ethers.js/packages/json-wallets/lib.esm/keystore.js

"use strict";
var __awaiter = (this && this.__awaiter) || function (thisArg, _arguments, P, generator) {
    function adopt(value) { return value instanceof P ? value : new P(function (resolve) { resolve(value); }); }
    return new (P || (P = Promise))(function (resolve, reject) {
        function fulfilled(value) { try { step(generator.next(value)); } catch (e) { reject(e); } }
        function rejected(value) { try { step(generator["throw"](value)); } catch (e) { reject(e); } }
        function step(result) { result.done ? resolve(result.value) : adopt(result.value).then(fulfilled, rejected); }
        step((generator = generator.apply(thisArg, _arguments || [])).next());
    });
};
import aes from "aes-js";
import * as scrypt from "scrypt-js";
import uuid from "uuid";
import { getAddress } from "@ethersproject/address";
import { arrayify, concat, hexlify } from "@ethersproject/bytes";
import { defaultPath, entropyToMnemonic, HDNode, mnemonicToEntropy } from "@ethersproject/hdnode";
import { keccak256 } from "@ethersproject/keccak256";
import { pbkdf2 } from "@ethersproject/pbkdf2";
import { randomBytes } from "@ethersproject/random";
import { Description } from "@ethersproject/properties";
import { computeAddress } from "@ethersproject/transactions";
import { getPassword, looseArrayify, searchPath, zpad } from "./utils";
import { Logger } from "@ethersproject/logger";
import { version } from "./_version";
const logger = new Logger(version);
// Exported Types
function hasMnemonic(value) {
    return (value != null && value.mnemonic && value.mnemonic.phrase);
}
export class KeystoreAccount extends Description {
    isKeystoreAccount(value) {
        return !!(value && value._isKeystoreAccount);
    }
}
export function decrypt(json, password, progressCallback) {
    return __awaiter(this, void 0, void 0, function* () {
        const data = JSON.parse(json);
        const passwordBytes = getPassword(password);
        const decrypt = function (key, ciphertext) {
            const cipher = searchPath(data, "crypto/cipher");
            if (cipher === "aes-128-ctr") {
                const iv = looseArrayify(searchPath(data, "crypto/cipherparams/iv"));
                const counter = new aes.Counter(iv);
                const aesCtr = new aes.ModeOfOperation.ctr(key, counter);
                return arrayify(aesCtr.decrypt(ciphertext));
            }
            return null;
        };
        const computeMAC = function (derivedHalf, ciphertext) {
            return keccak256(concat([derivedHalf, ciphertext]));
        };
        const getAccount = function (key) {
            return __awaiter(this, void 0, void 0, function* () {
                const ciphertext = looseArrayify(searchPath(data, "crypto/ciphertext"));
                const computedMAC = hexlify(computeMAC(key.slice(16, 32), ciphertext)).substring(2);
                if (computedMAC !== searchPath(data, "crypto/mac").toLowerCase()) {
                    throw new Error("invalid password");
                }
                const privateKey = decrypt(key.slice(0, 16), ciphertext);
                const mnemonicKey = key.slice(32, 64);
                if (!privateKey) {
                    logger.throwError("unsupported cipher", Logger.errors.UNSUPPORTED_OPERATION, {
                        operation: "decrypt"
                    });
                }
                const address = computeAddress(privateKey);
                if (data.address) {
                    let check = data.address.toLowerCase();
                    if (check.substring(0, 2) !== "0x") {
                        check = "0x" + check;
                    }
                    if (getAddress(check) !== address) {
                        throw new Error("address mismatch");
                    }
                }
                const account = {
                    _isKeystoreAccount: true,
                    address: address,
                    privateKey: hexlify(privateKey)
                };
                // Version 0.1 x-ethers metadata must contain an encrypted mnemonic phrase
                if (searchPath(data, "x-ethers/version") === "0.1") {
                    const mnemonicCiphertext = looseArrayify(searchPath(data, "x-ethers/mnemonicCiphertext"));
                    const mnemonicIv = looseArrayify(searchPath(data, "x-ethers/mnemonicCounter"));
                    const mnemonicCounter = new aes.Counter(mnemonicIv);
                    const mnemonicAesCtr = new aes.ModeOfOperation.ctr(mnemonicKey, mnemonicCounter);
