@ethereumjs/tx
Version:
Implementation of the various Ethereum Transaction Types
458 lines • 21.1 kB
JavaScript
"use strict";
Object.defineProperty(exports, "__esModule", { value: true });
exports.Blob4844Tx = exports.NetworkWrapperType = void 0;
const util_1 = require("@ethereumjs/util");
const EIP1559 = require("../capabilities/eip1559.js");
const EIP2718 = require("../capabilities/eip2718.js");
const EIP2930 = require("../capabilities/eip2930.js");
const Legacy = require("../capabilities/legacy.js");
const types_ts_1 = require("../types.js");
const access_ts_1 = require("../util/access.js");
const internal_ts_1 = require("../util/internal.js");
const constructors_ts_1 = require("./constructors.js");
exports.NetworkWrapperType = {
EIP4844: 0,
EIP7594: 1,
};
/**
* Typed transaction with a new gas fee market mechanism for transactions that include "blobs" of data
*
* - TransactionType: 3
* - EIP: [EIP-4844](https://eips.ethereum.org/EIPS/eip-4844)
*
* This tx type has two "modes": the plain canonical format only contains `blobVersionedHashes`.
* If blobs are passed in the tx automatically switches to "Network Wrapper" format and the
* `networkWrapperVersion` will be set or validated.
*/
class Blob4844Tx {
/**
* This constructor takes the values, validates them, assigns them and freezes the object.
*
* It is not recommended to use this constructor directly. Instead use
* the static constructors or factory methods to assist in creating a Transaction object from
* varying data types.
*/
constructor(txData, opts = {}) {
this.type = types_ts_1.TransactionType.BlobEIP4844; // 4844 tx type
this.cache = {};
/**
* List of tx type defining EIPs,
* e.g. 1559 (fee market) and 2930 (access lists)
* for FeeMarket1559Tx objects
*/
this.activeCapabilities = [];
// Check networkWrapperVersion early, before sharedConstructor, to ensure proper error ordering
// This validation needs to happen before EIP-7825 gas limit checks
const common = (0, internal_ts_1.getCommon)(opts.common);
const networkWrapperVersion = txData.networkWrapperVersion !== undefined
? (0, util_1.bytesToInt)((0, util_1.toBytes)(txData.networkWrapperVersion))
: undefined;
if (networkWrapperVersion !== undefined) {
switch (networkWrapperVersion) {
case exports.NetworkWrapperType.EIP7594:
if (!common.isActivatedEIP(7594)) {
throw (0, util_1.EthereumJSErrorWithoutCode)('EIP-7594 not enabled on Common for EIP-7594 network wrapper version');
}
break;
case exports.NetworkWrapperType.EIP4844:
if (common.isActivatedEIP(7594)) {
throw (0, util_1.EthereumJSErrorWithoutCode)('EIP-7594 is active on Common for EIP-4844 network wrapper version');
}
break;
default:
throw (0, util_1.EthereumJSErrorWithoutCode)(`Invalid networkWrapperVersion=${networkWrapperVersion}`);
}
}
(0, internal_ts_1.sharedConstructor)(this, { ...txData, type: types_ts_1.TransactionType.BlobEIP4844 }, opts);
const { chainId, accessList: rawAccessList, maxFeePerGas, maxPriorityFeePerGas, maxFeePerBlobGas, } = txData;
const accessList = rawAccessList ?? [];
if (chainId !== undefined && (0, util_1.bytesToBigInt)((0, util_1.toBytes)(chainId)) !== this.common.chainId()) {
throw (0, util_1.EthereumJSErrorWithoutCode)(`Common chain ID ${this.common.chainId} not matching the derived chain ID ${chainId}`);
}
this.chainId = this.common.chainId();
if (!this.common.isActivatedEIP(1559)) {
throw (0, util_1.EthereumJSErrorWithoutCode)('EIP-1559 not enabled on Common');
}
if (!this.common.isActivatedEIP(4844)) {
throw (0, util_1.EthereumJSErrorWithoutCode)('EIP-4844 not enabled on Common');
}
this.activeCapabilities = this.activeCapabilities.concat([1559, 2718, 2930]);
// Populate the access list fields
this.accessList = (0, types_ts_1.isAccessList)(accessList) ? (0, access_ts_1.accessListJSONToBytes)(accessList) : accessList;
// Verify the access list format.
