xmr-btc-swap/monero-adaptor/tests/integration_test.rs

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#![allow(non_snake_case)]
use curve25519_dalek::constants::ED25519_BASEPOINT_POINT;
use curve25519_dalek::edwards::CompressedEdwardsY;
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use curve25519_dalek::scalar::Scalar;
use hash_edwards_to_edwards::hash_point_to_point;
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use monero::blockdata::transaction::{ExtraField, KeyImage, SubField, TxOutTarget};
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use monero::cryptonote::hash::Hashable;
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use monero::cryptonote::onetime_key::{KeyGenerator, MONERO_MUL_FACTOR};
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use monero::util::key::H;
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use monero::util::ringct::{EcdhInfo, RctSig, RctSigBase, RctSigPrunable, RctType};
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use monero::{
PrivateKey, PublicKey, Transaction, TransactionPrefix, TxIn, TxOut, VarInt, ViewPair,
};
use monero_harness::Monero;
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use monero_rpc::monerod::{GetOutputsOut, MonerodRpc};
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use monero_wallet::MonerodClientExt;
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use rand::{Rng, SeedableRng};
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use std::convert::TryInto;
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use std::iter;
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use testcontainers::clients::Cli;
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#[tokio::test]
async fn monerod_integration_test() {
let mut rng = rand::rngs::StdRng::from_seed([0u8; 32]);
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let cli = Cli::default();
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let (monero, _monerod_container, _monero_wallet_rpc_containers) =
Monero::new(&cli, vec![]).await.unwrap();
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let signing_key = curve25519_dalek::scalar::Scalar::random(&mut rng);
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let lock_kp = monero::KeyPair {
view: monero::PrivateKey::from_scalar(curve25519_dalek::scalar::Scalar::random(&mut rng)),
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spend: monero::PrivateKey::from_scalar(signing_key),
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};
let lock_amount = 1_000_000_000_000;
let fee = 400_000_000;
let spend_amount = lock_amount - fee;
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let lock_address = monero::Address::from_keypair(monero::Network::Mainnet, &lock_kp);
dbg!(lock_address.to_string()); // 45BcRKAHaA4b5A9SdamF2f1w7zk1mKkBPhaqVoDWzuAtMoSAytzm5A6b2fE6ruupkAFmStrQzdojUExt96mR3oiiSKp8Exf
monero.init_miner().await.unwrap();
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let wallet = monero.wallet("miner").expect("wallet to exist");
let transfer = wallet
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.transfer(&lock_address.to_string(), lock_amount)
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.await
.expect("lock to succeed");
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let client = monero.monerod().client();
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let miner_address = wallet
.address()
.await
.expect("miner address to exist")
.address;
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client
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.generateblocks(10, miner_address)
.await
.expect("can generate blocks");
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let lock_tx = transfer.tx_hash.parse().unwrap();
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let o_indexes_response = client.get_o_indexes(lock_tx).await.unwrap();
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let transaction = client
.get_transactions(&[lock_tx])
.await
.unwrap()
.pop()
.unwrap();
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dbg!(&transaction.prefix.inputs);
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let viewpair = ViewPair::from(&lock_kp);
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let our_output = transaction
.check_outputs(&viewpair, 0..1, 0..1)
