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97ac985a1b
snarkjs/build/main.cjs
Jordi Baylina 97ac985a1b
Big ptau verification
2020-08-29 14:12:24 +02:00

6178 lines
197 KiB
JavaScript
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'use strict';
Object.defineProperty(exports, '__esModule', { value: true });
function _interopDefault (ex) { return (ex && (typeof ex === 'object') && 'default' in ex) ? ex['default'] : ex; }
var ffjavascript = require('ffjavascript');
var fs = _interopDefault(require('fs'));
var Blake2b = _interopDefault(require('blake2b-wasm'));
var readline = _interopDefault(require('readline'));
var crypto = _interopDefault(require('crypto'));
var circomRuntime = _interopDefault(require('circom_runtime'));
async function open(fileName, openFlags, cacheSize, pageSize) {
cacheSize = cacheSize || 4096*64;
if (["w+", "wx+", "r", "ax+", "a+"].indexOf(openFlags) <0)
throw new Error("Invalid open option");
const fd =await fs.promises.open(fileName, openFlags);
const stats = await fd.stat();
return new FastFile(fd, stats, cacheSize, pageSize, fileName);
}
const tmpBuff32 = new Uint8Array(4);
const tmpBuff32v = new DataView(tmpBuff32.buffer);
const tmpBuff64 = new Uint8Array(8);
const tmpBuff64v = new DataView(tmpBuff64.buffer);
class FastFile {
constructor(fd, stats, cacheSize, pageSize, fileName) {
this.fileName = fileName;
this.fd = fd;
this.pos = 0;
this.pageSize = pageSize || (1 << 8);
while (this.pageSize < stats.blksize*4) {
this.pageSize *= 2;
}
this.totalSize = stats.size;
this.totalPages = Math.floor((stats.size -1) / this.pageSize)+1;
this.maxPagesLoaded = Math.floor( cacheSize / this.pageSize)+1;
this.pages = {};
this.pendingLoads = [];
this.writing = false;
this.reading = false;
}
_loadPage(p) {
const self = this;
return new Promise((resolve, reject)=> {
self.pendingLoads.push({
page: p,
resolve: resolve,
reject: reject
});
setImmediate(self._triggerLoad.bind(self));
});
}
_triggerLoad() {
const self = this;
processPendingLoads();
if (self.pendingLoads.length == 0) return;
if (Object.keys(self.pages).length >= self.maxPagesLoaded) {
const dp = getDeletablePage();
if (dp<0) { // // No sizes available
// setTimeout(self._triggerLoad.bind(self), 10000);
return;
}
delete self.pages[dp];
}
const load = self.pendingLoads.shift();
if (load.page>=self.totalPages) {
self.pages[load.page] = {
dirty: false,
buff: new Uint8Array(self.pageSize),
pendingOps: 1,
size: 0
};
load.resolve();
setImmediate(self._triggerLoad.bind(self));
return;
}
if (self.reading) {
self.pendingLoads.unshift(load);
return; // Only one read at a time.
}
self.reading = true;
const page = {
dirty: false,
buff: new Uint8Array(self.pageSize),
pendingOps: 1,
size: 0
};
self.fd.read(page.buff, 0, self.pageSize, load.page*self.pageSize).then((res)=> {
page.size = res.bytesRead;
self.pages[load.page] = page;
self.reading = false;
load.resolve();
setImmediate(self._triggerLoad.bind(self));
}, (err) => {
load.reject(err);
});
function processPendingLoads() {
const newPendingLoads = [];
for (let i=0; i<self.pendingLoads.length; i++) {
const load = self.pendingLoads[i];
if (typeof self.pages[load.page] != "undefined") {
self.pages[load.page].pendingOps ++;
load.resolve();
} else {
newPendingLoads.push(load);
}
}
self.pendingLoads = newPendingLoads;
}
function getDeletablePage() {
for (let p in self.pages) {
const page = self.pages[p];
if ((page.dirty == false)&&(page.pendingOps==0)) return p;
}
return -1;
}
}
_triggerWrite() {
const self = this;
if (self.writing) return;
const p = self._getDirtyPage();
if (p<0) {
if (self.pendingClose) self.pendingClose();
return;
}
self.writing=true;
self.pages[p].dirty = false;
self.fd.write(self.pages[p].buff, 0, self.pages[p].size, p*self.pageSize).then(() => {
self.writing = false;
setImmediate(self._triggerWrite.bind(self));
setImmediate(self._triggerLoad.bind(self));
}, (err) => {
console.log("ERROR Writing: "+err);
self.error = err;
self._tryClose();
});
}
_getDirtyPage() {
for (let p in this.pages) {
if (this.pages[p].dirty) return p;
}
return -1;
}
async write(buff, pos) {
if (buff.byteLength == 0) return;
const self = this;
/*
if (buff.byteLength > self.pageSize*self.maxPagesLoaded*0.8) {
const cacheSize = Math.floor(buff.byteLength * 1.1);
this.maxPagesLoaded = Math.floor( cacheSize / self.pageSize)+1;
}
*/
if (typeof pos == "undefined") pos = self.pos;
self.pos = pos+buff.byteLength;
if (self.totalSize < pos + buff.byteLength) self.totalSize = pos + buff.byteLength;
if (self.pendingClose)
throw new Error("Writing a closing file");
const firstPage = Math.floor(pos / self.pageSize);
// for (let i=firstPage; i<=lastPage; i++) await self._loadPage(i);
let p = firstPage;
let o = pos % self.pageSize;
let r = buff.byteLength;
while (r>0) {
await self._loadPage(p);
const l = (o+r > self.pageSize) ? (self.pageSize -o) : r;
const srcView = new Uint8Array(buff.buffer, buff.byteLength - r, l);
const dstView = new Uint8Array(self.pages[p].buff.buffer, o, l);
dstView.set(srcView);
self.pages[p].dirty = true;
self.pages[p].pendingOps --;
self.pages[p].size = Math.max(o+l, self.pages[p].size);
if (p>=self.totalPages) {
self.totalPages = p+1;
}
r = r-l;
p ++;
o = 0;
setImmediate(self._triggerWrite.bind(self));
}
}
async read(len, pos) {
const self = this;
let buff = new Uint8Array(len);
await self.readToBuffer(buff, 0, len, pos);
return buff;
}
async readToBuffer(buffDst, offset, len, pos) {
if (len == 0) {
return;
}
const self = this;
if (len > self.pageSize*self.maxPagesLoaded*0.8) {
const cacheSize = Math.floor(len * 1.1);
this.maxPagesLoaded = Math.floor( cacheSize / self.pageSize)+1;
}
if (typeof pos == "undefined") pos = self.pos;
self.pos = pos+len;
if (self.pendingClose)
throw new Error("Reading a closing file");
const firstPage = Math.floor(pos / self.pageSize);
let p = firstPage;
let o = pos % self.pageSize;
// Remaining bytes to read
let r = pos + len > self.totalSize ? len - (pos + len - self.totalSize): len;
while (r>0) {
await self._loadPage(p);
// bytes to copy from this page
const l = (o+r > self.pageSize) ? (self.pageSize -o) : r;
const srcView = new Uint8Array(self.pages[p].buff.buffer, o, l);
buffDst.set(srcView, offset+len-r);
self.pages[p].pendingOps --;
r = r-l;
p ++;
o = 0;
setImmediate(self._triggerLoad.bind(self));
}
this.pos = pos + len;
}
_tryClose() {
const self = this;
if (!self.pendingClose) return;
if (self.error) {
self.pendingCloseReject(self.error);
}
const p = self._getDirtyPage();
if ((p>=0) || (self.writing) || (self.reading) || (self.pendingLoads.length>0)) return;
self.pendingClose();
}
close() {
const self = this;
if (self.pendingClose)
throw new Error("Closing the file twice");
return new Promise((resolve, reject) => {
self.pendingClose = resolve;
self.pendingCloseReject = reject;
self._tryClose();
}).then(()=> {
self.fd.close();
}, (err) => {
self.fd.close();
throw (err);
});
}
async discard() {
const self = this;
await self.close();
await fs.promises.unlink(this.fileName);
}
async writeULE32(v, pos) {
const self = this;
tmpBuff32v.setUint32(0, v, true);
await self.write(tmpBuff32, pos);
}
async writeUBE32(v, pos) {
const self = this;
tmpBuff32v.setUint32(0, v, false);
await self.write(tmpBuff32, pos);
}
async writeULE64(v, pos) {
const self = this;
tmpBuff64v.setUint32(0, v & 0xFFFFFFFF, true);
tmpBuff64v.setUint32(4, Math.floor(v / 0x100000000) , true);
await self.write(tmpBuff64, pos);
}
async readULE32(pos) {
const self = this;
const b = await self.read(4, pos);
const view = new Uint32Array(b.buffer);
return view[0];
}
async readUBE32(pos) {
const self = this;
const b = await self.read(4, pos);
const view = new DataView(b.buffer);
return view.getUint32(0, false);
}
async readULE64(pos) {
const self = this;
const b = await self.read(8, pos);
const view = new Uint32Array(b.buffer);
return view[1] * 0x100000000 + view[0];
}
}
function createNew(o) {
const initialSize = o.initialSize || 1<<20;
const fd = new MemFile();
fd.o = o;
fd.o.data = new Uint8Array(initialSize);
fd.allocSize = initialSize;
fd.totalSize = 0;
fd.readOnly = false;
fd.pos = 0;
return fd;
}
function readExisting(o) {
const fd = new MemFile();
fd.o = o;
fd.allocSize = o.data.byteLength;
fd.totalSize = o.data.byteLength;
fd.readOnly = true;
fd.pos = 0;
return fd;
}
const tmpBuff32$1 = new Uint8Array(4);
const tmpBuff32v$1 = new DataView(tmpBuff32$1.buffer);
const tmpBuff64$1 = new Uint8Array(8);
const tmpBuff64v$1 = new DataView(tmpBuff64$1.buffer);
class MemFile {
constructor() {
this.pageSize = 1 << 14; // for compatibility
}
_resizeIfNeeded(newLen) {
if (newLen > this.allocSize) {
const newAllocSize = Math.max(
this.allocSize + (1 << 20),
Math.floor(this.allocSize * 1.1),
newLen
);
const newData = new Uint8Array(newAllocSize);
newData.set(this.o.data);
this.o.data = newData;
this.allocSize = newAllocSize;
}
}
async write(buff, pos) {
const self =this;
if (typeof pos == "undefined") pos = self.pos;
if (this.readOnly) throw new Error("Writing a read only file");
this._resizeIfNeeded(pos + buff.byteLength);
this.o.data.set(buff, pos);
if (pos + buff.byteLength > this.totalSize) this.totalSize = pos + buff.byteLength;
this.pos = pos + buff.byteLength;
}
async readToBuffer(buffDest, offset, len, pos) {
const self = this;
if (typeof pos == "undefined") pos = self.pos;
if (this.readOnly) {
if (pos + len > this.totalSize) throw new Error("Reading out of bounds");
}
this._resizeIfNeeded(pos + len);
const buffSrc = new Uint8Array(this.o.data.buffer, this.o.data.byteOffset + pos, len);
buffDest.set(buffSrc, offset);
this.pos = pos + len;
}
async read(len, pos) {
const self = this;
const buff = new Uint8Array(len);
await self.readToBuffer(buff, 0, len, pos);
return buff;
}
close() {
if (this.o.data.byteLength != this.totalSize) {
this.o.data = this.o.data.slice(0, this.totalSize);
}
}
async discard() {
}
async writeULE32(v, pos) {
const self = this;
tmpBuff32v$1.setUint32(0, v, true);
await self.write(tmpBuff32$1, pos);
}
async writeUBE32(v, pos) {
const self = this;
tmpBuff32v$1.setUint32(0, v, false);
await self.write(tmpBuff32$1, pos);
}
async writeULE64(v, pos) {
const self = this;
tmpBuff64v$1.setUint32(0, v & 0xFFFFFFFF, true);
tmpBuff64v$1.setUint32(4, Math.floor(v / 0x100000000) , true);
await self.write(tmpBuff64$1, pos);
}
async readULE32(pos) {
const self = this;
const b = await self.read(4, pos);
const view = new Uint32Array(b.buffer);
return view[0];
}
async readUBE32(pos) {
const self = this;
const b = await self.read(4, pos);
const view = new DataView(b.buffer);
return view.getUint32(0, false);
}
async readULE64(pos) {
const self = this;
const b = await self.read(8, pos);
const view = new Uint32Array(b.buffer);
return view[1] * 0x100000000 + view[0];
}
}
const PAGE_SIZE = 1<<22;
function createNew$1(o) {
const initialSize = o.initialSize || 0;
const fd = new BigMemFile();
fd.o = o;
const nPages = initialSize ? Math.floor((initialSize - 1) / PAGE_SIZE)+1 : 0;
fd.o.data = [];
for (let i=0; i<nPages-1; i++) {
fd.o.data.push( new Uint8Array(PAGE_SIZE));
}
if (nPages) fd.o.data.push( new Uint8Array(initialSize - PAGE_SIZE*(nPages-1)));
fd.totalSize = 0;
fd.readOnly = false;
fd.pos = 0;
return fd;
}
function readExisting$1(o) {
const fd = new BigMemFile();
fd.o = o;
fd.totalSize = (o.data.length-1)* PAGE_SIZE + o.data[o.data.length-1].byteLength;
fd.readOnly = true;
fd.pos = 0;
return fd;
}
const tmpBuff32$2 = new Uint8Array(4);
const tmpBuff32v$2 = new DataView(tmpBuff32$2.buffer);
const tmpBuff64$2 = new Uint8Array(8);
const tmpBuff64v$2 = new DataView(tmpBuff64$2.buffer);
class BigMemFile {
constructor() {
this.pageSize = 1 << 14; // for compatibility
}
_resizeIfNeeded(newLen) {
if (newLen <= this.totalSize) return;
if (this.readOnly) throw new Error("Reading out of file bounds");
const nPages = Math.floor((newLen - 1) / PAGE_SIZE)+1;
for (let i= Math.max(this.o.data.length-1, 0); i<nPages; i++) {
const newSize = i<nPages-1 ? PAGE_SIZE : newLen - (nPages-1)*PAGE_SIZE;
const p = new Uint8Array(newSize);
if (i == this.o.data.length-1) p.set(this.o.data[i]);
this.o.data[i] = p;
}
this.totalSize = newLen;
}
async write(buff, pos) {
const self =this;
if (typeof pos == "undefined") pos = self.pos;
if (this.readOnly) throw new Error("Writing a read only file");
this._resizeIfNeeded(pos + buff.byteLength);
const firstPage = Math.floor(pos / PAGE_SIZE);
let p = firstPage;
let o = pos % PAGE_SIZE;
let r = buff.byteLength;
while (r>0) {
const l = (o+r > PAGE_SIZE) ? (PAGE_SIZE -o) : r;
const srcView = new Uint8Array(buff.buffer, buff.byteLength - r, l);
const dstView = new Uint8Array(self.o.data[p].buffer, o, l);
dstView.set(srcView);
r = r-l;
p ++;
o = 0;
}
this.pos = pos + buff.byteLength;
}
async readToBuffer(buffDst, offset, len, pos) {
const self = this;
if (typeof pos == "undefined") pos = self.pos;
if (this.readOnly) {
if (pos + len > this.totalSize) throw new Error("Reading out of bounds");
}
this._resizeIfNeeded(pos + len);
const firstPage = Math.floor(pos / PAGE_SIZE);
let p = firstPage;
let o = pos % PAGE_SIZE;
// Remaining bytes to read
let r = len;
while (r>0) {
// bytes to copy from this page
const l = (o+r > PAGE_SIZE) ? (PAGE_SIZE -o) : r;
const srcView = new Uint8Array(self.o.data[p].buffer, o, l);
buffDst.set(srcView, offset+len-r);
r = r-l;
p ++;
o = 0;
}
this.pos = pos + len;
}
async read(len, pos) {
const self = this;
const buff = new Uint8Array(len);
await self.readToBuffer(buff, 0, len, pos);
return buff;
}
close() {
}
async discard() {
}
async writeULE32(v, pos) {
const self = this;
tmpBuff32v$2.setUint32(0, v, true);
await self.write(tmpBuff32$2, pos);
}
async writeUBE32(v, pos) {
const self = this;
tmpBuff32v$2.setUint32(0, v, false);
await self.write(tmpBuff32$2, pos);
}
async writeULE64(v, pos) {
const self = this;
tmpBuff64v$2.setUint32(0, v & 0xFFFFFFFF, true);
tmpBuff64v$2.setUint32(4, Math.floor(v / 0x100000000) , true);
await self.write(tmpBuff64$2, pos);
}
async readULE32(pos) {
const self = this;
const b = await self.read(4, pos);
const view = new Uint32Array(b.buffer);
return view[0];
}
async readUBE32(pos) {
const self = this;
const b = await self.read(4, pos);
const view = new DataView(b.buffer);
return view.getUint32(0, false);
}
async readULE64(pos) {
const self = this;
const b = await self.read(8, pos);
const view = new Uint32Array(b.buffer);
return view[1] * 0x100000000 + view[0];
}
}
/* global fetch */
async function createOverride(o, b, c) {
if (typeof o === "string") {
o = {
type: "file",
fileName: o,
cacheSize: b,
pageSize: c
};
}
if (o.type == "file") {
return await open(o.fileName, "w+", o.cacheSize, o.pageSize);
} else if (o.type == "mem") {
return createNew(o);
} else if (o.type == "bigMem") {
return createNew$1(o);
} else {
throw new Error("Invalid FastFile type: "+o.type);
}
}
async function readExisting$2(o, b, c) {
if (o instanceof Uint8Array) {
o = {
type: "mem",
data: o
};
}
if (process.browser) {
if (typeof o === "string") {
const buff = await fetch(o).then( function(res) {
return res.arrayBuffer();
}).then(function (ab) {
return new Uint8Array(ab);
});
o = {
type: "mem",
data: buff
};
}
} else {
if (typeof o === "string") {
o = {
type: "file",
fileName: o,
cacheSize: b,
pageSize: c || (1 << 24)
};
}
}
if (o.type == "file") {
return await open(o.fileName, "r", o.cacheSize, o.pageSize);
} else if (o.type == "mem") {
return await readExisting(o);
} else if (o.type == "bigMem") {
return await readExisting$1(o);
} else {
throw new Error("Invalid FastFile type: "+o.type);
}
}
async function readBinFile(fileName, type, maxVersion) {
const fd = await readExisting$2(fileName);
const b = await fd.read(4);
let readedType = "";
for (let i=0; i<4; i++) readedType += String.fromCharCode(b[i]);
if (readedType != type) throw new Error(fileName + ": Invalid File format");
let v = await fd.readULE32();
if (v>maxVersion) throw new Error("Version not supported");
const nSections = await fd.readULE32();
// Scan sections
let sections = [];
for (let i=0; i<nSections; i++) {
let ht = await fd.readULE32();
let hl = await fd.readULE64();
if (typeof sections[ht] == "undefined") sections[ht] = [];
sections[ht].push({
p: fd.pos,
size: hl
});
fd.pos += hl;
}
return {fd, sections};
}
async function createBinFile(fileName, type, version, nSections) {
const fd = await createOverride(fileName);
const buff = new Uint8Array(4);
for (let i=0; i<4; i++) buff[i] = type.charCodeAt(i);
await fd.write(buff, 0); // Magic "r1cs"
await fd.writeULE32(version); // Version
await fd.writeULE32(nSections); // Number of Sections
return fd;
}
async function startWriteSection(fd, idSection) {
if (typeof fd.writingSection !== "undefined") throw new Error("Already writing a section");
await fd.writeULE32(idSection); // Header type
fd.writingSection = {
pSectionSize: fd.pos
};
await fd.writeULE64(0); // Temporally set to 0 length
}
async function endWriteSection(fd) {
if (typeof fd.writingSection === "undefined") throw new Error("Not writing a section");
const sectionSize = fd.pos - fd.writingSection.pSectionSize - 8;
const oldPos = fd.pos;
fd.pos = fd.writingSection.pSectionSize;
await fd.writeULE64(sectionSize);
fd.pos = oldPos;
delete fd.writingSection;
}
async function startReadUniqueSection(fd, sections, idSection) {
if (typeof fd.readingSection !== "undefined") throw new Error("Already reading a section");
if (!sections[idSection]) throw new Error(fd.fileName + ": Missing section "+ idSection );
if (sections[idSection].length>1) throw new Error(fd.fileName +": Section Duplicated " +idSection);
fd.pos = sections[idSection][0].p;
fd.readingSection = sections[idSection][0];
}
async function endReadSection(fd, noCheck) {
if (typeof fd.readingSection === "undefined") throw new Error("Not reading a section");
if (!noCheck) {
if (fd.pos-fd.readingSection.p != fd.readingSection.size) throw new Error("Invalid section size reading");
}
delete fd.readingSection;
}
async function writeBigInt(fd, n, n8, pos) {
const buff = new Uint8Array(n8);
ffjavascript.Scalar.toRprLE(buff, 0, n, n8);
await fd.write(buff, pos);
}
async function readBigInt(fd, n8, pos) {
const buff = await fd.read(n8, pos);
return ffjavascript.Scalar.fromRprLE(buff, 0, n8);
}
async function copySection(fdFrom, sections, fdTo, sectionId) {
const chunkSize = fdFrom.pageSize;
await startReadUniqueSection(fdFrom, sections, sectionId);
await startWriteSection(fdTo, sectionId);
for (let p=0; p<sections[sectionId][0].size; p+=chunkSize) {
const l = Math.min(sections[sectionId][0].size -p, chunkSize);
const buff = await fdFrom.read(l);
await fdTo.write(buff);
}
await endWriteSection(fdTo);
await endReadSection(fdFrom);
}
async function readFullSection(fd, sections, idSection) {
await startReadUniqueSection(fd, sections, idSection);
const res = await fd.read(fd.readingSection.size);
await endReadSection(fd);
return res;
}
async function sectionIsEqual(fd1, sections1, fd2, sections2, idSection) {
const MAX_BUFF_SIZE = fd1.pageSize * 16;
await startReadUniqueSection(fd1, sections1, idSection);
await startReadUniqueSection(fd2, sections2, idSection);
if (sections1[idSection][0].size != sections2[idSection][0].size) return false;
const totalBytes=sections1[idSection][0].size;
for (let i=0; i<totalBytes; i+= MAX_BUFF_SIZE) {
const n = Math.min(totalBytes-i, MAX_BUFF_SIZE);
const buff1 = await fd1.read(n);
const buff2 = await fd2.read(n);
for (let j=0; j<n; j++) if (buff1[j] != buff2[j]) return false;
}
await endReadSection(fd1);
await endReadSection(fd2);
return true;
}
const bls12381r = ffjavascript.Scalar.e("73eda753299d7d483339d80809a1d80553bda402fffe5bfeffffffff00000001", 16);
const bn128r = ffjavascript.Scalar.e("21888242871839275222246405745257275088548364400416034343698204186575808495617");
const bls12381q = ffjavascript.Scalar.e("1a0111ea397fe69a4b1ba7b6434bacd764774b84f38512bf6730d2a0f6b0f6241eabfffeb153ffffb9feffffffffaaab", 16);
const bn128q = ffjavascript.Scalar.e("21888242871839275222246405745257275088696311157297823662689037894645226208583");
async function getCurveFromQ(q) {
let curve;
if (ffjavascript.Scalar.eq(q, bn128q)) {
curve = await ffjavascript.buildBn128();
} else if (ffjavascript.Scalar.eq(q, bls12381q)) {
curve = await ffjavascript.buildBls12381();
} else {
throw new Error(`Curve not supported: ${ffjavascript.Scalar.toString(q)}`);
}
return curve;
}
async function getCurveFromName(name) {
let curve;
const normName = normalizeName(name);
if (["BN128", "BN254", "ALTBN128"].indexOf(normName) >= 0) {
curve = await ffjavascript.buildBn128();
} else if (["BLS12381"].indexOf(normName) >= 0) {
curve = await ffjavascript.buildBls12381();
} else {
throw new Error(`Curve not supported: ${name}`);
}
return curve;
function normalizeName(n) {
return n.toUpperCase().match(/[A-Za-z0-9]+/g).join("");
}
}
/* global window */
const _revTable = [];
for (let i=0; i<256; i++) {
_revTable[i] = _revSlow(i, 8);
}
function _revSlow(idx, bits) {