EIP2930.verifyAccessList(this);
this.maxFeePerGas = (0, util_1.bytesToBigInt)((0, util_1.toBytes)(maxFeePerGas));
this.maxPriorityFeePerGas = (0, util_1.bytesToBigInt)((0, util_1.toBytes)(maxPriorityFeePerGas));
(0, internal_ts_1.valueOverflowCheck)({
maxFeePerGas: this.maxFeePerGas,
maxPriorityFeePerGas: this.maxPriorityFeePerGas,
});
(0, internal_ts_1.validateNotArray)(txData);
if (this.gasLimit * this.maxFeePerGas > util_1.MAX_INTEGER) {
const msg = Legacy.errorMsg(this, 'gasLimit * maxFeePerGas cannot exceed MAX_INTEGER (2^256-1)');
throw (0, util_1.EthereumJSErrorWithoutCode)(msg);
}
if (this.maxFeePerGas < this.maxPriorityFeePerGas) {
const msg = Legacy.errorMsg(this, 'maxFeePerGas cannot be less than maxPriorityFeePerGas (The total must be the larger of the two)');
throw (0, util_1.EthereumJSErrorWithoutCode)(msg);
}
this.maxFeePerBlobGas = (0, util_1.bytesToBigInt)((0, util_1.toBytes)((maxFeePerBlobGas ?? '') === '' ? '0x' : maxFeePerBlobGas));
this.blobVersionedHashes = (txData.blobVersionedHashes ?? []).map((vh) => (0, util_1.toType)(vh, util_1.TypeOutput.PrefixedHexString));
EIP2718.validateYParity(this);
Legacy.validateHighS(this);
for (const hash of this.blobVersionedHashes) {
if (hash.length !== 66) {
// 66 is the length of a 32 byte hash as a PrefixedHexString
const msg = Legacy.errorMsg(this, 'versioned hash is invalid length');
throw (0, util_1.EthereumJSErrorWithoutCode)(msg);
}
if (BigInt(parseInt(hash.slice(2, 4))) !== this.common.param('blobCommitmentVersionKzg')) {
// We check the first "byte" of the hash (starts at position 2 since hash is a PrefixedHexString)
const msg = Legacy.errorMsg(this, 'versioned hash does not start with KZG commitment version');
throw (0, util_1.EthereumJSErrorWithoutCode)(msg);
}
}
// "Old" limit (superseded by EIP-7594 starting with Osaka)
const limitBlobsPerTx = this.common.param('maxBlobGasPerBlock') / this.common.param('blobGasPerBlob');
if (this.blobVersionedHashes.length > limitBlobsPerTx) {
const msg = Legacy.errorMsg(this, `tx causes total blob gas of ${Number(this.common.param('blobGasPerBlob')) * this.blobVersionedHashes.length} to exceed maximum blob gas per block of ${this.common.param('maxBlobGasPerBlock')}`);
throw (0, util_1.EthereumJSErrorWithoutCode)(msg);
}
// EIP-7594 PeerDAS: Limit of 6 blobs per transaction
if (this.common.isActivatedEIP(7594)) {
const maxBlobsPerTx = this.common.param('maxBlobsPerTx');
if (this.blobVersionedHashes.length > maxBlobsPerTx) {
const msg = Legacy.errorMsg(this, `${this.blobVersionedHashes.length} blobs exceeds max ${maxBlobsPerTx} blobs per tx (EIP-7594)`);
throw (0, util_1.EthereumJSErrorWithoutCode)(msg);
}
}
if (this.blobVersionedHashes.length === 0) {
const msg = Legacy.errorMsg(this, `tx should contain at least one blob`);
throw (0, util_1.EthereumJSErrorWithoutCode)(msg);
}
if (this.to === undefined) {
const msg = Legacy.errorMsg(this, `tx should have a "to" field and cannot be used to create contracts`);
throw (0, util_1.EthereumJSErrorWithoutCode)(msg);
}
// networkWrapperVersion was already validated earlier in the constructor
this.networkWrapperVersion =
txData.networkWrapperVersion !== undefined
? (0, util_1.bytesToInt)((0, util_1.toBytes)(txData.networkWrapperVersion))
: undefined;
this.blobs = txData.blobs?.map((blob) => (0, util_1.toType)(blob, util_1.TypeOutput.PrefixedHexString));
