"use strict";
Object.defineProperty(exports, "__esModule", { value: true });
exports.accountBodyToRLP = exports.accountBodyToSlim = exports.accountBodyFromSlim = exports.isZeroAddress = exports.zeroAddress = exports.importPublic = exports.privateToAddress = exports.privateToPublic = exports.publicToAddress = exports.pubToAddress = exports.isValidPublic = exports.isValidPrivate = exports.generateAddress2 = exports.generateAddress = exports.isValidChecksumAddress = exports.toChecksumAddress = exports.isValidAddress = exports.Account = void 0;
const rlp_1 = require("@ethereumjs/rlp");
const keccak_1 = require("ethereum-cryptography/keccak");
const secp256k1_1 = require("ethereum-cryptography/secp256k1");
const utils_1 = require("ethereum-cryptography/utils");
const bytes_1 = require("./bytes");
const constants_1 = require("./constants");
const helpers_1 = require("./helpers");
const internal_1 = require("./internal");
const _0n = BigInt(0);
class Account {
/**
* This constructor assigns and validates the values.
* Use the static factory methods to assist in creating an Account from varying data types.
*/
constructor(nonce = _0n, balance = _0n, storageRoot = constants_1.KECCAK256_RLP, codeHash = constants_1.KECCAK256_NULL) {
this.nonce = nonce;
this.balance = balance;
this.storageRoot = storageRoot;
this.codeHash = codeHash;
this._validate();
}
static fromAccountData(accountData) {
const { nonce, balance, storageRoot, codeHash } = accountData;
return new Account(nonce !== undefined ? (0, bytes_1.bufferToBigInt)((0, bytes_1.toBuffer)(nonce)) : undefined, balance !== undefined ? (0, bytes_1.bufferToBigInt)((0, bytes_1.toBuffer)(balance)) : undefined, storageRoot !== undefined ? (0, bytes_1.toBuffer)(storageRoot) : undefined, codeHash !== undefined ? (0, bytes_1.toBuffer)(codeHash) : undefined);
}
static fromRlpSerializedAccount(serialized) {
const values = (0, bytes_1.arrToBufArr)(rlp_1.RLP.decode(Uint8Array.from(serialized)));
if (!Array.isArray(values)) {
throw new Error('Invalid serialized account input. Must be array');
}
return this.fromValuesArray(values);
}
static fromValuesArray(values) {
const [nonce, balance, storageRoot, codeHash] = values;
return new Account((0, bytes_1.bufferToBigInt)(nonce), (0, bytes_1.bufferToBigInt)(balance), storageRoot, codeHash);
}
_validate() {
if (this.nonce < _0n) {
throw new Error('nonce must be greater than zero');
}
if (this.balance < _0n) {
throw new Error('balance must be greater than zero');
}
if (this.storageRoot.length !== 32) {
throw new Error('storageRoot must have a length of 32');
}
if (this.codeHash.length !== 32) {
throw new Error('codeHash must have a length of 32');
}
}
/**
* Returns a Buffer Array of the raw Buffers for the account, in order.
*/
raw() {
return [
(0, bytes_1.bigIntToUnpaddedBuffer)(this.nonce),
(0, bytes_1.bigIntToUnpaddedBuffer)(this.balance),
this.storageRoot,
this.codeHash,
];
}
/**
* Returns the RLP serialization of the account as a `Buffer`.
*/
serialize() {
return Buffer.from(rlp_1.RLP.encode((0, bytes_1.bufArrToArr)(this.raw())));
}
/**
* Returns a `Boolean` determining if the account is a contract.
*/
isContract() {
return !this.codeHash.equals(constants_1.KECCAK256_NULL);
}
/**
* Returns a `Boolean` determining if the account is empty complying to the definition of
* account emptiness in [EIP-161](https://eips.ethereum.org/EIPS/eip-161):
* "An account is considered empty when it has no code and zero nonce and zero balance."
*/
isEmpty() {
return this.balance === _0n && this.nonce === _0n && this.codeHash.equals(constants_1.KECCAK256_NULL);
}
}
exports.Account = Account;
/**
* Checks if the address is a valid. Accepts checksummed addresses too.
*/
const isValidAddress = function (hexAddress) {
try {
(0, helpers_1.assertIsString)(hexAddress);
}
catch (e) {
return false;
}
return /^0x[0-9a-fA-F]{40}$/.test(hexAddress);
};
exports.isValidAddress = isValidAddress;
/**
* Returns a checksummed address.
