Viewing File: /home/ubuntu/efiexchange-node-base/node_modules/ethereum-cryptography/secp256k1-compat.js
"use strict";
Object.defineProperty(exports, "__esModule", { value: true });
exports.createPrivateKeySync = createPrivateKeySync;
exports.createPrivateKey = createPrivateKey;
exports.privateKeyVerify = privateKeyVerify;
exports.publicKeyCreate = publicKeyCreate;
exports.publicKeyVerify = publicKeyVerify;
exports.publicKeyConvert = publicKeyConvert;
exports.ecdsaSign = ecdsaSign;
exports.ecdsaRecover = ecdsaRecover;
exports.ecdsaVerify = ecdsaVerify;
exports.privateKeyTweakAdd = privateKeyTweakAdd;
exports.privateKeyNegate = privateKeyNegate;
exports.publicKeyNegate = publicKeyNegate;
exports.publicKeyCombine = publicKeyCombine;
exports.publicKeyTweakAdd = publicKeyTweakAdd;
exports.publicKeyTweakMul = publicKeyTweakMul;
exports.privateKeyTweakMul = privateKeyTweakMul;
exports.signatureExport = signatureExport;
exports.signatureImport = signatureImport;
exports.signatureNormalize = signatureNormalize;
exports.ecdh = ecdh;
exports.contextRandomize = contextRandomize;
const sha256_1 = require("@noble/hashes/sha256");
const modular_1 = require("@noble/curves/abstract/modular");
const secp256k1_js_1 = require("./secp256k1.js");
const utils_js_1 = require("./utils.js");
// Use `secp256k1` module directly.
// This is a legacy compatibility layer for the npm package `secp256k1` via noble-secp256k1
const Point = secp256k1_js_1.secp256k1.ProjectivePoint;
function hexToNumber(hex) {
if (typeof hex !== "string") {
throw new TypeError("hexToNumber: expected string, got " + typeof hex);
}
return BigInt(`0x${hex}`);
}
// Copy-paste from secp256k1, maybe export it?
const bytesToNumber = (bytes) => hexToNumber((0, utils_js_1.toHex)(bytes));
const numberToHex = (num) => num.toString(16).padStart(64, "0");
const numberToBytes = (num) => (0, utils_js_1.hexToBytes)(numberToHex(num));
const ORDER = secp256k1_js_1.secp256k1.CURVE.n;
function output(out = (len) => new Uint8Array(len), length, value) {
if (typeof out === "function") {
out = out(length);
}
(0, utils_js_1.assertBytes)(out, length);
if (value) {
out.set(value);
}
return out;
}
function getSignature(signature) {
(0, utils_js_1.assertBytes)(signature, 64);
return secp256k1_js_1.secp256k1.Signature.fromCompact(signature);
}
function createPrivateKeySync() {
return secp256k1_js_1.secp256k1.utils.randomPrivateKey();
}
async function createPrivateKey() {
return createPrivateKeySync();
}
function privateKeyVerify(privateKey) {
(0, utils_js_1.assertBytes)(privateKey, 32);
return secp256k1_js_1.secp256k1.utils.isValidPrivateKey(privateKey);
}
function publicKeyCreate(privateKey, compressed = true, out) {
(0, utils_js_1.assertBytes)(privateKey, 32);
(0, utils_js_1.assertBool)(compressed);
const res = secp256k1_js_1.secp256k1.getPublicKey(privateKey, compressed);
return output(out, compressed ? 33 : 65, res);
}
function publicKeyVerify(publicKey) {
(0, utils_js_1.assertBytes)(publicKey, 33, 65);
try {
Point.fromHex(publicKey);
return true;
}
catch (e) {
return false;
}
}
function publicKeyConvert(publicKey, compressed = true, out) {
(0, utils_js_1.assertBytes)(publicKey, 33, 65);
(0, utils_js_1.assertBool)(compressed);
const res = Point.fromHex(publicKey).toRawBytes(compressed);
return output(out, compressed ? 33 : 65, res);
}
function ecdsaSign(msgHash, privateKey, options = { noncefn: undefined, data: undefined }, out) {
