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// Copyright 2015 The go-ethereum Authors
// This file is part of the go-ethereum library.
//
// The go-ethereum library is free software: you can redistribute it and/or modify
// it under the terms of the GNU Lesser General Public License as published by
// the Free Software Foundation, either version 3 of the License, or
// (at your option) any later version.
//
// The go-ethereum library is distributed in the hope that it will be useful,
// but WITHOUT ANY WARRANTY; without even the implied warranty of
// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
// GNU Lesser General Public License for more details.
//
// You should have received a copy of the GNU Lesser General Public License
// along with the go-ethereum library. If not, see <http://www.gnu.org/licenses/>.
// +build evmjit
package vm
/*
void* evmjit_create();
int evmjit_run(void* _jit, void* _data, void* _env);
void evmjit_destroy(void* _jit);
// Shared library evmjit (e.g. libevmjit.so) is expected to be installed in /usr/local/lib
// More: https://github.com/ethereum/evmjit
#cgo LDFLAGS: -levmjit
*/
import "C"
/*
import (
"bytes"
"errors"
"fmt"
"math/big"
"unsafe"
"github.com/ethereum/go-ethereum/core/state"
"github.com/ethereum/go-ethereum/crypto"
"github.com/ethereum/go-ethereum/params"
)
type JitVm struct {
env Environment
me ContextRef
callerAddr []byte
price *big.Int
data RuntimeData
}
type i256 [32]byte
type RuntimeData struct {
gas int64
gasPrice int64
callData *byte
callDataSize uint64
address i256
caller i256
origin i256
callValue i256
coinBase i256
difficulty i256
gasLimit i256
number uint64
timestamp int64
code *byte
codeSize uint64
codeHash i256
}
func hash2llvm(h []byte) i256 {
var m i256
copy(m[len(m)-len(h):], h) // right aligned copy
return m
}
func llvm2hash(m *i256) []byte {
return C.GoBytes(unsafe.Pointer(m), C.int(len(m)))
}
func llvm2hashRef(m *i256) []byte {
return (*[1 << 30]byte)(unsafe.Pointer(m))[:len(m):len(m)]
}
func address2llvm(addr []byte) i256 {
n := hash2llvm(addr)
bswap(&n)
return n
}
// bswap swap bytes of the 256-bit integer on LLVM side
// TODO: Do not change memory on LLVM side, that can conflict with memory access optimizations
func bswap(m *i256) *i256 {
for i, l := 0, len(m); i < l/2; i++ {
m[i], m[l-i-1] = m[l-i-1], m[i]
}
return m
}
func trim(m []byte) []byte {
skip := 0
for i := 0; i < len(m); i++ {
if m[i] == 0 {
skip++
} else {
break
}
}
return m[skip:]
}
func getDataPtr(m []byte) *byte {
var p *byte
if len(m) > 0 {
p = &m[0]
}
return p
}
func big2llvm(n *big.Int) i256 {
m := hash2llvm(n.Bytes())
bswap(&m)
return m
}
func llvm2big(m *i256) *big.Int {
n := big.NewInt(0)
for i := 0; i < len(m); i++ {
b := big.NewInt(int64(m[i]))
b.Lsh(b, uint(i)*8)
n.Add(n, b)
}
return n
}
// llvm2bytesRef creates a []byte slice that references byte buffer on LLVM side (as of that not controller by GC)
// User must asure that referenced memory is available to Go until the data is copied or not needed any more
func llvm2bytesRef(data *byte, length uint64) []byte {
if length == 0 {
return nil
}
if data == nil {
panic("Unexpected nil data pointer")
}
return (*[1 << 30]byte)(unsafe.Pointer(data))[:length:length]
}
func untested(condition bool, message string) {
if condition {
panic("Condition `" + message + "` tested. Remove assert.")
}
}
func assert(condition bool, message string) {
if !condition {
panic("Assert `" + message + "` failed!")
