//! spendable on-chain outputs which the user owns and is responsible for using just as any other
//! on-chain output which is theirs.
-use bitcoin::blockdata::transaction::{Transaction, TxOut, TxIn, SigHashType};
+use bitcoin::blockdata::transaction::{Transaction, TxOut, TxIn, EcdsaSighashType};
use bitcoin::blockdata::script::{Script, Builder};
use bitcoin::blockdata::opcodes;
use bitcoin::network::constants::Network;
use bitcoin::util::bip32::{ExtendedPrivKey, ExtendedPubKey, ChildNumber};
-use bitcoin::util::bip143;
+use bitcoin::util::sighash;
use bitcoin::bech32::u5;
use bitcoin::hashes::{Hash, HashEngine};
use bitcoin::hashes::sha256d::Hash as Sha256dHash;
use bitcoin::hash_types::WPubkeyHash;
-use bitcoin::secp256k1::key::{SecretKey, PublicKey};
-use bitcoin::secp256k1::{Secp256k1, Signature, Signing};
-use bitcoin::secp256k1::recovery::RecoverableSignature;
-use bitcoin::secp256k1;
+use bitcoin::secp256k1::{SecretKey, PublicKey, Scalar};
+use bitcoin::secp256k1::{Secp256k1, ecdsa::Signature, Signing};
+use bitcoin::secp256k1::ecdh::SharedSecret;
+use bitcoin::secp256k1::ecdsa::RecoverableSignature;
+use bitcoin::{PackedLockTime, secp256k1, Sequence, Witness};
-use util::{byte_utils, transaction_utils};
-use util::crypto::hkdf_extract_expand_twice;
-use util::ser::{Writeable, Writer, Readable, ReadableArgs};
+use crate::util::{byte_utils, transaction_utils};
+use crate::util::crypto::{hkdf_extract_expand_twice, sign};
+use crate::util::ser::{Writeable, Writer, Readable, ReadableArgs};
-use chain::transaction::OutPoint;
-use ln::{chan_utils, PaymentPreimage};
-use ln::chan_utils::{HTLCOutputInCommitment, make_funding_redeemscript, ChannelPublicKeys, HolderCommitmentTransaction, ChannelTransactionParameters, CommitmentTransaction, ClosingTransaction};
-use ln::msgs::UnsignedChannelAnnouncement;
-use ln::script::ShutdownScript;
+use crate::chain::transaction::OutPoint;
+use crate::ln::channel::ANCHOR_OUTPUT_VALUE_SATOSHI;
+use crate::ln::{chan_utils, PaymentPreimage};
+use crate::ln::chan_utils::{HTLCOutputInCommitment, make_funding_redeemscript, ChannelPublicKeys, HolderCommitmentTransaction, ChannelTransactionParameters, CommitmentTransaction, ClosingTransaction};
+use crate::ln::msgs::UnsignedChannelAnnouncement;
+use crate::ln::script::ShutdownScript;
-use prelude::*;
+use crate::prelude::*;
use core::sync::atomic::{AtomicUsize, Ordering};
-use io::{self, Error};
-use ln::msgs::{DecodeError, MAX_VALUE_MSAT};
-use util::invoice::construct_invoice_preimage;
+use crate::io::{self, Error};
+use crate::ln::msgs::{DecodeError, MAX_VALUE_MSAT};
+use crate::util::invoice::construct_invoice_preimage;
/// Used as initial key material, to be expanded into multiple secret keys (but not to be used
/// directly). This is used within LDK to encrypt/decrypt inbound payment data.
/// Information about a spendable output to a P2WSH script. See
/// SpendableOutputDescriptor::DelayedPaymentOutput for more details on how to spend this.
-#[derive(Clone, Debug, PartialEq)]
+#[derive(Clone, Debug, PartialEq, Eq)]
pub struct DelayedPaymentOutputDescriptor {
/// The outpoint which is spendable
pub outpoint: OutPoint,
/// Information about a spendable output to our "payment key". See
/// SpendableOutputDescriptor::StaticPaymentOutput for more details on how to spend this.