if (this.networkWrapperVersion === undefined && this.blobs !== undefined) {
if (this.common.isActivatedEIP(7594)) {
this.networkWrapperVersion = 1;
}
else {
this.networkWrapperVersion = 0;
}
}
if (this.networkWrapperVersion !== undefined && this.blobs === undefined) {
const msg = Legacy.errorMsg(this, 'tx is not allowed to be in network wrapper format if no blob list is provided');
throw (0, util_1.EthereumJSErrorWithoutCode)(msg);
}
this.kzgCommitments = txData.kzgCommitments?.map((commitment) => (0, util_1.toType)(commitment, util_1.TypeOutput.PrefixedHexString));
this.kzgProofs = txData.kzgProofs?.map((proof) => (0, util_1.toType)(proof, util_1.TypeOutput.PrefixedHexString));
if (this.blobs !== undefined) {
if (this.kzgCommitments === undefined) {
const msg = Legacy.errorMsg(this, 'kzgCommitments are mandatory if blobs are provided');
throw (0, util_1.EthereumJSErrorWithoutCode)(msg);
}
if (this.kzgProofs === undefined) {
const msg = Legacy.errorMsg(this, 'kzgProofs are mandatory if blobs are provided');
throw (0, util_1.EthereumJSErrorWithoutCode)(msg);
}
}
const freeze = opts?.freeze ?? true;
if (freeze) {
Object.freeze(this);
}
}
/**
* Checks if a tx type defining capability is active
* on a tx, for example the EIP-1559 fee market mechanism
* or the EIP-2930 access list feature.
*
* Note that this is different from the tx type itself,
* so EIP-2930 access lists can very well be active
* on an EIP-1559 tx for example.
*
* This method can be useful for feature checks if the
* tx type is unknown (e.g. when instantiated with
* the tx factory).
*
* See `Capabilities` in the `types` module for a reference
* on all supported capabilities.
*/
supports(capability) {
return this.activeCapabilities.includes(capability);
}
/**
* Returns the minimum of calculated priority fee (from maxFeePerGas and baseFee) and maxPriorityFeePerGas
* @param baseFee Base fee retrieved from block
*/
getEffectivePriorityFee(baseFee) {
return EIP1559.getEffectivePriorityFee(this, baseFee);
}
/**
* The amount of gas paid for the data in this tx
*/
getDataGas() {
return EIP2930.getDataGas(this);
}
/**
* The up front amount that an account must have for this transaction to be valid
* @param baseFee The base fee of the block (will be set to 0 if not provided)
*/
getUpfrontCost(baseFee = util_1.BIGINT_0) {
return EIP1559.getUpfrontCost(this, baseFee);
}
/**
* Blob4844Tx cannot create contracts
*/
toCreationAddress() {
throw (0, util_1.EthereumJSErrorWithoutCode)('Blob4844Tx cannot create contracts');
}
/**
* The minimum gas limit which the tx to have to be valid.
* This covers costs as the standard fee (21000 gas), the data fee (paid for each calldata byte),
* the optional creation fee (if the transaction creates a contract), and if relevant the gas
* to be paid for access lists (EIP-2930) and authority lists (EIP-7702).
*/
getIntrinsicGas() {
return Legacy.getIntrinsicGas(this);
}
/**
* Returns a Uint8Array Array of the raw Bytes of the EIP-4844 transaction, in order.
*
* Format: [chain_id, nonce, max_priority_fee_per_gas, max_fee_per_gas, gas_limit, to, value, data,
* access_list, max_fee_per_data_gas, blob_versioned_hashes, y_parity, r, s]`.
*
* Use {@link Blob4844Tx.serialize} to add a transaction to a block
* with {@link createBlockFromBytesArray}.
