#![cfg(feature = "full")]
use crate::instruction::Instruction;
use digest::Digest;
use serde_derive::{Deserialize, Serialize};
#[derive(Debug, PartialEq)]
pub enum Secp256k1Error {
InvalidSignature,
InvalidRecoveryId,
InvalidDataOffsets,
InvalidInstructionDataSize,
}
pub const HASHED_PUBKEY_SERIALIZED_SIZE: usize = 20;
pub const SIGNATURE_SERIALIZED_SIZE: usize = 64;
pub const SIGNATURE_OFFSETS_SERIALIZED_SIZE: usize = 11;
pub const DATA_START: usize = SIGNATURE_OFFSETS_SERIALIZED_SIZE + 1;
#[derive(Default, Serialize, Deserialize, Debug)]
pub struct SecpSignatureOffsets {
pub signature_offset: u16, pub signature_instruction_index: u8,
pub eth_address_offset: u16, pub eth_address_instruction_index: u8,
pub message_data_offset: u16, pub message_data_size: u16, pub message_instruction_index: u8,
}
pub fn new_secp256k1_instruction(
priv_key: &libsecp256k1::SecretKey,
message_arr: &[u8],
) -> Instruction {
let secp_pubkey = libsecp256k1::PublicKey::from_secret_key(priv_key);
let eth_pubkey = construct_eth_pubkey(&secp_pubkey);
let mut hasher = sha3::Keccak256::new();
hasher.update(&message_arr);
let message_hash = hasher.finalize();
let mut message_hash_arr = [0u8; 32];
message_hash_arr.copy_from_slice(&message_hash.as_slice());
let message = libsecp256k1::Message::parse(&message_hash_arr);
let (signature, recovery_id) = libsecp256k1::sign(&message, priv_key);
let signature_arr = signature.serialize();
assert_eq!(signature_arr.len(), SIGNATURE_SERIALIZED_SIZE);
let mut instruction_data = vec![];
instruction_data.resize(
DATA_START
.saturating_add(eth_pubkey.len())
.saturating_add(signature_arr.len())
.saturating_add(message_arr.len())
.saturating_add(1),
0,
);
let eth_address_offset = DATA_START;
instruction_data[eth_address_offset..eth_address_offset.saturating_add(eth_pubkey.len())]
.copy_from_slice(ð_pubkey);
let signature_offset = DATA_START.saturating_add(eth_pubkey.len());
instruction_data[signature_offset..signature_offset.saturating_add(signature_arr.len())]
.copy_from_slice(&signature_arr);
instruction_data[signature_offset.saturating_add(signature_arr.len())] =
recovery_id.serialize();
let message_data_offset = signature_offset
.saturating_add(signature_arr.len())
.saturating_add(1);
instruction_data[message_data_offset..].copy_from_slice(message_arr);
let num_signatures = 1;
instruction_data[0] = num_signatures;
let offsets = SecpSignatureOffsets {
signature_offset: signature_offset as u16,
signature_instruction_index: 0,
eth_address_offset: eth_address_offset as u16,
eth_address_instruction_index: 0,
message_data_offset: message_data_offset as u16,
message_data_size: message_arr.len() as u16,
message_instruction_index: 0,
};
let writer = std::io::Cursor::new(&mut instruction_data[1..DATA_START]);
bincode::serialize_into(writer, &offsets).unwrap();
Instruction {
program_id: solana_sdk::secp256k1_program::id(),
accounts: vec![],
data: instruction_data,
}
}
pub fn construct_eth_pubkey(
pubkey: &libsecp256k1::PublicKey,
) -> [u8; HASHED_PUBKEY_SERIALIZED_SIZE] {
let mut addr = [0u8; HASHED_PUBKEY_SERIALIZED_SIZE];
addr.copy_from_slice(&sha3::Keccak256::digest(&pubkey.serialize()[1..])[12..]);