-#[derive(Clone, Debug, PartialEq)]
+#[derive(Clone, Debug, PartialEq, Eq)]
pub struct StaticPaymentOutputDescriptor {
/// The outpoint which is spendable
pub outpoint: OutPoint,
/// spend on-chain. The information needed to do this is provided in this enum, including the
/// outpoint describing which txid and output index is available, the full output which exists at
/// that txid/index, and any keys or other information required to sign.
-#[derive(Clone, Debug, PartialEq)]
+#[derive(Clone, Debug, PartialEq, Eq)]
pub enum SpendableOutputDescriptor {
/// An output to a script which was provided via KeysInterface directly, either from
/// `get_destination_script()` or `get_shutdown_scriptpubkey()`, thus you should already know
/// chosen to forgo their output as dust.
fn sign_closing_transaction(&self, closing_tx: &ClosingTransaction, secp_ctx: &Secp256k1<secp256k1::All>) -> Result<Signature, ()>;
+ /// Computes the signature for a commitment transaction's anchor output used as an
+ /// input within `anchor_tx`, which spends the commitment transaction, at index `input`.
+ fn sign_holder_anchor_input(
+ &self, anchor_tx: &Transaction, input: usize, secp_ctx: &Secp256k1<secp256k1::All>,
+ ) -> Result<Signature, ()>;
+
/// Signs a channel announcement message with our funding key and our node secret key (aka
/// node_id or network_key), proving it comes from one of the channel participants.
///
/// A type which implements Sign which will be returned by get_channel_signer.
type Signer : Sign;
- /// Get node secret key (aka node_id or network_key) based on the provided [`Recipient`].
+ /// Get node secret key based on the provided [`Recipient`].
+ ///
+ /// The node_id/network_key is the public key that corresponds to this secret key.
///
/// This method must return the same value each time it is called with a given `Recipient`
/// parameter.
+ ///
+ /// Errors if the `Recipient` variant is not supported by the implementation.
fn get_node_secret(&self, recipient: Recipient) -> Result<SecretKey, ()>;
+ /// Get node id based on the provided [`Recipient`]. This public key corresponds to the secret in
+ /// [`get_node_secret`].
+ ///
+ /// This method must return the same value each time it is called with a given `Recipient`
+ /// parameter.
+ ///
+ /// Errors if the `Recipient` variant is not supported by the implementation.
+ ///
+ /// [`get_node_secret`]: KeysInterface::get_node_secret
+ fn get_node_id(&self, recipient: Recipient) -> Result<PublicKey, ()> {
+ let secp_ctx = Secp256k1::signing_only();
+ Ok(PublicKey::from_secret_key(&secp_ctx, &self.get_node_secret(recipient)?))
+ }
+ /// Gets the ECDH shared secret of our [`node secret`] and `other_key`, multiplying by `tweak` if
+ /// one is provided. Note that this tweak can be applied to `other_key` instead of our node
+ /// secret, though this is less efficient.
+ ///
+ /// Errors if the `Recipient` variant is not supported by the implementation.
+ ///
+ /// [`node secret`]: Self::get_node_secret
+ fn ecdh(&self, recipient: Recipient, other_key: &PublicKey, tweak: Option<&Scalar>) -> Result<SharedSecret, ()>;
/// Get a script pubkey which we send funds to when claiming on-chain contestable outputs.
///
/// This method should return a different value each time it is called, to avoid linking
/// The hrp is ascii bytes, while the invoice data is base32.
///
/// The secret key used to sign the invoice is dependent on the [`Recipient`].
