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@nomicfoundation/trie

v5.0.0-rc.1

Published

This is an implementation of the modified merkle patricia tree as specified in Ethereum's yellow paper.

Downloads

92

Readme

@ethereumjs/trie

NPM Package GitHub Issues Actions Status Code Coverage Discord

This is an implementation of the Modified Merkle Patricia Trie as specified in the Ethereum Yellow Paper:

The modified Merkle Patricia tree (trie) provides a persistent data structure to map between arbitrary-length binary data (byte arrays). It is defined in terms of a mutable data structure to map between 256-bit binary fragments and arbitrary-length binary data. The core of the trie, and its sole requirement in terms of the protocol specification, is to provide a single 32-byte value that identifies a given set of key-value pairs.

Installation

To obtain the latest version, simply require the project using npm:

npm install @ethereumjs/trie

Upgrading

If you currently use this package in your project and plan to upgrade, please review our upgrade guide first. It will ensure you take all the necessary steps and streamline the upgrade process.

Usage

This class implements the basic Modified Merkle Patricia Trie in the Trie base class, which you can use with the useKeyHashing option set to true to create a trie which stores values under the keccak256 hash of its keys (this is the Trie flavor which is used in Ethereum production systems).

Note: Up to v4 of the Trie library the secure trie was implemented as a separate SecureTrie class, see the upgrade guide for more infos.

An additional CheckpointTrie implementation adds checkpointing functionality to Trie through the methods checkpoint, commit and revert.

It is best to select the variant that is most appropriate for your unique use case.

Initialization and Basic Usage

import { Trie, LevelDB } from '@ethereumjs/trie'
import { Level } from 'level'

const trie = new Trie({ db: new LevelDB(new Level('MY_TRIE_DB_LOCATION')) })

async function test() {
  await trie.put(Buffer.from('test'), Buffer.from('one'))
  const value = await trie.get(Buffer.from('test'))
  console.log(value.toString()) // 'one'
}

test()

You can also review our examples for database implementations. The level.js example is the default implementation while lmdb.js is an alternative implementation that uses the popular LMDB as its underlying database.

If no db option is provided, an in-memory database powered by Map will fulfill this role.

Database

By default the only supported database is LevelDB via the level module.

The 5.0.0 release introduced the DB interface to allow for the decoupling of the database layer from the previously tightly-coupled LevelDB integration. The DB interface defines the methods get, put, del, batch and copy that a concrete implementation of the DB interface will need to implement. The default implementation of the DB interface is now an in-memory storage based on the native Map and functions identically to pre-5.0.0 releases.

The base trie implementation (Trie) as well as all subclass implementations (CheckpointTrie and SecureTrie) accept any database implementation that adheres to the DB interface as the db option. It is possible to use alternative implementations like LevelDB if you wish to.

Node Deletion

By default, the deletion of trie nodes from the underlying database does not occur in order to avoid corrupting older trie states (as of v4.2.0). Should you only wish to work with the latest state of a trie, you can switch to a delete behavior (for example, if you wish to save disk space) by using the deleteFromDB constructor option (see related release notes in the changelog for further details).

Persistence

You can enable persistence by setting the useRootPersistence option to true when constructing a trie through the Trie.create function. As such, this value is preserved when creating copies of the trie and is incapable of being modified once a trie is instantiated.

import { Trie, LevelDB } from '@ethereumjs/trie'
import { Level } from 'level'

const trie = await Trie.create({
  db: new LevelDB(new Level('MY_TRIE_DB_LOCATION')),
  useRootPersistence: true,
})

The Trie.create function is asynchronous and will read the root from your database before returning the trie instance. If you don't have the need for automatic restoration of the root then you can use the new Trie constructor with the same options and get persistence without the automatic restoration.

LevelDB

If you wish to continue to rely on LevelDB for all operations then you should create a file with the following implementation from our recipes in your project. It is then possible to use the LevelDB implementation as follows:

import { Trie } from '@ethereumjs/trie'
import { Level } from 'level'

import { LevelDB } from './your-level-implementation'

const trie = new Trie({ db: new LevelDB(new Level('MY_TRIE_DB_LOCATION')) })

Proofs

Merkle Proofs

The createProof and verifyProof functions allow you to verify that a certain value does or does not exist within a Merkle Patricia Tree with a given root.

