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🔐 Complete Library to prove EVM state in ZK, to cryptographically verify storage, transactions, receipts and accounts!

This library exposes functions and ZK circuits (SP1, Risc0) to obtain, verify and prove query infromation from Ethereum clients.

Overview of provided functions

account storage receipt transaction
Verify that an account exists in the Ethereum Trie Verify a value stored under an account or smart contract Verify a receipt or the entire receipt trie of a block Verify native Ethereum transactions
  • accounts: any Ethereum address with a Balance > 0
  • receipts: data related to events (for example ERC20 transfer information)

Obtain a Merkle Proof for a value in Ethereum State

For each of these values in storage a function is provided that helps obtain a merkle proof from the Ethereum client using alloy rpc:

trie-utils/src/proofs/*

  • account.rs
  • receipt.rs
  • storage.rs
  • transaction.rs

For example transaction.rs returns a merkle proof for an individual native Ethereum transaction:

pub async fn get_ethereum_transaction_proof_inputs(
    target_index: u32,
    block_hash: &str,
) -> MerkleProofInput {
    let key = load_infura_key_from_env();
    println!("Key: {}", key);
    let rpc_url = "https://mainnet.infura.io/v3/".to_string() + &key;
    let provider = ProviderBuilder::new().on_http(Url::from_str(&rpc_url).unwrap());
    let block = provider
        .get_block_by_hash(
            B256::from_str(block_hash).unwrap(),
            alloy::rpc::types::BlockTransactionsKind::Full,
        )
        .await
        .expect("Failed to get Block!")
        .expect("Block not found!");
    let memdb = Arc::new(MemoryDB::new(true));
    let mut trie = EthTrie::new(memdb.clone());

    for (index, tx) in block.transactions.txns().enumerate() {
        let path = alloy_rlp::encode(index);
        let mut encoded_tx = vec![];
        match &tx.inner {
            TxEnvelope::Legacy(tx) => tx.eip2718_encode(&mut encoded_tx),
            TxEnvelope::Eip2930(tx) => {
                tx.eip2718_encode(&mut encoded_tx);
            }
            TxEnvelope::Eip1559(tx) => {
                tx.eip2718_encode(&mut encoded_tx);
            }
            TxEnvelope::Eip4844(tx) => {
                tx.eip2718_encode(&mut encoded_tx);
            }
            TxEnvelope::Eip7702(tx) => {
                tx.eip2718_encode(&mut encoded_tx);
            }
            _ => panic!("Unsupported transaction type"),
        }
        trie.insert(&path, &encoded_tx).expect("Failed to insert");
    }

    trie.root_hash().unwrap();
    let tx_key: Vec<u8> = alloy_rlp::encode(target_index);
    let proof: Vec<Vec<u8>> = trie.get_proof(&tx_key).unwrap();
    MerkleProofInput {
        proof,
        root_hash: block.header.transactions_root.to_vec(),
        key: tx_key,
    }
}

Verify a Merkle Proof against a trusted State Root

The merkle proof is then be verified using the verify_merkle_proof function found in crypto-ops/lib.rs:

pub fn verify_merkle_proof(root_hash: B256, proof: Vec<Vec<u8>>, key: &[u8]) -> Vec<u8> {
    let proof_db = Arc::new(MemoryDB::new(true));
    for node_encoded in proof.clone().into_iter() {
        let hash: B256 = digest_keccak(&node_encoded).into();
        proof_db.insert(hash.as_slice(), node_encoded).unwrap();
    }
    let mut trie = EthTrie::from(proof_db, root_hash).expect("Invalid merkle proof");
    assert_eq!(root_hash, trie.root_hash().unwrap());
    trie.verify_proof(root_hash, key, proof)
        .expect("Failed to verify Merkle Proof")
        .expect("Key does not exist!")
}

This function checks that the trie root matches the trusted root obtained from the Light Client. And that the data we claim exists in the Trie is actually present at the specified path (=key).

Generate a ZK proof for the validity of a Merkle Proof

In order to prove our Merkle verification in ZK, we can use the circuit located in circuits/merkle-proof/src/main.rs:

#![no_main]
sp1_zkvm::entrypoint!(main);
use crypto_ops::{types::MerkleProofInput, verify_merkle_proof};
pub fn main() {
    let merkle_proof: MerkleProofInput =
        serde_json::from_slice(&sp1_zkvm::io::read::<Vec<u8>>()).unwrap();

    let output = verify_merkle_proof(
        merkle_proof.root_hash.as_slice().try_into().unwrap(),
        merkle_proof.proof.clone(),
        &merkle_proof.key,
    );
    sp1_zkvm::io::commit_slice(&output);
}

To try this against a real Ethereum Transaction for testing purposes, run:

cargo test --bin prover test_generate_ethereum_transaction_zk_proof_sp1 -F sp1

consider using -F cuda when cuda acceleration is available!

or

cargo test --bin prover test_generate_optimism_transaction_zk_proof_risc0 -F metal

Note

The feature flag sp1 tells the compiler to leverage the keccak precompile for hash acceleration in the ZK circuit.

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