let res =0;
let a = idx;
for (let i=0; i<bits; i++) {
res <<= 1;
res = res | (a &1);
a >>=1;
}
return res;
}
function bitReverse(idx, bits) {
return (
_revTable[idx >>> 24] |
(_revTable[(idx >>> 16) & 0xFF] << 8) |
(_revTable[(idx >>> 8) & 0xFF] << 16) |
(_revTable[idx & 0xFF] << 24)
) >>> (32-bits);
}
function log2( V )
{
return( ( ( V & 0xFFFF0000 ) !== 0 ? ( V &= 0xFFFF0000, 16 ) : 0 ) | ( ( V & 0xFF00FF00 ) !== 0 ? ( V &= 0xFF00FF00, 8 ) : 0 ) | ( ( V & 0xF0F0F0F0 ) !== 0 ? ( V &= 0xF0F0F0F0, 4 ) : 0 ) | ( ( V & 0xCCCCCCCC ) !== 0 ? ( V &= 0xCCCCCCCC, 2 ) : 0 ) | ( ( V & 0xAAAAAAAA ) !== 0 ) );
}
function formatHash(b, title) {
const a = new DataView(b.buffer, b.byteOffset, b.byteLength);
let S = "";
for (let i=0; i<4; i++) {
if (i>0) S += "\n";
S += "\t\t";
for (let j=0; j<4; j++) {
if (j>0) S += " ";
S += a.getUint32(i*16+j*4).toString(16).padStart(8, "0");
}
}
if (title) S = title + "\n" + S;
return S;
}
function hashIsEqual(h1, h2) {
if (h1.byteLength != h2.byteLength) return false;
var dv1 = new Int8Array(h1);
var dv2 = new Int8Array(h2);
for (var i = 0 ; i != h1.byteLength ; i++)
{
if (dv1[i] != dv2[i]) return false;
}
return true;
}
function cloneHasher(h) {
const ph = h.getPartialHash();
const res = Blake2b(64);
res.setPartialHash(ph);
return res;
}
async function sameRatio(curve, g1s, g1sx, g2s, g2sx) {
if (curve.G1.isZero(g1s)) return false;
if (curve.G1.isZero(g1sx)) return false;
if (curve.G2.isZero(g2s)) return false;
if (curve.G2.isZero(g2sx)) return false;
// return curve.F12.eq(curve.pairing(g1s, g2sx), curve.pairing(g1sx, g2s));
const res = await curve.pairingEq(g1s, g2sx, curve.G1.neg(g1sx), g2s);
return res;
}
function askEntropy() {
if (process.browser) {
return window.prompt("Enter a random text. (Entropy): ", "");
} else {
const rl = readline.createInterface({
input: process.stdin,
output: process.stdout
});
return new Promise((resolve) => {
rl.question("Enter a random text. (Entropy): ", (input) => resolve(input) );
});
}
}
async function getRandomRng(entropy) {
// Generate a random Rng
while (!entropy) {
entropy = await askEntropy();
}
const hasher = Blake2b(64);
hasher.update(crypto.randomBytes(64));
const enc = new TextEncoder(); // always utf-8
hasher.update(enc.encode(entropy));
const hash = Buffer.from(hasher.digest());
const seed = [];
for (let i=0;i<8;i++) {
seed[i] = hash.readUInt32BE(i*4);
}
const rng = new ffjavascript.ChaCha(seed);
return rng;
}
function rngFromBeaconParams(beaconHash, numIterationsExp) {
let nIterationsInner;
let nIterationsOuter;
if (numIterationsExp<32) {
nIterationsInner = (1 << numIterationsExp) >>> 0;
nIterationsOuter = 1;
} else {
nIterationsInner = 0x100000000;
nIterationsOuter = (1 << (numIterationsExp-32)) >>> 0;
}
let curHash = beaconHash;
for (let i=0; i<nIterationsOuter; i++) {
for (let j=0; j<nIterationsInner; j++) {
curHash = crypto.createHash("sha256").update(curHash).digest();
}
}
const curHashV = new DataView(curHash.buffer, curHash.byteOffset, curHash.byteLength);
const seed = [];
for (let i=0; i<8; i++) {
seed[i] = curHashV.getUint32(i*4, false);
}
const rng = new ffjavascript.ChaCha(seed);
return rng;
}
function hex2ByteArray(s) {
if (s instanceof Uint8Array) return s;
if (s.slice(0,2) == "0x") s= s.slice(2);
return new Uint8Array(s.match(/[\da-f]{2}/gi).map(function (h) {
return parseInt(h, 16);
}));
}
function byteArray2hex(byteArray) {
return Array.prototype.map.call(byteArray, function(byte) {
return ("0" + (byte & 0xFF).toString(16)).slice(-2);
}).join("");
}
async function writeHeader(fd, zkey) {
// Write the header
///////////
await startWriteSection(fd, 1);
await fd.writeULE32(1); // Groth
await endWriteSection(fd);
// Write the Groth header section
///////////
const curve = await getCurveFromQ(zkey.q);
await startWriteSection(fd, 2);
const primeQ = curve.q;
const n8q = (Math.floor( (ffjavascript.Scalar.bitLength(primeQ) - 1) / 64) +1)*8;
const primeR = curve.r;
const n8r = (Math.floor( (ffjavascript.Scalar.bitLength(primeR) - 1) / 64) +1)*8;
await fd.writeULE32(n8q);
await writeBigInt(fd, primeQ, n8q);
await fd.writeULE32(n8r);
await writeBigInt(fd, primeR, n8r);
await fd.writeULE32(zkey.nVars); // Total number of bars
await fd.writeULE32(zkey.nPublic); // Total number of public vars (not including ONE)
await fd.writeULE32(zkey.domainSize); // domainSize
await writeG1(fd, curve, zkey.vk_alpha_1);
await writeG1(fd, curve, zkey.vk_beta_1);
await writeG2(fd, curve, zkey.vk_beta_2);
await writeG2(fd, curve, zkey.vk_gamma_2);
await writeG1(fd, curve, zkey.vk_delta_1);
await writeG2(fd, curve, zkey.vk_delta_2);
await endWriteSection(fd);
}
async function writeG1(fd, curve, p) {
const buff = new Uint8Array(curve.G1.F.n8*2);
curve.G1.toRprLEM(buff, 0, p);
await fd.write(buff);
}
async function writeG2(fd, curve, p) {
const buff = new Uint8Array(curve.G2.F.n8*2);
curve.G2.toRprLEM(buff, 0, p);
await fd.write(buff);
}
async function readG1(fd, curve) {
const buff = await fd.read(curve.G1.F.n8*2);
return curve.G1.fromRprLEM(buff, 0);
}
async function readG2(fd, curve) {
const buff = await fd.read(curve.G2.F.n8*2);
return curve.G2.fromRprLEM(buff, 0);
}
async function readHeader(fd, sections, protocol) {
if (protocol != "groth16") throw new Error("Protocol not supported: "+protocol);
const zkey = {};
// Read Header
/////////////////////
await startReadUniqueSection(fd, sections, 1);
const protocolId = await fd.readULE32();
if (protocolId != 1) throw new Error("File is not groth");
zkey.protocol = "groth16";
await endReadSection(fd);
// Read Groth Header
/////////////////////
await startReadUniqueSection(fd, sections, 2);
const n8q = await fd.readULE32();
zkey.n8q = n8q;
zkey.q = await readBigInt(fd, n8q);
const n8r = await fd.readULE32();
zkey.n8r = n8r;
zkey.r = await readBigInt(fd, n8r);
let curve = await getCurveFromQ(zkey.q);
zkey.nVars = await fd.readULE32();
zkey.nPublic = await fd.readULE32();
zkey.domainSize = await fd.readULE32();
zkey.power = log2(zkey.domainSize);
zkey.vk_alpha_1 = await readG1(fd, curve);
zkey.vk_beta_1 = await readG1(fd, curve);
zkey.vk_beta_2 = await readG2(fd, curve);
zkey.vk_gamma_2 = await readG2(fd, curve);
zkey.vk_delta_1 = await readG1(fd, curve);
zkey.vk_delta_2 = await readG2(fd, curve);
await endReadSection(fd);
return zkey;
}
async function readZKey(fileName) {
const {fd, sections} = await readBinFile(fileName, "zkey", 1);
const zkey = await readHeader(fd, sections, "groth16");
const Fr = new ffjavascript.F1Field(zkey.r);
const Rr = ffjavascript.Scalar.mod(ffjavascript.Scalar.shl(1, zkey.n8r*8), zkey.r);
const Rri = Fr.inv(Rr);
const Rri2 = Fr.mul(Rri, Rri);
let curve = getCurveFromQ(zkey.q);
// Read IC Section
///////////
await startReadUniqueSection(fd, sections, 3);
zkey.IC = [];
for (let i=0; i<= zkey.nPublic; i++) {
const P = await readG1(fd, curve);
zkey.IC.push(P);
}
await endReadSection(fd);
// Read Coefs
///////////
await startReadUniqueSection(fd, sections, 4);
const nCCoefs = await fd.readULE32();
zkey.ccoefs = [];
for (let i=0; i<nCCoefs; i++) {
const m = await fd.readULE32();
const c = await fd.readULE32();
const s = await fd.readULE32();
const v = await readFr2();
zkey.ccoefs.push({
matrix: m,
constraint: c,
signal: s,
value: v
});
}
await endReadSection(fd);
// Read A points
///////////
await startReadUniqueSection(fd, sections, 5);
zkey.A = [];
for (let i=0; i<zkey.nVars; i++) {
const A = await readG1(fd, curve);
zkey.A[i] = A;
}
await endReadSection(fd);
// Read B1
///////////
await startReadUniqueSection(fd, sections, 6);
zkey.B1 = [];
for (let i=0; i<zkey.nVars; i++) {
const B1 = await readG1(fd, curve);
zkey.B1[i] = B1;
}
await endReadSection(fd);
// Read B2 points
///////////
await startReadUniqueSection(fd, sections, 7);
zkey.B2 = [];
for (let i=0; i<zkey.nVars; i++) {
const B2 = await readG2(fd, curve);
zkey.B2[i] = B2;
}
await endReadSection(fd);
// Read C points
///////////
await startReadUniqueSection(fd, sections, 8);
zkey.C = [];
for (let i=zkey.nPublic+1; i<zkey.nVars; i++) {
const C = await readG1(fd, curve);
zkey.C[i] = C;
}
await endReadSection(fd);
// Read H points
///////////
await startReadUniqueSection(fd, sections, 9);
zkey.hExps = [];
for (let i=0; i<zkey.domainSize; i++) {
const H = await readG1(fd, curve);
zkey.hExps.push(H);
}
await endReadSection(fd);
await fd.close();
return zkey;
async function readFr2() {
const n = await readBigInt(fd, zkey.n8r);
return Fr.mul(n, Rri2);
}
}
async function readContribution(fd, curve) {
const c = {delta:{}};
c.deltaAfter = await readG1(fd, curve);
c.delta.g1_s = await readG1(fd, curve);
c.delta.g1_sx = await readG1(fd, curve);
c.delta.g2_spx = await readG2(fd, curve);
c.transcript = await fd.read(64);
c.type = await fd.readULE32();
const paramLength = await fd.readULE32();
const curPos = fd.pos;
let lastType =0;
while (fd.pos-curPos < paramLength) {
const buffType = await fd.read(1);
if (buffType[0]<= lastType) throw new Error("Parameters in the contribution must be sorted");
lastType = buffType[0];
if (buffType[0]==1) { // Name
const buffLen = await fd.read(1);
const buffStr = await fd.read(buffLen[0]);
c.name = new TextDecoder().decode(buffStr);
} else if (buffType[0]==2) {
const buffExp = await fd.read(1);
c.numIterationsExp = buffExp[0];
} else if (buffType[0]==3) {
const buffLen = await fd.read(1);
c.beaconHash = await fd.read(buffLen[0]);
} else {
throw new Error("Parameter not recognized");
}
}
if (fd.pos != curPos + paramLength) {
throw new Error("Parametes do not match");
}
return c;
}
async function readMPCParams(fd, curve, sections) {
await startReadUniqueSection(fd, sections, 10);
const res = { contributions: []};
res.csHash = await fd.read(64);
const n = await fd.readULE32();
for (let i=0; i<n; i++) {
const c = await readContribution(fd, curve);
res.contributions.push(c);
}
await endReadSection(fd);
return res;
}
async function writeContribution(fd, curve, c) {
await writeG1(fd, curve, c.deltaAfter);
await writeG1(fd, curve, c.delta.g1_s);
await writeG1(fd, curve, c.delta.g1_sx);
await writeG2(fd, curve, c.delta.g2_spx);
await fd.write(c.transcript);
await fd.writeULE32(c.type || 0);
const params = [];
if (c.name) {
params.push(1); // Param Name
const nameData = new TextEncoder("utf-8").encode(c.name.substring(0,64));
params.push(nameData.byteLength);
for (let i=0; i<nameData.byteLength; i++) params.push(nameData[i]);
}
if (c.type == 1) {
params.push(2); // Param numIterationsExp
params.push(c.numIterationsExp);
params.push(3); // Beacon Hash
params.push(c.beaconHash.byteLength);
for (let i=0; i<c.beaconHash.byteLength; i++) params.push(c.beaconHash[i]);
}
if (params.length>0) {
const paramsBuff = new Uint8Array(params);
await fd.writeULE32(paramsBuff.byteLength);
await fd.write(paramsBuff);
} else {
await fd.writeULE32(0);
}
}
async function writeMPCParams(fd, curve, mpcParams) {
await startWriteSection(fd, 10);
await fd.write(mpcParams.csHash);
await fd.writeULE32(mpcParams.contributions.length);
for (let i=0; i<mpcParams.contributions.length; i++) {
await writeContribution(fd, curve,mpcParams.contributions[i]);
}
await endWriteSection(fd);
}
function hashG1(hasher, curve, p) {
const buff = new Uint8Array(curve.G1.F.n8*2);
curve.G1.toRprUncompressed(buff, 0, p);
hasher.update(buff);
}
function hashG2(hasher,curve, p) {
const buff = new Uint8Array(curve.G2.F.n8*2);
curve.G2.toRprUncompressed(buff, 0, p);
hasher.update(buff);
}
function hashPubKey(hasher, curve, c) {
hashG1(hasher, curve, c.deltaAfter);
hashG1(hasher, curve, c.delta.g1_s);
hashG1(hasher, curve, c.delta.g1_sx);
hashG2(hasher, curve, c.delta.g2_spx);
hasher.update(c.transcript);
}
async function write(fd, witness, prime) {
await startWriteSection(fd, 1);
const n8 = (Math.floor( (ffjavascript.Scalar.bitLength(prime) - 1) / 64) +1)*8;
await fd.writeULE32(n8);
await writeBigInt(fd, prime, n8);
await fd.writeULE32(witness.length);
await endWriteSection(fd);
await startWriteSection(fd, 2);
for (let i=0; i<witness.length; i++) {
await writeBigInt(fd, witness[i], n8);
}
await endWriteSection(fd);
}
async function writeBin(fd, witnessBin, prime) {
await startWriteSection(fd, 1);
const n8 = (Math.floor( (ffjavascript.Scalar.bitLength(prime) - 1) / 64) +1)*8;
await fd.writeULE32(n8);
await writeBigInt(fd, prime, n8);
if (witnessBin.byteLength % n8 != 0) {
throw new Error("Invalid witness length");
}
await fd.writeULE32(witnessBin.byteLength / n8);
await endWriteSection(fd);
await startWriteSection(fd, 2);
await fd.write(witnessBin);
await endWriteSection(fd);
}
async function readHeader$1(fd, sections) {
await startReadUniqueSection(fd, sections, 1);
const n8 = await fd.readULE32();
const q = await readBigInt(fd, n8);
const nWitness = await fd.readULE32();
await endReadSection(fd);
return {n8, q, nWitness};
}
async function read(fileName) {
const {fd, sections} = await readBinFile(fileName, "wtns", 2);
const {n8, nWitness} = await readHeader$1(fd, sections);
await startReadUniqueSection(fd, sections, 2);
const res = [];
for (let i=0; i<nWitness; i++) {
const v = await readBigInt(fd, n8);
res.push(v);
}
await endReadSection(fd);
await fd.close();
return res;
}
const {stringifyBigInts} = ffjavascript.utils;
async function groth16Prove(zkeyFileName, witnessFileName, logger) {
const {fd: fdWtns, sections: sectionsWtns} = await readBinFile(witnessFileName, "wtns", 2);
const wtns = await readHeader$1(fdWtns, sectionsWtns);
const {fd: fdZKey, sections: sectionsZKey} = await readBinFile(zkeyFileName, "zkey", 2);
const zkey = await readHeader(fdZKey, sectionsZKey, "groth16");
if (!ffjavascript.Scalar.eq(zkey.r, wtns.q)) {
throw new Error("Curve of the witness does not match the curve of the proving key");
}
if (wtns.nWitness != zkey.nVars) {
throw new Error(`Invalid witness length. Circuit: ${zkey.nVars}, witness: ${wtns.nWitness}`);
}
const curve = await getCurveFromQ(zkey.q);
const Fr = curve.Fr;
const G1 = curve.G1;
const G2 = curve.G2;
const power = log2(zkey.domainSize);
const buffWitness = await readFullSection(fdWtns, sectionsWtns, 2);
const buffCoeffs = await readFullSection(fdZKey, sectionsZKey, 4);
const buffBasesA = await readFullSection(fdZKey, sectionsZKey, 5);
const buffBasesB1 = await readFullSection(fdZKey, sectionsZKey, 6);
const buffBasesB2 = await readFullSection(fdZKey, sectionsZKey, 7);
const buffBasesC = await readFullSection(fdZKey, sectionsZKey, 8);
const buffBasesH = await readFullSection(fdZKey, sectionsZKey, 9);
const [buffA_T, buffB_T, buffC_T] = await buldABC(curve, zkey, buffWitness, buffCoeffs);
const buffA = await Fr.ifft(buffA_T);
const buffAodd = await Fr.batchApplyKey(buffA, Fr.e(1), curve.Fr.w[power+1]);
const buffAodd_T = await Fr.fft(buffAodd);
const buffB = await Fr.ifft(buffB_T);
const buffBodd = await Fr.batchApplyKey(buffB, Fr.e(1), curve.Fr.w[power+1]);
const buffBodd_T = await Fr.fft(buffBodd);
const buffC = await Fr.ifft(buffC_T);
const buffCodd = await Fr.batchApplyKey(buffC, Fr.e(1), curve.Fr.w[power+1]);
const buffCodd_T = await Fr.fft(buffCodd);
const buffPodd_T = await joinABC(curve, zkey, buffAodd_T, buffBodd_T, buffCodd_T);
let proof = {};
proof.pi_a = await curve.G1.multiExpAffine(buffBasesA, buffWitness);
let pib1 = await curve.G1.multiExpAffine(buffBasesB1, buffWitness);
proof.pi_b = await curve.G2.multiExpAffine(buffBasesB2, buffWitness);
proof.pi_c = await curve.G1.multiExpAffine(buffBasesC, buffWitness.slice((zkey.nPublic+1)*curve.Fr.n8));
const resH = await curve.G1.multiExpAffine(buffBasesH, buffPodd_T);
const r = curve.Fr.random();
const s = curve.Fr.random();
proof.pi_a = G1.add( proof.pi_a, zkey.vk_alpha_1 );
proof.pi_a = G1.add( proof.pi_a, G1.timesFr( zkey.vk_delta_1, r ));
proof.pi_b = G2.add( proof.pi_b, zkey.vk_beta_2 );
proof.pi_b = G2.add( proof.pi_b, G2.timesFr( zkey.vk_delta_2, s ));
pib1 = G1.add( pib1, zkey.vk_beta_1 );
pib1 = G1.add( pib1, G1.timesFr( zkey.vk_delta_1, s ));
proof.pi_c = G1.add(proof.pi_c, resH);
proof.pi_c = G1.add( proof.pi_c, G1.timesFr( proof.pi_a, s ));
proof.pi_c = G1.add( proof.pi_c, G1.timesFr( pib1, r ));
proof.pi_c = G1.add( proof.pi_c, G1.timesFr( zkey.vk_delta_1, Fr.neg(Fr.mul(r,s) )));
let publicSignals = [];
for (let i=1; i<= zkey.nPublic; i++) {
const b = buffWitness.slice(i*Fr.n8, i*Fr.n8+Fr.n8);
publicSignals.push(ffjavascript.Scalar.fromRprLE(b));
}
proof.pi_a = G1.toObject(G1.toAffine(proof.pi_a));
proof.pi_b = G2.toObject(G2.toAffine(proof.pi_b));
proof.pi_c = G1.toObject(G1.toAffine(proof.pi_c));
proof.protocol = "groth16";
await fdZKey.close();
await fdWtns.close();
proof = stringifyBigInts(proof);
publicSignals = stringifyBigInts(publicSignals);
return {proof, publicSignals};
}
async function buldABC(curve, zkey, witness, coeffs) {
const concurrency = curve.tm.concurrency;
const sCoef = 4*3 + zkey.n8r;
const elementsPerChunk = Math.floor(zkey.domainSize/concurrency);
const coeffsDV = new DataView(coeffs.buffer, coeffs.byteOffset, coeffs.byteLength);
const promises = [];
const cutPoints = [];
for (let i=0; i<concurrency; i++) {
cutPoints.push( getCutPoint( Math.floor(i*elementsPerChunk) ));
}
cutPoints.push(coeffs.byteLength);
for (let i=0; i<concurrency; i++) {
let n;
if (i< concurrency-1) {
n = elementsPerChunk;
} else {
n = zkey.domainSize - i*elementsPerChunk;
}
if (n==0) continue;
const task = [];
task.push({cmd: "ALLOCSET", var: 0, buff: coeffs.slice(cutPoints[i], cutPoints[i+1])});
task.push({cmd: "ALLOCSET", var: 1, buff: witness.slice()});
task.push({cmd: "ALLOC", var: 2, len: n*curve.Fr.n8});
task.push({cmd: "ALLOC", var: 3, len: n*curve.Fr.n8});
task.push({cmd: "ALLOC", var: 4, len: n*curve.Fr.n8});
task.push({cmd: "CALL", fnName: "qap_buildABC", params:[
{var: 0},
{val: (cutPoints[i+1] - cutPoints[i])/sCoef},
{var: 1},
{var: 2},
{var: 3},
{var: 4},
{val: i*elementsPerChunk},
{val: n}
]});
task.push({cmd: "GET", out: 0, var: 2, len: n*curve.Fr.n8});
task.push({cmd: "GET", out: 1, var: 3, len: n*curve.Fr.n8});
task.push({cmd: "GET", out: 2, var: 4, len: n*curve.Fr.n8});
promises.push(curve.tm.queueAction(task));
}
const result = await Promise.all(promises);
const outBuffA = new Uint8Array(zkey.domainSize * curve.Fr.n8);
const outBuffB = new Uint8Array(zkey.domainSize * curve.Fr.n8);
const outBuffC = new Uint8Array(zkey.domainSize * curve.Fr.n8);
let p=0;
for (let i=0; i<result.length; i++) {
outBuffA.set(result[i][0], p);
outBuffB.set(result[i][1], p);
outBuffC.set(result[i][2], p);
p += result[i][0].byteLength;
}
return [outBuffA, outBuffB, outBuffC];
function getCutPoint(v) {
let m = 0;
let n = coeffsDV.getUint32(0, true);
while (m < n) {
var k = (n + m) >> 1;
const va = coeffsDV.getUint32(4 + k*sCoef + 4, true);
if (va > v) {
n = k - 1;
} else if (va < v) {
m = k + 1;
} else {
n = k;
}
}
return 4 + m*sCoef;
}
}
async function joinABC(curve, zkey, a, b, c) {
const concurrency = curve.tm.concurrency;
const n8 = curve.Fr.n8;
const nElements = Math.floor(a.byteLength / curve.Fr.n8);
const elementsPerChunk = Math.floor(nElements/concurrency);
const promises = [];
for (let i=0; i<concurrency; i++) {
let n;
if (i< concurrency-1) {
n = elementsPerChunk;
} else {
n = nElements - i*elementsPerChunk;
}
if (n==0) continue;
const task = [];
const aChunk = a.slice(i*elementsPerChunk*n8, (i*elementsPerChunk + n)*n8 );
const bChunk = b.slice(i*elementsPerChunk*n8, (i*elementsPerChunk + n)*n8 );
const cChunk = c.slice(i*elementsPerChunk*n8, (i*elementsPerChunk + n)*n8 );
task.push({cmd: "ALLOCSET", var: 0, buff: aChunk});
task.push({cmd: "ALLOCSET", var: 1, buff: bChunk});
task.push({cmd: "ALLOCSET", var: 2, buff: cChunk});
task.push({cmd: "ALLOC", var: 3, len: n*n8});
task.push({cmd: "CALL", fnName: "qap_joinABC", params:[
{var: 0},
{var: 1},
{var: 2},
{val: n},
{var: 3},
]});
task.push({cmd: "CALL", fnName: "frm_batchFromMontgomery", params:[
{var: 3},
{val: n},
{var: 3}
]});
task.push({cmd: "GET", out: 0, var: 3, len: n*n8});
promises.push(curve.tm.queueAction(task));
}
const result = await Promise.all(promises);
const outBuff = new Uint8Array(a.byteLength);
let p=0;
for (let i=0; i<result.length; i++) {
outBuff.set(result[i][0], p);
p += result[i][0].byteLength;
}
return outBuff;
}
const { WitnessCalculatorBuilder } = circomRuntime;
async function wtnsCalculate(input, wasmFileName, wtnsFileName, options) {
const fdWasm = await readExisting$2(wasmFileName);
const wasm = await fdWasm.read(fdWasm.totalSize);
await fdWasm.close();
const wc = await WitnessCalculatorBuilder(wasm);
const w = await wc.calculateBinWitness(input);
const fdWtns = await createBinFile(wtnsFileName, "wtns", 2, 2);
await writeBin(fdWtns, w, wc.prime);
await fdWtns.close();
}
async function groth16FullProve(input, wasmFile, zkeyFileName, logger) {
const wtns= {
type: "mem"
};
await wtnsCalculate(input, wasmFile, wtns);
return await groth16Prove(zkeyFileName, wtns);
}
/*
Copyright 2018 0kims association.
This file is part of 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/>.