Proof-of-Inclusion

The following code demonstrates how to construct and subsequently verify a proof that confirms the existence of the key test (which corresponds with the value one) within the given trie. This is also known as inclusion, hence the name 'Proof-of-Inclusion.'

const trie = new Trie()

async function test() {
  await trie.put(Buffer.from('test'), Buffer.from('one'))
  const proof = await trie.createProof(Buffer.from('test'))
  const value = await trie.verifyProof(trie.root(), Buffer.from('test'), proof)
  console.log(value.toString()) // 'one'
}

test()

Proof-of-Exclusion

The following code demonstrates how to construct and subsequently verify a proof that confirms that the key test3 does not exist within the given trie. This is also known as exclusion, hence the name 'Proof-of-Exclusion.'

const trie = new Trie()

async function test() {
  await trie.put(Buffer.from('test'), Buffer.from('one'))
  await trie.put(Buffer.from('test2'), Buffer.from('two'))
  const proof = await trie.createProof(Buffer.from('test3'))
  const value = await trie.verifyProof(trie.root(), Buffer.from('test3'), proof)
  console.log(value.toString()) // null
}

test()

Invalid Proofs

If verifyProof detects an invalid proof, it will throw an error. While contrived, the below example illustrates the resulting error condition in the event a prover tampers with the data in a merkle proof.

const trie = new Trie()

async function test() {
  await trie.put(Buffer.from('test'), Buffer.from('one'))
  await trie.put(Buffer.from('test2'), Buffer.from('two'))
  const proof = await trie.createProof(Buffer.from('test2'))
  proof[1].reverse()
  try {
    const value = await trie.verifyProof(trie.root(), Buffer.from('test2'), proof)
    console.log(value.toString()) // results in error
  } catch (err) {
    console.log(err) // Missing node in DB
  }
}

test()

Range Proofs

You may use the Trie.verifyRangeProof() function to confirm if the given leaf nodes and edge proof possess the capacity to prove that the given trie leaves' range matches the specific root (which is useful for snap sync, for instance).

Read Stream on Geth DB

import { Level } from 'level'
import { LevelDB, Trie } from '@ethereumjs/trie'

// Set stateRoot to block #222
const stateRoot = '0xd7f8974fb5ac78d9ac099b9ad5018bedc2ce0a72dad1827a1709da30580f0544'
// Convert the state root to a Buffer (strip the 0x prefix)
const stateRootBuffer = Buffer.from(stateRoot.slice(2), 'hex')
// Initialize trie
const trie = new Trie({
  db: new LevelDB(new Level('YOUR_PATH_TO_THE_GETH_CHAIN_DB')),
  root: stateRootBuffer,
  useKeyHashing: true,
})

trie
  .createReadStream()
  .on('data', console.log)
  .on('end', () => console.log('End.'))

Read Account State Including Storage From Geth DB

import { Level } from 'level'
import { Trie, LevelDB } from '@ethereumjs/trie'
import { Account, bufferToHex } from '@ethereumjs/util'
import { RLP } from '@ethereumjs/rlp'

const stateRoot = 'STATE_ROOT_OF_A_BLOCK'

const trie = new Trie({
  db: new LevelDB(new Level('YOUR_PATH_TO_THE_GETH_CHAINDATA_FOLDER')),
  root: stateRoot
  useKeyHashing: true,
})

const address = 'AN_ETHEREUM_ACCOUNT_ADDRESS'

async function test() {
  const data = await trie.get(address)
  const acc = Account.fromAccountData(data)

  console.log('-------State-------')
  console.log(`nonce: ${acc.nonce}`)
  console.log(`balance in wei: ${acc.balance}`)
  console.log(`storageRoot: ${bufferToHex(acc.stateRoot)}`)
  console.log(`codeHash: ${bufferToHex(acc.codeHash)}`)

  const storageTrie = trie.copy()
  storageTrie.root(acc.stateRoot)

  console.log('------Storage------')
  const stream = storageTrie.createReadStream()
  stream
    .on('data', (data) => {
      console.log(`key: ${bufferToHex(data.key)}`)
      console.log(`Value: ${bufferToHex(Buffer.from(RLP.decode(data.value)))}`)
    })
    .on('end', () => console.log('Finished reading storage.'))
}

test()

You can find additional examples complete with detailed explanations here.

API

Docs

Generated TypeDoc API Documentation

BigInt Support

With the 5.0.0 release, BigInt takes the place of BN.js.

BigInt is a primitive that is used to represent and manipulate primitive bigint values that the number primitive is incapable of representing as a result of their magnitude. ES2020 saw the introduction of this particular feature. Note that this version update resulted in the altering of number-related API signatures and that the minimal build target is now set to ES2020.

Testing

You may run tests for browsers and node.js using:

npm run test

You may run tests for browsers using:

npm run test:browser

Note that this requires an installation of Mozilla Firefox, otherwise the tests will fail.

You may run tests for node.js using:

npm run test:node

Benchmarking

You will find two simple benchmarks in the benchmarks folder:

  • random.ts runs random PUT operations on the tree, and
  • checkpointing.ts runs checkpoints and commits between PUT operations

A third benchmark using mainnet data to simulate real load is also being considered.

You may run benchmarks using:

npm run benchmarks

To run a profiler on the random.ts benchmark and generate a flamegraph with 0x, you may use:

npm run profiling

0x processes the stacks and generates a profile folder (<pid>.0x) containing flamegraph.html.

References

EthereumJS

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.

License

MPL-2.0