}
}
func NewJitVm(env Environment) *JitVm {
return &JitVm{env: env}
}
func (self *JitVm) Run(me, caller ContextRef, code []byte, value, gas, price *big.Int, callData []byte) (ret []byte, err error) {
// TODO: depth is increased but never checked by VM. VM should not know about it at all.
self.env.SetDepth(self.env.Depth() + 1)
// TODO: Move it to Env.Call() or sth
if Precompiled[string(me.Address())] != nil {
// if it's address of precopiled contract
// fallback to standard VM
stdVm := New(self.env)
return stdVm.Run(me, caller, code, value, gas, price, callData)
}
if self.me != nil {
panic("JitVm.Run() can be called only once per JitVm instance")
}
self.me = me
self.callerAddr = caller.Address()
self.price = price
self.data.gas = gas.Int64()
self.data.gasPrice = price.Int64()
self.data.callData = getDataPtr(callData)
self.data.callDataSize = uint64(len(callData))
self.data.address = address2llvm(self.me.Address())
self.data.caller = address2llvm(caller.Address())
self.data.origin = address2llvm(self.env.Origin())
self.data.callValue = big2llvm(value)
self.data.coinBase = address2llvm(self.env.Coinbase())
self.data.difficulty = big2llvm(self.env.Difficulty())
self.data.gasLimit = big2llvm(self.env.GasLimit())
self.data.number = self.env.BlockNumber().Uint64()
self.data.timestamp = self.env.Time()
self.data.code = getDataPtr(code)
self.data.codeSize = uint64(len(code))
self.data.codeHash = hash2llvm(crypto.Sha3(code)) // TODO: Get already computed hash?
jit := C.evmjit_create()
retCode := C.evmjit_run(jit, unsafe.Pointer(&self.data), unsafe.Pointer(self))
if retCode < 0 {
err = errors.New("OOG from JIT")
gas.SetInt64(0) // Set gas to 0, JIT does not bother
} else {
gas.SetInt64(self.data.gas)
if retCode == 1 { // RETURN
ret = C.GoBytes(unsafe.Pointer(self.data.callData), C.int(self.data.callDataSize))
} else if retCode == 2 { // SUICIDE
// TODO: Suicide support logic should be moved to Env to be shared by VM implementations
state := self.Env().State()
receiverAddr := llvm2hashRef(bswap(&self.data.address))
receiver := state.GetOrNewStateObject(receiverAddr)
balance := state.GetBalance(me.Address())
receiver.AddBalance(balance)
state.Delete(me.Address())
}
}
C.evmjit_destroy(jit)
return
}
func (self *JitVm) Printf(format string, v ...interface{}) VirtualMachine {
return self
}
func (self *JitVm) Endl() VirtualMachine {
return self
}
func (self *JitVm) Env() Environment {
return self.env
}
//export env_sha3
func env_sha3(dataPtr *byte, length uint64, resultPtr unsafe.Pointer) {
data := llvm2bytesRef(dataPtr, length)
hash := crypto.Sha3(data)
result := (*i256)(resultPtr)
*result = hash2llvm(hash)
}
//export env_sstore
func env_sstore(vmPtr unsafe.Pointer, indexPtr unsafe.Pointer, valuePtr unsafe.Pointer) {
vm := (*JitVm)(vmPtr)
index := llvm2hash(bswap((*i256)(indexPtr)))
value := llvm2hash(bswap((*i256)(valuePtr)))
value = trim(value)
if len(value) == 0 {
prevValue := vm.env.State().GetState(vm.me.Address(), index)
if len(prevValue) != 0 {
vm.Env().State().Refund(vm.callerAddr, GasSStoreRefund)
}
}
vm.env.State().SetState(vm.me.Address(), index, value)
}
//export env_sload
func env_sload(vmPtr unsafe.Pointer, indexPtr unsafe.Pointer, resultPtr unsafe.Pointer) {
vm := (*JitVm)(vmPtr)
index := llvm2hash(bswap((*i256)(indexPtr)))
value := vm.env.State().GetState(vm.me.Address(), index)
result := (*i256)(resultPtr)
*result = hash2llvm(value)
bswap(result)
}
//export env_balance
