$ npm install @ethereumjs/blockchain
A module to store and interact with blocks. |
---|
Note: this README
reflects the state of the library from v5.0.0
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/blockchain
Note: If you want to work with EIP-4844
related functionality, you will have additional manual installation steps for the KZG setup, see related section below.
The Blockchain
package represents an Ethereum-compatible blockchain storing a sequential chain of @ethereumjs/block blocks and holding information about the current canonical head block as well as the context the chain is operating in (e.g. the hardfork rules the current head block adheres to).
New blocks can be added to the blockchain. Validation ensures that the block format adheres to the given chain rules (with the Blockchain.validateBlock()
function) and consensus rules (Blockchain.consensus.validateConsensus()
).
The library also supports reorg scenarios e.g. by allowing to add a new block with Blockchain.putBlock()
which follows a different canonical path to the head than given by the current canonical head block.
The following is an example to instantiate a simple Blockchain object, put blocks into the blockchain and then iterate through the blocks added:
// ./examples/simple.ts
import { Block } from '@ethereumjs/block'
import { Blockchain } from '@ethereumjs/blockchain'
import { Common, Hardfork } from '@ethereumjs/common'
import { bytesToHex } from '@ethereumjs/util'
const main = async () => {
const common = new Common({ chain: 'mainnet', hardfork: Hardfork.London })
// Use the safe static constructor which awaits the init method
const blockchain = await Blockchain.create({
validateBlocks: false, // Skipping validation so we can make a simple chain without having to provide complete blocks
validateConsensus: false,
common,
})
// We use minimal data to provide a sequence of blocks (increasing number, difficulty, and then setting parent hash to previous block)
const block = Block.fromBlockData(
{
header: {
number: 1n,
parentHash: blockchain.genesisBlock.hash(),
difficulty: blockchain.genesisBlock.header.difficulty + 1n,
},
},
{ common, setHardfork: true }
)
const block2 = Block.fromBlockData(
{
header: {
number: 2n,
parentHash: block.header.hash(),
difficulty: block.header.difficulty + 1n,
},
},
{ common, setHardfork: true }
)
// See @ethereumjs/block for more details on how to create a block
await blockchain.putBlock(block)
await blockchain.putBlock(block2)
// We iterate over the blocks in the chain to the current head (block 2)
await blockchain.iterator('i', (block) => {
const blockNumber = block.header.number.toString()
const blockHash = bytesToHex(block.hash())
console.log(`Block ${blockNumber}: ${blockHash}`)
})
// Block 1: 0xa1a061528d74ba81f560e1ebc4f29d6b58171fc13b72b876cdffe6e43b01bdc5
// Block 2: 0x5583be91cf9fb14f5dbeb03ad56e8cef19d1728f267c35a25ba5a355a528f602
}
main()
With the v7 release the Blockchain library database has gotten an additional abstraction layer which allows to switch the backend to whatever is fitting the best for a use case, see PR #2669 and PR #2673. The database just needs to conform to the new DB interface provided in the @ethereumjs/util
package (since this is used in other places as well).
By default the blockchain package now uses a MapDB non-persistent data storage which is also generically provided in the @ethereumjs/util
package.
If you need a persistent data store for your use case you can consider using the wrapper we have written within our client library.
Starting with v6 there is a dedicated consensus class for each type of supported consensus, Ethash
, Clique
and Casper
(PoS, this one is rather the do-nothing part of Casper
and letting the respective consensus/beacon client do the hard work! 🙂). Each consensus class adheres to a common interface Consensus
implementing the following five methods in a consensus-specific way:
genesisInit(genesisBlock: Block): Promise<void>
setup(): Promise<void>
validateConsensus(block: Block): Promise<void>
validateDifficulty(header: BlockHeader): Promise<void>
newBlock(block: Block, commonAncestor?: BlockHeader, ancientHeaders?: BlockHeader[]): Promise<void>
Also part of V6, you can also create a custom consensus class implementing the above interface and pass it into the Blockchain
constructor using the consensus
option at instantiation. See this test script for a complete example of how write and use a custom consensus implementation.
