } uint32_t __attribute__((visibility("default"))) TS_ChannelDetails_get_confirmations_required(uint32_t this_ptr) { LDKChannelDetails this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKCOption_u32Z *ret_copy = MALLOC(sizeof(LDKCOption_u32Z), "LDKCOption_u32Z"); *ret_copy = ChannelDetails_get_confirmations_required(&this_ptr_conv); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } void __attribute__((visibility("default"))) TS_ChannelDetails_set_confirmations_required(uint32_t this_ptr, uint32_t val) { LDKChannelDetails this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKCOption_u32Z val_conv = *(LDKCOption_u32Z*)(((uint64_t)val) & ~1); val_conv = COption_u32Z_clone((LDKCOption_u32Z*)(((uint64_t)val) & ~1)); ChannelDetails_set_confirmations_required(&this_ptr_conv, val_conv); } uint32_t __attribute__((visibility("default"))) TS_ChannelDetails_get_force_close_spend_delay(uint32_t this_ptr) { LDKChannelDetails this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKCOption_u16Z *ret_copy = MALLOC(sizeof(LDKCOption_u16Z), "LDKCOption_u16Z"); *ret_copy = ChannelDetails_get_force_close_spend_delay(&this_ptr_conv); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } void __attribute__((visibility("default"))) TS_ChannelDetails_set_force_close_spend_delay(uint32_t this_ptr, uint32_t val) { LDKChannelDetails this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKCOption_u16Z val_conv = *(LDKCOption_u16Z*)(((uint64_t)val) & ~1); val_conv = COption_u16Z_clone((LDKCOption_u16Z*)(((uint64_t)val) & ~1)); ChannelDetails_set_force_close_spend_delay(&this_ptr_conv, val_conv); } jboolean __attribute__((visibility("default"))) TS_ChannelDetails_get_is_outbound(uint32_t this_ptr) { LDKChannelDetails this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; jboolean ret_val = ChannelDetails_get_is_outbound(&this_ptr_conv); return ret_val; } void __attribute__((visibility("default"))) TS_ChannelDetails_set_is_outbound(uint32_t this_ptr, jboolean val) { LDKChannelDetails this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; ChannelDetails_set_is_outbound(&this_ptr_conv, val); } jboolean __attribute__((visibility("default"))) TS_ChannelDetails_get_is_funding_locked(uint32_t this_ptr) { LDKChannelDetails this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; jboolean ret_val = ChannelDetails_get_is_funding_locked(&this_ptr_conv); return ret_val; } void __attribute__((visibility("default"))) TS_ChannelDetails_set_is_funding_locked(uint32_t this_ptr, jboolean val) { LDKChannelDetails this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; ChannelDetails_set_is_funding_locked(&this_ptr_conv, val); } jboolean __attribute__((visibility("default"))) TS_ChannelDetails_get_is_usable(uint32_t this_ptr) { LDKChannelDetails this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; jboolean ret_val = ChannelDetails_get_is_usable(&this_ptr_conv); return ret_val; } void __attribute__((visibility("default"))) TS_ChannelDetails_set_is_usable(uint32_t this_ptr, jboolean val) { LDKChannelDetails this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; ChannelDetails_set_is_usable(&this_ptr_conv, val); } jboolean __attribute__((visibility("default"))) TS_ChannelDetails_get_is_public(uint32_t this_ptr) { LDKChannelDetails this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; jboolean ret_val = ChannelDetails_get_is_public(&this_ptr_conv); return ret_val; } void __attribute__((visibility("default"))) TS_ChannelDetails_set_is_public(uint32_t this_ptr, jboolean val) { LDKChannelDetails this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; ChannelDetails_set_is_public(&this_ptr_conv, val); } uint32_t __attribute__((visibility("default"))) TS_ChannelDetails_new(int8_tArray channel_id_arg, uint32_t counterparty_arg, uint32_t funding_txo_arg, uint32_t short_channel_id_arg, int64_t channel_value_satoshis_arg, uint32_t unspendable_punishment_reserve_arg, int64_t user_id_arg, int64_t outbound_capacity_msat_arg, int64_t inbound_capacity_msat_arg, uint32_t confirmations_required_arg, uint32_t force_close_spend_delay_arg, jboolean is_outbound_arg, jboolean is_funding_locked_arg, jboolean is_usable_arg, jboolean is_public_arg) { LDKThirtyTwoBytes channel_id_arg_ref; CHECK(*((uint32_t*)channel_id_arg) == 32); memcpy(channel_id_arg_ref.data, (uint8_t*)(channel_id_arg + 4), 32); LDKChannelCounterparty counterparty_arg_conv; counterparty_arg_conv.inner = (void*)(counterparty_arg & (~1)); counterparty_arg_conv.is_owned = (counterparty_arg & 1) || (counterparty_arg == 0); counterparty_arg_conv = ChannelCounterparty_clone(&counterparty_arg_conv); LDKOutPoint funding_txo_arg_conv; funding_txo_arg_conv.inner = (void*)(funding_txo_arg & (~1)); funding_txo_arg_conv.is_owned = (funding_txo_arg & 1) || (funding_txo_arg == 0); funding_txo_arg_conv = OutPoint_clone(&funding_txo_arg_conv); LDKCOption_u64Z short_channel_id_arg_conv = *(LDKCOption_u64Z*)(((uint64_t)short_channel_id_arg) & ~1); short_channel_id_arg_conv = COption_u64Z_clone((LDKCOption_u64Z*)(((uint64_t)short_channel_id_arg) & ~1)); LDKCOption_u64Z unspendable_punishment_reserve_arg_conv = *(LDKCOption_u64Z*)(((uint64_t)unspendable_punishment_reserve_arg) & ~1); LDKCOption_u32Z confirmations_required_arg_conv = *(LDKCOption_u32Z*)(((uint64_t)confirmations_required_arg) & ~1); confirmations_required_arg_conv = COption_u32Z_clone((LDKCOption_u32Z*)(((uint64_t)confirmations_required_arg) & ~1)); LDKCOption_u16Z force_close_spend_delay_arg_conv = *(LDKCOption_u16Z*)(((uint64_t)force_close_spend_delay_arg) & ~1); force_close_spend_delay_arg_conv = COption_u16Z_clone((LDKCOption_u16Z*)(((uint64_t)force_close_spend_delay_arg) & ~1)); LDKChannelDetails ret_var = ChannelDetails_new(channel_id_arg_ref, counterparty_arg_conv, funding_txo_arg_conv, short_channel_id_arg_conv, channel_value_satoshis_arg, unspendable_punishment_reserve_arg_conv, user_id_arg, outbound_capacity_msat_arg, inbound_capacity_msat_arg, confirmations_required_arg_conv, force_close_spend_delay_arg_conv, is_outbound_arg, is_funding_locked_arg, is_usable_arg, is_public_arg); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_ChannelDetails_clone(uint32_t orig) { LDKChannelDetails orig_conv; orig_conv.inner = (void*)(orig & (~1)); orig_conv.is_owned = false; LDKChannelDetails ret_var = ChannelDetails_clone(&orig_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } void __attribute__((visibility("default"))) TS_PaymentSendFailure_free(uint32_t this_ptr) { if ((this_ptr & 1) != 0) return; LDKPaymentSendFailure this_ptr_conv = *(LDKPaymentSendFailure*)(((uint64_t)this_ptr) & ~1); FREE((void*)this_ptr); PaymentSendFailure_free(this_ptr_conv); } uint32_t __attribute__((visibility("default"))) TS_PaymentSendFailure_clone(uint32_t orig) { LDKPaymentSendFailure* orig_conv = (LDKPaymentSendFailure*)orig; LDKPaymentSendFailure *ret_copy = MALLOC(sizeof(LDKPaymentSendFailure), "LDKPaymentSendFailure"); *ret_copy = PaymentSendFailure_clone(orig_conv); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_PaymentSendFailure_parameter_error(uint32_t a) { LDKAPIError a_conv = *(LDKAPIError*)(((uint64_t)a) & ~1); a_conv = APIError_clone((LDKAPIError*)(((uint64_t)a) & ~1)); LDKPaymentSendFailure *ret_copy = MALLOC(sizeof(LDKPaymentSendFailure), "LDKPaymentSendFailure"); *ret_copy = PaymentSendFailure_parameter_error(a_conv); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_PaymentSendFailure_path_parameter_error(uint32_tArray a) { LDKCVec_CResult_NoneAPIErrorZZ a_constr; a_constr.datalen = *((uint32_t*)a); if (a_constr.datalen > 0) a_constr.data = MALLOC(a_constr.datalen * sizeof(LDKCResult_NoneAPIErrorZ), "LDKCVec_CResult_NoneAPIErrorZZ Elements"); else a_constr.data = NULL; uint32_t* a_vals = (uint32_t*)(a + 4); for (size_t w = 0; w < a_constr.datalen; w++) { uint32_t a_conv_22 = a_vals[w]; LDKCResult_NoneAPIErrorZ a_conv_22_conv = *(LDKCResult_NoneAPIErrorZ*)(((uint64_t)a_conv_22) & ~1); a_conv_22_conv = CResult_NoneAPIErrorZ_clone((LDKCResult_NoneAPIErrorZ*)(((uint64_t)a_conv_22) & ~1)); a_constr.data[w] = a_conv_22_conv; } LDKPaymentSendFailure *ret_copy = MALLOC(sizeof(LDKPaymentSendFailure), "LDKPaymentSendFailure"); *ret_copy = PaymentSendFailure_path_parameter_error(a_constr); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_PaymentSendFailure_all_failed_retry_safe(uint32_tArray a) { LDKCVec_APIErrorZ a_constr; a_constr.datalen = *((uint32_t*)a); if (a_constr.datalen > 0) a_constr.data = MALLOC(a_constr.datalen * sizeof(LDKAPIError), "LDKCVec_APIErrorZ Elements"); else a_constr.data = NULL; uint32_t* a_vals = (uint32_t*)(a + 4); for (size_t k = 0; k < a_constr.datalen; k++) { uint32_t a_conv_10 = a_vals[k]; LDKAPIError a_conv_10_conv = *(LDKAPIError*)(((uint64_t)a_conv_10) & ~1); a_conv_10_conv = APIError_clone((LDKAPIError*)(((uint64_t)a_conv_10) & ~1)); a_constr.data[k] = a_conv_10_conv; } LDKPaymentSendFailure *ret_copy = MALLOC(sizeof(LDKPaymentSendFailure), "LDKPaymentSendFailure"); *ret_copy = PaymentSendFailure_all_failed_retry_safe(a_constr); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_PaymentSendFailure_partial_failure(uint32_tArray a) { LDKCVec_CResult_NoneAPIErrorZZ a_constr; a_constr.datalen = *((uint32_t*)a); if (a_constr.datalen > 0) a_constr.data = MALLOC(a_constr.datalen * sizeof(LDKCResult_NoneAPIErrorZ), "LDKCVec_CResult_NoneAPIErrorZZ Elements"); else a_constr.data = NULL; uint32_t* a_vals = (uint32_t*)(a + 4); for (size_t w = 0; w < a_constr.datalen; w++) { uint32_t a_conv_22 = a_vals[w]; LDKCResult_NoneAPIErrorZ a_conv_22_conv = *(LDKCResult_NoneAPIErrorZ*)(((uint64_t)a_conv_22) & ~1); a_conv_22_conv = CResult_NoneAPIErrorZ_clone((LDKCResult_NoneAPIErrorZ*)(((uint64_t)a_conv_22) & ~1)); a_constr.data[w] = a_conv_22_conv; } LDKPaymentSendFailure *ret_copy = MALLOC(sizeof(LDKPaymentSendFailure), "LDKPaymentSendFailure"); *ret_copy = PaymentSendFailure_partial_failure(a_constr); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_ChannelManager_new(uint32_t fee_est, uint32_t chain_monitor, uint32_t tx_broadcaster, uint32_t logger, uint32_t keys_manager, uint32_t config, uint32_t params) { LDKFeeEstimator fee_est_conv = *(LDKFeeEstimator*)(((uint64_t)fee_est) & ~1); LDKWatch chain_monitor_conv = *(LDKWatch*)(((uint64_t)chain_monitor) & ~1); LDKBroadcasterInterface tx_broadcaster_conv = *(LDKBroadcasterInterface*)(((uint64_t)tx_broadcaster) & ~1); LDKLogger logger_conv = *(LDKLogger*)(((uint64_t)logger) & ~1); LDKKeysInterface keys_manager_conv = *(LDKKeysInterface*)(((uint64_t)keys_manager) & ~1); LDKUserConfig config_conv; config_conv.inner = (void*)(config & (~1)); config_conv.is_owned = (config & 1) || (config == 0); config_conv = UserConfig_clone(&config_conv); LDKChainParameters params_conv; params_conv.inner = (void*)(params & (~1)); params_conv.is_owned = (params & 1) || (params == 0); params_conv = ChainParameters_clone(¶ms_conv); LDKChannelManager ret_var = ChannelManager_new(fee_est_conv, chain_monitor_conv, tx_broadcaster_conv, logger_conv, keys_manager_conv, config_conv, params_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_ChannelManager_get_current_default_configuration(uint32_t this_arg) { LDKChannelManager this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; LDKUserConfig ret_var = ChannelManager_get_current_default_configuration(&this_arg_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_ChannelManager_create_channel(uint32_t this_arg, int8_tArray their_network_key, int64_t channel_value_satoshis, int64_t push_msat, int64_t user_id, uint32_t override_config) { LDKChannelManager this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; LDKPublicKey their_network_key_ref; CHECK(*((uint32_t*)their_network_key) == 33); memcpy(their_network_key_ref.compressed_form, (uint8_t*)(their_network_key + 4), 33); LDKUserConfig override_config_conv; override_config_conv.inner = (void*)(override_config & (~1)); override_config_conv.is_owned = (override_config & 1) || (override_config == 0); override_config_conv = UserConfig_clone(&override_config_conv); LDKCResult_NoneAPIErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_NoneAPIErrorZ), "LDKCResult_NoneAPIErrorZ"); *ret_conv = ChannelManager_create_channel(&this_arg_conv, their_network_key_ref, channel_value_satoshis, push_msat, user_id, override_config_conv); return (uint64_t)ret_conv; } uint32_tArray __attribute__((visibility("default"))) TS_ChannelManager_list_channels(uint32_t this_arg) { LDKChannelManager this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; LDKCVec_ChannelDetailsZ ret_var = ChannelManager_list_channels(&this_arg_conv); uint32_tArray ret_arr = init_arr(ret_var.datalen, sizeof(uint32_t), "Native uint32_tArray Bytes"); uint32_t *ret_arr_ptr = (uint32_t*)(ret_arr + 4); for (size_t q = 0; q < ret_var.datalen; q++) { LDKChannelDetails ret_conv_16_var = ret_var.data[q]; CHECK((((uint64_t)ret_conv_16_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_conv_16_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_conv_16_ref = (uint64_t)ret_conv_16_var.inner; if (ret_conv_16_var.is_owned) { ret_conv_16_ref |= 1; } ret_arr_ptr[q] = ret_conv_16_ref; } FREE(ret_var.data); return ret_arr; } uint32_tArray __attribute__((visibility("default"))) TS_ChannelManager_list_usable_channels(uint32_t this_arg) { LDKChannelManager this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; LDKCVec_ChannelDetailsZ ret_var = ChannelManager_list_usable_channels(&this_arg_conv); uint32_tArray ret_arr = init_arr(ret_var.datalen, sizeof(uint32_t), "Native uint32_tArray Bytes"); uint32_t *ret_arr_ptr = (uint32_t*)(ret_arr + 4); for (size_t q = 0; q < ret_var.datalen; q++) { LDKChannelDetails ret_conv_16_var = ret_var.data[q]; CHECK((((uint64_t)ret_conv_16_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_conv_16_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_conv_16_ref = (uint64_t)ret_conv_16_var.inner; if (ret_conv_16_var.is_owned) { ret_conv_16_ref |= 1; } ret_arr_ptr[q] = ret_conv_16_ref; } FREE(ret_var.data); return ret_arr; } uint32_t __attribute__((visibility("default"))) TS_ChannelManager_close_channel(uint32_t this_arg, int8_tArray channel_id) { LDKChannelManager this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; unsigned char channel_id_arr[32]; CHECK(*((uint32_t*)channel_id) == 32); memcpy(channel_id_arr, (uint8_t*)(channel_id + 4), 32); unsigned char (*channel_id_ref)[32] = &channel_id_arr; LDKCResult_NoneAPIErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_NoneAPIErrorZ), "LDKCResult_NoneAPIErrorZ"); *ret_conv = ChannelManager_close_channel(&this_arg_conv, channel_id_ref); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_ChannelManager_close_channel_with_target_feerate(uint32_t this_arg, int8_tArray channel_id, int32_t target_feerate_sats_per_1000_weight) { LDKChannelManager this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; unsigned char channel_id_arr[32]; CHECK(*((uint32_t*)channel_id) == 32); memcpy(channel_id_arr, (uint8_t*)(channel_id + 4), 32); unsigned char (*channel_id_ref)[32] = &channel_id_arr; LDKCResult_NoneAPIErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_NoneAPIErrorZ), "LDKCResult_NoneAPIErrorZ"); *ret_conv = ChannelManager_close_channel_with_target_feerate(&this_arg_conv, channel_id_ref, target_feerate_sats_per_1000_weight); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_ChannelManager_force_close_channel(uint32_t this_arg, int8_tArray channel_id) { LDKChannelManager this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; unsigned char channel_id_arr[32]; CHECK(*((uint32_t*)channel_id) == 32); memcpy(channel_id_arr, (uint8_t*)(channel_id + 4), 32); unsigned char (*channel_id_ref)[32] = &channel_id_arr; LDKCResult_NoneAPIErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_NoneAPIErrorZ), "LDKCResult_NoneAPIErrorZ"); *ret_conv = ChannelManager_force_close_channel(&this_arg_conv, channel_id_ref); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_ChannelManager_force_close_all_channels(uint32_t this_arg) { LDKChannelManager this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; ChannelManager_force_close_all_channels(&this_arg_conv); } uint32_t __attribute__((visibility("default"))) TS_ChannelManager_send_payment(uint32_t this_arg, uint32_t route, int8_tArray payment_hash, int8_tArray payment_secret) { LDKChannelManager this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; LDKRoute route_conv; route_conv.inner = (void*)(route & (~1)); route_conv.is_owned = false; LDKThirtyTwoBytes payment_hash_ref; CHECK(*((uint32_t*)payment_hash) == 32); memcpy(payment_hash_ref.data, (uint8_t*)(payment_hash + 4), 32); LDKThirtyTwoBytes payment_secret_ref; CHECK(*((uint32_t*)payment_secret) == 32); memcpy(payment_secret_ref.data, (uint8_t*)(payment_secret + 4), 32); LDKCResult_NonePaymentSendFailureZ* ret_conv = MALLOC(sizeof(LDKCResult_NonePaymentSendFailureZ), "LDKCResult_NonePaymentSendFailureZ"); *ret_conv = ChannelManager_send_payment(&this_arg_conv, &route_conv, payment_hash_ref, payment_secret_ref); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_ChannelManager_send_spontaneous_payment(uint32_t this_arg, uint32_t route, int8_tArray payment_preimage) { LDKChannelManager this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; LDKRoute route_conv; route_conv.inner = (void*)(route & (~1)); route_conv.is_owned = false; LDKThirtyTwoBytes payment_preimage_ref; CHECK(*((uint32_t*)payment_preimage) == 32); memcpy(payment_preimage_ref.data, (uint8_t*)(payment_preimage + 4), 32); LDKCResult_PaymentHashPaymentSendFailureZ* ret_conv = MALLOC(sizeof(LDKCResult_PaymentHashPaymentSendFailureZ), "LDKCResult_PaymentHashPaymentSendFailureZ"); *ret_conv = ChannelManager_send_spontaneous_payment(&this_arg_conv, &route_conv, payment_preimage_ref); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_ChannelManager_funding_transaction_generated(uint32_t this_arg, int8_tArray temporary_channel_id, int8_tArray funding_transaction) { LDKChannelManager this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; unsigned char temporary_channel_id_arr[32]; CHECK(*((uint32_t*)temporary_channel_id) == 32); memcpy(temporary_channel_id_arr, (uint8_t*)(temporary_channel_id + 4), 32); unsigned char (*temporary_channel_id_ref)[32] = &temporary_channel_id_arr; LDKTransaction funding_transaction_ref; funding_transaction_ref.datalen = *((uint32_t*)funding_transaction); funding_transaction_ref.data = MALLOC(funding_transaction_ref.datalen, "LDKTransaction Bytes"); memcpy(funding_transaction_ref.data, (uint8_t*)(funding_transaction + 4), funding_transaction_ref.datalen); funding_transaction_ref.data_is_owned = true; LDKCResult_NoneAPIErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_NoneAPIErrorZ), "LDKCResult_NoneAPIErrorZ"); *ret_conv = ChannelManager_funding_transaction_generated(&this_arg_conv, temporary_channel_id_ref, funding_transaction_ref); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_ChannelManager_broadcast_node_announcement(uint32_t this_arg, int8_tArray rgb, int8_tArray alias, uint32_tArray addresses) { LDKChannelManager this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; LDKThreeBytes rgb_ref; CHECK(*((uint32_t*)rgb) == 3); memcpy(rgb_ref.data, (uint8_t*)(rgb + 4), 3); LDKThirtyTwoBytes alias_ref; CHECK(*((uint32_t*)alias) == 32); memcpy(alias_ref.data, (uint8_t*)(alias + 4), 32); LDKCVec_NetAddressZ addresses_constr; addresses_constr.datalen = *((uint32_t*)addresses); if (addresses_constr.datalen > 0) addresses_constr.data = MALLOC(addresses_constr.datalen * sizeof(LDKNetAddress), "LDKCVec_NetAddressZ Elements"); else addresses_constr.data = NULL; uint32_t* addresses_vals = (uint32_t*)(addresses + 4); for (size_t m = 0; m < addresses_constr.datalen; m++) { uint32_t addresses_conv_12 = addresses_vals[m]; LDKNetAddress addresses_conv_12_conv = *(LDKNetAddress*)(((uint64_t)addresses_conv_12) & ~1); addresses_constr.data[m] = addresses_conv_12_conv; } ChannelManager_broadcast_node_announcement(&this_arg_conv, rgb_ref, alias_ref, addresses_constr); } void __attribute__((visibility("default"))) TS_ChannelManager_process_pending_htlc_forwards(uint32_t this_arg) { LDKChannelManager this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; ChannelManager_process_pending_htlc_forwards(&this_arg_conv); } void __attribute__((visibility("default"))) TS_ChannelManager_timer_tick_occurred(uint32_t this_arg) { LDKChannelManager this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; ChannelManager_timer_tick_occurred(&this_arg_conv); } jboolean __attribute__((visibility("default"))) TS_ChannelManager_fail_htlc_backwards(uint32_t this_arg, int8_tArray payment_hash) { LDKChannelManager this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; unsigned char payment_hash_arr[32]; CHECK(*((uint32_t*)payment_hash) == 32); memcpy(payment_hash_arr, (uint8_t*)(payment_hash + 4), 32); unsigned char (*payment_hash_ref)[32] = &payment_hash_arr; jboolean ret_val = ChannelManager_fail_htlc_backwards(&this_arg_conv, payment_hash_ref); return ret_val; } jboolean __attribute__((visibility("default"))) TS_ChannelManager_claim_funds(uint32_t this_arg, int8_tArray payment_preimage) { LDKChannelManager this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; LDKThirtyTwoBytes payment_preimage_ref; CHECK(*((uint32_t*)payment_preimage) == 32); memcpy(payment_preimage_ref.data, (uint8_t*)(payment_preimage + 4), 32); jboolean ret_val = ChannelManager_claim_funds(&this_arg_conv, payment_preimage_ref); return ret_val; } int8_tArray __attribute__((visibility("default"))) TS_ChannelManager_get_our_node_id(uint32_t this_arg) { LDKChannelManager this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; int8_tArray ret_arr = init_arr(33, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), ChannelManager_get_our_node_id(&this_arg_conv).compressed_form, 33); return ret_arr; } void __attribute__((visibility("default"))) TS_ChannelManager_channel_monitor_updated(uint32_t this_arg, uint32_t funding_txo, int64_t highest_applied_update_id) { LDKChannelManager this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; LDKOutPoint funding_txo_conv; funding_txo_conv.inner = (void*)(funding_txo & (~1)); funding_txo_conv.is_owned = false; ChannelManager_channel_monitor_updated(&this_arg_conv, &funding_txo_conv, highest_applied_update_id); } uint32_t __attribute__((visibility("default"))) TS_ChannelManager_create_inbound_payment(uint32_t this_arg, uint32_t min_value_msat, int32_t invoice_expiry_delta_secs, int64_t user_payment_id) { LDKChannelManager this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; LDKCOption_u64Z min_value_msat_conv = *(LDKCOption_u64Z*)(((uint64_t)min_value_msat) & ~1); min_value_msat_conv = COption_u64Z_clone((LDKCOption_u64Z*)(((uint64_t)min_value_msat) & ~1)); LDKC2Tuple_PaymentHashPaymentSecretZ* ret_ref = MALLOC(sizeof(LDKC2Tuple_PaymentHashPaymentSecretZ), "LDKC2Tuple_PaymentHashPaymentSecretZ"); *ret_ref = ChannelManager_create_inbound_payment(&this_arg_conv, min_value_msat_conv, invoice_expiry_delta_secs, user_payment_id); return (uint64_t)ret_ref; } uint32_t __attribute__((visibility("default"))) TS_ChannelManager_create_inbound_payment_for_hash(uint32_t this_arg, int8_tArray payment_hash, uint32_t min_value_msat, int32_t invoice_expiry_delta_secs, int64_t user_payment_id) { LDKChannelManager this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; LDKThirtyTwoBytes payment_hash_ref; CHECK(*((uint32_t*)payment_hash) == 32); memcpy(payment_hash_ref.data, (uint8_t*)(payment_hash + 4), 32); LDKCOption_u64Z min_value_msat_conv = *(LDKCOption_u64Z*)(((uint64_t)min_value_msat) & ~1); min_value_msat_conv = COption_u64Z_clone((LDKCOption_u64Z*)(((uint64_t)min_value_msat) & ~1)); LDKCResult_PaymentSecretAPIErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_PaymentSecretAPIErrorZ), "LDKCResult_PaymentSecretAPIErrorZ"); *ret_conv = ChannelManager_create_inbound_payment_for_hash(&this_arg_conv, payment_hash_ref, min_value_msat_conv, invoice_expiry_delta_secs, user_payment_id); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_ChannelManager_as_MessageSendEventsProvider(uint32_t this_arg) { LDKChannelManager this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; LDKMessageSendEventsProvider* ret_ret =MALLOC(sizeof(LDKMessageSendEventsProvider), "LDKMessageSendEventsProvider"); *ret_ret = ChannelManager_as_MessageSendEventsProvider(&this_arg_conv); return (uint64_t)ret_ret; } uint32_t __attribute__((visibility("default"))) TS_ChannelManager_as_EventsProvider(uint32_t this_arg) { LDKChannelManager this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; LDKEventsProvider* ret_ret =MALLOC(sizeof(LDKEventsProvider), "LDKEventsProvider"); *ret_ret = ChannelManager_as_EventsProvider(&this_arg_conv); return (uint64_t)ret_ret; } uint32_t __attribute__((visibility("default"))) TS_ChannelManager_as_Listen(uint32_t this_arg) { LDKChannelManager this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; LDKListen* ret_ret =MALLOC(sizeof(LDKListen), "LDKListen"); *ret_ret = ChannelManager_as_Listen(&this_arg_conv); return (uint64_t)ret_ret; } uint32_t __attribute__((visibility("default"))) TS_ChannelManager_as_Confirm(uint32_t this_arg) { LDKChannelManager this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; LDKConfirm* ret_ret =MALLOC(sizeof(LDKConfirm), "LDKConfirm"); *ret_ret = ChannelManager_as_Confirm(&this_arg_conv); return (uint64_t)ret_ret; } jboolean __attribute__((visibility("default"))) TS_ChannelManager_await_persistable_update_timeout(uint32_t this_arg, int64_t max_wait) { LDKChannelManager this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; jboolean ret_val = ChannelManager_await_persistable_update_timeout(&this_arg_conv, max_wait); return ret_val; } void __attribute__((visibility("default"))) TS_ChannelManager_await_persistable_update(uint32_t this_arg) { LDKChannelManager this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; ChannelManager_await_persistable_update(&this_arg_conv); } uint32_t __attribute__((visibility("default"))) TS_ChannelManager_current_best_block(uint32_t this_arg) { LDKChannelManager this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; LDKBestBlock ret_var = ChannelManager_current_best_block(&this_arg_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_ChannelManager_as_ChannelMessageHandler(uint32_t this_arg) { LDKChannelManager this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; LDKChannelMessageHandler* ret_ret =MALLOC(sizeof(LDKChannelMessageHandler), "LDKChannelMessageHandler"); *ret_ret = ChannelManager_as_ChannelMessageHandler(&this_arg_conv); return (uint64_t)ret_ret; } int8_tArray __attribute__((visibility("default"))) TS_ChannelManager_write(uint32_t obj) { LDKChannelManager obj_conv; obj_conv.inner = (void*)(obj & (~1)); obj_conv.is_owned = false; LDKCVec_u8Z ret_var = ChannelManager_write(&obj_conv); int8_tArray ret_arr = init_arr(ret_var.datalen, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), ret_var.data, ret_var.datalen); CVec_u8Z_free(ret_var); return ret_arr; } void __attribute__((visibility("default"))) TS_ChannelManagerReadArgs_free(uint32_t this_obj) { LDKChannelManagerReadArgs this_obj_conv; this_obj_conv.inner = (void*)(this_obj & (~1)); this_obj_conv.is_owned = (this_obj & 1) || (this_obj == 0); ChannelManagerReadArgs_free(this_obj_conv); } uint32_t __attribute__((visibility("default"))) TS_ChannelManagerReadArgs_get_keys_manager(uint32_t this_ptr) { LDKChannelManagerReadArgs this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; uint64_t ret_ret = (uint64_t)ChannelManagerReadArgs_get_keys_manager(&this_ptr_conv); return ret_ret; } void __attribute__((visibility("default"))) TS_ChannelManagerReadArgs_set_keys_manager(uint32_t this_ptr, uint32_t val) { LDKChannelManagerReadArgs this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKKeysInterface val_conv = *(LDKKeysInterface*)(((uint64_t)val) & ~1); ChannelManagerReadArgs_set_keys_manager(&this_ptr_conv, val_conv); } uint32_t __attribute__((visibility("default"))) TS_ChannelManagerReadArgs_get_fee_estimator(uint32_t this_ptr) { LDKChannelManagerReadArgs this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; uint64_t ret_ret = (uint64_t)ChannelManagerReadArgs_get_fee_estimator(&this_ptr_conv); return ret_ret; } void __attribute__((visibility("default"))) TS_ChannelManagerReadArgs_set_fee_estimator(uint32_t this_ptr, uint32_t val) { LDKChannelManagerReadArgs this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKFeeEstimator val_conv = *(LDKFeeEstimator*)(((uint64_t)val) & ~1); ChannelManagerReadArgs_set_fee_estimator(&this_ptr_conv, val_conv); } uint32_t __attribute__((visibility("default"))) TS_ChannelManagerReadArgs_get_chain_monitor(uint32_t this_ptr) { LDKChannelManagerReadArgs this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; uint64_t ret_ret = (uint64_t)ChannelManagerReadArgs_get_chain_monitor(&this_ptr_conv); return ret_ret; } void __attribute__((visibility("default"))) TS_ChannelManagerReadArgs_set_chain_monitor(uint32_t this_ptr, uint32_t val) { LDKChannelManagerReadArgs this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKWatch val_conv = *(LDKWatch*)(((uint64_t)val) & ~1); ChannelManagerReadArgs_set_chain_monitor(&this_ptr_conv, val_conv); } uint32_t __attribute__((visibility("default"))) TS_ChannelManagerReadArgs_get_tx_broadcaster(uint32_t this_ptr) { LDKChannelManagerReadArgs this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; uint64_t ret_ret = (uint64_t)ChannelManagerReadArgs_get_tx_broadcaster(&this_ptr_conv); return ret_ret; } void __attribute__((visibility("default"))) TS_ChannelManagerReadArgs_set_tx_broadcaster(uint32_t this_ptr, uint32_t val) { LDKChannelManagerReadArgs this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKBroadcasterInterface val_conv = *(LDKBroadcasterInterface*)(((uint64_t)val) & ~1); ChannelManagerReadArgs_set_tx_broadcaster(&this_ptr_conv, val_conv); } uint32_t __attribute__((visibility("default"))) TS_ChannelManagerReadArgs_get_logger(uint32_t this_ptr) { LDKChannelManagerReadArgs this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; uint64_t ret_ret = (uint64_t)ChannelManagerReadArgs_get_logger(&this_ptr_conv); return ret_ret; } void __attribute__((visibility("default"))) TS_ChannelManagerReadArgs_set_logger(uint32_t this_ptr, uint32_t val) { LDKChannelManagerReadArgs this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKLogger val_conv = *(LDKLogger*)(((uint64_t)val) & ~1); ChannelManagerReadArgs_set_logger(&this_ptr_conv, val_conv); } uint32_t __attribute__((visibility("default"))) TS_ChannelManagerReadArgs_get_default_config(uint32_t this_ptr) { LDKChannelManagerReadArgs this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKUserConfig ret_var = ChannelManagerReadArgs_get_default_config(&this_ptr_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } void __attribute__((visibility("default"))) TS_ChannelManagerReadArgs_set_default_config(uint32_t this_ptr, uint32_t val) { LDKChannelManagerReadArgs this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKUserConfig val_conv; val_conv.inner = (void*)(val & (~1)); val_conv.is_owned = (val & 1) || (val == 0); val_conv = UserConfig_clone(&val_conv); ChannelManagerReadArgs_set_default_config(&this_ptr_conv, val_conv); } uint32_t __attribute__((visibility("default"))) TS_ChannelManagerReadArgs_new(uint32_t keys_manager, uint32_t fee_estimator, uint32_t chain_monitor, uint32_t tx_broadcaster, uint32_t logger, uint32_t default_config, uint32_tArray channel_monitors) { LDKKeysInterface keys_manager_conv = *(LDKKeysInterface*)(((uint64_t)keys_manager) & ~1); LDKFeeEstimator fee_estimator_conv = *(LDKFeeEstimator*)(((uint64_t)fee_estimator) & ~1); LDKWatch chain_monitor_conv = *(LDKWatch*)(((uint64_t)chain_monitor) & ~1); LDKBroadcasterInterface tx_broadcaster_conv = *(LDKBroadcasterInterface*)(((uint64_t)tx_broadcaster) & ~1); LDKLogger logger_conv = *(LDKLogger*)(((uint64_t)logger) & ~1); LDKUserConfig default_config_conv; default_config_conv.inner = (void*)(default_config & (~1)); default_config_conv.is_owned = (default_config & 1) || (default_config == 0); default_config_conv = UserConfig_clone(&default_config_conv); LDKCVec_ChannelMonitorZ channel_monitors_constr; channel_monitors_constr.datalen = *((uint32_t*)channel_monitors); if (channel_monitors_constr.datalen > 0) channel_monitors_constr.data = MALLOC(channel_monitors_constr.datalen * sizeof(LDKChannelMonitor), "LDKCVec_ChannelMonitorZ Elements"); else channel_monitors_constr.data = NULL; uint32_t* channel_monitors_vals = (uint32_t*)(channel_monitors + 4); for (size_t q = 0; q < channel_monitors_constr.datalen; q++) { uint32_t channel_monitors_conv_16 = channel_monitors_vals[q]; LDKChannelMonitor channel_monitors_conv_16_conv; channel_monitors_conv_16_conv.inner = (void*)(channel_monitors_conv_16 & (~1)); channel_monitors_conv_16_conv.is_owned = (channel_monitors_conv_16 & 1) || (channel_monitors_conv_16 == 0); channel_monitors_constr.data[q] = channel_monitors_conv_16_conv; } LDKChannelManagerReadArgs ret_var = ChannelManagerReadArgs_new(keys_manager_conv, fee_estimator_conv, chain_monitor_conv, tx_broadcaster_conv, logger_conv, default_config_conv, channel_monitors_constr); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_C2Tuple_BlockHashChannelManagerZ_read(int8_tArray ser, uint32_t arg) { LDKu8slice ser_ref; ser_ref.datalen = *((uint32_t*)ser); ser_ref.data = (int8_t*)(ser + 4); LDKChannelManagerReadArgs arg_conv; arg_conv.inner = (void*)(arg & (~1)); arg_conv.is_owned = (arg & 1) || (arg == 0); // Warning: we need a move here but no clone is available for LDKChannelManagerReadArgs LDKCResult_C2Tuple_BlockHashChannelManagerZDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_C2Tuple_BlockHashChannelManagerZDecodeErrorZ), "LDKCResult_C2Tuple_BlockHashChannelManagerZDecodeErrorZ"); *ret_conv = C2Tuple_BlockHashChannelManagerZ_read(ser_ref, arg_conv); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_DecodeError_free(uint32_t this_obj) { LDKDecodeError this_obj_conv; this_obj_conv.inner = (void*)(this_obj & (~1)); this_obj_conv.is_owned = (this_obj & 1) || (this_obj == 0); DecodeError_free(this_obj_conv); } uint32_t __attribute__((visibility("default"))) TS_DecodeError_clone(uint32_t orig) { LDKDecodeError orig_conv; orig_conv.inner = (void*)(orig & (~1)); orig_conv.is_owned = false; LDKDecodeError ret_var = DecodeError_clone(&orig_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } void __attribute__((visibility("default"))) TS_Init_free(uint32_t this_obj) { LDKInit this_obj_conv; this_obj_conv.inner = (void*)(this_obj & (~1)); this_obj_conv.is_owned = (this_obj & 1) || (this_obj == 0); Init_free(this_obj_conv); } uint32_t __attribute__((visibility("default"))) TS_Init_get_features(uint32_t this_ptr) { LDKInit this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKInitFeatures ret_var = Init_get_features(&this_ptr_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } void __attribute__((visibility("default"))) TS_Init_set_features(uint32_t this_ptr, uint32_t val) { LDKInit this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKInitFeatures val_conv; val_conv.inner = (void*)(val & (~1)); val_conv.is_owned = (val & 1) || (val == 0); val_conv = InitFeatures_clone(&val_conv); Init_set_features(&this_ptr_conv, val_conv); } uint32_t __attribute__((visibility("default"))) TS_Init_new(uint32_t features_arg) { LDKInitFeatures features_arg_conv; features_arg_conv.inner = (void*)(features_arg & (~1)); features_arg_conv.is_owned = (features_arg & 1) || (features_arg == 0); features_arg_conv = InitFeatures_clone(&features_arg_conv); LDKInit ret_var = Init_new(features_arg_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_Init_clone(uint32_t orig) { LDKInit orig_conv; orig_conv.inner = (void*)(orig & (~1)); orig_conv.is_owned = false; LDKInit ret_var = Init_clone(&orig_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } void __attribute__((visibility("default"))) TS_ErrorMessage_free(uint32_t this_obj) { LDKErrorMessage this_obj_conv; this_obj_conv.inner = (void*)(this_obj & (~1)); this_obj_conv.is_owned = (this_obj & 1) || (this_obj == 0); ErrorMessage_free(this_obj_conv); } int8_tArray __attribute__((visibility("default"))) TS_ErrorMessage_get_channel_id(uint32_t this_ptr) { LDKErrorMessage this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int8_tArray ret_arr = init_arr(32, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), *ErrorMessage_get_channel_id(&this_ptr_conv), 32); return ret_arr; } void __attribute__((visibility("default"))) TS_ErrorMessage_set_channel_id(uint32_t this_ptr, int8_tArray val) { LDKErrorMessage this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKThirtyTwoBytes val_ref; CHECK(*((uint32_t*)val) == 32); memcpy(val_ref.data, (uint8_t*)(val + 4), 32); ErrorMessage_set_channel_id(&this_ptr_conv, val_ref); } jstring __attribute__((visibility("default"))) TS_ErrorMessage_get_data(uint32_t this_ptr) { LDKErrorMessage this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKStr ret_str = ErrorMessage_get_data(&this_ptr_conv); jstring ret_conv = str_ref_to_ts(ret_str.chars, ret_str.len); Str_free(ret_str); return ret_conv; } void __attribute__((visibility("default"))) TS_ErrorMessage_set_data(uint32_t this_ptr, jstring val) { LDKErrorMessage this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKStr val_conv = str_ref_to_owned_c(val); ErrorMessage_set_data(&this_ptr_conv, val_conv); } uint32_t __attribute__((visibility("default"))) TS_ErrorMessage_new(int8_tArray channel_id_arg, jstring data_arg) { LDKThirtyTwoBytes channel_id_arg_ref; CHECK(*((uint32_t*)channel_id_arg) == 32); memcpy(channel_id_arg_ref.data, (uint8_t*)(channel_id_arg + 4), 32); LDKStr data_arg_conv = str_ref_to_owned_c(data_arg); LDKErrorMessage ret_var = ErrorMessage_new(channel_id_arg_ref, data_arg_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_ErrorMessage_clone(uint32_t orig) { LDKErrorMessage orig_conv; orig_conv.inner = (void*)(orig & (~1)); orig_conv.is_owned = false; LDKErrorMessage ret_var = ErrorMessage_clone(&orig_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } void __attribute__((visibility("default"))) TS_Ping_free(uint32_t this_obj) { LDKPing this_obj_conv; this_obj_conv.inner = (void*)(this_obj & (~1)); this_obj_conv.is_owned = (this_obj & 1) || (this_obj == 0); Ping_free(this_obj_conv); } int16_t __attribute__((visibility("default"))) TS_Ping_get_ponglen(uint32_t this_ptr) { LDKPing this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int16_t ret_val = Ping_get_ponglen(&this_ptr_conv); return ret_val; } void __attribute__((visibility("default"))) TS_Ping_set_ponglen(uint32_t this_ptr, int16_t val) { LDKPing this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; Ping_set_ponglen(&this_ptr_conv, val); } int16_t __attribute__((visibility("default"))) TS_Ping_get_byteslen(uint32_t this_ptr) { LDKPing this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int16_t ret_val = Ping_get_byteslen(&this_ptr_conv); return ret_val; } void __attribute__((visibility("default"))) TS_Ping_set_byteslen(uint32_t this_ptr, int16_t val) { LDKPing this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; Ping_set_byteslen(&this_ptr_conv, val); } uint32_t __attribute__((visibility("default"))) TS_Ping_new(int16_t ponglen_arg, int16_t byteslen_arg) { LDKPing ret_var = Ping_new(ponglen_arg, byteslen_arg); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_Ping_clone(uint32_t orig) { LDKPing orig_conv; orig_conv.inner = (void*)(orig & (~1)); orig_conv.is_owned = false; LDKPing ret_var = Ping_clone(&orig_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } void __attribute__((visibility("default"))) TS_Pong_free(uint32_t this_obj) { LDKPong this_obj_conv; this_obj_conv.inner = (void*)(this_obj & (~1)); this_obj_conv.is_owned = (this_obj & 1) || (this_obj == 0); Pong_free(this_obj_conv); } int16_t __attribute__((visibility("default"))) TS_Pong_get_byteslen(uint32_t this_ptr) { LDKPong this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int16_t ret_val = Pong_get_byteslen(&this_ptr_conv); return ret_val; } void __attribute__((visibility("default"))) TS_Pong_set_byteslen(uint32_t this_ptr, int16_t val) { LDKPong this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; Pong_set_byteslen(&this_ptr_conv, val); } uint32_t __attribute__((visibility("default"))) TS_Pong_new(int16_t byteslen_arg) { LDKPong ret_var = Pong_new(byteslen_arg); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_Pong_clone(uint32_t orig) { LDKPong orig_conv; orig_conv.inner = (void*)(orig & (~1)); orig_conv.is_owned = false; LDKPong ret_var = Pong_clone(&orig_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } void __attribute__((visibility("default"))) TS_OpenChannel_free(uint32_t this_obj) { LDKOpenChannel this_obj_conv; this_obj_conv.inner = (void*)(this_obj & (~1)); this_obj_conv.is_owned = (this_obj & 1) || (this_obj == 0); OpenChannel_free(this_obj_conv); } int8_tArray __attribute__((visibility("default"))) TS_OpenChannel_get_chain_hash(uint32_t this_ptr) { LDKOpenChannel this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int8_tArray ret_arr = init_arr(32, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), *OpenChannel_get_chain_hash(&this_ptr_conv), 32); return ret_arr; } void __attribute__((visibility("default"))) TS_OpenChannel_set_chain_hash(uint32_t this_ptr, int8_tArray val) { LDKOpenChannel this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKThirtyTwoBytes val_ref; CHECK(*((uint32_t*)val) == 32); memcpy(val_ref.data, (uint8_t*)(val + 4), 32); OpenChannel_set_chain_hash(&this_ptr_conv, val_ref); } int8_tArray __attribute__((visibility("default"))) TS_OpenChannel_get_temporary_channel_id(uint32_t this_ptr) { LDKOpenChannel this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int8_tArray ret_arr = init_arr(32, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), *OpenChannel_get_temporary_channel_id(&this_ptr_conv), 32); return ret_arr; } void __attribute__((visibility("default"))) TS_OpenChannel_set_temporary_channel_id(uint32_t this_ptr, int8_tArray val) { LDKOpenChannel this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKThirtyTwoBytes val_ref; CHECK(*((uint32_t*)val) == 32); memcpy(val_ref.data, (uint8_t*)(val + 4), 32); OpenChannel_set_temporary_channel_id(&this_ptr_conv, val_ref); } int64_t __attribute__((visibility("default"))) TS_OpenChannel_get_funding_satoshis(uint32_t this_ptr) { LDKOpenChannel this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int64_t ret_val = OpenChannel_get_funding_satoshis(&this_ptr_conv); return ret_val; } void __attribute__((visibility("default"))) TS_OpenChannel_set_funding_satoshis(uint32_t this_ptr, int64_t val) { LDKOpenChannel this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; OpenChannel_set_funding_satoshis(&this_ptr_conv, val); } int64_t __attribute__((visibility("default"))) TS_OpenChannel_get_push_msat(uint32_t this_ptr) { LDKOpenChannel this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int64_t ret_val = OpenChannel_get_push_msat(&this_ptr_conv); return ret_val; } void __attribute__((visibility("default"))) TS_OpenChannel_set_push_msat(uint32_t this_ptr, int64_t val) { LDKOpenChannel this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; OpenChannel_set_push_msat(&this_ptr_conv, val); } int64_t __attribute__((visibility("default"))) TS_OpenChannel_get_dust_limit_satoshis(uint32_t this_ptr) { LDKOpenChannel this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int64_t ret_val = OpenChannel_get_dust_limit_satoshis(&this_ptr_conv); return ret_val; } void __attribute__((visibility("default"))) TS_OpenChannel_set_dust_limit_satoshis(uint32_t this_ptr, int64_t val) { LDKOpenChannel this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; OpenChannel_set_dust_limit_satoshis(&this_ptr_conv, val); } int64_t __attribute__((visibility("default"))) TS_OpenChannel_get_max_htlc_value_in_flight_msat(uint32_t this_ptr) { LDKOpenChannel this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int64_t ret_val = OpenChannel_get_max_htlc_value_in_flight_msat(&this_ptr_conv); return ret_val; } void __attribute__((visibility("default"))) TS_OpenChannel_set_max_htlc_value_in_flight_msat(uint32_t this_ptr, int64_t val) { LDKOpenChannel this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; OpenChannel_set_max_htlc_value_in_flight_msat(&this_ptr_conv, val); } int64_t __attribute__((visibility("default"))) TS_OpenChannel_get_channel_reserve_satoshis(uint32_t this_ptr) { LDKOpenChannel this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int64_t ret_val = OpenChannel_get_channel_reserve_satoshis(&this_ptr_conv); return ret_val; } void __attribute__((visibility("default"))) TS_OpenChannel_set_channel_reserve_satoshis(uint32_t this_ptr, int64_t val) { LDKOpenChannel this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; OpenChannel_set_channel_reserve_satoshis(&this_ptr_conv, val); } int64_t __attribute__((visibility("default"))) TS_OpenChannel_get_htlc_minimum_msat(uint32_t this_ptr) { LDKOpenChannel this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int64_t ret_val = OpenChannel_get_htlc_minimum_msat(&this_ptr_conv); return ret_val; } void __attribute__((visibility("default"))) TS_OpenChannel_set_htlc_minimum_msat(uint32_t this_ptr, int64_t val) { LDKOpenChannel this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; OpenChannel_set_htlc_minimum_msat(&this_ptr_conv, val); } int32_t __attribute__((visibility("default"))) TS_OpenChannel_get_feerate_per_kw(uint32_t this_ptr) { LDKOpenChannel this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int32_t ret_val = OpenChannel_get_feerate_per_kw(&this_ptr_conv); return ret_val; } void __attribute__((visibility("default"))) TS_OpenChannel_set_feerate_per_kw(uint32_t this_ptr, int32_t val) { LDKOpenChannel this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; OpenChannel_set_feerate_per_kw(&this_ptr_conv, val); } int16_t __attribute__((visibility("default"))) TS_OpenChannel_get_to_self_delay(uint32_t this_ptr) { LDKOpenChannel this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int16_t ret_val = OpenChannel_get_to_self_delay(&this_ptr_conv); return ret_val; } void __attribute__((visibility("default"))) TS_OpenChannel_set_to_self_delay(uint32_t this_ptr, int16_t val) { LDKOpenChannel this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; OpenChannel_set_to_self_delay(&this_ptr_conv, val); } int16_t __attribute__((visibility("default"))) TS_OpenChannel_get_max_accepted_htlcs(uint32_t this_ptr) { LDKOpenChannel this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int16_t ret_val = OpenChannel_get_max_accepted_htlcs(&this_ptr_conv); return ret_val; } void __attribute__((visibility("default"))) TS_OpenChannel_set_max_accepted_htlcs(uint32_t this_ptr, int16_t val) { LDKOpenChannel this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; OpenChannel_set_max_accepted_htlcs(&this_ptr_conv, val); } int8_tArray __attribute__((visibility("default"))) TS_OpenChannel_get_funding_pubkey(uint32_t this_ptr) { LDKOpenChannel this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int8_tArray ret_arr = init_arr(33, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), OpenChannel_get_funding_pubkey(&this_ptr_conv).compressed_form, 33); return ret_arr; } void __attribute__((visibility("default"))) TS_OpenChannel_set_funding_pubkey(uint32_t this_ptr, int8_tArray val) { LDKOpenChannel this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKPublicKey val_ref; CHECK(*((uint32_t*)val) == 33); memcpy(val_ref.compressed_form, (uint8_t*)(val + 4), 33); OpenChannel_set_funding_pubkey(&this_ptr_conv, val_ref); } int8_tArray __attribute__((visibility("default"))) TS_OpenChannel_get_revocation_basepoint(uint32_t this_ptr) { LDKOpenChannel this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int8_tArray ret_arr = init_arr(33, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), OpenChannel_get_revocation_basepoint(&this_ptr_conv).compressed_form, 33); return ret_arr; } void __attribute__((visibility("default"))) TS_OpenChannel_set_revocation_basepoint(uint32_t this_ptr, int8_tArray val) { LDKOpenChannel this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKPublicKey val_ref; CHECK(*((uint32_t*)val) == 33); memcpy(val_ref.compressed_form, (uint8_t*)(val + 4), 33); OpenChannel_set_revocation_basepoint(&this_ptr_conv, val_ref); } int8_tArray __attribute__((visibility("default"))) TS_OpenChannel_get_payment_point(uint32_t this_ptr) { LDKOpenChannel this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int8_tArray ret_arr = init_arr(33, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), OpenChannel_get_payment_point(&this_ptr_conv).compressed_form, 33); return ret_arr; } void __attribute__((visibility("default"))) TS_OpenChannel_set_payment_point(uint32_t this_ptr, int8_tArray val) { LDKOpenChannel this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKPublicKey val_ref; CHECK(*((uint32_t*)val) == 33); memcpy(val_ref.compressed_form, (uint8_t*)(val + 4), 33); OpenChannel_set_payment_point(&this_ptr_conv, val_ref); } int8_tArray __attribute__((visibility("default"))) TS_OpenChannel_get_delayed_payment_basepoint(uint32_t this_ptr) { LDKOpenChannel this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int8_tArray ret_arr = init_arr(33, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), OpenChannel_get_delayed_payment_basepoint(&this_ptr_conv).compressed_form, 33); return ret_arr; } void __attribute__((visibility("default"))) TS_OpenChannel_set_delayed_payment_basepoint(uint32_t this_ptr, int8_tArray val) { LDKOpenChannel this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKPublicKey val_ref; CHECK(*((uint32_t*)val) == 33); memcpy(val_ref.compressed_form, (uint8_t*)(val + 4), 33); OpenChannel_set_delayed_payment_basepoint(&this_ptr_conv, val_ref); } int8_tArray __attribute__((visibility("default"))) TS_OpenChannel_get_htlc_basepoint(uint32_t this_ptr) { LDKOpenChannel this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int8_tArray ret_arr = init_arr(33, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), OpenChannel_get_htlc_basepoint(&this_ptr_conv).compressed_form, 33); return ret_arr; } void __attribute__((visibility("default"))) TS_OpenChannel_set_htlc_basepoint(uint32_t this_ptr, int8_tArray val) { LDKOpenChannel this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKPublicKey val_ref; CHECK(*((uint32_t*)val) == 33); memcpy(val_ref.compressed_form, (uint8_t*)(val + 4), 33); OpenChannel_set_htlc_basepoint(&this_ptr_conv, val_ref); } int8_tArray __attribute__((visibility("default"))) TS_OpenChannel_get_first_per_commitment_point(uint32_t this_ptr) { LDKOpenChannel this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int8_tArray ret_arr = init_arr(33, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), OpenChannel_get_first_per_commitment_point(&this_ptr_conv).compressed_form, 33); return ret_arr; } void __attribute__((visibility("default"))) TS_OpenChannel_set_first_per_commitment_point(uint32_t this_ptr, int8_tArray val) { LDKOpenChannel this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKPublicKey val_ref; CHECK(*((uint32_t*)val) == 33); memcpy(val_ref.compressed_form, (uint8_t*)(val + 4), 33); OpenChannel_set_first_per_commitment_point(&this_ptr_conv, val_ref); } int8_t __attribute__((visibility("default"))) TS_OpenChannel_get_channel_flags(uint32_t this_ptr) { LDKOpenChannel this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int8_t ret_val = OpenChannel_get_channel_flags(&this_ptr_conv); return ret_val; } void __attribute__((visibility("default"))) TS_OpenChannel_set_channel_flags(uint32_t this_ptr, int8_t val) { LDKOpenChannel this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; OpenChannel_set_channel_flags(&this_ptr_conv, val); } uint32_t __attribute__((visibility("default"))) TS_OpenChannel_clone(uint32_t orig) { LDKOpenChannel orig_conv; orig_conv.inner = (void*)(orig & (~1)); orig_conv.is_owned = false; LDKOpenChannel ret_var = OpenChannel_clone(&orig_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } void __attribute__((visibility("default"))) TS_AcceptChannel_free(uint32_t this_obj) { LDKAcceptChannel this_obj_conv; this_obj_conv.inner = (void*)(this_obj & (~1)); this_obj_conv.is_owned = (this_obj & 1) || (this_obj == 0); AcceptChannel_free(this_obj_conv); } int8_tArray __attribute__((visibility("default"))) TS_AcceptChannel_get_temporary_channel_id(uint32_t this_ptr) { LDKAcceptChannel this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int8_tArray ret_arr = init_arr(32, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), *AcceptChannel_get_temporary_channel_id(&this_ptr_conv), 32); return ret_arr; } void __attribute__((visibility("default"))) TS_AcceptChannel_set_temporary_channel_id(uint32_t this_ptr, int8_tArray val) { LDKAcceptChannel this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKThirtyTwoBytes val_ref; CHECK(*((uint32_t*)val) == 32); memcpy(val_ref.data, (uint8_t*)(val + 4), 32); AcceptChannel_set_temporary_channel_id(&this_ptr_conv, val_ref); } int64_t __attribute__((visibility("default"))) TS_AcceptChannel_get_dust_limit_satoshis(uint32_t this_ptr) { LDKAcceptChannel this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int64_t ret_val = AcceptChannel_get_dust_limit_satoshis(&this_ptr_conv); return ret_val; } void __attribute__((visibility("default"))) TS_AcceptChannel_set_dust_limit_satoshis(uint32_t this_ptr, int64_t val) { LDKAcceptChannel this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; AcceptChannel_set_dust_limit_satoshis(&this_ptr_conv, val); } int64_t __attribute__((visibility("default"))) TS_AcceptChannel_get_max_htlc_value_in_flight_msat(uint32_t this_ptr) { LDKAcceptChannel this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int64_t ret_val = AcceptChannel_get_max_htlc_value_in_flight_msat(&this_ptr_conv); return ret_val; } void __attribute__((visibility("default"))) TS_AcceptChannel_set_max_htlc_value_in_flight_msat(uint32_t this_ptr, int64_t val) { LDKAcceptChannel this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; AcceptChannel_set_max_htlc_value_in_flight_msat(&this_ptr_conv, val); } int64_t __attribute__((visibility("default"))) TS_AcceptChannel_get_channel_reserve_satoshis(uint32_t this_ptr) { LDKAcceptChannel this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int64_t ret_val = AcceptChannel_get_channel_reserve_satoshis(&this_ptr_conv); return ret_val; } void __attribute__((visibility("default"))) TS_AcceptChannel_set_channel_reserve_satoshis(uint32_t this_ptr, int64_t val) { LDKAcceptChannel this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; AcceptChannel_set_channel_reserve_satoshis(&this_ptr_conv, val); } int64_t __attribute__((visibility("default"))) TS_AcceptChannel_get_htlc_minimum_msat(uint32_t this_ptr) { LDKAcceptChannel this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int64_t ret_val = AcceptChannel_get_htlc_minimum_msat(&this_ptr_conv); return ret_val; } void __attribute__((visibility("default"))) TS_AcceptChannel_set_htlc_minimum_msat(uint32_t this_ptr, int64_t val) { LDKAcceptChannel this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; AcceptChannel_set_htlc_minimum_msat(&this_ptr_conv, val); } int32_t __attribute__((visibility("default"))) TS_AcceptChannel_get_minimum_depth(uint32_t this_ptr) { LDKAcceptChannel this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int32_t ret_val = AcceptChannel_get_minimum_depth(&this_ptr_conv); return ret_val; } void __attribute__((visibility("default"))) TS_AcceptChannel_set_minimum_depth(uint32_t this_ptr, int32_t val) { LDKAcceptChannel this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; AcceptChannel_set_minimum_depth(&this_ptr_conv, val); } int16_t __attribute__((visibility("default"))) TS_AcceptChannel_get_to_self_delay(uint32_t this_ptr) { LDKAcceptChannel this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int16_t ret_val = AcceptChannel_get_to_self_delay(&this_ptr_conv); return ret_val; } void __attribute__((visibility("default"))) TS_AcceptChannel_set_to_self_delay(uint32_t this_ptr, int16_t val) { LDKAcceptChannel this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; AcceptChannel_set_to_self_delay(&this_ptr_conv, val); } int16_t __attribute__((visibility("default"))) TS_AcceptChannel_get_max_accepted_htlcs(uint32_t this_ptr) { LDKAcceptChannel this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int16_t ret_val = AcceptChannel_get_max_accepted_htlcs(&this_ptr_conv); return ret_val; } void __attribute__((visibility("default"))) TS_AcceptChannel_set_max_accepted_htlcs(uint32_t this_ptr, int16_t val) { LDKAcceptChannel this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; AcceptChannel_set_max_accepted_htlcs(&this_ptr_conv, val); } int8_tArray __attribute__((visibility("default"))) TS_AcceptChannel_get_funding_pubkey(uint32_t this_ptr) { LDKAcceptChannel this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int8_tArray ret_arr = init_arr(33, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), AcceptChannel_get_funding_pubkey(&this_ptr_conv).compressed_form, 33); return ret_arr; } void __attribute__((visibility("default"))) TS_AcceptChannel_set_funding_pubkey(uint32_t this_ptr, int8_tArray val) { LDKAcceptChannel this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKPublicKey val_ref; CHECK(*((uint32_t*)val) == 33); memcpy(val_ref.compressed_form, (uint8_t*)(val + 4), 33); AcceptChannel_set_funding_pubkey(&this_ptr_conv, val_ref); } int8_tArray __attribute__((visibility("default"))) TS_AcceptChannel_get_revocation_basepoint(uint32_t this_ptr) { LDKAcceptChannel this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int8_tArray ret_arr = init_arr(33, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), AcceptChannel_get_revocation_basepoint(&this_ptr_conv).compressed_form, 33); return ret_arr; } void __attribute__((visibility("default"))) TS_AcceptChannel_set_revocation_basepoint(uint32_t this_ptr, int8_tArray val) { LDKAcceptChannel this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKPublicKey val_ref; CHECK(*((uint32_t*)val) == 33); memcpy(val_ref.compressed_form, (uint8_t*)(val + 4), 33); AcceptChannel_set_revocation_basepoint(&this_ptr_conv, val_ref); } int8_tArray __attribute__((visibility("default"))) TS_AcceptChannel_get_payment_point(uint32_t this_ptr) { LDKAcceptChannel this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int8_tArray ret_arr = init_arr(33, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), AcceptChannel_get_payment_point(&this_ptr_conv).compressed_form, 33); return ret_arr; } void __attribute__((visibility("default"))) TS_AcceptChannel_set_payment_point(uint32_t this_ptr, int8_tArray val) { LDKAcceptChannel this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKPublicKey val_ref; CHECK(*((uint32_t*)val) == 33); memcpy(val_ref.compressed_form, (uint8_t*)(val + 4), 33); AcceptChannel_set_payment_point(&this_ptr_conv, val_ref); } int8_tArray __attribute__((visibility("default"))) TS_AcceptChannel_get_delayed_payment_basepoint(uint32_t this_ptr) { LDKAcceptChannel this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int8_tArray ret_arr = init_arr(33, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), AcceptChannel_get_delayed_payment_basepoint(&this_ptr_conv).compressed_form, 33); return ret_arr; } void __attribute__((visibility("default"))) TS_AcceptChannel_set_delayed_payment_basepoint(uint32_t this_ptr, int8_tArray val) { LDKAcceptChannel this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKPublicKey val_ref; CHECK(*((uint32_t*)val) == 33); memcpy(val_ref.compressed_form, (uint8_t*)(val + 4), 33); AcceptChannel_set_delayed_payment_basepoint(&this_ptr_conv, val_ref); } int8_tArray __attribute__((visibility("default"))) TS_AcceptChannel_get_htlc_basepoint(uint32_t this_ptr) { LDKAcceptChannel this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int8_tArray ret_arr = init_arr(33, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), AcceptChannel_get_htlc_basepoint(&this_ptr_conv).compressed_form, 33); return ret_arr; } void __attribute__((visibility("default"))) TS_AcceptChannel_set_htlc_basepoint(uint32_t this_ptr, int8_tArray val) { LDKAcceptChannel this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKPublicKey val_ref; CHECK(*((uint32_t*)val) == 33); memcpy(val_ref.compressed_form, (uint8_t*)(val + 4), 33); AcceptChannel_set_htlc_basepoint(&this_ptr_conv, val_ref); } int8_tArray __attribute__((visibility("default"))) TS_AcceptChannel_get_first_per_commitment_point(uint32_t this_ptr) { LDKAcceptChannel this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int8_tArray ret_arr = init_arr(33, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), AcceptChannel_get_first_per_commitment_point(&this_ptr_conv).compressed_form, 33); return ret_arr; } void __attribute__((visibility("default"))) TS_AcceptChannel_set_first_per_commitment_point(uint32_t this_ptr, int8_tArray val) { LDKAcceptChannel this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKPublicKey val_ref; CHECK(*((uint32_t*)val) == 33); memcpy(val_ref.compressed_form, (uint8_t*)(val + 4), 33); AcceptChannel_set_first_per_commitment_point(&this_ptr_conv, val_ref); } uint32_t __attribute__((visibility("default"))) TS_AcceptChannel_clone(uint32_t orig) { LDKAcceptChannel orig_conv; orig_conv.inner = (void*)(orig & (~1)); orig_conv.is_owned = false; LDKAcceptChannel ret_var = AcceptChannel_clone(&orig_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } void __attribute__((visibility("default"))) TS_FundingCreated_free(uint32_t this_obj) { LDKFundingCreated this_obj_conv; this_obj_conv.inner = (void*)(this_obj & (~1)); this_obj_conv.is_owned = (this_obj & 1) || (this_obj == 0); FundingCreated_free(this_obj_conv); } int8_tArray __attribute__((visibility("default"))) TS_FundingCreated_get_temporary_channel_id(uint32_t this_ptr) { LDKFundingCreated this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int8_tArray ret_arr = init_arr(32, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), *FundingCreated_get_temporary_channel_id(&this_ptr_conv), 32); return ret_arr; } void __attribute__((visibility("default"))) TS_FundingCreated_set_temporary_channel_id(uint32_t this_ptr, int8_tArray val) { LDKFundingCreated this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKThirtyTwoBytes val_ref; CHECK(*((uint32_t*)val) == 32); memcpy(val_ref.data, (uint8_t*)(val + 4), 32); FundingCreated_set_temporary_channel_id(&this_ptr_conv, val_ref); } int8_tArray __attribute__((visibility("default"))) TS_FundingCreated_get_funding_txid(uint32_t this_ptr) { LDKFundingCreated this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int8_tArray ret_arr = init_arr(32, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), *FundingCreated_get_funding_txid(&this_ptr_conv), 32); return ret_arr; } void __attribute__((visibility("default"))) TS_FundingCreated_set_funding_txid(uint32_t this_ptr, int8_tArray val) { LDKFundingCreated this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKThirtyTwoBytes val_ref; CHECK(*((uint32_t*)val) == 32); memcpy(val_ref.data, (uint8_t*)(val + 4), 32); FundingCreated_set_funding_txid(&this_ptr_conv, val_ref); } int16_t __attribute__((visibility("default"))) TS_FundingCreated_get_funding_output_index(uint32_t this_ptr) { LDKFundingCreated this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int16_t ret_val = FundingCreated_get_funding_output_index(&this_ptr_conv); return ret_val; } void __attribute__((visibility("default"))) TS_FundingCreated_set_funding_output_index(uint32_t this_ptr, int16_t val) { LDKFundingCreated this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; FundingCreated_set_funding_output_index(&this_ptr_conv, val); } int8_tArray __attribute__((visibility("default"))) TS_FundingCreated_get_signature(uint32_t this_ptr) { LDKFundingCreated this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int8_tArray ret_arr = init_arr(64, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), FundingCreated_get_signature(&this_ptr_conv).compact_form, 64); return ret_arr; } void __attribute__((visibility("default"))) TS_FundingCreated_set_signature(uint32_t this_ptr, int8_tArray val) { LDKFundingCreated this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKSignature val_ref; CHECK(*((uint32_t*)val) == 64); memcpy(val_ref.compact_form, (uint8_t*)(val + 4), 64); FundingCreated_set_signature(&this_ptr_conv, val_ref); } uint32_t __attribute__((visibility("default"))) TS_FundingCreated_new(int8_tArray temporary_channel_id_arg, int8_tArray funding_txid_arg, int16_t funding_output_index_arg, int8_tArray signature_arg) { LDKThirtyTwoBytes temporary_channel_id_arg_ref; CHECK(*((uint32_t*)temporary_channel_id_arg) == 32); memcpy(temporary_channel_id_arg_ref.data, (uint8_t*)(temporary_channel_id_arg + 4), 32); LDKThirtyTwoBytes funding_txid_arg_ref; CHECK(*((uint32_t*)funding_txid_arg) == 32); memcpy(funding_txid_arg_ref.data, (uint8_t*)(funding_txid_arg + 4), 32); LDKSignature signature_arg_ref; CHECK(*((uint32_t*)signature_arg) == 64); memcpy(signature_arg_ref.compact_form, (uint8_t*)(signature_arg + 4), 64); LDKFundingCreated ret_var = FundingCreated_new(temporary_channel_id_arg_ref, funding_txid_arg_ref, funding_output_index_arg, signature_arg_ref); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_FundingCreated_clone(uint32_t orig) { LDKFundingCreated orig_conv; orig_conv.inner = (void*)(orig & (~1)); orig_conv.is_owned = false; LDKFundingCreated ret_var = FundingCreated_clone(&orig_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } void __attribute__((visibility("default"))) TS_FundingSigned_free(uint32_t this_obj) { LDKFundingSigned this_obj_conv; this_obj_conv.inner = (void*)(this_obj & (~1)); this_obj_conv.is_owned = (this_obj & 1) || (this_obj == 0); FundingSigned_free(this_obj_conv); } int8_tArray __attribute__((visibility("default"))) TS_FundingSigned_get_channel_id(uint32_t this_ptr) { LDKFundingSigned this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int8_tArray ret_arr = init_arr(32, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), *FundingSigned_get_channel_id(&this_ptr_conv), 32); return ret_arr; } void __attribute__((visibility("default"))) TS_FundingSigned_set_channel_id(uint32_t this_ptr, int8_tArray val) { LDKFundingSigned this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKThirtyTwoBytes val_ref; CHECK(*((uint32_t*)val) == 32); memcpy(val_ref.data, (uint8_t*)(val + 4), 32); FundingSigned_set_channel_id(&this_ptr_conv, val_ref); } int8_tArray __attribute__((visibility("default"))) TS_FundingSigned_get_signature(uint32_t this_ptr) { LDKFundingSigned this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int8_tArray ret_arr = init_arr(64, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), FundingSigned_get_signature(&this_ptr_conv).compact_form, 64); return ret_arr; } void __attribute__((visibility("default"))) TS_FundingSigned_set_signature(uint32_t this_ptr, int8_tArray val) { LDKFundingSigned this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKSignature val_ref; CHECK(*((uint32_t*)val) == 64); memcpy(val_ref.compact_form, (uint8_t*)(val + 4), 64); FundingSigned_set_signature(&this_ptr_conv, val_ref); } uint32_t __attribute__((visibility("default"))) TS_FundingSigned_new(int8_tArray channel_id_arg, int8_tArray signature_arg) { LDKThirtyTwoBytes channel_id_arg_ref; CHECK(*((uint32_t*)channel_id_arg) == 32); memcpy(channel_id_arg_ref.data, (uint8_t*)(channel_id_arg + 4), 32); LDKSignature signature_arg_ref; CHECK(*((uint32_t*)signature_arg) == 64); memcpy(signature_arg_ref.compact_form, (uint8_t*)(signature_arg + 4), 64); LDKFundingSigned ret_var = FundingSigned_new(channel_id_arg_ref, signature_arg_ref); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_FundingSigned_clone(uint32_t orig) { LDKFundingSigned orig_conv; orig_conv.inner = (void*)(orig & (~1)); orig_conv.is_owned = false; LDKFundingSigned ret_var = FundingSigned_clone(&orig_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } void __attribute__((visibility("default"))) TS_FundingLocked_free(uint32_t this_obj) { LDKFundingLocked this_obj_conv; this_obj_conv.inner = (void*)(this_obj & (~1)); this_obj_conv.is_owned = (this_obj & 1) || (this_obj == 0); FundingLocked_free(this_obj_conv); } int8_tArray __attribute__((visibility("default"))) TS_FundingLocked_get_channel_id(uint32_t this_ptr) { LDKFundingLocked this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int8_tArray ret_arr = init_arr(32, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), *FundingLocked_get_channel_id(&this_ptr_conv), 32); return ret_arr; } void __attribute__((visibility("default"))) TS_FundingLocked_set_channel_id(uint32_t this_ptr, int8_tArray val) { LDKFundingLocked this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKThirtyTwoBytes val_ref; CHECK(*((uint32_t*)val) == 32); memcpy(val_ref.data, (uint8_t*)(val + 4), 32); FundingLocked_set_channel_id(&this_ptr_conv, val_ref); } int8_tArray __attribute__((visibility("default"))) TS_FundingLocked_get_next_per_commitment_point(uint32_t this_ptr) { LDKFundingLocked this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int8_tArray ret_arr = init_arr(33, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), FundingLocked_get_next_per_commitment_point(&this_ptr_conv).compressed_form, 33); return ret_arr; } void __attribute__((visibility("default"))) TS_FundingLocked_set_next_per_commitment_point(uint32_t this_ptr, int8_tArray val) { LDKFundingLocked this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKPublicKey val_ref; CHECK(*((uint32_t*)val) == 33); memcpy(val_ref.compressed_form, (uint8_t*)(val + 4), 33); FundingLocked_set_next_per_commitment_point(&this_ptr_conv, val_ref); } uint32_t __attribute__((visibility("default"))) TS_FundingLocked_new(int8_tArray channel_id_arg, int8_tArray next_per_commitment_point_arg) { LDKThirtyTwoBytes channel_id_arg_ref; CHECK(*((uint32_t*)channel_id_arg) == 32); memcpy(channel_id_arg_ref.data, (uint8_t*)(channel_id_arg + 4), 32); LDKPublicKey next_per_commitment_point_arg_ref; CHECK(*((uint32_t*)next_per_commitment_point_arg) == 33); memcpy(next_per_commitment_point_arg_ref.compressed_form, (uint8_t*)(next_per_commitment_point_arg + 4), 33); LDKFundingLocked ret_var = FundingLocked_new(channel_id_arg_ref, next_per_commitment_point_arg_ref); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_FundingLocked_clone(uint32_t orig) { LDKFundingLocked orig_conv; orig_conv.inner = (void*)(orig & (~1)); orig_conv.is_owned = false; LDKFundingLocked ret_var = FundingLocked_clone(&orig_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } void __attribute__((visibility("default"))) TS_Shutdown_free(uint32_t this_obj) { LDKShutdown this_obj_conv; this_obj_conv.inner = (void*)(this_obj & (~1)); this_obj_conv.is_owned = (this_obj & 1) || (this_obj == 0); Shutdown_free(this_obj_conv); } int8_tArray __attribute__((visibility("default"))) TS_Shutdown_get_channel_id(uint32_t this_ptr) { LDKShutdown this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int8_tArray ret_arr = init_arr(32, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), *Shutdown_get_channel_id(&this_ptr_conv), 32); return ret_arr; } void __attribute__((visibility("default"))) TS_Shutdown_set_channel_id(uint32_t this_ptr, int8_tArray val) { LDKShutdown this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKThirtyTwoBytes val_ref; CHECK(*((uint32_t*)val) == 32); memcpy(val_ref.data, (uint8_t*)(val + 4), 32); Shutdown_set_channel_id(&this_ptr_conv, val_ref); } int8_tArray __attribute__((visibility("default"))) TS_Shutdown_get_scriptpubkey(uint32_t this_ptr) { LDKShutdown this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKu8slice ret_var = Shutdown_get_scriptpubkey(&this_ptr_conv); int8_tArray ret_arr = init_arr(ret_var.datalen, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), ret_var.data, ret_var.datalen); return ret_arr; } void __attribute__((visibility("default"))) TS_Shutdown_set_scriptpubkey(uint32_t this_ptr, int8_tArray val) { LDKShutdown this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKCVec_u8Z val_ref; val_ref.datalen = *((uint32_t*)val); val_ref.data = MALLOC(val_ref.datalen, "LDKCVec_u8Z Bytes"); memcpy(val_ref.data, (uint8_t*)(val + 4), val_ref.datalen); Shutdown_set_scriptpubkey(&this_ptr_conv, val_ref); } uint32_t __attribute__((visibility("default"))) TS_Shutdown_new(int8_tArray channel_id_arg, int8_tArray scriptpubkey_arg) { LDKThirtyTwoBytes channel_id_arg_ref; CHECK(*((uint32_t*)channel_id_arg) == 32); memcpy(channel_id_arg_ref.data, (uint8_t*)(channel_id_arg + 4), 32); LDKCVec_u8Z scriptpubkey_arg_ref; scriptpubkey_arg_ref.datalen = *((uint32_t*)scriptpubkey_arg); scriptpubkey_arg_ref.data = MALLOC(scriptpubkey_arg_ref.datalen, "LDKCVec_u8Z Bytes"); memcpy(scriptpubkey_arg_ref.data, (uint8_t*)(scriptpubkey_arg + 4), scriptpubkey_arg_ref.datalen); LDKShutdown ret_var = Shutdown_new(channel_id_arg_ref, scriptpubkey_arg_ref); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_Shutdown_clone(uint32_t orig) { LDKShutdown orig_conv; orig_conv.inner = (void*)(orig & (~1)); orig_conv.is_owned = false; LDKShutdown ret_var = Shutdown_clone(&orig_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } void __attribute__((visibility("default"))) TS_ClosingSignedFeeRange_free(uint32_t this_obj) { LDKClosingSignedFeeRange this_obj_conv; this_obj_conv.inner = (void*)(this_obj & (~1)); this_obj_conv.is_owned = (this_obj & 1) || (this_obj == 0); ClosingSignedFeeRange_free(this_obj_conv); } int64_t __attribute__((visibility("default"))) TS_ClosingSignedFeeRange_get_min_fee_satoshis(uint32_t this_ptr) { LDKClosingSignedFeeRange this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int64_t ret_val = ClosingSignedFeeRange_get_min_fee_satoshis(&this_ptr_conv); return ret_val; } void __attribute__((visibility("default"))) TS_ClosingSignedFeeRange_set_min_fee_satoshis(uint32_t this_ptr, int64_t val) { LDKClosingSignedFeeRange this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; ClosingSignedFeeRange_set_min_fee_satoshis(&this_ptr_conv, val); } int64_t __attribute__((visibility("default"))) TS_ClosingSignedFeeRange_get_max_fee_satoshis(uint32_t this_ptr) { LDKClosingSignedFeeRange this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int64_t ret_val = ClosingSignedFeeRange_get_max_fee_satoshis(&this_ptr_conv); return ret_val; } void __attribute__((visibility("default"))) TS_ClosingSignedFeeRange_set_max_fee_satoshis(uint32_t this_ptr, int64_t val) { LDKClosingSignedFeeRange this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; ClosingSignedFeeRange_set_max_fee_satoshis(&this_ptr_conv, val); } uint32_t __attribute__((visibility("default"))) TS_ClosingSignedFeeRange_new(int64_t min_fee_satoshis_arg, int64_t max_fee_satoshis_arg) { LDKClosingSignedFeeRange ret_var = ClosingSignedFeeRange_new(min_fee_satoshis_arg, max_fee_satoshis_arg); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_ClosingSignedFeeRange_clone(uint32_t orig) { LDKClosingSignedFeeRange orig_conv; orig_conv.inner = (void*)(orig & (~1)); orig_conv.is_owned = false; LDKClosingSignedFeeRange ret_var = ClosingSignedFeeRange_clone(&orig_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } void __attribute__((visibility("default"))) TS_ClosingSigned_free(uint32_t this_obj) { LDKClosingSigned this_obj_conv; this_obj_conv.inner = (void*)(this_obj & (~1)); this_obj_conv.is_owned = (this_obj & 1) || (this_obj == 0); ClosingSigned_free(this_obj_conv); } int8_tArray __attribute__((visibility("default"))) TS_ClosingSigned_get_channel_id(uint32_t this_ptr) { LDKClosingSigned this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int8_tArray ret_arr = init_arr(32, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), *ClosingSigned_get_channel_id(&this_ptr_conv), 32); return ret_arr; } void __attribute__((visibility("default"))) TS_ClosingSigned_set_channel_id(uint32_t this_ptr, int8_tArray val) { LDKClosingSigned this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKThirtyTwoBytes val_ref; CHECK(*((uint32_t*)val) == 32); memcpy(val_ref.data, (uint8_t*)(val + 4), 32); ClosingSigned_set_channel_id(&this_ptr_conv, val_ref); } int64_t __attribute__((visibility("default"))) TS_ClosingSigned_get_fee_satoshis(uint32_t this_ptr) { LDKClosingSigned this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int64_t ret_val = ClosingSigned_get_fee_satoshis(&this_ptr_conv); return ret_val; } void __attribute__((visibility("default"))) TS_ClosingSigned_set_fee_satoshis(uint32_t this_ptr, int64_t val) { LDKClosingSigned this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; ClosingSigned_set_fee_satoshis(&this_ptr_conv, val); } int8_tArray __attribute__((visibility("default"))) TS_ClosingSigned_get_signature(uint32_t this_ptr) { LDKClosingSigned this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int8_tArray ret_arr = init_arr(64, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), ClosingSigned_get_signature(&this_ptr_conv).compact_form, 64); return ret_arr; } void __attribute__((visibility("default"))) TS_ClosingSigned_set_signature(uint32_t this_ptr, int8_tArray val) { LDKClosingSigned this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKSignature val_ref; CHECK(*((uint32_t*)val) == 64); memcpy(val_ref.compact_form, (uint8_t*)(val + 4), 64); ClosingSigned_set_signature(&this_ptr_conv, val_ref); } uint32_t __attribute__((visibility("default"))) TS_ClosingSigned_get_fee_range(uint32_t this_ptr) { LDKClosingSigned this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKClosingSignedFeeRange ret_var = ClosingSigned_get_fee_range(&this_ptr_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } void __attribute__((visibility("default"))) TS_ClosingSigned_set_fee_range(uint32_t this_ptr, uint32_t val) { LDKClosingSigned this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKClosingSignedFeeRange val_conv; val_conv.inner = (void*)(val & (~1)); val_conv.is_owned = (val & 1) || (val == 0); val_conv = ClosingSignedFeeRange_clone(&val_conv); ClosingSigned_set_fee_range(&this_ptr_conv, val_conv); } uint32_t __attribute__((visibility("default"))) TS_ClosingSigned_new(int8_tArray channel_id_arg, int64_t fee_satoshis_arg, int8_tArray signature_arg, uint32_t fee_range_arg) { LDKThirtyTwoBytes channel_id_arg_ref; CHECK(*((uint32_t*)channel_id_arg) == 32); memcpy(channel_id_arg_ref.data, (uint8_t*)(channel_id_arg + 4), 32); LDKSignature signature_arg_ref; CHECK(*((uint32_t*)signature_arg) == 64); memcpy(signature_arg_ref.compact_form, (uint8_t*)(signature_arg + 4), 64); LDKClosingSignedFeeRange fee_range_arg_conv; fee_range_arg_conv.inner = (void*)(fee_range_arg & (~1)); fee_range_arg_conv.is_owned = (fee_range_arg & 1) || (fee_range_arg == 0); fee_range_arg_conv = ClosingSignedFeeRange_clone(&fee_range_arg_conv); LDKClosingSigned ret_var = ClosingSigned_new(channel_id_arg_ref, fee_satoshis_arg, signature_arg_ref, fee_range_arg_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_ClosingSigned_clone(uint32_t orig) { LDKClosingSigned orig_conv; orig_conv.inner = (void*)(orig & (~1)); orig_conv.is_owned = false; LDKClosingSigned ret_var = ClosingSigned_clone(&orig_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } void __attribute__((visibility("default"))) TS_UpdateAddHTLC_free(uint32_t this_obj) { LDKUpdateAddHTLC this_obj_conv; this_obj_conv.inner = (void*)(this_obj & (~1)); this_obj_conv.is_owned = (this_obj & 1) || (this_obj == 0); UpdateAddHTLC_free(this_obj_conv); } int8_tArray __attribute__((visibility("default"))) TS_UpdateAddHTLC_get_channel_id(uint32_t this_ptr) { LDKUpdateAddHTLC this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int8_tArray ret_arr = init_arr(32, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), *UpdateAddHTLC_get_channel_id(&this_ptr_conv), 32); return ret_arr; } void __attribute__((visibility("default"))) TS_UpdateAddHTLC_set_channel_id(uint32_t this_ptr, int8_tArray val) { LDKUpdateAddHTLC this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKThirtyTwoBytes val_ref; CHECK(*((uint32_t*)val) == 32); memcpy(val_ref.data, (uint8_t*)(val + 4), 32); UpdateAddHTLC_set_channel_id(&this_ptr_conv, val_ref); } int64_t __attribute__((visibility("default"))) TS_UpdateAddHTLC_get_htlc_id(uint32_t this_ptr) { LDKUpdateAddHTLC this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int64_t ret_val = UpdateAddHTLC_get_htlc_id(&this_ptr_conv); return ret_val; } void __attribute__((visibility("default"))) TS_UpdateAddHTLC_set_htlc_id(uint32_t this_ptr, int64_t val) { LDKUpdateAddHTLC this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; UpdateAddHTLC_set_htlc_id(&this_ptr_conv, val); } int64_t __attribute__((visibility("default"))) TS_UpdateAddHTLC_get_amount_msat(uint32_t this_ptr) { LDKUpdateAddHTLC this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int64_t ret_val = UpdateAddHTLC_get_amount_msat(&this_ptr_conv); return ret_val; } void __attribute__((visibility("default"))) TS_UpdateAddHTLC_set_amount_msat(uint32_t this_ptr, int64_t val) { LDKUpdateAddHTLC this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; UpdateAddHTLC_set_amount_msat(&this_ptr_conv, val); } int8_tArray __attribute__((visibility("default"))) TS_UpdateAddHTLC_get_payment_hash(uint32_t this_ptr) { LDKUpdateAddHTLC this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int8_tArray ret_arr = init_arr(32, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), *UpdateAddHTLC_get_payment_hash(&this_ptr_conv), 32); return ret_arr; } void __attribute__((visibility("default"))) TS_UpdateAddHTLC_set_payment_hash(uint32_t this_ptr, int8_tArray val) { LDKUpdateAddHTLC this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKThirtyTwoBytes val_ref; CHECK(*((uint32_t*)val) == 32); memcpy(val_ref.data, (uint8_t*)(val + 4), 32); UpdateAddHTLC_set_payment_hash(&this_ptr_conv, val_ref); } int32_t __attribute__((visibility("default"))) TS_UpdateAddHTLC_get_cltv_expiry(uint32_t this_ptr) { LDKUpdateAddHTLC this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int32_t ret_val = UpdateAddHTLC_get_cltv_expiry(&this_ptr_conv); return ret_val; } void __attribute__((visibility("default"))) TS_UpdateAddHTLC_set_cltv_expiry(uint32_t this_ptr, int32_t val) { LDKUpdateAddHTLC this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; UpdateAddHTLC_set_cltv_expiry(&this_ptr_conv, val); } uint32_t __attribute__((visibility("default"))) TS_UpdateAddHTLC_clone(uint32_t orig) { LDKUpdateAddHTLC orig_conv; orig_conv.inner = (void*)(orig & (~1)); orig_conv.is_owned = false; LDKUpdateAddHTLC ret_var = UpdateAddHTLC_clone(&orig_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } void __attribute__((visibility("default"))) TS_UpdateFulfillHTLC_free(uint32_t this_obj) { LDKUpdateFulfillHTLC this_obj_conv; this_obj_conv.inner = (void*)(this_obj & (~1)); this_obj_conv.is_owned = (this_obj & 1) || (this_obj == 0); UpdateFulfillHTLC_free(this_obj_conv); } int8_tArray __attribute__((visibility("default"))) TS_UpdateFulfillHTLC_get_channel_id(uint32_t this_ptr) { LDKUpdateFulfillHTLC this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int8_tArray ret_arr = init_arr(32, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), *UpdateFulfillHTLC_get_channel_id(&this_ptr_conv), 32); return ret_arr; } void __attribute__((visibility("default"))) TS_UpdateFulfillHTLC_set_channel_id(uint32_t this_ptr, int8_tArray val) { LDKUpdateFulfillHTLC this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKThirtyTwoBytes val_ref; CHECK(*((uint32_t*)val) == 32); memcpy(val_ref.data, (uint8_t*)(val + 4), 32); UpdateFulfillHTLC_set_channel_id(&this_ptr_conv, val_ref); } int64_t __attribute__((visibility("default"))) TS_UpdateFulfillHTLC_get_htlc_id(uint32_t this_ptr) { LDKUpdateFulfillHTLC this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int64_t ret_val = UpdateFulfillHTLC_get_htlc_id(&this_ptr_conv); return ret_val; } void __attribute__((visibility("default"))) TS_UpdateFulfillHTLC_set_htlc_id(uint32_t this_ptr, int64_t val) { LDKUpdateFulfillHTLC this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; UpdateFulfillHTLC_set_htlc_id(&this_ptr_conv, val); } int8_tArray __attribute__((visibility("default"))) TS_UpdateFulfillHTLC_get_payment_preimage(uint32_t this_ptr) { LDKUpdateFulfillHTLC this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int8_tArray ret_arr = init_arr(32, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), *UpdateFulfillHTLC_get_payment_preimage(&this_ptr_conv), 32); return ret_arr; } void __attribute__((visibility("default"))) TS_UpdateFulfillHTLC_set_payment_preimage(uint32_t this_ptr, int8_tArray val) { LDKUpdateFulfillHTLC this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKThirtyTwoBytes val_ref; CHECK(*((uint32_t*)val) == 32); memcpy(val_ref.data, (uint8_t*)(val + 4), 32); UpdateFulfillHTLC_set_payment_preimage(&this_ptr_conv, val_ref); } uint32_t __attribute__((visibility("default"))) TS_UpdateFulfillHTLC_new(int8_tArray channel_id_arg, int64_t htlc_id_arg, int8_tArray payment_preimage_arg) { LDKThirtyTwoBytes channel_id_arg_ref; CHECK(*((uint32_t*)channel_id_arg) == 32); memcpy(channel_id_arg_ref.data, (uint8_t*)(channel_id_arg + 4), 32); LDKThirtyTwoBytes payment_preimage_arg_ref; CHECK(*((uint32_t*)payment_preimage_arg) == 32); memcpy(payment_preimage_arg_ref.data, (uint8_t*)(payment_preimage_arg + 4), 32); LDKUpdateFulfillHTLC ret_var = UpdateFulfillHTLC_new(channel_id_arg_ref, htlc_id_arg, payment_preimage_arg_ref); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_UpdateFulfillHTLC_clone(uint32_t orig) { LDKUpdateFulfillHTLC orig_conv; orig_conv.inner = (void*)(orig & (~1)); orig_conv.is_owned = false; LDKUpdateFulfillHTLC ret_var = UpdateFulfillHTLC_clone(&orig_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } void __attribute__((visibility("default"))) TS_UpdateFailHTLC_free(uint32_t this_obj) { LDKUpdateFailHTLC this_obj_conv; this_obj_conv.inner = (void*)(this_obj & (~1)); this_obj_conv.is_owned = (this_obj & 1) || (this_obj == 0); UpdateFailHTLC_free(this_obj_conv); } int8_tArray __attribute__((visibility("default"))) TS_UpdateFailHTLC_get_channel_id(uint32_t this_ptr) { LDKUpdateFailHTLC this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int8_tArray ret_arr = init_arr(32, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), *UpdateFailHTLC_get_channel_id(&this_ptr_conv), 32); return ret_arr; } void __attribute__((visibility("default"))) TS_UpdateFailHTLC_set_channel_id(uint32_t this_ptr, int8_tArray val) { LDKUpdateFailHTLC this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKThirtyTwoBytes val_ref; CHECK(*((uint32_t*)val) == 32); memcpy(val_ref.data, (uint8_t*)(val + 4), 32); UpdateFailHTLC_set_channel_id(&this_ptr_conv, val_ref); } int64_t __attribute__((visibility("default"))) TS_UpdateFailHTLC_get_htlc_id(uint32_t this_ptr) { LDKUpdateFailHTLC this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int64_t ret_val = UpdateFailHTLC_get_htlc_id(&this_ptr_conv); return ret_val; } void __attribute__((visibility("default"))) TS_UpdateFailHTLC_set_htlc_id(uint32_t this_ptr, int64_t val) { LDKUpdateFailHTLC this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; UpdateFailHTLC_set_htlc_id(&this_ptr_conv, val); } uint32_t __attribute__((visibility("default"))) TS_UpdateFailHTLC_clone(uint32_t orig) { LDKUpdateFailHTLC orig_conv; orig_conv.inner = (void*)(orig & (~1)); orig_conv.is_owned = false; LDKUpdateFailHTLC ret_var = UpdateFailHTLC_clone(&orig_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } void __attribute__((visibility("default"))) TS_UpdateFailMalformedHTLC_free(uint32_t this_obj) { LDKUpdateFailMalformedHTLC this_obj_conv; this_obj_conv.inner = (void*)(this_obj & (~1)); this_obj_conv.is_owned = (this_obj & 1) || (this_obj == 0); UpdateFailMalformedHTLC_free(this_obj_conv); } int8_tArray __attribute__((visibility("default"))) TS_UpdateFailMalformedHTLC_get_channel_id(uint32_t this_ptr) { LDKUpdateFailMalformedHTLC this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int8_tArray ret_arr = init_arr(32, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), *UpdateFailMalformedHTLC_get_channel_id(&this_ptr_conv), 32); return ret_arr; } void __attribute__((visibility("default"))) TS_UpdateFailMalformedHTLC_set_channel_id(uint32_t this_ptr, int8_tArray val) { LDKUpdateFailMalformedHTLC this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKThirtyTwoBytes val_ref; CHECK(*((uint32_t*)val) == 32); memcpy(val_ref.data, (uint8_t*)(val + 4), 32); UpdateFailMalformedHTLC_set_channel_id(&this_ptr_conv, val_ref); } int64_t __attribute__((visibility("default"))) TS_UpdateFailMalformedHTLC_get_htlc_id(uint32_t this_ptr) { LDKUpdateFailMalformedHTLC this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int64_t ret_val = UpdateFailMalformedHTLC_get_htlc_id(&this_ptr_conv); return ret_val; } void __attribute__((visibility("default"))) TS_UpdateFailMalformedHTLC_set_htlc_id(uint32_t this_ptr, int64_t val) { LDKUpdateFailMalformedHTLC this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; UpdateFailMalformedHTLC_set_htlc_id(&this_ptr_conv, val); } int16_t __attribute__((visibility("default"))) TS_UpdateFailMalformedHTLC_get_failure_code(uint32_t this_ptr) { LDKUpdateFailMalformedHTLC this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int16_t ret_val = UpdateFailMalformedHTLC_get_failure_code(&this_ptr_conv); return ret_val; } void __attribute__((visibility("default"))) TS_UpdateFailMalformedHTLC_set_failure_code(uint32_t this_ptr, int16_t val) { LDKUpdateFailMalformedHTLC this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; UpdateFailMalformedHTLC_set_failure_code(&this_ptr_conv, val); } uint32_t __attribute__((visibility("default"))) TS_UpdateFailMalformedHTLC_clone(uint32_t orig) { LDKUpdateFailMalformedHTLC orig_conv; orig_conv.inner = (void*)(orig & (~1)); orig_conv.is_owned = false; LDKUpdateFailMalformedHTLC ret_var = UpdateFailMalformedHTLC_clone(&orig_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } void __attribute__((visibility("default"))) TS_CommitmentSigned_free(uint32_t this_obj) { LDKCommitmentSigned this_obj_conv; this_obj_conv.inner = (void*)(this_obj & (~1)); this_obj_conv.is_owned = (this_obj & 1) || (this_obj == 0); CommitmentSigned_free(this_obj_conv); } int8_tArray __attribute__((visibility("default"))) TS_CommitmentSigned_get_channel_id(uint32_t this_ptr) { LDKCommitmentSigned this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int8_tArray ret_arr = init_arr(32, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), *CommitmentSigned_get_channel_id(&this_ptr_conv), 32); return ret_arr; } void __attribute__((visibility("default"))) TS_CommitmentSigned_set_channel_id(uint32_t this_ptr, int8_tArray val) { LDKCommitmentSigned this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKThirtyTwoBytes val_ref; CHECK(*((uint32_t*)val) == 32); memcpy(val_ref.data, (uint8_t*)(val + 4), 32); CommitmentSigned_set_channel_id(&this_ptr_conv, val_ref); } int8_tArray __attribute__((visibility("default"))) TS_CommitmentSigned_get_signature(uint32_t this_ptr) { LDKCommitmentSigned this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int8_tArray ret_arr = init_arr(64, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), CommitmentSigned_get_signature(&this_ptr_conv).compact_form, 64); return ret_arr; } void __attribute__((visibility("default"))) TS_CommitmentSigned_set_signature(uint32_t this_ptr, int8_tArray val) { LDKCommitmentSigned this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKSignature val_ref; CHECK(*((uint32_t*)val) == 64); memcpy(val_ref.compact_form, (uint8_t*)(val + 4), 64); CommitmentSigned_set_signature(&this_ptr_conv, val_ref); } void __attribute__((visibility("default"))) TS_CommitmentSigned_set_htlc_signatures(uint32_t this_ptr, ptrArray val) { LDKCommitmentSigned this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKCVec_SignatureZ val_constr; val_constr.datalen = *((uint32_t*)val); if (val_constr.datalen > 0) val_constr.data = MALLOC(val_constr.datalen * sizeof(LDKSignature), "LDKCVec_SignatureZ Elements"); else val_constr.data = NULL; int8_tArray* val_vals = (int8_tArray*)(val + 4); for (size_t m = 0; m < val_constr.datalen; m++) { int8_tArray val_conv_12 = val_vals[m]; LDKSignature val_conv_12_ref; CHECK(*((uint32_t*)val_conv_12) == 64); memcpy(val_conv_12_ref.compact_form, (uint8_t*)(val_conv_12 + 4), 64); val_constr.data[m] = val_conv_12_ref; } CommitmentSigned_set_htlc_signatures(&this_ptr_conv, val_constr); } uint32_t __attribute__((visibility("default"))) TS_CommitmentSigned_new(int8_tArray channel_id_arg, int8_tArray signature_arg, ptrArray htlc_signatures_arg) { LDKThirtyTwoBytes channel_id_arg_ref; CHECK(*((uint32_t*)channel_id_arg) == 32); memcpy(channel_id_arg_ref.data, (uint8_t*)(channel_id_arg + 4), 32); LDKSignature signature_arg_ref; CHECK(*((uint32_t*)signature_arg) == 64); memcpy(signature_arg_ref.compact_form, (uint8_t*)(signature_arg + 4), 64); LDKCVec_SignatureZ htlc_signatures_arg_constr; htlc_signatures_arg_constr.datalen = *((uint32_t*)htlc_signatures_arg); if (htlc_signatures_arg_constr.datalen > 0) htlc_signatures_arg_constr.data = MALLOC(htlc_signatures_arg_constr.datalen * sizeof(LDKSignature), "LDKCVec_SignatureZ Elements"); else htlc_signatures_arg_constr.data = NULL; int8_tArray* htlc_signatures_arg_vals = (int8_tArray*)(htlc_signatures_arg + 4); for (size_t m = 0; m < htlc_signatures_arg_constr.datalen; m++) { int8_tArray htlc_signatures_arg_conv_12 = htlc_signatures_arg_vals[m]; LDKSignature htlc_signatures_arg_conv_12_ref; CHECK(*((uint32_t*)htlc_signatures_arg_conv_12) == 64); memcpy(htlc_signatures_arg_conv_12_ref.compact_form, (uint8_t*)(htlc_signatures_arg_conv_12 + 4), 64); htlc_signatures_arg_constr.data[m] = htlc_signatures_arg_conv_12_ref; } LDKCommitmentSigned ret_var = CommitmentSigned_new(channel_id_arg_ref, signature_arg_ref, htlc_signatures_arg_constr); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_CommitmentSigned_clone(uint32_t orig) { LDKCommitmentSigned orig_conv; orig_conv.inner = (void*)(orig & (~1)); orig_conv.is_owned = false; LDKCommitmentSigned ret_var = CommitmentSigned_clone(&orig_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } void __attribute__((visibility("default"))) TS_RevokeAndACK_free(uint32_t this_obj) { LDKRevokeAndACK this_obj_conv; this_obj_conv.inner = (void*)(this_obj & (~1)); this_obj_conv.is_owned = (this_obj & 1) || (this_obj == 0); RevokeAndACK_free(this_obj_conv); } int8_tArray __attribute__((visibility("default"))) TS_RevokeAndACK_get_channel_id(uint32_t this_ptr) { LDKRevokeAndACK this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int8_tArray ret_arr = init_arr(32, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), *RevokeAndACK_get_channel_id(&this_ptr_conv), 32); return ret_arr; } void __attribute__((visibility("default"))) TS_RevokeAndACK_set_channel_id(uint32_t this_ptr, int8_tArray val) { LDKRevokeAndACK this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKThirtyTwoBytes val_ref; CHECK(*((uint32_t*)val) == 32); memcpy(val_ref.data, (uint8_t*)(val + 4), 32); RevokeAndACK_set_channel_id(&this_ptr_conv, val_ref); } int8_tArray __attribute__((visibility("default"))) TS_RevokeAndACK_get_per_commitment_secret(uint32_t this_ptr) { LDKRevokeAndACK this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int8_tArray ret_arr = init_arr(32, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), *RevokeAndACK_get_per_commitment_secret(&this_ptr_conv), 32); return ret_arr; } void __attribute__((visibility("default"))) TS_RevokeAndACK_set_per_commitment_secret(uint32_t this_ptr, int8_tArray val) { LDKRevokeAndACK this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKThirtyTwoBytes val_ref; CHECK(*((uint32_t*)val) == 32); memcpy(val_ref.data, (uint8_t*)(val + 4), 32); RevokeAndACK_set_per_commitment_secret(&this_ptr_conv, val_ref); } int8_tArray __attribute__((visibility("default"))) TS_RevokeAndACK_get_next_per_commitment_point(uint32_t this_ptr) { LDKRevokeAndACK this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int8_tArray ret_arr = init_arr(33, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), RevokeAndACK_get_next_per_commitment_point(&this_ptr_conv).compressed_form, 33); return ret_arr; } void __attribute__((visibility("default"))) TS_RevokeAndACK_set_next_per_commitment_point(uint32_t this_ptr, int8_tArray val) { LDKRevokeAndACK this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKPublicKey val_ref; CHECK(*((uint32_t*)val) == 33); memcpy(val_ref.compressed_form, (uint8_t*)(val + 4), 33); RevokeAndACK_set_next_per_commitment_point(&this_ptr_conv, val_ref); } uint32_t __attribute__((visibility("default"))) TS_RevokeAndACK_new(int8_tArray channel_id_arg, int8_tArray per_commitment_secret_arg, int8_tArray next_per_commitment_point_arg) { LDKThirtyTwoBytes channel_id_arg_ref; CHECK(*((uint32_t*)channel_id_arg) == 32); memcpy(channel_id_arg_ref.data, (uint8_t*)(channel_id_arg + 4), 32); LDKThirtyTwoBytes per_commitment_secret_arg_ref; CHECK(*((uint32_t*)per_commitment_secret_arg) == 32); memcpy(per_commitment_secret_arg_ref.data, (uint8_t*)(per_commitment_secret_arg + 4), 32); LDKPublicKey next_per_commitment_point_arg_ref; CHECK(*((uint32_t*)next_per_commitment_point_arg) == 33); memcpy(next_per_commitment_point_arg_ref.compressed_form, (uint8_t*)(next_per_commitment_point_arg + 4), 33); LDKRevokeAndACK ret_var = RevokeAndACK_new(channel_id_arg_ref, per_commitment_secret_arg_ref, next_per_commitment_point_arg_ref); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_RevokeAndACK_clone(uint32_t orig) { LDKRevokeAndACK orig_conv; orig_conv.inner = (void*)(orig & (~1)); orig_conv.is_owned = false; LDKRevokeAndACK ret_var = RevokeAndACK_clone(&orig_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } void __attribute__((visibility("default"))) TS_UpdateFee_free(uint32_t this_obj) { LDKUpdateFee this_obj_conv; this_obj_conv.inner = (void*)(this_obj & (~1)); this_obj_conv.is_owned = (this_obj & 1) || (this_obj == 0); UpdateFee_free(this_obj_conv); } int8_tArray __attribute__((visibility("default"))) TS_UpdateFee_get_channel_id(uint32_t this_ptr) { LDKUpdateFee this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int8_tArray ret_arr = init_arr(32, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), *UpdateFee_get_channel_id(&this_ptr_conv), 32); return ret_arr; } void __attribute__((visibility("default"))) TS_UpdateFee_set_channel_id(uint32_t this_ptr, int8_tArray val) { LDKUpdateFee this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKThirtyTwoBytes val_ref; CHECK(*((uint32_t*)val) == 32); memcpy(val_ref.data, (uint8_t*)(val + 4), 32); UpdateFee_set_channel_id(&this_ptr_conv, val_ref); } int32_t __attribute__((visibility("default"))) TS_UpdateFee_get_feerate_per_kw(uint32_t this_ptr) { LDKUpdateFee this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int32_t ret_val = UpdateFee_get_feerate_per_kw(&this_ptr_conv); return ret_val; } void __attribute__((visibility("default"))) TS_UpdateFee_set_feerate_per_kw(uint32_t this_ptr, int32_t val) { LDKUpdateFee this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; UpdateFee_set_feerate_per_kw(&this_ptr_conv, val); } uint32_t __attribute__((visibility("default"))) TS_UpdateFee_new(int8_tArray channel_id_arg, int32_t feerate_per_kw_arg) { LDKThirtyTwoBytes channel_id_arg_ref; CHECK(*((uint32_t*)channel_id_arg) == 32); memcpy(channel_id_arg_ref.data, (uint8_t*)(channel_id_arg + 4), 32); LDKUpdateFee ret_var = UpdateFee_new(channel_id_arg_ref, feerate_per_kw_arg); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_UpdateFee_clone(uint32_t orig) { LDKUpdateFee orig_conv; orig_conv.inner = (void*)(orig & (~1)); orig_conv.is_owned = false; LDKUpdateFee ret_var = UpdateFee_clone(&orig_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } void __attribute__((visibility("default"))) TS_DataLossProtect_free(uint32_t this_obj) { LDKDataLossProtect this_obj_conv; this_obj_conv.inner = (void*)(this_obj & (~1)); this_obj_conv.is_owned = (this_obj & 1) || (this_obj == 0); DataLossProtect_free(this_obj_conv); } int8_tArray __attribute__((visibility("default"))) TS_DataLossProtect_get_your_last_per_commitment_secret(uint32_t this_ptr) { LDKDataLossProtect this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int8_tArray ret_arr = init_arr(32, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), *DataLossProtect_get_your_last_per_commitment_secret(&this_ptr_conv), 32); return ret_arr; } void __attribute__((visibility("default"))) TS_DataLossProtect_set_your_last_per_commitment_secret(uint32_t this_ptr, int8_tArray val) { LDKDataLossProtect this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKThirtyTwoBytes val_ref; CHECK(*((uint32_t*)val) == 32); memcpy(val_ref.data, (uint8_t*)(val + 4), 32); DataLossProtect_set_your_last_per_commitment_secret(&this_ptr_conv, val_ref); } int8_tArray __attribute__((visibility("default"))) TS_DataLossProtect_get_my_current_per_commitment_point(uint32_t this_ptr) { LDKDataLossProtect this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int8_tArray ret_arr = init_arr(33, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), DataLossProtect_get_my_current_per_commitment_point(&this_ptr_conv).compressed_form, 33); return ret_arr; } void __attribute__((visibility("default"))) TS_DataLossProtect_set_my_current_per_commitment_point(uint32_t this_ptr, int8_tArray val) { LDKDataLossProtect this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKPublicKey val_ref; CHECK(*((uint32_t*)val) == 33); memcpy(val_ref.compressed_form, (uint8_t*)(val + 4), 33); DataLossProtect_set_my_current_per_commitment_point(&this_ptr_conv, val_ref); } uint32_t __attribute__((visibility("default"))) TS_DataLossProtect_new(int8_tArray your_last_per_commitment_secret_arg, int8_tArray my_current_per_commitment_point_arg) { LDKThirtyTwoBytes your_last_per_commitment_secret_arg_ref; CHECK(*((uint32_t*)your_last_per_commitment_secret_arg) == 32); memcpy(your_last_per_commitment_secret_arg_ref.data, (uint8_t*)(your_last_per_commitment_secret_arg + 4), 32); LDKPublicKey my_current_per_commitment_point_arg_ref; CHECK(*((uint32_t*)my_current_per_commitment_point_arg) == 33); memcpy(my_current_per_commitment_point_arg_ref.compressed_form, (uint8_t*)(my_current_per_commitment_point_arg + 4), 33); LDKDataLossProtect ret_var = DataLossProtect_new(your_last_per_commitment_secret_arg_ref, my_current_per_commitment_point_arg_ref); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_DataLossProtect_clone(uint32_t orig) { LDKDataLossProtect orig_conv; orig_conv.inner = (void*)(orig & (~1)); orig_conv.is_owned = false; LDKDataLossProtect ret_var = DataLossProtect_clone(&orig_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } void __attribute__((visibility("default"))) TS_ChannelReestablish_free(uint32_t this_obj) { LDKChannelReestablish this_obj_conv; this_obj_conv.inner = (void*)(this_obj & (~1)); this_obj_conv.is_owned = (this_obj & 1) || (this_obj == 0); ChannelReestablish_free(this_obj_conv); } int8_tArray __attribute__((visibility("default"))) TS_ChannelReestablish_get_channel_id(uint32_t this_ptr) { LDKChannelReestablish this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int8_tArray ret_arr = init_arr(32, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), *ChannelReestablish_get_channel_id(&this_ptr_conv), 32); return ret_arr; } void __attribute__((visibility("default"))) TS_ChannelReestablish_set_channel_id(uint32_t this_ptr, int8_tArray val) { LDKChannelReestablish this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKThirtyTwoBytes val_ref; CHECK(*((uint32_t*)val) == 32); memcpy(val_ref.data, (uint8_t*)(val + 4), 32); ChannelReestablish_set_channel_id(&this_ptr_conv, val_ref); } int64_t __attribute__((visibility("default"))) TS_ChannelReestablish_get_next_local_commitment_number(uint32_t this_ptr) { LDKChannelReestablish this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int64_t ret_val = ChannelReestablish_get_next_local_commitment_number(&this_ptr_conv); return ret_val; } void __attribute__((visibility("default"))) TS_ChannelReestablish_set_next_local_commitment_number(uint32_t this_ptr, int64_t val) { LDKChannelReestablish this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; ChannelReestablish_set_next_local_commitment_number(&this_ptr_conv, val); } int64_t __attribute__((visibility("default"))) TS_ChannelReestablish_get_next_remote_commitment_number(uint32_t this_ptr) { LDKChannelReestablish this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int64_t ret_val = ChannelReestablish_get_next_remote_commitment_number(&this_ptr_conv); return ret_val; } void __attribute__((visibility("default"))) TS_ChannelReestablish_set_next_remote_commitment_number(uint32_t this_ptr, int64_t val) { LDKChannelReestablish this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; ChannelReestablish_set_next_remote_commitment_number(&this_ptr_conv, val); } uint32_t __attribute__((visibility("default"))) TS_ChannelReestablish_clone(uint32_t orig) { LDKChannelReestablish orig_conv; orig_conv.inner = (void*)(orig & (~1)); orig_conv.is_owned = false; LDKChannelReestablish ret_var = ChannelReestablish_clone(&orig_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } void __attribute__((visibility("default"))) TS_AnnouncementSignatures_free(uint32_t this_obj) { LDKAnnouncementSignatures this_obj_conv; this_obj_conv.inner = (void*)(this_obj & (~1)); this_obj_conv.is_owned = (this_obj & 1) || (this_obj == 0); AnnouncementSignatures_free(this_obj_conv); } int8_tArray __attribute__((visibility("default"))) TS_AnnouncementSignatures_get_channel_id(uint32_t this_ptr) { LDKAnnouncementSignatures this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int8_tArray ret_arr = init_arr(32, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), *AnnouncementSignatures_get_channel_id(&this_ptr_conv), 32); return ret_arr; } void __attribute__((visibility("default"))) TS_AnnouncementSignatures_set_channel_id(uint32_t this_ptr, int8_tArray val) { LDKAnnouncementSignatures this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKThirtyTwoBytes val_ref; CHECK(*((uint32_t*)val) == 32); memcpy(val_ref.data, (uint8_t*)(val + 4), 32); AnnouncementSignatures_set_channel_id(&this_ptr_conv, val_ref); } int64_t __attribute__((visibility("default"))) TS_AnnouncementSignatures_get_short_channel_id(uint32_t this_ptr) { LDKAnnouncementSignatures this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int64_t ret_val = AnnouncementSignatures_get_short_channel_id(&this_ptr_conv); return ret_val; } void __attribute__((visibility("default"))) TS_AnnouncementSignatures_set_short_channel_id(uint32_t this_ptr, int64_t val) { LDKAnnouncementSignatures this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; AnnouncementSignatures_set_short_channel_id(&this_ptr_conv, val); } int8_tArray __attribute__((visibility("default"))) TS_AnnouncementSignatures_get_node_signature(uint32_t this_ptr) { LDKAnnouncementSignatures this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int8_tArray ret_arr = init_arr(64, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), AnnouncementSignatures_get_node_signature(&this_ptr_conv).compact_form, 64); return ret_arr; } void __attribute__((visibility("default"))) TS_AnnouncementSignatures_set_node_signature(uint32_t this_ptr, int8_tArray val) { LDKAnnouncementSignatures this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKSignature val_ref; CHECK(*((uint32_t*)val) == 64); memcpy(val_ref.compact_form, (uint8_t*)(val + 4), 64); AnnouncementSignatures_set_node_signature(&this_ptr_conv, val_ref); } int8_tArray __attribute__((visibility("default"))) TS_AnnouncementSignatures_get_bitcoin_signature(uint32_t this_ptr) { LDKAnnouncementSignatures this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int8_tArray ret_arr = init_arr(64, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), AnnouncementSignatures_get_bitcoin_signature(&this_ptr_conv).compact_form, 64); return ret_arr; } void __attribute__((visibility("default"))) TS_AnnouncementSignatures_set_bitcoin_signature(uint32_t this_ptr, int8_tArray val) { LDKAnnouncementSignatures this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKSignature val_ref; CHECK(*((uint32_t*)val) == 64); memcpy(val_ref.compact_form, (uint8_t*)(val + 4), 64); AnnouncementSignatures_set_bitcoin_signature(&this_ptr_conv, val_ref); } uint32_t __attribute__((visibility("default"))) TS_AnnouncementSignatures_new(int8_tArray channel_id_arg, int64_t short_channel_id_arg, int8_tArray node_signature_arg, int8_tArray bitcoin_signature_arg) { LDKThirtyTwoBytes channel_id_arg_ref; CHECK(*((uint32_t*)channel_id_arg) == 32); memcpy(channel_id_arg_ref.data, (uint8_t*)(channel_id_arg + 4), 32); LDKSignature node_signature_arg_ref; CHECK(*((uint32_t*)node_signature_arg) == 64); memcpy(node_signature_arg_ref.compact_form, (uint8_t*)(node_signature_arg + 4), 64); LDKSignature bitcoin_signature_arg_ref; CHECK(*((uint32_t*)bitcoin_signature_arg) == 64); memcpy(bitcoin_signature_arg_ref.compact_form, (uint8_t*)(bitcoin_signature_arg + 4), 64); LDKAnnouncementSignatures ret_var = AnnouncementSignatures_new(channel_id_arg_ref, short_channel_id_arg, node_signature_arg_ref, bitcoin_signature_arg_ref); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_AnnouncementSignatures_clone(uint32_t orig) { LDKAnnouncementSignatures orig_conv; orig_conv.inner = (void*)(orig & (~1)); orig_conv.is_owned = false; LDKAnnouncementSignatures ret_var = AnnouncementSignatures_clone(&orig_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } void __attribute__((visibility("default"))) TS_NetAddress_free(uint32_t this_ptr) { if ((this_ptr & 1) != 0) return; LDKNetAddress this_ptr_conv = *(LDKNetAddress*)(((uint64_t)this_ptr) & ~1); FREE((void*)this_ptr); NetAddress_free(this_ptr_conv); } uint32_t __attribute__((visibility("default"))) TS_NetAddress_clone(uint32_t orig) { LDKNetAddress* orig_conv = (LDKNetAddress*)orig; LDKNetAddress *ret_copy = MALLOC(sizeof(LDKNetAddress), "LDKNetAddress"); *ret_copy = NetAddress_clone(orig_conv); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_NetAddress_ipv4(int8_tArray addr, int16_t port) { LDKFourBytes addr_ref; CHECK(*((uint32_t*)addr) == 4); memcpy(addr_ref.data, (uint8_t*)(addr + 4), 4); LDKNetAddress *ret_copy = MALLOC(sizeof(LDKNetAddress), "LDKNetAddress"); *ret_copy = NetAddress_ipv4(addr_ref, port); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_NetAddress_ipv6(int8_tArray addr, int16_t port) { LDKSixteenBytes addr_ref; CHECK(*((uint32_t*)addr) == 16); memcpy(addr_ref.data, (uint8_t*)(addr + 4), 16); LDKNetAddress *ret_copy = MALLOC(sizeof(LDKNetAddress), "LDKNetAddress"); *ret_copy = NetAddress_ipv6(addr_ref, port); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_NetAddress_onion_v2(int8_tArray addr, int16_t port) { LDKTenBytes addr_ref; CHECK(*((uint32_t*)addr) == 10); memcpy(addr_ref.data, (uint8_t*)(addr + 4), 10); LDKNetAddress *ret_copy = MALLOC(sizeof(LDKNetAddress), "LDKNetAddress"); *ret_copy = NetAddress_onion_v2(addr_ref, port); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_NetAddress_onion_v3(int8_tArray ed25519_pubkey, int16_t checksum, int8_t version, int16_t port) { LDKThirtyTwoBytes ed25519_pubkey_ref; CHECK(*((uint32_t*)ed25519_pubkey) == 32); memcpy(ed25519_pubkey_ref.data, (uint8_t*)(ed25519_pubkey + 4), 32); LDKNetAddress *ret_copy = MALLOC(sizeof(LDKNetAddress), "LDKNetAddress"); *ret_copy = NetAddress_onion_v3(ed25519_pubkey_ref, checksum, version, port); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } int8_tArray __attribute__((visibility("default"))) TS_NetAddress_write(uint32_t obj) { LDKNetAddress* obj_conv = (LDKNetAddress*)obj; LDKCVec_u8Z ret_var = NetAddress_write(obj_conv); int8_tArray ret_arr = init_arr(ret_var.datalen, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), ret_var.data, ret_var.datalen); CVec_u8Z_free(ret_var); return ret_arr; } uint32_t __attribute__((visibility("default"))) TS_Result_read(int8_tArray ser) { LDKu8slice ser_ref; ser_ref.datalen = *((uint32_t*)ser); ser_ref.data = (int8_t*)(ser + 4); LDKCResult_CResult_NetAddressu8ZDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_CResult_NetAddressu8ZDecodeErrorZ), "LDKCResult_CResult_NetAddressu8ZDecodeErrorZ"); *ret_conv = Result_read(ser_ref); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_NetAddress_read(int8_tArray ser) { LDKu8slice ser_ref; ser_ref.datalen = *((uint32_t*)ser); ser_ref.data = (int8_t*)(ser + 4); LDKCResult_NetAddressDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_NetAddressDecodeErrorZ), "LDKCResult_NetAddressDecodeErrorZ"); *ret_conv = NetAddress_read(ser_ref); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_UnsignedNodeAnnouncement_free(uint32_t this_obj) { LDKUnsignedNodeAnnouncement this_obj_conv; this_obj_conv.inner = (void*)(this_obj & (~1)); this_obj_conv.is_owned = (this_obj & 1) || (this_obj == 0); UnsignedNodeAnnouncement_free(this_obj_conv); } uint32_t __attribute__((visibility("default"))) TS_UnsignedNodeAnnouncement_get_features(uint32_t this_ptr) { LDKUnsignedNodeAnnouncement this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKNodeFeatures ret_var = UnsignedNodeAnnouncement_get_features(&this_ptr_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } void __attribute__((visibility("default"))) TS_UnsignedNodeAnnouncement_set_features(uint32_t this_ptr, uint32_t val) { LDKUnsignedNodeAnnouncement this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKNodeFeatures val_conv; val_conv.inner = (void*)(val & (~1)); val_conv.is_owned = (val & 1) || (val == 0); val_conv = NodeFeatures_clone(&val_conv); UnsignedNodeAnnouncement_set_features(&this_ptr_conv, val_conv); } int32_t __attribute__((visibility("default"))) TS_UnsignedNodeAnnouncement_get_timestamp(uint32_t this_ptr) { LDKUnsignedNodeAnnouncement this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int32_t ret_val = UnsignedNodeAnnouncement_get_timestamp(&this_ptr_conv); return ret_val; } void __attribute__((visibility("default"))) TS_UnsignedNodeAnnouncement_set_timestamp(uint32_t this_ptr, int32_t val) { LDKUnsignedNodeAnnouncement this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; UnsignedNodeAnnouncement_set_timestamp(&this_ptr_conv, val); } int8_tArray __attribute__((visibility("default"))) TS_UnsignedNodeAnnouncement_get_node_id(uint32_t this_ptr) { LDKUnsignedNodeAnnouncement this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int8_tArray ret_arr = init_arr(33, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), UnsignedNodeAnnouncement_get_node_id(&this_ptr_conv).compressed_form, 33); return ret_arr; } void __attribute__((visibility("default"))) TS_UnsignedNodeAnnouncement_set_node_id(uint32_t this_ptr, int8_tArray val) { LDKUnsignedNodeAnnouncement this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKPublicKey val_ref; CHECK(*((uint32_t*)val) == 33); memcpy(val_ref.compressed_form, (uint8_t*)(val + 4), 33); UnsignedNodeAnnouncement_set_node_id(&this_ptr_conv, val_ref); } int8_tArray __attribute__((visibility("default"))) TS_UnsignedNodeAnnouncement_get_rgb(uint32_t this_ptr) { LDKUnsignedNodeAnnouncement this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int8_tArray ret_arr = init_arr(3, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), *UnsignedNodeAnnouncement_get_rgb(&this_ptr_conv), 3); return ret_arr; } void __attribute__((visibility("default"))) TS_UnsignedNodeAnnouncement_set_rgb(uint32_t this_ptr, int8_tArray val) { LDKUnsignedNodeAnnouncement this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKThreeBytes val_ref; CHECK(*((uint32_t*)val) == 3); memcpy(val_ref.data, (uint8_t*)(val + 4), 3); UnsignedNodeAnnouncement_set_rgb(&this_ptr_conv, val_ref); } int8_tArray __attribute__((visibility("default"))) TS_UnsignedNodeAnnouncement_get_alias(uint32_t this_ptr) { LDKUnsignedNodeAnnouncement this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int8_tArray ret_arr = init_arr(32, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), *UnsignedNodeAnnouncement_get_alias(&this_ptr_conv), 32); return ret_arr; } void __attribute__((visibility("default"))) TS_UnsignedNodeAnnouncement_set_alias(uint32_t this_ptr, int8_tArray val) { LDKUnsignedNodeAnnouncement this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKThirtyTwoBytes val_ref; CHECK(*((uint32_t*)val) == 32); memcpy(val_ref.data, (uint8_t*)(val + 4), 32); UnsignedNodeAnnouncement_set_alias(&this_ptr_conv, val_ref); } void __attribute__((visibility("default"))) TS_UnsignedNodeAnnouncement_set_addresses(uint32_t this_ptr, uint32_tArray val) { LDKUnsignedNodeAnnouncement this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKCVec_NetAddressZ val_constr; val_constr.datalen = *((uint32_t*)val); if (val_constr.datalen > 0) val_constr.data = MALLOC(val_constr.datalen * sizeof(LDKNetAddress), "LDKCVec_NetAddressZ Elements"); else val_constr.data = NULL; uint32_t* val_vals = (uint32_t*)(val + 4); for (size_t m = 0; m < val_constr.datalen; m++) { uint32_t val_conv_12 = val_vals[m]; LDKNetAddress val_conv_12_conv = *(LDKNetAddress*)(((uint64_t)val_conv_12) & ~1); val_conv_12_conv = NetAddress_clone((LDKNetAddress*)(((uint64_t)val_conv_12) & ~1)); val_constr.data[m] = val_conv_12_conv; } UnsignedNodeAnnouncement_set_addresses(&this_ptr_conv, val_constr); } uint32_t __attribute__((visibility("default"))) TS_UnsignedNodeAnnouncement_clone(uint32_t orig) { LDKUnsignedNodeAnnouncement orig_conv; orig_conv.inner = (void*)(orig & (~1)); orig_conv.is_owned = false; LDKUnsignedNodeAnnouncement ret_var = UnsignedNodeAnnouncement_clone(&orig_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } void __attribute__((visibility("default"))) TS_NodeAnnouncement_free(uint32_t this_obj) { LDKNodeAnnouncement this_obj_conv; this_obj_conv.inner = (void*)(this_obj & (~1)); this_obj_conv.is_owned = (this_obj & 1) || (this_obj == 0); NodeAnnouncement_free(this_obj_conv); } int8_tArray __attribute__((visibility("default"))) TS_NodeAnnouncement_get_signature(uint32_t this_ptr) { LDKNodeAnnouncement this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int8_tArray ret_arr = init_arr(64, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), NodeAnnouncement_get_signature(&this_ptr_conv).compact_form, 64); return ret_arr; } void __attribute__((visibility("default"))) TS_NodeAnnouncement_set_signature(uint32_t this_ptr, int8_tArray val) { LDKNodeAnnouncement this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKSignature val_ref; CHECK(*((uint32_t*)val) == 64); memcpy(val_ref.compact_form, (uint8_t*)(val + 4), 64); NodeAnnouncement_set_signature(&this_ptr_conv, val_ref); } uint32_t __attribute__((visibility("default"))) TS_NodeAnnouncement_get_contents(uint32_t this_ptr) { LDKNodeAnnouncement this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKUnsignedNodeAnnouncement ret_var = NodeAnnouncement_get_contents(&this_ptr_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } void __attribute__((visibility("default"))) TS_NodeAnnouncement_set_contents(uint32_t this_ptr, uint32_t val) { LDKNodeAnnouncement this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKUnsignedNodeAnnouncement val_conv; val_conv.inner = (void*)(val & (~1)); val_conv.is_owned = (val & 1) || (val == 0); val_conv = UnsignedNodeAnnouncement_clone(&val_conv); NodeAnnouncement_set_contents(&this_ptr_conv, val_conv); } uint32_t __attribute__((visibility("default"))) TS_NodeAnnouncement_new(int8_tArray signature_arg, uint32_t contents_arg) { LDKSignature signature_arg_ref; CHECK(*((uint32_t*)signature_arg) == 64); memcpy(signature_arg_ref.compact_form, (uint8_t*)(signature_arg + 4), 64); LDKUnsignedNodeAnnouncement contents_arg_conv; contents_arg_conv.inner = (void*)(contents_arg & (~1)); contents_arg_conv.is_owned = (contents_arg & 1) || (contents_arg == 0); contents_arg_conv = UnsignedNodeAnnouncement_clone(&contents_arg_conv); LDKNodeAnnouncement ret_var = NodeAnnouncement_new(signature_arg_ref, contents_arg_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_NodeAnnouncement_clone(uint32_t orig) { LDKNodeAnnouncement orig_conv; orig_conv.inner = (void*)(orig & (~1)); orig_conv.is_owned = false; LDKNodeAnnouncement ret_var = NodeAnnouncement_clone(&orig_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } void __attribute__((visibility("default"))) TS_UnsignedChannelAnnouncement_free(uint32_t this_obj) { LDKUnsignedChannelAnnouncement this_obj_conv; this_obj_conv.inner = (void*)(this_obj & (~1)); this_obj_conv.is_owned = (this_obj & 1) || (this_obj == 0); UnsignedChannelAnnouncement_free(this_obj_conv); } uint32_t __attribute__((visibility("default"))) TS_UnsignedChannelAnnouncement_get_features(uint32_t this_ptr) { LDKUnsignedChannelAnnouncement this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKChannelFeatures ret_var = UnsignedChannelAnnouncement_get_features(&this_ptr_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } void __attribute__((visibility("default"))) TS_UnsignedChannelAnnouncement_set_features(uint32_t this_ptr, uint32_t val) { LDKUnsignedChannelAnnouncement this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKChannelFeatures val_conv; val_conv.inner = (void*)(val & (~1)); val_conv.is_owned = (val & 1) || (val == 0); val_conv = ChannelFeatures_clone(&val_conv); UnsignedChannelAnnouncement_set_features(&this_ptr_conv, val_conv); } int8_tArray __attribute__((visibility("default"))) TS_UnsignedChannelAnnouncement_get_chain_hash(uint32_t this_ptr) { LDKUnsignedChannelAnnouncement this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int8_tArray ret_arr = init_arr(32, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), *UnsignedChannelAnnouncement_get_chain_hash(&this_ptr_conv), 32); return ret_arr; } void __attribute__((visibility("default"))) TS_UnsignedChannelAnnouncement_set_chain_hash(uint32_t this_ptr, int8_tArray val) { LDKUnsignedChannelAnnouncement this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKThirtyTwoBytes val_ref; CHECK(*((uint32_t*)val) == 32); memcpy(val_ref.data, (uint8_t*)(val + 4), 32); UnsignedChannelAnnouncement_set_chain_hash(&this_ptr_conv, val_ref); } int64_t __attribute__((visibility("default"))) TS_UnsignedChannelAnnouncement_get_short_channel_id(uint32_t this_ptr) { LDKUnsignedChannelAnnouncement this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int64_t ret_val = UnsignedChannelAnnouncement_get_short_channel_id(&this_ptr_conv); return ret_val; } void __attribute__((visibility("default"))) TS_UnsignedChannelAnnouncement_set_short_channel_id(uint32_t this_ptr, int64_t val) { LDKUnsignedChannelAnnouncement this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; UnsignedChannelAnnouncement_set_short_channel_id(&this_ptr_conv, val); } int8_tArray __attribute__((visibility("default"))) TS_UnsignedChannelAnnouncement_get_node_id_1(uint32_t this_ptr) { LDKUnsignedChannelAnnouncement this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int8_tArray ret_arr = init_arr(33, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), UnsignedChannelAnnouncement_get_node_id_1(&this_ptr_conv).compressed_form, 33); return ret_arr; } void __attribute__((visibility("default"))) TS_UnsignedChannelAnnouncement_set_node_id_1(uint32_t this_ptr, int8_tArray val) { LDKUnsignedChannelAnnouncement this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKPublicKey val_ref; CHECK(*((uint32_t*)val) == 33); memcpy(val_ref.compressed_form, (uint8_t*)(val + 4), 33); UnsignedChannelAnnouncement_set_node_id_1(&this_ptr_conv, val_ref); } int8_tArray __attribute__((visibility("default"))) TS_UnsignedChannelAnnouncement_get_node_id_2(uint32_t this_ptr) { LDKUnsignedChannelAnnouncement this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int8_tArray ret_arr = init_arr(33, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), UnsignedChannelAnnouncement_get_node_id_2(&this_ptr_conv).compressed_form, 33); return ret_arr; } void __attribute__((visibility("default"))) TS_UnsignedChannelAnnouncement_set_node_id_2(uint32_t this_ptr, int8_tArray val) { LDKUnsignedChannelAnnouncement this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKPublicKey val_ref; CHECK(*((uint32_t*)val) == 33); memcpy(val_ref.compressed_form, (uint8_t*)(val + 4), 33); UnsignedChannelAnnouncement_set_node_id_2(&this_ptr_conv, val_ref); } int8_tArray __attribute__((visibility("default"))) TS_UnsignedChannelAnnouncement_get_bitcoin_key_1(uint32_t this_ptr) { LDKUnsignedChannelAnnouncement this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int8_tArray ret_arr = init_arr(33, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), UnsignedChannelAnnouncement_get_bitcoin_key_1(&this_ptr_conv).compressed_form, 33); return ret_arr; } void __attribute__((visibility("default"))) TS_UnsignedChannelAnnouncement_set_bitcoin_key_1(uint32_t this_ptr, int8_tArray val) { LDKUnsignedChannelAnnouncement this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKPublicKey val_ref; CHECK(*((uint32_t*)val) == 33); memcpy(val_ref.compressed_form, (uint8_t*)(val + 4), 33); UnsignedChannelAnnouncement_set_bitcoin_key_1(&this_ptr_conv, val_ref); } int8_tArray __attribute__((visibility("default"))) TS_UnsignedChannelAnnouncement_get_bitcoin_key_2(uint32_t this_ptr) { LDKUnsignedChannelAnnouncement this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int8_tArray ret_arr = init_arr(33, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), UnsignedChannelAnnouncement_get_bitcoin_key_2(&this_ptr_conv).compressed_form, 33); return ret_arr; } void __attribute__((visibility("default"))) TS_UnsignedChannelAnnouncement_set_bitcoin_key_2(uint32_t this_ptr, int8_tArray val) { LDKUnsignedChannelAnnouncement this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKPublicKey val_ref; CHECK(*((uint32_t*)val) == 33); memcpy(val_ref.compressed_form, (uint8_t*)(val + 4), 33); UnsignedChannelAnnouncement_set_bitcoin_key_2(&this_ptr_conv, val_ref); } uint32_t __attribute__((visibility("default"))) TS_UnsignedChannelAnnouncement_clone(uint32_t orig) { LDKUnsignedChannelAnnouncement orig_conv; orig_conv.inner = (void*)(orig & (~1)); orig_conv.is_owned = false; LDKUnsignedChannelAnnouncement ret_var = UnsignedChannelAnnouncement_clone(&orig_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } void __attribute__((visibility("default"))) TS_ChannelAnnouncement_free(uint32_t this_obj) { LDKChannelAnnouncement this_obj_conv; this_obj_conv.inner = (void*)(this_obj & (~1)); this_obj_conv.is_owned = (this_obj & 1) || (this_obj == 0); ChannelAnnouncement_free(this_obj_conv); } int8_tArray __attribute__((visibility("default"))) TS_ChannelAnnouncement_get_node_signature_1(uint32_t this_ptr) { LDKChannelAnnouncement this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int8_tArray ret_arr = init_arr(64, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), ChannelAnnouncement_get_node_signature_1(&this_ptr_conv).compact_form, 64); return ret_arr; } void __attribute__((visibility("default"))) TS_ChannelAnnouncement_set_node_signature_1(uint32_t this_ptr, int8_tArray val) { LDKChannelAnnouncement this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKSignature val_ref; CHECK(*((uint32_t*)val) == 64); memcpy(val_ref.compact_form, (uint8_t*)(val + 4), 64); ChannelAnnouncement_set_node_signature_1(&this_ptr_conv, val_ref); } int8_tArray __attribute__((visibility("default"))) TS_ChannelAnnouncement_get_node_signature_2(uint32_t this_ptr) { LDKChannelAnnouncement this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int8_tArray ret_arr = init_arr(64, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), ChannelAnnouncement_get_node_signature_2(&this_ptr_conv).compact_form, 64); return ret_arr; } void __attribute__((visibility("default"))) TS_ChannelAnnouncement_set_node_signature_2(uint32_t this_ptr, int8_tArray val) { LDKChannelAnnouncement this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKSignature val_ref; CHECK(*((uint32_t*)val) == 64); memcpy(val_ref.compact_form, (uint8_t*)(val + 4), 64); ChannelAnnouncement_set_node_signature_2(&this_ptr_conv, val_ref); } int8_tArray __attribute__((visibility("default"))) TS_ChannelAnnouncement_get_bitcoin_signature_1(uint32_t this_ptr) { LDKChannelAnnouncement this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int8_tArray ret_arr = init_arr(64, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), ChannelAnnouncement_get_bitcoin_signature_1(&this_ptr_conv).compact_form, 64); return ret_arr; } void __attribute__((visibility("default"))) TS_ChannelAnnouncement_set_bitcoin_signature_1(uint32_t this_ptr, int8_tArray val) { LDKChannelAnnouncement this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKSignature val_ref; CHECK(*((uint32_t*)val) == 64); memcpy(val_ref.compact_form, (uint8_t*)(val + 4), 64); ChannelAnnouncement_set_bitcoin_signature_1(&this_ptr_conv, val_ref); } int8_tArray __attribute__((visibility("default"))) TS_ChannelAnnouncement_get_bitcoin_signature_2(uint32_t this_ptr) { LDKChannelAnnouncement this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int8_tArray ret_arr = init_arr(64, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), ChannelAnnouncement_get_bitcoin_signature_2(&this_ptr_conv).compact_form, 64); return ret_arr; } void __attribute__((visibility("default"))) TS_ChannelAnnouncement_set_bitcoin_signature_2(uint32_t this_ptr, int8_tArray val) { LDKChannelAnnouncement this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKSignature val_ref; CHECK(*((uint32_t*)val) == 64); memcpy(val_ref.compact_form, (uint8_t*)(val + 4), 64); ChannelAnnouncement_set_bitcoin_signature_2(&this_ptr_conv, val_ref); } uint32_t __attribute__((visibility("default"))) TS_ChannelAnnouncement_get_contents(uint32_t this_ptr) { LDKChannelAnnouncement this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKUnsignedChannelAnnouncement ret_var = ChannelAnnouncement_get_contents(&this_ptr_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } void __attribute__((visibility("default"))) TS_ChannelAnnouncement_set_contents(uint32_t this_ptr, uint32_t val) { LDKChannelAnnouncement this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKUnsignedChannelAnnouncement val_conv; val_conv.inner = (void*)(val & (~1)); val_conv.is_owned = (val & 1) || (val == 0); val_conv = UnsignedChannelAnnouncement_clone(&val_conv); ChannelAnnouncement_set_contents(&this_ptr_conv, val_conv); } uint32_t __attribute__((visibility("default"))) TS_ChannelAnnouncement_new(int8_tArray node_signature_1_arg, int8_tArray node_signature_2_arg, int8_tArray bitcoin_signature_1_arg, int8_tArray bitcoin_signature_2_arg, uint32_t contents_arg) { LDKSignature node_signature_1_arg_ref; CHECK(*((uint32_t*)node_signature_1_arg) == 64); memcpy(node_signature_1_arg_ref.compact_form, (uint8_t*)(node_signature_1_arg + 4), 64); LDKSignature node_signature_2_arg_ref; CHECK(*((uint32_t*)node_signature_2_arg) == 64); memcpy(node_signature_2_arg_ref.compact_form, (uint8_t*)(node_signature_2_arg + 4), 64); LDKSignature bitcoin_signature_1_arg_ref; CHECK(*((uint32_t*)bitcoin_signature_1_arg) == 64); memcpy(bitcoin_signature_1_arg_ref.compact_form, (uint8_t*)(bitcoin_signature_1_arg + 4), 64); LDKSignature bitcoin_signature_2_arg_ref; CHECK(*((uint32_t*)bitcoin_signature_2_arg) == 64); memcpy(bitcoin_signature_2_arg_ref.compact_form, (uint8_t*)(bitcoin_signature_2_arg + 4), 64); LDKUnsignedChannelAnnouncement contents_arg_conv; contents_arg_conv.inner = (void*)(contents_arg & (~1)); contents_arg_conv.is_owned = (contents_arg & 1) || (contents_arg == 0); contents_arg_conv = UnsignedChannelAnnouncement_clone(&contents_arg_conv); LDKChannelAnnouncement ret_var = ChannelAnnouncement_new(node_signature_1_arg_ref, node_signature_2_arg_ref, bitcoin_signature_1_arg_ref, bitcoin_signature_2_arg_ref, contents_arg_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_ChannelAnnouncement_clone(uint32_t orig) { LDKChannelAnnouncement orig_conv; orig_conv.inner = (void*)(orig & (~1)); orig_conv.is_owned = false; LDKChannelAnnouncement ret_var = ChannelAnnouncement_clone(&orig_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } void __attribute__((visibility("default"))) TS_UnsignedChannelUpdate_free(uint32_t this_obj) { LDKUnsignedChannelUpdate this_obj_conv; this_obj_conv.inner = (void*)(this_obj & (~1)); this_obj_conv.is_owned = (this_obj & 1) || (this_obj == 0); UnsignedChannelUpdate_free(this_obj_conv); } int8_tArray __attribute__((visibility("default"))) TS_UnsignedChannelUpdate_get_chain_hash(uint32_t this_ptr) { LDKUnsignedChannelUpdate this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int8_tArray ret_arr = init_arr(32, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), *UnsignedChannelUpdate_get_chain_hash(&this_ptr_conv), 32); return ret_arr; } void __attribute__((visibility("default"))) TS_UnsignedChannelUpdate_set_chain_hash(uint32_t this_ptr, int8_tArray val) { LDKUnsignedChannelUpdate this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKThirtyTwoBytes val_ref; CHECK(*((uint32_t*)val) == 32); memcpy(val_ref.data, (uint8_t*)(val + 4), 32); UnsignedChannelUpdate_set_chain_hash(&this_ptr_conv, val_ref); } int64_t __attribute__((visibility("default"))) TS_UnsignedChannelUpdate_get_short_channel_id(uint32_t this_ptr) { LDKUnsignedChannelUpdate this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int64_t ret_val = UnsignedChannelUpdate_get_short_channel_id(&this_ptr_conv); return ret_val; } void __attribute__((visibility("default"))) TS_UnsignedChannelUpdate_set_short_channel_id(uint32_t this_ptr, int64_t val) { LDKUnsignedChannelUpdate this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; UnsignedChannelUpdate_set_short_channel_id(&this_ptr_conv, val); } int32_t __attribute__((visibility("default"))) TS_UnsignedChannelUpdate_get_timestamp(uint32_t this_ptr) { LDKUnsignedChannelUpdate this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int32_t ret_val = UnsignedChannelUpdate_get_timestamp(&this_ptr_conv); return ret_val; } void __attribute__((visibility("default"))) TS_UnsignedChannelUpdate_set_timestamp(uint32_t this_ptr, int32_t val) { LDKUnsignedChannelUpdate this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; UnsignedChannelUpdate_set_timestamp(&this_ptr_conv, val); } int8_t __attribute__((visibility("default"))) TS_UnsignedChannelUpdate_get_flags(uint32_t this_ptr) { LDKUnsignedChannelUpdate this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int8_t ret_val = UnsignedChannelUpdate_get_flags(&this_ptr_conv); return ret_val; } void __attribute__((visibility("default"))) TS_UnsignedChannelUpdate_set_flags(uint32_t this_ptr, int8_t val) { LDKUnsignedChannelUpdate this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; UnsignedChannelUpdate_set_flags(&this_ptr_conv, val); } int16_t __attribute__((visibility("default"))) TS_UnsignedChannelUpdate_get_cltv_expiry_delta(uint32_t this_ptr) { LDKUnsignedChannelUpdate this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int16_t ret_val = UnsignedChannelUpdate_get_cltv_expiry_delta(&this_ptr_conv); return ret_val; } void __attribute__((visibility("default"))) TS_UnsignedChannelUpdate_set_cltv_expiry_delta(uint32_t this_ptr, int16_t val) { LDKUnsignedChannelUpdate this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; UnsignedChannelUpdate_set_cltv_expiry_delta(&this_ptr_conv, val); } int64_t __attribute__((visibility("default"))) TS_UnsignedChannelUpdate_get_htlc_minimum_msat(uint32_t this_ptr) { LDKUnsignedChannelUpdate this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int64_t ret_val = UnsignedChannelUpdate_get_htlc_minimum_msat(&this_ptr_conv); return ret_val; } void __attribute__((visibility("default"))) TS_UnsignedChannelUpdate_set_htlc_minimum_msat(uint32_t this_ptr, int64_t val) { LDKUnsignedChannelUpdate this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; UnsignedChannelUpdate_set_htlc_minimum_msat(&this_ptr_conv, val); } int32_t __attribute__((visibility("default"))) TS_UnsignedChannelUpdate_get_fee_base_msat(uint32_t this_ptr) { LDKUnsignedChannelUpdate this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int32_t ret_val = UnsignedChannelUpdate_get_fee_base_msat(&this_ptr_conv); return ret_val; } void __attribute__((visibility("default"))) TS_UnsignedChannelUpdate_set_fee_base_msat(uint32_t this_ptr, int32_t val) { LDKUnsignedChannelUpdate this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; UnsignedChannelUpdate_set_fee_base_msat(&this_ptr_conv, val); } int32_t __attribute__((visibility("default"))) TS_UnsignedChannelUpdate_get_fee_proportional_millionths(uint32_t this_ptr) { LDKUnsignedChannelUpdate this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int32_t ret_val = UnsignedChannelUpdate_get_fee_proportional_millionths(&this_ptr_conv); return ret_val; } void __attribute__((visibility("default"))) TS_UnsignedChannelUpdate_set_fee_proportional_millionths(uint32_t this_ptr, int32_t val) { LDKUnsignedChannelUpdate this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; UnsignedChannelUpdate_set_fee_proportional_millionths(&this_ptr_conv, val); } uint32_t __attribute__((visibility("default"))) TS_UnsignedChannelUpdate_clone(uint32_t orig) { LDKUnsignedChannelUpdate orig_conv; orig_conv.inner = (void*)(orig & (~1)); orig_conv.is_owned = false; LDKUnsignedChannelUpdate ret_var = UnsignedChannelUpdate_clone(&orig_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } void __attribute__((visibility("default"))) TS_ChannelUpdate_free(uint32_t this_obj) { LDKChannelUpdate this_obj_conv; this_obj_conv.inner = (void*)(this_obj & (~1)); this_obj_conv.is_owned = (this_obj & 1) || (this_obj == 0); ChannelUpdate_free(this_obj_conv); } int8_tArray __attribute__((visibility("default"))) TS_ChannelUpdate_get_signature(uint32_t this_ptr) { LDKChannelUpdate this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int8_tArray ret_arr = init_arr(64, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), ChannelUpdate_get_signature(&this_ptr_conv).compact_form, 64); return ret_arr; } void __attribute__((visibility("default"))) TS_ChannelUpdate_set_signature(uint32_t this_ptr, int8_tArray val) { LDKChannelUpdate this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKSignature val_ref; CHECK(*((uint32_t*)val) == 64); memcpy(val_ref.compact_form, (uint8_t*)(val + 4), 64); ChannelUpdate_set_signature(&this_ptr_conv, val_ref); } uint32_t __attribute__((visibility("default"))) TS_ChannelUpdate_get_contents(uint32_t this_ptr) { LDKChannelUpdate this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKUnsignedChannelUpdate ret_var = ChannelUpdate_get_contents(&this_ptr_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } void __attribute__((visibility("default"))) TS_ChannelUpdate_set_contents(uint32_t this_ptr, uint32_t val) { LDKChannelUpdate this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKUnsignedChannelUpdate val_conv; val_conv.inner = (void*)(val & (~1)); val_conv.is_owned = (val & 1) || (val == 0); val_conv = UnsignedChannelUpdate_clone(&val_conv); ChannelUpdate_set_contents(&this_ptr_conv, val_conv); } uint32_t __attribute__((visibility("default"))) TS_ChannelUpdate_new(int8_tArray signature_arg, uint32_t contents_arg) { LDKSignature signature_arg_ref; CHECK(*((uint32_t*)signature_arg) == 64); memcpy(signature_arg_ref.compact_form, (uint8_t*)(signature_arg + 4), 64); LDKUnsignedChannelUpdate contents_arg_conv; contents_arg_conv.inner = (void*)(contents_arg & (~1)); contents_arg_conv.is_owned = (contents_arg & 1) || (contents_arg == 0); contents_arg_conv = UnsignedChannelUpdate_clone(&contents_arg_conv); LDKChannelUpdate ret_var = ChannelUpdate_new(signature_arg_ref, contents_arg_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_ChannelUpdate_clone(uint32_t orig) { LDKChannelUpdate orig_conv; orig_conv.inner = (void*)(orig & (~1)); orig_conv.is_owned = false; LDKChannelUpdate ret_var = ChannelUpdate_clone(&orig_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } void __attribute__((visibility("default"))) TS_QueryChannelRange_free(uint32_t this_obj) { LDKQueryChannelRange this_obj_conv; this_obj_conv.inner = (void*)(this_obj & (~1)); this_obj_conv.is_owned = (this_obj & 1) || (this_obj == 0); QueryChannelRange_free(this_obj_conv); } int8_tArray __attribute__((visibility("default"))) TS_QueryChannelRange_get_chain_hash(uint32_t this_ptr) { LDKQueryChannelRange this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int8_tArray ret_arr = init_arr(32, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), *QueryChannelRange_get_chain_hash(&this_ptr_conv), 32); return ret_arr; } void __attribute__((visibility("default"))) TS_QueryChannelRange_set_chain_hash(uint32_t this_ptr, int8_tArray val) { LDKQueryChannelRange this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKThirtyTwoBytes val_ref; CHECK(*((uint32_t*)val) == 32); memcpy(val_ref.data, (uint8_t*)(val + 4), 32); QueryChannelRange_set_chain_hash(&this_ptr_conv, val_ref); } int32_t __attribute__((visibility("default"))) TS_QueryChannelRange_get_first_blocknum(uint32_t this_ptr) { LDKQueryChannelRange this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int32_t ret_val = QueryChannelRange_get_first_blocknum(&this_ptr_conv); return ret_val; } void __attribute__((visibility("default"))) TS_QueryChannelRange_set_first_blocknum(uint32_t this_ptr, int32_t val) { LDKQueryChannelRange this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; QueryChannelRange_set_first_blocknum(&this_ptr_conv, val); } int32_t __attribute__((visibility("default"))) TS_QueryChannelRange_get_number_of_blocks(uint32_t this_ptr) { LDKQueryChannelRange this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int32_t ret_val = QueryChannelRange_get_number_of_blocks(&this_ptr_conv); return ret_val; } void __attribute__((visibility("default"))) TS_QueryChannelRange_set_number_of_blocks(uint32_t this_ptr, int32_t val) { LDKQueryChannelRange this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; QueryChannelRange_set_number_of_blocks(&this_ptr_conv, val); } uint32_t __attribute__((visibility("default"))) TS_QueryChannelRange_new(int8_tArray chain_hash_arg, int32_t first_blocknum_arg, int32_t number_of_blocks_arg) { LDKThirtyTwoBytes chain_hash_arg_ref; CHECK(*((uint32_t*)chain_hash_arg) == 32); memcpy(chain_hash_arg_ref.data, (uint8_t*)(chain_hash_arg + 4), 32); LDKQueryChannelRange ret_var = QueryChannelRange_new(chain_hash_arg_ref, first_blocknum_arg, number_of_blocks_arg); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_QueryChannelRange_clone(uint32_t orig) { LDKQueryChannelRange orig_conv; orig_conv.inner = (void*)(orig & (~1)); orig_conv.is_owned = false; LDKQueryChannelRange ret_var = QueryChannelRange_clone(&orig_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } void __attribute__((visibility("default"))) TS_ReplyChannelRange_free(uint32_t this_obj) { LDKReplyChannelRange this_obj_conv; this_obj_conv.inner = (void*)(this_obj & (~1)); this_obj_conv.is_owned = (this_obj & 1) || (this_obj == 0); ReplyChannelRange_free(this_obj_conv); } int8_tArray __attribute__((visibility("default"))) TS_ReplyChannelRange_get_chain_hash(uint32_t this_ptr) { LDKReplyChannelRange this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int8_tArray ret_arr = init_arr(32, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), *ReplyChannelRange_get_chain_hash(&this_ptr_conv), 32); return ret_arr; } void __attribute__((visibility("default"))) TS_ReplyChannelRange_set_chain_hash(uint32_t this_ptr, int8_tArray val) { LDKReplyChannelRange this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKThirtyTwoBytes val_ref; CHECK(*((uint32_t*)val) == 32); memcpy(val_ref.data, (uint8_t*)(val + 4), 32); ReplyChannelRange_set_chain_hash(&this_ptr_conv, val_ref); } int32_t __attribute__((visibility("default"))) TS_ReplyChannelRange_get_first_blocknum(uint32_t this_ptr) { LDKReplyChannelRange this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int32_t ret_val = ReplyChannelRange_get_first_blocknum(&this_ptr_conv); return ret_val; } void __attribute__((visibility("default"))) TS_ReplyChannelRange_set_first_blocknum(uint32_t this_ptr, int32_t val) { LDKReplyChannelRange this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; ReplyChannelRange_set_first_blocknum(&this_ptr_conv, val); } int32_t __attribute__((visibility("default"))) TS_ReplyChannelRange_get_number_of_blocks(uint32_t this_ptr) { LDKReplyChannelRange this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int32_t ret_val = ReplyChannelRange_get_number_of_blocks(&this_ptr_conv); return ret_val; } void __attribute__((visibility("default"))) TS_ReplyChannelRange_set_number_of_blocks(uint32_t this_ptr, int32_t val) { LDKReplyChannelRange this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; ReplyChannelRange_set_number_of_blocks(&this_ptr_conv, val); } jboolean __attribute__((visibility("default"))) TS_ReplyChannelRange_get_sync_complete(uint32_t this_ptr) { LDKReplyChannelRange this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; jboolean ret_val = ReplyChannelRange_get_sync_complete(&this_ptr_conv); return ret_val; } void __attribute__((visibility("default"))) TS_ReplyChannelRange_set_sync_complete(uint32_t this_ptr, jboolean val) { LDKReplyChannelRange this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; ReplyChannelRange_set_sync_complete(&this_ptr_conv, val); } void __attribute__((visibility("default"))) TS_ReplyChannelRange_set_short_channel_ids(uint32_t this_ptr, int64_tArray val) { LDKReplyChannelRange this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKCVec_u64Z val_constr; val_constr.datalen = *((uint32_t*)val); if (val_constr.datalen > 0) val_constr.data = MALLOC(val_constr.datalen * sizeof(int64_t), "LDKCVec_u64Z Elements"); else val_constr.data = NULL; int64_t* val_vals = (int64_t*)(val + 4); for (size_t i = 0; i < val_constr.datalen; i++) { int64_t val_conv_8 = val_vals[i]; val_constr.data[i] = val_conv_8; } ReplyChannelRange_set_short_channel_ids(&this_ptr_conv, val_constr); } uint32_t __attribute__((visibility("default"))) TS_ReplyChannelRange_new(int8_tArray chain_hash_arg, int32_t first_blocknum_arg, int32_t number_of_blocks_arg, jboolean sync_complete_arg, int64_tArray short_channel_ids_arg) { LDKThirtyTwoBytes chain_hash_arg_ref; CHECK(*((uint32_t*)chain_hash_arg) == 32); memcpy(chain_hash_arg_ref.data, (uint8_t*)(chain_hash_arg + 4), 32); LDKCVec_u64Z short_channel_ids_arg_constr; short_channel_ids_arg_constr.datalen = *((uint32_t*)short_channel_ids_arg); if (short_channel_ids_arg_constr.datalen > 0) short_channel_ids_arg_constr.data = MALLOC(short_channel_ids_arg_constr.datalen * sizeof(int64_t), "LDKCVec_u64Z Elements"); else short_channel_ids_arg_constr.data = NULL; int64_t* short_channel_ids_arg_vals = (int64_t*)(short_channel_ids_arg + 4); for (size_t i = 0; i < short_channel_ids_arg_constr.datalen; i++) { int64_t short_channel_ids_arg_conv_8 = short_channel_ids_arg_vals[i]; short_channel_ids_arg_constr.data[i] = short_channel_ids_arg_conv_8; } LDKReplyChannelRange ret_var = ReplyChannelRange_new(chain_hash_arg_ref, first_blocknum_arg, number_of_blocks_arg, sync_complete_arg, short_channel_ids_arg_constr); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_ReplyChannelRange_clone(uint32_t orig) { LDKReplyChannelRange orig_conv; orig_conv.inner = (void*)(orig & (~1)); orig_conv.is_owned = false; LDKReplyChannelRange ret_var = ReplyChannelRange_clone(&orig_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } void __attribute__((visibility("default"))) TS_QueryShortChannelIds_free(uint32_t this_obj) { LDKQueryShortChannelIds this_obj_conv; this_obj_conv.inner = (void*)(this_obj & (~1)); this_obj_conv.is_owned = (this_obj & 1) || (this_obj == 0); QueryShortChannelIds_free(this_obj_conv); } int8_tArray __attribute__((visibility("default"))) TS_QueryShortChannelIds_get_chain_hash(uint32_t this_ptr) { LDKQueryShortChannelIds this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int8_tArray ret_arr = init_arr(32, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), *QueryShortChannelIds_get_chain_hash(&this_ptr_conv), 32); return ret_arr; } void __attribute__((visibility("default"))) TS_QueryShortChannelIds_set_chain_hash(uint32_t this_ptr, int8_tArray val) { LDKQueryShortChannelIds this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKThirtyTwoBytes val_ref; CHECK(*((uint32_t*)val) == 32); memcpy(val_ref.data, (uint8_t*)(val + 4), 32); QueryShortChannelIds_set_chain_hash(&this_ptr_conv, val_ref); } void __attribute__((visibility("default"))) TS_QueryShortChannelIds_set_short_channel_ids(uint32_t this_ptr, int64_tArray val) { LDKQueryShortChannelIds this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKCVec_u64Z val_constr; val_constr.datalen = *((uint32_t*)val); if (val_constr.datalen > 0) val_constr.data = MALLOC(val_constr.datalen * sizeof(int64_t), "LDKCVec_u64Z Elements"); else val_constr.data = NULL; int64_t* val_vals = (int64_t*)(val + 4); for (size_t i = 0; i < val_constr.datalen; i++) { int64_t val_conv_8 = val_vals[i]; val_constr.data[i] = val_conv_8; } QueryShortChannelIds_set_short_channel_ids(&this_ptr_conv, val_constr); } uint32_t __attribute__((visibility("default"))) TS_QueryShortChannelIds_new(int8_tArray chain_hash_arg, int64_tArray short_channel_ids_arg) { LDKThirtyTwoBytes chain_hash_arg_ref; CHECK(*((uint32_t*)chain_hash_arg) == 32); memcpy(chain_hash_arg_ref.data, (uint8_t*)(chain_hash_arg + 4), 32); LDKCVec_u64Z short_channel_ids_arg_constr; short_channel_ids_arg_constr.datalen = *((uint32_t*)short_channel_ids_arg); if (short_channel_ids_arg_constr.datalen > 0) short_channel_ids_arg_constr.data = MALLOC(short_channel_ids_arg_constr.datalen * sizeof(int64_t), "LDKCVec_u64Z Elements"); else short_channel_ids_arg_constr.data = NULL; int64_t* short_channel_ids_arg_vals = (int64_t*)(short_channel_ids_arg + 4); for (size_t i = 0; i < short_channel_ids_arg_constr.datalen; i++) { int64_t short_channel_ids_arg_conv_8 = short_channel_ids_arg_vals[i]; short_channel_ids_arg_constr.data[i] = short_channel_ids_arg_conv_8; } LDKQueryShortChannelIds ret_var = QueryShortChannelIds_new(chain_hash_arg_ref, short_channel_ids_arg_constr); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_QueryShortChannelIds_clone(uint32_t orig) { LDKQueryShortChannelIds orig_conv; orig_conv.inner = (void*)(orig & (~1)); orig_conv.is_owned = false; LDKQueryShortChannelIds ret_var = QueryShortChannelIds_clone(&orig_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } void __attribute__((visibility("default"))) TS_ReplyShortChannelIdsEnd_free(uint32_t this_obj) { LDKReplyShortChannelIdsEnd this_obj_conv; this_obj_conv.inner = (void*)(this_obj & (~1)); this_obj_conv.is_owned = (this_obj & 1) || (this_obj == 0); ReplyShortChannelIdsEnd_free(this_obj_conv); } int8_tArray __attribute__((visibility("default"))) TS_ReplyShortChannelIdsEnd_get_chain_hash(uint32_t this_ptr) { LDKReplyShortChannelIdsEnd this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int8_tArray ret_arr = init_arr(32, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), *ReplyShortChannelIdsEnd_get_chain_hash(&this_ptr_conv), 32); return ret_arr; } void __attribute__((visibility("default"))) TS_ReplyShortChannelIdsEnd_set_chain_hash(uint32_t this_ptr, int8_tArray val) { LDKReplyShortChannelIdsEnd this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKThirtyTwoBytes val_ref; CHECK(*((uint32_t*)val) == 32); memcpy(val_ref.data, (uint8_t*)(val + 4), 32); ReplyShortChannelIdsEnd_set_chain_hash(&this_ptr_conv, val_ref); } jboolean __attribute__((visibility("default"))) TS_ReplyShortChannelIdsEnd_get_full_information(uint32_t this_ptr) { LDKReplyShortChannelIdsEnd this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; jboolean ret_val = ReplyShortChannelIdsEnd_get_full_information(&this_ptr_conv); return ret_val; } void __attribute__((visibility("default"))) TS_ReplyShortChannelIdsEnd_set_full_information(uint32_t this_ptr, jboolean val) { LDKReplyShortChannelIdsEnd this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; ReplyShortChannelIdsEnd_set_full_information(&this_ptr_conv, val); } uint32_t __attribute__((visibility("default"))) TS_ReplyShortChannelIdsEnd_new(int8_tArray chain_hash_arg, jboolean full_information_arg) { LDKThirtyTwoBytes chain_hash_arg_ref; CHECK(*((uint32_t*)chain_hash_arg) == 32); memcpy(chain_hash_arg_ref.data, (uint8_t*)(chain_hash_arg + 4), 32); LDKReplyShortChannelIdsEnd ret_var = ReplyShortChannelIdsEnd_new(chain_hash_arg_ref, full_information_arg); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_ReplyShortChannelIdsEnd_clone(uint32_t orig) { LDKReplyShortChannelIdsEnd orig_conv; orig_conv.inner = (void*)(orig & (~1)); orig_conv.is_owned = false; LDKReplyShortChannelIdsEnd ret_var = ReplyShortChannelIdsEnd_clone(&orig_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } void __attribute__((visibility("default"))) TS_GossipTimestampFilter_free(uint32_t this_obj) { LDKGossipTimestampFilter this_obj_conv; this_obj_conv.inner = (void*)(this_obj & (~1)); this_obj_conv.is_owned = (this_obj & 1) || (this_obj == 0); GossipTimestampFilter_free(this_obj_conv); } int8_tArray __attribute__((visibility("default"))) TS_GossipTimestampFilter_get_chain_hash(uint32_t this_ptr) { LDKGossipTimestampFilter this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int8_tArray ret_arr = init_arr(32, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), *GossipTimestampFilter_get_chain_hash(&this_ptr_conv), 32); return ret_arr; } void __attribute__((visibility("default"))) TS_GossipTimestampFilter_set_chain_hash(uint32_t this_ptr, int8_tArray val) { LDKGossipTimestampFilter this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKThirtyTwoBytes val_ref; CHECK(*((uint32_t*)val) == 32); memcpy(val_ref.data, (uint8_t*)(val + 4), 32); GossipTimestampFilter_set_chain_hash(&this_ptr_conv, val_ref); } int32_t __attribute__((visibility("default"))) TS_GossipTimestampFilter_get_first_timestamp(uint32_t this_ptr) { LDKGossipTimestampFilter this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int32_t ret_val = GossipTimestampFilter_get_first_timestamp(&this_ptr_conv); return ret_val; } void __attribute__((visibility("default"))) TS_GossipTimestampFilter_set_first_timestamp(uint32_t this_ptr, int32_t val) { LDKGossipTimestampFilter this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; GossipTimestampFilter_set_first_timestamp(&this_ptr_conv, val); } int32_t __attribute__((visibility("default"))) TS_GossipTimestampFilter_get_timestamp_range(uint32_t this_ptr) { LDKGossipTimestampFilter this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int32_t ret_val = GossipTimestampFilter_get_timestamp_range(&this_ptr_conv); return ret_val; } void __attribute__((visibility("default"))) TS_GossipTimestampFilter_set_timestamp_range(uint32_t this_ptr, int32_t val) { LDKGossipTimestampFilter this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; GossipTimestampFilter_set_timestamp_range(&this_ptr_conv, val); } uint32_t __attribute__((visibility("default"))) TS_GossipTimestampFilter_new(int8_tArray chain_hash_arg, int32_t first_timestamp_arg, int32_t timestamp_range_arg) { LDKThirtyTwoBytes chain_hash_arg_ref; CHECK(*((uint32_t*)chain_hash_arg) == 32); memcpy(chain_hash_arg_ref.data, (uint8_t*)(chain_hash_arg + 4), 32); LDKGossipTimestampFilter ret_var = GossipTimestampFilter_new(chain_hash_arg_ref, first_timestamp_arg, timestamp_range_arg); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_GossipTimestampFilter_clone(uint32_t orig) { LDKGossipTimestampFilter orig_conv; orig_conv.inner = (void*)(orig & (~1)); orig_conv.is_owned = false; LDKGossipTimestampFilter ret_var = GossipTimestampFilter_clone(&orig_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } void __attribute__((visibility("default"))) TS_ErrorAction_free(uint32_t this_ptr) { if ((this_ptr & 1) != 0) return; LDKErrorAction this_ptr_conv = *(LDKErrorAction*)(((uint64_t)this_ptr) & ~1); FREE((void*)this_ptr); ErrorAction_free(this_ptr_conv); } uint32_t __attribute__((visibility("default"))) TS_ErrorAction_clone(uint32_t orig) { LDKErrorAction* orig_conv = (LDKErrorAction*)orig; LDKErrorAction *ret_copy = MALLOC(sizeof(LDKErrorAction), "LDKErrorAction"); *ret_copy = ErrorAction_clone(orig_conv); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_ErrorAction_disconnect_peer(uint32_t msg) { LDKErrorMessage msg_conv; msg_conv.inner = (void*)(msg & (~1)); msg_conv.is_owned = (msg & 1) || (msg == 0); msg_conv = ErrorMessage_clone(&msg_conv); LDKErrorAction *ret_copy = MALLOC(sizeof(LDKErrorAction), "LDKErrorAction"); *ret_copy = ErrorAction_disconnect_peer(msg_conv); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_ErrorAction_ignore_error() { LDKErrorAction *ret_copy = MALLOC(sizeof(LDKErrorAction), "LDKErrorAction"); *ret_copy = ErrorAction_ignore_error(); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_ErrorAction_ignore_and_log(uint32_t a) { LDKLevel a_conv = LDKLevel_from_js(a); LDKErrorAction *ret_copy = MALLOC(sizeof(LDKErrorAction), "LDKErrorAction"); *ret_copy = ErrorAction_ignore_and_log(a_conv); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_ErrorAction_send_error_message(uint32_t msg) { LDKErrorMessage msg_conv; msg_conv.inner = (void*)(msg & (~1)); msg_conv.is_owned = (msg & 1) || (msg == 0); msg_conv = ErrorMessage_clone(&msg_conv); LDKErrorAction *ret_copy = MALLOC(sizeof(LDKErrorAction), "LDKErrorAction"); *ret_copy = ErrorAction_send_error_message(msg_conv); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } void __attribute__((visibility("default"))) TS_LightningError_free(uint32_t this_obj) { LDKLightningError this_obj_conv; this_obj_conv.inner = (void*)(this_obj & (~1)); this_obj_conv.is_owned = (this_obj & 1) || (this_obj == 0); LightningError_free(this_obj_conv); } jstring __attribute__((visibility("default"))) TS_LightningError_get_err(uint32_t this_ptr) { LDKLightningError this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKStr ret_str = LightningError_get_err(&this_ptr_conv); jstring ret_conv = str_ref_to_ts(ret_str.chars, ret_str.len); Str_free(ret_str); return ret_conv; } void __attribute__((visibility("default"))) TS_LightningError_set_err(uint32_t this_ptr, jstring val) { LDKLightningError this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKStr val_conv = str_ref_to_owned_c(val); LightningError_set_err(&this_ptr_conv, val_conv); } uint32_t __attribute__((visibility("default"))) TS_LightningError_get_action(uint32_t this_ptr) { LDKLightningError this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKErrorAction *ret_copy = MALLOC(sizeof(LDKErrorAction), "LDKErrorAction"); *ret_copy = LightningError_get_action(&this_ptr_conv); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } void __attribute__((visibility("default"))) TS_LightningError_set_action(uint32_t this_ptr, uint32_t val) { LDKLightningError this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKErrorAction val_conv = *(LDKErrorAction*)(((uint64_t)val) & ~1); val_conv = ErrorAction_clone((LDKErrorAction*)(((uint64_t)val) & ~1)); LightningError_set_action(&this_ptr_conv, val_conv); } uint32_t __attribute__((visibility("default"))) TS_LightningError_new(jstring err_arg, uint32_t action_arg) { LDKStr err_arg_conv = str_ref_to_owned_c(err_arg); LDKErrorAction action_arg_conv = *(LDKErrorAction*)(((uint64_t)action_arg) & ~1); action_arg_conv = ErrorAction_clone((LDKErrorAction*)(((uint64_t)action_arg) & ~1)); LDKLightningError ret_var = LightningError_new(err_arg_conv, action_arg_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_LightningError_clone(uint32_t orig) { LDKLightningError orig_conv; orig_conv.inner = (void*)(orig & (~1)); orig_conv.is_owned = false; LDKLightningError ret_var = LightningError_clone(&orig_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } void __attribute__((visibility("default"))) TS_CommitmentUpdate_free(uint32_t this_obj) { LDKCommitmentUpdate this_obj_conv; this_obj_conv.inner = (void*)(this_obj & (~1)); this_obj_conv.is_owned = (this_obj & 1) || (this_obj == 0); CommitmentUpdate_free(this_obj_conv); } uint32_tArray __attribute__((visibility("default"))) TS_CommitmentUpdate_get_update_add_htlcs(uint32_t this_ptr) { LDKCommitmentUpdate this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKCVec_UpdateAddHTLCZ ret_var = CommitmentUpdate_get_update_add_htlcs(&this_ptr_conv); uint32_tArray ret_arr = init_arr(ret_var.datalen, sizeof(uint32_t), "Native uint32_tArray Bytes"); uint32_t *ret_arr_ptr = (uint32_t*)(ret_arr + 4); for (size_t p = 0; p < ret_var.datalen; p++) { LDKUpdateAddHTLC ret_conv_15_var = ret_var.data[p]; CHECK((((uint64_t)ret_conv_15_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_conv_15_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_conv_15_ref = (uint64_t)ret_conv_15_var.inner; if (ret_conv_15_var.is_owned) { ret_conv_15_ref |= 1; } ret_arr_ptr[p] = ret_conv_15_ref; } FREE(ret_var.data); return ret_arr; } void __attribute__((visibility("default"))) TS_CommitmentUpdate_set_update_add_htlcs(uint32_t this_ptr, uint32_tArray val) { LDKCommitmentUpdate this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKCVec_UpdateAddHTLCZ val_constr; val_constr.datalen = *((uint32_t*)val); if (val_constr.datalen > 0) val_constr.data = MALLOC(val_constr.datalen * sizeof(LDKUpdateAddHTLC), "LDKCVec_UpdateAddHTLCZ Elements"); else val_constr.data = NULL; uint32_t* val_vals = (uint32_t*)(val + 4); for (size_t p = 0; p < val_constr.datalen; p++) { uint32_t val_conv_15 = val_vals[p]; LDKUpdateAddHTLC val_conv_15_conv; val_conv_15_conv.inner = (void*)(val_conv_15 & (~1)); val_conv_15_conv.is_owned = (val_conv_15 & 1) || (val_conv_15 == 0); val_conv_15_conv = UpdateAddHTLC_clone(&val_conv_15_conv); val_constr.data[p] = val_conv_15_conv; } CommitmentUpdate_set_update_add_htlcs(&this_ptr_conv, val_constr); } uint32_tArray __attribute__((visibility("default"))) TS_CommitmentUpdate_get_update_fulfill_htlcs(uint32_t this_ptr) { LDKCommitmentUpdate this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKCVec_UpdateFulfillHTLCZ ret_var = CommitmentUpdate_get_update_fulfill_htlcs(&this_ptr_conv); uint32_tArray ret_arr = init_arr(ret_var.datalen, sizeof(uint32_t), "Native uint32_tArray Bytes"); uint32_t *ret_arr_ptr = (uint32_t*)(ret_arr + 4); for (size_t t = 0; t < ret_var.datalen; t++) { LDKUpdateFulfillHTLC ret_conv_19_var = ret_var.data[t]; CHECK((((uint64_t)ret_conv_19_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_conv_19_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_conv_19_ref = (uint64_t)ret_conv_19_var.inner; if (ret_conv_19_var.is_owned) { ret_conv_19_ref |= 1; } ret_arr_ptr[t] = ret_conv_19_ref; } FREE(ret_var.data); return ret_arr; } void __attribute__((visibility("default"))) TS_CommitmentUpdate_set_update_fulfill_htlcs(uint32_t this_ptr, uint32_tArray val) { LDKCommitmentUpdate this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKCVec_UpdateFulfillHTLCZ val_constr; val_constr.datalen = *((uint32_t*)val); if (val_constr.datalen > 0) val_constr.data = MALLOC(val_constr.datalen * sizeof(LDKUpdateFulfillHTLC), "LDKCVec_UpdateFulfillHTLCZ Elements"); else val_constr.data = NULL; uint32_t* val_vals = (uint32_t*)(val + 4); for (size_t t = 0; t < val_constr.datalen; t++) { uint32_t val_conv_19 = val_vals[t]; LDKUpdateFulfillHTLC val_conv_19_conv; val_conv_19_conv.inner = (void*)(val_conv_19 & (~1)); val_conv_19_conv.is_owned = (val_conv_19 & 1) || (val_conv_19 == 0); val_conv_19_conv = UpdateFulfillHTLC_clone(&val_conv_19_conv); val_constr.data[t] = val_conv_19_conv; } CommitmentUpdate_set_update_fulfill_htlcs(&this_ptr_conv, val_constr); } uint32_tArray __attribute__((visibility("default"))) TS_CommitmentUpdate_get_update_fail_htlcs(uint32_t this_ptr) { LDKCommitmentUpdate this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKCVec_UpdateFailHTLCZ ret_var = CommitmentUpdate_get_update_fail_htlcs(&this_ptr_conv); uint32_tArray ret_arr = init_arr(ret_var.datalen, sizeof(uint32_t), "Native uint32_tArray Bytes"); uint32_t *ret_arr_ptr = (uint32_t*)(ret_arr + 4); for (size_t q = 0; q < ret_var.datalen; q++) { LDKUpdateFailHTLC ret_conv_16_var = ret_var.data[q]; CHECK((((uint64_t)ret_conv_16_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_conv_16_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_conv_16_ref = (uint64_t)ret_conv_16_var.inner; if (ret_conv_16_var.is_owned) { ret_conv_16_ref |= 1; } ret_arr_ptr[q] = ret_conv_16_ref; } FREE(ret_var.data); return ret_arr; } void __attribute__((visibility("default"))) TS_CommitmentUpdate_set_update_fail_htlcs(uint32_t this_ptr, uint32_tArray val) { LDKCommitmentUpdate this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKCVec_UpdateFailHTLCZ val_constr; val_constr.datalen = *((uint32_t*)val); if (val_constr.datalen > 0) val_constr.data = MALLOC(val_constr.datalen * sizeof(LDKUpdateFailHTLC), "LDKCVec_UpdateFailHTLCZ Elements"); else val_constr.data = NULL; uint32_t* val_vals = (uint32_t*)(val + 4); for (size_t q = 0; q < val_constr.datalen; q++) { uint32_t val_conv_16 = val_vals[q]; LDKUpdateFailHTLC val_conv_16_conv; val_conv_16_conv.inner = (void*)(val_conv_16 & (~1)); val_conv_16_conv.is_owned = (val_conv_16 & 1) || (val_conv_16 == 0); val_conv_16_conv = UpdateFailHTLC_clone(&val_conv_16_conv); val_constr.data[q] = val_conv_16_conv; } CommitmentUpdate_set_update_fail_htlcs(&this_ptr_conv, val_constr); } uint32_tArray __attribute__((visibility("default"))) TS_CommitmentUpdate_get_update_fail_malformed_htlcs(uint32_t this_ptr) { LDKCommitmentUpdate this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKCVec_UpdateFailMalformedHTLCZ ret_var = CommitmentUpdate_get_update_fail_malformed_htlcs(&this_ptr_conv); uint32_tArray ret_arr = init_arr(ret_var.datalen, sizeof(uint32_t), "Native uint32_tArray Bytes"); uint32_t *ret_arr_ptr = (uint32_t*)(ret_arr + 4); for (size_t z = 0; z < ret_var.datalen; z++) { LDKUpdateFailMalformedHTLC ret_conv_25_var = ret_var.data[z]; CHECK((((uint64_t)ret_conv_25_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_conv_25_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_conv_25_ref = (uint64_t)ret_conv_25_var.inner; if (ret_conv_25_var.is_owned) { ret_conv_25_ref |= 1; } ret_arr_ptr[z] = ret_conv_25_ref; } FREE(ret_var.data); return ret_arr; } void __attribute__((visibility("default"))) TS_CommitmentUpdate_set_update_fail_malformed_htlcs(uint32_t this_ptr, uint32_tArray val) { LDKCommitmentUpdate this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKCVec_UpdateFailMalformedHTLCZ val_constr; val_constr.datalen = *((uint32_t*)val); if (val_constr.datalen > 0) val_constr.data = MALLOC(val_constr.datalen * sizeof(LDKUpdateFailMalformedHTLC), "LDKCVec_UpdateFailMalformedHTLCZ Elements"); else val_constr.data = NULL; uint32_t* val_vals = (uint32_t*)(val + 4); for (size_t z = 0; z < val_constr.datalen; z++) { uint32_t val_conv_25 = val_vals[z]; LDKUpdateFailMalformedHTLC val_conv_25_conv; val_conv_25_conv.inner = (void*)(val_conv_25 & (~1)); val_conv_25_conv.is_owned = (val_conv_25 & 1) || (val_conv_25 == 0); val_conv_25_conv = UpdateFailMalformedHTLC_clone(&val_conv_25_conv); val_constr.data[z] = val_conv_25_conv; } CommitmentUpdate_set_update_fail_malformed_htlcs(&this_ptr_conv, val_constr); } uint32_t __attribute__((visibility("default"))) TS_CommitmentUpdate_get_update_fee(uint32_t this_ptr) { LDKCommitmentUpdate this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKUpdateFee ret_var = CommitmentUpdate_get_update_fee(&this_ptr_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } void __attribute__((visibility("default"))) TS_CommitmentUpdate_set_update_fee(uint32_t this_ptr, uint32_t val) { LDKCommitmentUpdate this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKUpdateFee val_conv; val_conv.inner = (void*)(val & (~1)); val_conv.is_owned = (val & 1) || (val == 0); val_conv = UpdateFee_clone(&val_conv); CommitmentUpdate_set_update_fee(&this_ptr_conv, val_conv); } uint32_t __attribute__((visibility("default"))) TS_CommitmentUpdate_get_commitment_signed(uint32_t this_ptr) { LDKCommitmentUpdate this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKCommitmentSigned ret_var = CommitmentUpdate_get_commitment_signed(&this_ptr_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } void __attribute__((visibility("default"))) TS_CommitmentUpdate_set_commitment_signed(uint32_t this_ptr, uint32_t val) { LDKCommitmentUpdate this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKCommitmentSigned val_conv; val_conv.inner = (void*)(val & (~1)); val_conv.is_owned = (val & 1) || (val == 0); val_conv = CommitmentSigned_clone(&val_conv); CommitmentUpdate_set_commitment_signed(&this_ptr_conv, val_conv); } uint32_t __attribute__((visibility("default"))) TS_CommitmentUpdate_new(uint32_tArray update_add_htlcs_arg, uint32_tArray update_fulfill_htlcs_arg, uint32_tArray update_fail_htlcs_arg, uint32_tArray update_fail_malformed_htlcs_arg, uint32_t update_fee_arg, uint32_t commitment_signed_arg) { LDKCVec_UpdateAddHTLCZ update_add_htlcs_arg_constr; update_add_htlcs_arg_constr.datalen = *((uint32_t*)update_add_htlcs_arg); if (update_add_htlcs_arg_constr.datalen > 0) update_add_htlcs_arg_constr.data = MALLOC(update_add_htlcs_arg_constr.datalen * sizeof(LDKUpdateAddHTLC), "LDKCVec_UpdateAddHTLCZ Elements"); else update_add_htlcs_arg_constr.data = NULL; uint32_t* update_add_htlcs_arg_vals = (uint32_t*)(update_add_htlcs_arg + 4); for (size_t p = 0; p < update_add_htlcs_arg_constr.datalen; p++) { uint32_t update_add_htlcs_arg_conv_15 = update_add_htlcs_arg_vals[p]; LDKUpdateAddHTLC update_add_htlcs_arg_conv_15_conv; update_add_htlcs_arg_conv_15_conv.inner = (void*)(update_add_htlcs_arg_conv_15 & (~1)); update_add_htlcs_arg_conv_15_conv.is_owned = (update_add_htlcs_arg_conv_15 & 1) || (update_add_htlcs_arg_conv_15 == 0); update_add_htlcs_arg_conv_15_conv = UpdateAddHTLC_clone(&update_add_htlcs_arg_conv_15_conv); update_add_htlcs_arg_constr.data[p] = update_add_htlcs_arg_conv_15_conv; } LDKCVec_UpdateFulfillHTLCZ update_fulfill_htlcs_arg_constr; update_fulfill_htlcs_arg_constr.datalen = *((uint32_t*)update_fulfill_htlcs_arg); if (update_fulfill_htlcs_arg_constr.datalen > 0) update_fulfill_htlcs_arg_constr.data = MALLOC(update_fulfill_htlcs_arg_constr.datalen * sizeof(LDKUpdateFulfillHTLC), "LDKCVec_UpdateFulfillHTLCZ Elements"); else update_fulfill_htlcs_arg_constr.data = NULL; uint32_t* update_fulfill_htlcs_arg_vals = (uint32_t*)(update_fulfill_htlcs_arg + 4); for (size_t t = 0; t < update_fulfill_htlcs_arg_constr.datalen; t++) { uint32_t update_fulfill_htlcs_arg_conv_19 = update_fulfill_htlcs_arg_vals[t]; LDKUpdateFulfillHTLC update_fulfill_htlcs_arg_conv_19_conv; update_fulfill_htlcs_arg_conv_19_conv.inner = (void*)(update_fulfill_htlcs_arg_conv_19 & (~1)); update_fulfill_htlcs_arg_conv_19_conv.is_owned = (update_fulfill_htlcs_arg_conv_19 & 1) || (update_fulfill_htlcs_arg_conv_19 == 0); update_fulfill_htlcs_arg_conv_19_conv = UpdateFulfillHTLC_clone(&update_fulfill_htlcs_arg_conv_19_conv); update_fulfill_htlcs_arg_constr.data[t] = update_fulfill_htlcs_arg_conv_19_conv; } LDKCVec_UpdateFailHTLCZ update_fail_htlcs_arg_constr; update_fail_htlcs_arg_constr.datalen = *((uint32_t*)update_fail_htlcs_arg); if (update_fail_htlcs_arg_constr.datalen > 0) update_fail_htlcs_arg_constr.data = MALLOC(update_fail_htlcs_arg_constr.datalen * sizeof(LDKUpdateFailHTLC), "LDKCVec_UpdateFailHTLCZ Elements"); else update_fail_htlcs_arg_constr.data = NULL; uint32_t* update_fail_htlcs_arg_vals = (uint32_t*)(update_fail_htlcs_arg + 4); for (size_t q = 0; q < update_fail_htlcs_arg_constr.datalen; q++) { uint32_t update_fail_htlcs_arg_conv_16 = update_fail_htlcs_arg_vals[q]; LDKUpdateFailHTLC update_fail_htlcs_arg_conv_16_conv; update_fail_htlcs_arg_conv_16_conv.inner = (void*)(update_fail_htlcs_arg_conv_16 & (~1)); update_fail_htlcs_arg_conv_16_conv.is_owned = (update_fail_htlcs_arg_conv_16 & 1) || (update_fail_htlcs_arg_conv_16 == 0); update_fail_htlcs_arg_conv_16_conv = UpdateFailHTLC_clone(&update_fail_htlcs_arg_conv_16_conv); update_fail_htlcs_arg_constr.data[q] = update_fail_htlcs_arg_conv_16_conv; } LDKCVec_UpdateFailMalformedHTLCZ update_fail_malformed_htlcs_arg_constr; update_fail_malformed_htlcs_arg_constr.datalen = *((uint32_t*)update_fail_malformed_htlcs_arg); if (update_fail_malformed_htlcs_arg_constr.datalen > 0) update_fail_malformed_htlcs_arg_constr.data = MALLOC(update_fail_malformed_htlcs_arg_constr.datalen * sizeof(LDKUpdateFailMalformedHTLC), "LDKCVec_UpdateFailMalformedHTLCZ Elements"); else update_fail_malformed_htlcs_arg_constr.data = NULL; uint32_t* update_fail_malformed_htlcs_arg_vals = (uint32_t*)(update_fail_malformed_htlcs_arg + 4); for (size_t z = 0; z < update_fail_malformed_htlcs_arg_constr.datalen; z++) { uint32_t update_fail_malformed_htlcs_arg_conv_25 = update_fail_malformed_htlcs_arg_vals[z]; LDKUpdateFailMalformedHTLC update_fail_malformed_htlcs_arg_conv_25_conv; update_fail_malformed_htlcs_arg_conv_25_conv.inner = (void*)(update_fail_malformed_htlcs_arg_conv_25 & (~1)); update_fail_malformed_htlcs_arg_conv_25_conv.is_owned = (update_fail_malformed_htlcs_arg_conv_25 & 1) || (update_fail_malformed_htlcs_arg_conv_25 == 0); update_fail_malformed_htlcs_arg_conv_25_conv = UpdateFailMalformedHTLC_clone(&update_fail_malformed_htlcs_arg_conv_25_conv); update_fail_malformed_htlcs_arg_constr.data[z] = update_fail_malformed_htlcs_arg_conv_25_conv; } LDKUpdateFee update_fee_arg_conv; update_fee_arg_conv.inner = (void*)(update_fee_arg & (~1)); update_fee_arg_conv.is_owned = (update_fee_arg & 1) || (update_fee_arg == 0); update_fee_arg_conv = UpdateFee_clone(&update_fee_arg_conv); LDKCommitmentSigned commitment_signed_arg_conv; commitment_signed_arg_conv.inner = (void*)(commitment_signed_arg & (~1)); commitment_signed_arg_conv.is_owned = (commitment_signed_arg & 1) || (commitment_signed_arg == 0); commitment_signed_arg_conv = CommitmentSigned_clone(&commitment_signed_arg_conv); LDKCommitmentUpdate ret_var = CommitmentUpdate_new(update_add_htlcs_arg_constr, update_fulfill_htlcs_arg_constr, update_fail_htlcs_arg_constr, update_fail_malformed_htlcs_arg_constr, update_fee_arg_conv, commitment_signed_arg_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_CommitmentUpdate_clone(uint32_t orig) { LDKCommitmentUpdate orig_conv; orig_conv.inner = (void*)(orig & (~1)); orig_conv.is_owned = false; LDKCommitmentUpdate ret_var = CommitmentUpdate_clone(&orig_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } void __attribute__((visibility("default"))) TS_ChannelMessageHandler_free(uint32_t this_ptr) { if ((this_ptr & 1) != 0) return; LDKChannelMessageHandler this_ptr_conv = *(LDKChannelMessageHandler*)(((uint64_t)this_ptr) & ~1); FREE((void*)this_ptr); ChannelMessageHandler_free(this_ptr_conv); } void __attribute__((visibility("default"))) TS_RoutingMessageHandler_free(uint32_t this_ptr) { if ((this_ptr & 1) != 0) return; LDKRoutingMessageHandler this_ptr_conv = *(LDKRoutingMessageHandler*)(((uint64_t)this_ptr) & ~1); FREE((void*)this_ptr); RoutingMessageHandler_free(this_ptr_conv); } int8_tArray __attribute__((visibility("default"))) TS_AcceptChannel_write(uint32_t obj) { LDKAcceptChannel obj_conv; obj_conv.inner = (void*)(obj & (~1)); obj_conv.is_owned = false; LDKCVec_u8Z ret_var = AcceptChannel_write(&obj_conv); int8_tArray ret_arr = init_arr(ret_var.datalen, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), ret_var.data, ret_var.datalen); CVec_u8Z_free(ret_var); return ret_arr; } uint32_t __attribute__((visibility("default"))) TS_AcceptChannel_read(int8_tArray ser) { LDKu8slice ser_ref; ser_ref.datalen = *((uint32_t*)ser); ser_ref.data = (int8_t*)(ser + 4); LDKCResult_AcceptChannelDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_AcceptChannelDecodeErrorZ), "LDKCResult_AcceptChannelDecodeErrorZ"); *ret_conv = AcceptChannel_read(ser_ref); return (uint64_t)ret_conv; } int8_tArray __attribute__((visibility("default"))) TS_AnnouncementSignatures_write(uint32_t obj) { LDKAnnouncementSignatures obj_conv; obj_conv.inner = (void*)(obj & (~1)); obj_conv.is_owned = false; LDKCVec_u8Z ret_var = AnnouncementSignatures_write(&obj_conv); int8_tArray ret_arr = init_arr(ret_var.datalen, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), ret_var.data, ret_var.datalen); CVec_u8Z_free(ret_var); return ret_arr; } uint32_t __attribute__((visibility("default"))) TS_AnnouncementSignatures_read(int8_tArray ser) { LDKu8slice ser_ref; ser_ref.datalen = *((uint32_t*)ser); ser_ref.data = (int8_t*)(ser + 4); LDKCResult_AnnouncementSignaturesDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_AnnouncementSignaturesDecodeErrorZ), "LDKCResult_AnnouncementSignaturesDecodeErrorZ"); *ret_conv = AnnouncementSignatures_read(ser_ref); return (uint64_t)ret_conv; } int8_tArray __attribute__((visibility("default"))) TS_ChannelReestablish_write(uint32_t obj) { LDKChannelReestablish obj_conv; obj_conv.inner = (void*)(obj & (~1)); obj_conv.is_owned = false; LDKCVec_u8Z ret_var = ChannelReestablish_write(&obj_conv); int8_tArray ret_arr = init_arr(ret_var.datalen, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), ret_var.data, ret_var.datalen); CVec_u8Z_free(ret_var); return ret_arr; } uint32_t __attribute__((visibility("default"))) TS_ChannelReestablish_read(int8_tArray ser) { LDKu8slice ser_ref; ser_ref.datalen = *((uint32_t*)ser); ser_ref.data = (int8_t*)(ser + 4); LDKCResult_ChannelReestablishDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_ChannelReestablishDecodeErrorZ), "LDKCResult_ChannelReestablishDecodeErrorZ"); *ret_conv = ChannelReestablish_read(ser_ref); return (uint64_t)ret_conv; } int8_tArray __attribute__((visibility("default"))) TS_ClosingSigned_write(uint32_t obj) { LDKClosingSigned obj_conv; obj_conv.inner = (void*)(obj & (~1)); obj_conv.is_owned = false; LDKCVec_u8Z ret_var = ClosingSigned_write(&obj_conv); int8_tArray ret_arr = init_arr(ret_var.datalen, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), ret_var.data, ret_var.datalen); CVec_u8Z_free(ret_var); return ret_arr; } uint32_t __attribute__((visibility("default"))) TS_ClosingSigned_read(int8_tArray ser) { LDKu8slice ser_ref; ser_ref.datalen = *((uint32_t*)ser); ser_ref.data = (int8_t*)(ser + 4); LDKCResult_ClosingSignedDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_ClosingSignedDecodeErrorZ), "LDKCResult_ClosingSignedDecodeErrorZ"); *ret_conv = ClosingSigned_read(ser_ref); return (uint64_t)ret_conv; } int8_tArray __attribute__((visibility("default"))) TS_ClosingSignedFeeRange_write(uint32_t obj) { LDKClosingSignedFeeRange obj_conv; obj_conv.inner = (void*)(obj & (~1)); obj_conv.is_owned = false; LDKCVec_u8Z ret_var = ClosingSignedFeeRange_write(&obj_conv); int8_tArray ret_arr = init_arr(ret_var.datalen, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), ret_var.data, ret_var.datalen); CVec_u8Z_free(ret_var); return ret_arr; } uint32_t __attribute__((visibility("default"))) TS_ClosingSignedFeeRange_read(int8_tArray ser) { LDKu8slice ser_ref; ser_ref.datalen = *((uint32_t*)ser); ser_ref.data = (int8_t*)(ser + 4); LDKCResult_ClosingSignedFeeRangeDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_ClosingSignedFeeRangeDecodeErrorZ), "LDKCResult_ClosingSignedFeeRangeDecodeErrorZ"); *ret_conv = ClosingSignedFeeRange_read(ser_ref); return (uint64_t)ret_conv; } int8_tArray __attribute__((visibility("default"))) TS_CommitmentSigned_write(uint32_t obj) { LDKCommitmentSigned obj_conv; obj_conv.inner = (void*)(obj & (~1)); obj_conv.is_owned = false; LDKCVec_u8Z ret_var = CommitmentSigned_write(&obj_conv); int8_tArray ret_arr = init_arr(ret_var.datalen, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), ret_var.data, ret_var.datalen); CVec_u8Z_free(ret_var); return ret_arr; } uint32_t __attribute__((visibility("default"))) TS_CommitmentSigned_read(int8_tArray ser) { LDKu8slice ser_ref; ser_ref.datalen = *((uint32_t*)ser); ser_ref.data = (int8_t*)(ser + 4); LDKCResult_CommitmentSignedDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_CommitmentSignedDecodeErrorZ), "LDKCResult_CommitmentSignedDecodeErrorZ"); *ret_conv = CommitmentSigned_read(ser_ref); return (uint64_t)ret_conv; } int8_tArray __attribute__((visibility("default"))) TS_FundingCreated_write(uint32_t obj) { LDKFundingCreated obj_conv; obj_conv.inner = (void*)(obj & (~1)); obj_conv.is_owned = false; LDKCVec_u8Z ret_var = FundingCreated_write(&obj_conv); int8_tArray ret_arr = init_arr(ret_var.datalen, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), ret_var.data, ret_var.datalen); CVec_u8Z_free(ret_var); return ret_arr; } uint32_t __attribute__((visibility("default"))) TS_FundingCreated_read(int8_tArray ser) { LDKu8slice ser_ref; ser_ref.datalen = *((uint32_t*)ser); ser_ref.data = (int8_t*)(ser + 4); LDKCResult_FundingCreatedDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_FundingCreatedDecodeErrorZ), "LDKCResult_FundingCreatedDecodeErrorZ"); *ret_conv = FundingCreated_read(ser_ref); return (uint64_t)ret_conv; } int8_tArray __attribute__((visibility("default"))) TS_FundingSigned_write(uint32_t obj) { LDKFundingSigned obj_conv; obj_conv.inner = (void*)(obj & (~1)); obj_conv.is_owned = false; LDKCVec_u8Z ret_var = FundingSigned_write(&obj_conv); int8_tArray ret_arr = init_arr(ret_var.datalen, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), ret_var.data, ret_var.datalen); CVec_u8Z_free(ret_var); return ret_arr; } uint32_t __attribute__((visibility("default"))) TS_FundingSigned_read(int8_tArray ser) { LDKu8slice ser_ref; ser_ref.datalen = *((uint32_t*)ser); ser_ref.data = (int8_t*)(ser + 4); LDKCResult_FundingSignedDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_FundingSignedDecodeErrorZ), "LDKCResult_FundingSignedDecodeErrorZ"); *ret_conv = FundingSigned_read(ser_ref); return (uint64_t)ret_conv; } int8_tArray __attribute__((visibility("default"))) TS_FundingLocked_write(uint32_t obj) { LDKFundingLocked obj_conv; obj_conv.inner = (void*)(obj & (~1)); obj_conv.is_owned = false; LDKCVec_u8Z ret_var = FundingLocked_write(&obj_conv); int8_tArray ret_arr = init_arr(ret_var.datalen, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), ret_var.data, ret_var.datalen); CVec_u8Z_free(ret_var); return ret_arr; } uint32_t __attribute__((visibility("default"))) TS_FundingLocked_read(int8_tArray ser) { LDKu8slice ser_ref; ser_ref.datalen = *((uint32_t*)ser); ser_ref.data = (int8_t*)(ser + 4); LDKCResult_FundingLockedDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_FundingLockedDecodeErrorZ), "LDKCResult_FundingLockedDecodeErrorZ"); *ret_conv = FundingLocked_read(ser_ref); return (uint64_t)ret_conv; } int8_tArray __attribute__((visibility("default"))) TS_Init_write(uint32_t obj) { LDKInit obj_conv; obj_conv.inner = (void*)(obj & (~1)); obj_conv.is_owned = false; LDKCVec_u8Z ret_var = Init_write(&obj_conv); int8_tArray ret_arr = init_arr(ret_var.datalen, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), ret_var.data, ret_var.datalen); CVec_u8Z_free(ret_var); return ret_arr; } uint32_t __attribute__((visibility("default"))) TS_Init_read(int8_tArray ser) { LDKu8slice ser_ref; ser_ref.datalen = *((uint32_t*)ser); ser_ref.data = (int8_t*)(ser + 4); LDKCResult_InitDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_InitDecodeErrorZ), "LDKCResult_InitDecodeErrorZ"); *ret_conv = Init_read(ser_ref); return (uint64_t)ret_conv; } int8_tArray __attribute__((visibility("default"))) TS_OpenChannel_write(uint32_t obj) { LDKOpenChannel obj_conv; obj_conv.inner = (void*)(obj & (~1)); obj_conv.is_owned = false; LDKCVec_u8Z ret_var = OpenChannel_write(&obj_conv); int8_tArray ret_arr = init_arr(ret_var.datalen, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), ret_var.data, ret_var.datalen); CVec_u8Z_free(ret_var); return ret_arr; } uint32_t __attribute__((visibility("default"))) TS_OpenChannel_read(int8_tArray ser) { LDKu8slice ser_ref; ser_ref.datalen = *((uint32_t*)ser); ser_ref.data = (int8_t*)(ser + 4); LDKCResult_OpenChannelDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_OpenChannelDecodeErrorZ), "LDKCResult_OpenChannelDecodeErrorZ"); *ret_conv = OpenChannel_read(ser_ref); return (uint64_t)ret_conv; } int8_tArray __attribute__((visibility("default"))) TS_RevokeAndACK_write(uint32_t obj) { LDKRevokeAndACK obj_conv; obj_conv.inner = (void*)(obj & (~1)); obj_conv.is_owned = false; LDKCVec_u8Z ret_var = RevokeAndACK_write(&obj_conv); int8_tArray ret_arr = init_arr(ret_var.datalen, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), ret_var.data, ret_var.datalen); CVec_u8Z_free(ret_var); return ret_arr; } uint32_t __attribute__((visibility("default"))) TS_RevokeAndACK_read(int8_tArray ser) { LDKu8slice ser_ref; ser_ref.datalen = *((uint32_t*)ser); ser_ref.data = (int8_t*)(ser + 4); LDKCResult_RevokeAndACKDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_RevokeAndACKDecodeErrorZ), "LDKCResult_RevokeAndACKDecodeErrorZ"); *ret_conv = RevokeAndACK_read(ser_ref); return (uint64_t)ret_conv; } int8_tArray __attribute__((visibility("default"))) TS_Shutdown_write(uint32_t obj) { LDKShutdown obj_conv; obj_conv.inner = (void*)(obj & (~1)); obj_conv.is_owned = false; LDKCVec_u8Z ret_var = Shutdown_write(&obj_conv); int8_tArray ret_arr = init_arr(ret_var.datalen, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), ret_var.data, ret_var.datalen); CVec_u8Z_free(ret_var); return ret_arr; } uint32_t __attribute__((visibility("default"))) TS_Shutdown_read(int8_tArray ser) { LDKu8slice ser_ref; ser_ref.datalen = *((uint32_t*)ser); ser_ref.data = (int8_t*)(ser + 4); LDKCResult_ShutdownDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_ShutdownDecodeErrorZ), "LDKCResult_ShutdownDecodeErrorZ"); *ret_conv = Shutdown_read(ser_ref); return (uint64_t)ret_conv; } int8_tArray __attribute__((visibility("default"))) TS_UpdateFailHTLC_write(uint32_t obj) { LDKUpdateFailHTLC obj_conv; obj_conv.inner = (void*)(obj & (~1)); obj_conv.is_owned = false; LDKCVec_u8Z ret_var = UpdateFailHTLC_write(&obj_conv); int8_tArray ret_arr = init_arr(ret_var.datalen, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), ret_var.data, ret_var.datalen); CVec_u8Z_free(ret_var); return ret_arr; } uint32_t __attribute__((visibility("default"))) TS_UpdateFailHTLC_read(int8_tArray ser) { LDKu8slice ser_ref; ser_ref.datalen = *((uint32_t*)ser); ser_ref.data = (int8_t*)(ser + 4); LDKCResult_UpdateFailHTLCDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_UpdateFailHTLCDecodeErrorZ), "LDKCResult_UpdateFailHTLCDecodeErrorZ"); *ret_conv = UpdateFailHTLC_read(ser_ref); return (uint64_t)ret_conv; } int8_tArray __attribute__((visibility("default"))) TS_UpdateFailMalformedHTLC_write(uint32_t obj) { LDKUpdateFailMalformedHTLC obj_conv; obj_conv.inner = (void*)(obj & (~1)); obj_conv.is_owned = false; LDKCVec_u8Z ret_var = UpdateFailMalformedHTLC_write(&obj_conv); int8_tArray ret_arr = init_arr(ret_var.datalen, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), ret_var.data, ret_var.datalen); CVec_u8Z_free(ret_var); return ret_arr; } uint32_t __attribute__((visibility("default"))) TS_UpdateFailMalformedHTLC_read(int8_tArray ser) { LDKu8slice ser_ref; ser_ref.datalen = *((uint32_t*)ser); ser_ref.data = (int8_t*)(ser + 4); LDKCResult_UpdateFailMalformedHTLCDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_UpdateFailMalformedHTLCDecodeErrorZ), "LDKCResult_UpdateFailMalformedHTLCDecodeErrorZ"); *ret_conv = UpdateFailMalformedHTLC_read(ser_ref); return (uint64_t)ret_conv; } int8_tArray __attribute__((visibility("default"))) TS_UpdateFee_write(uint32_t obj) { LDKUpdateFee obj_conv; obj_conv.inner = (void*)(obj & (~1)); obj_conv.is_owned = false; LDKCVec_u8Z ret_var = UpdateFee_write(&obj_conv); int8_tArray ret_arr = init_arr(ret_var.datalen, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), ret_var.data, ret_var.datalen); CVec_u8Z_free(ret_var); return ret_arr; } uint32_t __attribute__((visibility("default"))) TS_UpdateFee_read(int8_tArray ser) { LDKu8slice ser_ref; ser_ref.datalen = *((uint32_t*)ser); ser_ref.data = (int8_t*)(ser + 4); LDKCResult_UpdateFeeDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_UpdateFeeDecodeErrorZ), "LDKCResult_UpdateFeeDecodeErrorZ"); *ret_conv = UpdateFee_read(ser_ref); return (uint64_t)ret_conv; } int8_tArray __attribute__((visibility("default"))) TS_UpdateFulfillHTLC_write(uint32_t obj) { LDKUpdateFulfillHTLC obj_conv; obj_conv.inner = (void*)(obj & (~1)); obj_conv.is_owned = false; LDKCVec_u8Z ret_var = UpdateFulfillHTLC_write(&obj_conv); int8_tArray ret_arr = init_arr(ret_var.datalen, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), ret_var.data, ret_var.datalen); CVec_u8Z_free(ret_var); return ret_arr; } uint32_t __attribute__((visibility("default"))) TS_UpdateFulfillHTLC_read(int8_tArray ser) { LDKu8slice ser_ref; ser_ref.datalen = *((uint32_t*)ser); ser_ref.data = (int8_t*)(ser + 4); LDKCResult_UpdateFulfillHTLCDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_UpdateFulfillHTLCDecodeErrorZ), "LDKCResult_UpdateFulfillHTLCDecodeErrorZ"); *ret_conv = UpdateFulfillHTLC_read(ser_ref); return (uint64_t)ret_conv; } int8_tArray __attribute__((visibility("default"))) TS_UpdateAddHTLC_write(uint32_t obj) { LDKUpdateAddHTLC obj_conv; obj_conv.inner = (void*)(obj & (~1)); obj_conv.is_owned = false; LDKCVec_u8Z ret_var = UpdateAddHTLC_write(&obj_conv); int8_tArray ret_arr = init_arr(ret_var.datalen, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), ret_var.data, ret_var.datalen); CVec_u8Z_free(ret_var); return ret_arr; } uint32_t __attribute__((visibility("default"))) TS_UpdateAddHTLC_read(int8_tArray ser) { LDKu8slice ser_ref; ser_ref.datalen = *((uint32_t*)ser); ser_ref.data = (int8_t*)(ser + 4); LDKCResult_UpdateAddHTLCDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_UpdateAddHTLCDecodeErrorZ), "LDKCResult_UpdateAddHTLCDecodeErrorZ"); *ret_conv = UpdateAddHTLC_read(ser_ref); return (uint64_t)ret_conv; } int8_tArray __attribute__((visibility("default"))) TS_Ping_write(uint32_t obj) { LDKPing obj_conv; obj_conv.inner = (void*)(obj & (~1)); obj_conv.is_owned = false; LDKCVec_u8Z ret_var = Ping_write(&obj_conv); int8_tArray ret_arr = init_arr(ret_var.datalen, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), ret_var.data, ret_var.datalen); CVec_u8Z_free(ret_var); return ret_arr; } uint32_t __attribute__((visibility("default"))) TS_Ping_read(int8_tArray ser) { LDKu8slice ser_ref; ser_ref.datalen = *((uint32_t*)ser); ser_ref.data = (int8_t*)(ser + 4); LDKCResult_PingDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_PingDecodeErrorZ), "LDKCResult_PingDecodeErrorZ"); *ret_conv = Ping_read(ser_ref); return (uint64_t)ret_conv; } int8_tArray __attribute__((visibility("default"))) TS_Pong_write(uint32_t obj) { LDKPong obj_conv; obj_conv.inner = (void*)(obj & (~1)); obj_conv.is_owned = false; LDKCVec_u8Z ret_var = Pong_write(&obj_conv); int8_tArray ret_arr = init_arr(ret_var.datalen, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), ret_var.data, ret_var.datalen); CVec_u8Z_free(ret_var); return ret_arr; } uint32_t __attribute__((visibility("default"))) TS_Pong_read(int8_tArray ser) { LDKu8slice ser_ref; ser_ref.datalen = *((uint32_t*)ser); ser_ref.data = (int8_t*)(ser + 4); LDKCResult_PongDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_PongDecodeErrorZ), "LDKCResult_PongDecodeErrorZ"); *ret_conv = Pong_read(ser_ref); return (uint64_t)ret_conv; } int8_tArray __attribute__((visibility("default"))) TS_UnsignedChannelAnnouncement_write(uint32_t obj) { LDKUnsignedChannelAnnouncement obj_conv; obj_conv.inner = (void*)(obj & (~1)); obj_conv.is_owned = false; LDKCVec_u8Z ret_var = UnsignedChannelAnnouncement_write(&obj_conv); int8_tArray ret_arr = init_arr(ret_var.datalen, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), ret_var.data, ret_var.datalen); CVec_u8Z_free(ret_var); return ret_arr; } uint32_t __attribute__((visibility("default"))) TS_UnsignedChannelAnnouncement_read(int8_tArray ser) { LDKu8slice ser_ref; ser_ref.datalen = *((uint32_t*)ser); ser_ref.data = (int8_t*)(ser + 4); LDKCResult_UnsignedChannelAnnouncementDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_UnsignedChannelAnnouncementDecodeErrorZ), "LDKCResult_UnsignedChannelAnnouncementDecodeErrorZ"); *ret_conv = UnsignedChannelAnnouncement_read(ser_ref); return (uint64_t)ret_conv; } int8_tArray __attribute__((visibility("default"))) TS_ChannelAnnouncement_write(uint32_t obj) { LDKChannelAnnouncement obj_conv; obj_conv.inner = (void*)(obj & (~1)); obj_conv.is_owned = false; LDKCVec_u8Z ret_var = ChannelAnnouncement_write(&obj_conv); int8_tArray ret_arr = init_arr(ret_var.datalen, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), ret_var.data, ret_var.datalen); CVec_u8Z_free(ret_var); return ret_arr; } uint32_t __attribute__((visibility("default"))) TS_ChannelAnnouncement_read(int8_tArray ser) { LDKu8slice ser_ref; ser_ref.datalen = *((uint32_t*)ser); ser_ref.data = (int8_t*)(ser + 4); LDKCResult_ChannelAnnouncementDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_ChannelAnnouncementDecodeErrorZ), "LDKCResult_ChannelAnnouncementDecodeErrorZ"); *ret_conv = ChannelAnnouncement_read(ser_ref); return (uint64_t)ret_conv; } int8_tArray __attribute__((visibility("default"))) TS_UnsignedChannelUpdate_write(uint32_t obj) { LDKUnsignedChannelUpdate obj_conv; obj_conv.inner = (void*)(obj & (~1)); obj_conv.is_owned = false; LDKCVec_u8Z ret_var = UnsignedChannelUpdate_write(&obj_conv); int8_tArray ret_arr = init_arr(ret_var.datalen, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), ret_var.data, ret_var.datalen); CVec_u8Z_free(ret_var); return ret_arr; } uint32_t __attribute__((visibility("default"))) TS_UnsignedChannelUpdate_read(int8_tArray ser) { LDKu8slice ser_ref; ser_ref.datalen = *((uint32_t*)ser); ser_ref.data = (int8_t*)(ser + 4); LDKCResult_UnsignedChannelUpdateDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_UnsignedChannelUpdateDecodeErrorZ), "LDKCResult_UnsignedChannelUpdateDecodeErrorZ"); *ret_conv = UnsignedChannelUpdate_read(ser_ref); return (uint64_t)ret_conv; } int8_tArray __attribute__((visibility("default"))) TS_ChannelUpdate_write(uint32_t obj) { LDKChannelUpdate obj_conv; obj_conv.inner = (void*)(obj & (~1)); obj_conv.is_owned = false; LDKCVec_u8Z ret_var = ChannelUpdate_write(&obj_conv); int8_tArray ret_arr = init_arr(ret_var.datalen, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), ret_var.data, ret_var.datalen); CVec_u8Z_free(ret_var); return ret_arr; } uint32_t __attribute__((visibility("default"))) TS_ChannelUpdate_read(int8_tArray ser) { LDKu8slice ser_ref; ser_ref.datalen = *((uint32_t*)ser); ser_ref.data = (int8_t*)(ser + 4); LDKCResult_ChannelUpdateDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_ChannelUpdateDecodeErrorZ), "LDKCResult_ChannelUpdateDecodeErrorZ"); *ret_conv = ChannelUpdate_read(ser_ref); return (uint64_t)ret_conv; } int8_tArray __attribute__((visibility("default"))) TS_ErrorMessage_write(uint32_t obj) { LDKErrorMessage obj_conv; obj_conv.inner = (void*)(obj & (~1)); obj_conv.is_owned = false; LDKCVec_u8Z ret_var = ErrorMessage_write(&obj_conv); int8_tArray ret_arr = init_arr(ret_var.datalen, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), ret_var.data, ret_var.datalen); CVec_u8Z_free(ret_var); return ret_arr; } uint32_t __attribute__((visibility("default"))) TS_ErrorMessage_read(int8_tArray ser) { LDKu8slice ser_ref; ser_ref.datalen = *((uint32_t*)ser); ser_ref.data = (int8_t*)(ser + 4); LDKCResult_ErrorMessageDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_ErrorMessageDecodeErrorZ), "LDKCResult_ErrorMessageDecodeErrorZ"); *ret_conv = ErrorMessage_read(ser_ref); return (uint64_t)ret_conv; } int8_tArray __attribute__((visibility("default"))) TS_UnsignedNodeAnnouncement_write(uint32_t obj) { LDKUnsignedNodeAnnouncement obj_conv; obj_conv.inner = (void*)(obj & (~1)); obj_conv.is_owned = false; LDKCVec_u8Z ret_var = UnsignedNodeAnnouncement_write(&obj_conv); int8_tArray ret_arr = init_arr(ret_var.datalen, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), ret_var.data, ret_var.datalen); CVec_u8Z_free(ret_var); return ret_arr; } uint32_t __attribute__((visibility("default"))) TS_UnsignedNodeAnnouncement_read(int8_tArray ser) { LDKu8slice ser_ref; ser_ref.datalen = *((uint32_t*)ser); ser_ref.data = (int8_t*)(ser + 4); LDKCResult_UnsignedNodeAnnouncementDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_UnsignedNodeAnnouncementDecodeErrorZ), "LDKCResult_UnsignedNodeAnnouncementDecodeErrorZ"); *ret_conv = UnsignedNodeAnnouncement_read(ser_ref); return (uint64_t)ret_conv; } int8_tArray __attribute__((visibility("default"))) TS_NodeAnnouncement_write(uint32_t obj) { LDKNodeAnnouncement obj_conv; obj_conv.inner = (void*)(obj & (~1)); obj_conv.is_owned = false; LDKCVec_u8Z ret_var = NodeAnnouncement_write(&obj_conv); int8_tArray ret_arr = init_arr(ret_var.datalen, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), ret_var.data, ret_var.datalen); CVec_u8Z_free(ret_var); return ret_arr; } uint32_t __attribute__((visibility("default"))) TS_NodeAnnouncement_read(int8_tArray ser) { LDKu8slice ser_ref; ser_ref.datalen = *((uint32_t*)ser); ser_ref.data = (int8_t*)(ser + 4); LDKCResult_NodeAnnouncementDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_NodeAnnouncementDecodeErrorZ), "LDKCResult_NodeAnnouncementDecodeErrorZ"); *ret_conv = NodeAnnouncement_read(ser_ref); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_QueryShortChannelIds_read(int8_tArray ser) { LDKu8slice ser_ref; ser_ref.datalen = *((uint32_t*)ser); ser_ref.data = (int8_t*)(ser + 4); LDKCResult_QueryShortChannelIdsDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_QueryShortChannelIdsDecodeErrorZ), "LDKCResult_QueryShortChannelIdsDecodeErrorZ"); *ret_conv = QueryShortChannelIds_read(ser_ref); return (uint64_t)ret_conv; } int8_tArray __attribute__((visibility("default"))) TS_QueryShortChannelIds_write(uint32_t obj) { LDKQueryShortChannelIds obj_conv; obj_conv.inner = (void*)(obj & (~1)); obj_conv.is_owned = false; LDKCVec_u8Z ret_var = QueryShortChannelIds_write(&obj_conv); int8_tArray ret_arr = init_arr(ret_var.datalen, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), ret_var.data, ret_var.datalen); CVec_u8Z_free(ret_var); return ret_arr; } int8_tArray __attribute__((visibility("default"))) TS_ReplyShortChannelIdsEnd_write(uint32_t obj) { LDKReplyShortChannelIdsEnd obj_conv; obj_conv.inner = (void*)(obj & (~1)); obj_conv.is_owned = false; LDKCVec_u8Z ret_var = ReplyShortChannelIdsEnd_write(&obj_conv); int8_tArray ret_arr = init_arr(ret_var.datalen, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), ret_var.data, ret_var.datalen); CVec_u8Z_free(ret_var); return ret_arr; } uint32_t __attribute__((visibility("default"))) TS_ReplyShortChannelIdsEnd_read(int8_tArray ser) { LDKu8slice ser_ref; ser_ref.datalen = *((uint32_t*)ser); ser_ref.data = (int8_t*)(ser + 4); LDKCResult_ReplyShortChannelIdsEndDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_ReplyShortChannelIdsEndDecodeErrorZ), "LDKCResult_ReplyShortChannelIdsEndDecodeErrorZ"); *ret_conv = ReplyShortChannelIdsEnd_read(ser_ref); return (uint64_t)ret_conv; } int32_t __attribute__((visibility("default"))) TS_QueryChannelRange_end_blocknum(uint32_t this_arg) { LDKQueryChannelRange this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; int32_t ret_val = QueryChannelRange_end_blocknum(&this_arg_conv); return ret_val; } int8_tArray __attribute__((visibility("default"))) TS_QueryChannelRange_write(uint32_t obj) { LDKQueryChannelRange obj_conv; obj_conv.inner = (void*)(obj & (~1)); obj_conv.is_owned = false; LDKCVec_u8Z ret_var = QueryChannelRange_write(&obj_conv); int8_tArray ret_arr = init_arr(ret_var.datalen, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), ret_var.data, ret_var.datalen); CVec_u8Z_free(ret_var); return ret_arr; } uint32_t __attribute__((visibility("default"))) TS_QueryChannelRange_read(int8_tArray ser) { LDKu8slice ser_ref; ser_ref.datalen = *((uint32_t*)ser); ser_ref.data = (int8_t*)(ser + 4); LDKCResult_QueryChannelRangeDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_QueryChannelRangeDecodeErrorZ), "LDKCResult_QueryChannelRangeDecodeErrorZ"); *ret_conv = QueryChannelRange_read(ser_ref); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_ReplyChannelRange_read(int8_tArray ser) { LDKu8slice ser_ref; ser_ref.datalen = *((uint32_t*)ser); ser_ref.data = (int8_t*)(ser + 4); LDKCResult_ReplyChannelRangeDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_ReplyChannelRangeDecodeErrorZ), "LDKCResult_ReplyChannelRangeDecodeErrorZ"); *ret_conv = ReplyChannelRange_read(ser_ref); return (uint64_t)ret_conv; } int8_tArray __attribute__((visibility("default"))) TS_ReplyChannelRange_write(uint32_t obj) { LDKReplyChannelRange obj_conv; obj_conv.inner = (void*)(obj & (~1)); obj_conv.is_owned = false; LDKCVec_u8Z ret_var = ReplyChannelRange_write(&obj_conv); int8_tArray ret_arr = init_arr(ret_var.datalen, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), ret_var.data, ret_var.datalen); CVec_u8Z_free(ret_var); return ret_arr; } int8_tArray __attribute__((visibility("default"))) TS_GossipTimestampFilter_write(uint32_t obj) { LDKGossipTimestampFilter obj_conv; obj_conv.inner = (void*)(obj & (~1)); obj_conv.is_owned = false; LDKCVec_u8Z ret_var = GossipTimestampFilter_write(&obj_conv); int8_tArray ret_arr = init_arr(ret_var.datalen, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), ret_var.data, ret_var.datalen); CVec_u8Z_free(ret_var); return ret_arr; } uint32_t __attribute__((visibility("default"))) TS_GossipTimestampFilter_read(int8_tArray ser) { LDKu8slice ser_ref; ser_ref.datalen = *((uint32_t*)ser); ser_ref.data = (int8_t*)(ser + 4); LDKCResult_GossipTimestampFilterDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_GossipTimestampFilterDecodeErrorZ), "LDKCResult_GossipTimestampFilterDecodeErrorZ"); *ret_conv = GossipTimestampFilter_read(ser_ref); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_CustomMessageHandler_free(uint32_t this_ptr) { if ((this_ptr & 1) != 0) return; LDKCustomMessageHandler this_ptr_conv = *(LDKCustomMessageHandler*)(((uint64_t)this_ptr) & ~1); FREE((void*)this_ptr); CustomMessageHandler_free(this_ptr_conv); } void __attribute__((visibility("default"))) TS_IgnoringMessageHandler_free(uint32_t this_obj) { LDKIgnoringMessageHandler this_obj_conv; this_obj_conv.inner = (void*)(this_obj & (~1)); this_obj_conv.is_owned = (this_obj & 1) || (this_obj == 0); IgnoringMessageHandler_free(this_obj_conv); } uint32_t __attribute__((visibility("default"))) TS_IgnoringMessageHandler_new() { LDKIgnoringMessageHandler ret_var = IgnoringMessageHandler_new(); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_IgnoringMessageHandler_as_MessageSendEventsProvider(uint32_t this_arg) { LDKIgnoringMessageHandler this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; LDKMessageSendEventsProvider* ret_ret =MALLOC(sizeof(LDKMessageSendEventsProvider), "LDKMessageSendEventsProvider"); *ret_ret = IgnoringMessageHandler_as_MessageSendEventsProvider(&this_arg_conv); return (uint64_t)ret_ret; } uint32_t __attribute__((visibility("default"))) TS_IgnoringMessageHandler_as_RoutingMessageHandler(uint32_t this_arg) { LDKIgnoringMessageHandler this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; LDKRoutingMessageHandler* ret_ret =MALLOC(sizeof(LDKRoutingMessageHandler), "LDKRoutingMessageHandler"); *ret_ret = IgnoringMessageHandler_as_RoutingMessageHandler(&this_arg_conv); return (uint64_t)ret_ret; } uint32_t __attribute__((visibility("default"))) TS_IgnoringMessageHandler_as_CustomMessageReader(uint32_t this_arg) { LDKIgnoringMessageHandler this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; LDKCustomMessageReader* ret_ret =MALLOC(sizeof(LDKCustomMessageReader), "LDKCustomMessageReader"); *ret_ret = IgnoringMessageHandler_as_CustomMessageReader(&this_arg_conv); return (uint64_t)ret_ret; } uint32_t __attribute__((visibility("default"))) TS_IgnoringMessageHandler_as_CustomMessageHandler(uint32_t this_arg) { LDKIgnoringMessageHandler this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; LDKCustomMessageHandler* ret_ret =MALLOC(sizeof(LDKCustomMessageHandler), "LDKCustomMessageHandler"); *ret_ret = IgnoringMessageHandler_as_CustomMessageHandler(&this_arg_conv); return (uint64_t)ret_ret; } void __attribute__((visibility("default"))) TS_ErroringMessageHandler_free(uint32_t this_obj) { LDKErroringMessageHandler this_obj_conv; this_obj_conv.inner = (void*)(this_obj & (~1)); this_obj_conv.is_owned = (this_obj & 1) || (this_obj == 0); ErroringMessageHandler_free(this_obj_conv); } uint32_t __attribute__((visibility("default"))) TS_ErroringMessageHandler_new() { LDKErroringMessageHandler ret_var = ErroringMessageHandler_new(); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_ErroringMessageHandler_as_MessageSendEventsProvider(uint32_t this_arg) { LDKErroringMessageHandler this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; LDKMessageSendEventsProvider* ret_ret =MALLOC(sizeof(LDKMessageSendEventsProvider), "LDKMessageSendEventsProvider"); *ret_ret = ErroringMessageHandler_as_MessageSendEventsProvider(&this_arg_conv); return (uint64_t)ret_ret; } uint32_t __attribute__((visibility("default"))) TS_ErroringMessageHandler_as_ChannelMessageHandler(uint32_t this_arg) { LDKErroringMessageHandler this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; LDKChannelMessageHandler* ret_ret =MALLOC(sizeof(LDKChannelMessageHandler), "LDKChannelMessageHandler"); *ret_ret = ErroringMessageHandler_as_ChannelMessageHandler(&this_arg_conv); return (uint64_t)ret_ret; } void __attribute__((visibility("default"))) TS_MessageHandler_free(uint32_t this_obj) { LDKMessageHandler this_obj_conv; this_obj_conv.inner = (void*)(this_obj & (~1)); this_obj_conv.is_owned = (this_obj & 1) || (this_obj == 0); MessageHandler_free(this_obj_conv); } uint32_t __attribute__((visibility("default"))) TS_MessageHandler_get_chan_handler(uint32_t this_ptr) { LDKMessageHandler this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; uint64_t ret_ret = (uint64_t)MessageHandler_get_chan_handler(&this_ptr_conv); return ret_ret; } void __attribute__((visibility("default"))) TS_MessageHandler_set_chan_handler(uint32_t this_ptr, uint32_t val) { LDKMessageHandler this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKChannelMessageHandler val_conv = *(LDKChannelMessageHandler*)(((uint64_t)val) & ~1); MessageHandler_set_chan_handler(&this_ptr_conv, val_conv); } uint32_t __attribute__((visibility("default"))) TS_MessageHandler_get_route_handler(uint32_t this_ptr) { LDKMessageHandler this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; uint64_t ret_ret = (uint64_t)MessageHandler_get_route_handler(&this_ptr_conv); return ret_ret; } void __attribute__((visibility("default"))) TS_MessageHandler_set_route_handler(uint32_t this_ptr, uint32_t val) { LDKMessageHandler this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKRoutingMessageHandler val_conv = *(LDKRoutingMessageHandler*)(((uint64_t)val) & ~1); MessageHandler_set_route_handler(&this_ptr_conv, val_conv); } uint32_t __attribute__((visibility("default"))) TS_MessageHandler_new(uint32_t chan_handler_arg, uint32_t route_handler_arg) { LDKChannelMessageHandler chan_handler_arg_conv = *(LDKChannelMessageHandler*)(((uint64_t)chan_handler_arg) & ~1); LDKRoutingMessageHandler route_handler_arg_conv = *(LDKRoutingMessageHandler*)(((uint64_t)route_handler_arg) & ~1); LDKMessageHandler ret_var = MessageHandler_new(chan_handler_arg_conv, route_handler_arg_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_SocketDescriptor_clone(uint32_t orig) { LDKSocketDescriptor* orig_conv = (LDKSocketDescriptor*)(((uint64_t)orig) & ~1); LDKSocketDescriptor* ret_ret =MALLOC(sizeof(LDKSocketDescriptor), "LDKSocketDescriptor"); *ret_ret = SocketDescriptor_clone(orig_conv); return (uint64_t)ret_ret; } void __attribute__((visibility("default"))) TS_SocketDescriptor_free(uint32_t this_ptr) { if ((this_ptr & 1) != 0) return; LDKSocketDescriptor this_ptr_conv = *(LDKSocketDescriptor*)(((uint64_t)this_ptr) & ~1); FREE((void*)this_ptr); SocketDescriptor_free(this_ptr_conv); } void __attribute__((visibility("default"))) TS_PeerHandleError_free(uint32_t this_obj) { LDKPeerHandleError this_obj_conv; this_obj_conv.inner = (void*)(this_obj & (~1)); this_obj_conv.is_owned = (this_obj & 1) || (this_obj == 0); PeerHandleError_free(this_obj_conv); } jboolean __attribute__((visibility("default"))) TS_PeerHandleError_get_no_connection_possible(uint32_t this_ptr) { LDKPeerHandleError this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; jboolean ret_val = PeerHandleError_get_no_connection_possible(&this_ptr_conv); return ret_val; } void __attribute__((visibility("default"))) TS_PeerHandleError_set_no_connection_possible(uint32_t this_ptr, jboolean val) { LDKPeerHandleError this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; PeerHandleError_set_no_connection_possible(&this_ptr_conv, val); } uint32_t __attribute__((visibility("default"))) TS_PeerHandleError_new(jboolean no_connection_possible_arg) { LDKPeerHandleError ret_var = PeerHandleError_new(no_connection_possible_arg); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_PeerHandleError_clone(uint32_t orig) { LDKPeerHandleError orig_conv; orig_conv.inner = (void*)(orig & (~1)); orig_conv.is_owned = false; LDKPeerHandleError ret_var = PeerHandleError_clone(&orig_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } void __attribute__((visibility("default"))) TS_PeerManager_free(uint32_t this_obj) { LDKPeerManager this_obj_conv; this_obj_conv.inner = (void*)(this_obj & (~1)); this_obj_conv.is_owned = (this_obj & 1) || (this_obj == 0); PeerManager_free(this_obj_conv); } uint32_t __attribute__((visibility("default"))) TS_PeerManager_new(uint32_t message_handler, int8_tArray our_node_secret, int8_tArray ephemeral_random_data, uint32_t logger, uint32_t custom_message_handler) { LDKMessageHandler message_handler_conv; message_handler_conv.inner = (void*)(message_handler & (~1)); message_handler_conv.is_owned = (message_handler & 1) || (message_handler == 0); // Warning: we need a move here but no clone is available for LDKMessageHandler LDKSecretKey our_node_secret_ref; CHECK(*((uint32_t*)our_node_secret) == 32); memcpy(our_node_secret_ref.bytes, (uint8_t*)(our_node_secret + 4), 32); unsigned char ephemeral_random_data_arr[32]; CHECK(*((uint32_t*)ephemeral_random_data) == 32); memcpy(ephemeral_random_data_arr, (uint8_t*)(ephemeral_random_data + 4), 32); unsigned char (*ephemeral_random_data_ref)[32] = &ephemeral_random_data_arr; LDKLogger logger_conv = *(LDKLogger*)(((uint64_t)logger) & ~1); LDKCustomMessageHandler custom_message_handler_conv = *(LDKCustomMessageHandler*)(((uint64_t)custom_message_handler) & ~1); LDKPeerManager ret_var = PeerManager_new(message_handler_conv, our_node_secret_ref, ephemeral_random_data_ref, logger_conv, custom_message_handler_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } ptrArray __attribute__((visibility("default"))) TS_PeerManager_get_peer_node_ids(uint32_t this_arg) { LDKPeerManager this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; LDKCVec_PublicKeyZ ret_var = PeerManager_get_peer_node_ids(&this_arg_conv); ptrArray ret_arr = init_arr(ret_var.datalen, sizeof(uint32_t), "Native ptrArray Bytes"); int8_tArray *ret_arr_ptr = (int8_tArray*)(ret_arr + 4); for (size_t m = 0; m < ret_var.datalen; m++) { int8_tArray ret_conv_12_arr = init_arr(33, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_conv_12_arr + 4), ret_var.data[m].compressed_form, 33); ret_arr_ptr[m] = ret_conv_12_arr; } FREE(ret_var.data); return ret_arr; } uint32_t __attribute__((visibility("default"))) TS_PeerManager_new_outbound_connection(uint32_t this_arg, int8_tArray their_node_id, uint32_t descriptor) { LDKPeerManager this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; LDKPublicKey their_node_id_ref; CHECK(*((uint32_t*)their_node_id) == 33); memcpy(their_node_id_ref.compressed_form, (uint8_t*)(their_node_id + 4), 33); LDKSocketDescriptor descriptor_conv = *(LDKSocketDescriptor*)(((uint64_t)descriptor) & ~1); LDKCResult_CVec_u8ZPeerHandleErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_CVec_u8ZPeerHandleErrorZ), "LDKCResult_CVec_u8ZPeerHandleErrorZ"); *ret_conv = PeerManager_new_outbound_connection(&this_arg_conv, their_node_id_ref, descriptor_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_PeerManager_new_inbound_connection(uint32_t this_arg, uint32_t descriptor) { LDKPeerManager this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; LDKSocketDescriptor descriptor_conv = *(LDKSocketDescriptor*)(((uint64_t)descriptor) & ~1); LDKCResult_NonePeerHandleErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_NonePeerHandleErrorZ), "LDKCResult_NonePeerHandleErrorZ"); *ret_conv = PeerManager_new_inbound_connection(&this_arg_conv, descriptor_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_PeerManager_write_buffer_space_avail(uint32_t this_arg, uint32_t descriptor) { LDKPeerManager this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; LDKSocketDescriptor* descriptor_conv = (LDKSocketDescriptor*)(((uint64_t)descriptor) & ~1); LDKCResult_NonePeerHandleErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_NonePeerHandleErrorZ), "LDKCResult_NonePeerHandleErrorZ"); *ret_conv = PeerManager_write_buffer_space_avail(&this_arg_conv, descriptor_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_PeerManager_read_event(uint32_t this_arg, uint32_t peer_descriptor, int8_tArray data) { LDKPeerManager this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; LDKSocketDescriptor* peer_descriptor_conv = (LDKSocketDescriptor*)(((uint64_t)peer_descriptor) & ~1); LDKu8slice data_ref; data_ref.datalen = *((uint32_t*)data); data_ref.data = (int8_t*)(data + 4); LDKCResult_boolPeerHandleErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_boolPeerHandleErrorZ), "LDKCResult_boolPeerHandleErrorZ"); *ret_conv = PeerManager_read_event(&this_arg_conv, peer_descriptor_conv, data_ref); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_PeerManager_process_events(uint32_t this_arg) { LDKPeerManager this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; PeerManager_process_events(&this_arg_conv); } void __attribute__((visibility("default"))) TS_PeerManager_socket_disconnected(uint32_t this_arg, uint32_t descriptor) { LDKPeerManager this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; LDKSocketDescriptor* descriptor_conv = (LDKSocketDescriptor*)(((uint64_t)descriptor) & ~1); PeerManager_socket_disconnected(&this_arg_conv, descriptor_conv); } void __attribute__((visibility("default"))) TS_PeerManager_disconnect_by_node_id(uint32_t this_arg, int8_tArray node_id, jboolean no_connection_possible) { LDKPeerManager this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; LDKPublicKey node_id_ref; CHECK(*((uint32_t*)node_id) == 33); memcpy(node_id_ref.compressed_form, (uint8_t*)(node_id + 4), 33); PeerManager_disconnect_by_node_id(&this_arg_conv, node_id_ref, no_connection_possible); } void __attribute__((visibility("default"))) TS_PeerManager_timer_tick_occurred(uint32_t this_arg) { LDKPeerManager this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; PeerManager_timer_tick_occurred(&this_arg_conv); } int8_tArray __attribute__((visibility("default"))) TS_build_commitment_secret(int8_tArray commitment_seed, int64_t idx) { unsigned char commitment_seed_arr[32]; CHECK(*((uint32_t*)commitment_seed) == 32); memcpy(commitment_seed_arr, (uint8_t*)(commitment_seed + 4), 32); unsigned char (*commitment_seed_ref)[32] = &commitment_seed_arr; int8_tArray ret_arr = init_arr(32, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), build_commitment_secret(commitment_seed_ref, idx).data, 32); return ret_arr; } int8_tArray __attribute__((visibility("default"))) TS_build_closing_transaction(int64_t to_holder_value_sat, int64_t to_counterparty_value_sat, int8_tArray to_holder_script, int8_tArray to_counterparty_script, uint32_t funding_outpoint) { LDKCVec_u8Z to_holder_script_ref; to_holder_script_ref.datalen = *((uint32_t*)to_holder_script); to_holder_script_ref.data = MALLOC(to_holder_script_ref.datalen, "LDKCVec_u8Z Bytes"); memcpy(to_holder_script_ref.data, (uint8_t*)(to_holder_script + 4), to_holder_script_ref.datalen); LDKCVec_u8Z to_counterparty_script_ref; to_counterparty_script_ref.datalen = *((uint32_t*)to_counterparty_script); to_counterparty_script_ref.data = MALLOC(to_counterparty_script_ref.datalen, "LDKCVec_u8Z Bytes"); memcpy(to_counterparty_script_ref.data, (uint8_t*)(to_counterparty_script + 4), to_counterparty_script_ref.datalen); LDKOutPoint funding_outpoint_conv; funding_outpoint_conv.inner = (void*)(funding_outpoint & (~1)); funding_outpoint_conv.is_owned = (funding_outpoint & 1) || (funding_outpoint == 0); funding_outpoint_conv = OutPoint_clone(&funding_outpoint_conv); LDKTransaction ret_var = build_closing_transaction(to_holder_value_sat, to_counterparty_value_sat, to_holder_script_ref, to_counterparty_script_ref, funding_outpoint_conv); int8_tArray ret_arr = init_arr(ret_var.datalen, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), ret_var.data, ret_var.datalen); Transaction_free(ret_var); return ret_arr; } uint32_t __attribute__((visibility("default"))) TS_derive_private_key(int8_tArray per_commitment_point, int8_tArray base_secret) { LDKPublicKey per_commitment_point_ref; CHECK(*((uint32_t*)per_commitment_point) == 33); memcpy(per_commitment_point_ref.compressed_form, (uint8_t*)(per_commitment_point + 4), 33); unsigned char base_secret_arr[32]; CHECK(*((uint32_t*)base_secret) == 32); memcpy(base_secret_arr, (uint8_t*)(base_secret + 4), 32); unsigned char (*base_secret_ref)[32] = &base_secret_arr; LDKCResult_SecretKeyErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_SecretKeyErrorZ), "LDKCResult_SecretKeyErrorZ"); *ret_conv = derive_private_key(per_commitment_point_ref, base_secret_ref); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_derive_public_key(int8_tArray per_commitment_point, int8_tArray base_point) { LDKPublicKey per_commitment_point_ref; CHECK(*((uint32_t*)per_commitment_point) == 33); memcpy(per_commitment_point_ref.compressed_form, (uint8_t*)(per_commitment_point + 4), 33); LDKPublicKey base_point_ref; CHECK(*((uint32_t*)base_point) == 33); memcpy(base_point_ref.compressed_form, (uint8_t*)(base_point + 4), 33); LDKCResult_PublicKeyErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_PublicKeyErrorZ), "LDKCResult_PublicKeyErrorZ"); *ret_conv = derive_public_key(per_commitment_point_ref, base_point_ref); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_derive_private_revocation_key(int8_tArray per_commitment_secret, int8_tArray countersignatory_revocation_base_secret) { unsigned char per_commitment_secret_arr[32]; CHECK(*((uint32_t*)per_commitment_secret) == 32); memcpy(per_commitment_secret_arr, (uint8_t*)(per_commitment_secret + 4), 32); unsigned char (*per_commitment_secret_ref)[32] = &per_commitment_secret_arr; unsigned char countersignatory_revocation_base_secret_arr[32]; CHECK(*((uint32_t*)countersignatory_revocation_base_secret) == 32); memcpy(countersignatory_revocation_base_secret_arr, (uint8_t*)(countersignatory_revocation_base_secret + 4), 32); unsigned char (*countersignatory_revocation_base_secret_ref)[32] = &countersignatory_revocation_base_secret_arr; LDKCResult_SecretKeyErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_SecretKeyErrorZ), "LDKCResult_SecretKeyErrorZ"); *ret_conv = derive_private_revocation_key(per_commitment_secret_ref, countersignatory_revocation_base_secret_ref); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_derive_public_revocation_key(int8_tArray per_commitment_point, int8_tArray countersignatory_revocation_base_point) { LDKPublicKey per_commitment_point_ref; CHECK(*((uint32_t*)per_commitment_point) == 33); memcpy(per_commitment_point_ref.compressed_form, (uint8_t*)(per_commitment_point + 4), 33); LDKPublicKey countersignatory_revocation_base_point_ref; CHECK(*((uint32_t*)countersignatory_revocation_base_point) == 33); memcpy(countersignatory_revocation_base_point_ref.compressed_form, (uint8_t*)(countersignatory_revocation_base_point + 4), 33); LDKCResult_PublicKeyErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_PublicKeyErrorZ), "LDKCResult_PublicKeyErrorZ"); *ret_conv = derive_public_revocation_key(per_commitment_point_ref, countersignatory_revocation_base_point_ref); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_TxCreationKeys_free(uint32_t this_obj) { LDKTxCreationKeys this_obj_conv; this_obj_conv.inner = (void*)(this_obj & (~1)); this_obj_conv.is_owned = (this_obj & 1) || (this_obj == 0); TxCreationKeys_free(this_obj_conv); } int8_tArray __attribute__((visibility("default"))) TS_TxCreationKeys_get_per_commitment_point(uint32_t this_ptr) { LDKTxCreationKeys this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int8_tArray ret_arr = init_arr(33, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), TxCreationKeys_get_per_commitment_point(&this_ptr_conv).compressed_form, 33); return ret_arr; } void __attribute__((visibility("default"))) TS_TxCreationKeys_set_per_commitment_point(uint32_t this_ptr, int8_tArray val) { LDKTxCreationKeys this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKPublicKey val_ref; CHECK(*((uint32_t*)val) == 33); memcpy(val_ref.compressed_form, (uint8_t*)(val + 4), 33); TxCreationKeys_set_per_commitment_point(&this_ptr_conv, val_ref); } int8_tArray __attribute__((visibility("default"))) TS_TxCreationKeys_get_revocation_key(uint32_t this_ptr) { LDKTxCreationKeys this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int8_tArray ret_arr = init_arr(33, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), TxCreationKeys_get_revocation_key(&this_ptr_conv).compressed_form, 33); return ret_arr; } void __attribute__((visibility("default"))) TS_TxCreationKeys_set_revocation_key(uint32_t this_ptr, int8_tArray val) { LDKTxCreationKeys this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKPublicKey val_ref; CHECK(*((uint32_t*)val) == 33); memcpy(val_ref.compressed_form, (uint8_t*)(val + 4), 33); TxCreationKeys_set_revocation_key(&this_ptr_conv, val_ref); } int8_tArray __attribute__((visibility("default"))) TS_TxCreationKeys_get_broadcaster_htlc_key(uint32_t this_ptr) { LDKTxCreationKeys this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int8_tArray ret_arr = init_arr(33, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), TxCreationKeys_get_broadcaster_htlc_key(&this_ptr_conv).compressed_form, 33); return ret_arr; } void __attribute__((visibility("default"))) TS_TxCreationKeys_set_broadcaster_htlc_key(uint32_t this_ptr, int8_tArray val) { LDKTxCreationKeys this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKPublicKey val_ref; CHECK(*((uint32_t*)val) == 33); memcpy(val_ref.compressed_form, (uint8_t*)(val + 4), 33); TxCreationKeys_set_broadcaster_htlc_key(&this_ptr_conv, val_ref); } int8_tArray __attribute__((visibility("default"))) TS_TxCreationKeys_get_countersignatory_htlc_key(uint32_t this_ptr) { LDKTxCreationKeys this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int8_tArray ret_arr = init_arr(33, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), TxCreationKeys_get_countersignatory_htlc_key(&this_ptr_conv).compressed_form, 33); return ret_arr; } void __attribute__((visibility("default"))) TS_TxCreationKeys_set_countersignatory_htlc_key(uint32_t this_ptr, int8_tArray val) { LDKTxCreationKeys this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKPublicKey val_ref; CHECK(*((uint32_t*)val) == 33); memcpy(val_ref.compressed_form, (uint8_t*)(val + 4), 33); TxCreationKeys_set_countersignatory_htlc_key(&this_ptr_conv, val_ref); } int8_tArray __attribute__((visibility("default"))) TS_TxCreationKeys_get_broadcaster_delayed_payment_key(uint32_t this_ptr) { LDKTxCreationKeys this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int8_tArray ret_arr = init_arr(33, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), TxCreationKeys_get_broadcaster_delayed_payment_key(&this_ptr_conv).compressed_form, 33); return ret_arr; } void __attribute__((visibility("default"))) TS_TxCreationKeys_set_broadcaster_delayed_payment_key(uint32_t this_ptr, int8_tArray val) { LDKTxCreationKeys this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKPublicKey val_ref; CHECK(*((uint32_t*)val) == 33); memcpy(val_ref.compressed_form, (uint8_t*)(val + 4), 33); TxCreationKeys_set_broadcaster_delayed_payment_key(&this_ptr_conv, val_ref); } uint32_t __attribute__((visibility("default"))) TS_TxCreationKeys_new(int8_tArray per_commitment_point_arg, int8_tArray revocation_key_arg, int8_tArray broadcaster_htlc_key_arg, int8_tArray countersignatory_htlc_key_arg, int8_tArray broadcaster_delayed_payment_key_arg) { LDKPublicKey per_commitment_point_arg_ref; CHECK(*((uint32_t*)per_commitment_point_arg) == 33); memcpy(per_commitment_point_arg_ref.compressed_form, (uint8_t*)(per_commitment_point_arg + 4), 33); LDKPublicKey revocation_key_arg_ref; CHECK(*((uint32_t*)revocation_key_arg) == 33); memcpy(revocation_key_arg_ref.compressed_form, (uint8_t*)(revocation_key_arg + 4), 33); LDKPublicKey broadcaster_htlc_key_arg_ref; CHECK(*((uint32_t*)broadcaster_htlc_key_arg) == 33); memcpy(broadcaster_htlc_key_arg_ref.compressed_form, (uint8_t*)(broadcaster_htlc_key_arg + 4), 33); LDKPublicKey countersignatory_htlc_key_arg_ref; CHECK(*((uint32_t*)countersignatory_htlc_key_arg) == 33); memcpy(countersignatory_htlc_key_arg_ref.compressed_form, (uint8_t*)(countersignatory_htlc_key_arg + 4), 33); LDKPublicKey broadcaster_delayed_payment_key_arg_ref; CHECK(*((uint32_t*)broadcaster_delayed_payment_key_arg) == 33); memcpy(broadcaster_delayed_payment_key_arg_ref.compressed_form, (uint8_t*)(broadcaster_delayed_payment_key_arg + 4), 33); LDKTxCreationKeys ret_var = TxCreationKeys_new(per_commitment_point_arg_ref, revocation_key_arg_ref, broadcaster_htlc_key_arg_ref, countersignatory_htlc_key_arg_ref, broadcaster_delayed_payment_key_arg_ref); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_TxCreationKeys_clone(uint32_t orig) { LDKTxCreationKeys orig_conv; orig_conv.inner = (void*)(orig & (~1)); orig_conv.is_owned = false; LDKTxCreationKeys ret_var = TxCreationKeys_clone(&orig_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } int8_tArray __attribute__((visibility("default"))) TS_TxCreationKeys_write(uint32_t obj) { LDKTxCreationKeys obj_conv; obj_conv.inner = (void*)(obj & (~1)); obj_conv.is_owned = false; LDKCVec_u8Z ret_var = TxCreationKeys_write(&obj_conv); int8_tArray ret_arr = init_arr(ret_var.datalen, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), ret_var.data, ret_var.datalen); CVec_u8Z_free(ret_var); return ret_arr; } uint32_t __attribute__((visibility("default"))) TS_TxCreationKeys_read(int8_tArray ser) { LDKu8slice ser_ref; ser_ref.datalen = *((uint32_t*)ser); ser_ref.data = (int8_t*)(ser + 4); LDKCResult_TxCreationKeysDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_TxCreationKeysDecodeErrorZ), "LDKCResult_TxCreationKeysDecodeErrorZ"); *ret_conv = TxCreationKeys_read(ser_ref); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_ChannelPublicKeys_free(uint32_t this_obj) { LDKChannelPublicKeys this_obj_conv; this_obj_conv.inner = (void*)(this_obj & (~1)); this_obj_conv.is_owned = (this_obj & 1) || (this_obj == 0); ChannelPublicKeys_free(this_obj_conv); } int8_tArray __attribute__((visibility("default"))) TS_ChannelPublicKeys_get_funding_pubkey(uint32_t this_ptr) { LDKChannelPublicKeys this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int8_tArray ret_arr = init_arr(33, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), ChannelPublicKeys_get_funding_pubkey(&this_ptr_conv).compressed_form, 33); return ret_arr; } void __attribute__((visibility("default"))) TS_ChannelPublicKeys_set_funding_pubkey(uint32_t this_ptr, int8_tArray val) { LDKChannelPublicKeys this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKPublicKey val_ref; CHECK(*((uint32_t*)val) == 33); memcpy(val_ref.compressed_form, (uint8_t*)(val + 4), 33); ChannelPublicKeys_set_funding_pubkey(&this_ptr_conv, val_ref); } int8_tArray __attribute__((visibility("default"))) TS_ChannelPublicKeys_get_revocation_basepoint(uint32_t this_ptr) { LDKChannelPublicKeys this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int8_tArray ret_arr = init_arr(33, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), ChannelPublicKeys_get_revocation_basepoint(&this_ptr_conv).compressed_form, 33); return ret_arr; } void __attribute__((visibility("default"))) TS_ChannelPublicKeys_set_revocation_basepoint(uint32_t this_ptr, int8_tArray val) { LDKChannelPublicKeys this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKPublicKey val_ref; CHECK(*((uint32_t*)val) == 33); memcpy(val_ref.compressed_form, (uint8_t*)(val + 4), 33); ChannelPublicKeys_set_revocation_basepoint(&this_ptr_conv, val_ref); } int8_tArray __attribute__((visibility("default"))) TS_ChannelPublicKeys_get_payment_point(uint32_t this_ptr) { LDKChannelPublicKeys this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int8_tArray ret_arr = init_arr(33, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), ChannelPublicKeys_get_payment_point(&this_ptr_conv).compressed_form, 33); return ret_arr; } void __attribute__((visibility("default"))) TS_ChannelPublicKeys_set_payment_point(uint32_t this_ptr, int8_tArray val) { LDKChannelPublicKeys this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKPublicKey val_ref; CHECK(*((uint32_t*)val) == 33); memcpy(val_ref.compressed_form, (uint8_t*)(val + 4), 33); ChannelPublicKeys_set_payment_point(&this_ptr_conv, val_ref); } int8_tArray __attribute__((visibility("default"))) TS_ChannelPublicKeys_get_delayed_payment_basepoint(uint32_t this_ptr) { LDKChannelPublicKeys this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int8_tArray ret_arr = init_arr(33, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), ChannelPublicKeys_get_delayed_payment_basepoint(&this_ptr_conv).compressed_form, 33); return ret_arr; } void __attribute__((visibility("default"))) TS_ChannelPublicKeys_set_delayed_payment_basepoint(uint32_t this_ptr, int8_tArray val) { LDKChannelPublicKeys this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKPublicKey val_ref; CHECK(*((uint32_t*)val) == 33); memcpy(val_ref.compressed_form, (uint8_t*)(val + 4), 33); ChannelPublicKeys_set_delayed_payment_basepoint(&this_ptr_conv, val_ref); } int8_tArray __attribute__((visibility("default"))) TS_ChannelPublicKeys_get_htlc_basepoint(uint32_t this_ptr) { LDKChannelPublicKeys this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int8_tArray ret_arr = init_arr(33, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), ChannelPublicKeys_get_htlc_basepoint(&this_ptr_conv).compressed_form, 33); return ret_arr; } void __attribute__((visibility("default"))) TS_ChannelPublicKeys_set_htlc_basepoint(uint32_t this_ptr, int8_tArray val) { LDKChannelPublicKeys this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKPublicKey val_ref; CHECK(*((uint32_t*)val) == 33); memcpy(val_ref.compressed_form, (uint8_t*)(val + 4), 33); ChannelPublicKeys_set_htlc_basepoint(&this_ptr_conv, val_ref); } uint32_t __attribute__((visibility("default"))) TS_ChannelPublicKeys_new(int8_tArray funding_pubkey_arg, int8_tArray revocation_basepoint_arg, int8_tArray payment_point_arg, int8_tArray delayed_payment_basepoint_arg, int8_tArray htlc_basepoint_arg) { LDKPublicKey funding_pubkey_arg_ref; CHECK(*((uint32_t*)funding_pubkey_arg) == 33); memcpy(funding_pubkey_arg_ref.compressed_form, (uint8_t*)(funding_pubkey_arg + 4), 33); LDKPublicKey revocation_basepoint_arg_ref; CHECK(*((uint32_t*)revocation_basepoint_arg) == 33); memcpy(revocation_basepoint_arg_ref.compressed_form, (uint8_t*)(revocation_basepoint_arg + 4), 33); LDKPublicKey payment_point_arg_ref; CHECK(*((uint32_t*)payment_point_arg) == 33); memcpy(payment_point_arg_ref.compressed_form, (uint8_t*)(payment_point_arg + 4), 33); LDKPublicKey delayed_payment_basepoint_arg_ref; CHECK(*((uint32_t*)delayed_payment_basepoint_arg) == 33); memcpy(delayed_payment_basepoint_arg_ref.compressed_form, (uint8_t*)(delayed_payment_basepoint_arg + 4), 33); LDKPublicKey htlc_basepoint_arg_ref; CHECK(*((uint32_t*)htlc_basepoint_arg) == 33); memcpy(htlc_basepoint_arg_ref.compressed_form, (uint8_t*)(htlc_basepoint_arg + 4), 33); LDKChannelPublicKeys ret_var = ChannelPublicKeys_new(funding_pubkey_arg_ref, revocation_basepoint_arg_ref, payment_point_arg_ref, delayed_payment_basepoint_arg_ref, htlc_basepoint_arg_ref); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_ChannelPublicKeys_clone(uint32_t orig) { LDKChannelPublicKeys orig_conv; orig_conv.inner = (void*)(orig & (~1)); orig_conv.is_owned = false; LDKChannelPublicKeys ret_var = ChannelPublicKeys_clone(&orig_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } int8_tArray __attribute__((visibility("default"))) TS_ChannelPublicKeys_write(uint32_t obj) { LDKChannelPublicKeys obj_conv; obj_conv.inner = (void*)(obj & (~1)); obj_conv.is_owned = false; LDKCVec_u8Z ret_var = ChannelPublicKeys_write(&obj_conv); int8_tArray ret_arr = init_arr(ret_var.datalen, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), ret_var.data, ret_var.datalen); CVec_u8Z_free(ret_var); return ret_arr; } uint32_t __attribute__((visibility("default"))) TS_ChannelPublicKeys_read(int8_tArray ser) { LDKu8slice ser_ref; ser_ref.datalen = *((uint32_t*)ser); ser_ref.data = (int8_t*)(ser + 4); LDKCResult_ChannelPublicKeysDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_ChannelPublicKeysDecodeErrorZ), "LDKCResult_ChannelPublicKeysDecodeErrorZ"); *ret_conv = ChannelPublicKeys_read(ser_ref); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_TxCreationKeys_derive_new(int8_tArray per_commitment_point, int8_tArray broadcaster_delayed_payment_base, int8_tArray broadcaster_htlc_base, int8_tArray countersignatory_revocation_base, int8_tArray countersignatory_htlc_base) { LDKPublicKey per_commitment_point_ref; CHECK(*((uint32_t*)per_commitment_point) == 33); memcpy(per_commitment_point_ref.compressed_form, (uint8_t*)(per_commitment_point + 4), 33); LDKPublicKey broadcaster_delayed_payment_base_ref; CHECK(*((uint32_t*)broadcaster_delayed_payment_base) == 33); memcpy(broadcaster_delayed_payment_base_ref.compressed_form, (uint8_t*)(broadcaster_delayed_payment_base + 4), 33); LDKPublicKey broadcaster_htlc_base_ref; CHECK(*((uint32_t*)broadcaster_htlc_base) == 33); memcpy(broadcaster_htlc_base_ref.compressed_form, (uint8_t*)(broadcaster_htlc_base + 4), 33); LDKPublicKey countersignatory_revocation_base_ref; CHECK(*((uint32_t*)countersignatory_revocation_base) == 33); memcpy(countersignatory_revocation_base_ref.compressed_form, (uint8_t*)(countersignatory_revocation_base + 4), 33); LDKPublicKey countersignatory_htlc_base_ref; CHECK(*((uint32_t*)countersignatory_htlc_base) == 33); memcpy(countersignatory_htlc_base_ref.compressed_form, (uint8_t*)(countersignatory_htlc_base + 4), 33); LDKCResult_TxCreationKeysErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_TxCreationKeysErrorZ), "LDKCResult_TxCreationKeysErrorZ"); *ret_conv = TxCreationKeys_derive_new(per_commitment_point_ref, broadcaster_delayed_payment_base_ref, broadcaster_htlc_base_ref, countersignatory_revocation_base_ref, countersignatory_htlc_base_ref); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_TxCreationKeys_from_channel_static_keys(int8_tArray per_commitment_point, uint32_t broadcaster_keys, uint32_t countersignatory_keys) { LDKPublicKey per_commitment_point_ref; CHECK(*((uint32_t*)per_commitment_point) == 33); memcpy(per_commitment_point_ref.compressed_form, (uint8_t*)(per_commitment_point + 4), 33); LDKChannelPublicKeys broadcaster_keys_conv; broadcaster_keys_conv.inner = (void*)(broadcaster_keys & (~1)); broadcaster_keys_conv.is_owned = false; LDKChannelPublicKeys countersignatory_keys_conv; countersignatory_keys_conv.inner = (void*)(countersignatory_keys & (~1)); countersignatory_keys_conv.is_owned = false; LDKCResult_TxCreationKeysErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_TxCreationKeysErrorZ), "LDKCResult_TxCreationKeysErrorZ"); *ret_conv = TxCreationKeys_from_channel_static_keys(per_commitment_point_ref, &broadcaster_keys_conv, &countersignatory_keys_conv); return (uint64_t)ret_conv; } int8_tArray __attribute__((visibility("default"))) TS_get_revokeable_redeemscript(int8_tArray revocation_key, int16_t contest_delay, int8_tArray broadcaster_delayed_payment_key) { LDKPublicKey revocation_key_ref; CHECK(*((uint32_t*)revocation_key) == 33); memcpy(revocation_key_ref.compressed_form, (uint8_t*)(revocation_key + 4), 33); LDKPublicKey broadcaster_delayed_payment_key_ref; CHECK(*((uint32_t*)broadcaster_delayed_payment_key) == 33); memcpy(broadcaster_delayed_payment_key_ref.compressed_form, (uint8_t*)(broadcaster_delayed_payment_key + 4), 33); LDKCVec_u8Z ret_var = get_revokeable_redeemscript(revocation_key_ref, contest_delay, broadcaster_delayed_payment_key_ref); int8_tArray ret_arr = init_arr(ret_var.datalen, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), ret_var.data, ret_var.datalen); CVec_u8Z_free(ret_var); return ret_arr; } void __attribute__((visibility("default"))) TS_HTLCOutputInCommitment_free(uint32_t this_obj) { LDKHTLCOutputInCommitment this_obj_conv; this_obj_conv.inner = (void*)(this_obj & (~1)); this_obj_conv.is_owned = (this_obj & 1) || (this_obj == 0); HTLCOutputInCommitment_free(this_obj_conv); } jboolean __attribute__((visibility("default"))) TS_HTLCOutputInCommitment_get_offered(uint32_t this_ptr) { LDKHTLCOutputInCommitment this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; jboolean ret_val = HTLCOutputInCommitment_get_offered(&this_ptr_conv); return ret_val; } void __attribute__((visibility("default"))) TS_HTLCOutputInCommitment_set_offered(uint32_t this_ptr, jboolean val) { LDKHTLCOutputInCommitment this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; HTLCOutputInCommitment_set_offered(&this_ptr_conv, val); } int64_t __attribute__((visibility("default"))) TS_HTLCOutputInCommitment_get_amount_msat(uint32_t this_ptr) { LDKHTLCOutputInCommitment this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int64_t ret_val = HTLCOutputInCommitment_get_amount_msat(&this_ptr_conv); return ret_val; } void __attribute__((visibility("default"))) TS_HTLCOutputInCommitment_set_amount_msat(uint32_t this_ptr, int64_t val) { LDKHTLCOutputInCommitment this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; HTLCOutputInCommitment_set_amount_msat(&this_ptr_conv, val); } int32_t __attribute__((visibility("default"))) TS_HTLCOutputInCommitment_get_cltv_expiry(uint32_t this_ptr) { LDKHTLCOutputInCommitment this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int32_t ret_val = HTLCOutputInCommitment_get_cltv_expiry(&this_ptr_conv); return ret_val; } void __attribute__((visibility("default"))) TS_HTLCOutputInCommitment_set_cltv_expiry(uint32_t this_ptr, int32_t val) { LDKHTLCOutputInCommitment this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; HTLCOutputInCommitment_set_cltv_expiry(&this_ptr_conv, val); } int8_tArray __attribute__((visibility("default"))) TS_HTLCOutputInCommitment_get_payment_hash(uint32_t this_ptr) { LDKHTLCOutputInCommitment this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int8_tArray ret_arr = init_arr(32, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), *HTLCOutputInCommitment_get_payment_hash(&this_ptr_conv), 32); return ret_arr; } void __attribute__((visibility("default"))) TS_HTLCOutputInCommitment_set_payment_hash(uint32_t this_ptr, int8_tArray val) { LDKHTLCOutputInCommitment this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKThirtyTwoBytes val_ref; CHECK(*((uint32_t*)val) == 32); memcpy(val_ref.data, (uint8_t*)(val + 4), 32); HTLCOutputInCommitment_set_payment_hash(&this_ptr_conv, val_ref); } uint32_t __attribute__((visibility("default"))) TS_HTLCOutputInCommitment_get_transaction_output_index(uint32_t this_ptr) { LDKHTLCOutputInCommitment this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKCOption_u32Z *ret_copy = MALLOC(sizeof(LDKCOption_u32Z), "LDKCOption_u32Z"); *ret_copy = HTLCOutputInCommitment_get_transaction_output_index(&this_ptr_conv); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } void __attribute__((visibility("default"))) TS_HTLCOutputInCommitment_set_transaction_output_index(uint32_t this_ptr, uint32_t val) { LDKHTLCOutputInCommitment this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKCOption_u32Z val_conv = *(LDKCOption_u32Z*)(((uint64_t)val) & ~1); val_conv = COption_u32Z_clone((LDKCOption_u32Z*)(((uint64_t)val) & ~1)); HTLCOutputInCommitment_set_transaction_output_index(&this_ptr_conv, val_conv); } uint32_t __attribute__((visibility("default"))) TS_HTLCOutputInCommitment_new(jboolean offered_arg, int64_t amount_msat_arg, int32_t cltv_expiry_arg, int8_tArray payment_hash_arg, uint32_t transaction_output_index_arg) { LDKThirtyTwoBytes payment_hash_arg_ref; CHECK(*((uint32_t*)payment_hash_arg) == 32); memcpy(payment_hash_arg_ref.data, (uint8_t*)(payment_hash_arg + 4), 32); LDKCOption_u32Z transaction_output_index_arg_conv = *(LDKCOption_u32Z*)(((uint64_t)transaction_output_index_arg) & ~1); transaction_output_index_arg_conv = COption_u32Z_clone((LDKCOption_u32Z*)(((uint64_t)transaction_output_index_arg) & ~1)); LDKHTLCOutputInCommitment ret_var = HTLCOutputInCommitment_new(offered_arg, amount_msat_arg, cltv_expiry_arg, payment_hash_arg_ref, transaction_output_index_arg_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_HTLCOutputInCommitment_clone(uint32_t orig) { LDKHTLCOutputInCommitment orig_conv; orig_conv.inner = (void*)(orig & (~1)); orig_conv.is_owned = false; LDKHTLCOutputInCommitment ret_var = HTLCOutputInCommitment_clone(&orig_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } int8_tArray __attribute__((visibility("default"))) TS_HTLCOutputInCommitment_write(uint32_t obj) { LDKHTLCOutputInCommitment obj_conv; obj_conv.inner = (void*)(obj & (~1)); obj_conv.is_owned = false; LDKCVec_u8Z ret_var = HTLCOutputInCommitment_write(&obj_conv); int8_tArray ret_arr = init_arr(ret_var.datalen, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), ret_var.data, ret_var.datalen); CVec_u8Z_free(ret_var); return ret_arr; } uint32_t __attribute__((visibility("default"))) TS_HTLCOutputInCommitment_read(int8_tArray ser) { LDKu8slice ser_ref; ser_ref.datalen = *((uint32_t*)ser); ser_ref.data = (int8_t*)(ser + 4); LDKCResult_HTLCOutputInCommitmentDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_HTLCOutputInCommitmentDecodeErrorZ), "LDKCResult_HTLCOutputInCommitmentDecodeErrorZ"); *ret_conv = HTLCOutputInCommitment_read(ser_ref); return (uint64_t)ret_conv; } int8_tArray __attribute__((visibility("default"))) TS_get_htlc_redeemscript(uint32_t htlc, uint32_t keys) { LDKHTLCOutputInCommitment htlc_conv; htlc_conv.inner = (void*)(htlc & (~1)); htlc_conv.is_owned = false; LDKTxCreationKeys keys_conv; keys_conv.inner = (void*)(keys & (~1)); keys_conv.is_owned = false; LDKCVec_u8Z ret_var = get_htlc_redeemscript(&htlc_conv, &keys_conv); int8_tArray ret_arr = init_arr(ret_var.datalen, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), ret_var.data, ret_var.datalen); CVec_u8Z_free(ret_var); return ret_arr; } int8_tArray __attribute__((visibility("default"))) TS_make_funding_redeemscript(int8_tArray broadcaster, int8_tArray countersignatory) { LDKPublicKey broadcaster_ref; CHECK(*((uint32_t*)broadcaster) == 33); memcpy(broadcaster_ref.compressed_form, (uint8_t*)(broadcaster + 4), 33); LDKPublicKey countersignatory_ref; CHECK(*((uint32_t*)countersignatory) == 33); memcpy(countersignatory_ref.compressed_form, (uint8_t*)(countersignatory + 4), 33); LDKCVec_u8Z ret_var = make_funding_redeemscript(broadcaster_ref, countersignatory_ref); int8_tArray ret_arr = init_arr(ret_var.datalen, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), ret_var.data, ret_var.datalen); CVec_u8Z_free(ret_var); return ret_arr; } int8_tArray __attribute__((visibility("default"))) TS_build_htlc_transaction(int8_tArray commitment_txid, int32_t feerate_per_kw, int16_t contest_delay, uint32_t htlc, int8_tArray broadcaster_delayed_payment_key, int8_tArray revocation_key) { unsigned char commitment_txid_arr[32]; CHECK(*((uint32_t*)commitment_txid) == 32); memcpy(commitment_txid_arr, (uint8_t*)(commitment_txid + 4), 32); unsigned char (*commitment_txid_ref)[32] = &commitment_txid_arr; LDKHTLCOutputInCommitment htlc_conv; htlc_conv.inner = (void*)(htlc & (~1)); htlc_conv.is_owned = false; LDKPublicKey broadcaster_delayed_payment_key_ref; CHECK(*((uint32_t*)broadcaster_delayed_payment_key) == 33); memcpy(broadcaster_delayed_payment_key_ref.compressed_form, (uint8_t*)(broadcaster_delayed_payment_key + 4), 33); LDKPublicKey revocation_key_ref; CHECK(*((uint32_t*)revocation_key) == 33); memcpy(revocation_key_ref.compressed_form, (uint8_t*)(revocation_key + 4), 33); LDKTransaction ret_var = build_htlc_transaction(commitment_txid_ref, feerate_per_kw, contest_delay, &htlc_conv, broadcaster_delayed_payment_key_ref, revocation_key_ref); int8_tArray ret_arr = init_arr(ret_var.datalen, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), ret_var.data, ret_var.datalen); Transaction_free(ret_var); return ret_arr; } void __attribute__((visibility("default"))) TS_ChannelTransactionParameters_free(uint32_t this_obj) { LDKChannelTransactionParameters this_obj_conv; this_obj_conv.inner = (void*)(this_obj & (~1)); this_obj_conv.is_owned = (this_obj & 1) || (this_obj == 0); ChannelTransactionParameters_free(this_obj_conv); } uint32_t __attribute__((visibility("default"))) TS_ChannelTransactionParameters_get_holder_pubkeys(uint32_t this_ptr) { LDKChannelTransactionParameters this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKChannelPublicKeys ret_var = ChannelTransactionParameters_get_holder_pubkeys(&this_ptr_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } void __attribute__((visibility("default"))) TS_ChannelTransactionParameters_set_holder_pubkeys(uint32_t this_ptr, uint32_t val) { LDKChannelTransactionParameters this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKChannelPublicKeys val_conv; val_conv.inner = (void*)(val & (~1)); val_conv.is_owned = (val & 1) || (val == 0); val_conv = ChannelPublicKeys_clone(&val_conv); ChannelTransactionParameters_set_holder_pubkeys(&this_ptr_conv, val_conv); } int16_t __attribute__((visibility("default"))) TS_ChannelTransactionParameters_get_holder_selected_contest_delay(uint32_t this_ptr) { LDKChannelTransactionParameters this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int16_t ret_val = ChannelTransactionParameters_get_holder_selected_contest_delay(&this_ptr_conv); return ret_val; } void __attribute__((visibility("default"))) TS_ChannelTransactionParameters_set_holder_selected_contest_delay(uint32_t this_ptr, int16_t val) { LDKChannelTransactionParameters this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; ChannelTransactionParameters_set_holder_selected_contest_delay(&this_ptr_conv, val); } jboolean __attribute__((visibility("default"))) TS_ChannelTransactionParameters_get_is_outbound_from_holder(uint32_t this_ptr) { LDKChannelTransactionParameters this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; jboolean ret_val = ChannelTransactionParameters_get_is_outbound_from_holder(&this_ptr_conv); return ret_val; } void __attribute__((visibility("default"))) TS_ChannelTransactionParameters_set_is_outbound_from_holder(uint32_t this_ptr, jboolean val) { LDKChannelTransactionParameters this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; ChannelTransactionParameters_set_is_outbound_from_holder(&this_ptr_conv, val); } uint32_t __attribute__((visibility("default"))) TS_ChannelTransactionParameters_get_counterparty_parameters(uint32_t this_ptr) { LDKChannelTransactionParameters this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKCounterpartyChannelTransactionParameters ret_var = ChannelTransactionParameters_get_counterparty_parameters(&this_ptr_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } void __attribute__((visibility("default"))) TS_ChannelTransactionParameters_set_counterparty_parameters(uint32_t this_ptr, uint32_t val) { LDKChannelTransactionParameters this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKCounterpartyChannelTransactionParameters val_conv; val_conv.inner = (void*)(val & (~1)); val_conv.is_owned = (val & 1) || (val == 0); val_conv = CounterpartyChannelTransactionParameters_clone(&val_conv); ChannelTransactionParameters_set_counterparty_parameters(&this_ptr_conv, val_conv); } uint32_t __attribute__((visibility("default"))) TS_ChannelTransactionParameters_get_funding_outpoint(uint32_t this_ptr) { LDKChannelTransactionParameters this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKOutPoint ret_var = ChannelTransactionParameters_get_funding_outpoint(&this_ptr_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } void __attribute__((visibility("default"))) TS_ChannelTransactionParameters_set_funding_outpoint(uint32_t this_ptr, uint32_t val) { LDKChannelTransactionParameters this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKOutPoint val_conv; val_conv.inner = (void*)(val & (~1)); val_conv.is_owned = (val & 1) || (val == 0); val_conv = OutPoint_clone(&val_conv); ChannelTransactionParameters_set_funding_outpoint(&this_ptr_conv, val_conv); } uint32_t __attribute__((visibility("default"))) TS_ChannelTransactionParameters_new(uint32_t holder_pubkeys_arg, int16_t holder_selected_contest_delay_arg, jboolean is_outbound_from_holder_arg, uint32_t counterparty_parameters_arg, uint32_t funding_outpoint_arg) { LDKChannelPublicKeys holder_pubkeys_arg_conv; holder_pubkeys_arg_conv.inner = (void*)(holder_pubkeys_arg & (~1)); holder_pubkeys_arg_conv.is_owned = (holder_pubkeys_arg & 1) || (holder_pubkeys_arg == 0); holder_pubkeys_arg_conv = ChannelPublicKeys_clone(&holder_pubkeys_arg_conv); LDKCounterpartyChannelTransactionParameters counterparty_parameters_arg_conv; counterparty_parameters_arg_conv.inner = (void*)(counterparty_parameters_arg & (~1)); counterparty_parameters_arg_conv.is_owned = (counterparty_parameters_arg & 1) || (counterparty_parameters_arg == 0); counterparty_parameters_arg_conv = CounterpartyChannelTransactionParameters_clone(&counterparty_parameters_arg_conv); LDKOutPoint funding_outpoint_arg_conv; funding_outpoint_arg_conv.inner = (void*)(funding_outpoint_arg & (~1)); funding_outpoint_arg_conv.is_owned = (funding_outpoint_arg & 1) || (funding_outpoint_arg == 0); funding_outpoint_arg_conv = OutPoint_clone(&funding_outpoint_arg_conv); LDKChannelTransactionParameters ret_var = ChannelTransactionParameters_new(holder_pubkeys_arg_conv, holder_selected_contest_delay_arg, is_outbound_from_holder_arg, counterparty_parameters_arg_conv, funding_outpoint_arg_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_ChannelTransactionParameters_clone(uint32_t orig) { LDKChannelTransactionParameters orig_conv; orig_conv.inner = (void*)(orig & (~1)); orig_conv.is_owned = false; LDKChannelTransactionParameters ret_var = ChannelTransactionParameters_clone(&orig_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } void __attribute__((visibility("default"))) TS_CounterpartyChannelTransactionParameters_free(uint32_t this_obj) { LDKCounterpartyChannelTransactionParameters this_obj_conv; this_obj_conv.inner = (void*)(this_obj & (~1)); this_obj_conv.is_owned = (this_obj & 1) || (this_obj == 0); CounterpartyChannelTransactionParameters_free(this_obj_conv); } uint32_t __attribute__((visibility("default"))) TS_CounterpartyChannelTransactionParameters_get_pubkeys(uint32_t this_ptr) { LDKCounterpartyChannelTransactionParameters this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKChannelPublicKeys ret_var = CounterpartyChannelTransactionParameters_get_pubkeys(&this_ptr_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } void __attribute__((visibility("default"))) TS_CounterpartyChannelTransactionParameters_set_pubkeys(uint32_t this_ptr, uint32_t val) { LDKCounterpartyChannelTransactionParameters this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKChannelPublicKeys val_conv; val_conv.inner = (void*)(val & (~1)); val_conv.is_owned = (val & 1) || (val == 0); val_conv = ChannelPublicKeys_clone(&val_conv); CounterpartyChannelTransactionParameters_set_pubkeys(&this_ptr_conv, val_conv); } int16_t __attribute__((visibility("default"))) TS_CounterpartyChannelTransactionParameters_get_selected_contest_delay(uint32_t this_ptr) { LDKCounterpartyChannelTransactionParameters this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int16_t ret_val = CounterpartyChannelTransactionParameters_get_selected_contest_delay(&this_ptr_conv); return ret_val; } void __attribute__((visibility("default"))) TS_CounterpartyChannelTransactionParameters_set_selected_contest_delay(uint32_t this_ptr, int16_t val) { LDKCounterpartyChannelTransactionParameters this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; CounterpartyChannelTransactionParameters_set_selected_contest_delay(&this_ptr_conv, val); } uint32_t __attribute__((visibility("default"))) TS_CounterpartyChannelTransactionParameters_new(uint32_t pubkeys_arg, int16_t selected_contest_delay_arg) { LDKChannelPublicKeys pubkeys_arg_conv; pubkeys_arg_conv.inner = (void*)(pubkeys_arg & (~1)); pubkeys_arg_conv.is_owned = (pubkeys_arg & 1) || (pubkeys_arg == 0); pubkeys_arg_conv = ChannelPublicKeys_clone(&pubkeys_arg_conv); LDKCounterpartyChannelTransactionParameters ret_var = CounterpartyChannelTransactionParameters_new(pubkeys_arg_conv, selected_contest_delay_arg); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_CounterpartyChannelTransactionParameters_clone(uint32_t orig) { LDKCounterpartyChannelTransactionParameters orig_conv; orig_conv.inner = (void*)(orig & (~1)); orig_conv.is_owned = false; LDKCounterpartyChannelTransactionParameters ret_var = CounterpartyChannelTransactionParameters_clone(&orig_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } jboolean __attribute__((visibility("default"))) TS_ChannelTransactionParameters_is_populated(uint32_t this_arg) { LDKChannelTransactionParameters this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; jboolean ret_val = ChannelTransactionParameters_is_populated(&this_arg_conv); return ret_val; } uint32_t __attribute__((visibility("default"))) TS_ChannelTransactionParameters_as_holder_broadcastable(uint32_t this_arg) { LDKChannelTransactionParameters this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; LDKDirectedChannelTransactionParameters ret_var = ChannelTransactionParameters_as_holder_broadcastable(&this_arg_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_ChannelTransactionParameters_as_counterparty_broadcastable(uint32_t this_arg) { LDKChannelTransactionParameters this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; LDKDirectedChannelTransactionParameters ret_var = ChannelTransactionParameters_as_counterparty_broadcastable(&this_arg_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } int8_tArray __attribute__((visibility("default"))) TS_CounterpartyChannelTransactionParameters_write(uint32_t obj) { LDKCounterpartyChannelTransactionParameters obj_conv; obj_conv.inner = (void*)(obj & (~1)); obj_conv.is_owned = false; LDKCVec_u8Z ret_var = CounterpartyChannelTransactionParameters_write(&obj_conv); int8_tArray ret_arr = init_arr(ret_var.datalen, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), ret_var.data, ret_var.datalen); CVec_u8Z_free(ret_var); return ret_arr; } uint32_t __attribute__((visibility("default"))) TS_CounterpartyChannelTransactionParameters_read(int8_tArray ser) { LDKu8slice ser_ref; ser_ref.datalen = *((uint32_t*)ser); ser_ref.data = (int8_t*)(ser + 4); LDKCResult_CounterpartyChannelTransactionParametersDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_CounterpartyChannelTransactionParametersDecodeErrorZ), "LDKCResult_CounterpartyChannelTransactionParametersDecodeErrorZ"); *ret_conv = CounterpartyChannelTransactionParameters_read(ser_ref); return (uint64_t)ret_conv; } int8_tArray __attribute__((visibility("default"))) TS_ChannelTransactionParameters_write(uint32_t obj) { LDKChannelTransactionParameters obj_conv; obj_conv.inner = (void*)(obj & (~1)); obj_conv.is_owned = false; LDKCVec_u8Z ret_var = ChannelTransactionParameters_write(&obj_conv); int8_tArray ret_arr = init_arr(ret_var.datalen, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), ret_var.data, ret_var.datalen); CVec_u8Z_free(ret_var); return ret_arr; } uint32_t __attribute__((visibility("default"))) TS_ChannelTransactionParameters_read(int8_tArray ser) { LDKu8slice ser_ref; ser_ref.datalen = *((uint32_t*)ser); ser_ref.data = (int8_t*)(ser + 4); LDKCResult_ChannelTransactionParametersDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_ChannelTransactionParametersDecodeErrorZ), "LDKCResult_ChannelTransactionParametersDecodeErrorZ"); *ret_conv = ChannelTransactionParameters_read(ser_ref); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_DirectedChannelTransactionParameters_free(uint32_t this_obj) { LDKDirectedChannelTransactionParameters this_obj_conv; this_obj_conv.inner = (void*)(this_obj & (~1)); this_obj_conv.is_owned = (this_obj & 1) || (this_obj == 0); DirectedChannelTransactionParameters_free(this_obj_conv); } uint32_t __attribute__((visibility("default"))) TS_DirectedChannelTransactionParameters_broadcaster_pubkeys(uint32_t this_arg) { LDKDirectedChannelTransactionParameters this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; LDKChannelPublicKeys ret_var = DirectedChannelTransactionParameters_broadcaster_pubkeys(&this_arg_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_DirectedChannelTransactionParameters_countersignatory_pubkeys(uint32_t this_arg) { LDKDirectedChannelTransactionParameters this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; LDKChannelPublicKeys ret_var = DirectedChannelTransactionParameters_countersignatory_pubkeys(&this_arg_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } int16_t __attribute__((visibility("default"))) TS_DirectedChannelTransactionParameters_contest_delay(uint32_t this_arg) { LDKDirectedChannelTransactionParameters this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; int16_t ret_val = DirectedChannelTransactionParameters_contest_delay(&this_arg_conv); return ret_val; } jboolean __attribute__((visibility("default"))) TS_DirectedChannelTransactionParameters_is_outbound(uint32_t this_arg) { LDKDirectedChannelTransactionParameters this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; jboolean ret_val = DirectedChannelTransactionParameters_is_outbound(&this_arg_conv); return ret_val; } uint32_t __attribute__((visibility("default"))) TS_DirectedChannelTransactionParameters_funding_outpoint(uint32_t this_arg) { LDKDirectedChannelTransactionParameters this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; LDKOutPoint ret_var = DirectedChannelTransactionParameters_funding_outpoint(&this_arg_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } void __attribute__((visibility("default"))) TS_HolderCommitmentTransaction_free(uint32_t this_obj) { LDKHolderCommitmentTransaction this_obj_conv; this_obj_conv.inner = (void*)(this_obj & (~1)); this_obj_conv.is_owned = (this_obj & 1) || (this_obj == 0); HolderCommitmentTransaction_free(this_obj_conv); } int8_tArray __attribute__((visibility("default"))) TS_HolderCommitmentTransaction_get_counterparty_sig(uint32_t this_ptr) { LDKHolderCommitmentTransaction this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int8_tArray ret_arr = init_arr(64, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), HolderCommitmentTransaction_get_counterparty_sig(&this_ptr_conv).compact_form, 64); return ret_arr; } void __attribute__((visibility("default"))) TS_HolderCommitmentTransaction_set_counterparty_sig(uint32_t this_ptr, int8_tArray val) { LDKHolderCommitmentTransaction this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKSignature val_ref; CHECK(*((uint32_t*)val) == 64); memcpy(val_ref.compact_form, (uint8_t*)(val + 4), 64); HolderCommitmentTransaction_set_counterparty_sig(&this_ptr_conv, val_ref); } void __attribute__((visibility("default"))) TS_HolderCommitmentTransaction_set_counterparty_htlc_sigs(uint32_t this_ptr, ptrArray val) { LDKHolderCommitmentTransaction this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKCVec_SignatureZ val_constr; val_constr.datalen = *((uint32_t*)val); if (val_constr.datalen > 0) val_constr.data = MALLOC(val_constr.datalen * sizeof(LDKSignature), "LDKCVec_SignatureZ Elements"); else val_constr.data = NULL; int8_tArray* val_vals = (int8_tArray*)(val + 4); for (size_t m = 0; m < val_constr.datalen; m++) { int8_tArray val_conv_12 = val_vals[m]; LDKSignature val_conv_12_ref; CHECK(*((uint32_t*)val_conv_12) == 64); memcpy(val_conv_12_ref.compact_form, (uint8_t*)(val_conv_12 + 4), 64); val_constr.data[m] = val_conv_12_ref; } HolderCommitmentTransaction_set_counterparty_htlc_sigs(&this_ptr_conv, val_constr); } uint32_t __attribute__((visibility("default"))) TS_HolderCommitmentTransaction_clone(uint32_t orig) { LDKHolderCommitmentTransaction orig_conv; orig_conv.inner = (void*)(orig & (~1)); orig_conv.is_owned = false; LDKHolderCommitmentTransaction ret_var = HolderCommitmentTransaction_clone(&orig_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } int8_tArray __attribute__((visibility("default"))) TS_HolderCommitmentTransaction_write(uint32_t obj) { LDKHolderCommitmentTransaction obj_conv; obj_conv.inner = (void*)(obj & (~1)); obj_conv.is_owned = false; LDKCVec_u8Z ret_var = HolderCommitmentTransaction_write(&obj_conv); int8_tArray ret_arr = init_arr(ret_var.datalen, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), ret_var.data, ret_var.datalen); CVec_u8Z_free(ret_var); return ret_arr; } uint32_t __attribute__((visibility("default"))) TS_HolderCommitmentTransaction_read(int8_tArray ser) { LDKu8slice ser_ref; ser_ref.datalen = *((uint32_t*)ser); ser_ref.data = (int8_t*)(ser + 4); LDKCResult_HolderCommitmentTransactionDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_HolderCommitmentTransactionDecodeErrorZ), "LDKCResult_HolderCommitmentTransactionDecodeErrorZ"); *ret_conv = HolderCommitmentTransaction_read(ser_ref); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_HolderCommitmentTransaction_new(uint32_t commitment_tx, int8_tArray counterparty_sig, ptrArray counterparty_htlc_sigs, int8_tArray holder_funding_key, int8_tArray counterparty_funding_key) { LDKCommitmentTransaction commitment_tx_conv; commitment_tx_conv.inner = (void*)(commitment_tx & (~1)); commitment_tx_conv.is_owned = (commitment_tx & 1) || (commitment_tx == 0); commitment_tx_conv = CommitmentTransaction_clone(&commitment_tx_conv); LDKSignature counterparty_sig_ref; CHECK(*((uint32_t*)counterparty_sig) == 64); memcpy(counterparty_sig_ref.compact_form, (uint8_t*)(counterparty_sig + 4), 64); LDKCVec_SignatureZ counterparty_htlc_sigs_constr; counterparty_htlc_sigs_constr.datalen = *((uint32_t*)counterparty_htlc_sigs); if (counterparty_htlc_sigs_constr.datalen > 0) counterparty_htlc_sigs_constr.data = MALLOC(counterparty_htlc_sigs_constr.datalen * sizeof(LDKSignature), "LDKCVec_SignatureZ Elements"); else counterparty_htlc_sigs_constr.data = NULL; int8_tArray* counterparty_htlc_sigs_vals = (int8_tArray*)(counterparty_htlc_sigs + 4); for (size_t m = 0; m < counterparty_htlc_sigs_constr.datalen; m++) { int8_tArray counterparty_htlc_sigs_conv_12 = counterparty_htlc_sigs_vals[m]; LDKSignature counterparty_htlc_sigs_conv_12_ref; CHECK(*((uint32_t*)counterparty_htlc_sigs_conv_12) == 64); memcpy(counterparty_htlc_sigs_conv_12_ref.compact_form, (uint8_t*)(counterparty_htlc_sigs_conv_12 + 4), 64); counterparty_htlc_sigs_constr.data[m] = counterparty_htlc_sigs_conv_12_ref; } LDKPublicKey holder_funding_key_ref; CHECK(*((uint32_t*)holder_funding_key) == 33); memcpy(holder_funding_key_ref.compressed_form, (uint8_t*)(holder_funding_key + 4), 33); LDKPublicKey counterparty_funding_key_ref; CHECK(*((uint32_t*)counterparty_funding_key) == 33); memcpy(counterparty_funding_key_ref.compressed_form, (uint8_t*)(counterparty_funding_key + 4), 33); LDKHolderCommitmentTransaction ret_var = HolderCommitmentTransaction_new(commitment_tx_conv, counterparty_sig_ref, counterparty_htlc_sigs_constr, holder_funding_key_ref, counterparty_funding_key_ref); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } void __attribute__((visibility("default"))) TS_BuiltCommitmentTransaction_free(uint32_t this_obj) { LDKBuiltCommitmentTransaction this_obj_conv; this_obj_conv.inner = (void*)(this_obj & (~1)); this_obj_conv.is_owned = (this_obj & 1) || (this_obj == 0); BuiltCommitmentTransaction_free(this_obj_conv); } int8_tArray __attribute__((visibility("default"))) TS_BuiltCommitmentTransaction_get_transaction(uint32_t this_ptr) { LDKBuiltCommitmentTransaction this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKTransaction ret_var = BuiltCommitmentTransaction_get_transaction(&this_ptr_conv); int8_tArray ret_arr = init_arr(ret_var.datalen, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), ret_var.data, ret_var.datalen); Transaction_free(ret_var); return ret_arr; } void __attribute__((visibility("default"))) TS_BuiltCommitmentTransaction_set_transaction(uint32_t this_ptr, int8_tArray val) { LDKBuiltCommitmentTransaction this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKTransaction val_ref; val_ref.datalen = *((uint32_t*)val); val_ref.data = MALLOC(val_ref.datalen, "LDKTransaction Bytes"); memcpy(val_ref.data, (uint8_t*)(val + 4), val_ref.datalen); val_ref.data_is_owned = true; BuiltCommitmentTransaction_set_transaction(&this_ptr_conv, val_ref); } int8_tArray __attribute__((visibility("default"))) TS_BuiltCommitmentTransaction_get_txid(uint32_t this_ptr) { LDKBuiltCommitmentTransaction this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int8_tArray ret_arr = init_arr(32, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), *BuiltCommitmentTransaction_get_txid(&this_ptr_conv), 32); return ret_arr; } void __attribute__((visibility("default"))) TS_BuiltCommitmentTransaction_set_txid(uint32_t this_ptr, int8_tArray val) { LDKBuiltCommitmentTransaction this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKThirtyTwoBytes val_ref; CHECK(*((uint32_t*)val) == 32); memcpy(val_ref.data, (uint8_t*)(val + 4), 32); BuiltCommitmentTransaction_set_txid(&this_ptr_conv, val_ref); } uint32_t __attribute__((visibility("default"))) TS_BuiltCommitmentTransaction_new(int8_tArray transaction_arg, int8_tArray txid_arg) { LDKTransaction transaction_arg_ref; transaction_arg_ref.datalen = *((uint32_t*)transaction_arg); transaction_arg_ref.data = MALLOC(transaction_arg_ref.datalen, "LDKTransaction Bytes"); memcpy(transaction_arg_ref.data, (uint8_t*)(transaction_arg + 4), transaction_arg_ref.datalen); transaction_arg_ref.data_is_owned = true; LDKThirtyTwoBytes txid_arg_ref; CHECK(*((uint32_t*)txid_arg) == 32); memcpy(txid_arg_ref.data, (uint8_t*)(txid_arg + 4), 32); LDKBuiltCommitmentTransaction ret_var = BuiltCommitmentTransaction_new(transaction_arg_ref, txid_arg_ref); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_BuiltCommitmentTransaction_clone(uint32_t orig) { LDKBuiltCommitmentTransaction orig_conv; orig_conv.inner = (void*)(orig & (~1)); orig_conv.is_owned = false; LDKBuiltCommitmentTransaction ret_var = BuiltCommitmentTransaction_clone(&orig_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } int8_tArray __attribute__((visibility("default"))) TS_BuiltCommitmentTransaction_write(uint32_t obj) { LDKBuiltCommitmentTransaction obj_conv; obj_conv.inner = (void*)(obj & (~1)); obj_conv.is_owned = false; LDKCVec_u8Z ret_var = BuiltCommitmentTransaction_write(&obj_conv); int8_tArray ret_arr = init_arr(ret_var.datalen, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), ret_var.data, ret_var.datalen); CVec_u8Z_free(ret_var); return ret_arr; } uint32_t __attribute__((visibility("default"))) TS_BuiltCommitmentTransaction_read(int8_tArray ser) { LDKu8slice ser_ref; ser_ref.datalen = *((uint32_t*)ser); ser_ref.data = (int8_t*)(ser + 4); LDKCResult_BuiltCommitmentTransactionDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_BuiltCommitmentTransactionDecodeErrorZ), "LDKCResult_BuiltCommitmentTransactionDecodeErrorZ"); *ret_conv = BuiltCommitmentTransaction_read(ser_ref); return (uint64_t)ret_conv; } int8_tArray __attribute__((visibility("default"))) TS_BuiltCommitmentTransaction_get_sighash_all(uint32_t this_arg, int8_tArray funding_redeemscript, int64_t channel_value_satoshis) { LDKBuiltCommitmentTransaction this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; LDKu8slice funding_redeemscript_ref; funding_redeemscript_ref.datalen = *((uint32_t*)funding_redeemscript); funding_redeemscript_ref.data = (int8_t*)(funding_redeemscript + 4); int8_tArray ret_arr = init_arr(32, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), BuiltCommitmentTransaction_get_sighash_all(&this_arg_conv, funding_redeemscript_ref, channel_value_satoshis).data, 32); return ret_arr; } int8_tArray __attribute__((visibility("default"))) TS_BuiltCommitmentTransaction_sign(uint32_t this_arg, int8_tArray funding_key, int8_tArray funding_redeemscript, int64_t channel_value_satoshis) { LDKBuiltCommitmentTransaction this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; unsigned char funding_key_arr[32]; CHECK(*((uint32_t*)funding_key) == 32); memcpy(funding_key_arr, (uint8_t*)(funding_key + 4), 32); unsigned char (*funding_key_ref)[32] = &funding_key_arr; LDKu8slice funding_redeemscript_ref; funding_redeemscript_ref.datalen = *((uint32_t*)funding_redeemscript); funding_redeemscript_ref.data = (int8_t*)(funding_redeemscript + 4); int8_tArray ret_arr = init_arr(64, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), BuiltCommitmentTransaction_sign(&this_arg_conv, funding_key_ref, funding_redeemscript_ref, channel_value_satoshis).compact_form, 64); return ret_arr; } void __attribute__((visibility("default"))) TS_ClosingTransaction_free(uint32_t this_obj) { LDKClosingTransaction this_obj_conv; this_obj_conv.inner = (void*)(this_obj & (~1)); this_obj_conv.is_owned = (this_obj & 1) || (this_obj == 0); ClosingTransaction_free(this_obj_conv); } uint32_t __attribute__((visibility("default"))) TS_ClosingTransaction_new(int64_t to_holder_value_sat, int64_t to_counterparty_value_sat, int8_tArray to_holder_script, int8_tArray to_counterparty_script, uint32_t funding_outpoint) { LDKCVec_u8Z to_holder_script_ref; to_holder_script_ref.datalen = *((uint32_t*)to_holder_script); to_holder_script_ref.data = MALLOC(to_holder_script_ref.datalen, "LDKCVec_u8Z Bytes"); memcpy(to_holder_script_ref.data, (uint8_t*)(to_holder_script + 4), to_holder_script_ref.datalen); LDKCVec_u8Z to_counterparty_script_ref; to_counterparty_script_ref.datalen = *((uint32_t*)to_counterparty_script); to_counterparty_script_ref.data = MALLOC(to_counterparty_script_ref.datalen, "LDKCVec_u8Z Bytes"); memcpy(to_counterparty_script_ref.data, (uint8_t*)(to_counterparty_script + 4), to_counterparty_script_ref.datalen); LDKOutPoint funding_outpoint_conv; funding_outpoint_conv.inner = (void*)(funding_outpoint & (~1)); funding_outpoint_conv.is_owned = (funding_outpoint & 1) || (funding_outpoint == 0); funding_outpoint_conv = OutPoint_clone(&funding_outpoint_conv); LDKClosingTransaction ret_var = ClosingTransaction_new(to_holder_value_sat, to_counterparty_value_sat, to_holder_script_ref, to_counterparty_script_ref, funding_outpoint_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_ClosingTransaction_trust(uint32_t this_arg) { LDKClosingTransaction this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; LDKTrustedClosingTransaction ret_var = ClosingTransaction_trust(&this_arg_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_ClosingTransaction_verify(uint32_t this_arg, uint32_t funding_outpoint) { LDKClosingTransaction this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; LDKOutPoint funding_outpoint_conv; funding_outpoint_conv.inner = (void*)(funding_outpoint & (~1)); funding_outpoint_conv.is_owned = (funding_outpoint & 1) || (funding_outpoint == 0); funding_outpoint_conv = OutPoint_clone(&funding_outpoint_conv); LDKCResult_TrustedClosingTransactionNoneZ* ret_conv = MALLOC(sizeof(LDKCResult_TrustedClosingTransactionNoneZ), "LDKCResult_TrustedClosingTransactionNoneZ"); *ret_conv = ClosingTransaction_verify(&this_arg_conv, funding_outpoint_conv); return (uint64_t)ret_conv; } int64_t __attribute__((visibility("default"))) TS_ClosingTransaction_to_holder_value_sat(uint32_t this_arg) { LDKClosingTransaction this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; int64_t ret_val = ClosingTransaction_to_holder_value_sat(&this_arg_conv); return ret_val; } int64_t __attribute__((visibility("default"))) TS_ClosingTransaction_to_counterparty_value_sat(uint32_t this_arg) { LDKClosingTransaction this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; int64_t ret_val = ClosingTransaction_to_counterparty_value_sat(&this_arg_conv); return ret_val; } int8_tArray __attribute__((visibility("default"))) TS_ClosingTransaction_to_holder_script(uint32_t this_arg) { LDKClosingTransaction this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; LDKu8slice ret_var = ClosingTransaction_to_holder_script(&this_arg_conv); int8_tArray ret_arr = init_arr(ret_var.datalen, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), ret_var.data, ret_var.datalen); return ret_arr; } int8_tArray __attribute__((visibility("default"))) TS_ClosingTransaction_to_counterparty_script(uint32_t this_arg) { LDKClosingTransaction this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; LDKu8slice ret_var = ClosingTransaction_to_counterparty_script(&this_arg_conv); int8_tArray ret_arr = init_arr(ret_var.datalen, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), ret_var.data, ret_var.datalen); return ret_arr; } void __attribute__((visibility("default"))) TS_TrustedClosingTransaction_free(uint32_t this_obj) { LDKTrustedClosingTransaction this_obj_conv; this_obj_conv.inner = (void*)(this_obj & (~1)); this_obj_conv.is_owned = (this_obj & 1) || (this_obj == 0); TrustedClosingTransaction_free(this_obj_conv); } int8_tArray __attribute__((visibility("default"))) TS_TrustedClosingTransaction_built_transaction(uint32_t this_arg) { LDKTrustedClosingTransaction this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; LDKTransaction ret_var = TrustedClosingTransaction_built_transaction(&this_arg_conv); int8_tArray ret_arr = init_arr(ret_var.datalen, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), ret_var.data, ret_var.datalen); Transaction_free(ret_var); return ret_arr; } int8_tArray __attribute__((visibility("default"))) TS_TrustedClosingTransaction_get_sighash_all(uint32_t this_arg, int8_tArray funding_redeemscript, int64_t channel_value_satoshis) { LDKTrustedClosingTransaction this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; LDKu8slice funding_redeemscript_ref; funding_redeemscript_ref.datalen = *((uint32_t*)funding_redeemscript); funding_redeemscript_ref.data = (int8_t*)(funding_redeemscript + 4); int8_tArray ret_arr = init_arr(32, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), TrustedClosingTransaction_get_sighash_all(&this_arg_conv, funding_redeemscript_ref, channel_value_satoshis).data, 32); return ret_arr; } int8_tArray __attribute__((visibility("default"))) TS_TrustedClosingTransaction_sign(uint32_t this_arg, int8_tArray funding_key, int8_tArray funding_redeemscript, int64_t channel_value_satoshis) { LDKTrustedClosingTransaction this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; unsigned char funding_key_arr[32]; CHECK(*((uint32_t*)funding_key) == 32); memcpy(funding_key_arr, (uint8_t*)(funding_key + 4), 32); unsigned char (*funding_key_ref)[32] = &funding_key_arr; LDKu8slice funding_redeemscript_ref; funding_redeemscript_ref.datalen = *((uint32_t*)funding_redeemscript); funding_redeemscript_ref.data = (int8_t*)(funding_redeemscript + 4); int8_tArray ret_arr = init_arr(64, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), TrustedClosingTransaction_sign(&this_arg_conv, funding_key_ref, funding_redeemscript_ref, channel_value_satoshis).compact_form, 64); return ret_arr; } void __attribute__((visibility("default"))) TS_CommitmentTransaction_free(uint32_t this_obj) { LDKCommitmentTransaction this_obj_conv; this_obj_conv.inner = (void*)(this_obj & (~1)); this_obj_conv.is_owned = (this_obj & 1) || (this_obj == 0); CommitmentTransaction_free(this_obj_conv); } uint32_t __attribute__((visibility("default"))) TS_CommitmentTransaction_clone(uint32_t orig) { LDKCommitmentTransaction orig_conv; orig_conv.inner = (void*)(orig & (~1)); orig_conv.is_owned = false; LDKCommitmentTransaction ret_var = CommitmentTransaction_clone(&orig_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } int8_tArray __attribute__((visibility("default"))) TS_CommitmentTransaction_write(uint32_t obj) { LDKCommitmentTransaction obj_conv; obj_conv.inner = (void*)(obj & (~1)); obj_conv.is_owned = false; LDKCVec_u8Z ret_var = CommitmentTransaction_write(&obj_conv); int8_tArray ret_arr = init_arr(ret_var.datalen, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), ret_var.data, ret_var.datalen); CVec_u8Z_free(ret_var); return ret_arr; } uint32_t __attribute__((visibility("default"))) TS_CommitmentTransaction_read(int8_tArray ser) { LDKu8slice ser_ref; ser_ref.datalen = *((uint32_t*)ser); ser_ref.data = (int8_t*)(ser + 4); LDKCResult_CommitmentTransactionDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_CommitmentTransactionDecodeErrorZ), "LDKCResult_CommitmentTransactionDecodeErrorZ"); *ret_conv = CommitmentTransaction_read(ser_ref); return (uint64_t)ret_conv; } int64_t __attribute__((visibility("default"))) TS_CommitmentTransaction_commitment_number(uint32_t this_arg) { LDKCommitmentTransaction this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; int64_t ret_val = CommitmentTransaction_commitment_number(&this_arg_conv); return ret_val; } int64_t __attribute__((visibility("default"))) TS_CommitmentTransaction_to_broadcaster_value_sat(uint32_t this_arg) { LDKCommitmentTransaction this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; int64_t ret_val = CommitmentTransaction_to_broadcaster_value_sat(&this_arg_conv); return ret_val; } int64_t __attribute__((visibility("default"))) TS_CommitmentTransaction_to_countersignatory_value_sat(uint32_t this_arg) { LDKCommitmentTransaction this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; int64_t ret_val = CommitmentTransaction_to_countersignatory_value_sat(&this_arg_conv); return ret_val; } int32_t __attribute__((visibility("default"))) TS_CommitmentTransaction_feerate_per_kw(uint32_t this_arg) { LDKCommitmentTransaction this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; int32_t ret_val = CommitmentTransaction_feerate_per_kw(&this_arg_conv); return ret_val; } uint32_t __attribute__((visibility("default"))) TS_CommitmentTransaction_trust(uint32_t this_arg) { LDKCommitmentTransaction this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; LDKTrustedCommitmentTransaction ret_var = CommitmentTransaction_trust(&this_arg_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_CommitmentTransaction_verify(uint32_t this_arg, uint32_t channel_parameters, uint32_t broadcaster_keys, uint32_t countersignatory_keys) { LDKCommitmentTransaction this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; LDKDirectedChannelTransactionParameters channel_parameters_conv; channel_parameters_conv.inner = (void*)(channel_parameters & (~1)); channel_parameters_conv.is_owned = false; LDKChannelPublicKeys broadcaster_keys_conv; broadcaster_keys_conv.inner = (void*)(broadcaster_keys & (~1)); broadcaster_keys_conv.is_owned = false; LDKChannelPublicKeys countersignatory_keys_conv; countersignatory_keys_conv.inner = (void*)(countersignatory_keys & (~1)); countersignatory_keys_conv.is_owned = false; LDKCResult_TrustedCommitmentTransactionNoneZ* ret_conv = MALLOC(sizeof(LDKCResult_TrustedCommitmentTransactionNoneZ), "LDKCResult_TrustedCommitmentTransactionNoneZ"); *ret_conv = CommitmentTransaction_verify(&this_arg_conv, &channel_parameters_conv, &broadcaster_keys_conv, &countersignatory_keys_conv); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_TrustedCommitmentTransaction_free(uint32_t this_obj) { LDKTrustedCommitmentTransaction this_obj_conv; this_obj_conv.inner = (void*)(this_obj & (~1)); this_obj_conv.is_owned = (this_obj & 1) || (this_obj == 0); TrustedCommitmentTransaction_free(this_obj_conv); } int8_tArray __attribute__((visibility("default"))) TS_TrustedCommitmentTransaction_txid(uint32_t this_arg) { LDKTrustedCommitmentTransaction this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; int8_tArray ret_arr = init_arr(32, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), TrustedCommitmentTransaction_txid(&this_arg_conv).data, 32); return ret_arr; } uint32_t __attribute__((visibility("default"))) TS_TrustedCommitmentTransaction_built_transaction(uint32_t this_arg) { LDKTrustedCommitmentTransaction this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; LDKBuiltCommitmentTransaction ret_var = TrustedCommitmentTransaction_built_transaction(&this_arg_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_TrustedCommitmentTransaction_keys(uint32_t this_arg) { LDKTrustedCommitmentTransaction this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; LDKTxCreationKeys ret_var = TrustedCommitmentTransaction_keys(&this_arg_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_TrustedCommitmentTransaction_get_htlc_sigs(uint32_t this_arg, int8_tArray htlc_base_key, uint32_t channel_parameters) { LDKTrustedCommitmentTransaction this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; unsigned char htlc_base_key_arr[32]; CHECK(*((uint32_t*)htlc_base_key) == 32); memcpy(htlc_base_key_arr, (uint8_t*)(htlc_base_key + 4), 32); unsigned char (*htlc_base_key_ref)[32] = &htlc_base_key_arr; LDKDirectedChannelTransactionParameters channel_parameters_conv; channel_parameters_conv.inner = (void*)(channel_parameters & (~1)); channel_parameters_conv.is_owned = false; LDKCResult_CVec_SignatureZNoneZ* ret_conv = MALLOC(sizeof(LDKCResult_CVec_SignatureZNoneZ), "LDKCResult_CVec_SignatureZNoneZ"); *ret_conv = TrustedCommitmentTransaction_get_htlc_sigs(&this_arg_conv, htlc_base_key_ref, &channel_parameters_conv); return (uint64_t)ret_conv; } int64_t __attribute__((visibility("default"))) TS_get_commitment_transaction_number_obscure_factor(int8_tArray broadcaster_payment_basepoint, int8_tArray countersignatory_payment_basepoint, jboolean outbound_from_broadcaster) { LDKPublicKey broadcaster_payment_basepoint_ref; CHECK(*((uint32_t*)broadcaster_payment_basepoint) == 33); memcpy(broadcaster_payment_basepoint_ref.compressed_form, (uint8_t*)(broadcaster_payment_basepoint + 4), 33); LDKPublicKey countersignatory_payment_basepoint_ref; CHECK(*((uint32_t*)countersignatory_payment_basepoint) == 33); memcpy(countersignatory_payment_basepoint_ref.compressed_form, (uint8_t*)(countersignatory_payment_basepoint + 4), 33); int64_t ret_val = get_commitment_transaction_number_obscure_factor(broadcaster_payment_basepoint_ref, countersignatory_payment_basepoint_ref, outbound_from_broadcaster); return ret_val; } jboolean __attribute__((visibility("default"))) TS_InitFeatures_eq(uint32_t a, uint32_t b) { LDKInitFeatures a_conv; a_conv.inner = (void*)(a & (~1)); a_conv.is_owned = false; LDKInitFeatures b_conv; b_conv.inner = (void*)(b & (~1)); b_conv.is_owned = false; jboolean ret_val = InitFeatures_eq(&a_conv, &b_conv); return ret_val; } jboolean __attribute__((visibility("default"))) TS_NodeFeatures_eq(uint32_t a, uint32_t b) { LDKNodeFeatures a_conv; a_conv.inner = (void*)(a & (~1)); a_conv.is_owned = false; LDKNodeFeatures b_conv; b_conv.inner = (void*)(b & (~1)); b_conv.is_owned = false; jboolean ret_val = NodeFeatures_eq(&a_conv, &b_conv); return ret_val; } jboolean __attribute__((visibility("default"))) TS_ChannelFeatures_eq(uint32_t a, uint32_t b) { LDKChannelFeatures a_conv; a_conv.inner = (void*)(a & (~1)); a_conv.is_owned = false; LDKChannelFeatures b_conv; b_conv.inner = (void*)(b & (~1)); b_conv.is_owned = false; jboolean ret_val = ChannelFeatures_eq(&a_conv, &b_conv); return ret_val; } jboolean __attribute__((visibility("default"))) TS_InvoiceFeatures_eq(uint32_t a, uint32_t b) { LDKInvoiceFeatures a_conv; a_conv.inner = (void*)(a & (~1)); a_conv.is_owned = false; LDKInvoiceFeatures b_conv; b_conv.inner = (void*)(b & (~1)); b_conv.is_owned = false; jboolean ret_val = InvoiceFeatures_eq(&a_conv, &b_conv); return ret_val; } uint32_t __attribute__((visibility("default"))) TS_InitFeatures_clone(uint32_t orig) { LDKInitFeatures orig_conv; orig_conv.inner = (void*)(orig & (~1)); orig_conv.is_owned = false; LDKInitFeatures ret_var = InitFeatures_clone(&orig_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_NodeFeatures_clone(uint32_t orig) { LDKNodeFeatures orig_conv; orig_conv.inner = (void*)(orig & (~1)); orig_conv.is_owned = false; LDKNodeFeatures ret_var = NodeFeatures_clone(&orig_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_ChannelFeatures_clone(uint32_t orig) { LDKChannelFeatures orig_conv; orig_conv.inner = (void*)(orig & (~1)); orig_conv.is_owned = false; LDKChannelFeatures ret_var = ChannelFeatures_clone(&orig_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_InvoiceFeatures_clone(uint32_t orig) { LDKInvoiceFeatures orig_conv; orig_conv.inner = (void*)(orig & (~1)); orig_conv.is_owned = false; LDKInvoiceFeatures ret_var = InvoiceFeatures_clone(&orig_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } void __attribute__((visibility("default"))) TS_InitFeatures_free(uint32_t this_obj) { LDKInitFeatures this_obj_conv; this_obj_conv.inner = (void*)(this_obj & (~1)); this_obj_conv.is_owned = (this_obj & 1) || (this_obj == 0); InitFeatures_free(this_obj_conv); } void __attribute__((visibility("default"))) TS_NodeFeatures_free(uint32_t this_obj) { LDKNodeFeatures this_obj_conv; this_obj_conv.inner = (void*)(this_obj & (~1)); this_obj_conv.is_owned = (this_obj & 1) || (this_obj == 0); NodeFeatures_free(this_obj_conv); } void __attribute__((visibility("default"))) TS_ChannelFeatures_free(uint32_t this_obj) { LDKChannelFeatures this_obj_conv; this_obj_conv.inner = (void*)(this_obj & (~1)); this_obj_conv.is_owned = (this_obj & 1) || (this_obj == 0); ChannelFeatures_free(this_obj_conv); } void __attribute__((visibility("default"))) TS_InvoiceFeatures_free(uint32_t this_obj) { LDKInvoiceFeatures this_obj_conv; this_obj_conv.inner = (void*)(this_obj & (~1)); this_obj_conv.is_owned = (this_obj & 1) || (this_obj == 0); InvoiceFeatures_free(this_obj_conv); } uint32_t __attribute__((visibility("default"))) TS_InitFeatures_empty() { LDKInitFeatures ret_var = InitFeatures_empty(); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_InitFeatures_known() { LDKInitFeatures ret_var = InitFeatures_known(); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } jboolean __attribute__((visibility("default"))) TS_InitFeatures_requires_unknown_bits(uint32_t this_arg) { LDKInitFeatures this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; jboolean ret_val = InitFeatures_requires_unknown_bits(&this_arg_conv); return ret_val; } uint32_t __attribute__((visibility("default"))) TS_NodeFeatures_empty() { LDKNodeFeatures ret_var = NodeFeatures_empty(); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_NodeFeatures_known() { LDKNodeFeatures ret_var = NodeFeatures_known(); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } jboolean __attribute__((visibility("default"))) TS_NodeFeatures_requires_unknown_bits(uint32_t this_arg) { LDKNodeFeatures this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; jboolean ret_val = NodeFeatures_requires_unknown_bits(&this_arg_conv); return ret_val; } uint32_t __attribute__((visibility("default"))) TS_ChannelFeatures_empty() { LDKChannelFeatures ret_var = ChannelFeatures_empty(); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_ChannelFeatures_known() { LDKChannelFeatures ret_var = ChannelFeatures_known(); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } jboolean __attribute__((visibility("default"))) TS_ChannelFeatures_requires_unknown_bits(uint32_t this_arg) { LDKChannelFeatures this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; jboolean ret_val = ChannelFeatures_requires_unknown_bits(&this_arg_conv); return ret_val; } uint32_t __attribute__((visibility("default"))) TS_InvoiceFeatures_empty() { LDKInvoiceFeatures ret_var = InvoiceFeatures_empty(); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_InvoiceFeatures_known() { LDKInvoiceFeatures ret_var = InvoiceFeatures_known(); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } jboolean __attribute__((visibility("default"))) TS_InvoiceFeatures_requires_unknown_bits(uint32_t this_arg) { LDKInvoiceFeatures this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; jboolean ret_val = InvoiceFeatures_requires_unknown_bits(&this_arg_conv); return ret_val; } jboolean __attribute__((visibility("default"))) TS_InitFeatures_supports_payment_secret(uint32_t this_arg) { LDKInitFeatures this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; jboolean ret_val = InitFeatures_supports_payment_secret(&this_arg_conv); return ret_val; } jboolean __attribute__((visibility("default"))) TS_NodeFeatures_supports_payment_secret(uint32_t this_arg) { LDKNodeFeatures this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; jboolean ret_val = NodeFeatures_supports_payment_secret(&this_arg_conv); return ret_val; } jboolean __attribute__((visibility("default"))) TS_InvoiceFeatures_supports_payment_secret(uint32_t this_arg) { LDKInvoiceFeatures this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; jboolean ret_val = InvoiceFeatures_supports_payment_secret(&this_arg_conv); return ret_val; } int8_tArray __attribute__((visibility("default"))) TS_InitFeatures_write(uint32_t obj) { LDKInitFeatures obj_conv; obj_conv.inner = (void*)(obj & (~1)); obj_conv.is_owned = false; LDKCVec_u8Z ret_var = InitFeatures_write(&obj_conv); int8_tArray ret_arr = init_arr(ret_var.datalen, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), ret_var.data, ret_var.datalen); CVec_u8Z_free(ret_var); return ret_arr; } int8_tArray __attribute__((visibility("default"))) TS_NodeFeatures_write(uint32_t obj) { LDKNodeFeatures obj_conv; obj_conv.inner = (void*)(obj & (~1)); obj_conv.is_owned = false; LDKCVec_u8Z ret_var = NodeFeatures_write(&obj_conv); int8_tArray ret_arr = init_arr(ret_var.datalen, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), ret_var.data, ret_var.datalen); CVec_u8Z_free(ret_var); return ret_arr; } int8_tArray __attribute__((visibility("default"))) TS_ChannelFeatures_write(uint32_t obj) { LDKChannelFeatures obj_conv; obj_conv.inner = (void*)(obj & (~1)); obj_conv.is_owned = false; LDKCVec_u8Z ret_var = ChannelFeatures_write(&obj_conv); int8_tArray ret_arr = init_arr(ret_var.datalen, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), ret_var.data, ret_var.datalen); CVec_u8Z_free(ret_var); return ret_arr; } int8_tArray __attribute__((visibility("default"))) TS_InvoiceFeatures_write(uint32_t obj) { LDKInvoiceFeatures obj_conv; obj_conv.inner = (void*)(obj & (~1)); obj_conv.is_owned = false; LDKCVec_u8Z ret_var = InvoiceFeatures_write(&obj_conv); int8_tArray ret_arr = init_arr(ret_var.datalen, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), ret_var.data, ret_var.datalen); CVec_u8Z_free(ret_var); return ret_arr; } uint32_t __attribute__((visibility("default"))) TS_InitFeatures_read(int8_tArray ser) { LDKu8slice ser_ref; ser_ref.datalen = *((uint32_t*)ser); ser_ref.data = (int8_t*)(ser + 4); LDKCResult_InitFeaturesDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_InitFeaturesDecodeErrorZ), "LDKCResult_InitFeaturesDecodeErrorZ"); *ret_conv = InitFeatures_read(ser_ref); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_NodeFeatures_read(int8_tArray ser) { LDKu8slice ser_ref; ser_ref.datalen = *((uint32_t*)ser); ser_ref.data = (int8_t*)(ser + 4); LDKCResult_NodeFeaturesDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_NodeFeaturesDecodeErrorZ), "LDKCResult_NodeFeaturesDecodeErrorZ"); *ret_conv = NodeFeatures_read(ser_ref); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_ChannelFeatures_read(int8_tArray ser) { LDKu8slice ser_ref; ser_ref.datalen = *((uint32_t*)ser); ser_ref.data = (int8_t*)(ser + 4); LDKCResult_ChannelFeaturesDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_ChannelFeaturesDecodeErrorZ), "LDKCResult_ChannelFeaturesDecodeErrorZ"); *ret_conv = ChannelFeatures_read(ser_ref); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_InvoiceFeatures_read(int8_tArray ser) { LDKu8slice ser_ref; ser_ref.datalen = *((uint32_t*)ser); ser_ref.data = (int8_t*)(ser + 4); LDKCResult_InvoiceFeaturesDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_InvoiceFeaturesDecodeErrorZ), "LDKCResult_InvoiceFeaturesDecodeErrorZ"); *ret_conv = InvoiceFeatures_read(ser_ref); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_ShutdownScript_free(uint32_t this_obj) { LDKShutdownScript this_obj_conv; this_obj_conv.inner = (void*)(this_obj & (~1)); this_obj_conv.is_owned = (this_obj & 1) || (this_obj == 0); ShutdownScript_free(this_obj_conv); } uint32_t __attribute__((visibility("default"))) TS_ShutdownScript_clone(uint32_t orig) { LDKShutdownScript orig_conv; orig_conv.inner = (void*)(orig & (~1)); orig_conv.is_owned = false; LDKShutdownScript ret_var = ShutdownScript_clone(&orig_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } void __attribute__((visibility("default"))) TS_InvalidShutdownScript_free(uint32_t this_obj) { LDKInvalidShutdownScript this_obj_conv; this_obj_conv.inner = (void*)(this_obj & (~1)); this_obj_conv.is_owned = (this_obj & 1) || (this_obj == 0); InvalidShutdownScript_free(this_obj_conv); } int8_tArray __attribute__((visibility("default"))) TS_InvalidShutdownScript_get_script(uint32_t this_ptr) { LDKInvalidShutdownScript this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKu8slice ret_var = InvalidShutdownScript_get_script(&this_ptr_conv); int8_tArray ret_arr = init_arr(ret_var.datalen, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), ret_var.data, ret_var.datalen); return ret_arr; } void __attribute__((visibility("default"))) TS_InvalidShutdownScript_set_script(uint32_t this_ptr, int8_tArray val) { LDKInvalidShutdownScript this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKCVec_u8Z val_ref; val_ref.datalen = *((uint32_t*)val); val_ref.data = MALLOC(val_ref.datalen, "LDKCVec_u8Z Bytes"); memcpy(val_ref.data, (uint8_t*)(val + 4), val_ref.datalen); InvalidShutdownScript_set_script(&this_ptr_conv, val_ref); } uint32_t __attribute__((visibility("default"))) TS_InvalidShutdownScript_new(int8_tArray script_arg) { LDKCVec_u8Z script_arg_ref; script_arg_ref.datalen = *((uint32_t*)script_arg); script_arg_ref.data = MALLOC(script_arg_ref.datalen, "LDKCVec_u8Z Bytes"); memcpy(script_arg_ref.data, (uint8_t*)(script_arg + 4), script_arg_ref.datalen); LDKInvalidShutdownScript ret_var = InvalidShutdownScript_new(script_arg_ref); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } int8_tArray __attribute__((visibility("default"))) TS_ShutdownScript_write(uint32_t obj) { LDKShutdownScript obj_conv; obj_conv.inner = (void*)(obj & (~1)); obj_conv.is_owned = false; LDKCVec_u8Z ret_var = ShutdownScript_write(&obj_conv); int8_tArray ret_arr = init_arr(ret_var.datalen, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), ret_var.data, ret_var.datalen); CVec_u8Z_free(ret_var); return ret_arr; } uint32_t __attribute__((visibility("default"))) TS_ShutdownScript_read(int8_tArray ser) { LDKu8slice ser_ref; ser_ref.datalen = *((uint32_t*)ser); ser_ref.data = (int8_t*)(ser + 4); LDKCResult_ShutdownScriptDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_ShutdownScriptDecodeErrorZ), "LDKCResult_ShutdownScriptDecodeErrorZ"); *ret_conv = ShutdownScript_read(ser_ref); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_ShutdownScript_new_p2pkh(int8_tArray pubkey_hash) { unsigned char pubkey_hash_arr[20]; CHECK(*((uint32_t*)pubkey_hash) == 20); memcpy(pubkey_hash_arr, (uint8_t*)(pubkey_hash + 4), 20); unsigned char (*pubkey_hash_ref)[20] = &pubkey_hash_arr; LDKShutdownScript ret_var = ShutdownScript_new_p2pkh(pubkey_hash_ref); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_ShutdownScript_new_p2sh(int8_tArray script_hash) { unsigned char script_hash_arr[20]; CHECK(*((uint32_t*)script_hash) == 20); memcpy(script_hash_arr, (uint8_t*)(script_hash + 4), 20); unsigned char (*script_hash_ref)[20] = &script_hash_arr; LDKShutdownScript ret_var = ShutdownScript_new_p2sh(script_hash_ref); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_ShutdownScript_new_p2wpkh(int8_tArray pubkey_hash) { unsigned char pubkey_hash_arr[20]; CHECK(*((uint32_t*)pubkey_hash) == 20); memcpy(pubkey_hash_arr, (uint8_t*)(pubkey_hash + 4), 20); unsigned char (*pubkey_hash_ref)[20] = &pubkey_hash_arr; LDKShutdownScript ret_var = ShutdownScript_new_p2wpkh(pubkey_hash_ref); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_ShutdownScript_new_p2wsh(int8_tArray script_hash) { unsigned char script_hash_arr[32]; CHECK(*((uint32_t*)script_hash) == 32); memcpy(script_hash_arr, (uint8_t*)(script_hash + 4), 32); unsigned char (*script_hash_ref)[32] = &script_hash_arr; LDKShutdownScript ret_var = ShutdownScript_new_p2wsh(script_hash_ref); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_ShutdownScript_new_witness_program(int8_t version, int8_tArray program) { LDKu8slice program_ref; program_ref.datalen = *((uint32_t*)program); program_ref.data = (int8_t*)(program + 4); LDKCResult_ShutdownScriptInvalidShutdownScriptZ* ret_conv = MALLOC(sizeof(LDKCResult_ShutdownScriptInvalidShutdownScriptZ), "LDKCResult_ShutdownScriptInvalidShutdownScriptZ"); *ret_conv = ShutdownScript_new_witness_program(version, program_ref); return (uint64_t)ret_conv; } int8_tArray __attribute__((visibility("default"))) TS_ShutdownScript_into_inner(uint32_t this_arg) { LDKShutdownScript this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = (this_arg & 1) || (this_arg == 0); this_arg_conv = ShutdownScript_clone(&this_arg_conv); LDKCVec_u8Z ret_var = ShutdownScript_into_inner(this_arg_conv); int8_tArray ret_arr = init_arr(ret_var.datalen, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), ret_var.data, ret_var.datalen); CVec_u8Z_free(ret_var); return ret_arr; } int8_tArray __attribute__((visibility("default"))) TS_ShutdownScript_as_legacy_pubkey(uint32_t this_arg) { LDKShutdownScript this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; int8_tArray ret_arr = init_arr(33, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), ShutdownScript_as_legacy_pubkey(&this_arg_conv).compressed_form, 33); return ret_arr; } jboolean __attribute__((visibility("default"))) TS_ShutdownScript_is_compatible(uint32_t this_arg, uint32_t features) { LDKShutdownScript this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; LDKInitFeatures features_conv; features_conv.inner = (void*)(features & (~1)); features_conv.is_owned = false; jboolean ret_val = ShutdownScript_is_compatible(&this_arg_conv, &features_conv); return ret_val; } void __attribute__((visibility("default"))) TS_CustomMessageReader_free(uint32_t this_ptr) { if ((this_ptr & 1) != 0) return; LDKCustomMessageReader this_ptr_conv = *(LDKCustomMessageReader*)(((uint64_t)this_ptr) & ~1); FREE((void*)this_ptr); CustomMessageReader_free(this_ptr_conv); } uint32_t __attribute__((visibility("default"))) TS_Type_clone(uint32_t orig) { LDKType* orig_conv = (LDKType*)(((uint64_t)orig) & ~1); LDKType* ret_ret =MALLOC(sizeof(LDKType), "LDKType"); *ret_ret = Type_clone(orig_conv); return (uint64_t)ret_ret; } void __attribute__((visibility("default"))) TS_Type_free(uint32_t this_ptr) { if ((this_ptr & 1) != 0) return; LDKType this_ptr_conv = *(LDKType*)(((uint64_t)this_ptr) & ~1); FREE((void*)this_ptr); Type_free(this_ptr_conv); } void __attribute__((visibility("default"))) TS_RouteHop_free(uint32_t this_obj) { LDKRouteHop this_obj_conv; this_obj_conv.inner = (void*)(this_obj & (~1)); this_obj_conv.is_owned = (this_obj & 1) || (this_obj == 0); RouteHop_free(this_obj_conv); } int8_tArray __attribute__((visibility("default"))) TS_RouteHop_get_pubkey(uint32_t this_ptr) { LDKRouteHop this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int8_tArray ret_arr = init_arr(33, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), RouteHop_get_pubkey(&this_ptr_conv).compressed_form, 33); return ret_arr; } void __attribute__((visibility("default"))) TS_RouteHop_set_pubkey(uint32_t this_ptr, int8_tArray val) { LDKRouteHop this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKPublicKey val_ref; CHECK(*((uint32_t*)val) == 33); memcpy(val_ref.compressed_form, (uint8_t*)(val + 4), 33); RouteHop_set_pubkey(&this_ptr_conv, val_ref); } uint32_t __attribute__((visibility("default"))) TS_RouteHop_get_node_features(uint32_t this_ptr) { LDKRouteHop this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKNodeFeatures ret_var = RouteHop_get_node_features(&this_ptr_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } void __attribute__((visibility("default"))) TS_RouteHop_set_node_features(uint32_t this_ptr, uint32_t val) { LDKRouteHop this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKNodeFeatures val_conv; val_conv.inner = (void*)(val & (~1)); val_conv.is_owned = (val & 1) || (val == 0); val_conv = NodeFeatures_clone(&val_conv); RouteHop_set_node_features(&this_ptr_conv, val_conv); } int64_t __attribute__((visibility("default"))) TS_RouteHop_get_short_channel_id(uint32_t this_ptr) { LDKRouteHop this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int64_t ret_val = RouteHop_get_short_channel_id(&this_ptr_conv); return ret_val; } void __attribute__((visibility("default"))) TS_RouteHop_set_short_channel_id(uint32_t this_ptr, int64_t val) { LDKRouteHop this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; RouteHop_set_short_channel_id(&this_ptr_conv, val); } uint32_t __attribute__((visibility("default"))) TS_RouteHop_get_channel_features(uint32_t this_ptr) { LDKRouteHop this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKChannelFeatures ret_var = RouteHop_get_channel_features(&this_ptr_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } void __attribute__((visibility("default"))) TS_RouteHop_set_channel_features(uint32_t this_ptr, uint32_t val) { LDKRouteHop this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKChannelFeatures val_conv; val_conv.inner = (void*)(val & (~1)); val_conv.is_owned = (val & 1) || (val == 0); val_conv = ChannelFeatures_clone(&val_conv); RouteHop_set_channel_features(&this_ptr_conv, val_conv); } int64_t __attribute__((visibility("default"))) TS_RouteHop_get_fee_msat(uint32_t this_ptr) { LDKRouteHop this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int64_t ret_val = RouteHop_get_fee_msat(&this_ptr_conv); return ret_val; } void __attribute__((visibility("default"))) TS_RouteHop_set_fee_msat(uint32_t this_ptr, int64_t val) { LDKRouteHop this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; RouteHop_set_fee_msat(&this_ptr_conv, val); } int32_t __attribute__((visibility("default"))) TS_RouteHop_get_cltv_expiry_delta(uint32_t this_ptr) { LDKRouteHop this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int32_t ret_val = RouteHop_get_cltv_expiry_delta(&this_ptr_conv); return ret_val; } void __attribute__((visibility("default"))) TS_RouteHop_set_cltv_expiry_delta(uint32_t this_ptr, int32_t val) { LDKRouteHop this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; RouteHop_set_cltv_expiry_delta(&this_ptr_conv, val); } uint32_t __attribute__((visibility("default"))) TS_RouteHop_new(int8_tArray pubkey_arg, uint32_t node_features_arg, int64_t short_channel_id_arg, uint32_t channel_features_arg, int64_t fee_msat_arg, int32_t cltv_expiry_delta_arg) { LDKPublicKey pubkey_arg_ref; CHECK(*((uint32_t*)pubkey_arg) == 33); memcpy(pubkey_arg_ref.compressed_form, (uint8_t*)(pubkey_arg + 4), 33); LDKNodeFeatures node_features_arg_conv; node_features_arg_conv.inner = (void*)(node_features_arg & (~1)); node_features_arg_conv.is_owned = (node_features_arg & 1) || (node_features_arg == 0); node_features_arg_conv = NodeFeatures_clone(&node_features_arg_conv); LDKChannelFeatures channel_features_arg_conv; channel_features_arg_conv.inner = (void*)(channel_features_arg & (~1)); channel_features_arg_conv.is_owned = (channel_features_arg & 1) || (channel_features_arg == 0); channel_features_arg_conv = ChannelFeatures_clone(&channel_features_arg_conv); LDKRouteHop ret_var = RouteHop_new(pubkey_arg_ref, node_features_arg_conv, short_channel_id_arg, channel_features_arg_conv, fee_msat_arg, cltv_expiry_delta_arg); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_RouteHop_clone(uint32_t orig) { LDKRouteHop orig_conv; orig_conv.inner = (void*)(orig & (~1)); orig_conv.is_owned = false; LDKRouteHop ret_var = RouteHop_clone(&orig_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } int64_t __attribute__((visibility("default"))) TS_RouteHop_hash(uint32_t o) { LDKRouteHop o_conv; o_conv.inner = (void*)(o & (~1)); o_conv.is_owned = false; int64_t ret_val = RouteHop_hash(&o_conv); return ret_val; } jboolean __attribute__((visibility("default"))) TS_RouteHop_eq(uint32_t a, uint32_t b) { LDKRouteHop a_conv; a_conv.inner = (void*)(a & (~1)); a_conv.is_owned = false; LDKRouteHop b_conv; b_conv.inner = (void*)(b & (~1)); b_conv.is_owned = false; jboolean ret_val = RouteHop_eq(&a_conv, &b_conv); return ret_val; } int8_tArray __attribute__((visibility("default"))) TS_RouteHop_write(uint32_t obj) { LDKRouteHop obj_conv; obj_conv.inner = (void*)(obj & (~1)); obj_conv.is_owned = false; LDKCVec_u8Z ret_var = RouteHop_write(&obj_conv); int8_tArray ret_arr = init_arr(ret_var.datalen, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), ret_var.data, ret_var.datalen); CVec_u8Z_free(ret_var); return ret_arr; } uint32_t __attribute__((visibility("default"))) TS_RouteHop_read(int8_tArray ser) { LDKu8slice ser_ref; ser_ref.datalen = *((uint32_t*)ser); ser_ref.data = (int8_t*)(ser + 4); LDKCResult_RouteHopDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_RouteHopDecodeErrorZ), "LDKCResult_RouteHopDecodeErrorZ"); *ret_conv = RouteHop_read(ser_ref); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_Route_free(uint32_t this_obj) { LDKRoute this_obj_conv; this_obj_conv.inner = (void*)(this_obj & (~1)); this_obj_conv.is_owned = (this_obj & 1) || (this_obj == 0); Route_free(this_obj_conv); } ptrArray __attribute__((visibility("default"))) TS_Route_get_paths(uint32_t this_ptr) { LDKRoute this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKCVec_CVec_RouteHopZZ ret_var = Route_get_paths(&this_ptr_conv); ptrArray ret_arr = init_arr(ret_var.datalen, sizeof(uint32_t), "Native ptrArray Bytes"); uint32_tArray *ret_arr_ptr = (uint32_tArray*)(ret_arr + 4); for (size_t m = 0; m < ret_var.datalen; m++) { LDKCVec_RouteHopZ ret_conv_12_var = ret_var.data[m]; uint32_tArray ret_conv_12_arr = init_arr(ret_conv_12_var.datalen, sizeof(uint32_t), "Native uint32_tArray Bytes"); uint32_t *ret_conv_12_arr_ptr = (uint32_t*)(ret_conv_12_arr + 4); for (size_t k = 0; k < ret_conv_12_var.datalen; k++) { LDKRouteHop ret_conv_12_conv_10_var = ret_conv_12_var.data[k]; CHECK((((uint64_t)ret_conv_12_conv_10_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_conv_12_conv_10_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_conv_12_conv_10_ref = (uint64_t)ret_conv_12_conv_10_var.inner; if (ret_conv_12_conv_10_var.is_owned) { ret_conv_12_conv_10_ref |= 1; } ret_conv_12_arr_ptr[k] = ret_conv_12_conv_10_ref; } FREE(ret_conv_12_var.data); ret_arr_ptr[m] = ret_conv_12_arr; } FREE(ret_var.data); return ret_arr; } void __attribute__((visibility("default"))) TS_Route_set_paths(uint32_t this_ptr, ptrArray val) { LDKRoute this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKCVec_CVec_RouteHopZZ val_constr; val_constr.datalen = *((uint32_t*)val); if (val_constr.datalen > 0) val_constr.data = MALLOC(val_constr.datalen * sizeof(LDKCVec_RouteHopZ), "LDKCVec_CVec_RouteHopZZ Elements"); else val_constr.data = NULL; uint32_tArray* val_vals = (uint32_tArray*)(val + 4); for (size_t m = 0; m < val_constr.datalen; m++) { uint32_tArray val_conv_12 = val_vals[m]; LDKCVec_RouteHopZ val_conv_12_constr; val_conv_12_constr.datalen = *((uint32_t*)val_conv_12); if (val_conv_12_constr.datalen > 0) val_conv_12_constr.data = MALLOC(val_conv_12_constr.datalen * sizeof(LDKRouteHop), "LDKCVec_RouteHopZ Elements"); else val_conv_12_constr.data = NULL; uint32_t* val_conv_12_vals = (uint32_t*)(val_conv_12 + 4); for (size_t k = 0; k < val_conv_12_constr.datalen; k++) { uint32_t val_conv_12_conv_10 = val_conv_12_vals[k]; LDKRouteHop val_conv_12_conv_10_conv; val_conv_12_conv_10_conv.inner = (void*)(val_conv_12_conv_10 & (~1)); val_conv_12_conv_10_conv.is_owned = (val_conv_12_conv_10 & 1) || (val_conv_12_conv_10 == 0); val_conv_12_conv_10_conv = RouteHop_clone(&val_conv_12_conv_10_conv); val_conv_12_constr.data[k] = val_conv_12_conv_10_conv; } val_constr.data[m] = val_conv_12_constr; } Route_set_paths(&this_ptr_conv, val_constr); } uint32_t __attribute__((visibility("default"))) TS_Route_new(ptrArray paths_arg) { LDKCVec_CVec_RouteHopZZ paths_arg_constr; paths_arg_constr.datalen = *((uint32_t*)paths_arg); if (paths_arg_constr.datalen > 0) paths_arg_constr.data = MALLOC(paths_arg_constr.datalen * sizeof(LDKCVec_RouteHopZ), "LDKCVec_CVec_RouteHopZZ Elements"); else paths_arg_constr.data = NULL; uint32_tArray* paths_arg_vals = (uint32_tArray*)(paths_arg + 4); for (size_t m = 0; m < paths_arg_constr.datalen; m++) { uint32_tArray paths_arg_conv_12 = paths_arg_vals[m]; LDKCVec_RouteHopZ paths_arg_conv_12_constr; paths_arg_conv_12_constr.datalen = *((uint32_t*)paths_arg_conv_12); if (paths_arg_conv_12_constr.datalen > 0) paths_arg_conv_12_constr.data = MALLOC(paths_arg_conv_12_constr.datalen * sizeof(LDKRouteHop), "LDKCVec_RouteHopZ Elements"); else paths_arg_conv_12_constr.data = NULL; uint32_t* paths_arg_conv_12_vals = (uint32_t*)(paths_arg_conv_12 + 4); for (size_t k = 0; k < paths_arg_conv_12_constr.datalen; k++) { uint32_t paths_arg_conv_12_conv_10 = paths_arg_conv_12_vals[k]; LDKRouteHop paths_arg_conv_12_conv_10_conv; paths_arg_conv_12_conv_10_conv.inner = (void*)(paths_arg_conv_12_conv_10 & (~1)); paths_arg_conv_12_conv_10_conv.is_owned = (paths_arg_conv_12_conv_10 & 1) || (paths_arg_conv_12_conv_10 == 0); paths_arg_conv_12_conv_10_conv = RouteHop_clone(&paths_arg_conv_12_conv_10_conv); paths_arg_conv_12_constr.data[k] = paths_arg_conv_12_conv_10_conv; } paths_arg_constr.data[m] = paths_arg_conv_12_constr; } LDKRoute ret_var = Route_new(paths_arg_constr); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_Route_clone(uint32_t orig) { LDKRoute orig_conv; orig_conv.inner = (void*)(orig & (~1)); orig_conv.is_owned = false; LDKRoute ret_var = Route_clone(&orig_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } int64_t __attribute__((visibility("default"))) TS_Route_hash(uint32_t o) { LDKRoute o_conv; o_conv.inner = (void*)(o & (~1)); o_conv.is_owned = false; int64_t ret_val = Route_hash(&o_conv); return ret_val; } jboolean __attribute__((visibility("default"))) TS_Route_eq(uint32_t a, uint32_t b) { LDKRoute a_conv; a_conv.inner = (void*)(a & (~1)); a_conv.is_owned = false; LDKRoute b_conv; b_conv.inner = (void*)(b & (~1)); b_conv.is_owned = false; jboolean ret_val = Route_eq(&a_conv, &b_conv); return ret_val; } int64_t __attribute__((visibility("default"))) TS_Route_get_total_fees(uint32_t this_arg) { LDKRoute this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; int64_t ret_val = Route_get_total_fees(&this_arg_conv); return ret_val; } int64_t __attribute__((visibility("default"))) TS_Route_get_total_amount(uint32_t this_arg) { LDKRoute this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; int64_t ret_val = Route_get_total_amount(&this_arg_conv); return ret_val; } int8_tArray __attribute__((visibility("default"))) TS_Route_write(uint32_t obj) { LDKRoute obj_conv; obj_conv.inner = (void*)(obj & (~1)); obj_conv.is_owned = false; LDKCVec_u8Z ret_var = Route_write(&obj_conv); int8_tArray ret_arr = init_arr(ret_var.datalen, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), ret_var.data, ret_var.datalen); CVec_u8Z_free(ret_var); return ret_arr; } uint32_t __attribute__((visibility("default"))) TS_Route_read(int8_tArray ser) { LDKu8slice ser_ref; ser_ref.datalen = *((uint32_t*)ser); ser_ref.data = (int8_t*)(ser + 