func env_balance(_vm unsafe.Pointer, _addr unsafe.Pointer, _result unsafe.Pointer) {
vm := (*JitVm)(_vm)
addr := llvm2hash((*i256)(_addr))
balance := vm.Env().State().GetBalance(addr)
result := (*i256)(_result)
*result = big2llvm(balance)
}
//export env_blockhash
func env_blockhash(_vm unsafe.Pointer, _number unsafe.Pointer, _result unsafe.Pointer) {
vm := (*JitVm)(_vm)
number := llvm2big((*i256)(_number))
result := (*i256)(_result)
currNumber := vm.Env().BlockNumber()
limit := big.NewInt(0).Sub(currNumber, big.NewInt(256))
if number.Cmp(limit) >= 0 && number.Cmp(currNumber) < 0 {
hash := vm.Env().GetHash(uint64(number.Int64()))
*result = hash2llvm(hash)
} else {
*result = i256{}
}
}
//export env_call
func env_call(_vm unsafe.Pointer, _gas *int64, _receiveAddr unsafe.Pointer, _value unsafe.Pointer, inDataPtr unsafe.Pointer, inDataLen uint64, outDataPtr *byte, outDataLen uint64, _codeAddr unsafe.Pointer) bool {
vm := (*JitVm)(_vm)
//fmt.Printf("env_call (depth %d)\n", vm.Env().Depth())
defer func() {
if r := recover(); r != nil {
fmt.Printf("Recovered in env_call (depth %d, out %p %d): %s\n", vm.Env().Depth(), outDataPtr, outDataLen, r)
}
}()
balance := vm.Env().State().GetBalance(vm.me.Address())
value := llvm2big((*i256)(_value))
if balance.Cmp(value) >= 0 {
receiveAddr := llvm2hash((*i256)(_receiveAddr))
inData := C.GoBytes(inDataPtr, C.int(inDataLen))
outData := llvm2bytesRef(outDataPtr, outDataLen)
codeAddr := llvm2hash((*i256)(_codeAddr))
gas := big.NewInt(*_gas)
var out []byte
var err error
if bytes.Equal(codeAddr, receiveAddr) {
out, err = vm.env.Call(vm.me, codeAddr, inData, gas, vm.price, value)
} else {
out, err = vm.env.CallCode(vm.me, codeAddr, inData, gas, vm.price, value)
}
*_gas = gas.Int64()
if err == nil {
copy(outData, out)
return true
}
}
return false
}
//export env_create
func env_create(_vm unsafe.Pointer, _gas *int64, _value unsafe.Pointer, initDataPtr unsafe.Pointer, initDataLen uint64, _result unsafe.Pointer) {
vm := (*JitVm)(_vm)
value := llvm2big((*i256)(_value))
initData := C.GoBytes(initDataPtr, C.int(initDataLen)) // TODO: Unnecessary if low balance
result := (*i256)(_result)
*result = i256{}
gas := big.NewInt(*_gas)
ret, suberr, ref := vm.env.Create(vm.me, nil, initData, gas, vm.price, value)
if suberr == nil {
dataGas := big.NewInt(int64(len(ret))) // TODO: Nto the best design. env.Create can do it, it has the reference to gas counter
dataGas.Mul(dataGas, params.CreateDataGas)
gas.Sub(gas, dataGas)
*result = hash2llvm(ref.Address())
}
*_gas = gas.Int64()
}
//export env_log
func env_log(_vm unsafe.Pointer, dataPtr unsafe.Pointer, dataLen uint64, _topic1 unsafe.Pointer, _topic2 unsafe.Pointer, _topic3 unsafe.Pointer, _topic4 unsafe.Pointer) {
vm := (*JitVm)(_vm)
data := C.GoBytes(dataPtr, C.int(dataLen))
topics := make([][]byte, 0, 4)
if _topic1 != nil {
topics = append(topics, llvm2hash((*i256)(_topic1)))
}
if _topic2 != nil {
topics = append(topics, llvm2hash((*i256)(_topic2)))
}
if _topic3 != nil {
topics = append(topics, llvm2hash((*i256)(_topic3)))
}
if _topic4 != nil {
topics = append(topics, llvm2hash((*i256)(_topic4)))
}
vm.Env().AddLog(state.NewLog(vm.me.Address(), topics, data, vm.env.BlockNumber().Uint64()))
}
//export env_extcode
func env_extcode(_vm unsafe.Pointer, _addr unsafe.Pointer, o_size *uint64) *byte {
vm := (*JitVm)(_vm)
addr := llvm2hash((*i256)(_addr))
code := vm.Env().State().GetCode(addr)
*o_size = uint64(len(code))
return getDataPtr(code)
}*/
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