nimbus-eth1/nimbus/vm/interpreter/opcodes_impl.nim

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# Nimbus
# Copyright (c) 2018-2019 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
strformat, times, ranges, sequtils, options,
chronicles, stint, nimcrypto, ranges/typedranges, eth/common,
./utils/[macros_procs_opcodes, utils_numeric],
./gas_meter, ./gas_costs, ./opcode_values, ./vm_forks,
../memory, ../message, ../stack, ../code_stream, ../computation,
../../vm_state, ../../errors, ../../constants, ../../vm_types,
../../db/[db_chain, state_db], ../../utils
logScope:
topics = "opcode impl"
# ##################################
# Syntactic sugar
template push(x: typed) {.dirty.} =
## Push an expression on the computation stack
computation.stack.push x
# ##################################
# 0s: Stop and Arithmetic Operations
op add, inline = true, lhs, rhs:
## 0x01, Addition
push: lhs + rhs
op mul, inline = true, lhs, rhs:
## 0x02, Multiplication
push: lhs * rhs
op sub, inline = true, lhs, rhs:
## 0x03, Substraction
push: lhs - rhs
op divide, inline = true, lhs, rhs:
## 0x04, Division
push:
if rhs == 0: zero(Uint256) # EVM special casing of div by 0
else: lhs div rhs
op sdiv, inline = true, lhs, rhs:
## 0x05, Signed division
var r: UInt256
if rhs != 0:
const min = (1.u256 shl 255) - 1.u256
var a = lhs
var b = rhs
var signA, signB: bool
extractSign(a, signA)
extractSign(b, signB)
if a == min and b == not zero(UInt256):
r = min
else:
r = a div b
setSign(r, signA xor signB)
push(r)
op modulo, inline = true, lhs, rhs:
## 0x06, Modulo
push:
if rhs == 0: zero(Uint256)
else: lhs mod rhs
op smod, inline = true, lhs, rhs:
## 0x07, Signed modulo
var r: UInt256
if rhs != 0:
var sign: bool
var v = lhs
var m = rhs
extractSign(m, sign)
extractSign(v, sign)
r = v mod m
setSign(r, sign)
push(r)
op addmod, inline = true, lhs, rhs, modulus:
## 0x08, Modulo addition
## Intermediate computations do not roll over at 2^256
push:
if modulus == 0: zero(UInt256) # EVM special casing of div by 0
else: addmod(lhs, rhs, modulus)
op mulmod, inline = true, lhs, rhs, modulus:
## 0x09, Modulo multiplication
## Intermediate computations do not roll over at 2^256
push:
if modulus == 0: zero(UInt256) # EVM special casing of div by 0
else: mulmod(lhs, rhs, modulus)
op exp, inline = true, base, exponent:
## 0x0A, Exponentiation
computation.gasMeter.consumeGas(
computation.gasCosts[Exp].d_handler(exponent),
reason="EXP: exponent bytes"
)
push:
if base.isZero:
if exponent.isZero:
# https://github.com/ethereum/yellowpaper/issues/257
# https://github.com/ethereum/tests/pull/460
# https://github.com/ewasm/evm2wasm/issues/137
1.u256
else:
zero(UInt256)
else:
base.pow(exponent)
op signExtend, inline = false, bits, value:
## 0x0B, Sign extend
## Extend length of twos complement signed integer.
var res: UInt256
if bits <= 31.u256:
let
one = 1.u256
testBit = bits.toInt * 8 + 7
bitPos = one shl testBit
mask = bitPos - one
if not isZero(value and bitPos):
res = value or (not mask)
else:
res = value and mask
else:
res = value
push: res
# ##########################################
# 10s: Comparison & Bitwise Logic Operations
op lt, inline = true, lhs, rhs:
## 0x10, Less-than comparison
push: (lhs < rhs).uint.u256
op gt, inline = true, lhs, rhs:
## 0x11, Greater-than comparison
push: (lhs > rhs).uint.u256
op slt, inline = true, lhs, rhs:
## 0x12, Signed less-than comparison
push: (cast[Int256](lhs) < cast[Int256](rhs)).uint.u256
op sgt, inline = true, lhs, rhs:
## 0x13, Signed greater-than comparison
push: (cast[Int256](lhs) > cast[Int256](rhs)).uint.u256
op eq, inline = true, lhs, rhs:
## 0x14, Signed greater-than comparison
push: (lhs == rhs).uint.u256
op isZero, inline = true, value:
## 0x15, Check if zero
push: value.isZero.uint.u256
op andOp, inline = true, lhs, rhs:
## 0x16, Bitwise AND
push: lhs and rhs
op orOp, inline = true, lhs, rhs:
## 0x17, Bitwise AND
push: lhs or rhs
op xorOp, inline = true, lhs, rhs:
## 0x18, Bitwise AND
push: lhs xor rhs
op notOp, inline = true, value:
## 0x19, Check if zero
push: value.not
op byteOp, inline = true, position, value:
## 0x20, Retrieve single byte from word.
let pos = position.toInt
push:
if pos >= 32 or pos < 0: zero(Uint256)
else:
when system.cpuEndian == bigEndian:
cast[array[32, byte]](value)[pos].u256
else:
cast[array[32, byte]](value)[31 - pos].u256
# ##########################################
# 20s: SHA3
op sha3, inline = true, startPos, length:
## 0x20, Compute Keccak-256 hash.
let (pos, len) = (startPos.toInt, length.toInt)
if pos < 0 or len < 0 or pos > 2147483648:
raise newException(OutOfBoundsRead, "Out of bounds memory access")
computation.gasMeter.consumeGas(
computation.gasCosts[Op.Sha3].m_handler(computation.memory.len, pos, len),
reason="SHA3: word gas cost"
)
computation.memory.extend(pos, len)
let endRange = min(pos + len, computation.memory.len) - 1
if endRange == -1:
push(EMPTY_SHA3)
else:
push:
keccak256.digest computation.memory.bytes.toOpenArray(pos, endRange)
# ##########################################
# 30s: Environmental Information
proc writePaddedResult(mem: var Memory,
data: openarray[byte],
memPos, dataPos, len: Natural,
paddingValue = 0.byte) =
mem.extend(memPos, len)
let dataEndPosition = dataPos.int64 + len - 1
let sourceBytes = data[min(dataPos, data.len) .. min(data.len - 1, dataEndPosition)]
mem.write(memPos, sourceBytes)
# Don't duplicate zero-padding of mem.extend
let paddingOffset = min(memPos + sourceBytes.len, mem.len)
let numPaddingBytes = min(mem.len - paddingOffset, len - sourceBytes.len)
if numPaddingBytes > 0:
# TODO: avoid unnecessary memory allocation
mem.write(paddingOffset, repeat(paddingValue, numPaddingBytes))
op address, inline = true:
## 0x30, Get address of currently executing account.
push: computation.msg.storageAddress
op balance, inline = true:
## 0x31, Get balance of the given account.
let address = computation.stack.popAddress()
push: computation.vmState.readOnlyStateDB.getBalance(address)
op origin, inline = true:
## 0x32, Get execution origination address.
push: computation.msg.origin
op caller, inline = true:
## 0x33, Get caller address.
push: computation.msg.sender
op callValue, inline = true:
## 0x34, Get deposited value by the instruction/transaction
## responsible for this execution
push: computation.msg.value
op callDataLoad, inline = false, startPos:
## 0x35, Get input data of current environment
let dataPos = startPos.cleanMemRef
if dataPos >= computation.msg.data.len:
push: 0
return
let dataEndPosition = dataPos + 31
if dataEndPosition < computation.msg.data.len:
computation.stack.push(computation.msg.data[dataPos .. dataEndPosition])
else:
var bytes: array[32, byte]
var presentBytes = min(computation.msg.data.len - dataPos, 32)
if presentBytes > 0:
copyMem(addr bytes[0], addr computation.msg.data[dataPos], presentBytes)
else:
presentBytes = 0
for i in presentBytes ..< 32: bytes[i] = 0
computation.stack.push(bytes)
op callDataSize, inline = true:
## 0x36, Get size of input data in current environment.
push: computation.msg.data.len.u256
op callDataCopy, inline = false, memStartPos, copyStartPos, size:
## 0x37, Copy input data in current environment to memory.
# TODO tests: https://github.com/status-im/nimbus/issues/67
let (memPos, copyPos, len) = (memStartPos.cleanMemRef, copyStartPos.cleanMemRef, size.cleanMemRef)
computation.gasMeter.consumeGas(
computation.gasCosts[CallDataCopy].m_handler(computation.memory.len, memPos, len),
reason="CallDataCopy fee")
computation.memory.writePaddedResult(computation.msg.data, memPos, copyPos, len)
op codeSize, inline = true:
## 0x38, Get size of code running in current environment.
push: computation.code.len
op codeCopy, inline = false, memStartPos, copyStartPos, size:
## 0x39, Copy code running in current environment to memory.
# TODO tests: https://github.com/status-im/nimbus/issues/67
let (memPos, copyPos, len) = (memStartPos.cleanMemRef, copyStartPos.cleanMemRef, size.cleanMemRef)
computation.gasMeter.consumeGas(
computation.gasCosts[CodeCopy].m_handler(computation.memory.len, memPos, len),
reason="CodeCopy fee")
computation.memory.writePaddedResult(computation.code.bytes, memPos, copyPos, len)
op gasprice, inline = true:
## 0x3A, Get price of gas in current environment.
push: computation.msg.gasPrice
op extCodeSize, inline = true:
## 0x3b, Get size of an account's code
let account = computation.stack.popAddress()
let codeSize = computation.vmState.readOnlyStateDB.getCode(account).len
push uint(codeSize)
op extCodeCopy, inline = true:
## 0x3c, Copy an account's code to memory.
let account = computation.stack.popAddress()
let (memStartPos, codeStartPos, size) = computation.stack.popInt(3)
let (memPos, codePos, len) = (memStartPos.cleanMemRef, codeStartPos.cleanMemRef, size.cleanMemRef)
computation.gasMeter.consumeGas(
computation.gasCosts[ExtCodeCopy].m_handler(computation.memory.len, memPos, len),
reason="ExtCodeCopy fee")
let codeBytes = computation.vmState.readOnlyStateDB.getCode(account)
computation.memory.writePaddedResult(codeBytes.toOpenArray, memPos, codePos, len)
op returnDataSize, inline = true:
## 0x3d, Get size of output data from the previous call from the current environment.
push: computation.returnData.len
op returnDataCopy, inline = false, memStartPos, copyStartPos, size:
## 0x3e, Copy output data from the previous call to memory.
let (memPos, copyPos, len) = (memStartPos.cleanMemRef, copyStartPos.cleanMemRef, size.cleanMemRef)
computation.gasMeter.consumeGas(
computation.gasCosts[ReturnDataCopy].m_handler(memPos, copyPos, len),
reason="returnDataCopy fee")
if copyPos + len > computation.returnData.len:
# TODO Geth additionally checks copyPos + len < 64
# Parity uses a saturating addition
# Yellow paper mentions μs[1] + i are not subject to the 2^256 modulo.
raise newException(OutOfBoundsRead,
"Return data length is not sufficient to satisfy request. Asked \n" &
&"for data from index {copyStartPos} to {copyStartPos + size}. Return data is {computation.returnData.len} in \n" &
"length")
computation.memory.extend(memPos, len)
computation.memory.write(memPos):
computation.returnData.toOpenArray(copyPos, copyPos+len)
# ##########################################
# 40s: Block Information
op blockhash, inline = true, blockNumber:
## 0x40, Get the hash of one of the 256 most recent complete blocks.
push: computation.vmState.getAncestorHash(blockNumber)
op coinbase, inline = true:
## 0x41, Get the block's beneficiary address.
push: computation.vmState.coinbase
op timestamp, inline = true:
## 0x42, Get the block's timestamp.
push: computation.vmState.timestamp.toUnix
op blocknumber, inline = true:
## 0x43, Get the block's number.
push: computation.vmState.blockNumber
op difficulty, inline = true:
## 0x44, Get the block's difficulty
push: computation.vmState.difficulty
op gasLimit, inline = true:
## 0x45, Get the block's gas limit
push: computation.vmState.gasLimit
# ##########################################
# 50s: Stack, Memory, Storage and Flow Operations
op pop, inline = true:
## 0x50, Remove item from stack.
discard computation.stack.popInt()
op mload, inline = true, memStartPos:
## 0x51, Load word from memory
let memPos = memStartPos.cleanMemRef
computation.gasMeter.consumeGas(
computation.gasCosts[MLoad].m_handler(computation.memory.len, memPos, 32),
reason="MLOAD: GasVeryLow + memory expansion"
)
computation.memory.extend(memPos, 32)
push: computation.memory.read(memPos, 32) # TODO, should we convert to native endianness?
op mstore, inline = true, memStartPos, value:
## 0x52, Save word to memory
let memPos = memStartPos.cleanMemRef
computation.gasMeter.consumeGas(
computation.gasCosts[MStore].m_handler(computation.memory.len, memPos, 32),
reason="MSTORE: GasVeryLow + memory expansion"
)
computation.memory.extend(memPos, 32)
computation.memory.write(memPos, value.toByteArrayBE) # is big-endian correct? Parity/Geth do convert
op mstore8, inline = true, memStartPos, value:
## 0x53, Save byte to memory
let memPos = memStartPos.cleanMemRef
computation.gasMeter.consumeGas(
computation.gasCosts[MStore].m_handler(computation.memory.len, memPos, 1),
reason="MSTORE8: GasVeryLow + memory expansion"
)
computation.memory.extend(memPos, 1)
computation.memory.write(memPos, [value.toByteArrayBE[31]])
op sload, inline = true, slot:
## 0x54, Load word from storage.
let (value, _) = computation.vmState.readOnlyStateDB.getStorage(computation.msg.storageAddress, slot)
push(value)
op sstore, inline = false, slot, value:
## 0x55, Save word to storage.
let (currentValue, existing) = computation.vmState.readOnlyStateDB.getStorage(computation.msg.storageAddress, slot)
let
gasParam = GasParams(kind: Op.Sstore, s_isStorageEmpty: currentValue.isZero)
(gasCost, gasRefund) = computation.gasCosts[Sstore].c_handler(value, gasParam)
computation.gasMeter.consumeGas(gasCost, &"SSTORE: {computation.msg.storageAddress}[{slot}] -> {value} ({currentValue})")
if gasRefund > 0:
computation.gasMeter.refundGas(gasRefund)
computation.vmState.mutateStateDB:
db.setStorage(computation.msg.storageAddress, slot, value)
proc jumpImpl(computation: BaseComputation, jumpTarget: UInt256) =
if jumpTarget >= computation.code.len.u256:
raise newException(InvalidJumpDestination, "Invalid Jump Destination")
let jt = jumpTarget.toInt
computation.code.pc = jt
let nextOpcode = computation.code.peek
if nextOpcode != JUMPDEST:
raise newException(InvalidJumpDestination, "Invalid Jump Destination")
# TODO: next check seems redundant
if not computation.code.isValidOpcode(jt):
raise newException(InvalidInstruction, "Jump resulted in invalid instruction")
op jump, inline = true, jumpTarget:
## 0x56, Alter the program counter
jumpImpl(computation, jumpTarget)
op jumpI, inline = true, jumpTarget, testedValue:
## 0x57, Conditionally alter the program counter.
if testedValue != 0:
jumpImpl(computation, jumpTarget)
op pc, inline = true:
## 0x58, Get the value of the program counter prior to the increment corresponding to this instruction.
push: max(computation.code.pc - 1, 0)
op msize, inline = true:
## 0x59, Get the size of active memory in bytes.
push: computation.memory.len
op gas, inline = true:
## 0x5a, Get the amount of available gas, including the corresponding reduction for the cost of this instruction.
push: computation.gasMeter.gasRemaining
op jumpDest, inline = true:
## 0x5b, Mark a valid destination for jumps. This operation has no effect on machine state during execution.
discard
# ##########################################
# 60s & 70s: Push Operations.
# 80s: Duplication Operations
# 90s: Exchange Operations
# a0s: Logging Operations
genPush()
genDup()
genSwap()
genLog()
# ##########################################
# f0s: System operations.
proc canTransfer(computation: BaseComputation, memPos, memLen: int, value: Uint256): bool =
let gasParams = GasParams(kind: Create,
cr_currentMemSize: computation.memory.len,
cr_memOffset: memPos,
cr_memLength: memLen
)
let gasCost = computation.gasCosts[Create].c_handler(1.u256, gasParams).gasCost
let reason = &"CREATE: GasCreate + {memLen} * memory expansion"
computation.gasMeter.consumeGas(gasCost, reason = reason)
computation.memory.extend(memPos, memLen)
# the sender is childmsg sender, not parent msg sender
# perhaps we need to move this code somewhere else
# to avoid confusion
let senderBalance =
computation.vmState.readOnlyStateDb().
getBalance(computation.msg.storageAddress)
if senderBalance < value:
debug "Computation Failure", reason = "Insufficient funds available to transfer", required = computation.msg.value, balance = senderBalance
return false
# unlike the other MaxCallDepth comparison,
# this one has not been entered child computation
# thats why it has `+ 1`
if computation.msg.depth + 1 > MaxCallDepth:
debug "Computation Failure", reason = "Stack too deep", maximumDepth = MaxCallDepth, depth = computation.msg.depth
return false
result = true
proc setupCreate(computation: BaseComputation, memPos, len: int, value: Uint256): BaseComputation =
let
callData = computation.memory.read(memPos, len)
var
createMsgGas = computation.getGasRemaining()
if getFork(computation) >= FkTangerine:
createMsgGas -= createMsgGas div 64
# Consume gas here that will be passed to child
computation.gasMeter.consumeGas(createMsgGas, reason="CREATE")
# Generate new address and check for collisions
var
contractAddress: EthAddress
isCollision: bool
computation.vmState.mutateStateDB:
# Regarding collisions, see: https://github.com/status-im/nimbus/issues/133
# See: https://github.com/ethereum/EIPs/issues/684
let creationNonce = db.getNonce(computation.msg.storageAddress)
db.setNonce(computation.msg.storageAddress, creationNonce + 1)
contractAddress = generateAddress(computation.msg.storageAddress, creationNonce)
isCollision = db.hasCodeOrNonce(contractAddress)
if isCollision:
debug "Address collision while creating contract", address = contractAddress.toHex
push: 0
return
let childMsg = prepareChildMessage(
computation,
gas = createMsgGas,
to = CREATE_CONTRACT_ADDRESS,
value = value,
data = @[],
code = callData,
options = MessageOptions(createAddress: contractAddress)
)
childMsg.sender = computation.msg.storageAddress
result = newBaseComputation(
computation.vmState,
computation.vmState.blockNumber,
childMsg,
some(computation.getFork))
op create, inline = false, value, startPosition, size:
## 0xf0, Create a new account with associated code.
# TODO: Forked create for Homestead
let (memPos, len) = (startPosition.cleanMemRef, size.cleanMemRef)
if not computation.canTransfer(memPos, len, value):
push: 0
return
var childComp = setupCreate(computation, memPos, len, value)
if childComp.isNil: return
computation.child = childComp
continuation(childComp):
computation.addChildComputation(childComp)
if childComp.isError:
push: 0
else:
push: childComp.msg.storageAddress
childComp.applyMessage(Create)
proc callParams(computation: BaseComputation): (UInt256, UInt256, EthAddress, EthAddress, EthAddress, UInt256, UInt256, UInt256, UInt256, MsgFlags) =
let gas = computation.stack.popInt()
let codeAddress = computation.stack.popAddress()
let (value,
memoryInputStartPosition, memoryInputSize,
memoryOutputStartPosition, memoryOutputSize) = computation.stack.popInt(5)
let to = codeAddress
let sender = computation.msg.storageAddress
result = (gas,
value,
to,
sender,
codeAddress,
memoryInputStartPosition,
memoryInputSize,
memoryOutputStartPosition,
memoryOutputSize,