4); LDKCResult_RouteDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_RouteDecodeErrorZ), "LDKCResult_RouteDecodeErrorZ"); *ret_conv = Route_read(ser_ref); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_RouteHint_free(uint32_t this_obj) { LDKRouteHint this_obj_conv; this_obj_conv.inner = (void*)(this_obj & (~1)); this_obj_conv.is_owned = (this_obj & 1) || (this_obj == 0); RouteHint_free(this_obj_conv); } uint32_t __attribute__((visibility("default"))) TS_RouteHint_clone(uint32_t orig) { LDKRouteHint orig_conv; orig_conv.inner = (void*)(orig & (~1)); orig_conv.is_owned = false; LDKRouteHint ret_var = RouteHint_clone(&orig_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } int64_t __attribute__((visibility("default"))) TS_RouteHint_hash(uint32_t o) { LDKRouteHint o_conv; o_conv.inner = (void*)(o & (~1)); o_conv.is_owned = false; int64_t ret_val = RouteHint_hash(&o_conv); return ret_val; } jboolean __attribute__((visibility("default"))) TS_RouteHint_eq(uint32_t a, uint32_t b) { LDKRouteHint a_conv; a_conv.inner = (void*)(a & (~1)); a_conv.is_owned = false; LDKRouteHint b_conv; b_conv.inner = (void*)(b & (~1)); b_conv.is_owned = false; jboolean ret_val = RouteHint_eq(&a_conv, &b_conv); return ret_val; } void __attribute__((visibility("default"))) TS_RouteHintHop_free(uint32_t this_obj) { LDKRouteHintHop this_obj_conv; this_obj_conv.inner = (void*)(this_obj & (~1)); this_obj_conv.is_owned = (this_obj & 1) || (this_obj == 0); RouteHintHop_free(this_obj_conv); } int8_tArray __attribute__((visibility("default"))) TS_RouteHintHop_get_src_node_id(uint32_t this_ptr) { LDKRouteHintHop this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int8_tArray ret_arr = init_arr(33, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), RouteHintHop_get_src_node_id(&this_ptr_conv).compressed_form, 33); return ret_arr; } void __attribute__((visibility("default"))) TS_RouteHintHop_set_src_node_id(uint32_t this_ptr, int8_tArray val) { LDKRouteHintHop this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKPublicKey val_ref; CHECK(*((uint32_t*)val) == 33); memcpy(val_ref.compressed_form, (uint8_t*)(val + 4), 33); RouteHintHop_set_src_node_id(&this_ptr_conv, val_ref); } int64_t __attribute__((visibility("default"))) TS_RouteHintHop_get_short_channel_id(uint32_t this_ptr) { LDKRouteHintHop this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int64_t ret_val = RouteHintHop_get_short_channel_id(&this_ptr_conv); return ret_val; } void __attribute__((visibility("default"))) TS_RouteHintHop_set_short_channel_id(uint32_t this_ptr, int64_t val) { LDKRouteHintHop this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; RouteHintHop_set_short_channel_id(&this_ptr_conv, val); } uint32_t __attribute__((visibility("default"))) TS_RouteHintHop_get_fees(uint32_t this_ptr) { LDKRouteHintHop this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKRoutingFees ret_var = RouteHintHop_get_fees(&this_ptr_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } void __attribute__((visibility("default"))) TS_RouteHintHop_set_fees(uint32_t this_ptr, uint32_t val) { LDKRouteHintHop this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKRoutingFees val_conv; val_conv.inner = (void*)(val & (~1)); val_conv.is_owned = (val & 1) || (val == 0); val_conv = RoutingFees_clone(&val_conv); RouteHintHop_set_fees(&this_ptr_conv, val_conv); } int16_t __attribute__((visibility("default"))) TS_RouteHintHop_get_cltv_expiry_delta(uint32_t this_ptr) { LDKRouteHintHop this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int16_t ret_val = RouteHintHop_get_cltv_expiry_delta(&this_ptr_conv); return ret_val; } void __attribute__((visibility("default"))) TS_RouteHintHop_set_cltv_expiry_delta(uint32_t this_ptr, int16_t val) { LDKRouteHintHop this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; RouteHintHop_set_cltv_expiry_delta(&this_ptr_conv, val); } uint32_t __attribute__((visibility("default"))) TS_RouteHintHop_get_htlc_minimum_msat(uint32_t this_ptr) { LDKRouteHintHop this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKCOption_u64Z *ret_copy = MALLOC(sizeof(LDKCOption_u64Z), "LDKCOption_u64Z"); *ret_copy = RouteHintHop_get_htlc_minimum_msat(&this_ptr_conv); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } void __attribute__((visibility("default"))) TS_RouteHintHop_set_htlc_minimum_msat(uint32_t this_ptr, uint32_t val) { LDKRouteHintHop this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKCOption_u64Z val_conv = *(LDKCOption_u64Z*)(((uint64_t)val) & ~1); val_conv = COption_u64Z_clone((LDKCOption_u64Z*)(((uint64_t)val) & ~1)); RouteHintHop_set_htlc_minimum_msat(&this_ptr_conv, val_conv); } uint32_t __attribute__((visibility("default"))) TS_RouteHintHop_get_htlc_maximum_msat(uint32_t this_ptr) { LDKRouteHintHop this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKCOption_u64Z *ret_copy = MALLOC(sizeof(LDKCOption_u64Z), "LDKCOption_u64Z"); *ret_copy = RouteHintHop_get_htlc_maximum_msat(&this_ptr_conv); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } void __attribute__((visibility("default"))) TS_RouteHintHop_set_htlc_maximum_msat(uint32_t this_ptr, uint32_t val) { LDKRouteHintHop this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKCOption_u64Z val_conv = *(LDKCOption_u64Z*)(((uint64_t)val) & ~1); val_conv = COption_u64Z_clone((LDKCOption_u64Z*)(((uint64_t)val) & ~1)); RouteHintHop_set_htlc_maximum_msat(&this_ptr_conv, val_conv); } uint32_t __attribute__((visibility("default"))) TS_RouteHintHop_new(int8_tArray src_node_id_arg, int64_t short_channel_id_arg, uint32_t fees_arg, int16_t cltv_expiry_delta_arg, uint32_t htlc_minimum_msat_arg, uint32_t htlc_maximum_msat_arg) { LDKPublicKey src_node_id_arg_ref; CHECK(*((uint32_t*)src_node_id_arg) == 33); memcpy(src_node_id_arg_ref.compressed_form, (uint8_t*)(src_node_id_arg + 4), 33); LDKRoutingFees fees_arg_conv; fees_arg_conv.inner = (void*)(fees_arg & (~1)); fees_arg_conv.is_owned = (fees_arg & 1) || (fees_arg == 0); fees_arg_conv = RoutingFees_clone(&fees_arg_conv); LDKCOption_u64Z htlc_minimum_msat_arg_conv = *(LDKCOption_u64Z*)(((uint64_t)htlc_minimum_msat_arg) & ~1); htlc_minimum_msat_arg_conv = COption_u64Z_clone((LDKCOption_u64Z*)(((uint64_t)htlc_minimum_msat_arg) & ~1)); LDKCOption_u64Z htlc_maximum_msat_arg_conv = *(LDKCOption_u64Z*)(((uint64_t)htlc_maximum_msat_arg) & ~1); htlc_maximum_msat_arg_conv = COption_u64Z_clone((LDKCOption_u64Z*)(((uint64_t)htlc_maximum_msat_arg) & ~1)); LDKRouteHintHop ret_var = RouteHintHop_new(src_node_id_arg_ref, short_channel_id_arg, fees_arg_conv, cltv_expiry_delta_arg, htlc_minimum_msat_arg_conv, htlc_maximum_msat_arg_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_RouteHintHop_clone(uint32_t orig) { LDKRouteHintHop orig_conv; orig_conv.inner = (void*)(orig & (~1)); orig_conv.is_owned = false; LDKRouteHintHop ret_var = RouteHintHop_clone(&orig_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } int64_t __attribute__((visibility("default"))) TS_RouteHintHop_hash(uint32_t o) { LDKRouteHintHop o_conv; o_conv.inner = (void*)(o & (~1)); o_conv.is_owned = false; int64_t ret_val = RouteHintHop_hash(&o_conv); return ret_val; } jboolean __attribute__((visibility("default"))) TS_RouteHintHop_eq(uint32_t a, uint32_t b) { LDKRouteHintHop a_conv; a_conv.inner = (void*)(a & (~1)); a_conv.is_owned = false; LDKRouteHintHop b_conv; b_conv.inner = (void*)(b & (~1)); b_conv.is_owned = false; jboolean ret_val = RouteHintHop_eq(&a_conv, &b_conv); return ret_val; } uint32_t __attribute__((visibility("default"))) TS_get_keysend_route(int8_tArray our_node_id, uint32_t network, int8_tArray payee, uint32_tArray first_hops, uint32_tArray last_hops, int64_t final_value_msat, int32_t final_cltv, uint32_t logger) { LDKPublicKey our_node_id_ref; CHECK(*((uint32_t*)our_node_id) == 33); memcpy(our_node_id_ref.compressed_form, (uint8_t*)(our_node_id + 4), 33); LDKNetworkGraph network_conv; network_conv.inner = (void*)(network & (~1)); network_conv.is_owned = false; LDKPublicKey payee_ref; CHECK(*((uint32_t*)payee) == 33); memcpy(payee_ref.compressed_form, (uint8_t*)(payee + 4), 33); LDKCVec_ChannelDetailsZ first_hops_constr; LDKCVec_ChannelDetailsZ *first_hops_ptr = NULL; if (first_hops != 0) { first_hops_constr.datalen = *((uint32_t*)first_hops); if (first_hops_constr.datalen > 0) first_hops_constr.data = MALLOC(first_hops_constr.datalen * sizeof(LDKChannelDetails), "LDKCVec_ChannelDetailsZ Elements"); else first_hops_constr.data = NULL; uint32_t* first_hops_vals = (uint32_t*)(first_hops + 4); for (size_t q = 0; q < first_hops_constr.datalen; q++) { uint32_t first_hops_conv_16 = first_hops_vals[q]; LDKChannelDetails first_hops_conv_16_conv; first_hops_conv_16_conv.inner = (void*)(first_hops_conv_16 & (~1)); first_hops_conv_16_conv.is_owned = (first_hops_conv_16 & 1) || (first_hops_conv_16 == 0); first_hops_constr.data[q] = first_hops_conv_16_conv; } first_hops_ptr = &first_hops_constr; } LDKCVec_RouteHintZ last_hops_constr; last_hops_constr.datalen = *((uint32_t*)last_hops); if (last_hops_constr.datalen > 0) last_hops_constr.data = MALLOC(last_hops_constr.datalen * sizeof(LDKRouteHint), "LDKCVec_RouteHintZ Elements"); else last_hops_constr.data = NULL; uint32_t* last_hops_vals = (uint32_t*)(last_hops + 4); for (size_t l = 0; l < last_hops_constr.datalen; l++) { uint32_t last_hops_conv_11 = last_hops_vals[l]; LDKRouteHint last_hops_conv_11_conv; last_hops_conv_11_conv.inner = (void*)(last_hops_conv_11 & (~1)); last_hops_conv_11_conv.is_owned = (last_hops_conv_11 & 1) || (last_hops_conv_11 == 0); last_hops_conv_11_conv = RouteHint_clone(&last_hops_conv_11_conv); last_hops_constr.data[l] = last_hops_conv_11_conv; } LDKLogger logger_conv = *(LDKLogger*)(((uint64_t)logger) & ~1); LDKCResult_RouteLightningErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_RouteLightningErrorZ), "LDKCResult_RouteLightningErrorZ"); *ret_conv = get_keysend_route(our_node_id_ref, &network_conv, payee_ref, first_hops_ptr, last_hops_constr, final_value_msat, final_cltv, logger_conv); if (first_hops_ptr != NULL) { FREE(first_hops_constr.data); } return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_get_route(int8_tArray our_node_id, uint32_t network, int8_tArray payee, uint32_t payee_features, uint32_tArray first_hops, uint32_tArray last_hops, int64_t final_value_msat, int32_t final_cltv, uint32_t logger) { LDKPublicKey our_node_id_ref; CHECK(*((uint32_t*)our_node_id) == 33); memcpy(our_node_id_ref.compressed_form, (uint8_t*)(our_node_id + 4), 33); LDKNetworkGraph network_conv; network_conv.inner = (void*)(network & (~1)); network_conv.is_owned = false; LDKPublicKey payee_ref; CHECK(*((uint32_t*)payee) == 33); memcpy(payee_ref.compressed_form, (uint8_t*)(payee + 4), 33); LDKInvoiceFeatures payee_features_conv; payee_features_conv.inner = (void*)(payee_features & (~1)); payee_features_conv.is_owned = (payee_features & 1) || (payee_features == 0); payee_features_conv = InvoiceFeatures_clone(&payee_features_conv); LDKCVec_ChannelDetailsZ first_hops_constr; LDKCVec_ChannelDetailsZ *first_hops_ptr = NULL; if (first_hops != 0) { first_hops_constr.datalen = *((uint32_t*)first_hops); if (first_hops_constr.datalen > 0) first_hops_constr.data = MALLOC(first_hops_constr.datalen * sizeof(LDKChannelDetails), "LDKCVec_ChannelDetailsZ Elements"); else first_hops_constr.data = NULL; uint32_t* first_hops_vals = (uint32_t*)(first_hops + 4); for (size_t q = 0; q < first_hops_constr.datalen; q++) { uint32_t first_hops_conv_16 = first_hops_vals[q]; LDKChannelDetails first_hops_conv_16_conv; first_hops_conv_16_conv.inner = (void*)(first_hops_conv_16 & (~1)); first_hops_conv_16_conv.is_owned = (first_hops_conv_16 & 1) || (first_hops_conv_16 == 0); first_hops_constr.data[q] = first_hops_conv_16_conv; } first_hops_ptr = &first_hops_constr; } LDKCVec_RouteHintZ last_hops_constr; last_hops_constr.datalen = *((uint32_t*)last_hops); if (last_hops_constr.datalen > 0) last_hops_constr.data = MALLOC(last_hops_constr.datalen * sizeof(LDKRouteHint), "LDKCVec_RouteHintZ Elements"); else last_hops_constr.data = NULL; uint32_t* last_hops_vals = (uint32_t*)(last_hops + 4); for (size_t l = 0; l < last_hops_constr.datalen; l++) { uint32_t last_hops_conv_11 = last_hops_vals[l]; LDKRouteHint last_hops_conv_11_conv; last_hops_conv_11_conv.inner = (void*)(last_hops_conv_11 & (~1)); last_hops_conv_11_conv.is_owned = (last_hops_conv_11 & 1) || (last_hops_conv_11 == 0); last_hops_conv_11_conv = RouteHint_clone(&last_hops_conv_11_conv); last_hops_constr.data[l] = last_hops_conv_11_conv; } LDKLogger logger_conv = *(LDKLogger*)(((uint64_t)logger) & ~1); LDKCResult_RouteLightningErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_RouteLightningErrorZ), "LDKCResult_RouteLightningErrorZ"); *ret_conv = get_route(our_node_id_ref, &network_conv, payee_ref, payee_features_conv, first_hops_ptr, last_hops_constr, final_value_msat, final_cltv, logger_conv); if (first_hops_ptr != NULL) { FREE(first_hops_constr.data); } return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_NetworkGraph_free(uint32_t this_obj) { LDKNetworkGraph this_obj_conv; this_obj_conv.inner = (void*)(this_obj & (~1)); this_obj_conv.is_owned = (this_obj & 1) || (this_obj == 0); NetworkGraph_free(this_obj_conv); } void __attribute__((visibility("default"))) TS_ReadOnlyNetworkGraph_free(uint32_t this_obj) { LDKReadOnlyNetworkGraph this_obj_conv; this_obj_conv.inner = (void*)(this_obj & (~1)); this_obj_conv.is_owned = (this_obj & 1) || (this_obj == 0); ReadOnlyNetworkGraph_free(this_obj_conv); } void __attribute__((visibility("default"))) TS_NetworkUpdate_free(uint32_t this_ptr) { if ((this_ptr & 1) != 0) return; LDKNetworkUpdate this_ptr_conv = *(LDKNetworkUpdate*)(((uint64_t)this_ptr) & ~1); FREE((void*)this_ptr); NetworkUpdate_free(this_ptr_conv); } uint32_t __attribute__((visibility("default"))) TS_NetworkUpdate_clone(uint32_t orig) { LDKNetworkUpdate* orig_conv = (LDKNetworkUpdate*)orig; LDKNetworkUpdate *ret_copy = MALLOC(sizeof(LDKNetworkUpdate), "LDKNetworkUpdate"); *ret_copy = NetworkUpdate_clone(orig_conv); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_NetworkUpdate_channel_update_message(uint32_t msg) { LDKChannelUpdate msg_conv; msg_conv.inner = (void*)(msg & (~1)); msg_conv.is_owned = (msg & 1) || (msg == 0); msg_conv = ChannelUpdate_clone(&msg_conv); LDKNetworkUpdate *ret_copy = MALLOC(sizeof(LDKNetworkUpdate), "LDKNetworkUpdate"); *ret_copy = NetworkUpdate_channel_update_message(msg_conv); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_NetworkUpdate_channel_closed(int64_t short_channel_id, jboolean is_permanent) { LDKNetworkUpdate *ret_copy = MALLOC(sizeof(LDKNetworkUpdate), "LDKNetworkUpdate"); *ret_copy = NetworkUpdate_channel_closed(short_channel_id, is_permanent); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_NetworkUpdate_node_failure(int8_tArray node_id, jboolean is_permanent) { LDKPublicKey node_id_ref; CHECK(*((uint32_t*)node_id) == 33); memcpy(node_id_ref.compressed_form, (uint8_t*)(node_id + 4), 33); LDKNetworkUpdate *ret_copy = MALLOC(sizeof(LDKNetworkUpdate), "LDKNetworkUpdate"); *ret_copy = NetworkUpdate_node_failure(node_id_ref, is_permanent); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } int8_tArray __attribute__((visibility("default"))) TS_NetworkUpdate_write(uint32_t obj) { LDKNetworkUpdate* obj_conv = (LDKNetworkUpdate*)obj; LDKCVec_u8Z ret_var = NetworkUpdate_write(obj_conv); int8_tArray ret_arr = init_arr(ret_var.datalen, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), ret_var.data, ret_var.datalen); CVec_u8Z_free(ret_var); return ret_arr; } uint32_t __attribute__((visibility("default"))) TS_NetGraphMsgHandler_as_EventHandler(uint32_t this_arg) { LDKNetGraphMsgHandler this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; LDKEventHandler* ret_ret =MALLOC(sizeof(LDKEventHandler), "LDKEventHandler"); *ret_ret = NetGraphMsgHandler_as_EventHandler(&this_arg_conv); return (uint64_t)ret_ret; } void __attribute__((visibility("default"))) TS_NetGraphMsgHandler_free(uint32_t this_obj) { LDKNetGraphMsgHandler this_obj_conv; this_obj_conv.inner = (void*)(this_obj & (~1)); this_obj_conv.is_owned = (this_obj & 1) || (this_obj == 0); NetGraphMsgHandler_free(this_obj_conv); } uint32_t __attribute__((visibility("default"))) TS_NetGraphMsgHandler_get_network_graph(uint32_t this_ptr) { LDKNetGraphMsgHandler this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKNetworkGraph ret_var = NetGraphMsgHandler_get_network_graph(&this_ptr_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } void __attribute__((visibility("default"))) TS_NetGraphMsgHandler_set_network_graph(uint32_t this_ptr, uint32_t val) { LDKNetGraphMsgHandler this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKNetworkGraph val_conv; val_conv.inner = (void*)(val & (~1)); val_conv.is_owned = (val & 1) || (val == 0); // Warning: we need a move here but no clone is available for LDKNetworkGraph NetGraphMsgHandler_set_network_graph(&this_ptr_conv, val_conv); } uint32_t __attribute__((visibility("default"))) TS_NetGraphMsgHandler_new(uint32_t network_graph, uint32_t chain_access, uint32_t logger) { LDKNetworkGraph network_graph_conv; network_graph_conv.inner = (void*)(network_graph & (~1)); network_graph_conv.is_owned = (network_graph & 1) || (network_graph == 0); // Warning: we need a move here but no clone is available for LDKNetworkGraph LDKCOption_AccessZ chain_access_conv = *(LDKCOption_AccessZ*)(((uint64_t)chain_access) & ~1); // Warning: we may need a move here but no clone is available for LDKCOption_AccessZ if (chain_access_conv.tag == LDKCOption_AccessZ_Some) { // Manually implement clone for Java trait instances } LDKLogger logger_conv = *(LDKLogger*)(((uint64_t)logger) & ~1); LDKNetGraphMsgHandler ret_var = NetGraphMsgHandler_new(network_graph_conv, chain_access_conv, logger_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } void __attribute__((visibility("default"))) TS_NetGraphMsgHandler_add_chain_access(uint32_t this_arg, uint32_t chain_access) { LDKNetGraphMsgHandler this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; LDKCOption_AccessZ chain_access_conv = *(LDKCOption_AccessZ*)(((uint64_t)chain_access) & ~1); // Warning: we may need a move here but no clone is available for LDKCOption_AccessZ if (chain_access_conv.tag == LDKCOption_AccessZ_Some) { // Manually implement clone for Java trait instances } NetGraphMsgHandler_add_chain_access(&this_arg_conv, chain_access_conv); } uint32_t __attribute__((visibility("default"))) TS_NetGraphMsgHandler_as_RoutingMessageHandler(uint32_t this_arg) { LDKNetGraphMsgHandler this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; LDKRoutingMessageHandler* ret_ret =MALLOC(sizeof(LDKRoutingMessageHandler), "LDKRoutingMessageHandler"); *ret_ret = NetGraphMsgHandler_as_RoutingMessageHandler(&this_arg_conv); return (uint64_t)ret_ret; } uint32_t __attribute__((visibility("default"))) TS_NetGraphMsgHandler_as_MessageSendEventsProvider(uint32_t this_arg) { LDKNetGraphMsgHandler this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; LDKMessageSendEventsProvider* ret_ret =MALLOC(sizeof(LDKMessageSendEventsProvider), "LDKMessageSendEventsProvider"); *ret_ret = NetGraphMsgHandler_as_MessageSendEventsProvider(&this_arg_conv); return (uint64_t)ret_ret; } void __attribute__((visibility("default"))) TS_DirectionalChannelInfo_free(uint32_t this_obj) { LDKDirectionalChannelInfo this_obj_conv; this_obj_conv.inner = (void*)(this_obj & (~1)); this_obj_conv.is_owned = (this_obj & 1) || (this_obj == 0); DirectionalChannelInfo_free(this_obj_conv); } int32_t __attribute__((visibility("default"))) TS_DirectionalChannelInfo_get_last_update(uint32_t this_ptr) { LDKDirectionalChannelInfo this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int32_t ret_val = DirectionalChannelInfo_get_last_update(&this_ptr_conv); return ret_val; } void __attribute__((visibility("default"))) TS_DirectionalChannelInfo_set_last_update(uint32_t this_ptr, int32_t val) { LDKDirectionalChannelInfo this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; DirectionalChannelInfo_set_last_update(&this_ptr_conv, val); } jboolean __attribute__((visibility("default"))) TS_DirectionalChannelInfo_get_enabled(uint32_t this_ptr) { LDKDirectionalChannelInfo this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; jboolean ret_val = DirectionalChannelInfo_get_enabled(&this_ptr_conv); return ret_val; } void __attribute__((visibility("default"))) TS_DirectionalChannelInfo_set_enabled(uint32_t this_ptr, jboolean val) { LDKDirectionalChannelInfo this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; DirectionalChannelInfo_set_enabled(&this_ptr_conv, val); } int16_t __attribute__((visibility("default"))) TS_DirectionalChannelInfo_get_cltv_expiry_delta(uint32_t this_ptr) { LDKDirectionalChannelInfo this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int16_t ret_val = DirectionalChannelInfo_get_cltv_expiry_delta(&this_ptr_conv); return ret_val; } void __attribute__((visibility("default"))) TS_DirectionalChannelInfo_set_cltv_expiry_delta(uint32_t this_ptr, int16_t val) { LDKDirectionalChannelInfo this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; DirectionalChannelInfo_set_cltv_expiry_delta(&this_ptr_conv, val); } int64_t __attribute__((visibility("default"))) TS_DirectionalChannelInfo_get_htlc_minimum_msat(uint32_t this_ptr) { LDKDirectionalChannelInfo this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int64_t ret_val = DirectionalChannelInfo_get_htlc_minimum_msat(&this_ptr_conv); return ret_val; } void __attribute__((visibility("default"))) TS_DirectionalChannelInfo_set_htlc_minimum_msat(uint32_t this_ptr, int64_t val) { LDKDirectionalChannelInfo this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; DirectionalChannelInfo_set_htlc_minimum_msat(&this_ptr_conv, val); } uint32_t __attribute__((visibility("default"))) TS_DirectionalChannelInfo_get_htlc_maximum_msat(uint32_t this_ptr) { LDKDirectionalChannelInfo this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKCOption_u64Z *ret_copy = MALLOC(sizeof(LDKCOption_u64Z), "LDKCOption_u64Z"); *ret_copy = DirectionalChannelInfo_get_htlc_maximum_msat(&this_ptr_conv); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } void __attribute__((visibility("default"))) TS_DirectionalChannelInfo_set_htlc_maximum_msat(uint32_t this_ptr, uint32_t val) { LDKDirectionalChannelInfo this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKCOption_u64Z val_conv = *(LDKCOption_u64Z*)(((uint64_t)val) & ~1); val_conv = COption_u64Z_clone((LDKCOption_u64Z*)(((uint64_t)val) & ~1)); DirectionalChannelInfo_set_htlc_maximum_msat(&this_ptr_conv, val_conv); } uint32_t __attribute__((visibility("default"))) TS_DirectionalChannelInfo_get_fees(uint32_t this_ptr) { LDKDirectionalChannelInfo this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKRoutingFees ret_var = DirectionalChannelInfo_get_fees(&this_ptr_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } void __attribute__((visibility("default"))) TS_DirectionalChannelInfo_set_fees(uint32_t this_ptr, uint32_t val) { LDKDirectionalChannelInfo this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKRoutingFees val_conv; val_conv.inner = (void*)(val & (~1)); val_conv.is_owned = (val & 1) || (val == 0); val_conv = RoutingFees_clone(&val_conv); DirectionalChannelInfo_set_fees(&this_ptr_conv, val_conv); } uint32_t __attribute__((visibility("default"))) TS_DirectionalChannelInfo_get_last_update_message(uint32_t this_ptr) { LDKDirectionalChannelInfo this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKChannelUpdate ret_var = DirectionalChannelInfo_get_last_update_message(&this_ptr_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } void __attribute__((visibility("default"))) TS_DirectionalChannelInfo_set_last_update_message(uint32_t this_ptr, uint32_t val) { LDKDirectionalChannelInfo this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKChannelUpdate val_conv; val_conv.inner = (void*)(val & (~1)); val_conv.is_owned = (val & 1) || (val == 0); val_conv = ChannelUpdate_clone(&val_conv); DirectionalChannelInfo_set_last_update_message(&this_ptr_conv, val_conv); } uint32_t __attribute__((visibility("default"))) TS_DirectionalChannelInfo_new(int32_t last_update_arg, jboolean enabled_arg, int16_t cltv_expiry_delta_arg, int64_t htlc_minimum_msat_arg, uint32_t htlc_maximum_msat_arg, uint32_t fees_arg, uint32_t last_update_message_arg) { LDKCOption_u64Z htlc_maximum_msat_arg_conv = *(LDKCOption_u64Z*)(((uint64_t)htlc_maximum_msat_arg) & ~1); htlc_maximum_msat_arg_conv = COption_u64Z_clone((LDKCOption_u64Z*)(((uint64_t)htlc_maximum_msat_arg) & ~1)); LDKRoutingFees fees_arg_conv; fees_arg_conv.inner = (void*)(fees_arg & (~1)); fees_arg_conv.is_owned = (fees_arg & 1) || (fees_arg == 0); fees_arg_conv = RoutingFees_clone(&fees_arg_conv); LDKChannelUpdate last_update_message_arg_conv; last_update_message_arg_conv.inner = (void*)(last_update_message_arg & (~1)); last_update_message_arg_conv.is_owned = (last_update_message_arg & 1) || (last_update_message_arg == 0); last_update_message_arg_conv = ChannelUpdate_clone(&last_update_message_arg_conv); LDKDirectionalChannelInfo ret_var = DirectionalChannelInfo_new(last_update_arg, enabled_arg, cltv_expiry_delta_arg, htlc_minimum_msat_arg, htlc_maximum_msat_arg_conv, fees_arg_conv, last_update_message_arg_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_DirectionalChannelInfo_clone(uint32_t orig) { LDKDirectionalChannelInfo orig_conv; orig_conv.inner = (void*)(orig & (~1)); orig_conv.is_owned = false; LDKDirectionalChannelInfo ret_var = DirectionalChannelInfo_clone(&orig_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } int8_tArray __attribute__((visibility("default"))) TS_DirectionalChannelInfo_write(uint32_t obj) { LDKDirectionalChannelInfo obj_conv; obj_conv.inner = (void*)(obj & (~1)); obj_conv.is_owned = false; LDKCVec_u8Z ret_var = DirectionalChannelInfo_write(&obj_conv); int8_tArray ret_arr = init_arr(ret_var.datalen, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), ret_var.data, ret_var.datalen); CVec_u8Z_free(ret_var); return ret_arr; } uint32_t __attribute__((visibility("default"))) TS_DirectionalChannelInfo_read(int8_tArray ser) { LDKu8slice ser_ref; ser_ref.datalen = *((uint32_t*)ser); ser_ref.data = (int8_t*)(ser + 4); LDKCResult_DirectionalChannelInfoDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_DirectionalChannelInfoDecodeErrorZ), "LDKCResult_DirectionalChannelInfoDecodeErrorZ"); *ret_conv = DirectionalChannelInfo_read(ser_ref); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_ChannelInfo_free(uint32_t this_obj) { LDKChannelInfo this_obj_conv; this_obj_conv.inner = (void*)(this_obj & (~1)); this_obj_conv.is_owned = (this_obj & 1) || (this_obj == 0); ChannelInfo_free(this_obj_conv); } uint32_t __attribute__((visibility("default"))) TS_ChannelInfo_get_features(uint32_t this_ptr) { LDKChannelInfo this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKChannelFeatures ret_var = ChannelInfo_get_features(&this_ptr_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } void __attribute__((visibility("default"))) TS_ChannelInfo_set_features(uint32_t this_ptr, uint32_t val) { LDKChannelInfo this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKChannelFeatures val_conv; val_conv.inner = (void*)(val & (~1)); val_conv.is_owned = (val & 1) || (val == 0); val_conv = ChannelFeatures_clone(&val_conv); ChannelInfo_set_features(&this_ptr_conv, val_conv); } int8_tArray __attribute__((visibility("default"))) TS_ChannelInfo_get_node_one(uint32_t this_ptr) { LDKChannelInfo this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int8_tArray ret_arr = init_arr(33, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), ChannelInfo_get_node_one(&this_ptr_conv).compressed_form, 33); return ret_arr; } void __attribute__((visibility("default"))) TS_ChannelInfo_set_node_one(uint32_t this_ptr, int8_tArray val) { LDKChannelInfo this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKPublicKey val_ref; CHECK(*((uint32_t*)val) == 33); memcpy(val_ref.compressed_form, (uint8_t*)(val + 4), 33); ChannelInfo_set_node_one(&this_ptr_conv, val_ref); } uint32_t __attribute__((visibility("default"))) TS_ChannelInfo_get_one_to_two(uint32_t this_ptr) { LDKChannelInfo this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKDirectionalChannelInfo ret_var = ChannelInfo_get_one_to_two(&this_ptr_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } void __attribute__((visibility("default"))) TS_ChannelInfo_set_one_to_two(uint32_t this_ptr, uint32_t val) { LDKChannelInfo this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKDirectionalChannelInfo val_conv; val_conv.inner = (void*)(val & (~1)); val_conv.is_owned = (val & 1) || (val == 0); val_conv = DirectionalChannelInfo_clone(&val_conv); ChannelInfo_set_one_to_two(&this_ptr_conv, val_conv); } int8_tArray __attribute__((visibility("default"))) TS_ChannelInfo_get_node_two(uint32_t this_ptr) { LDKChannelInfo this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int8_tArray ret_arr = init_arr(33, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), ChannelInfo_get_node_two(&this_ptr_conv).compressed_form, 33); return ret_arr; } void __attribute__((visibility("default"))) TS_ChannelInfo_set_node_two(uint32_t this_ptr, int8_tArray val) { LDKChannelInfo this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKPublicKey val_ref; CHECK(*((uint32_t*)val) == 33); memcpy(val_ref.compressed_form, (uint8_t*)(val + 4), 33); ChannelInfo_set_node_two(&this_ptr_conv, val_ref); } uint32_t __attribute__((visibility("default"))) TS_ChannelInfo_get_two_to_one(uint32_t this_ptr) { LDKChannelInfo this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKDirectionalChannelInfo ret_var = ChannelInfo_get_two_to_one(&this_ptr_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } void __attribute__((visibility("default"))) TS_ChannelInfo_set_two_to_one(uint32_t this_ptr, uint32_t val) { LDKChannelInfo this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKDirectionalChannelInfo val_conv; val_conv.inner = (void*)(val & (~1)); val_conv.is_owned = (val & 1) || (val == 0); val_conv = DirectionalChannelInfo_clone(&val_conv); ChannelInfo_set_two_to_one(&this_ptr_conv, val_conv); } uint32_t __attribute__((visibility("default"))) TS_ChannelInfo_get_capacity_sats(uint32_t this_ptr) { LDKChannelInfo this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKCOption_u64Z *ret_copy = MALLOC(sizeof(LDKCOption_u64Z), "LDKCOption_u64Z"); *ret_copy = ChannelInfo_get_capacity_sats(&this_ptr_conv); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } void __attribute__((visibility("default"))) TS_ChannelInfo_set_capacity_sats(uint32_t this_ptr, uint32_t val) { LDKChannelInfo this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKCOption_u64Z val_conv = *(LDKCOption_u64Z*)(((uint64_t)val) & ~1); val_conv = COption_u64Z_clone((LDKCOption_u64Z*)(((uint64_t)val) & ~1)); ChannelInfo_set_capacity_sats(&this_ptr_conv, val_conv); } uint32_t __attribute__((visibility("default"))) TS_ChannelInfo_get_announcement_message(uint32_t this_ptr) { LDKChannelInfo this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKChannelAnnouncement ret_var = ChannelInfo_get_announcement_message(&this_ptr_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } void __attribute__((visibility("default"))) TS_ChannelInfo_set_announcement_message(uint32_t this_ptr, uint32_t val) { LDKChannelInfo this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKChannelAnnouncement val_conv; val_conv.inner = (void*)(val & (~1)); val_conv.is_owned = (val & 1) || (val == 0); val_conv = ChannelAnnouncement_clone(&val_conv); ChannelInfo_set_announcement_message(&this_ptr_conv, val_conv); } uint32_t __attribute__((visibility("default"))) TS_ChannelInfo_new(uint32_t features_arg, int8_tArray node_one_arg, uint32_t one_to_two_arg, int8_tArray node_two_arg, uint32_t two_to_one_arg, uint32_t capacity_sats_arg, uint32_t announcement_message_arg) { LDKChannelFeatures features_arg_conv; features_arg_conv.inner = (void*)(features_arg & (~1)); features_arg_conv.is_owned = (features_arg & 1) || (features_arg == 0); features_arg_conv = ChannelFeatures_clone(&features_arg_conv); LDKPublicKey node_one_arg_ref; CHECK(*((uint32_t*)node_one_arg) == 33); memcpy(node_one_arg_ref.compressed_form, (uint8_t*)(node_one_arg + 4), 33); LDKDirectionalChannelInfo one_to_two_arg_conv; one_to_two_arg_conv.inner = (void*)(one_to_two_arg & (~1)); one_to_two_arg_conv.is_owned = (one_to_two_arg & 1) || (one_to_two_arg == 0); one_to_two_arg_conv = DirectionalChannelInfo_clone(&one_to_two_arg_conv); LDKPublicKey node_two_arg_ref; CHECK(*((uint32_t*)node_two_arg) == 33); memcpy(node_two_arg_ref.compressed_form, (uint8_t*)(node_two_arg + 4), 33); LDKDirectionalChannelInfo two_to_one_arg_conv; two_to_one_arg_conv.inner = (void*)(two_to_one_arg & (~1)); two_to_one_arg_conv.is_owned = (two_to_one_arg & 1) || (two_to_one_arg == 0); two_to_one_arg_conv = DirectionalChannelInfo_clone(&two_to_one_arg_conv); LDKCOption_u64Z capacity_sats_arg_conv = *(LDKCOption_u64Z*)(((uint64_t)capacity_sats_arg) & ~1); capacity_sats_arg_conv = COption_u64Z_clone((LDKCOption_u64Z*)(((uint64_t)capacity_sats_arg) & ~1)); LDKChannelAnnouncement announcement_message_arg_conv; announcement_message_arg_conv.inner = (void*)(announcement_message_arg & (~1)); announcement_message_arg_conv.is_owned = (announcement_message_arg & 1) || (announcement_message_arg == 0); announcement_message_arg_conv = ChannelAnnouncement_clone(&announcement_message_arg_conv); LDKChannelInfo ret_var = ChannelInfo_new(features_arg_conv, node_one_arg_ref, one_to_two_arg_conv, node_two_arg_ref, two_to_one_arg_conv, capacity_sats_arg_conv, announcement_message_arg_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_ChannelInfo_clone(uint32_t orig) { LDKChannelInfo orig_conv; orig_conv.inner = (void*)(orig & (~1)); orig_conv.is_owned = false; LDKChannelInfo ret_var = ChannelInfo_clone(&orig_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } int8_tArray __attribute__((visibility("default"))) TS_ChannelInfo_write(uint32_t obj) { LDKChannelInfo obj_conv; obj_conv.inner = (void*)(obj & (~1)); obj_conv.is_owned = false; LDKCVec_u8Z ret_var = ChannelInfo_write(&obj_conv); int8_tArray ret_arr = init_arr(ret_var.datalen, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), ret_var.data, ret_var.datalen); CVec_u8Z_free(ret_var); return ret_arr; } uint32_t __attribute__((visibility("default"))) TS_ChannelInfo_read(int8_tArray ser) { LDKu8slice ser_ref; ser_ref.datalen = *((uint32_t*)ser); ser_ref.data = (int8_t*)(ser + 4); LDKCResult_ChannelInfoDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_ChannelInfoDecodeErrorZ), "LDKCResult_ChannelInfoDecodeErrorZ"); *ret_conv = ChannelInfo_read(ser_ref); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_RoutingFees_free(uint32_t this_obj) { LDKRoutingFees this_obj_conv; this_obj_conv.inner = (void*)(this_obj & (~1)); this_obj_conv.is_owned = (this_obj & 1) || (this_obj == 0); RoutingFees_free(this_obj_conv); } int32_t __attribute__((visibility("default"))) TS_RoutingFees_get_base_msat(uint32_t this_ptr) { LDKRoutingFees this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int32_t ret_val = RoutingFees_get_base_msat(&this_ptr_conv); return ret_val; } void __attribute__((visibility("default"))) TS_RoutingFees_set_base_msat(uint32_t this_ptr, int32_t val) { LDKRoutingFees this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; RoutingFees_set_base_msat(&this_ptr_conv, val); } int32_t __attribute__((visibility("default"))) TS_RoutingFees_get_proportional_millionths(uint32_t this_ptr) { LDKRoutingFees this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int32_t ret_val = RoutingFees_get_proportional_millionths(&this_ptr_conv); return ret_val; } void __attribute__((visibility("default"))) TS_RoutingFees_set_proportional_millionths(uint32_t this_ptr, int32_t val) { LDKRoutingFees this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; RoutingFees_set_proportional_millionths(&this_ptr_conv, val); } uint32_t __attribute__((visibility("default"))) TS_RoutingFees_new(int32_t base_msat_arg, int32_t proportional_millionths_arg) { LDKRoutingFees ret_var = RoutingFees_new(base_msat_arg, proportional_millionths_arg); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } jboolean __attribute__((visibility("default"))) TS_RoutingFees_eq(uint32_t a, uint32_t b) { LDKRoutingFees a_conv; a_conv.inner = (void*)(a & (~1)); a_conv.is_owned = false; LDKRoutingFees b_conv; b_conv.inner = (void*)(b & (~1)); b_conv.is_owned = false; jboolean ret_val = RoutingFees_eq(&a_conv, &b_conv); return ret_val; } uint32_t __attribute__((visibility("default"))) TS_RoutingFees_clone(uint32_t orig) { LDKRoutingFees orig_conv; orig_conv.inner = (void*)(orig & (~1)); orig_conv.is_owned = false; LDKRoutingFees ret_var = RoutingFees_clone(&orig_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } int64_t __attribute__((visibility("default"))) TS_RoutingFees_hash(uint32_t o) { LDKRoutingFees o_conv; o_conv.inner = (void*)(o & (~1)); o_conv.is_owned = false; int64_t ret_val = RoutingFees_hash(&o_conv); return ret_val; } int8_tArray __attribute__((visibility("default"))) TS_RoutingFees_write(uint32_t obj) { LDKRoutingFees obj_conv; obj_conv.inner = (void*)(obj & (~1)); obj_conv.is_owned = false; LDKCVec_u8Z ret_var = RoutingFees_write(&obj_conv); int8_tArray ret_arr = init_arr(ret_var.datalen, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), ret_var.data, ret_var.datalen); CVec_u8Z_free(ret_var); return ret_arr; } uint32_t __attribute__((visibility("default"))) TS_RoutingFees_read(int8_tArray ser) { LDKu8slice ser_ref; ser_ref.datalen = *((uint32_t*)ser); ser_ref.data = (int8_t*)(ser + 4); LDKCResult_RoutingFeesDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_RoutingFeesDecodeErrorZ), "LDKCResult_RoutingFeesDecodeErrorZ"); *ret_conv = RoutingFees_read(ser_ref); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_NodeAnnouncementInfo_free(uint32_t this_obj) { LDKNodeAnnouncementInfo this_obj_conv; this_obj_conv.inner = (void*)(this_obj & (~1)); this_obj_conv.is_owned = (this_obj & 1) || (this_obj == 0); NodeAnnouncementInfo_free(this_obj_conv); } uint32_t __attribute__((visibility("default"))) TS_NodeAnnouncementInfo_get_features(uint32_t this_ptr) { LDKNodeAnnouncementInfo this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKNodeFeatures ret_var = NodeAnnouncementInfo_get_features(&this_ptr_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } void __attribute__((visibility("default"))) TS_NodeAnnouncementInfo_set_features(uint32_t this_ptr, uint32_t val) { LDKNodeAnnouncementInfo this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKNodeFeatures val_conv; val_conv.inner = (void*)(val & (~1)); val_conv.is_owned = (val & 1) || (val == 0); val_conv = NodeFeatures_clone(&val_conv); NodeAnnouncementInfo_set_features(&this_ptr_conv, val_conv); } int32_t __attribute__((visibility("default"))) TS_NodeAnnouncementInfo_get_last_update(uint32_t this_ptr) { LDKNodeAnnouncementInfo this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int32_t ret_val = NodeAnnouncementInfo_get_last_update(&this_ptr_conv); return ret_val; } void __attribute__((visibility("default"))) TS_NodeAnnouncementInfo_set_last_update(uint32_t this_ptr, int32_t val) { LDKNodeAnnouncementInfo this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; NodeAnnouncementInfo_set_last_update(&this_ptr_conv, val); } int8_tArray __attribute__((visibility("default"))) TS_NodeAnnouncementInfo_get_rgb(uint32_t this_ptr) { LDKNodeAnnouncementInfo this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int8_tArray ret_arr = init_arr(3, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), *NodeAnnouncementInfo_get_rgb(&this_ptr_conv), 3); return ret_arr; } void __attribute__((visibility("default"))) TS_NodeAnnouncementInfo_set_rgb(uint32_t this_ptr, int8_tArray val) { LDKNodeAnnouncementInfo this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKThreeBytes val_ref; CHECK(*((uint32_t*)val) == 3); memcpy(val_ref.data, (uint8_t*)(val + 4), 3); NodeAnnouncementInfo_set_rgb(&this_ptr_conv, val_ref); } int8_tArray __attribute__((visibility("default"))) TS_NodeAnnouncementInfo_get_alias(uint32_t this_ptr) { LDKNodeAnnouncementInfo this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; int8_tArray ret_arr = init_arr(32, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), *NodeAnnouncementInfo_get_alias(&this_ptr_conv), 32); return ret_arr; } void __attribute__((visibility("default"))) TS_NodeAnnouncementInfo_set_alias(uint32_t this_ptr, int8_tArray val) { LDKNodeAnnouncementInfo this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKThirtyTwoBytes val_ref; CHECK(*((uint32_t*)val) == 32); memcpy(val_ref.data, (uint8_t*)(val + 4), 32); NodeAnnouncementInfo_set_alias(&this_ptr_conv, val_ref); } void __attribute__((visibility("default"))) TS_NodeAnnouncementInfo_set_addresses(uint32_t this_ptr, uint32_tArray val) { LDKNodeAnnouncementInfo this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKCVec_NetAddressZ val_constr; val_constr.datalen = *((uint32_t*)val); if (val_constr.datalen > 0) val_constr.data = MALLOC(val_constr.datalen * sizeof(LDKNetAddress), "LDKCVec_NetAddressZ Elements"); else val_constr.data = NULL; uint32_t* val_vals = (uint32_t*)(val + 4); for (size_t m = 0; m < val_constr.datalen; m++) { uint32_t val_conv_12 = val_vals[m]; LDKNetAddress val_conv_12_conv = *(LDKNetAddress*)(((uint64_t)val_conv_12) & ~1); val_conv_12_conv = NetAddress_clone((LDKNetAddress*)(((uint64_t)val_conv_12) & ~1)); val_constr.data[m] = val_conv_12_conv; } NodeAnnouncementInfo_set_addresses(&this_ptr_conv, val_constr); } uint32_t __attribute__((visibility("default"))) TS_NodeAnnouncementInfo_get_announcement_message(uint32_t this_ptr) { LDKNodeAnnouncementInfo this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKNodeAnnouncement ret_var = NodeAnnouncementInfo_get_announcement_message(&this_ptr_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } void __attribute__((visibility("default"))) TS_NodeAnnouncementInfo_set_announcement_message(uint32_t this_ptr, uint32_t val) { LDKNodeAnnouncementInfo this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKNodeAnnouncement val_conv; val_conv.inner = (void*)(val & (~1)); val_conv.is_owned = (val & 1) || (val == 0); val_conv = NodeAnnouncement_clone(&val_conv); NodeAnnouncementInfo_set_announcement_message(&this_ptr_conv, val_conv); } uint32_t __attribute__((visibility("default"))) TS_NodeAnnouncementInfo_new(uint32_t features_arg, int32_t last_update_arg, int8_tArray rgb_arg, int8_tArray alias_arg, uint32_tArray addresses_arg, uint32_t announcement_message_arg) { LDKNodeFeatures features_arg_conv; features_arg_conv.inner = (void*)(features_arg & (~1)); features_arg_conv.is_owned = (features_arg & 1) || (features_arg == 0); features_arg_conv = NodeFeatures_clone(&features_arg_conv); LDKThreeBytes rgb_arg_ref; CHECK(*((uint32_t*)rgb_arg) == 3); memcpy(rgb_arg_ref.data, (uint8_t*)(rgb_arg + 4), 3); LDKThirtyTwoBytes alias_arg_ref; CHECK(*((uint32_t*)alias_arg) == 32); memcpy(alias_arg_ref.data, (uint8_t*)(alias_arg + 4), 32); LDKCVec_NetAddressZ addresses_arg_constr; addresses_arg_constr.datalen = *((uint32_t*)addresses_arg); if (addresses_arg_constr.datalen > 0) addresses_arg_constr.data = MALLOC(addresses_arg_constr.datalen * sizeof(LDKNetAddress), "LDKCVec_NetAddressZ Elements"); else addresses_arg_constr.data = NULL; uint32_t* addresses_arg_vals = (uint32_t*)(addresses_arg + 4); for (size_t m = 0; m < addresses_arg_constr.datalen; m++) { uint32_t addresses_arg_conv_12 = addresses_arg_vals[m]; LDKNetAddress addresses_arg_conv_12_conv = *(LDKNetAddress*)(((uint64_t)addresses_arg_conv_12) & ~1); addresses_arg_constr.data[m] = addresses_arg_conv_12_conv; } LDKNodeAnnouncement announcement_message_arg_conv; announcement_message_arg_conv.inner = (void*)(announcement_message_arg & (~1)); announcement_message_arg_conv.is_owned = (announcement_message_arg & 1) || (announcement_message_arg == 0); announcement_message_arg_conv = NodeAnnouncement_clone(&announcement_message_arg_conv); LDKNodeAnnouncementInfo ret_var = NodeAnnouncementInfo_new(features_arg_conv, last_update_arg, rgb_arg_ref, alias_arg_ref, addresses_arg_constr, announcement_message_arg_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_NodeAnnouncementInfo_clone(uint32_t orig) { LDKNodeAnnouncementInfo orig_conv; orig_conv.inner = (void*)(orig & (~1)); orig_conv.is_owned = false; LDKNodeAnnouncementInfo ret_var = NodeAnnouncementInfo_clone(&orig_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } int8_tArray __attribute__((visibility("default"))) TS_NodeAnnouncementInfo_write(uint32_t obj) { LDKNodeAnnouncementInfo obj_conv; obj_conv.inner = (void*)(obj & (~1)); obj_conv.is_owned = false; LDKCVec_u8Z ret_var = NodeAnnouncementInfo_write(&obj_conv); int8_tArray ret_arr = init_arr(ret_var.datalen, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), ret_var.data, ret_var.datalen); CVec_u8Z_free(ret_var); return ret_arr; } uint32_t __attribute__((visibility("default"))) TS_NodeAnnouncementInfo_read(int8_tArray ser) { LDKu8slice ser_ref; ser_ref.datalen = *((uint32_t*)ser); ser_ref.data = (int8_t*)(ser + 4); LDKCResult_NodeAnnouncementInfoDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_NodeAnnouncementInfoDecodeErrorZ), "LDKCResult_NodeAnnouncementInfoDecodeErrorZ"); *ret_conv = NodeAnnouncementInfo_read(ser_ref); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_NodeInfo_free(uint32_t this_obj) { LDKNodeInfo this_obj_conv; this_obj_conv.inner = (void*)(this_obj & (~1)); this_obj_conv.is_owned = (this_obj & 1) || (this_obj == 0); NodeInfo_free(this_obj_conv); } void __attribute__((visibility("default"))) TS_NodeInfo_set_channels(uint32_t this_ptr, int64_tArray val) { LDKNodeInfo this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKCVec_u64Z val_constr; val_constr.datalen = *((uint32_t*)val); if (val_constr.datalen > 0) val_constr.data = MALLOC(val_constr.datalen * sizeof(int64_t), "LDKCVec_u64Z Elements"); else val_constr.data = NULL; int64_t* val_vals = (int64_t*)(val + 4); for (size_t i = 0; i < val_constr.datalen; i++) { int64_t val_conv_8 = val_vals[i]; val_constr.data[i] = val_conv_8; } NodeInfo_set_channels(&this_ptr_conv, val_constr); } uint32_t __attribute__((visibility("default"))) TS_NodeInfo_get_lowest_inbound_channel_fees(uint32_t this_ptr) { LDKNodeInfo this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKRoutingFees ret_var = NodeInfo_get_lowest_inbound_channel_fees(&this_ptr_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } void __attribute__((visibility("default"))) TS_NodeInfo_set_lowest_inbound_channel_fees(uint32_t this_ptr, uint32_t val) { LDKNodeInfo this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKRoutingFees val_conv; val_conv.inner = (void*)(val & (~1)); val_conv.is_owned = (val & 1) || (val == 0); val_conv = RoutingFees_clone(&val_conv); NodeInfo_set_lowest_inbound_channel_fees(&this_ptr_conv, val_conv); } uint32_t __attribute__((visibility("default"))) TS_NodeInfo_get_announcement_info(uint32_t this_ptr) { LDKNodeInfo this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKNodeAnnouncementInfo ret_var = NodeInfo_get_announcement_info(&this_ptr_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } void __attribute__((visibility("default"))) TS_NodeInfo_set_announcement_info(uint32_t this_ptr, uint32_t val) { LDKNodeInfo this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKNodeAnnouncementInfo val_conv; val_conv.inner = (void*)(val & (~1)); val_conv.is_owned = (val & 1) || (val == 0); val_conv = NodeAnnouncementInfo_clone(&val_conv); NodeInfo_set_announcement_info(&this_ptr_conv, val_conv); } uint32_t __attribute__((visibility("default"))) TS_NodeInfo_new(int64_tArray channels_arg, uint32_t lowest_inbound_channel_fees_arg, uint32_t announcement_info_arg) { LDKCVec_u64Z channels_arg_constr; channels_arg_constr.datalen = *((uint32_t*)channels_arg); if (channels_arg_constr.datalen > 0) channels_arg_constr.data = MALLOC(channels_arg_constr.datalen * sizeof(int64_t), "LDKCVec_u64Z Elements"); else channels_arg_constr.data = NULL; int64_t* channels_arg_vals = (int64_t*)(channels_arg + 4); for (size_t i = 0; i < channels_arg_constr.datalen; i++) { int64_t channels_arg_conv_8 = channels_arg_vals[i]; channels_arg_constr.data[i] = channels_arg_conv_8; } LDKRoutingFees lowest_inbound_channel_fees_arg_conv; lowest_inbound_channel_fees_arg_conv.inner = (void*)(lowest_inbound_channel_fees_arg & (~1)); lowest_inbound_channel_fees_arg_conv.is_owned = (lowest_inbound_channel_fees_arg & 1) || (lowest_inbound_channel_fees_arg == 0); lowest_inbound_channel_fees_arg_conv = RoutingFees_clone(&lowest_inbound_channel_fees_arg_conv); LDKNodeAnnouncementInfo announcement_info_arg_conv; announcement_info_arg_conv.inner = (void*)(announcement_info_arg & (~1)); announcement_info_arg_conv.is_owned = (announcement_info_arg & 1) || (announcement_info_arg == 0); announcement_info_arg_conv = NodeAnnouncementInfo_clone(&announcement_info_arg_conv); LDKNodeInfo ret_var = NodeInfo_new(channels_arg_constr, lowest_inbound_channel_fees_arg_conv, announcement_info_arg_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_NodeInfo_clone(uint32_t orig) { LDKNodeInfo orig_conv; orig_conv.inner = (void*)(orig & (~1)); orig_conv.is_owned = false; LDKNodeInfo ret_var = NodeInfo_clone(&orig_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } int8_tArray __attribute__((visibility("default"))) TS_NodeInfo_write(uint32_t obj) { LDKNodeInfo obj_conv; obj_conv.inner = (void*)(obj & (~1)); obj_conv.is_owned = false; LDKCVec_u8Z ret_var = NodeInfo_write(&obj_conv); int8_tArray ret_arr = init_arr(ret_var.datalen, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), ret_var.data, ret_var.datalen); CVec_u8Z_free(ret_var); return ret_arr; } uint32_t __attribute__((visibility("default"))) TS_NodeInfo_read(int8_tArray ser) { LDKu8slice ser_ref; ser_ref.datalen = *((uint32_t*)ser); ser_ref.data = (int8_t*)(ser + 4); LDKCResult_NodeInfoDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_NodeInfoDecodeErrorZ), "LDKCResult_NodeInfoDecodeErrorZ"); *ret_conv = NodeInfo_read(ser_ref); return (uint64_t)ret_conv; } int8_tArray __attribute__((visibility("default"))) TS_NetworkGraph_write(uint32_t obj) { LDKNetworkGraph obj_conv; obj_conv.inner = (void*)(obj & (~1)); obj_conv.is_owned = false; LDKCVec_u8Z ret_var = NetworkGraph_write(&obj_conv); int8_tArray ret_arr = init_arr(ret_var.datalen, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), ret_var.data, ret_var.datalen); CVec_u8Z_free(ret_var); return ret_arr; } uint32_t __attribute__((visibility("default"))) TS_NetworkGraph_read(int8_tArray ser) { LDKu8slice ser_ref; ser_ref.datalen = *((uint32_t*)ser); ser_ref.data = (int8_t*)(ser + 4); LDKCResult_NetworkGraphDecodeErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_NetworkGraphDecodeErrorZ), "LDKCResult_NetworkGraphDecodeErrorZ"); *ret_conv = NetworkGraph_read(ser_ref); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_NetworkGraph_new(int8_tArray genesis_hash) { LDKThirtyTwoBytes genesis_hash_ref; CHECK(*((uint32_t*)genesis_hash) == 32); memcpy(genesis_hash_ref.data, (uint8_t*)(genesis_hash + 4), 32); LDKNetworkGraph ret_var = NetworkGraph_new(genesis_hash_ref); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_NetworkGraph_read_only(uint32_t this_arg) { LDKNetworkGraph this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; LDKReadOnlyNetworkGraph ret_var = NetworkGraph_read_only(&this_arg_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_NetworkGraph_update_node_from_announcement(uint32_t this_arg, uint32_t msg) { LDKNetworkGraph this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; LDKNodeAnnouncement msg_conv; msg_conv.inner = (void*)(msg & (~1)); msg_conv.is_owned = false; LDKCResult_NoneLightningErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_NoneLightningErrorZ), "LDKCResult_NoneLightningErrorZ"); *ret_conv = NetworkGraph_update_node_from_announcement(&this_arg_conv, &msg_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_NetworkGraph_update_node_from_unsigned_announcement(uint32_t