                    const path = searchPath(data, "x-ethers/path") || defaultPath;
                    const locale = searchPath(data, "x-ethers/locale") || "en";
                    const entropy = arrayify(mnemonicAesCtr.decrypt(mnemonicCiphertext));
                    try {
                        const mnemonic = entropyToMnemonic(entropy, locale);
                        const node = HDNode.fromMnemonic(mnemonic, null, locale).derivePath(path);
                        if (node.privateKey != account.privateKey) {
                            throw new Error("mnemonic mismatch");
                        }
                        account.mnemonic = node.mnemonic;
                    }
                    catch (error) {
                        // If we don't have the locale wordlist installed to
                        // read this mnemonic, just bail and don't set the
                        // mnemonic
                        if (error.code !== Logger.errors.INVALID_ARGUMENT || error.argument !== "wordlist") {
                            throw error;
                        }
                    }
                }
                return new KeystoreAccount(account);
            });
        };
        const kdf = searchPath(data, "crypto/kdf");
        if (kdf && typeof (kdf) === "string") {
            const throwError = function (name, value) {
                return logger.throwArgumentError("invalid key-derivation function parameters", name, value);
            };
            if (kdf.toLowerCase() === "scrypt") {
                const salt = looseArrayify(searchPath(data, "crypto/kdfparams/salt"));
                const N = parseInt(searchPath(data, "crypto/kdfparams/n"));
                const r = parseInt(searchPath(data, "crypto/kdfparams/r"));
                const p = parseInt(searchPath(data, "crypto/kdfparams/p"));
                // Check for all required parameters
                if (!N || !r || !p) {
                    throwError("kdf", kdf);
                }
                // Make sure N is a power of 2
                if ((N & (N - 1)) !== 0) {
                    throwError("N", N);
                }
                const dkLen = parseInt(searchPath(data, "crypto/kdfparams/dklen"));
                if (dkLen !== 32) {
                    throwError("dklen", dkLen);
                }
                const key = yield scrypt.scrypt(passwordBytes, salt, N, r, p, 64, progressCallback);
                //key = arrayify(key);
                return getAccount(key);
            }
            else if (kdf.toLowerCase() === "pbkdf2") {
                const salt = looseArrayify(searchPath(data, "crypto/kdfparams/salt"));
                let prfFunc = null;
                const prf = searchPath(data, "crypto/kdfparams/prf");
                if (prf === "hmac-sha256") {
                    prfFunc = "sha256";
                }
                else if (prf === "hmac-sha512") {
                    prfFunc = "sha512";
                }
                else {
                    throwError("prf", prf);
                }
                const c = parseInt(searchPath(data, "crypto/kdfparams/c"));
                const dkLen = parseInt(searchPath(data, "crypto/kdfparams/dklen"));
                if (dkLen !== 32) {
                    throwError("dklen", dkLen);
                }
                const key = arrayify(pbkdf2(passwordBytes, salt, c, dkLen, prfFunc));
                return getAccount(key);
            }
        }
        return logger.throwArgumentError("unsupported key-derivation function", "kdf", kdf);
    });
}
export function encrypt(account, password, options, progressCallback) {
    try {
        // Check the address matches the private key
        if (getAddress(account.address) !== computeAddress(account.privateKey)) {
            throw new Error("address/privateKey mismatch");
        }
        // Check the mnemonic (if any) matches the private key
        if (hasMnemonic(account)) {
            const mnemonic = account.mnemonic;
            const node = HDNode.fromMnemonic(mnemonic.phrase, null, mnemonic.locale).derivePath(mnemonic.path || defaultPath);
            if (node.privateKey != account.privateKey) {
                throw new Error("mnemonic mismatch");
            }
        }
    }
    catch (e) {
        return Promise.reject(e);
    }
    // The options are optional, so adjust the call as needed
    if (typeof (options) === "function" && !progressCallback) {
        progressCallback = options;
        options = {};
    }