computation.msg.flags)
proc callCodeParams(computation: BaseComputation): (UInt256, UInt256, EthAddress, EthAddress, EthAddress, UInt256, UInt256, UInt256, UInt256, MsgFlags) =
let gas = computation.stack.popInt()
let to = computation.stack.popAddress()
let (value,
memoryInputStartPosition, memoryInputSize,
memoryOutputStartPosition, memoryOutputSize) = computation.stack.popInt(5)
result = (gas,
value,
to,
computation.msg.storageAddress, # sender
to, # code_address
memoryInputStartPosition,
memoryInputSize,
memoryOutputStartPosition,
memoryOutputSize,
computation.msg.flags)
proc delegateCallParams(computation: BaseComputation): (UInt256, UInt256, EthAddress, EthAddress, EthAddress, UInt256, UInt256, UInt256, UInt256, MsgFlags) =
let gas = computation.stack.popInt()
let codeAddress = computation.stack.popAddress()
let (memoryInputStartPosition, memoryInputSize,
memoryOutputStartPosition, memoryOutputSize) = computation.stack.popInt(4)
let to = computation.msg.storageAddress
let sender = computation.msg.sender
let value = computation.msg.value
result = (gas,
value,
to,
sender,
codeAddress,
memoryInputStartPosition,
memoryInputSize,
memoryOutputStartPosition,
memoryOutputSize,
computation.msg.flags)
proc staticCallParams(computation: BaseComputation): (UInt256, UInt256, EthAddress, EthAddress, EthAddress, UInt256, UInt256, UInt256, UInt256, MsgFlags) =
let gas = computation.stack.popInt()
let to = computation.stack.popAddress()
let (memoryInputStartPosition, memoryInputSize,
memoryOutputStartPosition, memoryOutputSize) = computation.stack.popInt(4)
result = (gas,
0.u256, # value
to,
ZERO_ADDRESS, # sender
ZERO_ADDRESS, # codeAddress
memoryInputStartPosition,
memoryInputSize,
memoryOutputStartPosition,
memoryOutputSize,
emvcStatic) # is_static
template genCall(callName: untyped, opCode: Op): untyped =
proc `callName Setup`(computation: BaseComputation, callNameStr: string): BaseComputation =
let (gas, value, to, sender,
codeAddress,
memoryInputStartPosition, memoryInputSize,
memoryOutputStartPosition, memoryOutputSize,
flags) = `callName Params`(computation)
let (memInPos, memInLen, memOutPos, memOutLen) = (memoryInputStartPosition.cleanMemRef, memoryInputSize.cleanMemRef, memoryOutputStartPosition.cleanMemRef, memoryOutputSize.cleanMemRef)
let isNewAccount = if getFork(computation) >= FkSpurious:
computation.vmState.readOnlyStateDb.isDeadAccount(to)
else:
not computation.vmState.readOnlyStateDb.accountExists(to)
let (memOffset, memLength) = if memInPos + memInLen > memOutPos + memOutLen:
(memInPos, memInLen)
else:
(memOutPos, memOutLen)
let (childGasFee, childGasLimit) = computation.gasCosts[opCode].c_handler(
value,
GasParams(kind: opCode,
c_isNewAccount: isNewAccount,
c_gasBalance: computation.gasMeter.gasRemaining,
c_contractGas: gas,
c_currentMemSize: computation.memory.len,
c_memOffset: memOffset,
c_memLength: memLength
))
if childGasFee >= 0:
computation.gasMeter.consumeGas(childGasFee, reason = $opCode)
if childGasFee < 0 and childGasLimit <= 0:
raise newException(OutOfGas, "Gas not enough to perform calculation (" & callNameStr & ")")
computation.memory.extend(memInPos, memInLen)
computation.memory.extend(memOutPos, memOutLen)
let
callData = computation.memory.read(memInPos, memInLen)
code = computation.vmState.readOnlyStateDb.getCode(codeAddress)
var childMsg = prepareChildMessage(
computation,
childGasLimit,
to,
value,
callData,
code.toSeq,
MessageOptions(flags: flags)
)
childMsg.sender = sender
when opCode == CallCode:
childMsg.storageAddress = computation.msg.storageAddress
var childComp = newBaseComputation(
computation.vmState,
computation.vmState.blockNumber,
childMsg,
some(computation.getFork))
computation.memOutPos = memOutPos
computation.memOutLen = memOutLen
result = childComp
op callName, inline = false:
## CALL, 0xf1, Message-Call into an account
## CALLCODE, 0xf2, Message-call into this account with an alternative account's code.
## DELEGATECALL, 0xf4, Message-call into this account with an alternative account's code, but persisting the current values for sender and value.