*
* For an unsigned tx this method uses the empty Bytes values for the
* signature parameters `v`, `r` and `s` for encoding. For an EIP-155 compliant
* representation for external signing use {@link Blob4844Tx.getMessageToSign}.
*/
raw() {
return [
(0, util_1.bigIntToUnpaddedBytes)(this.chainId),
(0, util_1.bigIntToUnpaddedBytes)(this.nonce),
(0, util_1.bigIntToUnpaddedBytes)(this.maxPriorityFeePerGas),
(0, util_1.bigIntToUnpaddedBytes)(this.maxFeePerGas),
(0, util_1.bigIntToUnpaddedBytes)(this.gasLimit),
this.to !== undefined ? this.to.bytes : new Uint8Array(0),
(0, util_1.bigIntToUnpaddedBytes)(this.value),
this.data,
this.accessList,
(0, util_1.bigIntToUnpaddedBytes)(this.maxFeePerBlobGas),
this.blobVersionedHashes.map((hash) => (0, util_1.hexToBytes)(hash)),
this.v !== undefined ? (0, util_1.bigIntToUnpaddedBytes)(this.v) : new Uint8Array(0),
this.r !== undefined ? (0, util_1.bigIntToUnpaddedBytes)(this.r) : new Uint8Array(0),
this.s !== undefined ? (0, util_1.bigIntToUnpaddedBytes)(this.s) : new Uint8Array(0),
];
}
/**
* Returns the serialized encoding of the EIP-4844 transaction.
*
* Format: `0x03 || rlp([chainId, nonce, maxPriorityFeePerGas, maxFeePerGas, gasLimit, to, value, data,
* access_list, max_fee_per_data_gas, blob_versioned_hashes, y_parity, r, s])`.
*
* Note that in contrast to the legacy tx serialization format this is not
* valid RLP any more due to the raw tx type preceding and concatenated to
* the RLP encoding of the values.
*/
serialize() {
return EIP2718.serialize(this);
}
/**
* @returns the serialized form of a blob transaction in the network wrapper format
* This format is used for gossipping mempool transactions over devp2p or when
* submitting a transaction via RPC.
*/
serializeNetworkWrapper() {
if (this.networkWrapperVersion === undefined ||
this.blobs === undefined ||
this.kzgCommitments === undefined ||
this.kzgProofs === undefined) {
throw (0, util_1.EthereumJSErrorWithoutCode)('cannot serialize network wrapper without networkWrapperVersion, blobs, KZG commitments and KZG proofs provided');
}
const networkSerialized = this.networkWrapperVersion === exports.NetworkWrapperType.EIP4844
? EIP2718.serialize(this, [this.raw(), this.blobs, this.kzgCommitments, this.kzgProofs])
: EIP2718.serialize(this, [
this.raw(),
(0, util_1.intToUnpaddedBytes)(this.networkWrapperVersion),
this.blobs,
this.kzgCommitments,
this.kzgProofs,
]);
return networkSerialized;
}
/**
* Returns the raw serialized unsigned tx, which can be used
* to sign the transaction (e.g. for sending to a hardware wallet).
*
* Note: in contrast to the legacy tx the raw message format is already
* serialized and doesn't need to be RLP encoded any more.
*
* ```javascript
* const serializedMessage = tx.getMessageToSign() // use this for the HW wallet input
* ```
* @returns Serialized unsigned transaction payload
*/
getMessageToSign() {
return EIP2718.serialize(this, this.raw().slice(0, 11));
}
/**
* Returns the hashed serialized unsigned tx, which can be used
* to sign the transaction (e.g. for sending to a hardware wallet).
*
* Note: in contrast to the legacy tx the raw message format is already
* serialized and doesn't need to be RLP encoded any more.
* @returns Keccak hash of the unsigned transaction payload
*/
getHashedMessageToSign() {
return EIP2718.getHashedMessageToSign(this);
}
/**
* Computes a sha3-256 hash of the serialized tx.
*
* This method can only be used for signed txs (it throws otherwise).
* Use {@link Blob4844Tx.getMessageToSign} to get a tx hash for the purpose of signing.
