go-pulse/tests/util.go
Jeffrey Wilcke 64af2aafda core, core/vm: added gas price variance table
This implements 1b & 1c of EIP150 by adding a new GasTable which must be
returned from the RuleSet config method. This table is used to determine
the gas prices for the current epoch.

Please note that when the CreateBySuicide gas price is set it is assumed
that we're in the new epoch phase.

In addition this PR will serve as temporary basis while refactorisation
in being done in the EVM64 PR, which will substentially overhaul the gas
price code.
2016-10-14 18:09:17 +02:00

327 lines
9.7 KiB
Go

// 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/>.
package tests
import (
"bytes"
"fmt"
"math/big"
"os"
"github.com/ethereum/go-ethereum/common"
"github.com/ethereum/go-ethereum/core"
"github.com/ethereum/go-ethereum/core/state"
"github.com/ethereum/go-ethereum/core/types"
"github.com/ethereum/go-ethereum/core/vm"
"github.com/ethereum/go-ethereum/crypto"
"github.com/ethereum/go-ethereum/ethdb"
"github.com/ethereum/go-ethereum/logger/glog"
"github.com/ethereum/go-ethereum/params"
)
var (
ForceJit bool
EnableJit bool
)
func init() {
glog.SetV(0)
if os.Getenv("JITVM") == "true" {
ForceJit = true
EnableJit = true
}
}
func checkLogs(tlog []Log, logs vm.Logs) error {
if len(tlog) != len(logs) {
return fmt.Errorf("log length mismatch. Expected %d, got %d", len(tlog), len(logs))
} else {
for i, log := range tlog {
if common.HexToAddress(log.AddressF) != logs[i].Address {
return fmt.Errorf("log address expected %v got %x", log.AddressF, logs[i].Address)
}
if !bytes.Equal(logs[i].Data, common.FromHex(log.DataF)) {
return fmt.Errorf("log data expected %v got %x", log.DataF, logs[i].Data)
}
if len(log.TopicsF) != len(logs[i].Topics) {
return fmt.Errorf("log topics length expected %d got %d", len(log.TopicsF), logs[i].Topics)
} else {
for j, topic := range log.TopicsF {
if common.HexToHash(topic) != logs[i].Topics[j] {
return fmt.Errorf("log topic[%d] expected %v got %x", j, topic, logs[i].Topics[j])
}
}
}
genBloom := common.LeftPadBytes(types.LogsBloom(vm.Logs{logs[i]}).Bytes(), 256)
if !bytes.Equal(genBloom, common.Hex2Bytes(log.BloomF)) {
return fmt.Errorf("bloom mismatch")
}
}
}
return nil
}
type Account struct {
Balance string
Code string
Nonce string
Storage map[string]string
}
type Log struct {
AddressF string `json:"address"`
DataF string `json:"data"`
TopicsF []string `json:"topics"`
BloomF string `json:"bloom"`
}
func (self Log) Address() []byte { return common.Hex2Bytes(self.AddressF) }
func (self Log) Data() []byte { return common.Hex2Bytes(self.DataF) }
func (self Log) RlpData() interface{} { return nil }
func (self Log) Topics() [][]byte {
t := make([][]byte, len(self.TopicsF))
for i, topic := range self.TopicsF {
t[i] = common.Hex2Bytes(topic)
}
return t
}
func makePreState(db ethdb.Database, accounts map[string]Account) *state.StateDB {
statedb, _ := state.New(common.Hash{}, db)
for addr, account := range accounts {
insertAccount(statedb, addr, account)
}
return statedb
}
func insertAccount(state *state.StateDB, saddr string, account Account) {
if common.IsHex(account.Code) {
account.Code = account.Code[2:]
}
addr := common.HexToAddress(saddr)
state.SetCode(addr, common.Hex2Bytes(account.Code))
state.SetNonce(addr, common.Big(account.Nonce).Uint64())
state.SetBalance(addr, common.Big(account.Balance))
for a, v := range account.Storage {
state.SetState(addr, common.HexToHash(a), common.HexToHash(v))
}
}
type VmEnv struct {
CurrentCoinbase string
CurrentDifficulty string
CurrentGasLimit string
CurrentNumber string
CurrentTimestamp interface{}
PreviousHash string
}
type VmTest struct {
Callcreates interface{}
//Env map[string]string
Env VmEnv
Exec map[string]string
Transaction map[string]string
Logs []Log
Gas string
Out string
Post map[string]Account
Pre map[string]Account
PostStateRoot string
}
type RuleSet struct {
HomesteadBlock *big.Int
DAOForkBlock *big.Int
DAOForkSupport bool
HomesteadGasRepriceBlock *big.Int
}
func (r RuleSet) IsHomestead(n *big.Int) bool {
return n.Cmp(r.HomesteadBlock) >= 0
}
func (r RuleSet) GasTable(num *big.Int) params.GasTable {
if r.HomesteadGasRepriceBlock == nil || num == nil || num.Cmp(r.HomesteadGasRepriceBlock) < 0 {
return params.GasTableHomestead
}
return params.GasTableHomesteadGasRepriceFork
}
type Env struct {
ruleSet RuleSet
depth int
state *state.StateDB
skipTransfer bool
initial bool
Gas *big.Int
origin common.Address
parent common.Hash
