@gxchain2-ethereumjs/vm
v5.5.14
Published
An Ethereum VM implementation
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Readme
@ethereumjs/vm
| TypeScript implementation of the Ethereum VM. | | --- |
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 preceeding release.
INSTALL
npm install @ethereumjs/vm
USAGE
import { BN } from 'ethereumjs-util'
import Common, { Chain, Hardfork } from '@ethereumjs/common'
import VM from '@ethereumjs/vm'
const common = new Common({ chain: Chain.Mainnet, hardfork: Hardfork.Berlin })
const vm = new VM({ common })
const STOP = '00'
const ADD = '01'
const PUSH1 = '60'
// Note that numbers added are hex values, so '20' would be '32' as decimal e.g.
const code = [PUSH1, '03', PUSH1, '05', ADD, STOP]
vm.on('step', function (data) {
console.log(`Opcode: ${data.opcode.name}\tStack: ${data.stack}`)
})
vm.runCode({
code: Buffer.from(code.join(''), 'hex'),
gasLimit: new BN(0xffff),
})
.then((results) => {
console.log(`Returned: ${results.returnValue.toString('hex')}`)
console.log(`gasUsed : ${results.gasUsed.toString()}`)
})
.catch(console.error)
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-code-browser: Show how to use this library in a browser.
- ./examples/run-solidity-contract: Compiles a Solidity contract, and calls constant and non-constant functions.
- ./examples/run-transactions-complete: Runs a contract-deployment transaction and then calls one of its functions.
- ./examples/decode-opcodes: Decodes a binary EVM program into its opcodes.
All of the examples have their own README.md
explaining how to run them.
API
VM
For documentation on VM
instantiation, exposed API and emitted events
see generated API docs.
StateManager
Documentation on the StateManager
can be found here. If you want to provide your own StateManager
you can implement the dedicated interface to ensure that your implementation conforms with the current API.
Note: along the EIP-2929
(Gas cost increases for state access opcodes) implementation released in v5.2.0
a new EIP2929StateManager
interface has been introduced inheriting from the base StateManager
interface. The methods introduced there will be merged into the base state manager on the next breaking release.
BROWSER
To build the VM for standalone use in the browser, see: Running the VM in a browser.
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
For the VM to work correctly in a Clique/PoA
context you need to use the library with the following library versions or higher:
- @ethereumjs/block ->
v3.1.0
- @ethereumjs/blockchain ->
v5.1.0
- @ethereumjs/common" ->
v2.1.0
The following is a simple example for a block run on Goerli
:
import VM from '@ethereumjs/vm'
import Common, { Chain } 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
Starting with the v5
release series all hardforks from Frontier
(chainstart
) up to the latest active mainnet hardfork are supported.
The VM currently supports the following hardfork rules:
chainstart
(a.k.a. Frontier) (v5.0.0
+)homestead
(v5.0.0
+)tangerineWhistle
(v5.0.0
+)spuriousDragon
(v5.0.0
+)byzantium
constantinople
petersburg
istanbul
(v4.1.1
+)muirGlacier
(onlymainnet
andropsten
) (v4.1.3
+)berlin
(v5.2.0
+)london
(v5.4.0
+)
Default: istanbul
(taken from Common.DEFAULT_HARDFORK
)
A specific hardfork VM ruleset can be activated by passing in the hardfork
along the Common
instance:
import Common, { Chain, Hardfork } from '@ethereumjs/common'
import VM from '@ethereumjs/vm'
const common = new Common({ chain: Chain.Mainnet, hardfork: Hardfork.Berlin })
const vm = new VM({ common })
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 Common, { Chain } from '@ethereumjs/common'
import VM from '@ethereumjs/vm'
const common = new Common({ chain: Chain.Mainnet, eips: [2537] })
const vm = new VM({ common })
Currently supported EIPs:
- EIP-1559 - Fee Market (
london
EIP) - EIP-2315: Simple subroutines
- EIP-2537: BLS precompiles
- EIP-2565: ModExp gas cost (
berlin
EIP) - EIP-2718: Typed transactions (
berlin
EIP) - EIP-2929: Gas cost increases for state access opcodes (
berlin
EIP) - EIP-2930: Optional Access Lists Typed Transactions (
berlin
EIP) - EIP-3198 - BASEFEE opcode (
london
EIP) - EIP-3529 - Reduction in refunds (
london
EIP) - EIP-3541 - Reject new contracts starting with the 0xEF byte (
london
EIP)
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.beforeMessage
: Emits aMessage
right after running it.afterMessage
: Emits anEVMResult
right after running a message.step
: Emits anInterpreterStep
right before running an EVM step.newContract
: Emits aNewContractEvent
right before creating a contract. This event contains the deployment code, not the deployed code, as the creation message may not return such a code.
An example for the step
event can be found in the initial usage example in this README
.
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 withing 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 withing 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=[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:evm
| EVM control flow, CALL or CREATE message execution |
| vm:evm:gas
| EVM gas logger |
| vm:eei:gas
| EEI gas logger |
| vm:state
| StateManager logger |
| vm:ops
| Opcode traces |
| vm:ops:[Lower-case opcode name]
| Traces on a specific opcode |
Here are some examples for useful logger combinations.
Run one specific logger:
DEBUG=vm:tx ts-node test.ts
Run all loggers currently available:
DEBUG=vm:*,vm:*:* ts-node test.ts
Run only the gas loggers:
DEBUG=vm:*:gas ts-node test.ts
Excluding the state logger:
DEBUG=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=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
- runCall
- checkpoint state
- transfer value
- load code
- runCode
- materialize created contracts
- revert or commit checkpoint
- runCode
- iterate over code
- run op codes
- track gas usage
- OpFns
- run individual op code
- modify stack
- modify memory
- calculate fee
The opFns for CREATE
, CALL
, and CALLCODE
call back up to runCall
.
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 do improvements on the libraries have a look at our contribution guidelines.