    if (!options) {
        options = {};
    }
    const privateKey = arrayify(account.privateKey);
    const passwordBytes = getPassword(password);
    let entropy = null;
    let path = null;
    let locale = null;
    if (hasMnemonic(account)) {
        const srcMnemonic = account.mnemonic;
        entropy = arrayify(mnemonicToEntropy(srcMnemonic.phrase, srcMnemonic.locale || "en"));
        path = srcMnemonic.path || defaultPath;
        locale = srcMnemonic.locale || "en";
    }
    let client = options.client;
    if (!client) {
        client = "ethers.js";
    }
    // Check/generate the salt
    let salt = null;
    if (options.salt) {
        salt = arrayify(options.salt);
    }
    else {
        salt = randomBytes(32);
        ;
    }
    // Override initialization vector
    let iv = null;
    if (options.iv) {
        iv = arrayify(options.iv);
        if (iv.length !== 16) {
            throw new Error("invalid iv");
        }
    }
    else {
        iv = randomBytes(16);
    }
    // Override the uuid
    let uuidRandom = null;
    if (options.uuid) {
        uuidRandom = arrayify(options.uuid);
        if (uuidRandom.length !== 16) {
            throw new Error("invalid uuid");
        }
    }
    else {
        uuidRandom = randomBytes(16);
    }
    // Override the scrypt password-based key derivation function parameters
    let N = (1 << 17), r = 8, p = 1;
    if (options.scrypt) {
        if (options.scrypt.N) {
            N = options.scrypt.N;
        }
        if (options.scrypt.r) {
            r = options.scrypt.r;
        }
        if (options.scrypt.p) {
            p = options.scrypt.p;
        }
    }
    // We take 64 bytes:
    //   - 32 bytes   As normal for the Web3 secret storage (derivedKey, macPrefix)
    //   - 32 bytes   AES key to encrypt mnemonic with (required here to be Ethers Wallet)
    return scrypt.scrypt(passwordBytes, salt, N, r, p, 64, progressCallback).then((key) => {
        key = arrayify(key);
        // This will be used to encrypt the wallet (as per Web3 secret storage)
        const derivedKey = key.slice(0, 16);
        const macPrefix = key.slice(16, 32);
        // This will be used to encrypt the mnemonic phrase (if any)
        const mnemonicKey = key.slice(32, 64);
        // Encrypt the private key
        const counter = new aes.Counter(iv);
        const aesCtr = new aes.ModeOfOperation.ctr(derivedKey, counter);
        const ciphertext = arrayify(aesCtr.encrypt(privateKey));
        // Compute the message authentication code, used to check the password
        const mac = keccak256(concat([macPrefix, ciphertext]));
        // See: https://github.com/ethereum/wiki/wiki/Web3-Secret-Storage-Definition
        const data = {
            address: account.address.substring(2).toLowerCase(),
            id: uuid.v4({ random: uuidRandom }),
            version: 3,
            Crypto: {
                cipher: "aes-128-ctr",
                cipherparams: {
                    iv: hexlify(iv).substring(2),
                },
                ciphertext: hexlify(ciphertext).substring(2),
                kdf: "scrypt",
                kdfparams: {
                    salt: hexlify(salt).substring(2),
                    n: N,
                    dklen: 32,
                    p: p,
                    r: r
                },
                mac: mac.substring(2)
            }
        };
        // If we have a mnemonic, encrypt it into the JSON wallet
        if (entropy) {
            const mnemonicIv = randomBytes(16);
            const mnemonicCounter = new aes.Counter(mnemonicIv);
            const mnemonicAesCtr = new aes.ModeOfOperation.ctr(mnemonicKey, mnemonicCounter);
            const mnemonicCiphertext = arrayify(mnemonicAesCtr.encrypt(entropy));
            const now = new Date();
            const timestamp = (now.getUTCFullYear() + "-" +
                zpad(now.getUTCMonth() + 1, 2) + "-" +
                zpad(now.getUTCDate(), 2) + "T" +
                zpad(now.getUTCHours(), 2) + "-" +
                zpad(now.getUTCMinutes(), 2) + "-" +
                zpad(now.getUTCSeconds(), 2) + ".0Z");
            data["x-ethers"] = {
                client: client,
                gethFilename: ("UTC--" + timestamp + "--" + data.address),
                mnemonicCounter: hexlify(mnemonicIv).substring(2),
                mnemonicCiphertext: hexlify(mnemonicCiphertext).substring(2),
                path: path,
                locale: locale,
                version: "0.1"
            };
        }
        return JSON.stringify(data);
    });
}