(0, utils_js_1.assertBytes)(msgHash, 32);
(0, utils_js_1.assertBytes)(privateKey, 32);
if (typeof options !== "object" || options === null) {
throw new TypeError("secp256k1.ecdsaSign: options should be object");
}
// noble-secp256k1 uses hmac instead of hmac-drbg here
if (options &&
(options.noncefn !== undefined || options.data !== undefined)) {
throw new Error("Secp256k1: noncefn && data is unsupported");
}
const sig = secp256k1_js_1.secp256k1.sign(msgHash, privateKey);
const recid = sig.recovery;
return { signature: output(out, 64, sig.toCompactRawBytes()), recid };
}
function ecdsaRecover(signature, recid, msgHash, compressed = true, out) {
(0, utils_js_1.assertBytes)(msgHash, 32);
(0, utils_js_1.assertBool)(compressed);
const sign = getSignature(signature);
const point = sign.addRecoveryBit(recid).recoverPublicKey(msgHash);
return output(out, compressed ? 33 : 65, point.toRawBytes(compressed));
}
function ecdsaVerify(signature, msgHash, publicKey) {
(0, utils_js_1.assertBytes)(signature, 64);
(0, utils_js_1.assertBytes)(msgHash, 32);
(0, utils_js_1.assertBytes)(publicKey, 33, 65);
(0, utils_js_1.assertBytes)(signature, 64);
const r = bytesToNumber(signature.slice(0, 32));
const s = bytesToNumber(signature.slice(32, 64));
if (r >= ORDER || s >= ORDER) {
throw new Error("Cannot parse signature");
}
const pub = Point.fromHex(publicKey); // can throw error
pub; // typescript
let sig;
try {
sig = getSignature(signature);
}
catch (error) {
return false;
}
return secp256k1_js_1.secp256k1.verify(sig, msgHash, publicKey);
}
function privateKeyTweakAdd(privateKey, tweak) {
(0, utils_js_1.assertBytes)(privateKey, 32);
(0, utils_js_1.assertBytes)(tweak, 32);
let t = bytesToNumber(tweak);
if (t === 0n) {
throw new Error("Tweak must not be zero");
}
if (t >= ORDER) {
throw new Error("Tweak bigger than curve order");
}
t += bytesToNumber(privateKey);
if (t >= ORDER) {
t -= ORDER;
}
if (t === 0n) {
throw new Error("The tweak was out of range or the resulted private key is invalid");
}
privateKey.set((0, utils_js_1.hexToBytes)(numberToHex(t)));
return privateKey;
}
function privateKeyNegate(privateKey) {
(0, utils_js_1.assertBytes)(privateKey, 32);
const bn = (0, modular_1.mod)(-bytesToNumber(privateKey), ORDER);
privateKey.set((0, utils_js_1.hexToBytes)(numberToHex(bn)));
return privateKey;
}
function publicKeyNegate(publicKey, compressed = true, out) {
(0, utils_js_1.assertBytes)(publicKey, 33, 65);
(0, utils_js_1.assertBool)(compressed);
const point = Point.fromHex(publicKey).negate();
return output(out, compressed ? 33 : 65, point.toRawBytes(compressed));
}
function publicKeyCombine(publicKeys, compressed = true, out) {
if (!Array.isArray(publicKeys) || !publicKeys.length) {
throw new TypeError(`Expected array with one or more items, not ${publicKeys}`);
}
for (const publicKey of publicKeys) {
(0, utils_js_1.assertBytes)(publicKey, 33, 65);
}
(0, utils_js_1.assertBool)(compressed);
const combined = publicKeys
.map((pub) => Point.fromHex(pub))
.reduce((res, curr) => res.add(curr), Point.ZERO);
// Prohibit returning ZERO point
if (combined.equals(Point.ZERO)) {
throw new Error("Combined result must not be zero");
}
return output(out, compressed ? 33 : 65, combined.toRawBytes(compressed));
}
function publicKeyTweakAdd(publicKey, tweak, compressed = true, out) {
(0, utils_js_1.assertBytes)(publicKey, 33, 65);
(0, utils_js_1.assertBytes)(tweak, 32);