*/
const {unstringifyBigInts} = ffjavascript.utils;
async function groth16Verify(vk_verifier, publicSignals, proof, logger) {
/*
let cpub = vk_verifier.IC[0];
for (let s= 0; s< vk_verifier.nPublic; s++) {
cpub = G1.add( cpub, G1.timesScalar( vk_verifier.IC[s+1], publicSignals[s]));
}
*/
vk_verifier = unstringifyBigInts(vk_verifier);
proof = unstringifyBigInts(proof);
publicSignals = unstringifyBigInts(publicSignals);
const curve = await getCurveFromName(vk_verifier.curve);
const IC0 = curve.G1.fromObject(vk_verifier.IC[0]);
const IC = new Uint8Array(curve.G1.F.n8*2 * publicSignals.length);
const w = new Uint8Array(curve.Fr.n8 * publicSignals.length);
for (let i=0; i<publicSignals.length; i++) {
const buffP = curve.G1.fromObject(vk_verifier.IC[i+1]);
IC.set(buffP, i*curve.G1.F.n8*2);
ffjavascript.Scalar.toRprLE(w, curve.Fr.n8*i, publicSignals[i], curve.Fr.n8);
}
let cpub = await curve.G1.multiExpAffine(IC, w);
cpub = curve.G1.add(cpub, IC0);
const pi_a = curve.G1.fromObject(proof.pi_a);
const pi_b = curve.G2.fromObject(proof.pi_b);
const pi_c = curve.G1.fromObject(proof.pi_c);
const vk_gamma_2 = curve.G2.fromObject(vk_verifier.vk_gamma_2);
const vk_delta_2 = curve.G2.fromObject(vk_verifier.vk_delta_2);
const vk_alpha_1 = curve.G1.fromObject(vk_verifier.vk_alpha_1);
const vk_beta_2 = curve.G2.fromObject(vk_verifier.vk_beta_2);
const res = await curve.pairingEq(
curve.G1.neg(pi_a) , pi_b,
cpub , vk_gamma_2,
pi_c , vk_delta_2,
vk_alpha_1, vk_beta_2
);
if (! res) {
if (logger) logger.error("Invalid proof");
return false;
}
if (logger) logger.info("OK!");
return true;
}
var groth16 = /*#__PURE__*/Object.freeze({
__proto__: null,
fullProve: groth16FullProve,
prove: groth16Prove,
verify: groth16Verify
});
function hashToG2(curve, hash) {
const hashV = new DataView(hash.buffer, hash.byteOffset, hash.byteLength);
const seed = [];
for (let i=0; i<8; i++) {
seed[i] = hashV.getUint32(i*4);
}
const rng = new ffjavascript.ChaCha(seed);
const g2_sp = curve.G2.fromRng(rng);
return g2_sp;
}
function getG2sp(curve, persinalization, challenge, g1s, g1sx) {
const h = Blake2b(64);
const b1 = new Uint8Array([persinalization]);
h.update(b1);
h.update(challenge);
const b3 = curve.G1.toUncompressed(g1s);
h.update( b3);
const b4 = curve.G1.toUncompressed(g1sx);
h.update( b4);
const hash =h.digest();
return hashToG2(curve, hash);
}
function calculatePubKey(k, curve, personalization, challengeHash, rng ) {
k.g1_s = curve.G1.toAffine(curve.G1.fromRng(rng));
k.g1_sx = curve.G1.toAffine(curve.G1.timesFr(k.g1_s, k.prvKey));
k.g2_sp = curve.G2.toAffine(getG2sp(curve, personalization, challengeHash, k.g1_s, k.g1_sx));
k.g2_spx = curve.G2.toAffine(curve.G2.timesFr(k.g2_sp, k.prvKey));
return k;
}
function createPTauKey(curve, challengeHash, rng) {
const key = {
tau: {},
alpha: {},
beta: {}
};
key.tau.prvKey = curve.Fr.fromRng(rng);
key.alpha.prvKey = curve.Fr.fromRng(rng);
key.beta.prvKey = curve.Fr.fromRng(rng);
calculatePubKey(key.tau, curve, 0, challengeHash, rng);
calculatePubKey(key.alpha, curve, 1, challengeHash, rng);
calculatePubKey(key.beta, curve, 2, challengeHash, rng);
return key;
}
async function writePTauHeader(fd, curve, power, ceremonyPower) {
// Write the header
///////////
if (! ceremonyPower) ceremonyPower = power;
await fd.writeULE32(1); // Header type
const pHeaderSize = fd.pos;
await fd.writeULE64(0); // Temporally set to 0 length
await fd.writeULE32(curve.F1.n64*8);
const buff = new Uint8Array(curve.F1.n8);
ffjavascript.Scalar.toRprLE(buff, 0, curve.q, curve.F1.n8);
await fd.write(buff);
await fd.writeULE32(power); // power
await fd.writeULE32(ceremonyPower); // power
const headerSize = fd.pos - pHeaderSize - 8;
const oldPos = fd.pos;
await fd.writeULE64(headerSize, pHeaderSize);
fd.pos = oldPos;
}
async function readPTauHeader(fd, sections) {
if (!sections[1]) throw new Error(fd.fileName + ": File has no header");
if (sections[1].length>1) throw new Error(fd.fileName +": File has more than one header");
fd.pos = sections[1][0].p;
const n8 = await fd.readULE32();
const buff = await fd.read(n8);
const q = ffjavascript.Scalar.fromRprLE(buff);
const curve = await getCurveFromQ(q);
if (curve.F1.n64*8 != n8) throw new Error(fd.fileName +": Invalid size");
const power = await fd.readULE32();
const ceremonyPower = await fd.readULE32();
if (fd.pos-sections[1][0].p != sections[1][0].size) throw new Error("Invalid PTau header size");
return {curve, power, ceremonyPower};
}
async function readPtauPubKey(fd, curve, montgomery) {
const buff = await fd.read(curve.F1.n8*2*6 + curve.F2.n8*2*3);
return fromPtauPubKeyRpr(buff, 0, curve, montgomery);
}
function fromPtauPubKeyRpr(buff, pos, curve, montgomery) {
const key = {
tau: {},
alpha: {},
beta: {}
};
key.tau.g1_s = readG1();
key.tau.g1_sx = readG1();
key.alpha.g1_s = readG1();
key.alpha.g1_sx = readG1();
key.beta.g1_s = readG1();
key.beta.g1_sx = readG1();
key.tau.g2_spx = readG2();
key.alpha.g2_spx = readG2();
key.beta.g2_spx = readG2();
return key;
function readG1() {
let p;
if (montgomery) {
p = curve.G1.fromRprLEM( buff, pos );
} else {
p = curve.G1.fromRprUncompressed( buff, pos );
}
pos += curve.G1.F.n8*2;
return p;
}
function readG2() {
let p;
if (montgomery) {
p = curve.G2.fromRprLEM( buff, pos );
} else {
p = curve.G2.fromRprUncompressed( buff, pos );
}
pos += curve.G2.F.n8*2;
return p;
}
}
function toPtauPubKeyRpr(buff, pos, curve, key, montgomery) {
writeG1(key.tau.g1_s);
writeG1(key.tau.g1_sx);
writeG1(key.alpha.g1_s);
writeG1(key.alpha.g1_sx);
writeG1(key.beta.g1_s);
writeG1(key.beta.g1_sx);
writeG2(key.tau.g2_spx);
writeG2(key.alpha.g2_spx);
writeG2(key.beta.g2_spx);
async function writeG1(p) {
if (montgomery) {
curve.G1.toRprLEM(buff, pos, p);
} else {
curve.G1.toRprUncompressed(buff, pos, p);
}
pos += curve.F1.n8*2;
}
async function writeG2(p) {
if (montgomery) {
curve.G2.toRprLEM(buff, pos, p);
} else {
curve.G2.toRprUncompressed(buff, pos, p);
}
pos += curve.F2.n8*2;
}
return buff;
}
async function writePtauPubKey(fd, curve, key, montgomery) {
const buff = new Uint8Array(curve.F1.n8*2*6 + curve.F2.n8*2*3);
toPtauPubKeyRpr(buff, 0, curve, key, montgomery);
await fd.write(buff);
}
async function readContribution$1(fd, curve) {
const c = {};
c.tauG1 = await readG1();
c.tauG2 = await readG2();
c.alphaG1 = await readG1();
c.betaG1 = await readG1();
c.betaG2 = await readG2();
c.key = await readPtauPubKey(fd, curve, true);
c.partialHash = await fd.read(216);
c.nextChallenge = await fd.read(64);
c.type = await fd.readULE32();
const buffV = new Uint8Array(curve.G1.F.n8*2*6+curve.G2.F.n8*2*3);
toPtauPubKeyRpr(buffV, 0, curve, c.key, false);
const responseHasher = Blake2b(64);
responseHasher.setPartialHash(c.partialHash);
responseHasher.update(buffV);
c.responseHash = responseHasher.digest();
const paramLength = await fd.readULE32();
const curPos = fd.pos;
let lastType =0;
while (fd.pos-curPos < paramLength) {
const buffType = await readDV(1);
if (buffType[0]<= lastType) throw new Error("Parameters in the contribution must be sorted");
lastType = buffType[0];
if (buffType[0]==1) { // Name
const buffLen = await readDV(1);
const buffStr = await readDV(buffLen[0]);
c.name = new TextDecoder().decode(buffStr);
} else if (buffType[0]==2) {
const buffExp = await readDV(1);
c.numIterationsExp = buffExp[0];
} else if (buffType[0]==3) {
const buffLen = await readDV(1);
c.beaconHash = await readDV(buffLen[0]);
} else {
throw new Error("Parameter not recognized");
}
}
if (fd.pos != curPos + paramLength) {
throw new Error("Parametes do not match");
}
return c;
async function readG1() {
const pBuff = await fd.read(curve.G1.F.n8*2);
return curve.G1.fromRprLEM( pBuff );
}
async function readG2() {
const pBuff = await fd.read(curve.G2.F.n8*2);
return curve.G2.fromRprLEM( pBuff );
}
async function readDV(n) {
const b = await fd.read(n);
return new Uint8Array(b);
}
}
async function readContributions(fd, curve, sections) {
if (!sections[7]) throw new Error(fd.fileName + ": File has no contributions");
if (sections[7][0].length>1) throw new Error(fd.fileName +": File has more than one contributions section");
fd.pos = sections[7][0].p;
const nContributions = await fd.readULE32();
const contributions = [];
for (let i=0; i<nContributions; i++) {
const c = await readContribution$1(fd, curve);
c.id = i+1;
contributions.push(c);
}
if (fd.pos-sections[7][0].p != sections[7][0].size) throw new Error("Invalid contribution section size");
return contributions;
}
async function writeContribution$1(fd, curve, contribution) {
const buffG1 = new Uint8Array(curve.F1.n8*2);
const buffG2 = new Uint8Array(curve.F2.n8*2);
await writeG1(contribution.tauG1);
await writeG2(contribution.tauG2);
await writeG1(contribution.alphaG1);
await writeG1(contribution.betaG1);
await writeG2(contribution.betaG2);
await writePtauPubKey(fd, curve, contribution.key, true);
await fd.write(contribution.partialHash);
await fd.write(contribution.nextChallenge);
await fd.writeULE32(contribution.type || 0);
const params = [];
if (contribution.name) {
params.push(1); // Param Name
const nameData = new TextEncoder("utf-8").encode(contribution.name.substring(0,64));
params.push(nameData.byteLength);
for (let i=0; i<nameData.byteLength; i++) params.push(nameData[i]);
}
if (contribution.type == 1) {
params.push(2); // Param numIterationsExp
params.push(contribution.numIterationsExp);
params.push(3); // Beacon Hash
params.push(contribution.beaconHash.byteLength);
for (let i=0; i<contribution.beaconHash.byteLength; i++) params.push(contribution.beaconHash[i]);
}
if (params.length>0) {
const paramsBuff = new Uint8Array(params);
await fd.writeULE32(paramsBuff.byteLength);
await fd.write(paramsBuff);
} else {
await fd.writeULE32(0);
}
async function writeG1(p) {
curve.G1.toRprLEM(buffG1, 0, p);
await fd.write(buffG1);
}
async function writeG2(p) {
curve.G2.toRprLEM(buffG2, 0, p);
await fd.write(buffG2);
}
}
async function writeContributions(fd, curve, contributions) {
await fd.writeULE32(7); // Header type
const pContributionsSize = fd.pos;
await fd.writeULE64(0); // Temporally set to 0 length
await fd.writeULE32(contributions.length);
for (let i=0; i< contributions.length; i++) {
await writeContribution$1(fd, curve, contributions[i]);
}
const contributionsSize = fd.pos - pContributionsSize - 8;
const oldPos = fd.pos;
await fd.writeULE64(contributionsSize, pContributionsSize);
fd.pos = oldPos;
}
function calculateFirstChallengeHash(curve, power, logger) {
if (logger) logger.debug("Calculating First Challenge Hash");
const hasher = new Blake2b(64);
const vG1 = new Uint8Array(curve.G1.F.n8*2);
const vG2 = new Uint8Array(curve.G2.F.n8*2);
curve.G1.toRprUncompressed(vG1, 0, curve.G1.g);
curve.G2.toRprUncompressed(vG2, 0, curve.G2.g);
hasher.update(Blake2b(64).digest());
let n;
n=(1 << power)*2 -1;
if (logger) logger.debug("Calculate Initial Hash: tauG1");
hashBlock(vG1, n);
n= 1 << power;
if (logger) logger.debug("Calculate Initial Hash: tauG2");
hashBlock(vG2, n);
if (logger) logger.debug("Calculate Initial Hash: alphaTauG1");
hashBlock(vG1, n);
if (logger) logger.debug("Calculate Initial Hash: betaTauG1");
hashBlock(vG1, n);
hasher.update(vG2);
return hasher.digest();
function hashBlock(buff, n) {
const blockSize = 500000;
const nBlocks = Math.floor(n / blockSize);
const rem = n % blockSize;
const bigBuff = new Uint8Array(blockSize * buff.byteLength);
for (let i=0; i<blockSize; i++) {
bigBuff.set(buff, i*buff.byteLength);
}
for (let i=0; i<nBlocks; i++) {
hasher.update(bigBuff);
if (logger) logger.debug("Initial hash: " +i*blockSize);
}
for (let i=0; i<rem; i++) {
hasher.update(buff);
}
}
}
function keyFromBeacon(curve, challengeHash, beaconHash, numIterationsExp) {
const rng = rngFromBeaconParams(beaconHash, numIterationsExp);
const key = createPTauKey(curve, challengeHash, rng);
return key;
}
/*
Header(1)
n8
prime
power
tauG1(2)
{(1<<power)*2-1} [
G1, tau*G1, tau^2 * G1, ....
]
tauG2(3)
{1<<power}[
G2, tau*G2, tau^2 * G2, ...
]
alphaTauG1(4)
{1<<power}[
alpha*G1, alpha*tau*G1, alpha*tau^2*G1,....
]
betaTauG1(5)
{1<<power} []
beta*G1, beta*tau*G1, beta*tau^2*G1, ....
]
betaG2(6)
{1}[
beta*G2
]
contributions(7)
NContributions
{NContributions}[
tau*G1
tau*G2
alpha*G1
beta*G1
beta*G2
pubKey
tau_g1s
tau_g1sx
tau_g2spx
alpha_g1s
alpha_g1sx
alpha_g1spx
beta_g1s
beta_g1sx
beta_g1spx
partialHash (216 bytes) See https://github.com/mafintosh/blake2b-wasm/blob/23bee06945806309977af802bc374727542617c7/blake2b.wat#L9
hashNewChallenge
]
*/
async function newAccumulator(curve, power, fileName, logger) {
await Blake2b.ready();
const fd = await createBinFile(fileName, "ptau", 1, 7);
await writePTauHeader(fd, curve, power, 0);
const buffG1 = curve.G1.oneAffine;
const buffG2 = curve.G2.oneAffine;
// Write tauG1
///////////
await startWriteSection(fd, 2);
const nTauG1 = (1 << power) * 2 -1;
for (let i=0; i< nTauG1; i++) {
await fd.write(buffG1);
if ((logger)&&((i%100000) == 0)&&i) logger.log("tauG1: " + i);
}
await endWriteSection(fd);
// Write tauG2
///////////
await startWriteSection(fd, 3);
const nTauG2 = (1 << power);
for (let i=0; i< nTauG2; i++) {
await fd.write(buffG2);
if ((logger)&&((i%100000) == 0)&&i) logger.log("tauG2: " + i);
}
await endWriteSection(fd);
// Write alphaTauG1
///////////
await startWriteSection(fd, 4);
const nAlfaTauG1 = (1 << power);
for (let i=0; i< nAlfaTauG1; i++) {
await fd.write(buffG1);
if ((logger)&&((i%100000) == 0)&&i) logger.log("alphaTauG1: " + i);
}
await endWriteSection(fd);
// Write betaTauG1
///////////
await startWriteSection(fd, 5);
const nBetaTauG1 = (1 << power);
for (let i=0; i< nBetaTauG1; i++) {
await fd.write(buffG1);
if ((logger)&&((i%100000) == 0)&&i) logger.log("betaTauG1: " + i);
}
await endWriteSection(fd);
// Write betaG2
///////////
await startWriteSection(fd, 6);
await fd.write(buffG2);
await endWriteSection(fd);
// Contributions
///////////
await startWriteSection(fd, 7);
await fd.writeULE32(0); // 0 Contributions
await endWriteSection(fd);
await fd.close();
const firstChallengeHash = calculateFirstChallengeHash(curve, power, logger);
if (logger) logger.debug(formatHash(Blake2b(64).digest(), "Blank Contribution Hash:"));
if (logger) logger.info(formatHash(firstChallengeHash, "First Contribution Hash:"));
return firstChallengeHash;
}
// Format of the outpu
async function exportChallenge(pTauFilename, challengeFilename, logger) {
await Blake2b.ready();
const {fd: fdFrom, sections} = await readBinFile(pTauFilename, "ptau", 1);
const {curve, power} = await readPTauHeader(fdFrom, sections);
const contributions = await readContributions(fdFrom, curve, sections);
let lastResponseHash, curChallengeHash;
if (contributions.length == 0) {
lastResponseHash = Blake2b(64).digest();
curChallengeHash = calculateFirstChallengeHash(curve, power);
} else {
lastResponseHash = contributions[contributions.length-1].responseHash;
curChallengeHash = contributions[contributions.length-1].nextChallenge;
}
if (logger) logger.info(formatHash(lastResponseHash, "Last Response Hash: "));
if (logger) logger.info(formatHash(curChallengeHash, "New Challenge Hash: "));
const fdTo = await createOverride(challengeFilename);
const toHash = Blake2b(64);
await fdTo.write(lastResponseHash);
toHash.update(lastResponseHash);
await exportSection(2, "G1", (1 << power) * 2 -1, "tauG1");
await exportSection(3, "G2", (1 << power) , "tauG2");
await exportSection(4, "G1", (1 << power) , "alphaTauG1");
await exportSection(5, "G1", (1 << power) , "betaTauG1");
await exportSection(6, "G2", 1 , "betaG2");
await fdFrom.close();
await fdTo.close();
const calcCurChallengeHash = toHash.digest();
if (!hashIsEqual (curChallengeHash, calcCurChallengeHash)) {
if (logger) logger.info(formatHash(calcCurChallengeHash, "Calc Curret Challenge Hash: "));
if (logger) logger.error("PTau file is corrupted. Calculated new challenge hash does not match with the eclared one");
throw new Error("PTau file is corrupted. Calculated new challenge hash does not match with the eclared one");
}
return curChallengeHash;
async function exportSection(sectionId, groupName, nPoints, sectionName) {
const G = curve[groupName];
const sG = G.F.n8*2;
const nPointsChunk = Math.floor((1<<24)/sG);
await startReadUniqueSection(fdFrom, sections, sectionId);
for (let i=0; i< nPoints; i+= nPointsChunk) {
if (logger) logger.debug(`Exporting ${sectionName}: ${i}/${nPoints}`);
const n = Math.min(nPoints-i, nPointsChunk);
let buff;
buff = await fdFrom.read(n*sG);
buff = await G.batchLEMtoU(buff);
await fdTo.write(buff);
toHash.update(buff);
}
await endReadSection(fdFrom);
}
}
async function importResponse(oldPtauFilename, contributionFilename, newPTauFilename, name, importPoints, logger) {
await Blake2b.ready();
const noHash = new Uint8Array(64);
for (let i=0; i<64; i++) noHash[i] = 0xFF;
const {fd: fdOld, sections} = await readBinFile(oldPtauFilename, "ptau", 1);
const {curve, power} = await readPTauHeader(fdOld, sections);
const contributions = await readContributions(fdOld, curve, sections);
const currentContribution = {};
if (name) currentContribution.name = name;
const sG1 = curve.F1.n8*2;
const scG1 = curve.F1.n8; // Compresed size
const sG2 = curve.F2.n8*2;
const scG2 = curve.F2.n8; // Compresed size
const fdResponse = await readExisting$2(contributionFilename);
if (fdResponse.totalSize !=
64 + // Old Hash
((1<<power)*2-1)*scG1 +
(1<<power)*scG2 +
(1<<power)*scG1 +
(1<<power)*scG1 +
scG2 +
sG1*6 + sG2*3)
throw new Error("Size of the contribution is invalid");
let lastChallengeHash;
if (contributions.length>0) {
lastChallengeHash = contributions[contributions.length-1].nextChallenge;
} else {
lastChallengeHash = calculateFirstChallengeHash(curve, power, logger);
}
const fdNew = await createBinFile(newPTauFilename, "ptau", 1, importPoints ? 7: 2);
await writePTauHeader(fdNew, curve, power);
const contributionPreviousHash = await fdResponse.read(64);
if (hashIsEqual(noHash,lastChallengeHash)) {
lastChallengeHash = contributionPreviousHash;
contributions[contributions.length-1].nextChallenge = lastChallengeHash;
}
if(!hashIsEqual(contributionPreviousHash,lastChallengeHash))
throw new Error("Wrong contribution. this contribution is not based on the previus hash");
const hasherResponse = new Blake2b(64);
hasherResponse.update(contributionPreviousHash);
const startSections = [];
let res;
res = await processSection(fdResponse, fdNew, "G1", 2, (1 << power) * 2 -1, [1], "tauG1");
currentContribution.tauG1 = res[0];
res = await processSection(fdResponse, fdNew, "G2", 3, (1 << power) , [1], "tauG2");
currentContribution.tauG2 = res[0];
res = await processSection(fdResponse, fdNew, "G1", 4, (1 << power) , [0], "alphaG1");
currentContribution.alphaG1 = res[0];
res = await processSection(fdResponse, fdNew, "G1", 5, (1 << power) , [0], "betaG1");
currentContribution.betaG1 = res[0];
res = await processSection(fdResponse, fdNew, "G2", 6, 1 , [0], "betaG2");
currentContribution.betaG2 = res[0];
currentContribution.partialHash = hasherResponse.getPartialHash();
const buffKey = await fdResponse.read(curve.F1.n8*2*6+curve.F2.n8*2*3);
currentContribution.key = fromPtauPubKeyRpr(buffKey, 0, curve, false);
hasherResponse.update(new Uint8Array(buffKey));
const hashResponse = hasherResponse.digest();
if (logger) logger.info(formatHash(hashResponse, "Contribution Response Hash imported: "));
if (importPoints) {
const nextChallengeHasher = new Blake2b(64);
nextChallengeHasher.update(hashResponse);
await hashSection(nextChallengeHasher, fdNew, "G1", 2, (1 << power) * 2 -1, "tauG1", logger);
await hashSection(nextChallengeHasher, fdNew, "G2", 3, (1 << power) , "tauG2", logger);
await hashSection(nextChallengeHasher, fdNew, "G1", 4, (1 << power) , "alphaTauG1", logger);
await hashSection(nextChallengeHasher, fdNew, "G1", 5, (1 << power) , "betaTauG1", logger);
await hashSection(nextChallengeHasher, fdNew, "G2", 6, 1 , "betaG2", logger);
currentContribution.nextChallenge = nextChallengeHasher.digest();
if (logger) logger.info(formatHash(currentContribution.nextChallenge, "Next Challenge Hash: "));
} else {
currentContribution.nextChallenge = noHash;
}
contributions.push(currentContribution);
await writeContributions(fdNew, curve, contributions);
await fdResponse.close();
await fdNew.close();
await fdOld.close();
return currentContribution.nextChallenge;
async function processSection(fdFrom, fdTo, groupName, sectionId, nPoints, singularPointIndexes, sectionName) {
if (importPoints) {
return await processSectionImportPoints(fdFrom, fdTo, groupName, sectionId, nPoints, singularPointIndexes, sectionName);
} else {
return await processSectionNoImportPoints(fdFrom, fdTo, groupName, sectionId, nPoints, singularPointIndexes, sectionName);
}
}
async function processSectionImportPoints(fdFrom, fdTo, groupName, sectionId, nPoints, singularPointIndexes, sectionName) {
const G = curve[groupName];
const scG = G.F.n8;
const sG = G.F.n8*2;
const singularPoints = [];
await startWriteSection(fdTo, sectionId);
const nPointsChunk = Math.floor((1<<24)/sG);
startSections[sectionId] = fdTo.pos;
for (let i=0; i< nPoints; i += nPointsChunk) {
if (logger) logger.debug(`Importing ${sectionName}: ${i}/${nPoints}`);
const n = Math.min(nPoints-i, nPointsChunk);
const buffC = await fdFrom.read(n * scG);
hasherResponse.update(buffC);
const buffLEM = await G.batchCtoLEM(buffC);
await fdTo.write(buffLEM);
for (let j=0; j<singularPointIndexes.length; j++) {
const sp = singularPointIndexes[j];
if ((sp >=i) && (sp < i+n)) {
const P = G.fromRprLEM(buffLEM, (sp-i)*sG);
singularPoints.push(P);
}
}
}
await endWriteSection(fdTo);
return singularPoints;
}
async function processSectionNoImportPoints(fdFrom, fdTo, groupName, sectionId, nPoints, singularPointIndexes, sectionName) {
const G = curve[groupName];
const scG = G.F.n8;
const singularPoints = [];
const nPointsChunk = Math.floor((1<<24)/scG);
for (let i=0; i< nPoints; i += nPointsChunk) {
if (logger) logger.debug(`Importing ${sectionName}: ${i}/${nPoints}`);
const n = Math.min(nPoints-i, nPointsChunk);
const buffC = await fdFrom.read(n * scG);
hasherResponse.update(buffC);
for (let j=0; j<singularPointIndexes.length; j++) {
const sp = singularPointIndexes[j];
if ((sp >=i) && (sp < i+n)) {
const P = G.fromRprCompressed(buffC, (sp-i)*scG);
singularPoints.push(P);
}
}
}
return singularPoints;
}
async function hashSection(nextChallengeHasher, fdTo, groupName, sectionId, nPoints, sectionName, logger) {
const G = curve[groupName];
const sG = G.F.n8*2;
const nPointsChunk = Math.floor((1<<24)/sG);
const oldPos = fdTo.pos;
fdTo.pos = startSections[sectionId];
for (let i=0; i< nPoints; i += nPointsChunk) {
if (logger) logger.debug(`Hashing ${sectionName}: ${i}/${nPoints}`);
const n = Math.min(nPoints-i, nPointsChunk);
const buffLEM = await fdTo.read(n * sG);
const buffU = await G.batchLEMtoU(buffLEM);
nextChallengeHasher.update(buffU);
}
fdTo.pos = oldPos;
}
}
const sameRatio$1 = sameRatio;
async function verifyContribution(curve, cur, prev, logger) {
let sr;
if (cur.type == 1) { // Verify the beacon.