assert_eq!(addr.len(), HASHED_PUBKEY_SERIALIZED_SIZE);
addr
}
pub fn verify_eth_addresses(
data: &[u8],
instruction_datas: &[&[u8]],
libsecp256k1_0_5_upgrade_enabled: bool,
) -> Result<(), Secp256k1Error> {
if data.is_empty() {
return Err(Secp256k1Error::InvalidInstructionDataSize);
}
let count = data[0] as usize;
let expected_data_size = count
.saturating_mul(SIGNATURE_OFFSETS_SERIALIZED_SIZE)
.saturating_add(1);
if data.len() < expected_data_size {
return Err(Secp256k1Error::InvalidInstructionDataSize);
}
for i in 0..count {
let start = i
.saturating_mul(SIGNATURE_OFFSETS_SERIALIZED_SIZE)
.saturating_add(1);
let end = start.saturating_add(SIGNATURE_OFFSETS_SERIALIZED_SIZE);
let offsets: SecpSignatureOffsets = bincode::deserialize(&data[start..end])
.map_err(|_| Secp256k1Error::InvalidSignature)?;
let signature_index = offsets.signature_instruction_index as usize;
if signature_index >= instruction_datas.len() {
return Err(Secp256k1Error::InvalidInstructionDataSize);
}
let signature_instruction = instruction_datas[signature_index];
let sig_start = offsets.signature_offset as usize;
let sig_end = sig_start.saturating_add(SIGNATURE_SERIALIZED_SIZE);
if sig_end >= signature_instruction.len() {
return Err(Secp256k1Error::InvalidSignature);
}
let sig_parse_result = if libsecp256k1_0_5_upgrade_enabled {
libsecp256k1::Signature::parse_standard_slice(
&signature_instruction[sig_start..sig_end],
)
} else {
libsecp256k1::Signature::parse_overflowing_slice(
&signature_instruction[sig_start..sig_end],
)
};
let signature = sig_parse_result.map_err(|_| Secp256k1Error::InvalidSignature)?;
let recovery_id = libsecp256k1::RecoveryId::parse(signature_instruction[sig_end])
.map_err(|_| Secp256k1Error::InvalidRecoveryId)?;
let eth_address_slice = get_data_slice(
instruction_datas,
offsets.eth_address_instruction_index,
offsets.eth_address_offset,
HASHED_PUBKEY_SERIALIZED_SIZE,
)?;
let message_slice = get_data_slice(
instruction_datas,
offsets.message_instruction_index,
offsets.message_data_offset,
offsets.message_data_size as usize,
)?;
let mut hasher = sha3::Keccak256::new();
hasher.update(message_slice);
let message_hash = hasher.finalize();
let pubkey = libsecp256k1::recover(
&libsecp256k1::Message::parse_slice(&message_hash).unwrap(),
&signature,
&recovery_id,
)
.map_err(|_| Secp256k1Error::InvalidSignature)?;
let eth_address = construct_eth_pubkey(&pubkey);
if eth_address_slice != eth_address {
return Err(Secp256k1Error::InvalidSignature);
}
}
Ok(())
}
fn get_data_slice<'a>(
instruction_datas: &'a [&[u8]],
instruction_index: u8,
offset_start: u16,
size: usize,
) -> Result<&'a [u8], Secp256k1Error> {
let signature_index = instruction_index as usize;
if signature_index >= instruction_datas.len() {
return Err(Secp256k1Error::InvalidDataOffsets);
}
let signature_instruction = &instruction_datas[signature_index];
let start = offset_start as usize;
let end = start.saturating_add(size);
if end > signature_instruction.len() {
return Err(Secp256k1Error::InvalidSignature);
}
Ok(&instruction_datas[signature_index][start..end])
}
#[cfg(test)]
pub mod test {
use super::*;