(0, utils_js_1.assertBool)(compressed);
const p1 = Point.fromHex(publicKey);
const p2 = Point.fromPrivateKey(tweak);
const point = p1.add(p2);
if (p2.equals(Point.ZERO) || point.equals(Point.ZERO)) {
throw new Error("Tweak must not be zero");
}
return output(out, compressed ? 33 : 65, point.toRawBytes(compressed));
}
function publicKeyTweakMul(publicKey, tweak, compressed = true, out) {
(0, utils_js_1.assertBytes)(publicKey, 33, 65);
(0, utils_js_1.assertBytes)(tweak, 32);
(0, utils_js_1.assertBool)(compressed);
const bn = bytesToNumber(tweak);
if (bn === 0n) {
throw new Error("Tweak must not be zero");
}
if (bn <= 1 || bn >= ORDER) {
throw new Error("Tweak is zero or bigger than curve order");
}
const point = Point.fromHex(publicKey).multiply(bn);
return output(out, compressed ? 33 : 65, point.toRawBytes(compressed));
}
function privateKeyTweakMul(privateKey, tweak) {
(0, utils_js_1.assertBytes)(privateKey, 32);
(0, utils_js_1.assertBytes)(tweak, 32);
const bn = bytesToNumber(tweak);
if (bn <= 1 || bn >= ORDER) {
throw new Error("Tweak is zero or bigger than curve order");
}
const res = (0, modular_1.mod)(bn * bytesToNumber(privateKey), ORDER);
if (res === 0n) {
throw new Error("The tweak was out of range or the resulted private key is invalid");
}
privateKey.set((0, utils_js_1.hexToBytes)(numberToHex(res)));
return privateKey;
}
// internal -> DER
function signatureExport(signature, out) {
const res = getSignature(signature).toDERRawBytes();
return output(out, 72, res.slice()).slice(0, res.length);
}
// DER -> internal
function signatureImport(signature, out) {
(0, utils_js_1.assertBytes)(signature);
const sig = secp256k1_js_1.secp256k1.Signature.fromDER(signature);
return output(out, 64, (0, utils_js_1.hexToBytes)(sig.toCompactHex()));
}
function signatureNormalize(signature) {
const res = getSignature(signature);
if (res.s > ORDER / 2n) {
signature.set(numberToBytes(ORDER - res.s), 32);
}
return signature;
}
function ecdh(publicKey, privateKey, options = {}, out) {
(0, utils_js_1.assertBytes)(publicKey, 33, 65);
(0, utils_js_1.assertBytes)(privateKey, 32);
if (typeof options !== "object" || options === null) {
throw new TypeError("secp256k1.ecdh: options should be object");
}
if (options.data !== undefined) {
(0, utils_js_1.assertBytes)(options.data);
}
const point = Point.fromHex(secp256k1_js_1.secp256k1.getSharedSecret(privateKey, publicKey));
if (options.hashfn === undefined) {
return output(out, 32, (0, sha256_1.sha256)(point.toRawBytes(true)));
}
if (typeof options.hashfn !== "function") {
throw new TypeError("secp256k1.ecdh: options.hashfn should be function");
}
if (options.xbuf !== undefined) {
(0, utils_js_1.assertBytes)(options.xbuf, 32);
}
if (options.ybuf !== undefined) {
(0, utils_js_1.assertBytes)(options.ybuf, 32);
}
(0, utils_js_1.assertBytes)(out, 32);
const { x, y } = point.toAffine();
const xbuf = options.xbuf || new Uint8Array(32);
xbuf.set(numberToBytes(x));
const ybuf = options.ybuf || new Uint8Array(32);
ybuf.set(numberToBytes(y));
const hash = options.hashfn(xbuf, ybuf, options.data);
if (!(hash instanceof Uint8Array) || hash.length !== 32) {
throw new Error("secp256k1.ecdh: invalid options.hashfn output");
}
return output(out, 32, hash);
}
function contextRandomize(seed) {
if (seed !== null) {
(0, utils_js_1.assertBytes)(seed, 32);
}
// There is no context to randomize
}
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