use bitcoin::secp256k1::key::SecretKey as SecpSecretKey;
use bitcoin::secp256k1::Signature as SecpSignature;
use bitcoin::secp256k1::Error as SecpError;
+use bitcoin::secp256k1::recovery::RecoveryId;
+use bitcoin::secp256k1::recovery::RecoverableSignature as SecpRecoverableSignature;
use bitcoin::bech32;
-use std::convert::TryInto; // Bindings need at least rustc 1.34
+use core::convert::TryInto; // Bindings need at least rustc 1.34
+use core::ffi::c_void;
+
+#[cfg(feature = "std")]
+pub(crate) use std::io::{self, Cursor, Read};
+#[cfg(feature = "no-std")]
+pub(crate) use core2::io::{self, Cursor, Read};
+#[cfg(feature = "no-std")]
+use alloc::{boxed::Box, vec::Vec, string::String};
+
+#[repr(C)]
+/// A dummy struct of which an instance must never exist.
+/// This corresponds to the Rust type `Infallible`, or, in unstable rust, `!`
+pub struct NotConstructable {
+ _priv_thing: core::convert::Infallible,
+}
+impl From<core::convert::Infallible> for NotConstructable {
+ fn from(_: core::convert::Infallible) -> Self { unreachable!(); }
+}
/// Integer in the range `0..32`
#[derive(PartialEq, Eq, Copy, Clone)]
}
#[repr(C)]
+#[derive(Clone)]
/// Represents a valid secp256k1 secret key serialized as a 32 byte array.
pub struct SecretKey {
/// The bytes of the secret key
}
#[repr(C)]
+#[derive(Clone)]
+/// Represents a secp256k1 signature serialized as two 32-byte numbers as well as a tag which
+/// allows recovering the exact public key which created the signature given the message.
+pub struct RecoverableSignature {
+ /// The bytes of the signature in "compact" form plus a "Recovery ID" which allows for
+ /// recovery.
+ pub serialized_form: [u8; 68],
+}
+impl RecoverableSignature {
+ pub(crate) fn from_rust(pk: &SecpRecoverableSignature) -> Self {
+ let (id, compact_form) = pk.serialize_compact();
+ let mut serialized_form = [0; 68];
+ serialized_form[0..64].copy_from_slice(&compact_form[..]);
+ serialized_form[64..].copy_from_slice(&id.to_i32().to_le_bytes());
+ Self { serialized_form }
+ }
+ pub(crate) fn into_rust(&self) -> SecpRecoverableSignature {
+ let mut id = [0; 4];
+ id.copy_from_slice(&self.serialized_form[64..]);
+ SecpRecoverableSignature::from_compact(&self.serialized_form[0..64],
+ RecoveryId::from_i32(i32::from_le_bytes(id)).expect("Invalid Recovery ID"))
+ .unwrap()
+ }
+}
+
+#[repr(C)]
+#[derive(Copy, Clone)]
/// Represents an error returned from libsecp256k1 during validation of some secp256k1 data
pub enum Secp256k1Error {
/// Signature failed verification
SecpError::NotEnoughMemory => Secp256k1Error::NotEnoughMemory,
}
}
+ pub(crate) fn into_rust(self) -> SecpError {
+ match self {
+ Secp256k1Error::IncorrectSignature => SecpError::IncorrectSignature,
+ Secp256k1Error::InvalidMessage => SecpError::InvalidMessage,
+ Secp256k1Error::InvalidPublicKey => SecpError::InvalidPublicKey,
+ Secp256k1Error::InvalidSignature => SecpError::InvalidSignature,
+ Secp256k1Error::InvalidSecretKey => SecpError::InvalidSecretKey,
+ Secp256k1Error::InvalidRecoveryId => SecpError::InvalidRecoveryId,
+ Secp256k1Error::InvalidTweak => SecpError::InvalidTweak,
+ Secp256k1Error::TweakCheckFailed => SecpError::TweakCheckFailed,
+ Secp256k1Error::NotEnoughMemory => SecpError::NotEnoughMemory,
+ }
+ }
+}
+
+#[repr(C)]
+#[derive(Copy, Clone)]
+/// Represents an error returned from the bech32 library during validation of some bech32 data
+pub enum Bech32Error {
