dagger-contracts/contracts/verifiers/testing/verifier.sol

// SPDX-License-Identifier: GPL-3.0
/*
    Copyright 2021 0KIMS association.

    This file is generated with [snarkJS](https://github.com/iden3/snarkjs).

    snarkJS is a free software: you can redistribute it and/or modify it
    under the terms of the GNU General Public License as published by
    the Free Software Foundation, either version 3 of the License, or
    (at your option) any later version.

    snarkJS is distributed in the hope that it will be useful, but WITHOUT
    ANY WARRANTY; without even the implied warranty of MERCHANTABILITY
    or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public
    License for more details.

    You should have received a copy of the GNU General Public License
    along with snarkJS. If not, see <https://www.gnu.org/licenses/>.
*/

pragma solidity >=0.7.0 <0.9.0;

contract Groth16Verifier {
    // Scalar field size
    uint256 constant r = 21888242871839275222246405745257275088548364400416034343698204186575808495617;
    // Base field size
    uint256 constant q = 21888242871839275222246405745257275088696311157297823662689037894645226208583;

    // Verification Key data
    uint256 constant alphax = 20491192805390485299153009773594534940189261866228447918068658471970481763042;
    uint256 constant alphay = 9383485363053290200918347156157836566562967994039712273449902621266178545958;
    uint256 constant betax1 = 4252822878758300859123897981450591353533073413197771768651442665752259397132;
    uint256 constant betax2 = 6375614351688725206403948262868962793625744043794305715222011528459656738731;
    uint256 constant betay1 = 21847035105528745403288232691147584728191162732299865338377159692350059136679;
    uint256 constant betay2 = 10505242626370262277552901082094356697409835680220590971873171140371331206856;
    uint256 constant gammax1 = 11559732032986387107991004021392285783925812861821192530917403151452391805634;
    uint256 constant gammax2 = 10857046999023057135944570762232829481370756359578518086990519993285655852781;
    uint256 constant gammay1 = 4082367875863433681332203403145435568316851327593401208105741076214120093531;
    uint256 constant gammay2 = 8495653923123431417604973247489272438418190587263600148770280649306958101930;
    uint256 constant deltax1 = 13712868925708658085847556664366075488044104377560666483004097971457124593853;
    uint256 constant deltax2 = 10641155327113821350709388160714981167756198765458730005846188297891779189493;
    uint256 constant deltay1 = 17764386955997045623322956974738840392389044888308308825307170058332555991668;
    uint256 constant deltay2 = 11545289596289529089490468468326982998415255475081847246298663415914281403462;


    uint256 constant IC0x = 2685717341061384289974985759706305556965509240536260442727245444252129889599;
    uint256 constant IC0y = 21827535600902499280458695057256182457185285685995970634461174274051979800815;

    uint256 constant IC1x = 13158415194355348546090070151711085027834066488127676886518524272551654481129;
    uint256 constant IC1y = 18831701962118195025265682681702066674741422770850028135520336928884612556978;

    uint256 constant IC2x = 20882269691461568155321689204947751047717828445545223718893788782534717197527;
    uint256 constant IC2y = 11996193054822748526485644723594571195813487505803351159052936325857690315211;

    uint256 constant IC3x = 18155166643053044822201627105588517913195535693446564472247126736722594445000;
    uint256 constant IC3y = 13816319482622393060406816684195314200198627617641073470088058848129378231754;

    // Memory data
    uint16 constant pVk = 0;
    uint16 constant pPairing = 128;

    uint16 constant pLastMem = 896;

    function verifyProof(uint[2] calldata _pA, uint[2][2] calldata _pB, uint[2] calldata _pC, uint[3] calldata _pubSignals) public view returns (bool) {
        assembly {
            function checkField(v) {
                if iszero(lt(v, q)) {
                    mstore(0, 0)
                    return (0, 0x20)
                }
            }

        // G1 function to multiply a G1 value(x,y) to value in an address
            function g1_mulAccC(pR, x, y, s) {
                let success
                let mIn := mload(0x40)
                mstore(mIn, x)
                mstore(add(mIn, 32), y)
                mstore(add(mIn, 64), s)

                success := staticcall(sub(gas(), 2000), 7, mIn, 96, mIn, 64)

                if iszero(success) {
                    mstore(0, 0)
                    return (0, 0x20)
                }

                mstore(add(mIn, 64), mload(pR))
                mstore(add(mIn, 96), mload(add(pR, 32)))

                success := staticcall(sub(gas(), 2000), 6, mIn, 128, pR, 64)

                if iszero(success) {
                    mstore(0, 0)
                    return (0, 0x20)
                }
            }

            function checkPairing(pA, pB, pC, pubSignals, pMem) -> isOk {
                let _pPairing := add(pMem, pPairing)
                let _pVk := add(pMem, pVk)

                mstore(_pVk, IC0x)
                mstore(add(_pVk, 32), IC0y)

            // Compute the linear combination vk_x

                g1_mulAccC(_pVk, IC1x, IC1y, calldataload(add(pubSignals, 0)))

                g1_mulAccC(_pVk, IC2x, IC2y, calldataload(add(pubSignals, 32)))

                g1_mulAccC(_pVk, IC3x, IC3y, calldataload(add(pubSignals, 64)))

            // -A
                mstore(_pPairing, calldataload(pA))
                mstore(add(_pPairing, 32), mod(sub(q, calldataload(add(pA, 32))), q))

            // B
                mstore(add(_pPairing, 64), calldataload(pB))
                mstore(add(_pPairing, 96), calldataload(add(pB, 32)))
                mstore(add(_pPairing, 128), calldataload(add(pB, 64)))
                mstore(add(_pPairing, 160), calldataload(add(pB, 96)))

            // alpha1
                mstore(add(_pPairing, 192), alphax)
                mstore(add(_pPairing, 224), alphay)

            // beta2
                mstore(add(_pPairing, 256), betax1)
                mstore(add(_pPairing, 288), betax2)
                mstore(add(_pPairing, 320), betay1)
                mstore(add(_pPairing, 352), betay2)

            // vk_x
                mstore(add(_pPairing, 384), mload(add(pMem, pVk)))
                mstore(add(_pPairing, 416), mload(add(pMem, add(pVk, 32))))

            // gamma2
                mstore(add(_pPairing, 448), gammax1)
                mstore(add(_pPairing, 480), gammax2)
                mstore(add(_pPairing, 512), gammay1)
                mstore(add(_pPairing, 544), gammay2)

            // C
                mstore(add(_pPairing, 576), calldataload(pC))
                mstore(add(_pPairing, 608), calldataload(add(pC, 32)))

            // delta2
                mstore(add(_pPairing, 640), deltax1)
                mstore(add(_pPairing, 672), deltax2)
                mstore(add(_pPairing, 704), deltay1)
                mstore(add(_pPairing, 736), deltay2)


                let success := staticcall(sub(gas(), 2000), 8, _pPairing, 768, _pPairing, 0x20)

                isOk := and(success, mload(_pPairing))
            }

            let pMem := mload(0x40)
            mstore(0x40, add(pMem, pLastMem))

        // Validate that all evaluations ∈ F

            checkField(calldataload(add(_pubSignals, 0)))

            checkField(calldataload(add(_pubSignals, 32)))

            checkField(calldataload(add(_pubSignals, 64)))

            checkField(calldataload(add(_pubSignals, 96)))

        // Validate all evaluations
            let isValid := checkPairing(_pA, _pB, _pC, _pubSignals, pMem)

            mstore(0, isValid)
            return (0, 0x20)
        }
    }
}