+ ///
+ /// Errors if the `Recipient` variant is not supported by the implementation.
fn sign_invoice(&self, hrp_bytes: &[u8], invoice_data: &[u5], receipient: Recipient) -> Result<RecoverableSignature, ()>;
/// Get secret key material as bytes for use in encrypting and decrypting inbound payment data.
htlc_base_key: SecretKey,
commitment_seed: [u8; 32],
channel_value_satoshis: u64,
- channel_keys_id: [u8; 32]) -> InMemorySigner {
+ channel_keys_id: [u8; 32],
+ ) -> InMemorySigner {
let holder_channel_pubkeys =
InMemorySigner::make_holder_keys(secp_ctx, &funding_key, &revocation_base_key,
&payment_key, &delayed_payment_base_key,
if spend_tx.input[input_idx].previous_output != descriptor.outpoint.into_bitcoin_outpoint() { return Err(()); }
let remotepubkey = self.pubkeys().payment_point;
- let witness_script = bitcoin::Address::p2pkh(&::bitcoin::PublicKey{compressed: true, key: remotepubkey}, Network::Testnet).script_pubkey();
- let sighash = hash_to_message!(&bip143::SigHashCache::new(spend_tx).signature_hash(input_idx, &witness_script, descriptor.output.value, SigHashType::All)[..]);
- let remotesig = secp_ctx.sign(&sighash, &self.payment_key);
- let payment_script = bitcoin::Address::p2wpkh(&::bitcoin::PublicKey{compressed: true, key: remotepubkey}, Network::Bitcoin).unwrap().script_pubkey();
+ let witness_script = bitcoin::Address::p2pkh(&::bitcoin::PublicKey{compressed: true, inner: remotepubkey}, Network::Testnet).script_pubkey();
+ let sighash = hash_to_message!(&sighash::SighashCache::new(spend_tx).segwit_signature_hash(input_idx, &witness_script, descriptor.output.value, EcdsaSighashType::All).unwrap()[..]);
+ let remotesig = sign(secp_ctx, &sighash, &self.payment_key);
+ let payment_script = bitcoin::Address::p2wpkh(&::bitcoin::PublicKey{compressed: true, inner: remotepubkey}, Network::Bitcoin).unwrap().script_pubkey();
if payment_script != descriptor.output.script_pubkey { return Err(()); }
let mut witness = Vec::with_capacity(2);
witness.push(remotesig.serialize_der().to_vec());
- witness[0].push(SigHashType::All as u8);
+ witness[0].push(EcdsaSighashType::All as u8);
witness.push(remotepubkey.serialize().to_vec());
Ok(witness)
}
if spend_tx.input.len() <= input_idx { return Err(()); }
if !spend_tx.input[input_idx].script_sig.is_empty() { return Err(()); }
if spend_tx.input[input_idx].previous_output != descriptor.outpoint.into_bitcoin_outpoint() { return Err(()); }
- if spend_tx.input[input_idx].sequence != descriptor.to_self_delay as u32 { return Err(()); }
+ if spend_tx.input[input_idx].sequence.0 != descriptor.to_self_delay as u32 { return Err(()); }
let delayed_payment_key = chan_utils::derive_private_key(&secp_ctx, &descriptor.per_commitment_point, &self.delayed_payment_base_key)
.expect("We constructed the payment_base_key, so we can only fail here if the RNG is busted.");
let delayed_payment_pubkey = PublicKey::from_secret_key(&secp_ctx, &delayed_payment_key);
let witness_script = chan_utils::get_revokeable_redeemscript(&descriptor.revocation_pubkey, descriptor.to_self_delay, &delayed_payment_pubkey);
- let sighash = hash_to_message!(&bip143::SigHashCache::new(spend_tx).signature_hash(input_idx, &witness_script, descriptor.output.value, SigHashType::All)[..]);
- let local_delayedsig = secp_ctx.sign(&sighash, &delayed_payment_key);