## STATICCALL, 0xfa, Static message-call into an account.
var childComp = `callName Setup`(computation, callName.astToStr)
computation.child = childComp
continuation(childComp):
addChildComputation(computation, childComp)
if childComp.isError:
push: 0
else:
push: 1
if not childComp.shouldEraseReturnData:
let actualOutputSize = min(computation.memOutLen, childComp.output.len)
computation.memory.write(
computation.memOutPos,
childComp.output.toOpenArray(0, actualOutputSize - 1))
childComp.applyMessage(opCode)
genCall(call, Call)
genCall(callCode, CallCode)
genCall(delegateCall, DelegateCall)
genCall(staticCall, StaticCall)
op returnOp, inline = false, startPos, size:
## 0xf3, Halt execution returning output data.
let (pos, len) = (startPos.cleanMemRef, size.cleanMemRef)
computation.gasMeter.consumeGas(
computation.gasCosts[Return].m_handler(computation.memory.len, pos, len),
reason = "RETURN"
)
computation.memory.extend(pos, len)
computation.output = computation.memory.read(pos, len)
op revert, inline = false, startPos, size:
## 0xfd, Halt execution reverting state changes but returning data and remaining gas.
let (pos, len) = (startPos.cleanMemRef, size.cleanMemRef)
computation.gasMeter.consumeGas(
computation.gasCosts[Revert].m_handler(computation.memory.len, pos, len),
reason = "REVERT"
)
computation.memory.extend(pos, len)
computation.output = computation.memory.read(pos, len)
proc selfDestructImpl(computation: BaseComputation, beneficiary: EthAddress) =
## 0xff Halt execution and register account for later deletion.
# TODO: This is the basic implementation of the self destruct op,
# Other forks have some extra functionality around this call.
# In particular, EIP150 and EIP161 have extra requirements.
computation.vmState.mutateStateDB:
let
localBalance = db.getBalance(computation.msg.storageAddress)
beneficiaryBalance = db.getBalance(beneficiary)
# Transfer to beneficiary
db.setBalance(beneficiary, localBalance + beneficiaryBalance)
# Zero the balance of the address being deleted.
# This must come after sending to beneficiary in case the
# contract named itself as the beneficiary.
db.setBalance(computation.msg.storageAddress, 0.u256)
# Register the account to be deleted
computation.registerAccountForDeletion(beneficiary)
trace "SELFDESTRUCT",
storageAddress = computation.msg.storageAddress.toHex,
localBalance = localBalance.toString,
beneficiary = beneficiary.toHex
op selfDestruct, inline = false:
let beneficiary = computation.stack.popAddress()
selfDestructImpl(computation, beneficiary)
op selfDestructEip150, inline = false:
let beneficiary = computation.stack.popAddress()
let gasParams = GasParams(kind: SelfDestruct,
sd_condition: not computation.vmState.readOnlyStateDb.accountExists(beneficiary)
)
let gasCost = computation.gasCosts[SelfDestruct].c_handler(0.u256, gasParams).gasCost
computation.gasMeter.consumeGas(gasCost, reason = "SELFDESTRUCT EIP150")
selfDestructImpl(computation, beneficiary)
op selfDestructEip161, inline = false:
let
beneficiary = computation.stack.popAddress()
stateDb = computation.vmState.readOnlyStateDb
isDead = stateDb.isDeadAccount(beneficiary)
balance = stateDb.getBalance(computation.msg.storageAddress)
let gasParams = GasParams(kind: SelfDestruct,
sd_condition: isDead and not balance.isZero
)
let gasCost = computation.gasCosts[SelfDestruct].c_handler(0.u256, gasParams).gasCost
computation.gasMeter.consumeGas(gasCost, reason = "SELFDESTRUCT EIP161")
selfDestructImpl(computation, beneficiary)