const beaconKey = keyFromBeacon(curve, prev.nextChallenge, cur.beaconHash, cur.numIterationsExp);
if (!curve.G1.eq(cur.key.tau.g1_s, beaconKey.tau.g1_s)) {
if (logger) logger.error(`BEACON key (tauG1_s) is not generated correctly in challenge #${cur.id} ${cur.name || ""}` );
return false;
}
if (!curve.G1.eq(cur.key.tau.g1_sx, beaconKey.tau.g1_sx)) {
if (logger) logger.error(`BEACON key (tauG1_sx) is not generated correctly in challenge #${cur.id} ${cur.name || ""}` );
return false;
}
if (!curve.G2.eq(cur.key.tau.g2_spx, beaconKey.tau.g2_spx)) {
if (logger) logger.error(`BEACON key (tauG2_spx) is not generated correctly in challenge #${cur.id} ${cur.name || ""}` );
return false;
}
if (!curve.G1.eq(cur.key.alpha.g1_s, beaconKey.alpha.g1_s)) {
if (logger) logger.error(`BEACON key (alphaG1_s) is not generated correctly in challenge #${cur.id} ${cur.name || ""}` );
return false;
}
if (!curve.G1.eq(cur.key.alpha.g1_sx, beaconKey.alpha.g1_sx)) {
if (logger) logger.error(`BEACON key (alphaG1_sx) is not generated correctly in challenge #${cur.id} ${cur.name || ""}` );
return false;
}
if (!curve.G2.eq(cur.key.alpha.g2_spx, beaconKey.alpha.g2_spx)) {
if (logger) logger.error(`BEACON key (alphaG2_spx) is not generated correctly in challenge #${cur.id} ${cur.name || ""}` );
return false;
}
if (!curve.G1.eq(cur.key.beta.g1_s, beaconKey.beta.g1_s)) {
if (logger) logger.error(`BEACON key (betaG1_s) is not generated correctly in challenge #${cur.id} ${cur.name || ""}` );
return false;
}
if (!curve.G1.eq(cur.key.beta.g1_sx, beaconKey.beta.g1_sx)) {
if (logger) logger.error(`BEACON key (betaG1_sx) is not generated correctly in challenge #${cur.id} ${cur.name || ""}` );
return false;
}
if (!curve.G2.eq(cur.key.beta.g2_spx, beaconKey.beta.g2_spx)) {
if (logger) logger.error(`BEACON key (betaG2_spx) is not generated correctly in challenge #${cur.id} ${cur.name || ""}` );
return false;
}
}
cur.key.tau.g2_sp = curve.G2.toAffine(getG2sp(curve, 0, prev.nextChallenge, cur.key.tau.g1_s, cur.key.tau.g1_sx));
cur.key.alpha.g2_sp = curve.G2.toAffine(getG2sp(curve, 1, prev.nextChallenge, cur.key.alpha.g1_s, cur.key.alpha.g1_sx));
cur.key.beta.g2_sp = curve.G2.toAffine(getG2sp(curve, 2, prev.nextChallenge, cur.key.beta.g1_s, cur.key.beta.g1_sx));
sr = await sameRatio$1(curve, cur.key.tau.g1_s, cur.key.tau.g1_sx, cur.key.tau.g2_sp, cur.key.tau.g2_spx);
if (sr !== true) {
if (logger) logger.error("INVALID key (tau) in challenge #"+cur.id);
return false;
}
sr = await sameRatio$1(curve, cur.key.alpha.g1_s, cur.key.alpha.g1_sx, cur.key.alpha.g2_sp, cur.key.alpha.g2_spx);
if (sr !== true) {
if (logger) logger.error("INVALID key (alpha) in challenge #"+cur.id);
return false;
}
sr = await sameRatio$1(curve, cur.key.beta.g1_s, cur.key.beta.g1_sx, cur.key.beta.g2_sp, cur.key.beta.g2_spx);
if (sr !== true) {
if (logger) logger.error("INVALID key (beta) in challenge #"+cur.id);
return false;
}
sr = await sameRatio$1(curve, prev.tauG1, cur.tauG1, cur.key.tau.g2_sp, cur.key.tau.g2_spx);
if (sr !== true) {
if (logger) logger.error("INVALID tau*G1. challenge #"+cur.id+" It does not follow the previous contribution");
return false;
}
sr = await sameRatio$1(curve, cur.key.tau.g1_s, cur.key.tau.g1_sx, prev.tauG2, cur.tauG2);
if (sr !== true) {
if (logger) logger.error("INVALID tau*G2. challenge #"+cur.id+" It does not follow the previous contribution");
return false;
}
sr = await sameRatio$1(curve, prev.alphaG1, cur.alphaG1, cur.key.alpha.g2_sp, cur.key.alpha.g2_spx);
if (sr !== true) {
if (logger) logger.error("INVALID alpha*G1. challenge #"+cur.id+" It does not follow the previous contribution");
return false;
}
sr = await sameRatio$1(curve, prev.betaG1, cur.betaG1, cur.key.beta.g2_sp, cur.key.beta.g2_spx);
if (sr !== true) {
if (logger) logger.error("INVALID beta*G1. challenge #"+cur.id+" It does not follow the previous contribution");
return false;
}
sr = await sameRatio$1(curve, cur.key.beta.g1_s, cur.key.beta.g1_sx, prev.betaG2, cur.betaG2);
if (sr !== true) {
if (logger) logger.error("INVALID beta*G2. challenge #"+cur.id+"It does not follow the previous contribution");
return false;
}
if (logger) logger.info("Powers Of tau file OK!");
return true;
}
async function verify(tauFilename, logger) {
let sr;
await Blake2b.ready();
const {fd, sections} = await readBinFile(tauFilename, "ptau", 1);
const {curve, power, ceremonyPower} = await readPTauHeader(fd, sections);
const contrs = await readContributions(fd, curve, sections);
if (logger) logger.debug("power: 2**" + power);
// Verify Last contribution
if (logger) logger.debug("Computing initial contribution hash");
const initialContribution = {
tauG1: curve.G1.g,
tauG2: curve.G2.g,
alphaG1: curve.G1.g,
betaG1: curve.G1.g,
betaG2: curve.G2.g,
nextChallenge: calculateFirstChallengeHash(curve, ceremonyPower, logger),
responseHash: Blake2b(64).digest()
};
if (contrs.length == 0) {
if (logger) logger.error("This file has no contribution! It cannot be used in production");
return false;
}
let prevContr;
if (contrs.length>1) {
prevContr = contrs[contrs.length-2];
} else {
prevContr = initialContribution;
}
const curContr = contrs[contrs.length-1];
if (logger) logger.debug("Validating contribution #"+contrs[contrs.length-1].id);
const res = await verifyContribution(curve, curContr, prevContr, logger);
if (!res) return false;
const nextContributionHasher = Blake2b(64);
nextContributionHasher.update(curContr.responseHash);
// Verify powers and compute nextChallengeHash
// await test();
// Verify Section tau*G1
if (logger) logger.debug("Verifying powers in tau*G1 section");
const rTau1 = await processSection(2, "G1", "tauG1", (1 << power)*2-1, [0, 1], logger);
sr = await sameRatio$1(curve, rTau1.R1, rTau1.R2, curve.G2.g, curContr.tauG2);
if (sr !== true) {
if (logger) logger.error("tauG1 section. Powers do not match");
return false;
}
if (!curve.G1.eq(curve.G1.g, rTau1.singularPoints[0])) {
if (logger) logger.error("First element of tau*G1 section must be the generator");
return false;
}
if (!curve.G1.eq(curContr.tauG1, rTau1.singularPoints[1])) {
if (logger) logger.error("Second element of tau*G1 section does not match the one in the contribution section");
return false;
}
// await test();
// Verify Section tau*G2
if (logger) logger.debug("Verifying powers in tau*G2 section");
const rTau2 = await processSection(3, "G2", "tauG2", 1 << power, [0, 1], logger);
sr = await sameRatio$1(curve, curve.G1.g, curContr.tauG1, rTau2.R1, rTau2.R2);
if (sr !== true) {
if (logger) logger.error("tauG2 section. Powers do not match");
return false;
}
if (!curve.G2.eq(curve.G2.g, rTau2.singularPoints[0])) {
if (logger) logger.error("First element of tau*G2 section must be the generator");
return false;
}
if (!curve.G2.eq(curContr.tauG2, rTau2.singularPoints[1])) {
if (logger) logger.error("Second element of tau*G2 section does not match the one in the contribution section");
return false;
}
// Verify Section alpha*tau*G1
if (logger) logger.debug("Verifying powers in alpha*tau*G1 section");
const rAlphaTauG1 = await processSection(4, "G1", "alphatauG1", 1 << power, [0], logger);
sr = await sameRatio$1(curve, rAlphaTauG1.R1, rAlphaTauG1.R2, curve.G2.g, curContr.tauG2);
if (sr !== true) {
if (logger) logger.error("alphaTauG1 section. Powers do not match");
return false;
}
if (!curve.G1.eq(curContr.alphaG1, rAlphaTauG1.singularPoints[0])) {
if (logger) logger.error("First element of alpha*tau*G1 section (alpha*G1) does not match the one in the contribution section");
return false;
}
// Verify Section beta*tau*G1
if (logger) logger.debug("Verifying powers in beta*tau*G1 section");
const rBetaTauG1 = await processSection(5, "G1", "betatauG1", 1 << power, [0], logger);
sr = await sameRatio$1(curve, rBetaTauG1.R1, rBetaTauG1.R2, curve.G2.g, curContr.tauG2);
if (sr !== true) {
if (logger) logger.error("betaTauG1 section. Powers do not match");
return false;
}
if (!curve.G1.eq(curContr.betaG1, rBetaTauG1.singularPoints[0])) {
if (logger) logger.error("First element of beta*tau*G1 section (beta*G1) does not match the one in the contribution section");
return false;
}
//Verify Beta G2
const betaG2 = await processSectionBetaG2(logger);
if (!curve.G2.eq(curContr.betaG2, betaG2)) {
if (logger) logger.error("betaG2 element in betaG2 section does not match the one in the contribution section");
return false;
}
const nextContributionHash = nextContributionHasher.digest();
// Check the nextChallengeHash
if (!hashIsEqual(nextContributionHash,curContr.nextChallenge)) {
if (logger) logger.error("Hash of the values does not match the next challenge of the last contributor in the contributions section");
return false;
}
if (logger) logger.info(formatHash(nextContributionHash, "Next challenge hash: "));
// Verify Previous contributions
printContribution(curContr, prevContr);
for (let i = contrs.length-2; i>=0; i--) {
const curContr = contrs[i];
const prevContr = (i>0) ? contrs[i-1] : initialContribution;
const res = await verifyContribution(curve, curContr, prevContr, logger);
if (!res) return false;
printContribution(curContr, prevContr);
}
if (logger) logger.info("-----------------------------------------------------");
if ((!sections[12]) || (!sections[13]) || (!sections[14]) || (!sections[15])) {
if (logger) logger.warn(
"this file does not contain phase2 precalculated values. Please run: \n" +
" snarkjs \"powersoftau preparephase2\" to prepare this file to be used in the phase2 ceremony."
);
} else {
let res;
res = await verifyLagrangeEvaluations("G1", 2, 12, "tauG1", logger);
if (!res) return false;
res = await verifyLagrangeEvaluations("G2", 3, 13, "tauG2", logger);
if (!res) return false;
res = await verifyLagrangeEvaluations("G1", 4, 14, "alphaTauG1", logger);
if (!res) return false;
res = await verifyLagrangeEvaluations("G1", 5, 15, "betaTauG1", logger);
if (!res) return false;
}
await fd.close();
return true;
function printContribution(curContr, prevContr) {
if (!logger) return;
logger.info("-----------------------------------------------------");
logger.info(`Contribution #${curContr.id}: ${curContr.name ||""}`);
logger.info(formatHash(curContr.nextChallenge, "Next Challenge: "));
const buffV = new Uint8Array(curve.G1.F.n8*2*6+curve.G2.F.n8*2*3);
toPtauPubKeyRpr(buffV, 0, curve, curContr.key, false);
const responseHasher = Blake2b(64);
responseHasher.setPartialHash(curContr.partialHash);
responseHasher.update(buffV);
const responseHash = responseHasher.digest();
logger.info(formatHash(responseHash, "Response Hash:"));
logger.info(formatHash(prevContr.nextChallenge, "Response Hash:"));
if (curContr.type == 1) {
logger.info(`Beacon generator: ${byteArray2hex(curContr.beaconHash)}`);
logger.info(`Beacon iterations Exp: ${curContr.numIterationsExp}`);
}
}
async function processSectionBetaG2(logger) {
const G = curve.G2;
const sG = G.F.n8*2;
const buffUv = new Uint8Array(sG);
if (!sections[6]) {
logger.error("File has no BetaG2 section");
throw new Error("File has no BetaG2 section");
}
if (sections[6].length>1) {
logger.error("File has no BetaG2 section");
throw new Error("File has more than one GetaG2 section");
}
fd.pos = sections[6][0].p;
const buff = await fd.read(sG);
const P = G.fromRprLEM(buff);
G.toRprUncompressed(buffUv, 0, P);
nextContributionHasher.update(buffUv);
return P;
}
async function processSection(idSection, groupName, sectionName, nPoints, singularPointIndexes, logger) {
const MAX_CHUNK_SIZE = 1<<16;
const G = curve[groupName];
const sG = G.F.n8*2;
await startReadUniqueSection(fd, sections, idSection);
const singularPoints = [];
let R1 = G.zero;
let R2 = G.zero;
let lastBase = G.zero;
for (let i=0; i<nPoints; i += MAX_CHUNK_SIZE) {
if (logger) logger.debug(`points relations: ${sectionName}: ${i}/${nPoints} `);
const n = Math.min(nPoints - i, MAX_CHUNK_SIZE);
const bases = await fd.read(n*sG);
const basesU = await G.batchLEMtoU(bases);
nextContributionHasher.update(basesU);
const scalars = new Uint8Array(4*(n-1));
crypto.randomFillSync(scalars);
if (i>0) {
const firstBase = G.fromRprLEM(bases, 0);
const r = crypto.randomBytes(4).readUInt32BE(0, true);
R1 = G.add(R1, G.timesScalar(lastBase, r));
R2 = G.add(R2, G.timesScalar(firstBase, r));
}
const r1 = await G.multiExpAffine(bases.slice(0, (n-1)*sG), scalars);
const r2 = await G.multiExpAffine(bases.slice(sG), scalars);
R1 = G.add(R1, r1);
R2 = G.add(R2, r2);
lastBase = G.fromRprLEM( bases, (n-1)*sG);
for (let j=0; j<singularPointIndexes.length; j++) {
const sp = singularPointIndexes[j];
if ((sp >=i) && (sp < i+n)) {
const P = G.fromRprLEM(bases, (sp-i)*sG);
singularPoints.push(P);
}
}
}
await endReadSection(fd);
return {
R1: R1,
R2: R2,
singularPoints: singularPoints
};
}
async function verifyLagrangeEvaluations(gName, tauSection, lagrangeSection, sectionName, logger) {
if (logger) logger.debug(`Verifying phase2 calculated values ${sectionName}...`);
const G = curve[gName];
const sG = G.F.n8*2;
const seed= new Array(8);
for (let i=0; i<8; i++) {
seed[i] = crypto.randomBytes(4).readUInt32BE(0, true);
}
for (let p=0; p<= power; p ++) {
const res = await verifyPower(p);
if (!res) return false;
}
return true;
async function verifyPower(p) {
if (logger) logger.debug(`Power ${p}...`);
const n8r = curve.Fr.n8;
const nPoints = 1<<p;
let buff_r = new Uint32Array(nPoints);
let buffG;
let rng = new ffjavascript.ChaCha(seed);
if (logger) logger.debug(`Creating random numbers Powers${p}...`);
for (let i=0; i<nPoints; i++) {
buff_r[i] = rng.nextU32();
}
buff_r = new Uint8Array(buff_r.buffer, buff_r.byteOffset, buff_r.byteLength);
if (logger) logger.debug(`reading points Powers${p}...`);
await startReadUniqueSection(fd, sections, tauSection);
buffG = new ffjavascript.BigBuffer(nPoints*sG);
await fd.readToBuffer(buffG, 0, nPoints*sG);
await endReadSection(fd, true);
const resTau = await G.multiExpAffine(buffG, buff_r, logger, sectionName + "_" + p);
buff_r = new ffjavascript.BigBuffer(nPoints * n8r);
rng = new ffjavascript.ChaCha(seed);
const buff4 = new Uint8Array(4);
const buff4V = new DataView(buff4.buffer);
if (logger) logger.debug(`Creating random numbers Powers${p}...`);
for (let i=0; i<nPoints; i++) {
buff4V.setUint32(0, rng.nextU32(), true);
buff_r.set(buff4, i*n8r);
}
if (logger) logger.debug(`batchToMontgomery ${p}...`);
buff_r = await curve.Fr.batchToMontgomery(buff_r);
if (logger) logger.debug(`fft ${p}...`);
buff_r = await curve.Fr.fft(buff_r);
if (logger) logger.debug(`batchFromMontgomery ${p}...`);
buff_r = await curve.Fr.batchFromMontgomery(buff_r);
if (logger) logger.debug(`reading points Lagrange${p}...`);
await startReadUniqueSection(fd, sections, lagrangeSection);
fd.pos += sG*((1 << p)-1);
await fd.readToBuffer(buffG, 0, nPoints*sG);
await endReadSection(fd, true);
const resLagrange = await G.multiExpAffine(buffG, buff_r, logger, sectionName + "_" + p + "_transformed");
if (!G.eq(resTau, resLagrange)) {
if (logger) logger.error("Phase2 caclutation does not match with powers of tau");
return false;
}
return true;
}
}
}
/*
This function creates a new section in the fdTo file with id idSection.
It multiplies the pooints in fdFrom by first, first*inc, first*inc^2, ....
nPoint Times.
It also updates the newChallengeHasher with the new points
*/
async function applyKeyToSection(fdOld, sections, fdNew, idSection, curve, groupName, first, inc, sectionName, logger) {
const MAX_CHUNK_SIZE = 1 << 16;
const G = curve[groupName];
const sG = G.F.n8*2;
const nPoints = sections[idSection][0].size / sG;
await startReadUniqueSection(fdOld, sections,idSection );
await startWriteSection(fdNew, idSection);
let t = first;
for (let i=0; i<nPoints; i += MAX_CHUNK_SIZE) {
if (logger) logger.debug(`Applying key: ${sectionName}: ${i}/${nPoints}`);
const n= Math.min(nPoints - i, MAX_CHUNK_SIZE);
let buff;
buff = await fdOld.read(n*sG);
buff = await G.batchApplyKey(buff, t, inc);
await fdNew.write(buff);
t = curve.Fr.mul(t, curve.Fr.exp(inc, n));
}
await endWriteSection(fdNew);
await endReadSection(fdOld);
}
async function applyKeyToChallengeSection(fdOld, fdNew, responseHasher, curve, groupName, nPoints, first, inc, formatOut, sectionName, logger) {
const G = curve[groupName];
const sG = G.F.n8*2;
const chunkSize = Math.floor((1<<20) / sG); // 128Mb chunks
let t = first;
for (let i=0 ; i<nPoints ; i+= chunkSize) {
if (logger) logger.debug(`Applying key ${sectionName}: ${i}/${nPoints}`);
const n= Math.min(nPoints-i, chunkSize );
const buffInU = await fdOld.read(n * sG);
const buffInLEM = await G.batchUtoLEM(buffInU);
const buffOutLEM = await G.batchApplyKey(buffInLEM, t, inc);
let buffOut;
if (formatOut == "COMPRESSED") {
buffOut = await G.batchLEMtoC(buffOutLEM);
} else {
buffOut = await G.batchLEMtoU(buffOutLEM);
}
if (responseHasher) responseHasher.update(buffOut);
await fdNew.write(buffOut);
t = curve.Fr.mul(t, curve.Fr.exp(inc, n));
}
}
// Format of the output
async function challengeContribute(curve, challengeFilename, responesFileName, entropy, logger) {
await Blake2b.ready();
const fdFrom = await readExisting$2(challengeFilename);
const sG1 = curve.F1.n64*8*2;
const sG2 = curve.F2.n64*8*2;
const domainSize = (fdFrom.totalSize + sG1 - 64 - sG2) / (4*sG1 + sG2);
let e = domainSize;
let power = 0;
while (e>1) {
e = e /2;
power += 1;
}
if (1<<power != domainSize) throw new Error("Invalid file size");
if (logger) logger.debug("Power to tau size: "+power);
const rng = await getRandomRng(entropy);
const fdTo = await createOverride(responesFileName);
// Calculate the hash
const challengeHasher = Blake2b(64);
for (let i=0; i<fdFrom.totalSize; i+= fdFrom.pageSize) {
if (logger) logger.debug(`Hashing challenge ${i}/${fdFrom.totalSize}`);
const s = Math.min(fdFrom.totalSize - i, fdFrom.pageSize);
const buff = await fdFrom.read(s);
challengeHasher.update(buff);
}
const claimedHash = await fdFrom.read(64, 0);
if (logger) logger.info(formatHash(claimedHash, "Claimed Previous Response Hash: "));
const challengeHash = challengeHasher.digest();
if (logger) logger.info(formatHash(challengeHash, "Current Challenge Hash: "));
const key = createPTauKey(curve, challengeHash, rng);
if (logger) {
["tau", "alpha", "beta"].forEach( (k) => {
logger.debug(k + ".g1_s: " + curve.G1.toString(key[k].g1_s, 16));
logger.debug(k + ".g1_sx: " + curve.G1.toString(key[k].g1_sx, 16));
logger.debug(k + ".g2_sp: " + curve.G2.toString(key[k].g2_sp, 16));
logger.debug(k + ".g2_spx: " + curve.G2.toString(key[k].g2_spx, 16));
logger.debug("");
});
}
const responseHasher = Blake2b(64);
await fdTo.write(challengeHash);
responseHasher.update(challengeHash);
await applyKeyToChallengeSection(fdFrom, fdTo, responseHasher, curve, "G1", (1<<power)*2-1, curve.Fr.one , key.tau.prvKey, "COMPRESSED", "tauG1" , logger );
await applyKeyToChallengeSection(fdFrom, fdTo, responseHasher, curve, "G2", (1<<power) , curve.Fr.one , key.tau.prvKey, "COMPRESSED", "tauG2" , logger );
await applyKeyToChallengeSection(fdFrom, fdTo, responseHasher, curve, "G1", (1<<power) , key.alpha.prvKey, key.tau.prvKey, "COMPRESSED", "alphaTauG1", logger );
await applyKeyToChallengeSection(fdFrom, fdTo, responseHasher, curve, "G1", (1<<power) , key.beta.prvKey , key.tau.prvKey, "COMPRESSED", "betaTauG1" , logger );
await applyKeyToChallengeSection(fdFrom, fdTo, responseHasher, curve, "G2", 1 , key.beta.prvKey , key.tau.prvKey, "COMPRESSED", "betaTauG2" , logger );
// Write and hash key
const buffKey = new Uint8Array(curve.F1.n8*2*6+curve.F2.n8*2*3);
toPtauPubKeyRpr(buffKey, 0, curve, key, false);
await fdTo.write(buffKey);
responseHasher.update(buffKey);
const responseHash = responseHasher.digest();
if (logger) logger.info(formatHash(responseHash, "Contribution Response Hash: "));
await fdTo.close();
await fdFrom.close();
}
async function beacon(oldPtauFilename, newPTauFilename, name, beaconHashStr,numIterationsExp, logger) {
const beaconHash = hex2ByteArray(beaconHashStr);
if ( (beaconHash.byteLength == 0)
|| (beaconHash.byteLength*2 !=beaconHashStr.length))
{
if (logger) logger.error("Invalid Beacon Hash. (It must be a valid hexadecimal sequence)");
return false;
}
if (beaconHash.length>=256) {
if (logger) logger.error("Maximum lenght of beacon hash is 255 bytes");
return false;
}
numIterationsExp = parseInt(numIterationsExp);
if ((numIterationsExp<10)||(numIterationsExp>63)) {
if (logger) logger.error("Invalid numIterationsExp. (Must be between 10 and 63)");
return false;
}
await Blake2b.ready();
const {fd: fdOld, sections} = await readBinFile(oldPtauFilename, "ptau", 1);
const {curve, power, ceremonyPower} = await readPTauHeader(fdOld, sections);
if (power != ceremonyPower) {
if (logger) logger.error("This file has been reduced. You cannot contribute into a reduced file.");
return false;
}
if (sections[12]) {
if (logger) logger.warn("Contributing into a file that has phase2 calculated. You will have to prepare phase2 again.");
}
const contributions = await readContributions(fdOld, curve, sections);
const curContribution = {
name: name,
type: 1, // Beacon
numIterationsExp: numIterationsExp,
beaconHash: beaconHash
};
let lastChallengeHash;
if (contributions.length>0) {
lastChallengeHash = contributions[contributions.length-1].nextChallenge;
} else {
lastChallengeHash = calculateFirstChallengeHash(curve, power, logger);
}
curContribution.key = keyFromBeacon(curve, lastChallengeHash, beaconHash, numIterationsExp);
const responseHasher = new Blake2b(64);
responseHasher.update(lastChallengeHash);
const fdNew = await createBinFile(newPTauFilename, "ptau", 1, 7);
await writePTauHeader(fdNew, curve, power);
const startSections = [];
let firstPoints;
firstPoints = await processSection(2, "G1", (1<<power) * 2 -1, curve.Fr.e(1), curContribution.key.tau.prvKey, "tauG1", logger );
curContribution.tauG1 = firstPoints[1];
firstPoints = await processSection(3, "G2", (1<<power) , curve.Fr.e(1), curContribution.key.tau.prvKey, "tauG2", logger );
curContribution.tauG2 = firstPoints[1];
firstPoints = await processSection(4, "G1", (1<<power) , curContribution.key.alpha.prvKey, curContribution.key.tau.prvKey, "alphaTauG1", logger );
curContribution.alphaG1 = firstPoints[0];
firstPoints = await processSection(5, "G1", (1<<power) , curContribution.key.beta.prvKey, curContribution.key.tau.prvKey, "betaTauG1", logger );
curContribution.betaG1 = firstPoints[0];
firstPoints = await processSection(6, "G2", 1, curContribution.key.beta.prvKey, curContribution.key.tau.prvKey, "betaTauG2", logger );
curContribution.betaG2 = firstPoints[0];
curContribution.partialHash = responseHasher.getPartialHash();
const buffKey = new Uint8Array(curve.F1.n8*2*6+curve.F2.n8*2*3);
toPtauPubKeyRpr(buffKey, 0, curve, curContribution.key, false);
responseHasher.update(new Uint8Array(buffKey));
const hashResponse = responseHasher.digest();
if (logger) logger.info(formatHash(hashResponse, "Contribution Response Hash imported: "));
const nextChallengeHasher = new Blake2b(64);
nextChallengeHasher.update(hashResponse);
await hashSection(fdNew, "G1", 2, (1 << power) * 2 -1, "tauG1", logger);
await hashSection(fdNew, "G2", 3, (1 << power) , "tauG2", logger);
await hashSection(fdNew, "G1", 4, (1 << power) , "alphaTauG1", logger);
await hashSection(fdNew, "G1", 5, (1 << power) , "betaTauG1", logger);
await hashSection(fdNew, "G2", 6, 1 , "betaG2", logger);
curContribution.nextChallenge = nextChallengeHasher.digest();
if (logger) logger.info(formatHash(curContribution.nextChallenge, "Next Challenge Hash: "));
contributions.push(curContribution);
await writeContributions(fdNew, curve, contributions);
await fdOld.close();
await fdNew.close();
return hashResponse;
async function processSection(sectionId, groupName, NPoints, first, inc, sectionName, logger) {
const res = [];
fdOld.pos = sections[sectionId][0].p;
await startWriteSection(fdNew, sectionId);
startSections[sectionId] = fdNew.pos;
const G = curve[groupName];
const sG = G.F.n8*2;
const chunkSize = Math.floor((1<<20) / sG); // 128Mb chunks
let t = first;
for (let i=0 ; i<NPoints ; i+= chunkSize) {
if (logger) logger.debug(`applying key${sectionName}: ${i}/${NPoints}`);
const n= Math.min(NPoints-i, chunkSize );
const buffIn = await fdOld.read(n * sG);
const buffOutLEM = await G.batchApplyKey(buffIn, t, inc);
/* Code to test the case where we don't have the 2^m-2 component
if (sectionName== "tauG1") {
const bz = new Uint8Array(64);
buffOutLEM.set(bz, 64*((1 << power) - 1 ));
}
*/
const promiseWrite = fdNew.write(buffOutLEM);
const buffOutC = await G.batchLEMtoC(buffOutLEM);
responseHasher.update(buffOutC);
await promiseWrite;
if (i==0) // Return the 2 first points.