*
* If an eip1191ChainId is provided, the chainId will be included in the checksum calculation. This
* has the effect of checksummed addresses for one chain having invalid checksums for others.
* For more details see [EIP-1191](https://eips.ethereum.org/EIPS/eip-1191).
*
* WARNING: Checksums with and without the chainId will differ and the EIP-1191 checksum is not
* backwards compatible to the original widely adopted checksum format standard introduced in
* [EIP-55](https://eips.ethereum.org/EIPS/eip-55), so this will break in existing applications.
* Usage of this EIP is therefore discouraged unless you have a very targeted use case.
*/
const toChecksumAddress = function (hexAddress, eip1191ChainId) {
(0, helpers_1.assertIsHexString)(hexAddress);
const address = (0, internal_1.stripHexPrefix)(hexAddress).toLowerCase();
let prefix = '';
if (eip1191ChainId !== undefined) {
const chainId = (0, bytes_1.bufferToBigInt)((0, bytes_1.toBuffer)(eip1191ChainId));
prefix = chainId.toString() + '0x';
}
const buf = Buffer.from(prefix + address, 'utf8');
const hash = (0, utils_1.bytesToHex)((0, keccak_1.keccak256)(buf));
let ret = '0x';
for (let i = 0; i < address.length; i++) {
if (parseInt(hash[i], 16) >= 8) {
ret += address[i].toUpperCase();
}
else {
ret += address[i];
}
}
return ret;
};
exports.toChecksumAddress = toChecksumAddress;
/**
* Checks if the address is a valid checksummed address.
*
* See toChecksumAddress' documentation for details about the eip1191ChainId parameter.
*/
const isValidChecksumAddress = function (hexAddress, eip1191ChainId) {
return (0, exports.isValidAddress)(hexAddress) && (0, exports.toChecksumAddress)(hexAddress, eip1191ChainId) === hexAddress;
};
exports.isValidChecksumAddress = isValidChecksumAddress;
/**
* Generates an address of a newly created contract.
* @param from The address which is creating this new address
* @param nonce The nonce of the from account
*/
const generateAddress = function (from, nonce) {
(0, helpers_1.assertIsBuffer)(from);
(0, helpers_1.assertIsBuffer)(nonce);
if ((0, bytes_1.bufferToBigInt)(nonce) === BigInt(0)) {
// in RLP we want to encode null in the case of zero nonce
// read the RLP documentation for an answer if you dare
return Buffer.from((0, keccak_1.keccak256)(rlp_1.RLP.encode((0, bytes_1.bufArrToArr)([from, null])))).slice(-20);
}
// Only take the lower 160bits of the hash
return Buffer.from((0, keccak_1.keccak256)(rlp_1.RLP.encode((0, bytes_1.bufArrToArr)([from, nonce])))).slice(-20);
};
exports.generateAddress = generateAddress;
/**
* Generates an address for a contract created using CREATE2.
* @param from The address which is creating this new address
* @param salt A salt
* @param initCode The init code of the contract being created
*/
const generateAddress2 = function (from, salt, initCode) {
(0, helpers_1.assertIsBuffer)(from);
(0, helpers_1.assertIsBuffer)(salt);
(0, helpers_1.assertIsBuffer)(initCode);
if (from.length !== 20) {
throw new Error('Expected from to be of length 20');
}
if (salt.length !== 32) {
throw new Error('Expected salt to be of length 32');
}
const address = (0, keccak_1.keccak256)(Buffer.concat([Buffer.from('ff', 'hex'), from, salt, (0, keccak_1.keccak256)(initCode)]));
return (0, bytes_1.toBuffer)(address).slice(-20);
};
exports.generateAddress2 = generateAddress2;
/**
* Checks if the private key satisfies the rules of the curve secp256k1.
*/
const isValidPrivate = function (privateKey) {
return secp256k1_1.secp256k1.utils.isValidPrivateKey(privateKey);
};
exports.isValidPrivate = isValidPrivate;
/**
* Checks if the public key satisfies the rules of the curve secp256k1
* and the requirements of Ethereum.
* @param publicKey The two points of an uncompressed key, unless sanitize is enabled
* @param sanitize Accept public keys in other formats
*/
const isValidPublic = function (publicKey, sanitize = false) {
(0, helpers_1.assertIsBuffer)(publicKey);
if (publicKey.length === 64) {
// Convert to SEC1 for secp256k1
// Automatically checks whether point is on curve
try {
secp256k1_1.secp256k1.ProjectivePoint.fromHex(Buffer.concat([Buffer.from([4]), publicKey]));
return true;
}
catch (e) {
return false;
}
}
if (!sanitize) {
return false;
}
try {
secp256k1_1.secp256k1.ProjectivePoint.fromHex(publicKey);
return true;
}
catch (e) {
return false;
}
};
exports.isValidPublic = isValidPublic;
/**
* Returns the ethereum address of a given public key.