+ let sighash = hash_to_message!(&sighash::SighashCache::new(spend_tx).segwit_signature_hash(input_idx, &witness_script, descriptor.output.value, EcdsaSighashType::All).unwrap()[..]);
+ let local_delayedsig = sign(secp_ctx, &sighash, &delayed_payment_key);
let payment_script = bitcoin::Address::p2wsh(&witness_script, Network::Bitcoin).script_pubkey();
if descriptor.output.script_pubkey != payment_script { return Err(()); }
let mut witness = Vec::with_capacity(3);
witness.push(local_delayedsig.serialize_der().to_vec());
- witness[0].push(SigHashType::All as u8);
+ witness[0].push(EcdsaSighashType::All as u8);
witness.push(vec!()); //MINIMALIF
witness.push(witness_script.clone().into_bytes());
Ok(witness)
}
+
}
impl BaseSign for InMemorySigner {
let mut htlc_sigs = Vec::with_capacity(commitment_tx.htlcs().len());
for htlc in commitment_tx.htlcs() {
- let htlc_tx = chan_utils::build_htlc_transaction(&commitment_txid, commitment_tx.feerate_per_kw(), self.holder_selected_contest_delay(), htlc, self.opt_anchors(), &keys.broadcaster_delayed_payment_key, &keys.revocation_key);
+ let channel_parameters = self.get_channel_parameters();
+ let htlc_tx = chan_utils::build_htlc_transaction(&commitment_txid, commitment_tx.feerate_per_kw(), self.holder_selected_contest_delay(), htlc, self.opt_anchors(), channel_parameters.opt_non_zero_fee_anchors.is_some(), &keys.broadcaster_delayed_payment_key, &keys.revocation_key);
let htlc_redeemscript = chan_utils::get_htlc_redeemscript(&htlc, self.opt_anchors(), &keys);
- let htlc_sighashtype = if self.opt_anchors() { SigHashType::SinglePlusAnyoneCanPay } else { SigHashType::All };
- let htlc_sighash = hash_to_message!(&bip143::SigHashCache::new(&htlc_tx).signature_hash(0, &htlc_redeemscript, htlc.amount_msat / 1000, htlc_sighashtype)[..]);
+ let htlc_sighashtype = if self.opt_anchors() { EcdsaSighashType::SinglePlusAnyoneCanPay } else { EcdsaSighashType::All };
+ let htlc_sighash = hash_to_message!(&sighash::SighashCache::new(&htlc_tx).segwit_signature_hash(0, &htlc_redeemscript, htlc.amount_msat / 1000, htlc_sighashtype).unwrap()[..]);
let holder_htlc_key = chan_utils::derive_private_key(&secp_ctx, &keys.per_commitment_point, &self.htlc_base_key).map_err(|_| ())?;
- htlc_sigs.push(secp_ctx.sign(&htlc_sighash, &holder_htlc_key));
+ htlc_sigs.push(sign(secp_ctx, &htlc_sighash, &holder_htlc_key));
}
Ok((commitment_sig, htlc_sigs))
let counterparty_delayedpubkey = chan_utils::derive_public_key(&secp_ctx, &per_commitment_point, &self.counterparty_pubkeys().delayed_payment_basepoint).map_err(|_| ())?;
chan_utils::get_revokeable_redeemscript(&revocation_pubkey, self.holder_selected_contest_delay(), &counterparty_delayedpubkey)
};
- let mut sighash_parts = bip143::SigHashCache::new(justice_tx);
- let sighash = hash_to_message!(&sighash_parts.signature_hash(input, &witness_script, amount, SigHashType::All)[..]);
- return Ok(secp_ctx.sign(&sighash, &revocation_key))
+ let mut sighash_parts = sighash::SighashCache::new(justice_tx);
+ let sighash = hash_to_message!(&sighash_parts.segwit_signature_hash(input, &witness_script, amount, EcdsaSighashType::All).unwrap()[..]);
+ return Ok(sign(secp_ctx, &sighash, &revocation_key))
}