for (let j=0; j<Math.min(2, NPoints); j++)
res.push(G.fromRprLEM(buffOutLEM, j*sG));
t = curve.Fr.mul(t, curve.Fr.exp(inc, n));
}
await endWriteSection(fdNew);
return res;
}
async function hashSection(fdTo, groupName, sectionId, nPoints, sectionName, logger) {
const G = curve[groupName];
const sG = G.F.n8*2;
const nPointsChunk = Math.floor((1<<24)/sG);
const oldPos = fdTo.pos;
fdTo.pos = startSections[sectionId];
for (let i=0; i< nPoints; i += nPointsChunk) {
if (logger) logger.debug(`Hashing ${sectionName}: ${i}/${nPoints}`);
const n = Math.min(nPoints-i, nPointsChunk);
const buffLEM = await fdTo.read(n * sG);
const buffU = await G.batchLEMtoU(buffLEM);
nextChallengeHasher.update(buffU);
}
fdTo.pos = oldPos;
}
}
// Format of the output
async function contribute(oldPtauFilename, newPTauFilename, name, entropy, logger) {
await Blake2b.ready();
const {fd: fdOld, sections} = await readBinFile(oldPtauFilename, "ptau", 1);
const {curve, power, ceremonyPower} = await readPTauHeader(fdOld, sections);
if (power != ceremonyPower) {
if (logger) logger.error("This file has been reduced. You cannot contribute into a reduced file.");
throw new Error("This file has been reduced. You cannot contribute into a reduced file.");
}
if (sections[12]) {
if (logger) logger.warn("WARNING: Contributing into a file that has phase2 calculated. You will have to prepare phase2 again.");
}
const contributions = await readContributions(fdOld, curve, sections);
const curContribution = {
name: name,
type: 0, // Beacon
};
let lastChallengeHash;
const rng = await getRandomRng(entropy);
if (contributions.length>0) {
lastChallengeHash = contributions[contributions.length-1].nextChallenge;
} else {
lastChallengeHash = calculateFirstChallengeHash(curve, power, logger);
}
// Generate a random key
curContribution.key = createPTauKey(curve, lastChallengeHash, rng);
const responseHasher = new Blake2b(64);
responseHasher.update(lastChallengeHash);
const fdNew = await createBinFile(newPTauFilename, "ptau", 1, 7);
await writePTauHeader(fdNew, curve, power);
const startSections = [];
let firstPoints;
firstPoints = await processSection(2, "G1", (1<<power) * 2 -1, curve.Fr.e(1), curContribution.key.tau.prvKey, "tauG1" );
curContribution.tauG1 = firstPoints[1];
firstPoints = await processSection(3, "G2", (1<<power) , curve.Fr.e(1), curContribution.key.tau.prvKey, "tauG2" );
curContribution.tauG2 = firstPoints[1];
firstPoints = await processSection(4, "G1", (1<<power) , curContribution.key.alpha.prvKey, curContribution.key.tau.prvKey, "alphaTauG1" );
curContribution.alphaG1 = firstPoints[0];
firstPoints = await processSection(5, "G1", (1<<power) , curContribution.key.beta.prvKey, curContribution.key.tau.prvKey, "betaTauG1" );
curContribution.betaG1 = firstPoints[0];
firstPoints = await processSection(6, "G2", 1, curContribution.key.beta.prvKey, curContribution.key.tau.prvKey, "betaTauG2" );
curContribution.betaG2 = firstPoints[0];
curContribution.partialHash = responseHasher.getPartialHash();
const buffKey = new Uint8Array(curve.F1.n8*2*6+curve.F2.n8*2*3);
toPtauPubKeyRpr(buffKey, 0, curve, curContribution.key, false);
responseHasher.update(new Uint8Array(buffKey));
const hashResponse = responseHasher.digest();
if (logger) logger.info(formatHash(hashResponse, "Contribution Response Hash imported: "));
const nextChallengeHasher = new Blake2b(64);
nextChallengeHasher.update(hashResponse);
await hashSection(fdNew, "G1", 2, (1 << power) * 2 -1, "tauG1");
await hashSection(fdNew, "G2", 3, (1 << power) , "tauG2");
await hashSection(fdNew, "G1", 4, (1 << power) , "alphaTauG1");
await hashSection(fdNew, "G1", 5, (1 << power) , "betaTauG1");
await hashSection(fdNew, "G2", 6, 1 , "betaG2");
curContribution.nextChallenge = nextChallengeHasher.digest();
if (logger) logger.info(formatHash(curContribution.nextChallenge, "Next Challenge Hash: "));
contributions.push(curContribution);
await writeContributions(fdNew, curve, contributions);
await fdOld.close();
await fdNew.close();
return hashResponse;
async function processSection(sectionId, groupName, NPoints, first, inc, sectionName) {
const res = [];
fdOld.pos = sections[sectionId][0].p;
await startWriteSection(fdNew, sectionId);
startSections[sectionId] = fdNew.pos;
const G = curve[groupName];
const sG = G.F.n8*2;
const chunkSize = Math.floor((1<<20) / sG); // 128Mb chunks
let t = first;
for (let i=0 ; i<NPoints ; i+= chunkSize) {
if (logger) logger.debug(`processing: ${sectionName}: ${i}/${NPoints}`);
const n= Math.min(NPoints-i, chunkSize );
const buffIn = await fdOld.read(n * sG);
const buffOutLEM = await G.batchApplyKey(buffIn, t, inc);
/* Code to test the case where we don't have the 2^m-2 component
if (sectionName== "tauG1") {
const bz = new Uint8Array(64);
buffOutLEM.set(bz, 64*((1 << power) - 1 ));
}
*/
const promiseWrite = fdNew.write(buffOutLEM);
const buffOutC = await G.batchLEMtoC(buffOutLEM);
responseHasher.update(buffOutC);
await promiseWrite;
if (i==0) // Return the 2 first points.
for (let j=0; j<Math.min(2, NPoints); j++)
res.push(G.fromRprLEM(buffOutLEM, j*sG));
t = curve.Fr.mul(t, curve.Fr.exp(inc, n));
}
await endWriteSection(fdNew);
return res;
}
async function hashSection(fdTo, groupName, sectionId, nPoints, sectionName) {
const G = curve[groupName];
const sG = G.F.n8*2;
const nPointsChunk = Math.floor((1<<24)/sG);
const oldPos = fdTo.pos;
fdTo.pos = startSections[sectionId];
for (let i=0; i< nPoints; i += nPointsChunk) {
if ((logger)&&i) logger.debug(`Hashing ${sectionName}: ` + i);
const n = Math.min(nPoints-i, nPointsChunk);
const buffLEM = await fdTo.read(n * sG);
const buffU = await G.batchLEMtoU(buffLEM);
nextChallengeHasher.update(buffU);
}
fdTo.pos = oldPos;
}
}
async function preparePhase2(oldPtauFilename, newPTauFilename, logger) {
const {fd: fdOld, sections} = await readBinFile(oldPtauFilename, "ptau", 1);
const {curve, power} = await readPTauHeader(fdOld, sections);
const fdNew = await createBinFile(newPTauFilename, "ptau", 1, 11);
await writePTauHeader(fdNew, curve, power);
// const fdTmp = await fastFile.createOverride(newPTauFilename+ ".tmp");
const fdTmp = await createOverride({type: "bigMem"});
await copySection(fdOld, sections, fdNew, 2);
await copySection(fdOld, sections, fdNew, 3);
await copySection(fdOld, sections, fdNew, 4);
await copySection(fdOld, sections, fdNew, 5);
await copySection(fdOld, sections, fdNew, 6);
await copySection(fdOld, sections, fdNew, 7);
await processSection(2, 12, "G1", "tauG1" );
await processSection(3, 13, "G2", "tauG2" );
await processSection(4, 14, "G1", "alphaTauG1" );
await processSection(5, 15, "G1", "betaTauG1" );
await fdOld.close();
await fdNew.close();
await fdTmp.close();
// await fs.promises.unlink(newPTauFilename+ ".tmp");
return;
async function processSection(oldSectionId, newSectionId, Gstr, sectionName) {
const CHUNKPOW = 16;
if (logger) logger.debug("Starting section: "+sectionName);
await startWriteSection(fdNew, newSectionId);
for (let p=0; p<=power; p++) {
await processSectionPower(p);
}
await endWriteSection(fdNew);
async function processSectionPower(p) {
const chunkPower = p > CHUNKPOW ? CHUNKPOW : p;
const pointsPerChunk = 1<<chunkPower;
const nPoints = 1 << p;
const nChunks = nPoints / pointsPerChunk;
const G = curve[Gstr];
const Fr = curve.Fr;
const sGin = G.F.n8*2;
const sGmid = G.F.n8*3;
await startReadUniqueSection(fdOld, sections, oldSectionId);
// Build the initial tmp Buff
fdTmp.pos =0;
for (let i=0; i<nChunks; i++) {
let buff;
if (logger) logger.debug(`${sectionName} Prepare ${i+1}/${nChunks}`);
buff = await fdOld.read(pointsPerChunk*sGin);
buff = await G.batchToJacobian(buff);
for (let j=0; j<pointsPerChunk; j++) {
fdTmp.pos = bitReverse(i*pointsPerChunk+j, p)*sGmid;
await fdTmp.write(buff.slice(j*sGmid, (j+1)*sGmid ));
}
}
await endReadSection(fdOld, true);
for (let j=0; j<nChunks; j++) {
if (logger) logger.debug(`${sectionName} ${p} FFTMix ${j+1}/${nChunks}`);
let buff;
fdTmp.pos = (j*pointsPerChunk)*sGmid;
buff = await fdTmp.read(pointsPerChunk*sGmid);
buff = await G.fftMix(buff);
fdTmp.pos = (j*pointsPerChunk)*sGmid;
await fdTmp.write(buff);
}
for (let i=chunkPower+1; i<= p; i++) {
const nGroups = 1 << (p - i);
const nChunksPerGroup = nChunks / nGroups;
for (let j=0; j<nGroups; j++) {
for (let k=0; k <nChunksPerGroup/2; k++) {
if (logger) logger.debug(`${sectionName} ${i}/${p} FFTJoin ${j+1}/${nGroups} ${k+1}/${nChunksPerGroup/2}`);
const first = Fr.exp( Fr.w[i], k*pointsPerChunk);
const inc = Fr.w[i];
const o1 = j*nChunksPerGroup + k;
const o2 = j*nChunksPerGroup + k + nChunksPerGroup/2;
let buff1, buff2;
fdTmp.pos = o1*pointsPerChunk*sGmid;
buff1 = await fdTmp.read(pointsPerChunk * sGmid);
fdTmp.pos = o2*pointsPerChunk*sGmid;
buff2 = await fdTmp.read(pointsPerChunk * sGmid);
[buff1, buff2] = await G.fftJoin(buff1, buff2, first, inc);
fdTmp.pos = o1*pointsPerChunk*sGmid;
await fdTmp.write(buff1);
fdTmp.pos = o2*pointsPerChunk*sGmid;
await fdTmp.write(buff2);
}
}
}
await finalInverse(p);
}
async function finalInverse(p) {
const G = curve[Gstr];
const Fr = curve.Fr;
const sGmid = G.F.n8*3;
const sGout = G.F.n8*2;
const chunkPower = p > CHUNKPOW ? CHUNKPOW : p;
const pointsPerChunk = 1<<chunkPower;
const nPoints = 1 << p;
const nChunks = nPoints / pointsPerChunk;
const o = fdNew.pos;
fdTmp.pos = 0;
const factor = Fr.inv( Fr.e( 1<< p));
for (let i=0; i<nChunks; i++) {
if (logger) logger.debug(`${sectionName} ${p} FFTFinal ${i+1}/${nChunks}`);
let buff;
buff = await fdTmp.read(pointsPerChunk * sGmid);
buff = await G.fftFinal(buff, factor);
if ( i == 0) {
fdNew.pos = o;
await fdNew.write(buff.slice((pointsPerChunk-1)*sGout));
fdNew.pos = o + ((nChunks - 1)*pointsPerChunk + 1) * sGout;
await fdNew.write(buff.slice(0, (pointsPerChunk-1)*sGout));
} else {
fdNew.pos = o + ((nChunks - 1 - i)*pointsPerChunk + 1) * sGout;
await fdNew.write(buff);
}
}
fdNew.pos = o + nChunks * pointsPerChunk * sGout;
}
}
}
async function exportJson(pTauFilename, verbose) {
const {fd, sections} = await readBinFile(pTauFilename, "ptau", 1);
const {curve, power} = await readPTauHeader(fd, sections);
const pTau = {};
pTau.q = curve.q;
pTau.power = power;
pTau.contributions = await readContributions(fd, curve, sections);
pTau.tauG1 = await exportSection(2, "G1", (1 << power)*2 -1, "tauG1");
pTau.tauG2 = await exportSection(3, "G2", (1 << power), "tauG2");
pTau.alphaTauG1 = await exportSection(4, "G1", (1 << power), "alphaTauG1");
pTau.betaTauG1 = await exportSection(5, "G1", (1 << power), "betaTauG1");
pTau.betaG2 = await exportSection(6, "G2", 1, "betaG2");
pTau.lTauG1 = await exportLagrange(12, "G1", "lTauG1");
pTau.lTauG2 = await exportLagrange(13, "G2", "lTauG2");
pTau.lAlphaTauG1 = await exportLagrange(14, "G1", "lAlphaTauG2");
pTau.lBetaTauG1 = await exportLagrange(15, "G1", "lBetaTauG2");
await fd.close();
return pTau;
async function exportSection(sectionId, groupName, nPoints, sectionName) {
const G = curve[groupName];
const sG = G.F.n8*2;
const res = [];
await startReadUniqueSection(fd, sections, sectionId);
for (let i=0; i< nPoints; i++) {
if ((verbose)&&i&&(i%10000 == 0)) console.log(`${sectionName}: ` + i);
const buff = await fd.read(sG);
res.push(G.fromRprLEM(buff, 0));
}
await endReadSection(fd);
return res;
}
async function exportLagrange(sectionId, groupName, sectionName) {
const G = curve[groupName];
const sG = G.F.n8*2;
const res = [];
await startReadUniqueSection(fd, sections, sectionId);
for (let p=0; p<=power; p++) {
if (verbose) console.log(`${sectionName}: Power: ${p}`);
res[p] = [];
const nPoints = (1<<p);
for (let i=0; i<nPoints; i++) {
if ((verbose)&&i&&(i%10000 == 0)) console.log(`${sectionName}: ${i}/${nPoints}`);
const buff = await fd.read(sG);
res[p].push(G.fromRprLEM(buff, 0));
}
}
await endReadSection(fd);
return res;
}
}
var powersoftau = /*#__PURE__*/Object.freeze({
__proto__: null,
newAccumulator: newAccumulator,
exportChallenge: exportChallenge,
importResponse: importResponse,
verify: verify,
challengeContribute: challengeContribute,
beacon: beacon,
contribute: contribute,
preparePhase2: preparePhase2,
exportJson: exportJson
});
function r1csPrint(r1cs, syms, logger) {
for (let i=0; i<r1cs.constraints.length; i++) {
printCostraint(r1cs.constraints[i]);
}
function printCostraint(c) {
const lc2str = (lc) => {
let S = "";
const keys = Object.keys(lc);
keys.forEach( (k) => {
let name = syms.varIdx2Name[k];
if (name == "one") name = "";
let vs = r1cs.Fr.toString(lc[k]);
if (vs == "1") vs = ""; // Do not show ones
if (vs == "-1") vs = "-"; // Do not show ones
if ((S!="")&&(vs[0]!="-")) vs = "+"+vs;
if (S!="") vs = " "+vs;
S= S + vs + name;
});
return S;
};
const S = `[ ${lc2str(c[0])} ] * [ ${lc2str(c[1])} ] - [ ${lc2str(c[2])} ] = 0`;
if (logger) logger.info(S);
}
}
async function open$1(fileName, openFlags, cacheSize) {
cacheSize = cacheSize || 4096*64;
if (["w+", "wx+", "r", "ax+", "a+"].indexOf(openFlags) <0)
throw new Error("Invalid open option");
const fd =await fs.promises.open(fileName, openFlags);
const stats = await fd.stat();
return new FastFile$1(fd, stats, cacheSize, fileName);
}
class FastFile$1 {
constructor(fd, stats, cacheSize, fileName) {
this.fileName = fileName;
this.fd = fd;
this.pos = 0;
this.pageBits = 8;
this.pageSize = (1 << this.pageBits);
while (this.pageSize < stats.blksize*4) {
this.pageBits ++;
this.pageSize *= 2;
}
this.totalSize = stats.size;
this.totalPages = Math.floor((stats.size -1) / this.pageSize)+1;
this.maxPagesLoaded = Math.floor( cacheSize / this.pageSize)+1;
this.pages = {};
this.pendingLoads = [];
this.writing = false;
this.reading = false;
}
_loadPage(p) {
const self = this;
return new Promise((resolve, reject)=> {
self.pendingLoads.push({
page: p,
resolve: resolve,
reject: reject
});
setImmediate(self._triggerLoad.bind(self));
});
}
_triggerLoad() {
const self = this;
processPendingLoads();
if (self.pendingLoads.length == 0) return;
if (Object.keys(self.pages).length >= self.maxPagesLoaded) {
const dp = getDeletablePage();
if (dp<0) { // // No sizes available
// setTimeout(self._triggerLoad.bind(self), 10000);
return;
}
delete self.pages[dp];
}
const load = self.pendingLoads.shift();
if (load.page>=self.totalPages) {
self.pages[load.page] = {
dirty: false,
buff: new Uint8Array(self.pageSize),
pendingOps: 1,
size: 0
};
load.resolve();
setImmediate(self._triggerLoad.bind(self));
return;
}
if (self.reading) {
self.pendingLoads.unshift(load);
return; // Only one read at a time.
