Implements schema and functions related to Ethereum's transaction. |
---|
Note: this README
reflects the state of the library from v3.0.0
onwards. See README
from the standalone repository for an introduction on the last preceding release.
To obtain the latest version, simply require the project using npm
:
npm install @ethereumjs/tx
This library supports an experimental version of EIP-4844
blob transactions (see usage instructions below) starting with v4.1.0
.
For blob transactions and other KZG related proof functionality (e.g. for EVM precompiles) KZG has to be manually installed and initialized once in a global scope. The functionality is then available for all KZG usages throughout different libraries (Transaction, Block, EVM).
The following two manual installation steps for a KZG library and the trusted setup are needed.
- Install an additional dependency that supports the
kzg
interface defined in the kzg interface. You can install the default option c-kzg by simply runningnpm install c-kzg
. - Download the trusted setup required for the KZG module. It can be found here within the client package.
Global initialization can then be done like this (using the c-kzg
module for our KZG dependency):
import { initKZG } from '@ethereumjs/util'
// Make the kzg library available globally
import * as kzg from 'c-kzg'
// Initialize the trusted setup
initKZG(kzg, 'path/to/my/trusted_setup.txt')
To instantiate a tx it is not recommended to use the constructor directly. Instead each tx type comes with the following set of static constructor methods which helps on instantiation depending on the input data format:
public static fromTxData(txData: TxData, opts: TxOptions = {})
: instantiate from a data dictionarypublic static fromSerializedTx(serialized: Uint8Array, opts: TxOptions = {})
: instantiate from a serialized txpublic static fromValuesArray(values: Uint8Array[], opts: TxOptions = {})
: instantiate from a values array
See one of the code examples on the tx types below on how to use.
All types of transaction objects are frozen with Object.freeze()
which gives you enhanced security and consistency properties when working with the instantiated object. This behavior can be modified using the freeze
option in the constructor if needed.
The LegacyTransaction
constructor receives a parameter of an @ethereumjs/common
object that lets you specify the chain and hardfork to be used. If there is no Common
provided the chain ID provided as a parameter on typed tx or the chain ID derived from the v
value on signed EIP-155 conforming legacy txs will be taken (introduced in v3.2.1
). In other cases the chain defaults to mainnet
.
Base default HF (determined by Common
): Hardfork.Shanghai
Hardforks adding features and/or tx types:
Hardfork | Introduced | Description |
---|---|---|
spuriousDragon |
v2.0.0 |
EIP-155 replay protection (disable by setting HF pre-spuriousDragon ) |
istanbul |
v2.1.1 |
Support for reduced non-zero call blob gas prices (EIP-2028) |
muirGlacier |
v2.1.2 |
- |
berlin |
v3.1.0 |
EIP-2718 Typed Transactions, Optional Access Lists Tx Type EIP-2930 |
london |
v3.2.0 |
EIP-1559 Transactions |
cancun |
v5.0.0 |
EIP-4844 Transactions |
This library supports the following transaction types (EIP-2718):
BlobEIP4844Transaction
(EIP-4844, proto-danksharding)FeeMarketEIP1559Transaction
(EIP-1559, gas fee market)AccessListEIP2930Transaction
(EIP-2930, optional access lists)BlobEIP4844Transaction
(EIP-4844, blob transactions)LegacyTransaction
, the Ethereum standard tx up toberlin
, now referred to as legacy txs with the introduction of tx types
- Class:
BlobEIP4844Transaction
- Activation:
cancun
- Type:
3
This library supports the blob transaction type introduced with EIP-4844 as being specified in the b9a5a11 EIP version from July 2023 deployed along 4844-devnet-7 (July 2023), see PR #2349 and following.
Note: 4844 support is not yet completely stable and there will still be (4844-)breaking changes along all types of library releases.
Note: This functionality needs a manual KZG library installation and global initialization, see KZG Setup for instructions.