* Accepts "Ethereum public keys" and SEC1 encoded keys.
* @param pubKey The two points of an uncompressed key, unless sanitize is enabled
* @param sanitize Accept public keys in other formats
*/
const pubToAddress = function (pubKey, sanitize = false) {
(0, helpers_1.assertIsBuffer)(pubKey);
if (sanitize && pubKey.length !== 64) {
pubKey = Buffer.from(secp256k1_1.secp256k1.ProjectivePoint.fromHex(pubKey).toRawBytes(false).slice(1));
}
if (pubKey.length !== 64) {
throw new Error('Expected pubKey to be of length 64');
}
// Only take the lower 160bits of the hash
return Buffer.from((0, keccak_1.keccak256)(pubKey)).slice(-20);
};
exports.pubToAddress = pubToAddress;
exports.publicToAddress = exports.pubToAddress;
/**
* Returns the ethereum public key of a given private key.
* @param privateKey A private key must be 256 bits wide
*/
const privateToPublic = function (privateKey) {
(0, helpers_1.assertIsBuffer)(privateKey);
// skip the type flag and use the X, Y points
return Buffer.from(secp256k1_1.secp256k1.ProjectivePoint.fromPrivateKey(privateKey).toRawBytes(false).slice(1));
};
exports.privateToPublic = privateToPublic;
/**
* Returns the ethereum address of a given private key.
* @param privateKey A private key must be 256 bits wide
*/
const privateToAddress = function (privateKey) {
return (0, exports.publicToAddress)((0, exports.privateToPublic)(privateKey));
};
exports.privateToAddress = privateToAddress;
/**
* Converts a public key to the Ethereum format.
*/
const importPublic = function (publicKey) {
(0, helpers_1.assertIsBuffer)(publicKey);
if (publicKey.length !== 64) {
publicKey = Buffer.from(secp256k1_1.secp256k1.ProjectivePoint.fromHex(publicKey).toRawBytes(false).slice(1));
}
return publicKey;
};
exports.importPublic = importPublic;
/**
* Returns the zero address.
*/
const zeroAddress = function () {
const addressLength = 20;
const addr = (0, bytes_1.zeros)(addressLength);
return (0, bytes_1.bufferToHex)(addr);
};
exports.zeroAddress = zeroAddress;
/**
* Checks if a given address is the zero address.
*/
const isZeroAddress = function (hexAddress) {
try {
(0, helpers_1.assertIsString)(hexAddress);
}
catch (e) {
return false;
}
const zeroAddr = (0, exports.zeroAddress)();
return zeroAddr === hexAddress;
};
exports.isZeroAddress = isZeroAddress;
function accountBodyFromSlim(body) {
const [nonce, balance, storageRoot, codeHash] = body;
return [
nonce,
balance,
(0, bytes_1.arrToBufArr)(storageRoot).length === 0 ? constants_1.KECCAK256_RLP : storageRoot,
(0, bytes_1.arrToBufArr)(codeHash).length === 0 ? constants_1.KECCAK256_NULL : codeHash,
];
}
exports.accountBodyFromSlim = accountBodyFromSlim;
const emptyUint8Arr = new Uint8Array(0);
function accountBodyToSlim(body) {
const [nonce, balance, storageRoot, codeHash] = body;
return [
nonce,
balance,
(0, bytes_1.arrToBufArr)(storageRoot).equals(constants_1.KECCAK256_RLP) ? emptyUint8Arr : storageRoot,
(0, bytes_1.arrToBufArr)(codeHash).equals(constants_1.KECCAK256_NULL) ? emptyUint8Arr : codeHash,
];
}
exports.accountBodyToSlim = accountBodyToSlim;
/**
* Converts a slim account (per snap protocol spec) to the RLP encoded version of the account
* @param body Array of 4 Buffer-like items to represent the account
* @returns RLP encoded version of the account
*/
function accountBodyToRLP(body, couldBeSlim = true) {
const accountBody = couldBeSlim ? accountBodyFromSlim(body) : body;
return (0, bytes_1.arrToBufArr)(rlp_1.RLP.encode(accountBody));
}
exports.accountBodyToRLP = accountBodyToRLP;
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