}
self.reading = true;
const page = {
dirty: false,
buff: new Uint8Array(self.pageSize),
pendingOps: 1,
size: 0
};
self.fd.read(page.buff, 0, self.pageSize, load.page*self.pageSize).then((res)=> {
page.size = res.bytesRead;
self.pages[load.page] = page;
self.reading = false;
load.resolve();
setImmediate(self._triggerLoad.bind(self));
}, (err) => {
load.reject(err);
});
function processPendingLoads() {
const newPendingLoads = [];
for (let i=0; i<self.pendingLoads.length; i++) {
const load = self.pendingLoads[i];
if (typeof self.pages[load.page] != "undefined") {
self.pages[load.page].pendingOps ++;
load.resolve();
} else {
newPendingLoads.push(load);
}
}
self.pendingLoads = newPendingLoads;
}
function getDeletablePage() {
for (let p in self.pages) {
const page = self.pages[p];
if ((page.dirty == false)&&(page.pendingOps==0)) return p;
}
return -1;
}
}
_triggerWrite() {
const self = this;
if (self.writing) return;
const p = self._getDirtyPage();
if (p<0) {
if (self.pendingClose) self.pendingClose();
return;
}
self.writing=true;
self.pages[p].dirty = false;
self.fd.write(self.pages[p].buff, 0, self.pages[p].size, p*self.pageSize).then(() => {
self.writing = false;
setImmediate(self._triggerWrite.bind(self));
setImmediate(self._triggerLoad.bind(self));
}, (err) => {
console.log("ERROR Writing: "+err);
self.error = err;
self._tryClose();
});
}
_getDirtyPage() {
for (let p in this.pages) {
if (this.pages[p].dirty) return p;
}
return -1;
}
async write(buff, pos) {
if (buff.byteLength == 0) return;
const self = this;
if (buff.byteLength > self.pageSize*self.maxPagesLoaded*0.8) {
const cacheSize = Math.floor(buff.byteLength * 1.1);
this.maxPagesLoaded = Math.floor( cacheSize / self.pageSize)+1;
}
if (typeof pos == "undefined") pos = self.pos;
self.pos = pos+buff.byteLength;
if (self.totalSize < pos + buff.byteLength) self.totalSize = pos + buff.byteLength;
if (self.pendingClose)
throw new Error("Writing a closing file");
const firstPage = Math.floor(pos / self.pageSize);
const lastPage = Math.floor((pos+buff.byteLength-1) / self.pageSize);
for (let i=firstPage; i<=lastPage; i++) await self._loadPage(i);
let p = firstPage;
let o = pos % self.pageSize;
let r = buff.byteLength;
while (r>0) {
const l = (o+r > self.pageSize) ? (self.pageSize -o) : r;
const srcView = new Uint8Array(buff.buffer, buff.byteLength - r, l);
const dstView = new Uint8Array(self.pages[p].buff.buffer, o, l);
dstView.set(srcView);
self.pages[p].dirty = true;
self.pages[p].pendingOps --;
self.pages[p].size = Math.max(o+l, self.pages[p].size);
if (p>=self.totalPages) {
self.totalPages = p+1;
}
r = r-l;
p ++;
o = 0;
}
setImmediate(self._triggerWrite.bind(self));
}
async read(len, pos) {
if (len == 0) {
return new Uint8Array(0);
}
const self = this;
if (len > self.pageSize*self.maxPagesLoaded*0.8) {
const cacheSize = Math.floor(len * 1.1);
this.maxPagesLoaded = Math.floor( cacheSize / self.pageSize)+1;
}
if (typeof pos == "undefined") pos = self.pos;
self.pos = pos+len;
if (self.pendingClose)
throw new Error("Reading a closing file");
const firstPage = Math.floor(pos / self.pageSize);
const lastPage = Math.floor((pos+len-1) / self.pageSize);
for (let i=firstPage; i<=lastPage; i++) await self._loadPage(i);
let buff = new Uint8Array(len);
let dstView = new Uint8Array(buff);
let p = firstPage;
let o = pos % self.pageSize;
// Remaining bytes to read
let r = pos + len > self.totalSize ? len - (pos + len - self.totalSize): len;
while (r>0) {
// bytes to copy from this page
const l = (o+r > self.pageSize) ? (self.pageSize -o) : r;
const srcView = new Uint8Array(self.pages[p].buff.buffer, o, l);
buff.set(srcView, dstView.byteLength-r);
self.pages[p].pendingOps --;
r = r-l;
p ++;
o = 0;
}
setImmediate(self._triggerLoad.bind(self));
return buff;
}
_tryClose() {
const self = this;
if (!self.pendingClose) return;
if (self.error) {
self.pendingCloseReject(self.error);
}
const p = self._getDirtyPage();
if ((p>=0) || (self.writing) || (self.reading) || (self.pendingLoads.length>0)) return;
self.pendingClose();
}
close() {
const self = this;
if (self.pendingClose)
throw new Error("Closing the file twice");
return new Promise((resolve, reject) => {
self.pendingClose = resolve;
self.pendingCloseReject = reject;
self._tryClose();
}).then(()=> {
self.fd.close();
}, (err) => {
self.fd.close();
throw (err);
});
}
async discard() {
const self = this;
await self.close();
await fs.promises.unlink(this.fileName);
}
async writeULE32(v, pos) {
const self = this;
const b = Uint32Array.of(v);
await self.write(new Uint8Array(b.buffer), pos);
}
async writeUBE32(v, pos) {
const self = this;
const buff = new Uint8Array(4);
const buffV = new DataView(buff.buffer);
buffV.setUint32(0, v, false);
await self.write(buff, pos);
}
async writeULE64(v, pos) {
const self = this;
const b = Uint32Array.of(v & 0xFFFFFFFF, Math.floor(v / 0x100000000));
await self.write(new Uint8Array(b.buffer), pos);
}
async readULE32(pos) {
const self = this;
const b = await self.read(4, pos);
const view = new Uint32Array(b.buffer);
return view[0];
}
async readUBE32(pos) {
const self = this;
const b = await self.read(4, pos);
const view = new DataView(b.buffer);
return view.getUint32(0, false);
}
async readULE64(pos) {
const self = this;
const b = await self.read(8, pos);
const view = new Uint32Array(b.buffer);
return view[1] * 0x100000000 + view[0];
}
}
function readExisting$3(o) {
const fd = new MemFile$1();
fd.o = o;
fd.allocSize = o.data.byteLength;
fd.totalSize = o.data.byteLength;
fd.readOnly = true;
fd.pos = 0;
return fd;
}
class MemFile$1 {
constructor() {
this.pageSize = 1 << 14; // for compatibility
}
_resizeIfNeeded(newLen) {
if (newLen > this.allocSize) {
const newAllocSize = Math.max(
this.allocSize + (1 << 20),
Math.floor(this.allocSize * 1.1),
newLen
);
const newData = new Uint8Array(newAllocSize);
newData.set(this.o.data);
this.o.data = newData;
this.allocSize = newAllocSize;
}
}
async write(buff, pos) {
const self =this;
if (typeof pos == "undefined") pos = self.pos;
if (this.readOnly) throw new Error("Writing a read only file");
this._resizeIfNeeded(pos + buff.byteLength);
this.o.data.set(buff, pos);
if (pos + buff.byteLength > this.totalSize) this.totalSize = pos + buff.byteLength;
this.pos = pos + buff.byteLength;
}
async read(len, pos) {
const self = this;
if (typeof pos == "undefined") pos = self.pos;
if (this.readOnly) {
if (pos + len > this.totalSize) throw new Error("Reading out of bounds");
}
this._resizeIfNeeded(pos + len);
const buff = this.o.data.slice(pos, pos+len);
this.pos = pos + len;
return buff;
}
close() {
if (this.o.data.byteLength != this.totalSize) {
this.o.data = this.o.data.slice(0, this.totalSize);
}
}
async discard() {
}
async writeULE32(v, pos) {
const self = this;
const b = Uint32Array.of(v);
await self.write(new Uint8Array(b.buffer), pos);
}
async writeUBE32(v, pos) {
const self = this;
const buff = new Uint8Array(4);
const buffV = new DataView(buff.buffer);
buffV.setUint32(0, v, false);
await self.write(buff, pos);
}
async writeULE64(v, pos) {
const self = this;
const b = Uint32Array.of(v & 0xFFFFFFFF, Math.floor(v / 0x100000000));
await self.write(new Uint8Array(b.buffer), pos);
}
async readULE32(pos) {
const self = this;
const b = await self.read(4, pos);
const view = new Uint32Array(b.buffer);
return view[0];
}
async readUBE32(pos) {
const self = this;
const b = await self.read(4, pos);
const view = new DataView(b.buffer);
return view.getUint32(0, false);
}
async readULE64(pos) {
const self = this;
const b = await self.read(8, pos);
const view = new Uint32Array(b.buffer);
return view[1] * 0x100000000 + view[0];
}
}
/* global fetch */
async function readExisting$4(o, b) {
if (o instanceof Uint8Array) {
o = {
type: "mem",
data: o
};
}
if (process.browser) {
if (typeof o === "string") {
const buff = await fetch(o).then( function(res) {
return res.arrayBuffer();
}).then(function (ab) {
return new Uint8Array(ab);
});
o = {
type: "mem",
data: buff
};
}
} else {
if (typeof o === "string") {
o = {
type: "file",
fileName: o,
cacheSize: b
};
}
}
if (o.type == "file") {
return await open$1(o.fileName, "r", o.cacheSize);
} else if (o.type == "mem") {
return await readExisting$3(o);
} else {
throw new Error("Invalid FastFile type: "+o.type);
}
}
async function readBinFile$1(fileName, type, maxVersion) {
const fd = await readExisting$4(fileName);
const b = await fd.read(4);
let readedType = "";
for (let i=0; i<4; i++) readedType += String.fromCharCode(b[i]);
if (readedType != type) throw new Error(fileName + ": Invalid File format");
let v = await fd.readULE32();
if (v>maxVersion) throw new Error("Version not supported");
const nSections = await fd.readULE32();
// Scan sections
let sections = [];
for (let i=0; i<nSections; i++) {
let ht = await fd.readULE32();
let hl = await fd.readULE64();
if (typeof sections[ht] == "undefined") sections[ht] = [];
sections[ht].push({
p: fd.pos,
size: hl
});
fd.pos += hl;
}
return {fd, sections};
}
async function startReadUniqueSection$1(fd, sections, idSection) {
if (typeof fd.readingSection != "undefined")
throw new Error("Already reading a section");
if (!sections[idSection]) throw new Error(fd.fileName + ": Missing section "+ idSection );
if (sections[idSection].length>1) throw new Error(fd.fileName +": Section Duplicated " +idSection);
fd.pos = sections[idSection][0].p;
fd.readingSection = sections[idSection][0];
}
async function endReadSection$1(fd, noCheck) {
if (typeof fd.readingSection == "undefined")
throw new Error("Not reading a section");
if (!noCheck) {
if (fd.pos-fd.readingSection.p != fd.readingSection.size)
throw new Error("Invalid section size");
}
delete fd.readingSection;
}
async function readBigInt$1(fd, n8, pos) {
const buff = await fd.read(n8, pos);
return ffjavascript.Scalar.fromRprLE(buff, 0, n8);
}
async function loadHeader(fd,sections) {
const res = {};
await startReadUniqueSection$1(fd, sections, 1);
// Read Header
res.n8 = await fd.readULE32();
res.prime = await readBigInt$1(fd, res.n8);
res.Fr = new ffjavascript.ZqField(res.prime);
res.nVars = await fd.readULE32();
res.nOutputs = await fd.readULE32();
res.nPubInputs = await fd.readULE32();
res.nPrvInputs = await fd.readULE32();
res.nLabels = await fd.readULE64();
res.nConstraints = await fd.readULE32();
await endReadSection$1(fd);
return res;
}
async function load(fileName, loadConstraints, loadMap) {
const {fd, sections} = await readBinFile$1(fileName, "r1cs", 1);
const res = await loadHeader(fd, sections);
if (loadConstraints) {
await startReadUniqueSection$1(fd, sections, 2);
res.constraints = [];
for (let i=0; i<res.nConstraints; i++) {
const c = await readConstraint();
res.constraints.push(c);
}
await endReadSection$1(fd);
}
// Read Labels
if (loadMap) {
await startReadUniqueSection$1(fd, sections, 3);
res.map = [];
for (let i=0; i<res.nVars; i++) {
const idx = await fd.readULE64();
res.map.push(idx);
}
await endReadSection$1(fd);
}
await fd.close();
return res;
async function readConstraint() {
const c = [];
c[0] = await readLC();
c[1] = await readLC();
c[2] = await readLC();
return c;
}
async function readLC() {
const lc= {};
const nIdx = await fd.readULE32();
for (let i=0; i<nIdx; i++) {
const idx = await fd.readULE32();
const val = res.Fr.e(await readBigInt$1(fd, res.n8));
lc[idx] = val;
}
return lc;
}
}
const bls12381r$1 = ffjavascript.Scalar.e("73eda753299d7d483339d80809a1d80553bda402fffe5bfeffffffff00000001", 16);
const bn128r$1 = ffjavascript.Scalar.e("21888242871839275222246405745257275088548364400416034343698204186575808495617");
async function r1csInfo(r1csName, logger) {
const cir = await load(r1csName);
if (ffjavascript.Scalar.eq(cir.prime, bn128r$1)) {
if (logger) logger.info("Curve: bn-128");
} else if (ffjavascript.Scalar.eq(cir.prime, bls12381r$1)) {
if (logger) logger.info("Curve: bls12-381");
} else {
if (logger) logger.info(`Unknown Curve. Prime: ${ffjavascript.Scalar.toString(cir.prime)}`);
}
if (logger) logger.info(`# of Wires: ${cir.nVars}`);
if (logger) logger.info(`# of Constraints: ${cir.nConstraints}`);
if (logger) logger.info(`# of Private Inputs: ${cir.nPrvInputs}`);
if (logger) logger.info(`# of Public Inputs: ${cir.nPubInputs}`);
if (logger) logger.info(`# of Outputs: ${cir.nOutputs}`);
return cir;
}
async function r1csExportJson(r1csFileName, logger) {
const cir = await load(r1csFileName, true, true);
return cir;
}
var r1cs = /*#__PURE__*/Object.freeze({
__proto__: null,
print: r1csPrint,
info: r1csInfo,
exportJson: r1csExportJson
});
async function loadSymbols(symFileName) {
const sym = {
labelIdx2Name: [ "one" ],
varIdx2Name: [ "one" ],
componentIdx2Name: []
};
const fd = await readExisting$2(symFileName);
const buff = await fd.read(fd.totalSize);
const symsStr = new TextDecoder("utf-8").decode(buff);
const lines = symsStr.split("\n");
for (let i=0; i<lines.length; i++) {
const arr = lines[i].split(",");
if (arr.length!=4) continue;
if (sym.varIdx2Name[arr[1]]) {
sym.varIdx2Name[arr[1]] += "|" + arr[3];
} else {
sym.varIdx2Name[arr[1]] = arr[3];
}
sym.labelIdx2Name[arr[0]] = arr[3];
if (!sym.componentIdx2Name[arr[2]]) {
sym.componentIdx2Name[arr[2]] = extractComponent(arr[3]);
}
}
await fd.close();
return sym;
function extractComponent(name) {
const arr = name.split(".");
arr.pop(); // Remove the lasr element
return arr.join(".");
}
}
const { WitnessCalculatorBuilder: WitnessCalculatorBuilder$1 } = circomRuntime;
async function wtnsDebug(input, wasmFileName, wtnsFileName, symName, options, logger) {
const fdWasm = await readExisting$2(wasmFileName);
const wasm = await fdWasm.read(fdWasm.totalSize);
await fdWasm.close();
let wcOps = {
sanityCheck: true
};
let sym = await loadSymbols(symName);
if (options.set) {
if (!sym) sym = await loadSymbols(symName);
wcOps.logSetSignal= function(labelIdx, value) {
if (logger) logger.info("SET " + sym.labelIdx2Name[labelIdx] + " <-- " + value.toString());
};
}
if (options.get) {
if (!sym) sym = await loadSymbols(symName);
wcOps.logGetSignal= function(varIdx, value) {
if (logger) logger.info("GET " + sym.labelIdx2Name[varIdx] + " --> " + value.toString());
};
}
if (options.trigger) {
if (!sym) sym = await loadSymbols(symName);
wcOps.logStartComponent= function(cIdx) {
if (logger) logger.info("START: " + sym.componentIdx2Name[cIdx]);
};
wcOps.logFinishComponent= function(cIdx) {
if (logger) logger.info("FINISH: " + sym.componentIdx2Name[cIdx]);
};
}
const wc = await WitnessCalculatorBuilder$1(wasm, wcOps);
const w = await wc.calculateWitness(input);
const fdWtns = await createBinFile(wtnsFileName, "wtns", 2, 2);
await write(fdWtns, w, wc.prime);
await fdWtns.close();
}
async function wtnsExportJson(wtnsFileName) {
const w = await read(wtnsFileName);
return w;
}
var wtns = /*#__PURE__*/Object.freeze({
__proto__: null,
calculate: wtnsCalculate,
debug: wtnsDebug,
exportJson: wtnsExportJson
});
const SUBARRAY_SIZE = 0x40000;
const BigArrayHandler = {
get: function(obj, prop) {
if (!isNaN(prop)) {
return obj.getElement(prop);
} else return obj[prop];
},
set: function(obj, prop, value) {
if (!isNaN(prop)) {
return obj.setElement(prop, value);
} else {
obj[prop] = value;
return true;
}
}
};
class _BigArray {
constructor (initSize) {
this.length = initSize || 0;
this.arr = new Array(SUBARRAY_SIZE);
for (let i=0; i<initSize; i+=SUBARRAY_SIZE) {
this.arr[i/SUBARRAY_SIZE] = new Array(Math.min(SUBARRAY_SIZE, initSize - i));
}
return this;
}
push () {
for (let i=0; i<arguments.length; i++) {
this.setElement (this.length, arguments[i]);
}
}
slice (f, t) {
const arr = new Array(t-f);
for (let i=f; i< t; i++) arr[i-f] = this.getElement(i);
return arr;
}
getElement(idx) {
idx = parseInt(idx);
const idx1 = Math.floor(idx / SUBARRAY_SIZE);
const idx2 = idx % SUBARRAY_SIZE;
return this.arr[idx1] ? this.arr[idx1][idx2] : undefined;
}
setElement(idx, value) {
idx = parseInt(idx);
const idx1 = Math.floor(idx / SUBARRAY_SIZE);
if (!this.arr[idx1]) {
this.arr[idx1] = new Array(SUBARRAY_SIZE);
}
const idx2 = idx % SUBARRAY_SIZE;
this.arr[idx1][idx2] = value;
if (idx >= this.length) this.length = idx+1;
return true;
}
getKeys() {
const newA = new BigArray();
for (let i=0; i<this.arr.length; i++) {
if (this.arr[i]) {
for (let j=0; j<this.arr[i].length; j++) {
if (typeof this.arr[i][j] !== "undefined") {
newA.push(i*SUBARRAY_SIZE+j);
}
}
}
}
return newA;
}
}
class BigArray {
constructor( initSize ) {
const obj = new _BigArray(initSize);
const extObj = new Proxy(obj, BigArrayHandler);
return extObj;
}
}
async function newZKey(r1csName, ptauName, zkeyName, logger) {
await Blake2b.ready();
const csHasher = Blake2b(64);
const {fd: fdR1cs, sections: sectionsR1cs} = await readBinFile(r1csName, "r1cs", 1);
const r1cs = await loadHeader(fdR1cs, sectionsR1cs);
const {fd: fdPTau, sections: sectionsPTau} = await readBinFile(ptauName, "ptau", 1);
const {curve, power} = await readPTauHeader(fdPTau, sectionsPTau);
const fdZKey = await createBinFile(zkeyName, "zkey", 1, 10);
const sG1 = curve.G1.F.n8*2;
const sG2 = curve.G2.F.n8*2;
if (r1cs.prime != curve.r) {
if (logger) logger.error("r1cs curve does not match powers of tau ceremony curve");
return -1;
}
const cirPower = log2(r1cs.nConstraints + r1cs.nPubInputs + r1cs.nOutputs +1 -1) +1;
if (cirPower > power+1) {
if (logger) logger.error(`circuit too big for this power of tau ceremony. ${r1cs.nConstraints}*2 > 2**${power}`);
return -1;
}
if (!sectionsPTau[12]) {
if (logger) logger.error("Powers of tau is not prepared.");
return -1;
}
const nPublic = r1cs.nOutputs + r1cs.nPubInputs;
const domainSize = 1 << cirPower;
// Write the header
///////////
await startWriteSection(fdZKey, 1);
await fdZKey.writeULE32(1); // Groth
await endWriteSection(fdZKey);
// Write the Groth header section
///////////
await startWriteSection(fdZKey, 2);
const primeQ = curve.q;
const n8q = (Math.floor( (ffjavascript.Scalar.bitLength(primeQ) - 1) / 64) +1)*8;
const primeR = curve.r;
const n8r = (Math.floor( (ffjavascript.Scalar.bitLength(primeR) - 1) / 64) +1)*8;
const Rr = ffjavascript.Scalar.mod(ffjavascript.Scalar.shl(1, n8r*8), primeR);
const R2r = curve.Fr.e(ffjavascript.Scalar.mod(ffjavascript.Scalar.mul(Rr,Rr), primeR));
await fdZKey.writeULE32(n8q);
await writeBigInt(fdZKey, primeQ, n8q);
await fdZKey.writeULE32(n8r);
await writeBigInt(fdZKey, primeR, n8r);
await fdZKey.writeULE32(r1cs.nVars); // Total number of bars
await fdZKey.writeULE32(nPublic); // Total number of public vars (not including ONE)
await fdZKey.writeULE32(domainSize); // domainSize
let bAlpha1;
bAlpha1 = await fdPTau.read(sG1, sectionsPTau[4][0].p);
await fdZKey.write(bAlpha1);
bAlpha1 = await curve.G1.batchLEMtoU(bAlpha1);
csHasher.update(bAlpha1);
let bBeta1;
bBeta1 = await fdPTau.read(sG1, sectionsPTau[5][0].p);
await fdZKey.write(bBeta1);
bBeta1 = await curve.G1.batchLEMtoU(bBeta1);
csHasher.update(bBeta1);
let bBeta2;
bBeta2 = await fdPTau.read(sG2, sectionsPTau[6][0].p);
await fdZKey.write(bBeta2);
bBeta2 = await curve.G2.batchLEMtoU(bBeta2);
csHasher.update(bBeta2);
const bg1 = new Uint8Array(sG1);
curve.G1.toRprLEM(bg1, 0, curve.G1.g);
const bg2 = new Uint8Array(sG2);
curve.G2.toRprLEM(bg2, 0, curve.G2.g);
const bg1U = new Uint8Array(sG1);
curve.G1.toRprUncompressed(bg1U, 0, curve.G1.g);
const bg2U = new Uint8Array(sG2);
curve.G2.toRprUncompressed(bg2U, 0, curve.G2.g);
await fdZKey.write(bg2); // gamma2
await fdZKey.write(bg1); // delta1
await fdZKey.write(bg2); // delta2
csHasher.update(bg2U); // gamma2
csHasher.update(bg1U); // delta1
csHasher.update(bg2U); // delta2
await endWriteSection(fdZKey);
const A = new BigArray(r1cs.nVars);
const B1 = new BigArray(r1cs.nVars);
const B2 = new BigArray(r1cs.nVars);
const C = new BigArray(r1cs.nVars- nPublic -1);
const IC = new Array(nPublic+1);
const buffCoeff = new Uint8Array(12 + curve.Fr.n8);
const buffCoeffV = new DataView(buffCoeff.buffer);
const lTauG1 = sectionsPTau[12][0].p + ((1 << cirPower) -1)*sG1;
const lTauG2 = sectionsPTau[13][0].p + ((1 << cirPower) -1)*sG2;
const lAlphaTauG1 = sectionsPTau[14][0].p + ((1 << cirPower) -1)*sG1;
const lBetaTauG1 = sectionsPTau[15][0].p + ((1 << cirPower) -1)*sG1;
await startWriteSection(fdZKey, 4);
await startReadUniqueSection(fdR1cs, sectionsR1cs, 2);
const pNCoefs = fdZKey.pos;
let nCoefs = 0;
fdZKey.pos += 4;
for (let c=0; c<r1cs.nConstraints; c++) {
if ((logger)&&(c%10000 == 0)) logger.debug(`processing constraints: ${c}/${r1cs.nConstraints}`);
const nA = await fdR1cs.readULE32();
for (let i=0; i<nA; i++) {
const s = await fdR1cs.readULE32();
const coef = await fdR1cs.read(r1cs.n8);
const l1 = lTauG1 + sG1*c;
const l2 = lBetaTauG1 + sG1*c;
if (typeof A[s] === "undefined") A[s] = [];
A[s].push([l1, coef]);
if (s <= nPublic) {
if (typeof IC[s] === "undefined") IC[s] = [];
IC[s].push([l2, coef]);
} else {
if (typeof C[s- nPublic -1] === "undefined") C[s- nPublic -1] = [];
C[s - nPublic -1].push([l2, coef]);
}
await writeCoef(0, c, s, coef);
nCoefs ++;
}
const nB = await fdR1cs.readULE32();
for (let i=0; i<nB; i++) {
const s = await fdR1cs.readULE32();
const coef = await fdR1cs.read(r1cs.n8);
const l1 = lTauG1 + sG1*c;
const l2 = lTauG2 + sG2*c;
const l3 = lAlphaTauG1 + sG1*c;
if (typeof B1[s] === "undefined") B1[s] = [];
B1[s].push([l1, coef]);
if (typeof B2[s] === "undefined") B2[s] = [];
