/** * This implements the Ethereum Kernel * Kernels must implement two methods `codeHandler` and `callHandler` (and `linkHandler` for sharding) * The Kernel Contract handles the following * - Interprocess communications * - Intializing the VM and exposes ROM to it (codeHandler) * - Expose namespace which VM instance exists and Intializes the Environment (callHandler) * - Provides some built in contract (runTx, runBlock) * - Provides resource sharing and limiting via gas * * All State should be stored in the Environment. * */ // The Kernel Exposes this Interface to VM instances it makes const Interface = require('./interface.js') // The Kernel Stores all of its state in the Environment. The Interface is used // to by the VM to retrive infromation from the Environment. const Environment = require('./environment.js') const DebugInterface = require('./debugInterface.js') const Address = require('./deps/address.js') const U256 = require('./deps/u256.js') const Utils = require('./deps/utils.js') const Transaction = require('./deps/transaction.js') const Precompile = require('./precompile.js') const identityContract = new Address('0x0000000000000000000000000000000000000004') const meteringContract = new Address('0x000000000000000000000000000000000000000A') const transcompilerContract = new Address('0x000000000000000000000000000000000000000B') module.exports = class Kernel { // runs some code in the VM constructor (environment = new Environment()) { this.environment = environment this.environment.addAccount(identityContract, {}) this.environment.addAccount(meteringContract, {}) this.environment.addAccount(transcompilerContract, {}) } // handles running code. // NOTE: it assumes that wasm will raise an exception if something went wrong, // otherwise execution succeeded codeHandler (code, ethInterface = new Interface(new Environment())) { const debugInterface = new DebugInterface(ethInterface.environment) const module = WebAssembly.Module(code) const imports = { 'ethereum': ethInterface.exportTable, 'debug': debugInterface.exportTable, // export this for Rust // FIXME: remove once Rust has proper imports, see https://github.com/ethereum/evm2.0-design/issues/15 'spectest': ethInterface.exportTable, // export this for Binaryen // FIXME: remove once C has proper imports, see https://github.com/ethereum/evm2.0-design/issues/16 'env': ethInterface.exportTable } // add shims imports.ethereum.useGas = ethInterface.shims.exports.useGas imports.ethereum.getGasLeft = ethInterface.shims.exports.getGasLeft imports.ethereum.call = ethInterface.shims.exports.call const instance = WebAssembly.Instance(module, imports) ethInterface.setModule(instance) debugInterface.setModule(instance) if (instance.exports.main) { instance.exports.main() } return instance } // loads code from the merkle trie and delegates the message // Detects if code is EVM or WASM // Detects if the code injection is needed // Detects if transcompilation is needed callHandler (call) { // FIXME: this is here until these two contracts are compiled to WASM // The two special contracts (precompiles now, but will be real ones later) if (call.to.equals(meteringContract)) { return Precompile.meteringInjector(call) } else if (call.to.equals(transcompilerContract)) { return Precompile.transcompiler(call) } else if (call.to.equals(identityContract)) { return Precompile.identity(call) } let account = this.environment.state.get(call.to.toString()) if (!account) { throw new Error('Account not found: ' + call.to.toString()) } let code = Uint8Array.from(account.get('code')) if (code.length === 0) { throw new Error('Contract not found') } if (!Utils.isWASMCode(code)) { // throw new Error('Not an eWASM contract') // Transcompile code // FIXME: decide if these are the right values here: from: 0, gasLimit: 0, value: 0 code = this.callHandler({ from: Address.zero(), to: transcompilerContract, gasLimit: 0, value: new U256(0), data: code }).returnValue if (code[0] === 0) { code = code.slice(1) } else { throw new Error('Transcompilation failed: ' + Buffer.from(code).slice(1).toString()) } } // creats a new Kernel const environment = new Environment() environment.parent = this // copy the transaction details environment.code = code environment.address = call.to // FIXME: make distinction between origin and caller environment.origin = call.from environment.caller = call.from