coinbase common.Address
number *big.Int
time *big.Int
difficulty *big.Int
gasLimit *big.Int
vmTest bool
evm *vm.EVM
}
func NewEnv(ruleSet RuleSet, state *state.StateDB) *Env {
env := &Env{
ruleSet: ruleSet,
state: state,
}
return env
}
func NewEnvFromMap(ruleSet RuleSet, state *state.StateDB, envValues map[string]string, exeValues map[string]string) *Env {
env := NewEnv(ruleSet, state)
env.origin = common.HexToAddress(exeValues["caller"])
env.parent = common.HexToHash(envValues["previousHash"])
env.coinbase = common.HexToAddress(envValues["currentCoinbase"])
env.number = common.Big(envValues["currentNumber"])
env.time = common.Big(envValues["currentTimestamp"])
env.difficulty = common.Big(envValues["currentDifficulty"])
env.gasLimit = common.Big(envValues["currentGasLimit"])
env.Gas = new(big.Int)
env.evm = vm.New(env, vm.Config{
EnableJit: EnableJit,
ForceJit: ForceJit,
})
return env
}
func (self *Env) RuleSet() vm.RuleSet { return self.ruleSet }
func (self *Env) Vm() vm.Vm { return self.evm }
func (self *Env) Origin() common.Address { return self.origin }
func (self *Env) BlockNumber() *big.Int { return self.number }
func (self *Env) Coinbase() common.Address { return self.coinbase }
func (self *Env) Time() *big.Int { return self.time }
func (self *Env) Difficulty() *big.Int { return self.difficulty }
func (self *Env) Db() vm.Database { return self.state }
func (self *Env) GasLimit() *big.Int { return self.gasLimit }
func (self *Env) VmType() vm.Type { return vm.StdVmTy }
func (self *Env) GetHash(n uint64) common.Hash {
return common.BytesToHash(crypto.Keccak256([]byte(big.NewInt(int64(n)).String())))
}
func (self *Env) AddLog(log *vm.Log) {
self.state.AddLog(log)
}
func (self *Env) Depth() int { return self.depth }
func (self *Env) SetDepth(i int) { self.depth = i }
func (self *Env) CanTransfer(from common.Address, balance *big.Int) bool {
if self.skipTransfer {
if self.initial {
self.initial = false
return true
}
}
return self.state.GetBalance(from).Cmp(balance) >= 0
}
func (self *Env) SnapshotDatabase() int {
return self.state.Snapshot()
}
func (self *Env) RevertToSnapshot(snapshot int) {
self.state.RevertToSnapshot(snapshot)
}
func (self *Env) Transfer(from, to vm.Account, amount *big.Int) {
if self.skipTransfer {
return
}
core.Transfer(from, to, amount)
}
func (self *Env) Call(caller vm.ContractRef, addr common.Address, data []byte, gas, price, value *big.Int) ([]byte, error) {
if self.vmTest && self.depth > 0 {
caller.ReturnGas(gas, price)
return nil, nil
}
ret, err := core.Call(self, caller, addr, data, gas, price, value)
self.Gas = gas
return ret, err
}
func (self *Env) CallCode(caller vm.ContractRef, addr common.Address, data []byte, gas, price, value *big.Int) ([]byte, error) {
if self.vmTest && self.depth > 0 {
caller.ReturnGas(gas, price)
return nil, nil
}
return core.CallCode(self, caller, addr, data, gas, price, value)
}
func (self *Env) DelegateCall(caller vm.ContractRef, addr common.Address, data []byte, gas, price *big.Int) ([]byte, error) {
if self.vmTest && self.depth > 0 {
caller.ReturnGas(gas, price)
return nil, nil
}
return core.DelegateCall(self, caller, addr, data, gas, price)
}
func (self *Env) Create(caller vm.ContractRef, data []byte, gas, price, value *big.Int) ([]byte, common.Address, error) {
if self.vmTest {
caller.ReturnGas(gas, price)
nonce := self.state.GetNonce(caller.Address())
obj := self.state.GetOrNewStateObject(crypto.CreateAddress(caller.Address(), nonce))
return nil, obj.Address(), nil
} else {
return core.Create(self, caller, data, gas, price, value)
}
}
type Message struct {
from common.Address
to *common.Address
value, gas, price *big.Int
data []byte
nonce uint64
}
func NewMessage(from common.Address, to *common.Address, data []byte, value, gas, price *big.Int, nonce uint64) Message {
return Message{from, to, value, gas, price, data, nonce}
}
func (self Message) Hash() []byte { return nil }
func (self Message) From() (common.Address, error) { return self.from, nil }
func (self Message) FromFrontier() (common.Address, error) { return self.from, nil }
func (self Message) To() *common.Address { return self.to }
func (self Message) GasPrice() *big.Int { return self.price }
func (self Message) Gas() *big.Int { return self.gas }
func (self Message) Value() *big.Int { return self.value }
func (self Message) Nonce() uint64 { return self.nonce }
func (self Message) CheckNonce() bool { return true }
func (self Message) Data() []byte { return self.data }