B2[s].push([l2, coef]);
if (s <= nPublic) {
if (typeof IC[s] === "undefined") IC[s] = [];
IC[s].push([l3, coef]);
} else {
if (typeof C[s- nPublic -1] === "undefined") C[s- nPublic -1] = [];
C[s- nPublic -1].push([l3, coef]);
}
await writeCoef(1, c, s, coef);
nCoefs ++;
}
const nC = await fdR1cs.readULE32();
for (let i=0; i<nC; i++) {
const s = await fdR1cs.readULE32();
const coef = await fdR1cs.read(r1cs.n8);
const l1 = lTauG1 + sG1*c;
if (s <= nPublic) {
if (typeof IC[s] === "undefined") IC[s] = [];
IC[s].push([l1, coef]);
} else {
if (typeof C[s- nPublic -1] === "undefined") C[s- nPublic -1] = [];
C[s- nPublic -1].push([l1, coef]);
}
}
}
const bOne = new Uint8Array(curve.Fr.n8);
curve.Fr.toRprLE(bOne, 0, curve.Fr.e(1));
for (let s = 0; s <= nPublic ; s++) {
const l1 = lTauG1 + sG1*(r1cs.nConstraints + s);
const l2 = lBetaTauG1 + sG1*(r1cs.nConstraints + s);
if (typeof A[s] === "undefined") A[s] = [];
A[s].push([l1, bOne]);
if (typeof IC[s] === "undefined") IC[s] = [];
IC[s].push([l2, bOne]);
await writeCoef(0, r1cs.nConstraints + s, s, bOne);
nCoefs ++;
}
const oldPos = fdZKey.pos;
await fdZKey.writeULE32(nCoefs, pNCoefs);
fdZKey.pos = oldPos;
await endWriteSection(fdZKey);
await endReadSection(fdR1cs);
/*
zKey.hExps = new Array(zKey.domainSize-1);
for (let i=0; i< zKey.domainSize; i++) {
const t1 = await readEvaluation("tauG1", i);
const t2 = await readEvaluation("tauG1", i+zKey.domainSize);
zKey.hExps[i] = curve.G1.sub(t2, t1);
}
*/
await composeAndWritePoints(3, "G1", IC, "IC");
// Write Hs
await startWriteSection(fdZKey, 9);
const o = sectionsPTau[12][0].p + ((1 << (cirPower+1)) -1)*sG1;
for (let i=0; i< domainSize; i++) {
const buff = await fdPTau.read(sG1, o + (i*2+1)*sG1 );
await fdZKey.write(buff);
}
await endWriteSection(fdZKey);
await hashHPoints();
await composeAndWritePoints(8, "G1", C, "C");
await composeAndWritePoints(5, "G1", A, "A");
await composeAndWritePoints(6, "G1", B1, "B1");
await composeAndWritePoints(7, "G2", B2, "B2");
const csHash = csHasher.digest();
// Contributions section
await startWriteSection(fdZKey, 10);
await fdZKey.write(csHash);
await fdZKey.writeULE32(0);
await endWriteSection(fdZKey);
if (logger) logger.info(formatHash(csHash, "Circuit hash: "));
await fdZKey.close();
await fdPTau.close();
await fdR1cs.close();
return csHash;
async function writeCoef(a, c, s, coef) {
const n = curve.Fr.fromRprLE(coef, 0);
const nR2 = curve.Fr.mul(n, R2r);
buffCoeffV.setUint32(0, a, true);
buffCoeffV.setUint32(4, c, true);
buffCoeffV.setUint32(8, s, true);
curve.Fr.toRprLE(buffCoeff, 12, nR2);
await fdZKey.write(buffCoeff);
}
async function composeAndWritePoints(idSection, groupName, arr, sectionName) {
const CHUNK_SIZE= 1<<16;
hashU32(arr.length);
await startWriteSection(fdZKey, idSection);
for (let i=0; i<arr.length; i+= CHUNK_SIZE) {
if (logger) logger.debug(`Writing points ${sectionName}: ${i}/${arr.length}`);
const n = Math.min(arr.length -i, CHUNK_SIZE);
const subArr = arr.slice(i, i + n);
await composeAndWritePointsChunk(groupName, subArr);
}
await endWriteSection(fdZKey);
}
async function composeAndWritePointsChunk(groupName, arr) {
const concurrency= curve.tm.concurrency;
const nElementsPerThread = Math.floor(arr.length / concurrency);
const opPromises = [];
const G = curve[groupName];
for (let i=0; i<concurrency; i++) {
let n;
if (i< concurrency-1) {
n = nElementsPerThread;
} else {
n = arr.length - i*nElementsPerThread;
}
if (n==0) continue;
const subArr = arr.slice(i*nElementsPerThread, i*nElementsPerThread + n);
opPromises.push(composeAndWritePointsThread(groupName, subArr));
}
const result = await Promise.all(opPromises);
for (let i=0; i<result.length; i++) {
await fdZKey.write(result[i][0]);
const buff = await G.batchLEMtoU(result[i][0]);
csHasher.update(buff);
}
}
async function composeAndWritePointsThread(groupName, arr) {
const G = curve[groupName];
const sGin = G.F.n8*2;
const sGmid = G.F.n8*3;
const sGout = G.F.n8*2;
let fnExp, fnMultiExp, fnBatchToAffine, fnZero;
if (groupName == "G1") {
fnExp = "g1m_timesScalarAffine";
fnMultiExp = "g1m_multiexpAffine";
fnBatchToAffine = "g1m_batchToAffine";
fnZero = "g1m_zero";
} else if (groupName == "G2") {
fnExp = "g2m_timesScalarAffine";
fnMultiExp = "g2m_multiexpAffine";
fnBatchToAffine = "g2m_batchToAffine";
fnZero = "g2m_zero";
} else {
throw new Error("Invalid group");
}
let acc =0;
for (let i=0; i<arr.length; i++) acc += arr[i] ? arr[i].length : 0;
const bBases = new Uint8Array(acc*sGin);
const bScalars = new Uint8Array(acc*curve.Fr.n8);
let pB =0;
let pS =0;
for (let i=0; i<arr.length; i++) {
if (!arr[i]) continue;
for (let j=0; j<arr[i].length; j++) {
const bBase = await fdPTau.read(sGin, arr[i][j][0]);
bBases.set(bBase, pB);
pB += sGin;
bScalars.set(arr[i][j][1], pS);
pS += curve.Fr.n8;
}
}
const task = [];
task.push({cmd: "ALLOCSET", var: 0, buff: bBases});
task.push({cmd: "ALLOCSET", var: 1, buff: bScalars});
task.push({cmd: "ALLOC", var: 2, len: arr.length*sGmid});
pB = 0;
pS = 0;
let pD =0;
for (let i=0; i<arr.length; i++) {
if (!arr[i]) {
task.push({cmd: "CALL", fnName: fnZero, params: [
{var: 2, offset: pD}
]});
pD += sGmid;
continue;
}
if (arr[i].length == 1) {
task.push({cmd: "CALL", fnName: fnExp, params: [
{var: 0, offset: pB},
{var: 1, offset: pS},
{val: curve.Fr.n8},
{var: 2, offset: pD}
]});
} else {
task.push({cmd: "CALL", fnName: fnMultiExp, params: [
{var: 0, offset: pB},
{var: 1, offset: pS},
{val: curve.Fr.n8},
{val: arr[i].length},
{var: 2, offset: pD}
]});
}
pB += sGin*arr[i].length;
pS += curve.Fr.n8*arr[i].length;
pD += sGmid;
}
task.push({cmd: "CALL", fnName: fnBatchToAffine, params: [
{var: 2},
{val: arr.length},
{var: 2},
]});
task.push({cmd: "GET", out: 0, var: 2, len: arr.length*sGout});
const res = await curve.tm.queueAction(task);
return res;
}
async function hashHPoints() {
const CHUNK_SIZE = 1<<14;
hashU32(domainSize-1);
for (let i=0; i<domainSize-1; i+= CHUNK_SIZE) {
if (logger) logger.debug(`HashingHPoints: ${i}/${domainSize}`);
const n = Math.min(domainSize-1, CHUNK_SIZE);
await hashHPointsChunk(i, n);
}
}
async function hashHPointsChunk(offset, nPoints) {
const buff1 = await fdPTau.read(nPoints *sG1, sectionsPTau[2][0].p + (offset + domainSize)*sG1);
const buff2 = await fdPTau.read(nPoints *sG1, sectionsPTau[2][0].p + offset*sG1);
const concurrency= curve.tm.concurrency;
const nPointsPerThread = Math.floor(nPoints / concurrency);
const opPromises = [];
for (let i=0; i<concurrency; i++) {
let n;
if (i< concurrency-1) {
n = nPointsPerThread;
} else {
n = nPoints - i*nPointsPerThread;
}
if (n==0) continue;
const subBuff1 = buff1.slice(i*nPointsPerThread*sG1, (i*nPointsPerThread+n)*sG1);
const subBuff2 = buff2.slice(i*nPointsPerThread*sG1, (i*nPointsPerThread+n)*sG1);
opPromises.push(hashHPointsThread(subBuff1, subBuff2));
}
const result = await Promise.all(opPromises);
for (let i=0; i<result.length; i++) {
csHasher.update(result[i][0]);
}
}
async function hashHPointsThread(buff1, buff2) {
const nPoints = buff1.byteLength/sG1;
const sGmid = curve.G1.F.n8*3;
const task = [];
task.push({cmd: "ALLOCSET", var: 0, buff: buff1});
task.push({cmd: "ALLOCSET", var: 1, buff: buff2});
task.push({cmd: "ALLOC", var: 2, len: nPoints*sGmid});
for (let i=0; i<nPoints; i++) {
task.push({
cmd: "CALL",
fnName: "g1m_subAffine",
params: [
{var: 0, offset: i*sG1},
{var: 1, offset: i*sG1},
{var: 2, offset: i*sGmid},
]
});
}
task.push({cmd: "CALL", fnName: "g1m_batchToAffine", params: [
{var: 2},
{val: nPoints},
{var: 2},
]});
task.push({cmd: "CALL", fnName: "g1m_batchLEMtoU", params: [
{var: 2},
{val: nPoints},
{var: 2},
]});
task.push({cmd: "GET", out: 0, var: 2, len: nPoints*sG1});
const res = await curve.tm.queueAction(task);
return res;
}
function hashU32(n) {
const buff = new Uint8Array(4);
const buffV = new DataView(buff.buffer, buff.byteOffset, buff.byteLength);
buffV.setUint32(0, n, false);
csHasher.update(buff);
}
}
async function phase2exportMPCParams(zkeyName, mpcparamsName, logger) {
const {fd: fdZKey, sections: sectionsZKey} = await readBinFile(zkeyName, "zkey", 2);
const zkey = await readHeader(fdZKey, sectionsZKey, "groth16");
const curve = await getCurveFromQ(zkey.q);
const sG1 = curve.G1.F.n8*2;
const sG2 = curve.G2.F.n8*2;
const mpcParams = await readMPCParams(fdZKey, curve, sectionsZKey);
const fdMPCParams = await createOverride(mpcparamsName);
/////////////////////
// Verification Key Section
/////////////////////
await writeG1(zkey.vk_alpha_1);
await writeG1(zkey.vk_beta_1);
await writeG2(zkey.vk_beta_2);
await writeG2(zkey.vk_gamma_2);
await writeG1(zkey.vk_delta_1);
await writeG2(zkey.vk_delta_2);
// IC
let buffBasesIC;
buffBasesIC = await readFullSection(fdZKey, sectionsZKey, 3);
buffBasesIC = await curve.G1.batchLEMtoU(buffBasesIC);
await writePointArray("G1", buffBasesIC);
/////////////////////
// h Section
/////////////////////
const buffBasesH_Lodd = await readFullSection(fdZKey, sectionsZKey, 9);
let buffBasesH_Tau;
buffBasesH_Tau = await curve.G1.fft(buffBasesH_Lodd, "affine", "jacobian", logger);
buffBasesH_Tau = await curve.G1.batchApplyKey(buffBasesH_Tau, curve.Fr.neg(curve.Fr.e(2)), curve.Fr.w[zkey.power+1], "jacobian", "affine", logger);
// Remove last element. (The degree of H will be allways m-2)
buffBasesH_Tau = buffBasesH_Tau.slice(0, buffBasesH_Tau.byteLength - sG1);
buffBasesH_Tau = await curve.G1.batchLEMtoU(buffBasesH_Tau);
await writePointArray("G1", buffBasesH_Tau);
/////////////////////
// L section
/////////////////////
let buffBasesC;
buffBasesC = await readFullSection(fdZKey, sectionsZKey, 8);
buffBasesC = await curve.G1.batchLEMtoU(buffBasesC);
await writePointArray("G1", buffBasesC);
/////////////////////
// A Section (C section)
/////////////////////
let buffBasesA;
buffBasesA = await readFullSection(fdZKey, sectionsZKey, 5);
buffBasesA = await curve.G1.batchLEMtoU(buffBasesA);
await writePointArray("G1", buffBasesA);
/////////////////////
// B1 Section
/////////////////////
let buffBasesB1;
buffBasesB1 = await readFullSection(fdZKey, sectionsZKey, 6);
buffBasesB1 = await curve.G1.batchLEMtoU(buffBasesB1);
await writePointArray("G1", buffBasesB1);
/////////////////////
// B2 Section
/////////////////////
let buffBasesB2;
buffBasesB2 = await readFullSection(fdZKey, sectionsZKey, 7);
buffBasesB2 = await curve.G2.batchLEMtoU(buffBasesB2);
await writePointArray("G2", buffBasesB2);
await fdMPCParams.write(mpcParams.csHash);
await writeU32(mpcParams.contributions.length);
for (let i=0; i<mpcParams.contributions.length; i++) {
const c = mpcParams.contributions[i];
await writeG1(c.deltaAfter);
await writeG1(c.delta.g1_s);
await writeG1(c.delta.g1_sx);
await writeG2(c.delta.g2_spx);
await fdMPCParams.write(c.transcript);
}
await fdZKey.close();
await fdMPCParams.close();
async function writeG1(P) {
const buff = new Uint8Array(sG1);
curve.G1.toRprUncompressed(buff, 0, P);
await fdMPCParams.write(buff);
}
async function writeG2(P) {
const buff = new Uint8Array(sG2);
curve.G2.toRprUncompressed(buff, 0, P);
await fdMPCParams.write(buff);
}
async function writePointArray(groupName, buff) {
let sG;
if (groupName == "G1") {
sG = sG1;
} else {
sG = sG2;
}
const buffSize = new Uint8Array(4);
const buffSizeV = new DataView(buffSize.buffer, buffSize.byteOffset, buffSize.byteLength);
buffSizeV.setUint32(0, buff.byteLength / sG, false);
await fdMPCParams.write(buffSize);
await fdMPCParams.write(buff);
}
async function writeU32(n) {
const buffSize = new Uint8Array(4);
const buffSizeV = new DataView(buffSize.buffer, buffSize.byteOffset, buffSize.byteLength);
buffSizeV.setUint32(0, n, false);
await fdMPCParams.write(buffSize);
}
}
async function phase2importMPCParams(zkeyNameOld, mpcparamsName, zkeyNameNew, name, logger) {
const {fd: fdZKeyOld, sections: sectionsZKeyOld} = await readBinFile(zkeyNameOld, "zkey", 2);
const zkeyHeader = await readHeader(fdZKeyOld, sectionsZKeyOld, "groth16");
const curve = await getCurveFromQ(zkeyHeader.q);
const sG1 = curve.G1.F.n8*2;
const sG2 = curve.G2.F.n8*2;
const oldMPCParams = await readMPCParams(fdZKeyOld, curve, sectionsZKeyOld);
const newMPCParams = {};
const fdMPCParams = await readExisting$2(mpcparamsName);
fdMPCParams.pos =
sG1*3 + sG2*3 + // vKey
8 + sG1*zkeyHeader.nVars + // IC + C
4 + sG1*(zkeyHeader.domainSize-1) + // H
4 + sG1*zkeyHeader.nVars + // A
4 + sG1*zkeyHeader.nVars + // B1
4 + sG2*zkeyHeader.nVars; // B2
// csHash
newMPCParams.csHash = await fdMPCParams.read(64);
const nConttributions = await fdMPCParams.readUBE32();
newMPCParams.contributions = [];
for (let i=0; i<nConttributions; i++) {
const c = { delta:{} };
c.deltaAfter = await readG1(fdMPCParams);
c.delta.g1_s = await readG1(fdMPCParams);
c.delta.g1_sx = await readG1(fdMPCParams);
c.delta.g2_spx = await readG2(fdMPCParams);
c.transcript = await fdMPCParams.read(64);
if (i<oldMPCParams.contributions.length) {
c.type = oldMPCParams.contributions[i].type;
if (c.type==1) {
c.beaconHash = oldMPCParams.contributions[i].beaconHash;
c.numIterationsExp = oldMPCParams.contributions[i].numIterationsExp;
}
if (oldMPCParams.contributions[i].name) {
c.name = oldMPCParams.contributions[i].name;
}
}
newMPCParams.contributions.push(c);
}
if (!hashIsEqual(newMPCParams.csHash, oldMPCParams.csHash)) {
if (logger) logger.error("Hash of the original circuit does not match with the MPC one");
return false;
}
if (oldMPCParams.contributions.length > newMPCParams.contributions.length) {
if (logger) logger.error("The impoerted file does not include new contributions");
return false;
}
for (let i=0; i<oldMPCParams.contributions.length; i++) {
if (!contributionIsEqual(oldMPCParams.contributions[i], newMPCParams.contributions[i])) {
if (logger) logger.error(`Previos contribution ${i} does not match`);
return false;
}
}
// Set the same name to all new controbutions
if (name) {
for (let i=oldMPCParams.contributions.length; i<newMPCParams.contributions.length; i++) {
newMPCParams.contributions[i].name = name;
}
}
const fdZKeyNew = await createBinFile(zkeyNameNew, "zkey", 1, 10);
fdMPCParams.pos = 0;
// Header
fdMPCParams.pos += sG1; // ignore alpha1 (keep original)
fdMPCParams.pos += sG1; // ignore beta1
fdMPCParams.pos += sG2; // ignore beta2
fdMPCParams.pos += sG2; // ignore gamma2
zkeyHeader.vk_delta_1 = await readG1(fdMPCParams);
zkeyHeader.vk_delta_2 = await readG2(fdMPCParams);
await writeHeader(fdZKeyNew, zkeyHeader);
// IC (Keep original)
const nIC = await fdMPCParams.readUBE32();
if (nIC != zkeyHeader.nPublic +1) {
if (logger) logger.error("Invalid number of points in IC");
await fdZKeyNew.discard();
return false;
}
fdMPCParams.pos += sG1*(zkeyHeader.nPublic+1);
await copySection(fdZKeyOld, sectionsZKeyOld, fdZKeyNew, 3);
// Coeffs (Keep original)
await copySection(fdZKeyOld, sectionsZKeyOld, fdZKeyNew, 4);
// H Section
const nH = await fdMPCParams.readUBE32();
if (nH != zkeyHeader.domainSize-1) {
if (logger) logger.error("Invalid number of points in H");
await fdZKeyNew.discard();
return false;
}
let buffH;
const buffTauU = await fdMPCParams.read(sG1*(zkeyHeader.domainSize-1));
const buffTauLEM = await curve.G1.batchUtoLEM(buffTauU);
buffH = new Uint8Array(zkeyHeader.domainSize*sG1);
buffH.set(buffTauLEM); // Let the last one to zero.
curve.G1.toRprLEM(buffH, sG1*(zkeyHeader.domainSize-1), curve.G1.zeroAffine);
const n2Inv = curve.Fr.neg(curve.Fr.inv(curve.Fr.e(2)));
const wInv = curve.Fr.inv(curve.Fr.w[zkeyHeader.power+1]);
buffH = await curve.G1.batchApplyKey(buffH, n2Inv, wInv, "affine", "jacobian", logger);
buffH = await curve.G1.ifft(buffH, "jacobian", "affine", logger);
await startWriteSection(fdZKeyNew, 9);
await fdZKeyNew.write(buffH);
await endWriteSection(fdZKeyNew);
// C Secion (L section)
const nL = await fdMPCParams.readUBE32();
if (nL != (zkeyHeader.nVars-zkeyHeader.nPublic-1)) {
if (logger) logger.error("Invalid number of points in L");
await fdZKeyNew.discard();
return false;
}
let buffL;
buffL = await fdMPCParams.read(sG1*(zkeyHeader.nVars-zkeyHeader.nPublic-1));
buffL = await curve.G1.batchUtoLEM(buffL);
await startWriteSection(fdZKeyNew, 8);
await fdZKeyNew.write(buffL);
await endWriteSection(fdZKeyNew);
// A Section
const nA = await fdMPCParams.readUBE32();
if (nA != zkeyHeader.nVars) {
if (logger) logger.error("Invalid number of points in A");
await fdZKeyNew.discard();
return false;
}
fdMPCParams.pos += sG1*(zkeyHeader.nVars);
await copySection(fdZKeyOld, sectionsZKeyOld, fdZKeyNew, 5);
// B1 Section
const nB1 = await fdMPCParams.readUBE32();
if (nB1 != zkeyHeader.nVars) {
if (logger) logger.error("Invalid number of points in B1");
await fdZKeyNew.discard();
return false;
}
fdMPCParams.pos += sG1*(zkeyHeader.nVars);
await copySection(fdZKeyOld, sectionsZKeyOld, fdZKeyNew, 6);
// B2 Section
const nB2 = await fdMPCParams.readUBE32();
if (nB2 != zkeyHeader.nVars) {
if (logger) logger.error("Invalid number of points in B2");
await fdZKeyNew.discard();
return false;
}
fdMPCParams.pos += sG2*(zkeyHeader.nVars);
await copySection(fdZKeyOld, sectionsZKeyOld, fdZKeyNew, 7);
await writeMPCParams(fdZKeyNew, curve, newMPCParams);
await fdMPCParams.close();
await fdZKeyNew.close();
await fdZKeyOld.close();
return true;
async function readG1(fd) {
const buff = await fd.read(curve.G1.F.n8*2);
return curve.G1.fromRprUncompressed(buff, 0);
}
async function readG2(fd) {
const buff = await fd.read(curve.G2.F.n8*2);
return curve.G2.fromRprUncompressed(buff, 0);
}
function contributionIsEqual(c1, c2) {
if (!curve.G1.eq(c1.deltaAfter , c2.deltaAfter)) return false;
if (!curve.G1.eq(c1.delta.g1_s , c2.delta.g1_s)) return false;
if (!curve.G1.eq(c1.delta.g1_sx , c2.delta.g1_sx)) return false;
if (!curve.G2.eq(c1.delta.g2_spx , c2.delta.g2_spx)) return false;
if (!hashIsEqual(c1.transcript, c2.transcript)) return false;
return true;
}
}
const sameRatio$2 = sameRatio;
async function phase2verify(r1csFileName, pTauFileName, zkeyFileName, logger) {
let sr;
await Blake2b.ready();
const {fd, sections} = await readBinFile(zkeyFileName, "zkey", 2);
const zkey = await readHeader(fd, sections, "groth16");
const curve = await getCurveFromQ(zkey.q);
const sG1 = curve.G1.F.n8*2;
const sG2 = curve.G2.F.n8*2;
const mpcParams = await readMPCParams(fd, curve, sections);
const accumulatedHasher = Blake2b(64);
accumulatedHasher.update(mpcParams.csHash);
let curDelta = curve.G1.g;
for (let i=0; i<mpcParams.contributions.length; i++) {
const c = mpcParams.contributions[i];
const ourHasher = cloneHasher(accumulatedHasher);
hashG1(ourHasher, curve, c.delta.g1_s);
hashG1(ourHasher, curve, c.delta.g1_sx);
if (!hashIsEqual(ourHasher.digest(), c.transcript)) {
console.log(`INVALID(${i}): Inconsistent transcript `);
return false;
}
const delta_g2_sp = hashToG2(curve, c.transcript);
sr = await sameRatio$2(curve, c.delta.g1_s, c.delta.g1_sx, delta_g2_sp, c.delta.g2_spx);
if (sr !== true) {
console.log(`INVALID(${i}): public key G1 and G2 do not have the same ration `);
return false;
}
sr = await sameRatio$2(curve, curDelta, c.deltaAfter, delta_g2_sp, c.delta.g2_spx);
if (sr !== true) {
console.log(`INVALID(${i}): deltaAfter does not fillow the public key `);
return false;
}
if (c.type == 1) {
const rng = rngFromBeaconParams(c.beaconHash, c.numIterationsExp);
const expected_prvKey = curve.Fr.fromRng(rng);
const expected_g1_s = curve.G1.toAffine(curve.G1.fromRng(rng));
const expected_g1_sx = curve.G1.toAffine(curve.G1.timesFr(expected_g1_s, expected_prvKey));
if (curve.G1.eq(expected_g1_s, c.delta.g1_s) !== true) {
console.log(`INVALID(${i}): Key of the beacon does not match. g1_s `);
return false;
}
if (curve.G1.eq(expected_g1_sx, c.delta.g1_sx) !== true) {
console.log(`INVALID(${i}): Key of the beacon does not match. g1_sx `);
return false;
}
}
hashPubKey(accumulatedHasher, curve, c);
const contributionHasher = Blake2b(64);
hashPubKey(contributionHasher, curve, c);
c.contributionHash = contributionHasher.digest();
curDelta = c.deltaAfter;
}
// const initFileName = "~" + zkeyFileName + ".init";
const initFileName = {type: "mem"};
await newZKey(r1csFileName, pTauFileName, initFileName);
const {fd: fdInit, sections: sectionsInit} = await readBinFile(initFileName, "zkey", 2);
const zkeyInit = await readHeader(fdInit, sectionsInit, "groth16");
if ( (!ffjavascript.Scalar.eq(zkeyInit.q, zkey.q))
||(!ffjavascript.Scalar.eq(zkeyInit.r, zkey.r))
||(zkeyInit.n8q != zkey.n8q)
||(zkeyInit.n8r != zkey.n8r))
{
if (logger) logger.error("INVALID: Different curves");
return false;
}
if ( (zkeyInit.nVars != zkey.nVars)
||(zkeyInit.nPublic != zkey.nPublic)
||(zkeyInit.domainSize != zkey.domainSize))
{
if (logger) logger.error("INVALID: Different circuit parameters");
return false;
}
if (!curve.G1.eq(zkey.vk_alpha_1, zkeyInit.vk_alpha_1)) {
if (logger) logger.error("INVALID: Invalid alpha1");
return false;
}
if (!curve.G1.eq(zkey.vk_beta_1, zkeyInit.vk_beta_1)) {
if (logger) logger.error("INVALID: Invalid beta1");
return false;
}
if (!curve.G2.eq(zkey.vk_beta_2, zkeyInit.vk_beta_2)) {
if (logger) logger.error("INVALID: Invalid beta2");
return false;
}
if (!curve.G2.eq(zkey.vk_gamma_2, zkeyInit.vk_gamma_2)) {
if (logger) logger.error("INVALID: Invalid gamma2");
return false;
}
if (!curve.G1.eq(zkey.vk_delta_1, curDelta)) {
if (logger) logger.error("INVALID: Invalud delta1");