fn sign_justice_revoked_htlc(&self, justice_tx: &Transaction, input: usize, amount: u64, per_commitment_key: &SecretKey, htlc: &HTLCOutputInCommitment, secp_ctx: &Secp256k1<secp256k1::All>) -> Result<Signature, ()> {
let holder_htlcpubkey = chan_utils::derive_public_key(&secp_ctx, &per_commitment_point, &self.pubkeys().htlc_basepoint).map_err(|_| ())?;
chan_utils::get_htlc_redeemscript_with_explicit_keys(&htlc, self.opt_anchors(), &counterparty_htlcpubkey, &holder_htlcpubkey, &revocation_pubkey)
};
- let mut sighash_parts = bip143::SigHashCache::new(justice_tx);
- let sighash = hash_to_message!(&sighash_parts.signature_hash(input, &witness_script, amount, SigHashType::All)[..]);
- return Ok(secp_ctx.sign(&sighash, &revocation_key))
+ let mut sighash_parts = sighash::SighashCache::new(justice_tx);
+ let sighash = hash_to_message!(&sighash_parts.segwit_signature_hash(input, &witness_script, amount, EcdsaSighashType::All).unwrap()[..]);
+ return Ok(sign(secp_ctx, &sighash, &revocation_key))
}
fn sign_counterparty_htlc_transaction(&self, htlc_tx: &Transaction, input: usize, amount: u64, per_commitment_point: &PublicKey, htlc: &HTLCOutputInCommitment, secp_ctx: &Secp256k1<secp256k1::All>) -> Result<Signature, ()> {
} else { return Err(()) }
} else { return Err(()) }
} else { return Err(()) };
- let mut sighash_parts = bip143::SigHashCache::new(htlc_tx);
- let sighash = hash_to_message!(&sighash_parts.signature_hash(input, &witness_script, amount, SigHashType::All)[..]);
- return Ok(secp_ctx.sign(&sighash, &htlc_key))
+ let mut sighash_parts = sighash::SighashCache::new(htlc_tx);
+ let sighash = hash_to_message!(&sighash_parts.segwit_signature_hash(input, &witness_script, amount, EcdsaSighashType::All).unwrap()[..]);
+ return Ok(sign(secp_ctx, &sighash, &htlc_key))
}
Err(())
}
Ok(closing_tx.trust().sign(&self.funding_key, &channel_funding_redeemscript, self.channel_value_satoshis, secp_ctx))
}
+ fn sign_holder_anchor_input(
+ &self, anchor_tx: &Transaction, input: usize, secp_ctx: &Secp256k1<secp256k1::All>,
+ ) -> Result<Signature, ()> {
+ let witness_script = chan_utils::get_anchor_redeemscript(&self.holder_channel_pubkeys.funding_pubkey);
+ let sighash = sighash::SighashCache::new(&*anchor_tx).segwit_signature_hash(
+ input, &witness_script, ANCHOR_OUTPUT_VALUE_SATOSHI, EcdsaSighashType::All,
+ ).unwrap();
+ Ok(sign(secp_ctx, &hash_to_message!(&sighash[..]), &self.funding_key))
+ }
+
fn sign_channel_announcement(&self, msg: &UnsignedChannelAnnouncement, secp_ctx: &Secp256k1<secp256k1::All>)
-> Result<(Signature, Signature), ()> {
let msghash = hash_to_message!(&Sha256dHash::hash(&msg.encode()[..])[..]);
- Ok((secp_ctx.sign(&msghash, &self.node_secret), secp_ctx.sign(&msghash, &self.funding_key)))
+ Ok((sign(secp_ctx, &msghash, &self.node_secret), sign(secp_ctx, &msghash, &self.funding_key)))
}
fn ready_channel(&mut self, channel_parameters: &ChannelTransactionParameters) {
pub struct KeysManager {
secp_ctx: Secp256k1<secp256k1::All>,
node_secret: SecretKey,
+ node_id: PublicKey,
inbound_payment_key: KeyMaterial,
destination_script: Script,
shutdown_pubkey: PublicKey,
// Note that when we aren't serializing the key, network doesn't matter
match ExtendedPrivKey::new_master(Network::Testnet, seed) {
Ok(master_key) => {