Note, if you construct a blockchain with a custom consensus implementation, transition checks for switching from PoW to PoS are disabled so defining a merge hardfork will have no impact on the consensus mechanism defined for the chain.
Genesis state was huge and had previously been bundled with the Blockchain
package with the burden going over to the VM, since Blockchain
is a dependency.
Starting with the v7 release genesis state has been removed from blockchain
and moved into its own auxiliary package @ethereumjs/genesis, from which it can be included if needed (for most - especially VM - use cases it is not necessary), see PR #2844.
This goes along with some changes in Blockchain and VM API:
genesisStateRoot
beside genesisBlock
and genesisState
for an alternative condensed way to provide the genesis state root directlygenesisState(): GenesisState
method has been replaced by the async getGenesisStateRoot(chainId: Chain): Promise<Uint8Array>
methodactivateGenesisState?: boolean
constructor option has been replaced with a genesisState?: GenesisState
optionFor the v6 release responsibility for setting up a custom genesis state moved from the Common library to the Blockchain
package, see PR #1924 for some work context.
A genesis state can be set along Blockchain
creation by passing in a custom genesisBlock
and genesisState
. For mainnet
and the official test networks like sepolia
or goerli
genesis is already provided with the block data coming from @ethereumjs/common
. The genesis state is being integrated in the Blockchain
library (see genesisStates
folder).
For many custom chains we might come across a genesis configuration, which can be used to build both chain config as well the genesis state (and hence the genesis block as well to start off with)
// ./examples/gethGenesis.ts
import { Blockchain } from '@ethereumjs/blockchain'
import { Common, parseGethGenesis } from '@ethereumjs/common'
import { bytesToHex, parseGethGenesisState } from '@ethereumjs/util'
import gethGenesisJson from './genesisData/post-merge.json'
const main = async () => {
// Load geth genesis json file into lets say `gethGenesisJson`
const common = Common.fromGethGenesis(gethGenesisJson, { chain: 'customChain' })
const genesisState = parseGethGenesisState(gethGenesisJson)
const blockchain = await Blockchain.create({
genesisState,
common,
})
const genesisBlockHash = blockchain.genesisBlock.hash()
common.setForkHashes(genesisBlockHash)
console.log(
`Genesis hash from geth genesis parameters - ${bytesToHex(blockchain.genesisBlock.hash())}`
)
}
main()
The genesis block from the initialized Blockchain
can be retrieved via the Blockchain.genesisBlock
getter. For creating a genesis block from the params in @ethereumjs/common
, the createGenesisBlock(stateRoot: Buffer): Block
method can be used.
This library supports the handling of EIP-1559
blocks and transactions starting with the v5.3.0
release.
This library supports the blob transaction type introduced with EIP-4844.
The blockchain library now allows for blob transactions to be validated and included in a chain where EIP-4844 activated either by hardfork or standalone EIP.
Note: Working with blob transactions needs a manual KZG library installation and global initialization, see KZG Setup for instructions.
This libary supports blocks including the following EIP-7685 requests:
v7.3.0
+)v7.3.0
+)v7.3.0
+)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.
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 v6 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
.
The Blockchain
class has a public property events
which contains an EventEmitter
. Following events are emitted on which you can react within your code:
Event | Description |
---|---|
deletedCanonicalBlocks |
Emitted when blocks are reorged and deleted |
For debugging blockchain control flows the debug library is used and can be activated on the CL with DEBUG=[Logger Selection] node [Your Script to Run].js
.
The following initial logger is currently available:
Logger | Description |
---|---|
blockchain:clique |
Clique operations like updating the vote and/or signer list |
The following is an example for a logger run:
Run with the clique logger:
DEBUG=ethjs,blockchain:clique tsx test.ts
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.
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