.expect("to have outputs in this transaction")
.pop()
.expect("to own at least one output");
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let actual_lock_amount = transaction.get_amount(&viewpair, &our_output).unwrap();
assert_eq!(actual_lock_amount, lock_amount);
let real_key_offset = o_indexes_response.o_indexes[our_output.index];
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let (lower, upper) = client.calculate_key_offset_boundaries().await.unwrap();
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let mut key_offsets = Vec::with_capacity(11);
key_offsets.push(VarInt(real_key_offset));
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for _ in 0..10 {
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loop {
let decoy_offset = VarInt(rng.gen_range(lower.0, upper.0));
if key_offsets.contains(&decoy_offset) {
continue;
}
key_offsets.push(decoy_offset);
break;
}
}
dbg!(&key_offsets);
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let response = client
.get_outs(
key_offsets
.iter()
.map(|offset| GetOutputsOut {
amount: 0,
index: offset.0,
})
.collect(),
)
.await
.unwrap();
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dbg!(&response);
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let ring = response
.outs
.iter()
.map(|out| out.key.point.decompress().unwrap())
.collect::<Vec<_>>()
.try_into()
.unwrap();
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key_offsets.sort();
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let relative_key_offsets = to_relative_offsets(&key_offsets);
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dbg!(&relative_key_offsets);
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let target_address = "498AVruCDWgP9Az9LjMm89VWjrBrSZ2W2K3HFBiyzzrRjUJWUcCVxvY1iitfuKoek2FdX6MKGAD9Qb1G1P8QgR5jPmmt3Vj".parse::<monero::Address>().unwrap();
let ecdh_key_0 = PrivateKey::random(&mut rng);
let (ecdh_info_0, out_blinding_0) = EcdhInfo::new_bulletproof(spend_amount, ecdh_key_0.scalar);
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let ecdh_key_1 = PrivateKey::random(&mut rng);
let (ecdh_info_1, out_blinding_1) = EcdhInfo::new_bulletproof(spend_amount, ecdh_key_1.scalar);
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let (bulletproof, out_pk) = monero::make_bulletproof(&mut rng, &[spend_amount, 0], &[
out_blinding_0,
out_blinding_1,
])
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.unwrap();
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let k_image = {
let k = lock_kp.spend.scalar;
let K = ViewPair::from(&lock_kp).spend.point;
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let k_image = k * hash_point_to_point(K.decompress().unwrap());
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KeyImage {
image: monero::cryptonote::hash::Hash(k_image.compress().to_bytes()),
}
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};
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let prefix = TransactionPrefix {
version: VarInt(2),
unlock_time: Default::default(),
inputs: vec![TxIn::ToKey {
amount: VarInt(0),
key_offsets: relative_key_offsets,
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k_image,
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}],
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outputs: vec![
TxOut {
amount: VarInt(0),
target: TxOutTarget::ToKey {
key: KeyGenerator::from_random(
target_address.public_view,
target_address.public_spend,
ecdh_key_0,
)
.one_time_key(0), // TODO: This must be the output index
},
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},
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TxOut {
amount: VarInt(0),
target: TxOutTarget::ToKey {
key: KeyGenerator::from_random(
target_address.public_view,
target_address.public_spend,
ecdh_key_1,
)
.one_time_key(1), // TODO: This must be the output index
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},
},
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],
extra: ExtraField(vec![
SubField::TxPublicKey(PublicKey::from_private_key(&ecdh_key_0)),
SubField::TxPublicKey(PublicKey::from_private_key(&ecdh_key_1)),
]),
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};
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// assert_eq!(prefix.hash(),
// "c3ded4d1a8cddd4f76c09b63edff4e312e759b3afc46beda4e1fd75c9c68d997".parse().
