ffade701ba
(cherry picked from commit 1fea8e0ef042d0e68e88e271fb7e79949a884a51)
241 lines
5.3 KiB
JavaScript
241 lines
5.3 KiB
JavaScript
const {unstringifyBigInts} = require("./stringifybigint.js");
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const fs = require("fs");
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const bigInt = require("big-integer");
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const assert = require("assert");
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const version = require("../package").version;
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const argv = require("yargs")
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.version(version)
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.usage(`node buildpkey.js -i "proving_key.json" -o "proving_key.bin"
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Default: circuit.json
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`)
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.alias("i", "input")
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.alias("o", "output")
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.help("h")
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.alias("h", "help")
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.epilogue(`Copyright (C) 2018 0kims association
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This program comes with ABSOLUTELY NO WARRANTY;
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This is free software, and you are welcome to redistribute it
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under certain conditions; see the COPYING file in the official
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repo directory at https://github.com/iden3/circom `)
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.argv;
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const inputName = (argv.input) ? argv.input : "proving_key.json";
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const outputName = (argv.output) ? argv.output : "proving_key.bin";
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const provingKey = unstringifyBigInts(JSON.parse(fs.readFileSync(inputName, "utf8")));
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function writeUint32(h, val) {
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h.dataView.setUint32(h.offset, val, true);
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h.offset += 4;
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}
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function writeUint32ToPointer(h, p, val) {
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h.dataView.setUint32(p, val, true);
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}
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function alloc(h, n) {
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const o = h.offset;
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h.offset += n;
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return o;
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}
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function writeBigInt(h, bi) {
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for (let i=0; i<8; i++) {
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const v = bi.shiftRight(i*32).and(0xFFFFFFFF).toJSNumber();
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writeUint32(h, v);
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}
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}
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function toMontgomeryQ(p) {
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const q = bigInt("21888242871839275222246405745257275088696311157297823662689037894645226208583");
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return p.times(bigInt.one.shiftLeft(256)).mod(q);
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}
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function toMontgomeryR(p) {
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const r = bigInt("21888242871839275222246405745257275088548364400416034343698204186575808495617");
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return p.times(bigInt.one.shiftLeft(256)).mod(r);
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}
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function writePoint(h, p) {
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writeBigInt(h, toMontgomeryQ(p[0]));
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writeBigInt(h, toMontgomeryQ(p[1]));
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}
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function writePoint2(h, p) {
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writeBigInt(h, toMontgomeryQ(p[0][0]));
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writeBigInt(h, toMontgomeryQ(p[0][1]));
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writeBigInt(h, toMontgomeryQ(p[1][0]));
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writeBigInt(h, toMontgomeryQ(p[1][1]));
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}
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function writeTransformedPolynomial(h, p) {
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const keys = Object.keys(p);
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writeUint32(h, keys.length);
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for (let i=0; i<keys.length; i++) {
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writeUint32(h, keys[i]);
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writeBigInt(h, toMontgomeryR(p[keys[i]]));
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}
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}
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function calculateBuffLen(provingKey) {
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function polSize(pol) {
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const l= Object.keys(pol).length;
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return 36*l + 4;
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}
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let size = 40;
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// alfa1, beta1, delta1
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size += 3 * (32*2);
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// beta2, delta2
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size += 2 * (32*4);
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for (let i=0; i<provingKey.nVars; i++) {
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size += polSize(provingKey.polsA[i]);
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size += polSize(provingKey.polsB[i]);
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}
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size += provingKey.nVars* (32*2);
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size += provingKey.nVars* (32*2);
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size += provingKey.nVars* (32*4);
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size += (provingKey.nVars - provingKey.nPublic - 1)* (32*2);
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size += (provingKey.domainSize - 1) * (32*2);
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return size;
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}
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const buffLen = calculateBuffLen(provingKey);
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const buff = new ArrayBuffer(buffLen);
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const h = {
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dataView: new DataView(buff),
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offset: 0
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};
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writeUint32(h, provingKey.nVars);
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writeUint32(h, provingKey.nPublic);
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writeUint32(h, provingKey.domainSize);
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const pPolsA = alloc(h, 4);
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const pPolsB = alloc(h, 4);
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const pPointsA = alloc(h, 4);
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const pPointsB1 = alloc(h, 4);
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const pPointsB2 = alloc(h, 4);
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const pPointsC = alloc(h, 4);
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const pPointsHExps = alloc(h, 4);
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writePoint(h, provingKey.vk_alfa_1);
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writePoint(h, provingKey.vk_beta_1);
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writePoint(h, provingKey.vk_delta_1);
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writePoint2(h, provingKey.vk_beta_2);
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writePoint2(h, provingKey.vk_delta_2);
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writeUint32ToPointer(h, pPolsA, h.offset);
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for (let i=0; i<provingKey.nVars; i++) {
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writeTransformedPolynomial(h, provingKey.polsA[i]);
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}
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writeUint32ToPointer(h, pPolsB, h.offset);
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for (let i=0; i<provingKey.nVars; i++) {
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writeTransformedPolynomial(h, provingKey.polsB[i]);
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}
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writeUint32ToPointer(h, pPointsA, h.offset);
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for (let i=0; i<provingKey.nVars; i++) {
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writePoint(h, provingKey.A[i]);
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}
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writeUint32ToPointer(h, pPointsB1, h.offset);
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for (let i=0; i<provingKey.nVars; i++) {
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writePoint(h, provingKey.B1[i]);
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}
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writeUint32ToPointer(h, pPointsB2, h.offset);
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for (let i=0; i<provingKey.nVars; i++) {
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writePoint2(h, provingKey.B2[i]);
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}
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writeUint32ToPointer(h, pPointsC, h.offset);
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for (let i=provingKey.nPublic+1; i<provingKey.nVars; i++) {
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writePoint(h, provingKey.C[i]);
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}
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writeUint32ToPointer(h, pPointsHExps, h.offset);
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for (let i=0; i<provingKey.domainSize - 1; i++) {
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writePoint(h, provingKey.hExps[i]);
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}
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assert.equal(h.offset, buffLen);
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var wstream = fs.createWriteStream(outputName);
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wstream.write(Buffer.from(buff));
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wstream.end();
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/*
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NSignals
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NPublic
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DomainSize (2 multiple)
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pPolsA
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pPolsB
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pPointsA
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pPointsB1
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pPointsB2
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pPointsC
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pPointsHExps
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Alfa1
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Beta1
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Delta1
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Beta2
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Delta2
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PolinomialA_0
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PolinomialA_1
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PolinomialA_2
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...
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PolinomialA_NVars-1
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PolinomialB_0
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PolinomialB_1
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PolinomialB_2
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...
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PolinomialB_NVars-1
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PointA_0
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PointA_1
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...
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PointA_NVars-1
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PointB1_0
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PointB1_1
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...
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PointB1_NVars-1
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PointB2_0
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PointB2_1
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...
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PointB2_NVars-1
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PointC_nPublics+1
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PointC_nPublics+2
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...
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PointC_nPublics+NVars
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PointHExp_0
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PointHExp_1
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...
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PointHExp_DomainSize-1
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*/
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