See the following code snipped for an example on how to instantiate (using the c-kzg
module for our KZG dependency).
import { Chain, Common, Hardfork } from '@ethereumjs/common'
import { BlobEIP4844Transaction } from '@ethereumjs/tx'
import { initKZG } from '@ethereumjs/util'
import * as kzg from 'c-kzg'
initKZG(kzg, 'path/to/my/trusted_setup.txt')
const common = new Common({ chain: Chain.Mainnet, hardfork: Hardfork.Shanghai, eips: [4844] })
const txData = {
data: '0x1a8451e600000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000',
gasLimit: '0x02625a00',
maxPriorityFeePerGas: '0x01',
maxFeePerGas: '0xff',
maxFeePerDataGas: '0xfff',
nonce: '0x00',
to: '0xcccccccccccccccccccccccccccccccccccccccc',
value: '0x0186a0',
v: '0x01',
r: '0xafb6e247b1c490e284053c87ab5f6b59e219d51f743f7a4d83e400782bc7e4b9',
s: '0x479a268e0e0acd4de3f1e28e4fac2a6b32a4195e8dfa9d19147abe8807aa6f64',
chainId: '0x01',
accessList: [],
type: '0x05',
versionedHashes: ['0xabc...'], // Test with empty array on a first run
kzgCommitments: ['0xdef...'], // Test with empty array on a first run
blobs: ['0xghi...'], // Test with empty array on a first run
proofs: ['0xabcd...'], //
}
const tx = BlobEIP4844Transaction.fromTxData(txData, { common })
Note that versionedHashes
and kzgCommitments
have a real length of 32 bytes, blobs
have a real length of 4096
bytes and values are trimmed here for brevity.
Alternatively, you can pass a blobsData
property with an array of strings corresponding to a set of blobs and the fromTxData
constructor will derive the corresponding blobs
, versionedHashes
, kzgCommitments
, and kzgProofs
for you.
See the Blob Transaction Tests for examples of usage in instantiating, serializing, and deserializing these transactions.
- Class:
FeeMarketEIP1559Transaction
- Activation:
london
- Type:
2
This is the recommended tx type starting with the activation of the london
HF, see the following code snipped for an example on how to instantiate:
import { Chain, Common, Hardfork } from '@ethereumjs/common'
import { FeeMarketEIP1559Transaction } from '@ethereumjs/tx'
const common = new Common({ chain: Chain.Mainnet, hardfork: Hardfork.London })
const txData = {
data: '0x1a8451e600000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000',
gasLimit: '0x02625a00',
maxPriorityFeePerGas: '0x01',
maxFeePerGas: '0xff',
nonce: '0x00',
to: '0xcccccccccccccccccccccccccccccccccccccccc',
value: '0x0186a0',
v: '0x01',
r: '0xafb6e247b1c490e284053c87ab5f6b59e219d51f743f7a4d83e400782bc7e4b9',
s: '0x479a268e0e0acd4de3f1e28e4fac2a6b32a4195e8dfa9d19147abe8807aa6f64',
chainId: '0x01',
accessList: [],
type: '0x02',
}
const tx = FeeMarketEIP1559Transaction.fromTxData(txData, { common })
- Class:
AccessListEIP2930Transaction
- Activation:
berlin
- Type:
1
This transaction type has been introduced along the berlin
HF. See the following code snipped for an example on how to instantiate:
import { Chain, Common, Hardfork } from '@ethereumjs/common'
import { AccessListEIP2930Transaction } from '@ethereumjs/tx'
const common = new Common({ chain: Chain.Mainnet, hardfork: Hardfork.Berlin })
const txData = {
data: '0x1a8451e600000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000',
gasLimit: '0x02625a00',
gasPrice: '0x01',
nonce: '0x00',
to: '0xcccccccccccccccccccccccccccccccccccccccc',
value: '0x0186a0',
v: '0x01',
r: '0xafb6e247b1c490e284053c87ab5f6b59e219d51f743f7a4d83e400782bc7e4b9',
s: '0x479a268e0e0acd4de3f1e28e4fac2a6b32a4195e8dfa9d19147abe8807aa6f64',
chainId: '0x01',
accessList: [
{
address: '0x0000000000000000000000000000000000000101',
storageKeys: [
'0x0000000000000000000000000000000000000000000000000000000000000000',
'0x00000000000000000000000000000000000000000000000000000000000060a7',
],
},
],
type: '0x01',
}
const tx = AccessListEIP2930Transaction.fromTxData(txData, { common })
For generating access lists from tx data based on a certain network state there is a reportAccessList
option
on the Vm.runTx()
method of the @ethereumjs/vm
TypeScript
VM implementation.