environment.callData = call.data environment.callValue = call.value environment.gasLeft = call.gasLimit environment.callHandler = this.callHandler.bind(this) environment.createHandler = this.createHandler.bind(this) const kernel = new Kernel(environment) kernel.codeHandler(code, new Interface(environment)) // self destructed if (environment.selfDestruct) { const balance = this.state.get(call.to.toString()).get('balance') const beneficiary = this.state.get(environment.selfDestructAddress) beneficiary.set('balance', beneficiary.get('balance').add(balance)) this.state.delete(call.to.toString()) } // generate new stateroot // this.environment.state.set(address, { stateRoot: stateRoot }) return { executionOutcome: 1, // success gasLeft: new U256(environment.gasLeft), gasRefund: new U256(environment.gasRefund), returnValue: environment.returnValue, selfDestruct: environment.selfDestruct, selfDestructAddress: environment.selfDestructAddress, logs: environment.logs } } createHandler (create) { let code = create.data // Inject metering if (Utils.isWASMCode(code)) { // FIXME: decide if these are the right values here: from: 0, gasLimit: 0, value: 0 code = this.callHandler({ from: Address.zero(), to: meteringContract, gasLimit: 0, value: new U256(0), data: code }).returnValue if (code[0] === 0) { code = code.slice(1) } else { throw new Error('Metering injection failed: ' + Buffer.from(code).slice(1).toString()) } } let address = Utils.newAccountAddress(create.from, code) this.environment.addAccount(address.toString(), { balance: create.value, code: code }) // Run code and take return value as contract code // FIXME: decide if these are the right values here: value: 0, data: '' code = this.callHandler({ from: create.from, to: address, gasLimit: create.gasLimit, value: new U256(0), data: new Uint8Array() }).returnValue // FIXME: special handling for selfdestruct this.environment.state.get(address.toString()).set('code', code) return { executionOutcome: 1, // success gasLeft: new U256(this.environment.gasLeft), gasRefund: new U256(this.environment.gasRefund), accountCreated: address, logs: this.environment.logs } } // run tx; the tx message handler runTx (tx, environment = new Environment()) { this.environment = environment if (Buffer.isBuffer(tx) || typeof tx === 'string') { tx = new Transaction(tx) if (!tx.valid) { throw new Error('Invalid transaction signature') } } // look up sender let fromAccount = this.environment.state.get(tx.from.toString()) if (!fromAccount) { throw new Error('Sender account not found: ' + tx.from.toString()) } if (fromAccount.get('nonce').gt(tx.nonce)) { throw new Error(`Invalid nonce: ${fromAccount.get('nonce')} > ${tx.nonce}`) } fromAccount.set('nonce', fromAccount.get('nonce').add(new U256(1))) let isCreation = false // Special case: contract deployment if (tx.to.isZero() && (tx.data.length !== 0)) { console.log('This is a contract deployment transaction') isCreation = true } // This cost will not be refunded let txCost = 21000 + (isCreation ? 32000 : 0) tx.data.forEach((item) => { if (item === 0) { txCost += 4 } else { txCost += 68 } }) if (tx.gasLimit.lt(new U256(txCost))) { throw new Error(`Minimum transaction gas limit not met: ${txCost}`) } if (fromAccount.get('balance').lt(tx.gasLimit.mul(tx.gasPrice))) { throw new Error(`Insufficient account balance: ${fromAccount.get('balance').toString()} < ${tx.gasLimit.mul(tx.gasPrice).toString()}`) } // deduct gasLimit * gasPrice from sender fromAccount.set('balance', fromAccount.get('balance').sub(tx.gasLimit.mul(tx.gasPrice))) const handler = isCreation ? this.createHandler.bind(this) : this.callHandler.bind(this) let ret = handler({ to: tx.to, from: tx.from, gasLimit: tx.gasLimit - txCost, value: tx.value, data: tx.data }) // refund unused gas if (ret.executionOutcome === 1) { fromAccount.set('balance', fromAccount.get('balance').add(tx.gasPrice.mul(ret.gasLeft.add(ret.gasRefund)))) } // save new state? return { executionOutcome: ret.executionOutcome, accountCreated: isCreation ? ret.accountCreated : undefined, returnValue: isCreation ? undefined : ret.returnValue, gasLeft: ret.gasLeft, logs: ret.logs } } // run block; the block message handler runBlock (block, environment = new Environment()) { // verify block then run each tx block.tx.forEach((tx) => { this.runTx(tx, environment) }) } // run blockchain // runBlockchain () {} }