+ /// String does not contain the separator character
+ MissingSeparator,
+ /// The checksum does not match the rest of the data
+ InvalidChecksum,
+ /// The data or human-readable part is too long or too short
+ InvalidLength,
+ /// Some part of the string contains an invalid character
+ InvalidChar(u32),
+ /// Some part of the data has an invalid value
+ InvalidData(u8),
+ /// The bit conversion failed due to a padding issue
+ InvalidPadding,
+ /// The whole string must be of one case
+ MixedCase,
+}
+impl Bech32Error {
+ pub(crate) fn from_rust(err: bech32::Error) -> Self {
+ match err {
+ bech32::Error::MissingSeparator => Self::MissingSeparator,
+ bech32::Error::InvalidChecksum => Self::InvalidChecksum,
+ bech32::Error::InvalidLength => Self::InvalidLength,
+ bech32::Error::InvalidChar(c) => Self::InvalidChar(c as u32),
+ bech32::Error::InvalidData(d) => Self::InvalidData(d),
+ bech32::Error::InvalidPadding => Self::InvalidPadding,
+ bech32::Error::MixedCase => Self::MixedCase,
+ }
+ }
+ pub(crate) fn into_rust(self) -> bech32::Error {
+ match self {
+ Self::MissingSeparator => bech32::Error::MissingSeparator,
+ Self::InvalidChecksum => bech32::Error::InvalidChecksum,
+ Self::InvalidLength => bech32::Error::InvalidLength,
+ Self::InvalidChar(c) => bech32::Error::InvalidChar(core::char::from_u32(c).expect("Invalid UTF-8 character in Bech32Error::InvalidChar")),
+ Self::InvalidData(d) => bech32::Error::InvalidData(d),
+ Self::InvalidPadding => bech32::Error::InvalidPadding,
+ Self::MixedCase => bech32::Error::MixedCase,
+ }
+ }
+}
+#[no_mangle]
+/// Creates a new Bech32Error which has the same data as `orig`
+pub extern "C" fn Bech32Error_clone(orig: &Bech32Error) -> Bech32Error { orig.clone() }
+#[no_mangle]
+/// Releases any memory held by the given `Bech32Error` (which is currently none)
+pub extern "C" fn Bech32Error_free(o: Bech32Error) { }
+
+#[repr(C)]
+#[derive(Clone, Copy, PartialEq)]
+/// Sub-errors which don't have specific information in them use this type.
+pub struct Error {
+ /// Zero-Sized_types aren't consistent across Rust/C/C++, so we add some size here
+ pub _dummy: u8,
}
#[repr(C)]
#[allow(missing_docs)] // If there's no docs upstream, that's good enough for us
+#[derive(Clone, Copy, PartialEq)]
/// Represents an IO Error. Note that some information is lost in the conversion from Rust.
pub enum IOError {
NotFound,
Other,
UnexpectedEof,
}
+#[cfg(feature = "std")]
impl IOError {
pub(crate) fn from_rust(err: std::io::Error) -> Self {
match err.kind() {
_ => IOError::Other,
}
}
+ pub(crate) fn to_rust(&self) -> std::io::Error {
+ std::io::Error::new(match self {
+ IOError::NotFound => std::io::ErrorKind::NotFound,
+ IOError::PermissionDenied => std::io::ErrorKind::PermissionDenied,
+ IOError::ConnectionRefused => std::io::ErrorKind::ConnectionRefused,
+ IOError::ConnectionReset => std::io::ErrorKind::ConnectionReset,
+ IOError::ConnectionAborted => std::io::ErrorKind::ConnectionAborted,
+ IOError::NotConnected => std::io::ErrorKind::NotConnected,
+ IOError::AddrInUse => std::io::ErrorKind::AddrInUse,
+ IOError::AddrNotAvailable => std::io::ErrorKind::AddrNotAvailable,
+ IOError::BrokenPipe => std::io::ErrorKind::BrokenPipe,
+ IOError::AlreadyExists => std::io::ErrorKind::AlreadyExists,
+ IOError::WouldBlock => std::io::ErrorKind::WouldBlock,
+ IOError::InvalidInput => std::io::ErrorKind::InvalidInput,