- Class:
LegacyTransaction
- Activation:
chainstart
(with modifications along the road, see HF section below) - Type:
0
(internal)
Legacy transaction are still valid transaction within Ethereum mainnet
but will likely be deprecated at some point.
See this example script or the following code example on how to use.
import { Chain, Common, Hardfork } from '@ethereumjs/common'
import { LegacyTransaction } from '@ethereumjs/tx'
const txParams = {
nonce: '0x00',
gasPrice: '0x09184e72a000',
gasLimit: '0x2710',
to: '0x0000000000000000000000000000000000000000',
value: '0x00',
data: '0x7f7465737432000000000000000000000000000000000000000000000000000000600057',
}
const common = new Common({ chain: Chain.Mainnet, hardfork: Hardfork.Istanbul })
const tx = LegacyTransaction.fromTxData(txParams, { common })
const privateKey = Buffer.from(
'e331b6d69882b4cb4ea581d88e0b604039a3de5967688d3dcffdd2270c0fd109',
'hex'
)
const signedTx = tx.sign(privateKey)
const serializedTx = signedTx.serialize()
If you only know on runtime which tx type will be used within your code or if you want to keep your code transparent to tx types, this library comes with a TransactionFactory
for your convenience which can be used as follows:
import { Chain, Common, Hardfork } from '@ethereumjs/common'
import { TransactionFactory } from '@ethereumjs/tx'
const common = new Common({ chain: Chain.Mainnet, hardfork: Hardfork.Berlin })
const txData = {} // Use data from the different tx type examples
const tx = TransactionFactory.fromTxData(txData, { common })
if (tx.supports(Capability.EIP2930AccessLists)) {
// Do something which only makes sense for txs with support for access lists
}
The correct tx type class for instantiation will then be chosen on runtime based on the data provided as an input.
TransactionFactory
supports the following static constructor methods:
public static fromTxData(txData: TxData | AccessListEIP2930TxData, txOptions: TxOptions = {}): TypedTransaction
public static fromSerializedData(data: Uint8Array, txOptions: TxOptions = {}): TypedTransaction
public static fromBlockBodyData(data: Uint8Array | Uint8Array[], txOptions: TxOptions = {})
public static async fromJsonRpcProvider(provider: string | EthersProvider, txHash: string, txOptions?: TxOptions)
This library has been tested to work with various L2 networks (v3.3.0
+). All predefined supported custom chains introduced with Common
v2.4.0
or higher are supported, the following is a simple example to send a tx to the xDai chain:
import { Common } from '@ethereumjs/common'
import { LegacyTransaction } from '@ethereumjs/tx'
import { hexToBytes } from '@ethereumjs/util'
const from = 'PUBLIC_KEY'
const PRIV_KEY = process.argv[2]
const to = 'DESTINATION_ETHEREUM_ADDRESS'
const common = Common.custom(CustomChain.xDaiChain)
const txData = {
from,
nonce: 0,
gasPrice: 1000000000,
gasLimit: 21000,
to,
value: 1,
}
const tx = LegacyTransaction.fromTxData(txData, { common })
const signedTx = tx.sign(hexToBytes(PRIV_KEY))
The following L2 networks have been tested to work with @ethereumjs/tx
, see usage examples as well as some notes on peculiarities in the issues linked below:
L2 Network | Common name | Issue |
---|---|---|
Arbitrum Rinkeby Testnet | CustomChain.ArbitrumRinkebyTestnet |
#1290 |
Polygon Mainnet | CustomChain.PolygonMainnet |
#1289 |
Polygon Mumbai Testnet | CustomChain.PolygonMumbai |
#1289 |
xDai Chain | Common.xDaiChain |
#1323 |
Optimistic Kovan | Common.OptimisticKovan |
#1554 |
Optimistic Ethereum | Common.OptimisticEthereum |
#1554 |
Note: For Optimistic Kovan and Optimistic Ethereum, the London hardfork has not been implemented so transactions submitted with a baseFee
will revert.
The London hardfork is targeted to implement on Optimism in Q1.22.
For a non-predefined custom chain it is also possible to just provide a chain ID as well as other parameters to Common
:
const common = Common.custom({ chainId: 1234 })
With the breaking release round in Summer 2023 we have added hybrid ESM/CJS builds for all our libraries (see section below) and have eliminated many of the caveats which had previously prevented a frictionless browser usage.
