Headline
GHSA-7p92-x423-vwj6: Plonk verifier KZG multi point verification
Impact
The vulnerability allows a third party to derive a valid proof from a valid initial tuple {proof, public_inputs}, corresponding to the same public inputs as the initial proof. It is due to a randomness being generated using a small part of the scratch memory describing the state, allowing for degrees of freedom in the transcript.
Note that the impact is limited to the PlonK verifier smart contract.
Patches
We still use a hash function on some data to have a pseudo rng, but instead of hashing the first 32 bytes of the state (
let random := mod(keccak256(state, 0x20), r_mod) )
we hash the whole state at this point of the verifier as if it was a Fiat Shamir transcript:
mstore(mPtr, mload(add(state, STATE_FOLDED_DIGESTS_X)))
mstore(add(mPtr, 0x20), mload(add(state, STATE_FOLDED_DIGESTS_Y)))
mstore(add(mPtr, 0x40), calldataload(add(aproof, PROOF_BATCH_OPENING_AT_ZETA_X)))
mstore(add(mPtr, 0x60), calldataload(add(aproof, PROOF_BATCH_OPENING_AT_ZETA_Y)))
mstore(add(mPtr, 0x80), calldataload(add(aproof, PROOF_GRAND_PRODUCT_COMMITMENT_X)))
mstore(add(mPtr, 0xa0), calldataload(add(aproof, PROOF_GRAND_PRODUCT_COMMITMENT_Y)))
mstore(add(mPtr, 0xc0), calldataload(add(aproof, PROOF_OPENING_AT_ZETA_OMEGA_X)))
mstore(add(mPtr, 0xe0), calldataload(add(aproof, PROOF_OPENING_AT_ZETA_OMEGA_Y)))
mstore(add(mPtr, 0x100), mload(add(state, STATE_ZETA)))
mstore(add(mPtr, 0x120), mload(add(state, STATE_GAMMA_KZG)))
let random := staticcall(gas(), 0x2, mPtr, 0x140, mPtr, 0x20)
Workarounds
In the function batch_verify_multi_points, the variable random (corresponding to u in the paper, step 12 of the plonk verification process) should depend on state_folded_digests_x, state_folded_digests_y, proof_grand_product_commitment_x, proof_grand_product_commitment_y and state_zeta (by hashing those values for instance).
Impact
The vulnerability allows a third party to derive a valid proof from a valid initial tuple {proof, public_inputs}, corresponding to the same public inputs as the initial proof. It is due to a randomness being generated using a small part of the scratch memory describing the state, allowing for degrees of freedom in the transcript.
Note that the impact is limited to the PlonK verifier smart contract.
Patches
We still use a hash function on some data to have a pseudo rng, but instead of hashing the first 32 bytes of the state (
let random := mod(keccak256(state, 0x20), r_mod) )
we hash the whole state at this point of the verifier as if it was a Fiat Shamir transcript:
mstore(mPtr, mload(add(state, STATE_FOLDED_DIGESTS_X)))
mstore(add(mPtr, 0x20), mload(add(state, STATE_FOLDED_DIGESTS_Y)))
mstore(add(mPtr, 0x40), calldataload(add(aproof, PROOF_BATCH_OPENING_AT_ZETA_X)))
mstore(add(mPtr, 0x60), calldataload(add(aproof, PROOF_BATCH_OPENING_AT_ZETA_Y)))
mstore(add(mPtr, 0x80), calldataload(add(aproof, PROOF_GRAND_PRODUCT_COMMITMENT_X)))
mstore(add(mPtr, 0xa0), calldataload(add(aproof, PROOF_GRAND_PRODUCT_COMMITMENT_Y)))
mstore(add(mPtr, 0xc0), calldataload(add(aproof, PROOF_OPENING_AT_ZETA_OMEGA_X)))
mstore(add(mPtr, 0xe0), calldataload(add(aproof, PROOF_OPENING_AT_ZETA_OMEGA_Y)))
mstore(add(mPtr, 0x100), mload(add(state, STATE_ZETA)))
mstore(add(mPtr, 0x120), mload(add(state, STATE_GAMMA_KZG)))
let random := staticcall(gas(), 0x2, mPtr, 0x140, mPtr, 0x20)
Workarounds
In the function batch_verify_multi_points, the variable random (corresponding to u in the paper, step 12 of the plonk verification process) should depend on state_folded_digests_x, state_folded_digests_y, proof_grand_product_commitment_x, proof_grand_product_commitment_y and state_zeta (by hashing those values for instance).
References
- GHSA-7p92-x423-vwj6