// unwrap());
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let signing_key = signing_key
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+ KeyGenerator::from_key(&viewpair, our_output.tx_pubkey)
.get_rvn_scalar(our_output.index)
.scalar;
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let commitment_ring = response
.outs
.iter()
.map(|out| CompressedEdwardsY(out.mask.key).decompress().unwrap())
.collect::<Vec<_>>()
.try_into()
.unwrap();
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let out_pk = out_pk
.into_iter()
.map(|p| (p.decompress().unwrap() * Scalar::from(MONERO_MUL_FACTOR)).compress())
.collect::<Vec<_>>();
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let fee_key = Scalar::from(fee) * H.point.decompress().unwrap();
let pseudo_out = fee_key + out_pk[0].decompress().unwrap() + out_pk[1].decompress().unwrap();
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let (_, real_commitment_blinder) = transaction.clone().rct_signatures.sig.unwrap().ecdh_info
[our_output.index]
.open_commitment(&viewpair, &our_output.tx_pubkey, our_output.index);
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let H_p_pk = hash_point_to_point(signing_key * ED25519_BASEPOINT_POINT);
let alpha = Scalar::random(&mut rng);
let sig = monero_adaptor::clsag::sign(
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&prefix.hash().to_bytes(),
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signing_key,
H_p_pk,
alpha,
&ring,
&commitment_ring,
random_array(|| Scalar::random(&mut rng)),
real_commitment_blinder
- (out_blinding_0 + out_blinding_1) * Scalar::from(MONERO_MUL_FACTOR),
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pseudo_out,
alpha * ED25519_BASEPOINT_POINT,
alpha * H_p_pk,
signing_key * H_p_pk,
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);
sig.responses.iter().enumerate().for_each(|(i, res)| {
println!(
r#"epee::string_tools::hex_to_pod("{}", clsag.s[{}]);"#,
hex::encode(res.as_bytes()),
i
);
});
println!("{}", hex::encode(sig.h_0.as_bytes()));
println!("{}", hex::encode(sig.D.compress().as_bytes()));
let I = hex::encode(sig.I.compress().to_bytes());
println!("{}", I);
let msg = hex::encode(&prefix.hash().to_bytes());
println!("{}", msg);
ring.iter().zip(commitment_ring.iter()).for_each(|(pk, c)| {
println!(
"std::make_tuple(\"{}\",\"{}\"),",
hex::encode(pk.compress().to_bytes()),
hex::encode(c.compress().to_bytes())
);
});
println!("{}", hex::encode(pseudo_out.compress().to_bytes()));
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let out_pk = out_pk
.iter()
.map(|c| monero::util::ringct::CtKey {
mask: monero::util::ringct::Key { key: c.to_bytes() },
})
.collect::<Vec<_>>();
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let transaction = Transaction {
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prefix,
signatures: Vec::new(),
rct_signatures: RctSig {
sig: Some(RctSigBase {
rct_type: RctType::Clsag,
txn_fee: VarInt(fee),
pseudo_outs: Vec::new(),
ecdh_info: vec![ecdh_info_0, ecdh_info_1],
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out_pk,
}),
p: Some(RctSigPrunable {
range_sigs: Vec::new(),
bulletproofs: vec![bulletproof],
MGs: Vec::new(),
Clsags: vec![sig.into()],
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pseudo_outs: vec![monero::util::ringct::Key {
key: pseudo_out.compress().0,
}],
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}),
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},
};
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client.send_raw_transaction(transaction).await.unwrap();
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}
fn to_relative_offsets(offsets: &[VarInt]) -> Vec<VarInt> {
let vals = offsets.iter();
let next_vals = offsets.iter().skip(1);
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let diffs = vals
.zip(next_vals)
.map(|(cur, next)| VarInt(next.0 - cur.0));
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iter::once(offsets[0].clone()).chain(diffs).collect()
}
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fn random_array<T: Default + Copy, const N: usize>(rng: impl FnMut() -> T) -> [T; N] {
let mut ring = [T::default(); N];
ring[..].fill_with(rng);
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ring
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}
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#[cfg(test)]
mod tests {
use super::*;
#[test]
fn calculate_relative_key_offsets() {
let key_offsets = [
VarInt(78),
VarInt(81),
VarInt(91),
VarInt(91),
VarInt(96),
VarInt(98),
VarInt(101),
VarInt(112),
VarInt(113),
VarInt(114),
VarInt(117),
];
let relative_offsets = to_relative_offsets(&key_offsets);
assert_eq!(&relative_offsets, &[
VarInt(78),
VarInt(3),
VarInt(10),
VarInt(0),
VarInt(5),
VarInt(2),
VarInt(3),
VarInt(11),
VarInt(1),
VarInt(1),
VarInt(3),
])
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}
}