// make push instruction function
func makePush(size uint64, bsize *big.Int) instrFn {
return func(instr instruction, pc *uint64, env Environment, contract *Contract, memory *Memory, stack *stack) {
byts := getData(contract.Code, new(big.Int).SetUint64(*pc+1), bsize)
stack.push(common.Bytes2Big(byts))
*pc += size
}
}
func ecrecoverFunc(in []byte) []byte {
in = common.RightPadBytes(in, 128)
// "in" is (hash, v, r, s), each 32 bytes
// but for ecrecover we want (r, s, v)
r := common.BytesToBig(in[64:96])
s := common.BytesToBig(in[96:128])
// Treat V as a 256bit integer
vbig := common.Bytes2Big(in[32:64])
v := byte(vbig.Uint64())
if !crypto.ValidateSignatureValues(v, r, s) {
glog.V(logger.Debug).Infof("EC RECOVER FAIL: v, r or s value invalid")
return nil
}
// v needs to be at the end and normalized for libsecp256k1
vbignormal := new(big.Int).Sub(vbig, big.NewInt(27))
vnormal := byte(vbignormal.Uint64())
rsv := append(in[64:128], vnormal)
pubKey, err := crypto.Ecrecover(in[:32], rsv)
// make sure the public key is a valid one
if err != nil {
glog.V(logger.Error).Infof("EC RECOVER FAIL: ", err)
return nil
}
// the first byte of pubkey is bitcoin heritage
return common.LeftPadBytes(crypto.Sha3(pubKey[1:])[12:], 32)
}
func (b Bloom) Big() *big.Int {
return common.Bytes2Big(b[:])
}
func opCalldataLoad(instr instruction, env Environment, context *Context, memory *Memory, stack *stack) {
stack.push(common.Bytes2Big(getData(context.Input, stack.pop(), common.Big32)))
}
func opCaller(instr instruction, env Environment, context *Context, memory *Memory, stack *stack) {
stack.push(common.Bytes2Big(context.caller.Address().Bytes()))
}
func opAddress(instr instruction, pc *uint64, env Environment, contract *Contract, memory *Memory, stack *stack) {
stack.push(common.Bytes2Big(contract.Address().Bytes()))
}
// CompileProgram compiles the given program and return an error when it fails
func CompileProgram(program *Program) (err error) {
if progStatus(atomic.LoadInt32(&program.status)) == progCompile {
return nil
}
atomic.StoreInt32(&program.status, int32(progCompile))
defer func() {
if err != nil {
atomic.StoreInt32(&program.status, int32(progError))
} else {
atomic.StoreInt32(&program.status, int32(progReady))
}
}()
if glog.V(logger.Debug) {
glog.Infof("compiling %x\n", program.Id[:4])
tstart := time.Now()
defer func() {
glog.Infof("compiled %x instrc: %d time: %v\n", program.Id[:4], len(program.instructions), time.Since(tstart))
}()
}
// loop thru the opcodes and "compile" in to instructions
for pc := uint64(0); pc < uint64(len(program.code)); pc++ {
switch op := OpCode(program.code[pc]); op {
case ADD:
program.addInstr(op, pc, opAdd, nil)
case SUB:
program.addInstr(op, pc, opSub, nil)
case MUL:
program.addInstr(op, pc, opMul, nil)
case DIV:
program.addInstr(op, pc, opDiv, nil)
case SDIV:
program.addInstr(op, pc, opSdiv, nil)
case MOD:
program.addInstr(op, pc, opMod, nil)
case SMOD:
program.addInstr(op, pc, opSmod, nil)
case EXP:
program.addInstr(op, pc, opExp, nil)
case SIGNEXTEND:
program.addInstr(op, pc, opSignExtend, nil)
case NOT:
program.addInstr(op, pc, opNot, nil)
case LT:
program.addInstr(op, pc, opLt, nil)
case GT:
program.addInstr(op, pc, opGt, nil)
case SLT:
program.addInstr(op, pc, opSlt, nil)
case SGT:
program.addInstr(op, pc, opSgt, nil)
case EQ:
program.addInstr(op, pc, opEq, nil)
case ISZERO:
program.addInstr(op, pc, opIszero, nil)
case AND:
program.addInstr(op, pc, opAnd, nil)
case OR:
program.addInstr(op, pc, opOr, nil)
case XOR:
program.addInstr(op, pc, opXor, nil)
case BYTE:
program.addInstr(op, pc, opByte, nil)
case ADDMOD:
program.addInstr(op, pc, opAddmod, nil)
case MULMOD:
program.addInstr(op, pc, opMulmod, nil)
case SHA3:
program.addInstr(op, pc, opSha3, nil)
case ADDRESS:
program.addInstr(op, pc, opAddress, nil)
case BALANCE:
program.addInstr(op, pc, opBalance, nil)
case ORIGIN:
program.addInstr(op, pc, opOrigin, nil)
case CALLER:
program.addInstr(op, pc, opCaller, nil)
case CALLVALUE:
program.addInstr(op, pc, opCallValue, nil)
case CALLDATALOAD:
program.addInstr(op, pc, opCalldataLoad, nil)
case CALLDATASIZE:
program.addInstr(op, pc, opCalldataSize, nil)
case CALLDATACOPY:
program.addInstr(op, pc, opCalldataCopy, nil)
case CODESIZE:
program.addInstr(op, pc, opCodeSize, nil)
case EXTCODESIZE:
program.addInstr(op, pc, opExtCodeSize, nil)
case CODECOPY:
program.addInstr(op, pc, opCodeCopy, nil)
case EXTCODECOPY:
program.addInstr(op, pc, opExtCodeCopy, nil)
case GASPRICE:
program.addInstr(op, pc, opGasprice, nil)
case BLOCKHASH:
program.addInstr(op, pc, opBlockhash, nil)
case COINBASE:
program.addInstr(op, pc, opCoinbase, nil)
case TIMESTAMP:
program.addInstr(op, pc, opTimestamp, nil)
case NUMBER:
program.addInstr(op, pc, opNumber, nil)
case DIFFICULTY:
program.addInstr(op, pc, opDifficulty, nil)
case GASLIMIT:
program.addInstr(op, pc, opGasLimit, nil)
case PUSH1, PUSH2, PUSH3, PUSH4, PUSH5, PUSH6, PUSH7, PUSH8, PUSH9, PUSH10, PUSH11, PUSH12, PUSH13, PUSH14, PUSH15, PUSH16, PUSH17, PUSH18, PUSH19, PUSH20, PUSH21, PUSH22, PUSH23, PUSH24, PUSH25, PUSH26, PUSH27, PUSH28, PUSH29, PUSH30, PUSH31, PUSH32:
size := uint64(op - PUSH1 + 1)
bytes := getData([]byte(program.code), new(big.Int).SetUint64(pc+1), new(big.Int).SetUint64(size))
program.addInstr(op, pc, opPush, common.Bytes2Big(bytes))
pc += size
case POP:
program.addInstr(op, pc, opPop, nil)
case DUP1, DUP2, DUP3, DUP4, DUP5, DUP6, DUP7, DUP8, DUP9, DUP10, DUP11, DUP12, DUP13, DUP14, DUP15, DUP16:
program.addInstr(op, pc, opDup, big.NewInt(int64(op-DUP1+1)))
case SWAP1, SWAP2, SWAP3, SWAP4, SWAP5, SWAP6, SWAP7, SWAP8, SWAP9, SWAP10, SWAP11, SWAP12, SWAP13, SWAP14, SWAP15, SWAP16:
program.addInstr(op, pc, opSwap, big.NewInt(int64(op-SWAP1+2)))
case LOG0, LOG1, LOG2, LOG3, LOG4:
program.addInstr(op, pc, opLog, big.NewInt(int64(op-LOG0)))
case MLOAD:
program.addInstr(op, pc, opMload, nil)
case MSTORE:
program.addInstr(op, pc, opMstore, nil)
case MSTORE8:
program.addInstr(op, pc, opMstore8, nil)
case SLOAD:
program.addInstr(op, pc, opSload, nil)
case SSTORE:
program.addInstr(op, pc, opSstore, nil)
case JUMP:
program.addInstr(op, pc, opJump, nil)
case JUMPI:
program.addInstr(op, pc, opJumpi, nil)
case JUMPDEST:
program.addInstr(op, pc, opJumpdest, nil)
program.destinations[pc] = struct{}{}
case PC:
program.addInstr(op, pc, opPc, big.NewInt(int64(pc)))
case MSIZE:
program.addInstr(op, pc, opMsize, nil)
case GAS:
program.addInstr(op, pc, opGas, nil)
case CREATE:
program.addInstr(op, pc, opCreate, nil)
case DELEGATECALL:
// Instruction added regardless of homestead phase.