- let node_secret = master_key.ckd_priv(&secp_ctx, ChildNumber::from_hardened_idx(0).unwrap()).expect("Your RNG is busted").private_key.key;
+ let node_secret = master_key.ckd_priv(&secp_ctx, ChildNumber::from_hardened_idx(0).unwrap()).expect("Your RNG is busted").private_key;
+ let node_id = PublicKey::from_secret_key(&secp_ctx, &node_secret);
let destination_script = match master_key.ckd_priv(&secp_ctx, ChildNumber::from_hardened_idx(1).unwrap()) {
Ok(destination_key) => {
- let wpubkey_hash = WPubkeyHash::hash(&ExtendedPubKey::from_private(&secp_ctx, &destination_key).public_key.to_bytes());
+ let wpubkey_hash = WPubkeyHash::hash(&ExtendedPubKey::from_priv(&secp_ctx, &destination_key).to_pub().to_bytes());
Builder::new().push_opcode(opcodes::all::OP_PUSHBYTES_0)
.push_slice(&wpubkey_hash.into_inner())
.into_script()
Err(_) => panic!("Your RNG is busted"),
};
let shutdown_pubkey = match master_key.ckd_priv(&secp_ctx, ChildNumber::from_hardened_idx(2).unwrap()) {
- Ok(shutdown_key) => ExtendedPubKey::from_private(&secp_ctx, &shutdown_key).public_key.key,
+ Ok(shutdown_key) => ExtendedPubKey::from_priv(&secp_ctx, &shutdown_key).public_key,
Err(_) => panic!("Your RNG is busted"),
};
let channel_master_key = master_key.ckd_priv(&secp_ctx, ChildNumber::from_hardened_idx(3).unwrap()).expect("Your RNG is busted");
let rand_bytes_master_key = master_key.ckd_priv(&secp_ctx, ChildNumber::from_hardened_idx(4).unwrap()).expect("Your RNG is busted");
- let inbound_payment_key: SecretKey = master_key.ckd_priv(&secp_ctx, ChildNumber::from_hardened_idx(5).unwrap()).expect("Your RNG is busted").private_key.key;
+ let inbound_payment_key: SecretKey = master_key.ckd_priv(&secp_ctx, ChildNumber::from_hardened_idx(5).unwrap()).expect("Your RNG is busted").private_key;
let mut inbound_pmt_key_bytes = [0; 32];
inbound_pmt_key_bytes.copy_from_slice(&inbound_payment_key[..]);
let mut res = KeysManager {
secp_ctx,
node_secret,
+ node_id,
inbound_payment_key: KeyMaterial(inbound_pmt_key_bytes),
destination_script,
// entropy, everything else just ensures uniqueness. We rely on the unique_start (ie
// starting_time provided in the constructor) to be unique.
let child_privkey = self.channel_master_key.ckd_priv(&self.secp_ctx, ChildNumber::from_hardened_idx(chan_id as u32).expect("key space exhausted")).expect("Your RNG is busted");
- unique_start.input(&child_privkey.private_key.key[..]);
+ unique_start.input(&child_privkey.private_key[..]);
let seed = Sha256::from_engine(unique_start).into_inner();
htlc_base_key,
commitment_seed,
channel_value_satoshis,
- params.clone()
+ params.clone(),
)
}
input.push(TxIn {
previous_output: descriptor.outpoint.into_bitcoin_outpoint(),
script_sig: Script::new(),
- sequence: 0,
- witness: Vec::new(),
+ sequence: Sequence::ZERO,
+ witness: Witness::new(),
});
witness_weight += StaticPaymentOutputDescriptor::MAX_WITNESS_LENGTH;
input_value += descriptor.output.value;
input.push(TxIn {
previous_output: descriptor.outpoint.into_bitcoin_outpoint(),
script_sig: Script::new(),
- sequence: descriptor.to_self_delay as u32,
- witness: Vec::new(),
+ sequence: Sequence(descriptor.to_self_delay as u32),
+ witness: Witness::new(),
});
witness_weight += DelayedPaymentOutputDescriptor::MAX_WITNESS_LENGTH;
input_value += descriptor.output.value;
input.push(TxIn {