return false;
}
sr = await sameRatio$2(curve, curve.G1.g, curDelta, curve.G2.g, zkey.vk_delta_2);
if (sr !== true) {
if (logger) logger.error("INVALID: Invalud delta2");
return false;
}
const mpcParamsInit = await readMPCParams(fdInit, curve, sectionsInit);
if (!hashIsEqual(mpcParams.csHash, mpcParamsInit.csHash)) {
if (logger) logger.error("INVALID: Circuit does not match");
return false;
}
// Check sizes of sections
if (sections[8][0].size != sG1*(zkey.nVars-zkey.nPublic-1)) {
if (logger) logger.error("INVALID: Invalid L section size");
return false;
}
if (sections[9][0].size != sG1*(zkey.domainSize)) {
if (logger) logger.error("INVALID: Invalid H section size");
return false;
}
let ss;
ss = await sectionIsEqual(fd, sections, fdInit, sectionsInit, 3);
if (!ss) {
if (logger) logger.error("INVALID: IC section is not identical");
return false;
}
ss = await sectionIsEqual(fd, sections, fdInit, sectionsInit, 4);
if (!ss) {
if (logger) logger.error("Coeffs section is not identical");
return false;
}
ss = await sectionIsEqual(fd, sections, fdInit, sectionsInit, 5);
if (!ss) {
if (logger) logger.error("A section is not identical");
return false;
}
ss = await sectionIsEqual(fd, sections, fdInit, sectionsInit, 6);
if (!ss) {
if (logger) logger.error("B1 section is not identical");
return false;
}
ss = await sectionIsEqual(fd, sections, fdInit, sectionsInit, 7);
if (!ss) {
if (logger) logger.error("B2 section is not identical");
return false;
}
// Check L
sr = await sectionHasSameRatio("G1", fdInit, sectionsInit, fd, sections, 8, zkey.vk_delta_2, zkeyInit.vk_delta_2, "L section");
if (sr!==true) {
if (logger) logger.error("L section does not match");
return false;
}
// Check H
sr = await sameRatioH();
if (sr!==true) {
if (logger) logger.error("H section does not match");
return false;
}
if (logger) logger.info(formatHash(mpcParams.csHash, "Circuit Hash: "));
await fd.close();
await fdInit.close();
for (let i=mpcParams.contributions.length-1; i>=0; i--) {
const c = mpcParams.contributions[i];
if (logger) logger.info("-------------------------");
if (logger) logger.info(formatHash(c.contributionHash, `contribution #${i+1} ${c.name ? c.name : ""}:`));
if (c.type == 1) {
if (logger) logger.info(`Beacon generator: ${byteArray2hex(c.beaconHash)}`);
if (logger) logger.info(`Beacon iterations Exp: ${c.numIterationsExp}`);
}
}
if (logger) logger.info("-------------------------");
if (logger) logger.info("ZKey Ok!");
return true;
async function sectionHasSameRatio(groupName, fd1, sections1, fd2, sections2, idSection, g2sp, g2spx, sectionName) {
const MAX_CHUNK_SIZE = 1<<20;
const G = curve[groupName];
const sG = G.F.n8*2;
await startReadUniqueSection(fd1, sections1, idSection);
await startReadUniqueSection(fd2, sections2, idSection);
let R1 = G.zero;
let R2 = G.zero;
const nPoints = sections1[idSection][0].size / sG;
for (let i=0; i<nPoints; i += MAX_CHUNK_SIZE) {
if (logger) logger.debug(`Same ratio check ${sectionName}: ${i}/${nPoints}`);
const n = Math.min(nPoints - i, MAX_CHUNK_SIZE);
const bases1 = await fd1.read(n*sG);
const bases2 = await fd2.read(n*sG);
const scalars = new Uint8Array(4*n);
crypto.randomFillSync(scalars);
const r1 = await G.multiExpAffine(bases1, scalars);
const r2 = await G.multiExpAffine(bases2, scalars);
R1 = G.add(R1, r1);
R2 = G.add(R2, r2);
}
await endReadSection(fd1);
await endReadSection(fd2);
if (nPoints == 0) return true;
sr = await sameRatio$2(curve, R1, R2, g2sp, g2spx);
if (sr !== true) return false;
return true;
}
async function sameRatioH() {
const MAX_CHUNK_SIZE = 1<<20;
const G = curve.G1;
const sG = G.F.n8*2;
const {fd: fdPTau, sections: sectionsPTau} = await readBinFile(pTauFileName, "ptau", 1);
let buff_r = new Uint8Array(zkey.domainSize * zkey.n8r);
const seed= new Array(8);
for (let i=0; i<8; i++) {
seed[i] = crypto.randomBytes(4).readUInt32BE(0, true);
}
const rng = new ffjavascript.ChaCha(seed);
for (let i=0; i<zkey.domainSize-1; i++) { // Note that last one is zero
const e = curve.Fr.fromRng(rng);
curve.Fr.toRprLE(buff_r, i*zkey.n8r, e);
}
curve.Fr.toRprLE(buff_r, (zkey.domainSize-1)*zkey.n8r, curve.Fr.zero);
let R1 = G.zero;
for (let i=0; i<zkey.domainSize; i += MAX_CHUNK_SIZE) {
if (logger) logger.debug(`H Verificaition(tau): ${i}/${zkey.domainSize}`);
const n = Math.min(zkey.domainSize - i, MAX_CHUNK_SIZE);
const buff1 = await fdPTau.read(sG*n, sectionsPTau[2][0].p + zkey.domainSize*sG + i*MAX_CHUNK_SIZE*sG);
const buff2 = await fdPTau.read(sG*n, sectionsPTau[2][0].p + i*MAX_CHUNK_SIZE*sG);
const buffB = await batchSubstract(buff1, buff2);
const buffS = buff_r.slice((i*MAX_CHUNK_SIZE)*zkey.n8r, (i*MAX_CHUNK_SIZE+n)*zkey.n8r);
const r = await G.multiExpAffine(buffB, buffS);
R1 = G.add(R1, r);
}
// Caluclate odd coeficients in transformed domain
buff_r = await curve.Fr.batchToMontgomery(buff_r);
// const first = curve.Fr.neg(curve.Fr.inv(curve.Fr.e(2)));
// Works*2 const first = curve.Fr.neg(curve.Fr.e(2));
const first = curve.Fr.neg(curve.Fr.e(2));
// const inc = curve.Fr.inv(curve.PFr.w[zkey.power+1]);
const inc = curve.Fr.w[zkey.power+1];
buff_r = await curve.Fr.batchApplyKey(buff_r, first, inc);
buff_r = await curve.Fr.fft(buff_r);
buff_r = await curve.Fr.batchFromMontgomery(buff_r);
await startReadUniqueSection(fd, sections, 9);
let R2 = G.zero;
for (let i=0; i<zkey.domainSize; i += MAX_CHUNK_SIZE) {
if (logger) logger.debug(`H Verificaition(lagrange): ${i}/${zkey.domainSize}`);
const n = Math.min(zkey.domainSize - i, MAX_CHUNK_SIZE);
const buff = await fd.read(sG*n);
const buffS = buff_r.slice((i*MAX_CHUNK_SIZE)*zkey.n8r, (i*MAX_CHUNK_SIZE+n)*zkey.n8r);
const r = await G.multiExpAffine(buff, buffS);
R2 = G.add(R2, r);
}
await endReadSection(fd);
sr = await sameRatio$2(curve, R1, R2, zkey.vk_delta_2, zkeyInit.vk_delta_2);
if (sr !== true) return false;
return true;
}
async function batchSubstract(buff1, buff2) {
const sG = curve.G1.F.n8*2;
const nPoints = buff1.byteLength / sG;
const concurrency= curve.tm.concurrency;
const nPointsPerThread = Math.floor(nPoints / concurrency);
const opPromises = [];
for (let i=0; i<concurrency; i++) {
let n;
if (i< concurrency-1) {
n = nPointsPerThread;
} else {
n = nPoints - i*nPointsPerThread;
}
if (n==0) continue;
const subBuff1 = buff1.slice(i*nPointsPerThread*sG1, (i*nPointsPerThread+n)*sG1);
const subBuff2 = buff2.slice(i*nPointsPerThread*sG1, (i*nPointsPerThread+n)*sG1);
opPromises.push(batchSubstractThread(subBuff1, subBuff2));
}
const result = await Promise.all(opPromises);
const fullBuffOut = new Uint8Array(nPoints*sG);
let p =0;
for (let i=0; i<result.length; i++) {
fullBuffOut.set(result[i][0], p);
p+=result[i][0].byteLength;
}
return fullBuffOut;
}
async function batchSubstractThread(buff1, buff2) {
const sG1 = curve.G1.F.n8*2;
const sGmid = curve.G1.F.n8*3;
const nPoints = buff1.byteLength/sG1;
const task = [];
task.push({cmd: "ALLOCSET", var: 0, buff: buff1});
task.push({cmd: "ALLOCSET", var: 1, buff: buff2});
task.push({cmd: "ALLOC", var: 2, len: nPoints*sGmid});
for (let i=0; i<nPoints; i++) {
task.push({
cmd: "CALL",
fnName: "g1m_subAffine",
params: [
{var: 0, offset: i*sG1},
{var: 1, offset: i*sG1},
{var: 2, offset: i*sGmid},
]
});
}
task.push({cmd: "CALL", fnName: "g1m_batchToAffine", params: [
{var: 2},
{val: nPoints},
{var: 2},
]});
task.push({cmd: "GET", out: 0, var: 2, len: nPoints*sG1});
const res = await curve.tm.queueAction(task);
return res;
}
}
async function phase2contribute(zkeyNameOld, zkeyNameNew, name, entropy, logger) {
await Blake2b.ready();
const {fd: fdOld, sections: sections} = await readBinFile(zkeyNameOld, "zkey", 2);
const zkey = await readHeader(fdOld, sections, "groth16");
const curve = await getCurveFromQ(zkey.q);
const mpcParams = await readMPCParams(fdOld, curve, sections);
const fdNew = await createBinFile(zkeyNameNew, "zkey", 1, 10);
const rng = await getRandomRng(entropy);
const transcriptHasher = Blake2b(64);
transcriptHasher.update(mpcParams.csHash);
for (let i=0; i<mpcParams.contributions.length; i++) {
hashPubKey(transcriptHasher, curve, mpcParams.contributions[i]);
}
const curContribution = {};
curContribution.delta = {};
curContribution.delta.prvKey = curve.Fr.fromRng(rng);
curContribution.delta.g1_s = curve.G1.toAffine(curve.G1.fromRng(rng));
curContribution.delta.g1_sx = curve.G1.toAffine(curve.G1.timesFr(curContribution.delta.g1_s, curContribution.delta.prvKey));
hashG1(transcriptHasher, curve, curContribution.delta.g1_s);
hashG1(transcriptHasher, curve, curContribution.delta.g1_sx);
curContribution.transcript = transcriptHasher.digest();
curContribution.delta.g2_sp = hashToG2(curve, curContribution.transcript);
curContribution.delta.g2_spx = curve.G2.toAffine(curve.G2.timesFr(curContribution.delta.g2_sp, curContribution.delta.prvKey));
zkey.vk_delta_1 = curve.G1.timesFr(zkey.vk_delta_1, curContribution.delta.prvKey);
zkey.vk_delta_2 = curve.G2.timesFr(zkey.vk_delta_2, curContribution.delta.prvKey);
curContribution.deltaAfter = zkey.vk_delta_1;
curContribution.type = 0;
if (name) curContribution.name = name;
mpcParams.contributions.push(curContribution);
await writeHeader(fdNew, zkey);
// IC
await copySection(fdOld, sections, fdNew, 3);
// Coeffs (Keep original)
await copySection(fdOld, sections, fdNew, 4);
// A Section
await copySection(fdOld, sections, fdNew, 5);
// B1 Section
await copySection(fdOld, sections, fdNew, 6);
// B2 Section
await copySection(fdOld, sections, fdNew, 7);
const invDelta = curve.Fr.inv(curContribution.delta.prvKey);
await applyKeyToSection(fdOld, sections, fdNew, 8, curve, "G1", invDelta, curve.Fr.e(1), "L Section", logger);
await applyKeyToSection(fdOld, sections, fdNew, 9, curve, "G1", invDelta, curve.Fr.e(1), "H Section", logger);
await writeMPCParams(fdNew, curve, mpcParams);
await fdOld.close();
await fdNew.close();
const contributionHasher = Blake2b(64);
hashPubKey(contributionHasher, curve, curContribution);
const contribuionHash = contributionHasher.digest();
if (logger) logger.info(formatHash(contribuionHash, "Contribution Hash: "));
return contribuionHash;
}
async function beacon$1(zkeyNameOld, zkeyNameNew, name, beaconHashStr, numIterationsExp, logger) {
await Blake2b.ready();
const beaconHash = hex2ByteArray(beaconHashStr);
if ( (beaconHash.byteLength == 0)
|| (beaconHash.byteLength*2 !=beaconHashStr.length))
{
if (logger) logger.error("Invalid Beacon Hash. (It must be a valid hexadecimal sequence)");
return false;
}
if (beaconHash.length>=256) {
if (logger) logger.error("Maximum lenght of beacon hash is 255 bytes");
return false;
}
numIterationsExp = parseInt(numIterationsExp);
if ((numIterationsExp<10)||(numIterationsExp>63)) {
if (logger) logger.error("Invalid numIterationsExp. (Must be between 10 and 63)");
return false;
}
const {fd: fdOld, sections: sections} = await readBinFile(zkeyNameOld, "zkey", 2);
const zkey = await readHeader(fdOld, sections, "groth16");
const curve = await getCurveFromQ(zkey.q);
const mpcParams = await readMPCParams(fdOld, curve, sections);
const fdNew = await createBinFile(zkeyNameNew, "zkey", 1, 10);
const rng = await rngFromBeaconParams(beaconHash, numIterationsExp);
const transcriptHasher = Blake2b(64);
transcriptHasher.update(mpcParams.csHash);
for (let i=0; i<mpcParams.contributions.length; i++) {
hashPubKey(transcriptHasher, curve, mpcParams.contributions[i]);
}
const curContribution = {};
curContribution.delta = {};
curContribution.delta.prvKey = curve.Fr.fromRng(rng);
curContribution.delta.g1_s = curve.G1.toAffine(curve.G1.fromRng(rng));
curContribution.delta.g1_sx = curve.G1.toAffine(curve.G1.timesFr(curContribution.delta.g1_s, curContribution.delta.prvKey));
hashG1(transcriptHasher, curve, curContribution.delta.g1_s);
hashG1(transcriptHasher, curve, curContribution.delta.g1_sx);
curContribution.transcript = transcriptHasher.digest();
curContribution.delta.g2_sp = hashToG2(curve, curContribution.transcript);
curContribution.delta.g2_spx = curve.G2.toAffine(curve.G2.timesFr(curContribution.delta.g2_sp, curContribution.delta.prvKey));
zkey.vk_delta_1 = curve.G1.timesFr(zkey.vk_delta_1, curContribution.delta.prvKey);
zkey.vk_delta_2 = curve.G2.timesFr(zkey.vk_delta_2, curContribution.delta.prvKey);
curContribution.deltaAfter = zkey.vk_delta_1;
curContribution.type = 1;
curContribution.numIterationsExp = numIterationsExp;
curContribution.beaconHash = beaconHash;
if (name) curContribution.name = name;
mpcParams.contributions.push(curContribution);
await writeHeader(fdNew, zkey);
// IC
await copySection(fdOld, sections, fdNew, 3);
// Coeffs (Keep original)
await copySection(fdOld, sections, fdNew, 4);
// A Section
await copySection(fdOld, sections, fdNew, 5);
// B1 Section
await copySection(fdOld, sections, fdNew, 6);
// B2 Section
await copySection(fdOld, sections, fdNew, 7);
const invDelta = curve.Fr.inv(curContribution.delta.prvKey);
await applyKeyToSection(fdOld, sections, fdNew, 8, curve, "G1", invDelta, curve.Fr.e(1), "L Section", logger);
await applyKeyToSection(fdOld, sections, fdNew, 9, curve, "G1", invDelta, curve.Fr.e(1), "H Section", logger);
await writeMPCParams(fdNew, curve, mpcParams);
await fdOld.close();
await fdNew.close();
const contributionHasher = Blake2b(64);
hashPubKey(contributionHasher, curve, curContribution);
const contribuionHash = contributionHasher.digest();
if (logger) logger.info(formatHash(contribuionHash, "Contribution Hash: "));
return contribuionHash;
}
async function zkeyExportJson(zkeyFileName, verbose) {
const zKey = await readZKey(zkeyFileName);
return zKey;
}
// Format of the output
async function bellmanContribute(curve, challengeFilename, responesFileName, entropy, logger) {
await Blake2b.ready();
const rng = await getRandomRng(entropy);
const delta = curve.Fr.fromRng(rng);
const invDelta = curve.Fr.inv(delta);
const sG1 = curve.G1.F.n8*2;
const sG2 = curve.G2.F.n8*2;
const fdFrom = await readExisting$2(challengeFilename);
const fdTo = await createOverride(responesFileName);
await copy(sG1); // alpha1
await copy(sG1); // beta1
await copy(sG2); // beta2
await copy(sG2); // gamma2
const oldDelta1 = await readG1();
const delta1 = curve.G1.timesFr(oldDelta1, delta);
await writeG1(delta1);
const oldDelta2 = await readG2();
const delta2 = curve.G2.timesFr(oldDelta2, delta);
await writeG2(delta2);
// IC
const nIC = await fdFrom.readUBE32();
await fdTo.writeUBE32(nIC);
await copy(nIC*sG1);
// H
const nH = await fdFrom.readUBE32();
await fdTo.writeUBE32(nH);
await applyKeyToChallengeSection(fdFrom, fdTo, null, curve, "G1", nH, invDelta, curve.Fr.e(1), "UNCOMPRESSED", "H", logger);
// L
const nL = await fdFrom.readUBE32();
await fdTo.writeUBE32(nL);
await applyKeyToChallengeSection(fdFrom, fdTo, null, curve, "G1", nL, invDelta, curve.Fr.e(1), "UNCOMPRESSED", "L", logger);
// A
const nA = await fdFrom.readUBE32();
await fdTo.writeUBE32(nA);
await copy(nA*sG1);
// B1
const nB1 = await fdFrom.readUBE32();
await fdTo.writeUBE32(nB1);
await copy(nB1*sG1);
// B2
const nB2 = await fdFrom.readUBE32();
await fdTo.writeUBE32(nB2);
await copy(nB2*sG2);
//////////
/// Read contributions
//////////
const transcriptHasher = Blake2b(64);
const mpcParams = {};
// csHash
mpcParams.csHash = await fdFrom.read(64);
transcriptHasher.update(mpcParams.csHash);
const nConttributions = await fdFrom.readUBE32();
mpcParams.contributions = [];
for (let i=0; i<nConttributions; i++) {
const c = { delta:{} };
c.deltaAfter = await readG1();
c.delta.g1_s = await readG1();
c.delta.g1_sx = await readG1();
c.delta.g2_spx = await readG2();
c.transcript = await fdFrom.read(64);
mpcParams.contributions.push(c);
hashPubKey(transcriptHasher, curve, c);
}
const curContribution = {};
curContribution.delta = {};
curContribution.delta.prvKey = delta;
curContribution.delta.g1_s = curve.G1.toAffine(curve.G1.fromRng(rng));
curContribution.delta.g1_sx = curve.G1.toAffine(curve.G1.timesFr(curContribution.delta.g1_s, delta));
hashG1(transcriptHasher, curve, curContribution.delta.g1_s);
hashG1(transcriptHasher, curve, curContribution.delta.g1_sx);
curContribution.transcript = transcriptHasher.digest();
curContribution.delta.g2_sp = hashToG2(curve, curContribution.transcript);
curContribution.delta.g2_spx = curve.G2.toAffine(curve.G2.timesFr(curContribution.delta.g2_sp, delta));
curContribution.deltaAfter = delta1;
curContribution.type = 0;
mpcParams.contributions.push(curContribution);
//////////
/// Write COntribution
//////////
await fdTo.write(mpcParams.csHash);
await fdTo.writeUBE32(mpcParams.contributions.length);
for (let i=0; i<mpcParams.contributions.length; i++) {
const c = mpcParams.contributions[i];
await writeG1(c.deltaAfter);
await writeG1(c.delta.g1_s);
await writeG1(c.delta.g1_sx);
await writeG2(c.delta.g2_spx);
await fdTo.write(c.transcript);
}
const contributionHasher = Blake2b(64);
hashPubKey(contributionHasher, curve, curContribution);
const contributionHash = contributionHasher.digest();
if (logger) logger.info(formatHash(contributionHash, "Contribution Hash: "));
await fdTo.close();
await fdFrom.close();
return contributionHash;
async function copy(nBytes) {
const CHUNK_SIZE = fdFrom.pageSize*2;
for (let i=0; i<nBytes; i+= CHUNK_SIZE) {
const n = Math.min(nBytes -i, CHUNK_SIZE);
const buff = await fdFrom.read(n);
await fdTo.write(buff);
}
}
async function readG1() {
const buff = await fdFrom.read(curve.G1.F.n8*2);
return curve.G1.fromRprUncompressed(buff, 0);
}
async function readG2() {
const buff = await fdFrom.read(curve.G2.F.n8*2);
return curve.G2.fromRprUncompressed(buff, 0);
}
async function writeG1(P) {
const buff = new Uint8Array(sG1);
curve.G1.toRprUncompressed(buff, 0, P);
await fdTo.write(buff);
}
async function writeG2(P) {
const buff = new Uint8Array(sG2);
curve.G2.toRprUncompressed(buff, 0, P);
await fdTo.write(buff);
}
}
const {stringifyBigInts: stringifyBigInts$1} = ffjavascript.utils;
async function zkeyExportVerificationKey(zkeyName, logger) {
const {fd, sections} = await readBinFile(zkeyName, "zkey", 2);
const zkey = await readHeader(fd, sections, "groth16");
const curve = await getCurveFromQ(zkey.q);
const sG1 = curve.G1.F.n8*2;
const alphaBeta = await curve.pairing( zkey.vk_alpha_1 , zkey.vk_beta_2 );
let vKey = {
protocol: zkey.protocol,
curve: curve.name,
nPublic: zkey.nPublic,
vk_alpha_1: curve.G1.toObject(zkey.vk_alpha_1),
vk_beta_2: curve.G2.toObject(zkey.vk_beta_2),
vk_gamma_2: curve.G2.toObject(zkey.vk_gamma_2),
vk_delta_2: curve.G2.toObject(zkey.vk_delta_2),
vk_alphabeta_12: curve.Gt.toObject(alphaBeta)
};
// Read IC Section
///////////
await startReadUniqueSection(fd, sections, 3);
vKey.IC = [];
for (let i=0; i<= zkey.nPublic; i++) {
const buff = await fd.read(sG1);
const P = curve.G1.toObject(buff);
vKey.IC.push(P);
}
await endReadSection(fd);
vKey = stringifyBigInts$1(vKey);
await fd.close();
return vKey;
}
// Not ready yet
// module.exports.generateVerifier_kimleeoh = generateVerifier_kimleeoh;
async function exportSolidityVerifier(zKeyName, templateName, logger) {
const verificationKey = await zkeyExportVerificationKey(zKeyName);
const fd = await readExisting$2(templateName);
const buff = await fd.read(fd.totalSize);
let template = new TextDecoder("utf-8").decode(buff);
const vkalpha1_str = `${verificationKey.vk_alpha_1[0].toString()},`+
`${verificationKey.vk_alpha_1[1].toString()}`;
template = template.replace("<%vk_alpha1%>", vkalpha1_str);
const vkbeta2_str = `[${verificationKey.vk_beta_2[0][1].toString()},`+
`${verificationKey.vk_beta_2[0][0].toString()}], `+
`[${verificationKey.vk_beta_2[1][1].toString()},` +
`${verificationKey.vk_beta_2[1][0].toString()}]`;
template = template.replace("<%vk_beta2%>", vkbeta2_str);
const vkgamma2_str = `[${verificationKey.vk_gamma_2[0][1].toString()},`+
`${verificationKey.vk_gamma_2[0][0].toString()}], `+
`[${verificationKey.vk_gamma_2[1][1].toString()},` +
`${verificationKey.vk_gamma_2[1][0].toString()}]`;
template = template.replace("<%vk_gamma2%>", vkgamma2_str);
const vkdelta2_str = `[${verificationKey.vk_delta_2[0][1].toString()},`+
`${verificationKey.vk_delta_2[0][0].toString()}], `+
`[${verificationKey.vk_delta_2[1][1].toString()},` +
`${verificationKey.vk_delta_2[1][0].toString()}]`;
template = template.replace("<%vk_delta2%>", vkdelta2_str);
// The points
template = template.replace("<%vk_input_length%>", (verificationKey.IC.length-1).toString());
template = template.replace("<%vk_ic_length%>", verificationKey.IC.length.toString());
let vi = "";
for (let i=0; i<verificationKey.IC.length; i++) {
if (vi != "") vi = vi + " ";
vi = vi + `vk.IC[${i}] = Pairing.G1Point(${verificationKey.IC[i][0].toString()},`+
`${verificationKey.IC[i][1].toString()});\n`;
}
template = template.replace("<%vk_ic_pts%>", vi);
return template;
}
var zkey = /*#__PURE__*/Object.freeze({
__proto__: null,
newZKey: newZKey,
exportBellman: phase2exportMPCParams,
importBellman: phase2importMPCParams,
verify: phase2verify,
contribute: phase2contribute,
beacon: beacon$1,
exportJson: zkeyExportJson,
bellmanContribute: bellmanContribute,
exportVerificationKey: zkeyExportVerificationKey,
exportSolidityVerifier: exportSolidityVerifier
});
exports.groth16 = groth16;
exports.powersOfTau = powersoftau;
exports.r1cs = r1cs;
exports.wtns = wtns;
exports.zKey = zkey;
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