+ IOError::InvalidData => std::io::ErrorKind::InvalidData,
+ IOError::TimedOut => std::io::ErrorKind::TimedOut,
+ IOError::WriteZero => std::io::ErrorKind::WriteZero,
+ IOError::Interrupted => std::io::ErrorKind::Interrupted,
+ IOError::Other => std::io::ErrorKind::Other,
+ IOError::UnexpectedEof => std::io::ErrorKind::UnexpectedEof,
+ }, "")
+ }
}
#[repr(C)]
pub data_is_owned: bool,
}
impl Transaction {
- pub(crate) fn into_bitcoin(&self) -> BitcoinTransaction {
- if self.datalen == 0 { panic!("0-length buffer can never represent a valid Transaction"); }
- ::bitcoin::consensus::encode::deserialize(unsafe { std::slice::from_raw_parts(self.data, self.datalen) }).unwrap()
- }
- pub(crate) fn from_bitcoin(btc: &BitcoinTransaction) -> Self {
- let vec = ::bitcoin::consensus::encode::serialize(btc);
+ fn from_vec(vec: Vec<u8>) -> Self {
let datalen = vec.len();
let data = Box::into_raw(vec.into_boxed_slice());
Self {
data_is_owned: true,
}
}
+ pub(crate) fn into_bitcoin(&self) -> BitcoinTransaction {
+ if self.datalen == 0 { panic!("0-length buffer can never represent a valid Transaction"); }
+ ::bitcoin::consensus::encode::deserialize(unsafe { core::slice::from_raw_parts(self.data, self.datalen) }).unwrap()
+ }
+ pub(crate) fn from_bitcoin(btc: &BitcoinTransaction) -> Self {
+ let vec = ::bitcoin::consensus::encode::serialize(btc);
+ Self::from_vec(vec)
+ }
}
impl Drop for Transaction {
fn drop(&mut self) {
}
}
}
+impl Clone for Transaction {
+ fn clone(&self) -> Self {
+ let sl = unsafe { core::slice::from_raw_parts(self.data, self.datalen) };
+ let mut v = Vec::new();
+ v.extend_from_slice(&sl);
+ Self::from_vec(v)
+ }
+}
#[no_mangle]
/// Frees the data buffer, if data_is_owned is set and datalen > 0.
pub extern "C" fn Transaction_free(_res: Transaction) { }
pub(crate) fn bitcoin_to_C_outpoint(outpoint: ::bitcoin::blockdata::transaction::OutPoint) -> crate::lightning::chain::transaction::OutPoint {
crate::lightning::chain::transaction::OutPoint_new(ThirtyTwoBytes { data: outpoint.txid.into_inner() }, outpoint.vout.try_into().unwrap())
}
+pub(crate) fn C_to_bitcoin_outpoint(outpoint: crate::lightning::chain::transaction::OutPoint) -> ::bitcoin::blockdata::transaction::OutPoint {
+ unsafe {
+ ::bitcoin::blockdata::transaction::OutPoint {
+ txid: (*outpoint.inner).txid, vout: (*outpoint.inner).index as u32
+ }
+ }
+}
#[repr(C)]
#[derive(Clone)]
}
}
}
+
+#[no_mangle]
+/// Convenience function for constructing a new TxOut
+pub extern "C" fn TxOut_new(script_pubkey: derived::CVec_u8Z, value: u64) -> TxOut {
+ TxOut { script_pubkey, value }
+}
#[no_mangle]
/// Frees the data pointed to by script_pubkey.
pub extern "C" fn TxOut_free(_res: TxOut) { }
}
pub(crate) fn to_slice(&self) -> &[u8] {
if self.datalen == 0 { return &[]; }
- unsafe { std::slice::from_raw_parts(self.data, self.datalen) }
+ unsafe { core::slice::from_raw_parts(self.data, self.datalen) }
+ }
+ pub(crate) fn to_reader<'a>(&'a self) -> Cursor<&'a [u8]> {
+ let sl = self.to_slice();
+ Cursor::new(sl)
}
+ pub(crate) fn from_vec(v: &derived::CVec_u8Z) -> u8slice {
+ Self::from_slice(v.as_slice())
+ }
+}
+pub(crate) fn reader_to_vec<R: Read>(r: &mut R) -> derived::CVec_u8Z {
+ let mut res = Vec::new();
+ r.read_to_end(&mut res).unwrap();
+ derived::CVec_u8Z::from(res)
}
#[repr(C)]
pub struct FourBytes { /** The four bytes */ pub data: [u8; 4], }
#[derive(Clone)]
#[repr(C)]
-/// A 10-byte byte array.
