@celo/ethereumjs-vm
v6.4.1-unofficial.0
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An Ethereum VM implementation
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@ethereumjs/vm
| Execution Context for the Ethereum EVM Implementation. | | ------------------------------------------------------ |
This package is a CELO
compatible fork of @ethereumjs/vm and provides an Ethereum mainnet
compatible execution context for the
@ethereumjs/evm
EVM implementation.
Note that up till v5
this package also was the bundled package for the EVM implementation itself.
Installation
To obtain the latest version, simply require the project using npm
:
npm install @ethereumjs/vm
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.
Usage
Running a Transaction
import { Address } from '@ethereumjs/util'
import { Chain, Common, Hardfork } from '@ethereumjs/common'
import { Transaction } from '@ethereumjs/tx'
import { VM } from '@ethereumjs/vm'
const common = new Common({ chain: Chain.Mainnet, hardfork: Hardfork.Berlin })
const vm = await VM.create({ common })
const tx = Transaction.fromTxData({
gasLimit: BigInt(21000),
value: BigInt(1),
to: Address.zero(),
v: BigInt(37),
r: BigInt('62886504200765677832366398998081608852310526822767264927793100349258111544447'),
s: BigInt('21948396863567062449199529794141973192314514851405455194940751428901681436138'),
})
await vm.runTx({ tx, skipBalance: true })
Note that there is an additional API method VM.runBlock()
which allows to run the whole block and execute all included transactions along.
Building a Block
The VM package can also be used to construct a new valid block by executing and then integrating txs one-by-one.
The following non-complete example gives some illustration on how to use the Block Builder API:
import { Chain, Common, Hardfork } from '@ethereumjs/common'
import { Transaction } from '@ethereumjs/tx'
import { VM } from '@ethereumjs/vm'
const common = new Common({ chain: Chain.Mainnet })
const vm = await VM.create({ common })
const blockBuilder = await vm.buildBlock({
parentBlock, // the parent @ethereumjs/block Block
headerData, // header values for the new block
blockOpts: { calcDifficultyFromHeader: parentBlock.header, freeze: false },
})
const tx = Transaction.fromTxData()
await blockBuilder.addTransaction(tx)
// Add more transactions
const block = await blockBuilder.build()
Example
This projects contain the following examples:
- ./examples/run-blockchain: Loads tests data, including accounts and blocks, and runs all of them in the VM.
- ./examples/run-solidity-contract: Compiles a Solidity contract, and calls constant and non-constant functions.
All of the examples have their own README.md
explaining how to run them.
API
Docs
For documentation on VM
instantiation, exposed API and emitted events
see generated API docs.
BigInt Support
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
.
Architecture
VM/EVM Relation
Starting with the VM
v6 version the inner Ethereum Virtual Machine core previously included in this library has been extracted to an own package @ethereumjs/evm.
It is still possible to access all EVM
functionality through the evm
property of the initialized vm
object, e.g.:
vm.evm.runCode() // or
vm.evm.events.on('step', function (data) {
console.log(`Opcode: ${data.opcode.name}\tStack: ${data.stack}`)
})
Note that it's now also possible to pass in an own or customized EVM
instance by using the optional evm
constructor option.
Execution Environment (EEI) and State
This package provides a concrete implementation of the @ethereumjs/evm EEI interface to instantiate a VM/EVM combination with an Ethereum mainnet
compatible execution context.
With VM
v6 the previously included StateManager
has been extracted to its own package @ethereumjs/statemanager. The StateManager
package provides a unified state interface and it is now also possible to provide a modified or custom StateManager
to the VM via the optional stateManager
constructor option.
Setup
Chain Support
Starting with v5.1.0
the VM supports running both Ethash/PoW
and Clique/PoA
blocks and transactions. Clique support has been added along the work on PR #1032 and follow-up PRs and (block) validation checks and the switch of the execution context now happens correctly.
Ethash/PoW Chains
@ethereumjs/blockchain
validates the PoW algorithm with @ethereumjs/ethash
and validates blocks' difficulty to match their canonical difficulty.
Clique/PoA Chains
The following is a simple example for a block run on Goerli
:
import { VM } from '@ethereumjs/vm'
import { Chain, Common } from '@ethereumjs/common'
const common = new Common({ chain: Chain.Goerli })
const hardforkByBlockNumber = true
const vm = new VM({ common, hardforkByBlockNumber })
const serialized = Buffer.from('f901f7a06bfee7294bf4457...', 'hex')
const block = Block.fromRLPSerializedBlock(serialized, { hardforkByBlockNumber })
const result = await vm.runBlock(block)
Hardfork Support
For hardfork support see the Hardfork Support section from the underlying @ethereumjs/evm
instance.
An explicit HF in the VM
- which is then passed on to the inner EVM
- can be set with:
import { Chain, Common, Hardfork } from '@ethereumjs/common'
import { VM } from '@ethereumjs/vm'
const common = new Common({ chain: Chain.Mainnet, hardfork: Hardfork.Berlin })
const vm = new VM({ common })
Custom genesis state support
Genesis state code logic has been reworked substantially along the v6 breaking releases and a lot of the genesis state code moved from both the @ethereumjs/common
and @ethereumjs/block
libraries to the @ethereumjs/blockchain
library, see PR #1916 for an overview on the broad set of changes.