previous_output: outpoint.into_bitcoin_outpoint(),
script_sig: Script::new(),
- sequence: 0,
- witness: Vec::new(),
+ sequence: Sequence::ZERO,
+ witness: Witness::new(),
});
witness_weight += 1 + 73 + 34;
input_value += output.value;
}
let mut spend_tx = Transaction {
version: 2,
- lock_time: 0,
+ lock_time: PackedLockTime(0),
input,
output: outputs,
};
self.derive_channel_keys(descriptor.channel_value_satoshis, &descriptor.channel_keys_id),
descriptor.channel_keys_id));
}
- spend_tx.input[input_idx].witness = keys_cache.as_ref().unwrap().0.sign_counterparty_payment_input(&spend_tx, input_idx, &descriptor, &secp_ctx)?;
+ spend_tx.input[input_idx].witness = Witness::from_vec(keys_cache.as_ref().unwrap().0.sign_counterparty_payment_input(&spend_tx, input_idx, &descriptor, &secp_ctx)?);
},
SpendableOutputDescriptor::DelayedPaymentOutput(descriptor) => {
if keys_cache.is_none() || keys_cache.as_ref().unwrap().1 != descriptor.channel_keys_id {
self.derive_channel_keys(descriptor.channel_value_satoshis, &descriptor.channel_keys_id),
descriptor.channel_keys_id));
}
- spend_tx.input[input_idx].witness = keys_cache.as_ref().unwrap().0.sign_dynamic_p2wsh_input(&spend_tx, input_idx, &descriptor, &secp_ctx)?;
+ spend_tx.input[input_idx].witness = Witness::from_vec(keys_cache.as_ref().unwrap().0.sign_dynamic_p2wsh_input(&spend_tx, input_idx, &descriptor, &secp_ctx)?);
},
SpendableOutputDescriptor::StaticOutput { ref output, .. } => {
let derivation_idx = if output.script_pubkey == self.destination_script {
Err(_) => panic!("Your rng is busted"),
}
};
- let pubkey = ExtendedPubKey::from_private(&secp_ctx, &secret).public_key;
+ let pubkey = ExtendedPubKey::from_priv(&secp_ctx, &secret).to_pub();
if derivation_idx == 2 {
- assert_eq!(pubkey.key, self.shutdown_pubkey);
+ assert_eq!(pubkey.inner, self.shutdown_pubkey);
}
let witness_script = bitcoin::Address::p2pkh(&pubkey, Network::Testnet).script_pubkey();
let payment_script = bitcoin::Address::p2wpkh(&pubkey, Network::Testnet).expect("uncompressed key found").script_pubkey();
if payment_script != output.script_pubkey { return Err(()); };
- let sighash = hash_to_message!(&bip143::SigHashCache::new(&spend_tx).signature_hash(input_idx, &witness_script, output.value, SigHashType::All)[..]);
- let sig = secp_ctx.sign(&sighash, &secret.private_key.key);
- spend_tx.input[input_idx].witness.push(sig.serialize_der().to_vec());
- spend_tx.input[input_idx].witness[0].push(SigHashType::All as u8);
- spend_tx.input[input_idx].witness.push(pubkey.key.serialize().to_vec());
+ let sighash = hash_to_message!(&sighash::SighashCache::new(&spend_tx).segwit_signature_hash(input_idx, &witness_script, output.value, EcdsaSighashType::All).unwrap()[..]);
+ let sig = sign(secp_ctx, &sighash, &secret.private_key);
+ let mut sig_ser = sig.serialize_der().to_vec();
+ sig_ser.push(EcdsaSighashType::All as u8);
+ spend_tx.input[input_idx].witness.push(sig_ser);
+ spend_tx.input[input_idx].witness.push(pubkey.inner.serialize().to_vec());
},
}
input_idx += 1;
}
- debug_assert!(expected_max_weight >= spend_tx.get_weight());
+ debug_assert!(expected_max_weight >= spend_tx.weight());
// Note that witnesses with a signature vary somewhat in size, so allow
// `expected_max_weight` to overshoot by up to 3 bytes per input.
