use ethers::types::{Bytes, EIP1186ProofResponse}; use ethers::utils::keccak256; use ethers::utils::rlp::{decode_list, RlpStream}; pub fn verify_proof(proof: &Vec, root: &Vec, path: &Vec, value: &Vec) -> bool { let mut expected_hash = root.clone(); let mut path_offset = 0; for (i, node) in proof.iter().enumerate() { if expected_hash != keccak256(node).to_vec() { return false; } let node_list: Vec> = decode_list(node); if node_list.len() == 17 { if i == proof.len() - 1 { // exclusion proof let nibble = get_nibble(&path, path_offset); let node = &node_list[nibble as usize]; if node.len() == 0 && is_empty_value(value) { return true; } } else { let nibble = get_nibble(&path, path_offset); expected_hash = node_list[nibble as usize].clone(); path_offset += 1; } } else if node_list.len() == 2 { if i == proof.len() - 1 { // exclusion proof if !paths_match( &node_list[0], skip_length(&node_list[0]), &path, path_offset, ) && is_empty_value(value) { return true; } // inclusion proof if &node_list[1] == value { return paths_match( &node_list[0], skip_length(&node_list[0]), &path, path_offset, ); } } else { let node_path = &node_list[0]; let prefix_length = shared_prefix_length(path, path_offset, node_path); if prefix_length < node_path.len() * 2 - skip_length(node_path) { // The proof shows a divergent path, but we're not // at the end of the proof, so something's wrong. return false; } path_offset += prefix_length; expected_hash = node_list[1].clone(); } } else { return false; } } false } fn paths_match(p1: &Vec, s1: usize, p2: &Vec, s2: usize) -> bool { let len1 = p1.len() * 2 - s1; let len2 = p2.len() * 2 - s2; if len1 != len2 { return false; } for offset in 0..len1 { let n1 = get_nibble(p1, s1 + offset); let n2 = get_nibble(p2, s2 + offset); if n1 != n2 { return false; } } true } #[allow(dead_code)] fn get_rest_path(p: &Vec, s: usize) -> String { let mut ret = String::new(); for i in s..p.len() * 2 { let n = get_nibble(p, i); ret += &format!("{:01x}", n); } ret } fn is_empty_value(value: &Vec) -> bool { let mut stream = RlpStream::new(); stream.begin_list(4); stream.append_empty_data(); stream.append_empty_data(); let empty_storage_hash = "56e81f171bcc55a6ff8345e692c0f86e5b48e01b996cadc001622fb5e363b421"; stream.append(&hex::decode(empty_storage_hash).unwrap()); let empty_code_hash = "c5d2460186f7233c927e7db2dcc703c0e500b653ca82273b7bfad8045d85a470"; stream.append(&hex::decode(empty_code_hash).unwrap()); let empty_account = stream.out(); let is_empty_slot = value.len() == 1 && value[0] == 0x80; let is_empty_account = value == &empty_account; is_empty_slot || is_empty_account } fn shared_prefix_length(path: &Vec, path_offset: usize, node_path: &Vec) -> usize { let skip_length = skip_length(node_path); let len = std::cmp::min( node_path.len() * 2 - skip_length, path.len() * 2 - path_offset, ); let mut prefix_len = 0; for i in 0..len { let path_nibble = get_nibble(path, i + path_offset); let node_path_nibble = get_nibble(node_path, i + skip_length); if path_nibble == node_path_nibble { prefix_len += 1; } else { break; } } prefix_len } fn skip_length(node: &Vec) -> usize { if node.len() == 0 { return 0; } let nibble = get_nibble(node, 0); match nibble { 0 => 2, 1 => 1, 2 => 2, 3 => 1, _ => 0, } } fn get_nibble(path: &Vec, offset: usize) -> u8 { let byte = path[offset / 2]; if offset % 2 == 0 { byte >> 4 } else { byte & 0xF } } pub fn encode_account(proof: &EIP1186ProofResponse) -> Vec { let mut stream = RlpStream::new_list(4); stream.append(&proof.nonce); stream.append(&proof.balance); stream.append(&proof.storage_hash); stream.append(&proof.code_hash); let encoded = stream.out(); encoded.to_vec() } #[cfg(test)] mod tests { use crate::proof::shared_prefix_length; #[tokio::test] async fn test_shared_prefix_length() { // We compare the path starting from the 6th nibble i.e. the 6 in 0x6f let path: Vec = vec![0x12, 0x13, 0x14, 0x6f, 0x6c, 0x64, 0x21]; let path_offset = 6; // Our node path matches only the first 5 nibbles of the path let node_path: Vec = vec![0x6f, 0x6c, 0x63, 0x21]; let shared_len = shared_prefix_length(&path, path_offset, &node_path); assert_eq!(shared_len, 5); // Now we compare the path starting from the 5th nibble i.e. the 4 in 0x14 let path: Vec = vec![0x12, 0x13, 0x14, 0x6f, 0x6c, 0x64, 0x21]; let path_offset = 5; // Our node path matches only the first 7 nibbles of the path // Note the first nibble is 1, so we skip 1 nibble let node_path: Vec = vec![0x14, 0x6f, 0x6c, 0x64, 0x11]; let shared_len = shared_prefix_length(&path, path_offset, &node_path); assert_eq!(shared_len, 7); } }