# Nimbus # Copyright (c) 2018 Status Research & Development GmbH # Licensed under either of # * Apache License, version 2.0, ([LICENSE-APACHE](LICENSE-APACHE) or http://www.apache.org/licenses/LICENSE-2.0) # * MIT license ([LICENSE-MIT](LICENSE-MIT) or http://opensource.org/licenses/MIT) # at your option. This file may not be copied, modified, or distributed except according to those terms. import chronicles, strformat, strutils, sequtils, macros, terminal, math, tables, options, eth/[common, keys], ../constants, ../errors, ../validation, ../vm_state, ../vm_types, ./interpreter/[opcode_values, gas_meter, gas_costs, vm_forks], ./code_stream, ./memory, ./message, ./stack, ../db/[state_db, db_chain], ../utils/header, byteutils, ranges, precompiles, transaction_tracer logScope: topics = "vm computation" proc newBaseComputation*(vmState: BaseVMState, blockNumber: UInt256, message: Message, forkOverride=none(Fork)): BaseComputation = new result result.vmState = vmState result.msg = message result.memory = Memory() result.stack = newStack() result.gasMeter.init(message.gas) result.children = @[] result.accountsToDelete = initTable[EthAddress, EthAddress]() result.code = newCodeStream(message.code) # result.rawOutput = "0x" result.gasCosts = if forkOverride.isSome: forkOverride.get.forkToSchedule else: blockNumber.toFork.forkToSchedule result.forkOverride = forkOverride proc isOriginComputation*(c: BaseComputation): bool = # Is this computation the computation initiated by a transaction c.msg.isOrigin template isSuccess*(c: BaseComputation): bool = c.error.isNil template isError*(c: BaseComputation): bool = not c.isSuccess func shouldBurnGas*(c: BaseComputation): bool = c.isError and c.error.burnsGas func shouldEraseReturnData*(c: BaseComputation): bool = c.isError and c.error.erasesReturnData func bytesToHex(x: openarray[byte]): string {.inline.} = ## TODO: use seq[byte] for raw data and delete this proc foldl(x, a & b.int.toHex(2).toLowerAscii, "0x") func output*(c: BaseComputation): seq[byte] = if c.shouldEraseReturnData: @[] else: c.rawOutput func `output=`*(c: var BaseComputation, value: openarray[byte]) = c.rawOutput = @value proc outputHex*(c: BaseComputation): string = if c.shouldEraseReturnData: return "0x" c.rawOutput.bytesToHex proc prepareChildMessage*( c: var BaseComputation, gas: GasInt, to: EthAddress, value: UInt256, data: seq[byte], code: seq[byte], options: MessageOptions = newMessageOptions()): Message = var childOptions = options childOptions.depth = c.msg.depth + 1 result = newMessage( gas, c.msg.gasPrice, to, c.msg.origin, value, data, code, childOptions) type ComputationSnapshot* = object snapshot: Snapshot computation: BaseComputation proc snapshot*(computation: BaseComputation): ComputationSnapshot = result.snapshot = computation.vmState.snapshot() result.computation = computation proc revert*(snapshot: var ComputationSnapshot, burnsGas: bool = false) = snapshot.snapshot.revert() snapshot.computation.error = Error(info: getCurrentExceptionMsg(), burnsGas: burnsGas) proc commit*(snapshot: var ComputationSnapshot) {.inline.} = snapshot.snapshot.commit() proc dispose*(snapshot: var ComputationSnapshot) {.inline.} = snapshot.snapshot.dispose() proc applyMessageAux(computation: var BaseComputation, opCode: static[Op]) = if computation.msg.depth > STACK_DEPTH_LIMIT: raise newException(StackDepthError, "Stack depth limit reached") let nilai = computation.vmState.readOnlyStateDb().getBalance(computation.msg.sender) if computation.msg.value != 0: let senderBalance = computation.vmState.readOnlyStateDb(). getBalance(computation.msg.sender) var newBalance = senderBalance if senderBalance < computation.msg.value: raise newException(InsufficientFunds, &"Insufficient funds: {senderBalance} < {computation.msg.value}" ) let insufficientFunds = senderBalance < computation.msg.value stackTooDeep = computation.msg.depth >= MaxCallDepth if insufficientFunds or stackTooDeep: computation.returnData = @[] var errMessage: string if insufficientFunds: errMessage = &"Insufficient Funds: have: {$senderBalance} need: {$computation.msg.value}" elif stackTooDeep: errMessage = "Stack Limit Reached" else: raise newException(VMError, "Invariant: Unreachable code path") debug "Computation failure", msg = errMessage computation.gasMeter.returnGas(computation.msg.gas) push: 0 return newBalance = senderBalance - computation.msg.value computation.vmState.mutateStateDb: db.setBalance(computation.msg.sender, newBalance) db.addBalance(computation.msg.storageAddress, computation.msg.value) trace "Value transferred", source = computation.msg.sender, dest = computation.msg.storageAddress, value = computation.msg.value, oldSenderBalance = senderBalance, newSenderBalance = newBalance, gasPrice = computation.msg.gasPrice, gas = computation.msg.gas trace "Apply message", value = computation.msg.value, senderBalance = newBalance, sender = computation.msg.sender.toHex, address = computation.msg.storageAddress.toHex, gasPrice = computation.msg.gasPrice, gas = computation.msg.gas else: # even though the value is zero, the account # should be exist. computation.vmState.mutateStateDb: db.addBalance(computation.msg.storageAddress, computation.msg.value) proc applyMessage(computation: var BaseComputation, opCode: static[Op]) = var snapshot = computation.snapshot() defer: snapshot.dispose() when opCode in {Call, Create}: try: computation.applyMessageAux(opCode) except VMError: snapshot.revert() debug "applyMessageAux failed", msg = computation.error.info return if computation.gasMeter.gasRemaining < 0: snapshot.commit() return try: # Run code # We cannot use the normal dispatching function `executeOpcodes` # within `interpreter_dispatch.nim` due to a cyclic dependency. if not computation.execPrecompiles: computation.opcodeExec(computation) snapshot.commit() except VMError: snapshot.revert(true) debug "VMError applyMessage failed", msg = computation.error.info, depth = computation.msg.depth except EVMError: snapshot.revert() # TODO: true or false? debug "EVMError applyMessage failed", msg = computation.error.info, depth = computation.msg.depth proc applyCreateMessage(fork: Fork, computation: var BaseComputation, opCode: static[Op]) = computation.applyMessage(opCode) if computation.isError: return let contractCode = computation.output if contractCode.len == 0: return var snapshot = computation.snapshot() defer: snapshot.dispose() if fork >= FkSpurious and contractCode.len >= EIP170_CODE_SIZE_LIMIT: raise newException(OutOfGas, &"Contract code size exceeds EIP170 limit of {EIP170_CODE_SIZE_LIMIT}. Got code of size: {contractCode.len}") try: # tricky gasCost: 1,0,0 -> createCost. 0,0,x -> depositCost let gasCost = computation.gasCosts[Create].m_handler(0, 0, contractCode.len) computation.gasMeter.consumeGas(gasCost, reason = "Write contract code for CREATE") let storageAddr = computation.msg.storageAddress trace "SETTING CODE", address = storageAddr.toHex, length = len(contract_code), hash = contractCode.rlpHash computation.vmState.mutateStateDb: db.setCode(storageAddr, contractCode.toRange) snapshot.commit() except OutOfGas: debug "applyCreateMessage failed: ", msg = getCurrentExceptionMsg(), depth = computation.msg.depth if fork < FkHomestead: computation.output = @[] else: # Different from Frontier: # Reverts state on gas failure while writing contract code. snapshot.revert() proc generateChildComputation*(fork: Fork, computation: var BaseComputation, childMsg: Message, opCode: static[Op]): BaseComputation = var childComp = newBaseComputation( computation.vmState, computation.vmState.blockNumber, childMsg, some(fork)) # Copy the fork op code executor proc (assumes child computation is in the same fork) childComp.opCodeExec = computation.opCodeExec if childMsg.isCreate: fork.applyCreateMessage(childComp, opCode) else: applyMessage(childComp, opCode) return childComp proc addChildComputation(fork: Fork, computation: var BaseComputation, child: BaseComputation) = if child.isError: if child.msg.isCreate: computation.returnData = child.output elif child.shouldBurnGas: computation.returnData = @[] else: computation.returnData = child.output else: if child.msg.isCreate: computation.returnData = @[] else: computation.returnData = child.output for k, v in child.accountsToDelete: computation.accountsToDelete[k] = v computation.children.add(child) proc getFork*(computation: BaseComputation): Fork = result = if computation.forkOverride.isSome: computation.forkOverride.get else: computation.vmState.blockNumber.toFork proc applyChildComputation*(computation: var BaseComputation, childMsg: Message, opCode: static[Op]): BaseComputation = ## Apply the vm message childMsg as a child computation. let fork = computation.getFork result = fork.generateChildComputation(computation, childMsg, opCode) fork.addChildComputation(computation, result) proc registerAccountForDeletion*(c: var BaseComputation, beneficiary: EthAddress) = if c.msg.storageAddress in c.accountsToDelete: raise newException(ValueError, "invariant: should be impossible for an account to be " & "registered for deletion multiple times") c.accountsToDelete[c.msg.storageAddress] = beneficiary proc isSuicided*(c: var BaseComputation, address: EthAddress): bool = result = address in c.accountsToDelete proc addLogEntry*(c: var BaseComputation, log: Log) {.inline.} = c.vmState.addLogEntry(log) # many methods are basically TODO, but they still return valid values # in order to test some existing code func getAccountsForDeletion*(c: BaseComputation): seq[EthAddress] = # TODO if c.isError: result = @[] else: result = @[] for account in c.accountsToDelete.keys: result.add(account) proc getGasRefund*(c: BaseComputation): GasInt = if c.isError: result = 0 else: result = c.gasMeter.gasRefunded + c.children.mapIt(it.getGasRefund()).foldl(a + b, 0'i64) proc getGasUsed*(c: BaseComputation): GasInt = if c.shouldBurnGas: result = c.msg.gas else: result = max(0, c.msg.gas - c.gasMeter.gasRemaining) proc getGasRemaining*(c: BaseComputation): GasInt = if c.shouldBurnGas: result = 0 else: result = c.gasMeter.gasRemaining proc tracingEnabled*(c: BaseComputation): bool = c.vmState.tracingEnabled proc traceOpCodeStarted*(c: BaseComputation, op: Op): int = c.vmState.tracer.traceOpCodeStarted(c, op) proc traceOpCodeEnded*(c: BaseComputation, op: Op, lastIndex: int) = c.vmState.tracer.traceOpCodeEnded(c, op, lastIndex) proc traceError*(c: BaseComputation) = c.vmState.tracer.traceError(c) proc prepareTracer*(c: BaseComputation) = c.vmState.tracer.prepare(c.msg.depth)