-pub struct TenBytes { /** The ten bytes */ pub data: [u8; 10], }
+/// A 12-byte byte array.
+pub struct TwelveBytes { /** The twelve bytes */ pub data: [u8; 12], }
#[derive(Clone)]
#[repr(C)]
/// A 16-byte byte array.
pub(crate) struct VecWriter(pub Vec<u8>);
impl lightning::util::ser::Writer for VecWriter {
- fn write_all(&mut self, buf: &[u8]) -> Result<(), ::std::io::Error> {
+ fn write_all(&mut self, buf: &[u8]) -> Result<(), io::Error> {
self.0.extend_from_slice(buf);
Ok(())
}
- fn size_hint(&mut self, size: usize) {
- self.0.reserve_exact(size);
- }
}
pub(crate) fn serialize_obj<I: lightning::util::ser::Writeable>(i: &I) -> derived::CVec_u8Z {
let mut out = VecWriter(Vec::new());
pub(crate) fn deserialize_obj<I: lightning::util::ser::Readable>(s: u8slice) -> Result<I, lightning::ln::msgs::DecodeError> {
I::read(&mut s.to_slice())
}
+pub(crate) fn maybe_deserialize_obj<I: lightning::util::ser::MaybeReadable>(s: u8slice) -> Result<Option<I>, lightning::ln::msgs::DecodeError> {
+ I::read(&mut s.to_slice())
+}
pub(crate) fn deserialize_obj_arg<A, I: lightning::util::ser::ReadableArgs<A>>(s: u8slice, args: A) -> Result<I, lightning::ln::msgs::DecodeError> {
I::read(&mut s.to_slice(), args)
}
#[repr(C)]
-#[derive(Clone)]
/// A Rust str object, ie a reference to a UTF8-valid string.
/// This is *not* null-terminated so cannot be used directly as a C string!
pub struct Str {
Str { chars: self.as_ptr(), len: self.len(), chars_is_owned: false }
}
}
-impl Into<&'static str> for Str {
- fn into(self) -> &'static str {
+impl Into<Str> for &mut &'static str {
+ fn into(self) -> Str {
+ let us: &'static str = *self;
+ us.into()
+ }
+}
+
+impl Str {
+ pub(crate) fn into_str(&self) -> &'static str {
if self.len == 0 { return ""; }
- std::str::from_utf8(unsafe { std::slice::from_raw_parts(self.chars, self.len) }).unwrap()
+ core::str::from_utf8(unsafe { core::slice::from_raw_parts(self.chars, self.len) }).unwrap()
+ }
+ pub(crate) fn into_string(mut self) -> String {
+ let bytes = if self.len == 0 {
+ Vec::new()
+ } else if self.chars_is_owned {
+ let ret = unsafe {
+ Box::from_raw(core::slice::from_raw_parts_mut(unsafe { self.chars as *mut u8 }, self.len))
+ }.into();
+ self.chars_is_owned = false;
+ ret
+ } else {
+ let mut ret = Vec::with_capacity(self.len);
+ ret.extend_from_slice(unsafe { core::slice::from_raw_parts(self.chars, self.len) });
+ ret
+ };
+ String::from_utf8(bytes).unwrap()
}
}
impl Into<Str> for String {
Str { chars: s.as_ptr(), len: s.len(), chars_is_owned: true }
}
}
+impl Clone for Str {
+ fn clone(&self) -> Self {
+ String::from(self.into_str()).into()
+ }
+}
impl Drop for Str {
fn drop(&mut self) {
impl<T> TakePointer<*const T> for *const T {
fn take_ptr(&mut self) -> *const T {
let ret = *self;
- *self = std::ptr::null();
+ *self = core::ptr::null();
ret
}
}
impl<T> TakePointer<*mut T> for *mut T {
fn take_ptr(&mut self) -> *mut T {
let ret = *self;
- *self = std::ptr::null_mut();
+ *self = core::ptr::null_mut();
ret
}
}
+
+
+pub(crate) mod ObjOps {
+ #[cfg(feature = "no-std")]
+ use alloc::boxed::Box;
+
+ #[inline]
+ #[must_use = "returns new dangling pointer"]
+ pub(crate) fn heap_alloc<T>(obj: T) -> *mut T {
+ let ptr = Box::into_raw(Box::new(obj));
+ nonnull_ptr_to_inner(ptr)
+ }
+ #[inline]
+ pub(crate) fn nonnull_ptr_to_inner<T>(ptr: *const T) -> *mut T {
+ if core::mem::size_of::<T>() == 0 {
+ // We map `None::<T>` as `T { inner: null, .. }` which works great for all
+ // non-Zero-Sized-Types `T`.