fn test_case(num_signatures: u8, offsets: &SecpSignatureOffsets) -> Result<(), Secp256k1Error> {
let mut instruction_data = vec![0u8; DATA_START];
instruction_data[0] = num_signatures;
let writer = std::io::Cursor::new(&mut instruction_data[1..]);
bincode::serialize_into(writer, &offsets).unwrap();
verify_eth_addresses(&instruction_data, &[&[0u8; 100]], false)
}
#[test]
fn test_invalid_offsets() {
solana_logger::setup();
let mut instruction_data = vec![0u8; DATA_START];
let offsets = SecpSignatureOffsets::default();
instruction_data[0] = 1;
let writer = std::io::Cursor::new(&mut instruction_data[1..]);
bincode::serialize_into(writer, &offsets).unwrap();
instruction_data.truncate(instruction_data.len() - 1);
assert_eq!(
verify_eth_addresses(&instruction_data, &[&[0u8; 100]], false),
Err(Secp256k1Error::InvalidInstructionDataSize)
);
let offsets = SecpSignatureOffsets {
signature_instruction_index: 1,
..SecpSignatureOffsets::default()
};
assert_eq!(
test_case(1, &offsets),
Err(Secp256k1Error::InvalidInstructionDataSize)
);
let offsets = SecpSignatureOffsets {
message_instruction_index: 1,
..SecpSignatureOffsets::default()
};
assert_eq!(
test_case(1, &offsets),
Err(Secp256k1Error::InvalidDataOffsets)
);
let offsets = SecpSignatureOffsets {
eth_address_instruction_index: 1,
..SecpSignatureOffsets::default()
};
assert_eq!(
test_case(1, &offsets),
Err(Secp256k1Error::InvalidDataOffsets)
);
}
#[test]
fn test_message_data_offsets() {
let offsets = SecpSignatureOffsets {
message_data_offset: 99,
message_data_size: 1,
..SecpSignatureOffsets::default()
};
assert_eq!(
test_case(1, &offsets),
Err(Secp256k1Error::InvalidSignature)
);
let offsets = SecpSignatureOffsets {
message_data_offset: 100,
message_data_size: 1,
..SecpSignatureOffsets::default()
};
assert_eq!(
test_case(1, &offsets),
Err(Secp256k1Error::InvalidSignature)
);
let offsets = SecpSignatureOffsets {
message_data_offset: 100,
message_data_size: 1000,
..SecpSignatureOffsets::default()
};
assert_eq!(
test_case(1, &offsets),
Err(Secp256k1Error::InvalidSignature)
);
let offsets = SecpSignatureOffsets {
message_data_offset: std::u16::MAX,
message_data_size: std::u16::MAX,
..SecpSignatureOffsets::default()
};
assert_eq!(
test_case(1, &offsets),
Err(Secp256k1Error::InvalidSignature)
);
}
#[test]
fn test_eth_offset() {
let offsets = SecpSignatureOffsets {
eth_address_offset: std::u16::MAX,
..SecpSignatureOffsets::default()
};
assert_eq!(
test_case(1, &offsets),
Err(Secp256k1Error::InvalidSignature)
);
let offsets = SecpSignatureOffsets {
eth_address_offset: 100 - HASHED_PUBKEY_SERIALIZED_SIZE as u16 + 1,
..SecpSignatureOffsets::default()
};
assert_eq!(
test_case(1, &offsets),
Err(Secp256k1Error::InvalidSignature)
);
}
#[test]
fn test_signature_offset() {
let offsets = SecpSignatureOffsets {
signature_offset: std::u16::MAX,
..SecpSignatureOffsets::default()
};
assert_eq!(
test_case(1, &offsets),
Err(Secp256k1Error::InvalidSignature)
);
let offsets = SecpSignatureOffsets {
signature_offset: 100 - SIGNATURE_SERIALIZED_SIZE as u16 + 1,
..SecpSignatureOffsets::default()
};
assert_eq!(
test_case(1, &offsets),
Err(Secp256k1Error::InvalidSignature)
);
}
}