this_arg, uint32_t msg) { LDKNetworkGraph this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; LDKUnsignedNodeAnnouncement msg_conv; msg_conv.inner = (void*)(msg & (~1)); msg_conv.is_owned = false; LDKCResult_NoneLightningErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_NoneLightningErrorZ), "LDKCResult_NoneLightningErrorZ"); *ret_conv = NetworkGraph_update_node_from_unsigned_announcement(&this_arg_conv, &msg_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_NetworkGraph_update_channel_from_announcement(uint32_t this_arg, uint32_t msg, uint32_t chain_access) { LDKNetworkGraph this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; LDKChannelAnnouncement msg_conv; msg_conv.inner = (void*)(msg & (~1)); msg_conv.is_owned = false; LDKCOption_AccessZ chain_access_conv = *(LDKCOption_AccessZ*)(((uint64_t)chain_access) & ~1); // Warning: we may need a move here but no clone is available for LDKCOption_AccessZ if (chain_access_conv.tag == LDKCOption_AccessZ_Some) { // Manually implement clone for Java trait instances } LDKCResult_NoneLightningErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_NoneLightningErrorZ), "LDKCResult_NoneLightningErrorZ"); *ret_conv = NetworkGraph_update_channel_from_announcement(&this_arg_conv, &msg_conv, chain_access_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_NetworkGraph_update_channel_from_unsigned_announcement(uint32_t this_arg, uint32_t msg, uint32_t chain_access) { LDKNetworkGraph this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; LDKUnsignedChannelAnnouncement msg_conv; msg_conv.inner = (void*)(msg & (~1)); msg_conv.is_owned = false; LDKCOption_AccessZ chain_access_conv = *(LDKCOption_AccessZ*)(((uint64_t)chain_access) & ~1); // Warning: we may need a move here but no clone is available for LDKCOption_AccessZ if (chain_access_conv.tag == LDKCOption_AccessZ_Some) { // Manually implement clone for Java trait instances } LDKCResult_NoneLightningErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_NoneLightningErrorZ), "LDKCResult_NoneLightningErrorZ"); *ret_conv = NetworkGraph_update_channel_from_unsigned_announcement(&this_arg_conv, &msg_conv, chain_access_conv); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_NetworkGraph_close_channel_from_update(uint32_t this_arg, int64_t short_channel_id, jboolean is_permanent) { LDKNetworkGraph this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; NetworkGraph_close_channel_from_update(&this_arg_conv, short_channel_id, is_permanent); } void __attribute__((visibility("default"))) TS_NetworkGraph_fail_node(uint32_t this_arg, int8_tArray _node_id, jboolean is_permanent) { LDKNetworkGraph this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; LDKPublicKey _node_id_ref; CHECK(*((uint32_t*)_node_id) == 33); memcpy(_node_id_ref.compressed_form, (uint8_t*)(_node_id + 4), 33); NetworkGraph_fail_node(&this_arg_conv, _node_id_ref, is_permanent); } uint32_t __attribute__((visibility("default"))) TS_NetworkGraph_update_channel(uint32_t this_arg, uint32_t msg) { LDKNetworkGraph this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; LDKChannelUpdate msg_conv; msg_conv.inner = (void*)(msg & (~1)); msg_conv.is_owned = false; LDKCResult_NoneLightningErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_NoneLightningErrorZ), "LDKCResult_NoneLightningErrorZ"); *ret_conv = NetworkGraph_update_channel(&this_arg_conv, &msg_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_NetworkGraph_update_channel_unsigned(uint32_t this_arg, uint32_t msg) { LDKNetworkGraph this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; LDKUnsignedChannelUpdate msg_conv; msg_conv.inner = (void*)(msg & (~1)); msg_conv.is_owned = false; LDKCResult_NoneLightningErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_NoneLightningErrorZ), "LDKCResult_NoneLightningErrorZ"); *ret_conv = NetworkGraph_update_channel_unsigned(&this_arg_conv, &msg_conv); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_FilesystemPersister_free(uint32_t this_obj) { LDKFilesystemPersister this_obj_conv; this_obj_conv.inner = (void*)(this_obj & (~1)); this_obj_conv.is_owned = (this_obj & 1) || (this_obj == 0); FilesystemPersister_free(this_obj_conv); } uint32_t __attribute__((visibility("default"))) TS_FilesystemPersister_new(jstring path_to_channel_data) { LDKStr path_to_channel_data_conv = str_ref_to_owned_c(path_to_channel_data); LDKFilesystemPersister ret_var = FilesystemPersister_new(path_to_channel_data_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } jstring __attribute__((visibility("default"))) TS_FilesystemPersister_get_data_dir(uint32_t this_arg) { LDKFilesystemPersister this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; LDKStr ret_str = FilesystemPersister_get_data_dir(&this_arg_conv); jstring ret_conv = str_ref_to_ts(ret_str.chars, ret_str.len); Str_free(ret_str); return ret_conv; } uint32_t __attribute__((visibility("default"))) TS_FilesystemPersister_persist_manager(jstring data_dir, uint32_t manager) { LDKStr data_dir_conv = str_ref_to_owned_c(data_dir); LDKChannelManager manager_conv; manager_conv.inner = (void*)(manager & (~1)); manager_conv.is_owned = false; LDKCResult_NoneErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_NoneErrorZ), "LDKCResult_NoneErrorZ"); *ret_conv = FilesystemPersister_persist_manager(data_dir_conv, &manager_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_FilesystemPersister_read_channelmonitors(uint32_t this_arg, uint32_t keys_manager) { LDKFilesystemPersister this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; LDKKeysInterface keys_manager_conv = *(LDKKeysInterface*)(((uint64_t)keys_manager) & ~1); LDKCResult_CVec_C2Tuple_BlockHashChannelMonitorZZErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_CVec_C2Tuple_BlockHashChannelMonitorZZErrorZ), "LDKCResult_CVec_C2Tuple_BlockHashChannelMonitorZZErrorZ"); *ret_conv = FilesystemPersister_read_channelmonitors(&this_arg_conv, keys_manager_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_FilesystemPersister_as_Persist(uint32_t this_arg) { LDKFilesystemPersister this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; LDKPersist* ret_ret =MALLOC(sizeof(LDKPersist), "LDKPersist"); *ret_ret = FilesystemPersister_as_Persist(&this_arg_conv); return (uint64_t)ret_ret; } void __attribute__((visibility("default"))) TS_BackgroundProcessor_free(uint32_t this_obj) { LDKBackgroundProcessor this_obj_conv; this_obj_conv.inner = (void*)(this_obj & (~1)); this_obj_conv.is_owned = (this_obj & 1) || (this_obj == 0); BackgroundProcessor_free(this_obj_conv); } void __attribute__((visibility("default"))) TS_ChannelManagerPersister_free(uint32_t this_ptr) { if ((this_ptr & 1) != 0) return; LDKChannelManagerPersister this_ptr_conv = *(LDKChannelManagerPersister*)(((uint64_t)this_ptr) & ~1); FREE((void*)this_ptr); ChannelManagerPersister_free(this_ptr_conv); } uint32_t __attribute__((visibility("default"))) TS_BackgroundProcessor_start(uint32_t persister, uint32_t event_handler, uint32_t chain_monitor, uint32_t channel_manager, uint32_t net_graph_msg_handler, uint32_t peer_manager, uint32_t logger) { LDKChannelManagerPersister persister_conv = *(LDKChannelManagerPersister*)(((uint64_t)persister) & ~1); LDKEventHandler event_handler_conv = *(LDKEventHandler*)(((uint64_t)event_handler) & ~1); LDKChainMonitor chain_monitor_conv; chain_monitor_conv.inner = (void*)(chain_monitor & (~1)); chain_monitor_conv.is_owned = false; LDKChannelManager channel_manager_conv; channel_manager_conv.inner = (void*)(channel_manager & (~1)); channel_manager_conv.is_owned = false; LDKNetGraphMsgHandler net_graph_msg_handler_conv; net_graph_msg_handler_conv.inner = (void*)(net_graph_msg_handler & (~1)); net_graph_msg_handler_conv.is_owned = (net_graph_msg_handler & 1) || (net_graph_msg_handler == 0); LDKPeerManager peer_manager_conv; peer_manager_conv.inner = (void*)(peer_manager & (~1)); peer_manager_conv.is_owned = false; LDKLogger logger_conv = *(LDKLogger*)(((uint64_t)logger) & ~1); LDKBackgroundProcessor ret_var = BackgroundProcessor_start(persister_conv, event_handler_conv, &chain_monitor_conv, &channel_manager_conv, net_graph_msg_handler_conv, &peer_manager_conv, logger_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_BackgroundProcessor_join(uint32_t this_arg) { LDKBackgroundProcessor this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = (this_arg & 1) || (this_arg == 0); // Warning: we need a move here but no clone is available for LDKBackgroundProcessor LDKCResult_NoneErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_NoneErrorZ), "LDKCResult_NoneErrorZ"); *ret_conv = BackgroundProcessor_join(this_arg_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_BackgroundProcessor_stop(uint32_t this_arg) { LDKBackgroundProcessor this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = (this_arg & 1) || (this_arg == 0); // Warning: we need a move here but no clone is available for LDKBackgroundProcessor LDKCResult_NoneErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_NoneErrorZ), "LDKCResult_NoneErrorZ"); *ret_conv = BackgroundProcessor_stop(this_arg_conv); return (uint64_t)ret_conv; } void __attribute__((visibility("default"))) TS_check_platform() { check_platform(); } void __attribute__((visibility("default"))) TS_Invoice_free(uint32_t this_obj) { LDKInvoice this_obj_conv; this_obj_conv.inner = (void*)(this_obj & (~1)); this_obj_conv.is_owned = (this_obj & 1) || (this_obj == 0); Invoice_free(this_obj_conv); } jboolean __attribute__((visibility("default"))) TS_Invoice_eq(uint32_t a, uint32_t b) { LDKInvoice a_conv; a_conv.inner = (void*)(a & (~1)); a_conv.is_owned = false; LDKInvoice b_conv; b_conv.inner = (void*)(b & (~1)); b_conv.is_owned = false; jboolean ret_val = Invoice_eq(&a_conv, &b_conv); return ret_val; } uint32_t __attribute__((visibility("default"))) TS_Invoice_clone(uint32_t orig) { LDKInvoice orig_conv; orig_conv.inner = (void*)(orig & (~1)); orig_conv.is_owned = false; LDKInvoice ret_var = Invoice_clone(&orig_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } void __attribute__((visibility("default"))) TS_SignedRawInvoice_free(uint32_t this_obj) { LDKSignedRawInvoice this_obj_conv; this_obj_conv.inner = (void*)(this_obj & (~1)); this_obj_conv.is_owned = (this_obj & 1) || (this_obj == 0); SignedRawInvoice_free(this_obj_conv); } jboolean __attribute__((visibility("default"))) TS_SignedRawInvoice_eq(uint32_t a, uint32_t b) { LDKSignedRawInvoice a_conv; a_conv.inner = (void*)(a & (~1)); a_conv.is_owned = false; LDKSignedRawInvoice b_conv; b_conv.inner = (void*)(b & (~1)); b_conv.is_owned = false; jboolean ret_val = SignedRawInvoice_eq(&a_conv, &b_conv); return ret_val; } uint32_t __attribute__((visibility("default"))) TS_SignedRawInvoice_clone(uint32_t orig) { LDKSignedRawInvoice orig_conv; orig_conv.inner = (void*)(orig & (~1)); orig_conv.is_owned = false; LDKSignedRawInvoice ret_var = SignedRawInvoice_clone(&orig_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } void __attribute__((visibility("default"))) TS_RawInvoice_free(uint32_t this_obj) { LDKRawInvoice this_obj_conv; this_obj_conv.inner = (void*)(this_obj & (~1)); this_obj_conv.is_owned = (this_obj & 1) || (this_obj == 0); RawInvoice_free(this_obj_conv); } uint32_t __attribute__((visibility("default"))) TS_RawInvoice_get_data(uint32_t this_ptr) { LDKRawInvoice this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKRawDataPart ret_var = RawInvoice_get_data(&this_ptr_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } void __attribute__((visibility("default"))) TS_RawInvoice_set_data(uint32_t this_ptr, uint32_t val) { LDKRawInvoice this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKRawDataPart val_conv; val_conv.inner = (void*)(val & (~1)); val_conv.is_owned = (val & 1) || (val == 0); val_conv = RawDataPart_clone(&val_conv); RawInvoice_set_data(&this_ptr_conv, val_conv); } jboolean __attribute__((visibility("default"))) TS_RawInvoice_eq(uint32_t a, uint32_t b) { LDKRawInvoice a_conv; a_conv.inner = (void*)(a & (~1)); a_conv.is_owned = false; LDKRawInvoice b_conv; b_conv.inner = (void*)(b & (~1)); b_conv.is_owned = false; jboolean ret_val = RawInvoice_eq(&a_conv, &b_conv); return ret_val; } uint32_t __attribute__((visibility("default"))) TS_RawInvoice_clone(uint32_t orig) { LDKRawInvoice orig_conv; orig_conv.inner = (void*)(orig & (~1)); orig_conv.is_owned = false; LDKRawInvoice ret_var = RawInvoice_clone(&orig_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } void __attribute__((visibility("default"))) TS_RawDataPart_free(uint32_t this_obj) { LDKRawDataPart this_obj_conv; this_obj_conv.inner = (void*)(this_obj & (~1)); this_obj_conv.is_owned = (this_obj & 1) || (this_obj == 0); RawDataPart_free(this_obj_conv); } uint32_t __attribute__((visibility("default"))) TS_RawDataPart_get_timestamp(uint32_t this_ptr) { LDKRawDataPart this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKPositiveTimestamp ret_var = RawDataPart_get_timestamp(&this_ptr_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } void __attribute__((visibility("default"))) TS_RawDataPart_set_timestamp(uint32_t this_ptr, uint32_t val) { LDKRawDataPart this_ptr_conv; this_ptr_conv.inner = (void*)(this_ptr & (~1)); this_ptr_conv.is_owned = false; LDKPositiveTimestamp val_conv; val_conv.inner = (void*)(val & (~1)); val_conv.is_owned = (val & 1) || (val == 0); val_conv = PositiveTimestamp_clone(&val_conv); RawDataPart_set_timestamp(&this_ptr_conv, val_conv); } jboolean __attribute__((visibility("default"))) TS_RawDataPart_eq(uint32_t a, uint32_t b) { LDKRawDataPart a_conv; a_conv.inner = (void*)(a & (~1)); a_conv.is_owned = false; LDKRawDataPart b_conv; b_conv.inner = (void*)(b & (~1)); b_conv.is_owned = false; jboolean ret_val = RawDataPart_eq(&a_conv, &b_conv); return ret_val; } uint32_t __attribute__((visibility("default"))) TS_RawDataPart_clone(uint32_t orig) { LDKRawDataPart orig_conv; orig_conv.inner = (void*)(orig & (~1)); orig_conv.is_owned = false; LDKRawDataPart ret_var = RawDataPart_clone(&orig_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } void __attribute__((visibility("default"))) TS_PositiveTimestamp_free(uint32_t this_obj) { LDKPositiveTimestamp this_obj_conv; this_obj_conv.inner = (void*)(this_obj & (~1)); this_obj_conv.is_owned = (this_obj & 1) || (this_obj == 0); PositiveTimestamp_free(this_obj_conv); } jboolean __attribute__((visibility("default"))) TS_PositiveTimestamp_eq(uint32_t a, uint32_t b) { LDKPositiveTimestamp a_conv; a_conv.inner = (void*)(a & (~1)); a_conv.is_owned = false; LDKPositiveTimestamp b_conv; b_conv.inner = (void*)(b & (~1)); b_conv.is_owned = false; jboolean ret_val = PositiveTimestamp_eq(&a_conv, &b_conv); return ret_val; } uint32_t __attribute__((visibility("default"))) TS_PositiveTimestamp_clone(uint32_t orig) { LDKPositiveTimestamp orig_conv; orig_conv.inner = (void*)(orig & (~1)); orig_conv.is_owned = false; LDKPositiveTimestamp ret_var = PositiveTimestamp_clone(&orig_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_SiPrefix_clone(uint32_t orig) { LDKSiPrefix* orig_conv = (LDKSiPrefix*)(orig & ~1); uint32_t ret_conv = LDKSiPrefix_to_js(SiPrefix_clone(orig_conv)); return ret_conv; } uint32_t __attribute__((visibility("default"))) TS_SiPrefix_milli() { uint32_t ret_conv = LDKSiPrefix_to_js(SiPrefix_milli()); return ret_conv; } uint32_t __attribute__((visibility("default"))) TS_SiPrefix_micro() { uint32_t ret_conv = LDKSiPrefix_to_js(SiPrefix_micro()); return ret_conv; } uint32_t __attribute__((visibility("default"))) TS_SiPrefix_nano() { uint32_t ret_conv = LDKSiPrefix_to_js(SiPrefix_nano()); return ret_conv; } uint32_t __attribute__((visibility("default"))) TS_SiPrefix_pico() { uint32_t ret_conv = LDKSiPrefix_to_js(SiPrefix_pico()); return ret_conv; } jboolean __attribute__((visibility("default"))) TS_SiPrefix_eq(uint32_t a, uint32_t b) { LDKSiPrefix* a_conv = (LDKSiPrefix*)(a & ~1); LDKSiPrefix* b_conv = (LDKSiPrefix*)(b & ~1); jboolean ret_val = SiPrefix_eq(a_conv, b_conv); return ret_val; } int64_t __attribute__((visibility("default"))) TS_SiPrefix_multiplier(uint32_t this_arg) { LDKSiPrefix* this_arg_conv = (LDKSiPrefix*)(this_arg & ~1); int64_t ret_val = SiPrefix_multiplier(this_arg_conv); return ret_val; } uint32_t __attribute__((visibility("default"))) TS_Currency_clone(uint32_t orig) { LDKCurrency* orig_conv = (LDKCurrency*)(orig & ~1); uint32_t ret_conv = LDKCurrency_to_js(Currency_clone(orig_conv)); return ret_conv; } uint32_t __attribute__((visibility("default"))) TS_Currency_bitcoin() { uint32_t ret_conv = LDKCurrency_to_js(Currency_bitcoin()); return ret_conv; } uint32_t __attribute__((visibility("default"))) TS_Currency_bitcoin_testnet() { uint32_t ret_conv = LDKCurrency_to_js(Currency_bitcoin_testnet()); return ret_conv; } uint32_t __attribute__((visibility("default"))) TS_Currency_regtest() { uint32_t ret_conv = LDKCurrency_to_js(Currency_regtest()); return ret_conv; } uint32_t __attribute__((visibility("default"))) TS_Currency_simnet() { uint32_t ret_conv = LDKCurrency_to_js(Currency_simnet()); return ret_conv; } uint32_t __attribute__((visibility("default"))) TS_Currency_signet() { uint32_t ret_conv = LDKCurrency_to_js(Currency_signet()); return ret_conv; } int64_t __attribute__((visibility("default"))) TS_Currency_hash(uint32_t o) { LDKCurrency* o_conv = (LDKCurrency*)(o & ~1); int64_t ret_val = Currency_hash(o_conv); return ret_val; } jboolean __attribute__((visibility("default"))) TS_Currency_eq(uint32_t a, uint32_t b) { LDKCurrency* a_conv = (LDKCurrency*)(a & ~1); LDKCurrency* b_conv = (LDKCurrency*)(b & ~1); jboolean ret_val = Currency_eq(a_conv, b_conv); return ret_val; } void __attribute__((visibility("default"))) TS_Sha256_free(uint32_t this_obj) { LDKSha256 this_obj_conv; this_obj_conv.inner = (void*)(this_obj & (~1)); this_obj_conv.is_owned = (this_obj & 1) || (this_obj == 0); Sha256_free(this_obj_conv); } uint32_t __attribute__((visibility("default"))) TS_Sha256_clone(uint32_t orig) { LDKSha256 orig_conv; orig_conv.inner = (void*)(orig & (~1)); orig_conv.is_owned = false; LDKSha256 ret_var = Sha256_clone(&orig_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } int64_t __attribute__((visibility("default"))) TS_Sha256_hash(uint32_t o) { LDKSha256 o_conv; o_conv.inner = (void*)(o & (~1)); o_conv.is_owned = false; int64_t ret_val = Sha256_hash(&o_conv); return ret_val; } jboolean __attribute__((visibility("default"))) TS_Sha256_eq(uint32_t a, uint32_t b) { LDKSha256 a_conv; a_conv.inner = (void*)(a & (~1)); a_conv.is_owned = false; LDKSha256 b_conv; b_conv.inner = (void*)(b & (~1)); b_conv.is_owned = false; jboolean ret_val = Sha256_eq(&a_conv, &b_conv); return ret_val; } void __attribute__((visibility("default"))) TS_Description_free(uint32_t this_obj) { LDKDescription this_obj_conv; this_obj_conv.inner = (void*)(this_obj & (~1)); this_obj_conv.is_owned = (this_obj & 1) || (this_obj == 0); Description_free(this_obj_conv); } uint32_t __attribute__((visibility("default"))) TS_Description_clone(uint32_t orig) { LDKDescription orig_conv; orig_conv.inner = (void*)(orig & (~1)); orig_conv.is_owned = false; LDKDescription ret_var = Description_clone(&orig_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } int64_t __attribute__((visibility("default"))) TS_Description_hash(uint32_t o) { LDKDescription o_conv; o_conv.inner = (void*)(o & (~1)); o_conv.is_owned = false; int64_t ret_val = Description_hash(&o_conv); return ret_val; } jboolean __attribute__((visibility("default"))) TS_Description_eq(uint32_t a, uint32_t b) { LDKDescription a_conv; a_conv.inner = (void*)(a & (~1)); a_conv.is_owned = false; LDKDescription b_conv; b_conv.inner = (void*)(b & (~1)); b_conv.is_owned = false; jboolean ret_val = Description_eq(&a_conv, &b_conv); return ret_val; } void __attribute__((visibility("default"))) TS_PayeePubKey_free(uint32_t this_obj) { LDKPayeePubKey this_obj_conv; this_obj_conv.inner = (void*)(this_obj & (~1)); this_obj_conv.is_owned = (this_obj & 1) || (this_obj == 0); PayeePubKey_free(this_obj_conv); } uint32_t __attribute__((visibility("default"))) TS_PayeePubKey_clone(uint32_t orig) { LDKPayeePubKey orig_conv; orig_conv.inner = (void*)(orig & (~1)); orig_conv.is_owned = false; LDKPayeePubKey ret_var = PayeePubKey_clone(&orig_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } int64_t __attribute__((visibility("default"))) TS_PayeePubKey_hash(uint32_t o) { LDKPayeePubKey o_conv; o_conv.inner = (void*)(o & (~1)); o_conv.is_owned = false; int64_t ret_val = PayeePubKey_hash(&o_conv); return ret_val; } jboolean __attribute__((visibility("default"))) TS_PayeePubKey_eq(uint32_t a, uint32_t b) { LDKPayeePubKey a_conv; a_conv.inner = (void*)(a & (~1)); a_conv.is_owned = false; LDKPayeePubKey b_conv; b_conv.inner = (void*)(b & (~1)); b_conv.is_owned = false; jboolean ret_val = PayeePubKey_eq(&a_conv, &b_conv); return ret_val; } void __attribute__((visibility("default"))) TS_ExpiryTime_free(uint32_t this_obj) { LDKExpiryTime this_obj_conv; this_obj_conv.inner = (void*)(this_obj & (~1)); this_obj_conv.is_owned = (this_obj & 1) || (this_obj == 0); ExpiryTime_free(this_obj_conv); } uint32_t __attribute__((visibility("default"))) TS_ExpiryTime_clone(uint32_t orig) { LDKExpiryTime orig_conv; orig_conv.inner = (void*)(orig & (~1)); orig_conv.is_owned = false; LDKExpiryTime ret_var = ExpiryTime_clone(&orig_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } int64_t __attribute__((visibility("default"))) TS_ExpiryTime_hash(uint32_t o) { LDKExpiryTime o_conv; o_conv.inner = (void*)(o & (~1)); o_conv.is_owned = false; int64_t ret_val = ExpiryTime_hash(&o_conv); return ret_val; } jboolean __attribute__((visibility("default"))) TS_ExpiryTime_eq(uint32_t a, uint32_t b) { LDKExpiryTime a_conv; a_conv.inner = (void*)(a & (~1)); a_conv.is_owned = false; LDKExpiryTime b_conv; b_conv.inner = (void*)(b & (~1)); b_conv.is_owned = false; jboolean ret_val = ExpiryTime_eq(&a_conv, &b_conv); return ret_val; } void __attribute__((visibility("default"))) TS_MinFinalCltvExpiry_free(uint32_t this_obj) { LDKMinFinalCltvExpiry this_obj_conv; this_obj_conv.inner = (void*)(this_obj & (~1)); this_obj_conv.is_owned = (this_obj & 1) || (this_obj == 0); MinFinalCltvExpiry_free(this_obj_conv); } uint32_t __attribute__((visibility("default"))) TS_MinFinalCltvExpiry_clone(uint32_t orig) { LDKMinFinalCltvExpiry orig_conv; orig_conv.inner = (void*)(orig & (~1)); orig_conv.is_owned = false; LDKMinFinalCltvExpiry ret_var = MinFinalCltvExpiry_clone(&orig_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } int64_t __attribute__((visibility("default"))) TS_MinFinalCltvExpiry_hash(uint32_t o) { LDKMinFinalCltvExpiry o_conv; o_conv.inner = (void*)(o & (~1)); o_conv.is_owned = false; int64_t ret_val = MinFinalCltvExpiry_hash(&o_conv); return ret_val; } jboolean __attribute__((visibility("default"))) TS_MinFinalCltvExpiry_eq(uint32_t a, uint32_t b) { LDKMinFinalCltvExpiry a_conv; a_conv.inner = (void*)(a & (~1)); a_conv.is_owned = false; LDKMinFinalCltvExpiry b_conv; b_conv.inner = (void*)(b & (~1)); b_conv.is_owned = false; jboolean ret_val = MinFinalCltvExpiry_eq(&a_conv, &b_conv); return ret_val; } void __attribute__((visibility("default"))) TS_Fallback_free(uint32_t this_ptr) { if ((this_ptr & 1) != 0) return; LDKFallback this_ptr_conv = *(LDKFallback*)(((uint64_t)this_ptr) & ~1); FREE((void*)this_ptr); Fallback_free(this_ptr_conv); } uint32_t __attribute__((visibility("default"))) TS_Fallback_clone(uint32_t orig) { LDKFallback* orig_conv = (LDKFallback*)orig; LDKFallback *ret_copy = MALLOC(sizeof(LDKFallback), "LDKFallback"); *ret_copy = Fallback_clone(orig_conv); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_Fallback_seg_wit_program(int8_t version, int8_tArray program) { LDKCVec_u8Z program_ref; program_ref.datalen = *((uint32_t*)program); program_ref.data = MALLOC(program_ref.datalen, "LDKCVec_u8Z Bytes"); memcpy(program_ref.data, (uint8_t*)(program + 4), program_ref.datalen); LDKFallback *ret_copy = MALLOC(sizeof(LDKFallback), "LDKFallback"); *ret_copy = Fallback_seg_wit_program((LDKu5){ ._0 = version }, program_ref); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_Fallback_pub_key_hash(int8_tArray a) { LDKTwentyBytes a_ref; CHECK(*((uint32_t*)a) == 20); memcpy(a_ref.data, (uint8_t*)(a + 4), 20); LDKFallback *ret_copy = MALLOC(sizeof(LDKFallback), "LDKFallback"); *ret_copy = Fallback_pub_key_hash(a_ref); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_Fallback_script_hash(int8_tArray a) { LDKTwentyBytes a_ref; CHECK(*((uint32_t*)a) == 20); memcpy(a_ref.data, (uint8_t*)(a + 4), 20); LDKFallback *ret_copy = MALLOC(sizeof(LDKFallback), "LDKFallback"); *ret_copy = Fallback_script_hash(a_ref); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } int64_t __attribute__((visibility("default"))) TS_Fallback_hash(uint32_t o) { LDKFallback* o_conv = (LDKFallback*)o; int64_t ret_val = Fallback_hash(o_conv); return ret_val; } jboolean __attribute__((visibility("default"))) TS_Fallback_eq(uint32_t a, uint32_t b) { LDKFallback* a_conv = (LDKFallback*)a; LDKFallback* b_conv = (LDKFallback*)b; jboolean ret_val = Fallback_eq(a_conv, b_conv); return ret_val; } void __attribute__((visibility("default"))) TS_InvoiceSignature_free(uint32_t this_obj) { LDKInvoiceSignature this_obj_conv; this_obj_conv.inner = (void*)(this_obj & (~1)); this_obj_conv.is_owned = (this_obj & 1) || (this_obj == 0); InvoiceSignature_free(this_obj_conv); } uint32_t __attribute__((visibility("default"))) TS_InvoiceSignature_clone(uint32_t orig) { LDKInvoiceSignature orig_conv; orig_conv.inner = (void*)(orig & (~1)); orig_conv.is_owned = false; LDKInvoiceSignature ret_var = InvoiceSignature_clone(&orig_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } jboolean __attribute__((visibility("default"))) TS_InvoiceSignature_eq(uint32_t a, uint32_t b) { LDKInvoiceSignature a_conv; a_conv.inner = (void*)(a & (~1)); a_conv.is_owned = false; LDKInvoiceSignature b_conv; b_conv.inner = (void*)(b & (~1)); b_conv.is_owned = false; jboolean ret_val = InvoiceSignature_eq(&a_conv, &b_conv); return ret_val; } void __attribute__((visibility("default"))) TS_PrivateRoute_free(uint32_t this_obj) { LDKPrivateRoute this_obj_conv; this_obj_conv.inner = (void*)(this_obj & (~1)); this_obj_conv.is_owned = (this_obj & 1) || (this_obj == 0); PrivateRoute_free(this_obj_conv); } uint32_t __attribute__((visibility("default"))) TS_PrivateRoute_clone(uint32_t orig) { LDKPrivateRoute orig_conv; orig_conv.inner = (void*)(orig & (~1)); orig_conv.is_owned = false; LDKPrivateRoute ret_var = PrivateRoute_clone(&orig_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } int64_t __attribute__((visibility("default"))) TS_PrivateRoute_hash(uint32_t o) { LDKPrivateRoute o_conv; o_conv.inner = (void*)(o & (~1)); o_conv.is_owned = false; int64_t ret_val = PrivateRoute_hash(&o_conv); return ret_val; } jboolean __attribute__((visibility("default"))) TS_PrivateRoute_eq(uint32_t a, uint32_t b) { LDKPrivateRoute a_conv; a_conv.inner = (void*)(a & (~1)); a_conv.is_owned = false; LDKPrivateRoute b_conv; b_conv.inner = (void*)(b & (~1)); b_conv.is_owned = false; jboolean ret_val = PrivateRoute_eq(&a_conv, &b_conv); return ret_val; } uint32_t __attribute__((visibility("default"))) TS_SignedRawInvoice_into_parts(uint32_t this_arg) { LDKSignedRawInvoice this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = (this_arg & 1) || (this_arg == 0); this_arg_conv = SignedRawInvoice_clone(&this_arg_conv); LDKC3Tuple_RawInvoice_u832InvoiceSignatureZ* ret_ref = MALLOC(sizeof(LDKC3Tuple_RawInvoice_u832InvoiceSignatureZ), "LDKC3Tuple_RawInvoice_u832InvoiceSignatureZ"); *ret_ref = SignedRawInvoice_into_parts(this_arg_conv); return (uint64_t)ret_ref; } uint32_t __attribute__((visibility("default"))) TS_SignedRawInvoice_raw_invoice(uint32_t this_arg) { LDKSignedRawInvoice this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; LDKRawInvoice ret_var = SignedRawInvoice_raw_invoice(&this_arg_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } int8_tArray __attribute__((visibility("default"))) TS_SignedRawInvoice_hash(uint32_t this_arg) { LDKSignedRawInvoice this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; int8_tArray ret_arr = init_arr(32, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), *SignedRawInvoice_hash(&this_arg_conv), 32); return ret_arr; } uint32_t __attribute__((visibility("default"))) TS_SignedRawInvoice_signature(uint32_t this_arg) { LDKSignedRawInvoice this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; LDKInvoiceSignature ret_var = SignedRawInvoice_signature(&this_arg_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_SignedRawInvoice_recover_payee_pub_key(uint32_t this_arg) { LDKSignedRawInvoice this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; LDKCResult_PayeePubKeyErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_PayeePubKeyErrorZ), "LDKCResult_PayeePubKeyErrorZ"); *ret_conv = SignedRawInvoice_recover_payee_pub_key(&this_arg_conv); return (uint64_t)ret_conv; } jboolean __attribute__((visibility("default"))) TS_SignedRawInvoice_check_signature(uint32_t this_arg) { LDKSignedRawInvoice this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; jboolean ret_val = SignedRawInvoice_check_signature(&this_arg_conv); return ret_val; } int8_tArray __attribute__((visibility("default"))) TS_RawInvoice_hash(uint32_t this_arg) { LDKRawInvoice this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; int8_tArray ret_arr = init_arr(32, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), RawInvoice_hash(&this_arg_conv).data, 32); return ret_arr; } uint32_t __attribute__((visibility("default"))) TS_RawInvoice_payment_hash(uint32_t this_arg) { LDKRawInvoice this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; LDKSha256 ret_var = RawInvoice_payment_hash(&this_arg_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_RawInvoice_description(uint32_t this_arg) { LDKRawInvoice this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; LDKDescription ret_var = RawInvoice_description(&this_arg_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_RawInvoice_payee_pub_key(uint32_t this_arg) { LDKRawInvoice this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; LDKPayeePubKey ret_var = RawInvoice_payee_pub_key(&this_arg_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_RawInvoice_description_hash(uint32_t this_arg) { LDKRawInvoice this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; LDKSha256 ret_var = RawInvoice_description_hash(&this_arg_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_RawInvoice_expiry_time(uint32_t this_arg) { LDKRawInvoice this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; LDKExpiryTime ret_var = RawInvoice_expiry_time(&this_arg_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_RawInvoice_min_final_cltv_expiry(uint32_t this_arg) { LDKRawInvoice this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; LDKMinFinalCltvExpiry ret_var = RawInvoice_min_final_cltv_expiry(&this_arg_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } int8_tArray __attribute__((visibility("default"))) TS_RawInvoice_payment_secret(uint32_t this_arg) { LDKRawInvoice this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; int8_tArray ret_arr = init_arr(32, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), RawInvoice_payment_secret(&this_arg_conv).data, 32); return ret_arr; } uint32_t __attribute__((visibility("default"))) TS_RawInvoice_features(uint32_t this_arg) { LDKRawInvoice this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; LDKInvoiceFeatures ret_var = RawInvoice_features(&this_arg_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } uint32_tArray __attribute__((visibility("default"))) TS_RawInvoice_private_routes(uint32_t this_arg) { LDKRawInvoice this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; LDKCVec_PrivateRouteZ ret_var = RawInvoice_private_routes(&this_arg_conv); uint32_tArray ret_arr = init_arr(ret_var.datalen, sizeof(uint32_t), "Native uint32_tArray Bytes"); uint32_t *ret_arr_ptr = (uint32_t*)(ret_arr + 4); for (size_t o = 0; o < ret_var.datalen; o++) { LDKPrivateRoute ret_conv_14_var = ret_var.data[o]; CHECK((((uint64_t)ret_conv_14_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_conv_14_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_conv_14_ref = (uint64_t)ret_conv_14_var.inner; if (ret_conv_14_var.is_owned) { ret_conv_14_ref |= 1; } ret_arr_ptr[o] = ret_conv_14_ref; } FREE(ret_var.data); return ret_arr; } uint32_t __attribute__((visibility("default"))) TS_RawInvoice_amount_pico_btc(uint32_t this_arg) { LDKRawInvoice this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; LDKCOption_u64Z *ret_copy = MALLOC(sizeof(LDKCOption_u64Z), "LDKCOption_u64Z"); *ret_copy = RawInvoice_amount_pico_btc(&this_arg_conv); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_RawInvoice_currency(uint32_t this_arg) { LDKRawInvoice this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; uint32_t ret_conv = LDKCurrency_to_js(RawInvoice_currency(&this_arg_conv)); return ret_conv; } uint32_t __attribute__((visibility("default"))) TS_PositiveTimestamp_from_unix_timestamp(int64_t unix_seconds) { LDKCResult_PositiveTimestampCreationErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_PositiveTimestampCreationErrorZ), "LDKCResult_PositiveTimestampCreationErrorZ"); *ret_conv = PositiveTimestamp_from_unix_timestamp(unix_seconds); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_PositiveTimestamp_from_system_time(int64_t time) { LDKCResult_PositiveTimestampCreationErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_PositiveTimestampCreationErrorZ), "LDKCResult_PositiveTimestampCreationErrorZ"); *ret_conv = PositiveTimestamp_from_system_time(time); return (uint64_t)ret_conv; } int64_t __attribute__((visibility("default"))) TS_PositiveTimestamp_as_unix_timestamp(uint32_t this_arg) { LDKPositiveTimestamp this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; int64_t ret_val = PositiveTimestamp_as_unix_timestamp(&this_arg_conv); return ret_val; } int64_t __attribute__((visibility("default"))) TS_PositiveTimestamp_as_time(uint32_t this_arg) { LDKPositiveTimestamp this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; int64_t ret_val = PositiveTimestamp_as_time(&this_arg_conv); return ret_val; } uint32_t __attribute__((visibility("default"))) TS_Invoice_into_signed_raw(uint32_t this_arg) { LDKInvoice this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = (this_arg & 1) || (this_arg == 0); this_arg_conv = Invoice_clone(&this_arg_conv); LDKSignedRawInvoice ret_var = Invoice_into_signed_raw(this_arg_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_Invoice_check_signature(uint32_t this_arg) { LDKInvoice this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; LDKCResult_NoneSemanticErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_NoneSemanticErrorZ), "LDKCResult_NoneSemanticErrorZ"); *ret_conv = Invoice_check_signature(&this_arg_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_Invoice_from_signed(uint32_t signed_invoice) { LDKSignedRawInvoice signed_invoice_conv; signed_invoice_conv.inner = (void*)(signed_invoice & (~1)); signed_invoice_conv.is_owned = (signed_invoice & 1) || (signed_invoice == 0); signed_invoice_conv = SignedRawInvoice_clone(&signed_invoice_conv); LDKCResult_InvoiceSemanticErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_InvoiceSemanticErrorZ), "LDKCResult_InvoiceSemanticErrorZ"); *ret_conv = Invoice_from_signed(signed_invoice_conv); return (uint64_t)ret_conv; } int64_t __attribute__((visibility("default"))) TS_Invoice_timestamp(uint32_t this_arg) { LDKInvoice this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; int64_t ret_val = Invoice_timestamp(&this_arg_conv); return ret_val; } int8_tArray __attribute__((visibility("default"))) TS_Invoice_payment_hash(uint32_t this_arg) { LDKInvoice this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; int8_tArray ret_arr = init_arr(32, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), *Invoice_payment_hash(&this_arg_conv), 32); return ret_arr; } int8_tArray __attribute__((visibility("default"))) TS_Invoice_payee_pub_key(uint32_t this_arg) { LDKInvoice this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; int8_tArray ret_arr = init_arr(33, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), Invoice_payee_pub_key(&this_arg_conv).compressed_form, 33); return ret_arr; } int8_tArray __attribute__((visibility("default"))) TS_Invoice_payment_secret(uint32_t this_arg) { LDKInvoice this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; int8_tArray ret_arr = init_arr(32, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), Invoice_payment_secret(&this_arg_conv).data, 32); return ret_arr; } uint32_t __attribute__((visibility("default"))) TS_Invoice_features(uint32_t this_arg) { LDKInvoice this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; LDKInvoiceFeatures ret_var = Invoice_features(&this_arg_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } int8_tArray __attribute__((visibility("default"))) TS_Invoice_recover_payee_pub_key(uint32_t this_arg) { LDKInvoice this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; int8_tArray ret_arr = init_arr(33, sizeof(uint8_t), "Native int8_tArray Bytes"); memcpy((uint8_t*)(ret_arr + 4), Invoice_recover_payee_pub_key(&this_arg_conv).compressed_form, 33); return ret_arr; } int64_t __attribute__((visibility("default"))) TS_Invoice_expiry_time(uint32_t this_arg) { LDKInvoice this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; int64_t ret_val = Invoice_expiry_time(&this_arg_conv); return ret_val; } int64_t __attribute__((visibility("default"))) TS_Invoice_min_final_cltv_expiry(uint32_t this_arg) { LDKInvoice this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; int64_t ret_val = Invoice_min_final_cltv_expiry(&this_arg_conv); return ret_val; } uint32_tArray __attribute__((visibility("default"))) TS_Invoice_private_routes(uint32_t this_arg) { LDKInvoice this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; LDKCVec_PrivateRouteZ ret_var = Invoice_private_routes(&this_arg_conv); uint32_tArray ret_arr = init_arr(ret_var.datalen, sizeof(uint32_t), "Native uint32_tArray Bytes"); uint32_t *ret_arr_ptr = (uint32_t*)(ret_arr + 4); for (size_t o = 0; o < ret_var.datalen; o++) { LDKPrivateRoute ret_conv_14_var = ret_var.data[o]; CHECK((((uint64_t)ret_conv_14_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_conv_14_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_conv_14_ref = (uint64_t)ret_conv_14_var.inner; if (ret_conv_14_var.is_owned) { ret_conv_14_ref |= 1; } ret_arr_ptr[o] = ret_conv_14_ref; } FREE(ret_var.data); return ret_arr; } uint32_tArray __attribute__((visibility("default"))) TS_Invoice_route_hints(uint32_t this_arg) { LDKInvoice this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; LDKCVec_RouteHintZ ret_var = Invoice_route_hints(&this_arg_conv); uint32_tArray ret_arr = init_arr(ret_var.datalen, sizeof(uint32_t), "Native uint32_tArray Bytes"); uint32_t *ret_arr_ptr = (uint32_t*)(ret_arr + 4); for (size_t l = 0; l < ret_var.datalen; l++) { LDKRouteHint ret_conv_11_var = ret_var.data[l]; CHECK((((uint64_t)ret_conv_11_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_conv_11_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_conv_11_ref = (uint64_t)ret_conv_11_var.inner; if (ret_conv_11_var.is_owned) { ret_conv_11_ref |= 1; } ret_arr_ptr[l] = ret_conv_11_ref; } FREE(ret_var.data); return ret_arr; } uint32_t __attribute__((visibility("default"))) TS_Invoice_currency(uint32_t this_arg) { LDKInvoice this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; uint32_t ret_conv = LDKCurrency_to_js(Invoice_currency(&this_arg_conv)); return ret_conv; } uint32_t __attribute__((visibility("default"))) TS_Invoice_amount_pico_btc(uint32_t this_arg) { LDKInvoice this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; LDKCOption_u64Z *ret_copy = MALLOC(sizeof(LDKCOption_u64Z), "LDKCOption_u64Z"); *ret_copy = Invoice_amount_pico_btc(&this_arg_conv); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_Description_new(jstring description) { LDKStr description_conv = str_ref_to_owned_c(description); LDKCResult_DescriptionCreationErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_DescriptionCreationErrorZ), "LDKCResult_DescriptionCreationErrorZ"); *ret_conv = Description_new(description_conv); return (uint64_t)ret_conv; } jstring __attribute__((visibility("default"))) TS_Description_into_inner(uint32_t this_arg) { LDKDescription this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = (this_arg & 1) || (this_arg == 0); this_arg_conv = Description_clone(&this_arg_conv); LDKStr ret_str = Description_into_inner(this_arg_conv); jstring ret_conv = str_ref_to_ts(ret_str.chars, ret_str.len); Str_free(ret_str); return ret_conv; } uint32_t __attribute__((visibility("default"))) TS_ExpiryTime_from_seconds(int64_t seconds) { LDKCResult_ExpiryTimeCreationErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_ExpiryTimeCreationErrorZ), "LDKCResult_ExpiryTimeCreationErrorZ"); *ret_conv = ExpiryTime_from_seconds(seconds); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_ExpiryTime_from_duration(int64_t duration) { LDKCResult_ExpiryTimeCreationErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_ExpiryTimeCreationErrorZ), "LDKCResult_ExpiryTimeCreationErrorZ"); *ret_conv = ExpiryTime_from_duration(duration); return (uint64_t)ret_conv; } int64_t __attribute__((visibility("default"))) TS_ExpiryTime_as_seconds(uint32_t this_arg) { LDKExpiryTime this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; int64_t ret_val = ExpiryTime_as_seconds(&this_arg_conv); return ret_val; } int64_t __attribute__((visibility("default"))) TS_ExpiryTime_as_duration(uint32_t this_arg) { LDKExpiryTime this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = false; int64_t ret_val = ExpiryTime_as_duration(&this_arg_conv); return ret_val; } uint32_t __attribute__((visibility("default"))) TS_PrivateRoute_new(uint32_t hops) { LDKRouteHint hops_conv; hops_conv.inner = (void*)(hops & (~1)); hops_conv.is_owned = (hops & 1) || (hops == 0); hops_conv = RouteHint_clone(&hops_conv); LDKCResult_PrivateRouteCreationErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_PrivateRouteCreationErrorZ), "LDKCResult_PrivateRouteCreationErrorZ"); *ret_conv = PrivateRoute_new(hops_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_PrivateRoute_into_inner(uint32_t this_arg) { LDKPrivateRoute this_arg_conv; this_arg_conv.inner = (void*)(this_arg & (~1)); this_arg_conv.is_owned = (this_arg & 1) || (this_arg == 0); this_arg_conv = PrivateRoute_clone(&this_arg_conv); LDKRouteHint ret_var = PrivateRoute_into_inner(this_arg_conv); CHECK((((uint64_t)ret_var.inner) & 1) == 0); // We rely on a free low bit, malloc guarantees this. CHECK((((uint64_t)&ret_var) & 1) == 0); // We rely on a free low bit, pointer alignment guarantees this. uint64_t ret_ref = (uint64_t)ret_var.inner; if (ret_var.is_owned) { ret_ref |= 1; } return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_CreationError_clone(uint32_t orig) { LDKCreationError* orig_conv = (LDKCreationError*)(orig & ~1); uint32_t ret_conv = LDKCreationError_to_js(CreationError_clone(orig_conv)); return ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CreationError_description_too_long() { uint32_t ret_conv = LDKCreationError_to_js(CreationError_description_too_long()); return ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CreationError_route_too_long() { uint32_t ret_conv = LDKCreationError_to_js(CreationError_route_too_long()); return ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CreationError_timestamp_out_of_bounds() { uint32_t ret_conv = LDKCreationError_to_js(CreationError_timestamp_out_of_bounds()); return ret_conv; } uint32_t __attribute__((visibility("default"))) TS_CreationError_expiry_time_out_of_bounds() { uint32_t ret_conv = LDKCreationError_to_js(CreationError_expiry_time_out_of_bounds()); return ret_conv; } jboolean __attribute__((visibility("default"))) TS_CreationError_eq(uint32_t a, uint32_t b) { LDKCreationError* a_conv = (LDKCreationError*)(a & ~1); LDKCreationError* b_conv = (LDKCreationError*)(b & ~1); jboolean ret_val = CreationError_eq(a_conv, b_conv); return ret_val; } jstring __attribute__((visibility("default"))) TS_CreationError_to_str(uint32_t o) { LDKCreationError* o_conv = (LDKCreationError*)(o & ~1); LDKStr ret_str = CreationError_to_str(o_conv); jstring ret_conv = str_ref_to_ts(ret_str.chars, ret_str.len); Str_free(ret_str); return ret_conv; } uint32_t __attribute__((visibility("default"))) TS_SemanticError_clone(uint32_t orig) { LDKSemanticError* orig_conv = (LDKSemanticError*)(orig & ~1); uint32_t ret_conv = LDKSemanticError_to_js(SemanticError_clone(orig_conv)); return ret_conv; } uint32_t __attribute__((visibility("default"))) TS_SemanticError_no_payment_hash() { uint32_t ret_conv = LDKSemanticError_to_js(SemanticError_no_payment_hash()); return ret_conv; } uint32_t __attribute__((visibility("default"))) TS_SemanticError_multiple_payment_hashes() { uint32_t ret_conv = LDKSemanticError_to_js(SemanticError_multiple_payment_hashes()); return ret_conv; } uint32_t __attribute__((visibility("default"))) TS_SemanticError_no_description() { uint32_t ret_conv = LDKSemanticError_to_js(SemanticError_no_description()); return ret_conv; } uint32_t __attribute__((visibility("default"))) TS_SemanticError_multiple_descriptions() { uint32_t ret_conv = LDKSemanticError_to_js(SemanticError_multiple_descriptions()); return ret_conv; } uint32_t __attribute__((visibility("default"))) TS_SemanticError_no_payment_secret() { uint32_t ret_conv = LDKSemanticError_to_js(SemanticError_no_payment_secret()); return ret_conv; } uint32_t __attribute__((visibility("default"))) TS_SemanticError_multiple_payment_secrets() { uint32_t ret_conv = LDKSemanticError_to_js(SemanticError_multiple_payment_secrets()); return ret_conv; } uint32_t __attribute__((visibility("default"))) TS_SemanticError_invalid_features() { uint32_t ret_conv = LDKSemanticError_to_js(SemanticError_invalid_features()); return ret_conv; } uint32_t __attribute__((visibility("default"))) TS_SemanticError_invalid_recovery_id() { uint32_t ret_conv = LDKSemanticError_to_js(SemanticError_invalid_recovery_id()); return ret_conv; } uint32_t __attribute__((visibility("default"))) TS_SemanticError_invalid_signature() { uint32_t ret_conv = LDKSemanticError_to_js(SemanticError_invalid_signature()); return ret_conv; } uint32_t __attribute__((visibility("default"))) TS_SemanticError_imprecise_amount() { uint32_t ret_conv = LDKSemanticError_to_js(SemanticError_imprecise_amount()); return ret_conv; } jboolean __attribute__((visibility("default"))) TS_SemanticError_eq(uint32_t a, uint32_t b) { LDKSemanticError* a_conv = (LDKSemanticError*)(a & ~1); LDKSemanticError* b_conv = (LDKSemanticError*)(b & ~1); jboolean ret_val = SemanticError_eq(a_conv, b_conv); return ret_val; } jstring __attribute__((visibility("default"))) TS_SemanticError_to_str(uint32_t o) { LDKSemanticError* o_conv = (LDKSemanticError*)(o & ~1); LDKStr ret_str = SemanticError_to_str(o_conv); jstring ret_conv = str_ref_to_ts(ret_str.chars, ret_str.len); Str_free(ret_str); return ret_conv; } void __attribute__((visibility("default"))) TS_SignOrCreationError_free(uint32_t this_ptr) { if ((this_ptr & 1) != 0) return; LDKSignOrCreationError this_ptr_conv = *(LDKSignOrCreationError*)(((uint64_t)this_ptr) & ~1); FREE((void*)this_ptr); SignOrCreationError_free(this_ptr_conv); } uint32_t __attribute__((visibility("default"))) TS_SignOrCreationError_clone(uint32_t orig) { LDKSignOrCreationError* orig_conv = (LDKSignOrCreationError*)orig; LDKSignOrCreationError *ret_copy = MALLOC(sizeof(LDKSignOrCreationError), "LDKSignOrCreationError"); *ret_copy = SignOrCreationError_clone(orig_conv); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_SignOrCreationError_sign_error() { LDKSignOrCreationError *ret_copy = MALLOC(sizeof(LDKSignOrCreationError), "LDKSignOrCreationError"); *ret_copy = SignOrCreationError_sign_error(); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } uint32_t __attribute__((visibility("default"))) TS_SignOrCreationError_creation_error(uint32_t a) { LDKCreationError a_conv = LDKCreationError_from_js(a); LDKSignOrCreationError *ret_copy = MALLOC(sizeof(LDKSignOrCreationError), "LDKSignOrCreationError"); *ret_copy = SignOrCreationError_creation_error(a_conv); uint64_t ret_ref = (uint64_t)ret_copy; return ret_ref; } jboolean __attribute__((visibility("default"))) TS_SignOrCreationError_eq(uint32_t a, uint32_t b) { LDKSignOrCreationError* a_conv = (LDKSignOrCreationError*)a; LDKSignOrCreationError* b_conv = (LDKSignOrCreationError*)b; jboolean ret_val = SignOrCreationError_eq(a_conv, b_conv); return ret_val; } jstring __attribute__((visibility("default"))) TS_SignOrCreationError_to_str(uint32_t o) { LDKSignOrCreationError* o_conv = (LDKSignOrCreationError*)o; LDKStr ret_str = SignOrCreationError_to_str(o_conv); jstring ret_conv = str_ref_to_ts(ret_str.chars, ret_str.len); Str_free(ret_str); return ret_conv; } uint32_t __attribute__((visibility("default"))) TS_create_invoice_from_channelmanager(uint32_t channelmanager, uint32_t keys_manager, uint32_t network, uint32_t amt_msat, jstring description) { LDKChannelManager channelmanager_conv; channelmanager_conv.inner = (void*)(channelmanager & (~1)); channelmanager_conv.is_owned = false; LDKKeysInterface keys_manager_conv = *(LDKKeysInterface*)(((uint64_t)keys_manager) & ~1); LDKCurrency network_conv = LDKCurrency_from_js(network); LDKCOption_u64Z amt_msat_conv = *(LDKCOption_u64Z*)(((uint64_t)amt_msat) & ~1); amt_msat_conv = COption_u64Z_clone((LDKCOption_u64Z*)(((uint64_t)amt_msat) & ~1)); LDKStr description_conv = str_ref_to_owned_c(description); LDKCResult_InvoiceSignOrCreationErrorZ* ret_conv = MALLOC(sizeof(LDKCResult_InvoiceSignOrCreationErrorZ), "LDKCResult_InvoiceSignOrCreationErrorZ"); *ret_conv = create_invoice_from_channelmanager(&channelmanager_conv, keys_manager_conv, network_conv, amt_msat_conv, description_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_SiPrefix_from_str(jstring s) { LDKStr s_conv = str_ref_to_owned_c(s); LDKCResult_SiPrefixNoneZ* ret_conv = MALLOC(sizeof(LDKCResult_SiPrefixNoneZ), "LDKCResult_SiPrefixNoneZ"); *ret_conv = SiPrefix_from_str(s_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_Invoice_from_str(jstring s) { LDKStr s_conv = str_ref_to_owned_c(s); LDKCResult_InvoiceNoneZ* ret_conv = MALLOC(sizeof(LDKCResult_InvoiceNoneZ), "LDKCResult_InvoiceNoneZ"); *ret_conv = Invoice_from_str(s_conv); return (uint64_t)ret_conv; } uint32_t __attribute__((visibility("default"))) TS_SignedRawInvoice_from_str(jstring s) { LDKStr s_conv = str_ref_to_owned_c(s); LDKCResult_SignedRawInvoiceNoneZ* ret_conv = MALLOC(sizeof(LDKCResult_SignedRawInvoiceNoneZ), "LDKCResult_SignedRawInvoiceNoneZ"); *ret_conv = SignedRawInvoice_from_str(s_conv); return (uint64_t)ret_conv; } jstring __attribute__((visibility("default"))) TS_Invoice_to_str(uint32_t o) { LDKInvoice o_conv; o_conv.inner = (void*)(o & (~1)); o_conv.is_owned = false; LDKStr ret_str = Invoice_to_str(&o_conv); jstring ret_conv = str_ref_to_ts(ret_str.chars, ret_str.len); Str_free(ret_str); return ret_conv; } jstring __attribute__((visibility("default"))) TS_SignedRawInvoice_to_str(uint32_t o) { LDKSignedRawInvoice o_conv; o_conv.inner = (void*)(o & (~1)); o_conv.is_owned = false; LDKStr ret_str = SignedRawInvoice_to_str(&o_conv); jstring ret_conv = str_ref_to_ts(ret_str.chars, ret_str.len); Str_free(ret_str); return ret_conv; } jstring __attribute__((visibility("default"))) TS_Currency_to_str(uint32_t o) { LDKCurrency* o_conv = (LDKCurrency*)(o & ~1); LDKStr ret_str = Currency_to_str(o_conv); jstring ret_conv = str_ref_to_ts(ret_str.chars, ret_str.len); Str_free(ret_str); return ret_conv; } jstring __attribute__((visibility("default"))) TS_SiPrefix_to_str(uint32_t o) { LDKSiPrefix* o_conv = (LDKSiPrefix*)(o & ~1); LDKStr ret_str = SiPrefix_to_str(o_conv); jstring ret_conv = str_ref_to_ts(ret_str.chars, ret_str.len); Str_free(ret_str); return ret_conv; }