* @returns Hash of the serialized signed transaction
*/
hash() {
return Legacy.hash(this);
}
/**
* Returns the hashed unsigned transaction that should be used for signature verification.
* @returns Hash of the unsigned transaction payload
*/
getMessageToVerifySignature() {
return this.getHashedMessageToSign();
}
/**
* Returns the public key of the sender
* @returns Sender public key
*/
getSenderPublicKey() {
return Legacy.getSenderPublicKey(this);
}
/**
* Produces a JSON representation compliant with the execution API.
* @returns JSON encoding of the transaction
*/
toJSON() {
const accessListJSON = (0, access_ts_1.accessListBytesToJSON)(this.accessList);
const baseJSON = (0, internal_ts_1.getBaseJSON)(this);
return {
...baseJSON,
chainId: (0, util_1.bigIntToHex)(this.chainId),
maxPriorityFeePerGas: (0, util_1.bigIntToHex)(this.maxPriorityFeePerGas),
maxFeePerGas: (0, util_1.bigIntToHex)(this.maxFeePerGas),
accessList: accessListJSON,
maxFeePerBlobGas: (0, util_1.bigIntToHex)(this.maxFeePerBlobGas),
blobVersionedHashes: this.blobVersionedHashes,
};
}
/**
* Adds signature values (and optional network wrapper fields) and returns a new transaction.
* @param v - Recovery parameter
* @param r - Signature `r` value
* @param s - Signature `s` value
* @returns New `Blob4844Tx` instance containing the signature
*/
addSignature(v, r, s) {
r = (0, util_1.toBytes)(r);
s = (0, util_1.toBytes)(s);
const opts = { ...this.txOptions, common: this.common };
return (0, constructors_ts_1.createBlob4844Tx)({
chainId: this.chainId,
nonce: this.nonce,
maxPriorityFeePerGas: this.maxPriorityFeePerGas,
maxFeePerGas: this.maxFeePerGas,
gasLimit: this.gasLimit,
to: this.to,
value: this.value,
data: this.data,
accessList: this.accessList,
v,
r: (0, util_1.bytesToBigInt)(r),
s: (0, util_1.bytesToBigInt)(s),
maxFeePerBlobGas: this.maxFeePerBlobGas,
networkWrapperVersion: this.networkWrapperVersion,
blobVersionedHashes: this.blobVersionedHashes,
blobs: this.blobs,
kzgCommitments: this.kzgCommitments,
kzgProofs: this.kzgProofs,
}, opts);
}
/**
* Returns validation errors for this transaction, if any.
* @returns Array of validation error messages
*/
getValidationErrors() {
return Legacy.getValidationErrors(this);
}
/**
* @returns true if the transaction has no validation errors
*/
isValid() {
return Legacy.isValid(this);
}
/**
* Verifies whether the attached signature is valid.
* @returns true if signature verification succeeds
*/
verifySignature() {
return Legacy.verifySignature(this);
}
/**
* Returns the recovered sender address.
* @returns Sender {@link Address}
*/
getSenderAddress() {
return Legacy.getSenderAddress(this);
}
/**
* Signs the transaction with the provided private key and returns the signed instance.
* @param privateKey - 32-byte private key used for signing
* @param extraEntropy - Optional entropy passed to the signing routine
* @returns Newly signed transaction
*/
sign(privateKey, extraEntropy = false) {
return Legacy.sign(this, privateKey, extraEntropy);
}
/**
* Indicates whether the transaction already carries signature values.
* @returns true if signature parts are present
*/
isSigned() {
const { v, r, s } = this;
if (v === undefined || r === undefined || s === undefined) {
return false;
}
else {
return true;
}
}
/**
* Return a compact error string representation of the object
* @returns Human-readable error summary
*/
errorStr() {
let errorStr = Legacy.getSharedErrorPostfix(this);
errorStr += ` maxFeePerGas=${this.maxFeePerGas} maxPriorityFeePerGas=${this.maxPriorityFeePerGas}`;
return errorStr;
}
/**
* @returns the number of blobs included with this transaction
*/
numBlobs() {
return this.blobVersionedHashes.length;
}
}
exports.Blob4844Tx = Blob4844Tx;
//# sourceMappingURL=tx.js.map