+ // For ZSTs, we need to differentiate between null implying `None` and null implying
+ // `Some` with no allocation.
+ // Thus, for ZSTs, we add one (usually) page here, which should always be aligned.
+ // Note that this relies on undefined behavior! A pointer to NULL may be valid, but a
+ // pointer to NULL + 4096 is almost certainly not. That said, Rust's existing use of
+ // `(*mut T)1` for the pointer we're adding to is also not defined, so we should be
+ // fine.
+ // Note that we add 4095 here as at least the Java client assumes that the low bit on
+ // any heap pointer is 0, which is generally provided by malloc, but which is not true
+ // for ZSTs "allocated" by `Box::new`.
+ debug_assert_eq!(ptr as usize, 1);
+ unsafe { (ptr as *mut T).cast::<u8>().add(4096 - 1).cast::<T>() }
+ } else {
+ // In order to get better test coverage, also increment non-ZST pointers with
+ // --cfg=test_mod_pointers, which is set in genbindings.sh for debug builds.
+ #[cfg(test_mod_pointers)]
+ unsafe { (ptr as *mut T).cast::<u8>().add(4096).cast::<T>() }
+ #[cfg(not(test_mod_pointers))]
+ unsafe { ptr as *mut T }
+ }
+ }
+ #[inline]
+ /// Invert nonnull_ptr_to_inner
+ pub(crate) fn untweak_ptr<T>(ptr: *mut T) -> *mut T {
+ if core::mem::size_of::<T>() == 0 {
+ unsafe { ptr.cast::<u8>().sub(4096 - 1).cast::<T>() }
+ } else {
+ #[cfg(test_mod_pointers)]
+ unsafe { ptr.cast::<u8>().sub(4096).cast::<T>() }
+ #[cfg(not(test_mod_pointers))]
+ ptr
+ }
+ }
+}
+
+#[cfg(test_mod_pointers)]
+#[no_mangle]
+/// This function exists for memory safety testing purposes. It should never be used in production
+/// code
+pub extern "C" fn __unmangle_inner_ptr(ptr: *const c_void) -> *const c_void {
+ if ptr as usize == 1 {
+ core::ptr::null()
+ } else {
+ unsafe { ptr.cast::<u8>().sub(4096).cast::<c_void>() }
+ }
+}
+
+pub(crate) struct SmartPtr<T> {
+ ptr: *mut T,
+}
+impl<T> SmartPtr<T> {
+ pub(crate) fn from_obj(o: T) -> Self {
+ Self { ptr: Box::into_raw(Box::new(o)) }
+ }
+ pub(crate) fn null() -> Self {
+ Self { ptr: core::ptr::null_mut() }
+ }
+}
+impl<T> Drop for SmartPtr<T> {
+ fn drop(&mut self) {
+ if self.ptr != core::ptr::null_mut() {
+ unsafe { Box::from_raw(self.ptr); }
+ }
+ }
+}
+impl<T> core::ops::Deref for SmartPtr<T> {
+ type Target = *mut T;
+ fn deref(&self) -> &*mut T {
+ &self.ptr
+ }
+}