For initializing a custom genesis state you can now use the genesisState
constructor option in the Blockchain
library in a similar way this had been done in the Common
library before.
If you want to create a new instance of the VM and add your own genesis state, you can do it by passing a Blockchain
instance with custom genesis state set with the genesisState
constructor option and passing the flag activateGenesisState
in VMOpts
.
import { Common } from '@ethereumjs/common'
import { VM } from '@ethereumjs/vm'
import myCustomChain1 from '[PATH_TO_MY_CHAINS]/myCustomChain1.json'
import chain1GenesisState from '[PATH_TO_GENESIS_STATES]/chain1GenesisState.json'
const common = new Common({
// TODO: complete example
})
const blockchain = await Blockchain.create({
// TODO: complete example
})
const vm = await VM.create({ common, activateGenesisState: true })
Genesis state can be configured to contain both EOAs as well as (system) contracts with initial storage values set.
EIP Support
It is possible to individually activate EIP support in the VM by instantiate the Common
instance passed
with the respective EIPs, e.g.:
import { Chain, Common } from '@ethereumjs/common'
import { VM } from '@ethereumjs/vm'
const common = new Common({ chain: Chain.Mainnet, eips: [2537] })
const vm = new VM({ common })
For a list with supported EIPs see the @ethereumjs/evm documentation.
EIP-4844 Shard Blob Transactions Support (experimental)
This library supports an experimental version of the blob transaction type introduced with EIP-4844 as being specified in the 01d3209 EIP version from February 8, 2023 and deployed along eip4844-devnet-4
(January 2023) starting with v1.3.0
.
Initialization
To run VM/EVM related EIP-4844 functionality you have to active the EIP in the associated @ethereumjs/common
library:
import { Common, Chain, Hardfork } from '@ethereumjs/common'
const common = new Common({ chain: Chain.Mainnet, hardfork: Hardfork.Shanghai, eips: [4844] })
EIP-4844 comes with a new opcode DATAHASH
and adds a new point evaluation precompile at address 0x14
in the underlying @ethereumjs/evm
package.
Note: Usage of the point evaluation precompile needs a manual KZG library installation and global initialization, see KZG Setup for instructions.
Tracing Events
Our TypeScript
VM is implemented as an AsyncEventEmitter and events are submitted along major execution steps which you can listen to.
You can subscribe to the following events:
beforeBlock
: Emits aBlock
right before running it.afterBlock
: EmitsAfterBlockEvent
right after running a block.beforeTx
: Emits aTransaction
right before running it.afterTx
: Emits aAfterTxEvent
right after running a transaction.
Please note that there are additional EVM-specific events in the @ethereumjs/evm package.
Asynchronous event handlers
You can perform asynchronous operations from within an event handler and prevent the VM to keep running until they finish.
In order to do that, your event handler has to accept two arguments. The first one will be the event object, and the second one a function. The VM won't continue until you call this function.
If an exception is passed to that function, or thrown from within the handler or a function called by it, the exception will bubble into the VM and interrupt it, possibly corrupting its state. It's strongly recommended not to do that.
Synchronous event handlers
If you want to perform synchronous operations, you don't need to receive a function as the handler's second argument, nor call it.
Note that if your event handler receives multiple arguments, the second one will be the continuation function, and it must be called.
If an exception is thrown from within the handler or a function called by it, the exception will bubble into the VM and interrupt it, possibly corrupting its state. It's strongly recommended not to throw from within event handlers.
Understanding the VM
If you want to understand your VM runs we have added a hierarchically structured list of debug loggers for your convenience which can be activated in arbitrary combinations. We also use these loggers internally for development and testing. These loggers use the debug library and can be activated on the CL with DEBUG=ethjs,[Logger Selection] node [Your Script to Run].js
and produce output like the following:
The following loggers are currently available:
| Logger | Description |
| ----------- | ------------------------------------------------------------------ |
| vm:block
| Block operations (run txs, generating receipts, block rewards,...) |
| vm:tx
| Transaction operations (account updates, checkpointing,...) |
| vm:tx:gas
| Transaction gas logger |
| vm:state
| StateManager logger |
Note that there are additional EVM-specific loggers in the @ethereumjs/evm package.
Here are some examples for useful logger combinations.
Run one specific logger:
DEBUG=ethjs,vm:tx ts-node test.ts
Run all loggers currently available:
DEBUG=ethjs,vm:*,vm:*:* ts-node test.ts
Run only the gas loggers:
DEBUG=ethjs,vm:*:gas ts-node test.ts
Excluding the state logger:
DEBUG=ethjs,vm:*,vm:*:*,-vm:state ts-node test.ts
Run some specific loggers including a logger specifically logging the SSTORE
executions from the VM (this is from the screenshot above):
DEBUG=ethjs,vm:tx,vm:evm,vm:ops:sstore,vm:*:gas ts-node test.ts
Internal Structure
The VM processes state changes at many levels.
- runBlockchain
- for every block, runBlock
- runBlock
- for every tx, runTx
- pay miner and uncles
- runTx
- check sender balance
- check sender nonce
- runCall
- transfer gas charges
TODO: this section likely needs an update.
Development
Developer documentation - currently mainly with information on testing and debugging - can be found here.
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.