- debug_assert!(expected_max_weight <= spend_tx.get_weight() + descriptors.len() * 3);
+ debug_assert!(expected_max_weight <= spend_tx.weight() + descriptors.len() * 3);
Ok(spend_tx)
}
}
}
+ fn get_node_id(&self, recipient: Recipient) -> Result<PublicKey, ()> {
+ match recipient {
+ Recipient::Node => Ok(self.node_id.clone()),
+ Recipient::PhantomNode => Err(())
+ }
+ }
+
+ fn ecdh(&self, recipient: Recipient, other_key: &PublicKey, tweak: Option<&Scalar>) -> Result<SharedSecret, ()> {
+ let mut node_secret = self.get_node_secret(recipient)?;
+ if let Some(tweak) = tweak {
+ node_secret = node_secret.mul_tweak(tweak).map_err(|_| ())?;
+ }
+ Ok(SharedSecret::new(other_key, &node_secret))
+ }
+
fn get_inbound_payment_key_material(&self) -> KeyMaterial {
self.inbound_payment_key.clone()
}
let child_ix = self.rand_bytes_child_index.fetch_add(1, Ordering::AcqRel);
let child_privkey = self.rand_bytes_master_key.ckd_priv(&self.secp_ctx, ChildNumber::from_hardened_idx(child_ix as u32).expect("key space exhausted")).expect("Your RNG is busted");
- sha.input(&child_privkey.private_key.key[..]);
+ sha.input(&child_privkey.private_key[..]);
sha.input(b"Unique Secure Random Bytes Salt");
Sha256::from_engine(sha).into_inner()
Recipient::Node => self.get_node_secret(Recipient::Node)?,
Recipient::PhantomNode => return Err(()),
};
- Ok(self.secp_ctx.sign_recoverable(&hash_to_message!(&Sha256::hash(&preimage)), &secret))
+ Ok(self.secp_ctx.sign_ecdsa_recoverable(&hash_to_message!(&Sha256::hash(&preimage)), &secret))
}
}
inner: KeysManager,
inbound_payment_key: KeyMaterial,
phantom_secret: SecretKey,
+ phantom_node_id: PublicKey,
}
impl KeysInterface for PhantomKeysManager {
}
}
+ fn get_node_id(&self, recipient: Recipient) -> Result<PublicKey, ()> {
+ match recipient {
+ Recipient::Node => self.inner.get_node_id(Recipient::Node),
+ Recipient::PhantomNode => Ok(self.phantom_node_id.clone()),
+ }
+ }
+
+ fn ecdh(&self, recipient: Recipient, other_key: &PublicKey, tweak: Option<&Scalar>) -> Result<SharedSecret, ()> {
+ let mut node_secret = self.get_node_secret(recipient)?;
+ if let Some(tweak) = tweak {
+ node_secret = node_secret.mul_tweak(tweak).map_err(|_| ())?;
+ }
+ Ok(SharedSecret::new(other_key, &node_secret))
+ }
+
fn get_inbound_payment_key_material(&self) -> KeyMaterial {
self.inbound_payment_key.clone()
}
fn sign_invoice(&self, hrp_bytes: &[u8], invoice_data: &[u5], recipient: Recipient) -> Result<RecoverableSignature, ()> {
let preimage = construct_invoice_preimage(&hrp_bytes, &invoice_data);
let secret = self.get_node_secret(recipient)?;
- Ok(self.inner.secp_ctx.sign_recoverable(&hash_to_message!(&Sha256::hash(&preimage)), &secret))
+ Ok(self.inner.secp_ctx.sign_ecdsa_recoverable(&hash_to_message!(&Sha256::hash(&preimage)), &secret))
}
}
pub fn new(seed: &[u8; 32], starting_time_secs: u64, starting_time_nanos: u32, cross_node_seed: &[u8; 32]) -> Self {
let inner = KeysManager::new(seed, starting_time_secs, starting_time_nanos);
let (inbound_key, phantom_key) = hkdf_extract_expand_twice(b"LDK Inbound and Phantom Payment Key Expansion", cross_node_seed);
+ let phantom_secret = SecretKey::from_slice(&phantom_key).unwrap();
+ let phantom_node_id = PublicKey::from_secret_key(&inner.secp_ctx, &phantom_secret);
Self {
inner,
inbound_payment_key: KeyMaterial(inbound_key),
- phantom_secret: SecretKey::from_slice(&phantom_key).unwrap(),
+ phantom_secret,
+ phantom_node_id,
}
}