It is now easily possible to run a browser build of one of the EthereumJS libraries within a modern browser using the provided ESM build. For a setup example see ./examples/browser.html.
To sign a tx with a hardware or external wallet use tx.getMessageToSign()
to return an EIP-155 compliant unsigned tx.
A legacy transaction will return a Buffer list of the values, and a Typed Transaction (EIP-2718) will return the serialized output.
Here is an example of signing txs with @ledgerhq/hw-app-eth
as of v6.5.0
:
import { Chain, Common } from '@ethereumjs/common'
import { LegacyTransaction, FeeMarketEIP1559Transaction } from '@ethereumjs/tx'
import { bytesToHex } from '@ethereumjs/util'
import { RLP } from '@ethereumjs/rlp'
import Eth from '@ledgerhq/hw-app-eth'
const eth = new Eth(transport)
const common = new Common({ chain: Chain.Sepolia })
let txData: any = { value: 1 }
let tx: Transaction | FeeMarketEIP1559Transaction
let unsignedTx: Uint8Array[] | Uint8Array
let signedTx: typeof tx
const bip32Path = "44'/60'/0'/0/0"
const run = async () => {
// Signing a legacy tx
tx = LegacyTransaction.fromTxData(txData, { common })
unsignedTx = tx.getMessageToSign()
unsignedTx = RLP.encode(unsignedTx) // ledger signTransaction API expects it to be serialized
let { v, r, s } = await eth.signTransaction(bip32Path, unsignedTx)
txData = { ...txData, v, r, s }
signedTx = LegacyTransaction.fromTxData(txData, { common })
let from = bytesToHex(signedTx.getSenderAddress())
console.log(`signedTx: ${bytesToHex(signedTx.serialize())}\nfrom: ${from}`)
// Signing a 1559 tx
txData = { value: 1 }
tx = FeeMarketEIP1559Transaction.fromTxData(txData, { common })
unsignedTx = tx.getMessageToSign()
;({ v, r, s } = await eth.signTransaction(bip32Path, unsignedTx)) // this syntax is: object destructuring - assignment without declaration
txData = { ...txData, v, r, s }
signedTx = FeeMarketEIP1559Transaction.fromTxData(txData, { common })
from = bytesToHex(signedTx.getSenderAddress())
console.log(`signedTx: ${bytesToHex(signedTx.serialize())}\nfrom: ${from}`)
}
run()
Creating a fake transaction for use in e.g. VM.runTx()
is simple, just overwrite getSenderAddress()
with a custom Address
like so:
import { Address } from '@ethereumjs/util'
import { Transaction } from '@ethereumjs/tx'
_getFakeTransaction(txParams: TxParams): Transaction {
const from = Address.fromString(txParams.from)
delete txParams.from
const opts = { common: this._common, freeze: false }
const tx = LegacyTransaction.fromTxData(txParams, opts)
// override getSenderAddress
tx.getSenderAddress = () => { return from }
return tx
}
Generated TypeDoc API Documentation
With the breaking releases from Summer 2023 we have started to ship our libraries with both CommonJS (cjs
folder) and ESM builds (esm
folder), see package.json
for the detailed setup.
If you use an ES6-style import
in your code files from the ESM build will be used:
import { EthereumJSClass } from '@ethereumjs/[PACKAGE_NAME]'
If you use Node.js specific require
, the CJS build will be used:
const { EthereumJSClass } = require('@ethereumjs/[PACKAGE_NAME]')
Using ESM will give you additional advantages over CJS beyond browser usage like static code analysis / Tree Shaking which CJS can not provide.
With the breaking releases from Summer 2023 we have removed all Node.js specific Buffer
usages from our libraries and replace these with Uint8Array representations, which are available both in Node.js and the browser (Buffer
is a subclass of Uint8Array
).
We have converted existing Buffer conversion methods to Uint8Array conversion methods in the @ethereumjs/util bytes
module, see the respective README section for guidance.
Starting with v4 the usage of BN.js for big numbers has been removed from the library and replaced with the usage of the native JS BigInt data type (introduced in ES2020
).
Please note that number-related API signatures have changed along with this version update and the minimal build target has been updated to ES2020
.
See our organizational documentation for an introduction to EthereumJS
as well as information on current standards and best practices. If you want to join for work or carry out improvements on the libraries, please review our contribution guidelines first.