// Homestead (and execution of the opcode) is checked during
// runtime.
program.addInstr(op, pc, opDelegateCall, nil)
case CALL:
program.addInstr(op, pc, opCall, nil)
case CALLCODE:
program.addInstr(op, pc, opCallCode, nil)
case RETURN:
program.addInstr(op, pc, opReturn, nil)
case SUICIDE:
program.addInstr(op, pc, opSuicide, nil)
case STOP: // Stop the contract
program.addInstr(op, pc, opStop, nil)
default:
program.addInstr(op, pc, nil, nil)
}
}
optimiseProgram(program)
return nil
}
// Run loops and evaluates the contract's code with the given input data
func (self *Vm) Run(context *Context, input []byte) (ret []byte, err error) {
self.env.SetDepth(self.env.Depth() + 1)
defer self.env.SetDepth(self.env.Depth() - 1)
// User defer pattern to check for an error and, based on the error being nil or not, use all gas and return.
defer func() {
if err != nil {
// In case of a VM exception (known exceptions) all gas consumed (panics NOT included).
context.UseGas(context.Gas)
ret = context.Return(nil)
}
}()
if context.CodeAddr != nil {
if p := Precompiled[context.CodeAddr.Str()]; p != nil {
return self.RunPrecompiled(p, input, context)
}
}
var (
codehash = crypto.Sha3Hash(context.Code) // codehash is used when doing jump dest caching
program *Program
)
if EnableJit {
// Fetch program status.
// * If ready run using JIT
// * If unknown, compile in a seperate goroutine
// * If forced wait for compilation and run once done
if status := GetProgramStatus(codehash); status == progReady {
return RunProgram(GetProgram(codehash), self.env, context, input)
} else if status == progUnknown {
if ForceJit {
// Create and compile program
program = NewProgram(context.Code)
perr := CompileProgram(program)
if perr == nil {
return RunProgram(program, self.env, context, input)
}
glog.V(logger.Info).Infoln("error compiling program", err)
} else {
// create and compile the program. Compilation
// is done in a seperate goroutine
program = NewProgram(context.Code)
go func() {
err := CompileProgram(program)
if err != nil {
glog.V(logger.Info).Infoln("error compiling program", err)
return
}
}()
}
}
}
var (
caller = context.caller
code = context.Code
value = context.value
price = context.Price
op OpCode // current opcode
mem = NewMemory() // bound memory
stack = newstack() // local stack
statedb = self.env.State() // current state
// For optimisation reason we're using uint64 as the program counter.
// It's theoretically possible to go above 2^64. The YP defines the PC to be uint256. Pratically much less so feasible.
pc = uint64(0) // program counter
// jump evaluates and checks whether the given jump destination is a valid one
// if valid move the `pc` otherwise return an error.
jump = func(from uint64, to *big.Int) error {
if !context.jumpdests.has(codehash, code, to) {
nop := context.GetOp(to.Uint64())
return fmt.Errorf("invalid jump destination (%v) %v", nop, to)
}
pc = to.Uint64()
return nil
}
newMemSize *big.Int
cost *big.Int
)
// User defer pattern to check for an error and, based on the error being nil or not, use all gas and return.
defer func() {
if err != nil {
self.log(pc, op, context.Gas, cost, mem, stack, context, err)
}
}()
// Don't bother with the execution if there's no code.
if len(code) == 0 {
return context.Return(nil), nil
}
for {
// Overhead of the atomic read might not be worth it
/* TODO this still causes a few issues in the tests
if program != nil && progStatus(atomic.LoadInt32(&program.status)) == progReady {
// move execution
glog.V(logger.Info).Infoln("Moved execution to JIT")
return runProgram(program, pc, mem, stack, self.env, context, input)
}
*/
// The base for all big integer arithmetic
base := new(big.Int)
// Get the memory location of pc
op = context.GetOp(pc)
// calculate the new memory size and gas price for the current executing opcode
newMemSize, cost, err = calculateGasAndSize(self.env, context, caller, op, statedb, mem, stack)
if err != nil {
return nil, err
}
// Use the calculated gas. When insufficient gas is present, use all gas and return an
// Out Of Gas error
if !context.UseGas(cost) {
return nil, OutOfGasError
}
// Resize the memory calculated previously
mem.Resize(newMemSize.Uint64())
// Add a log message
self.log(pc, op, context.Gas, cost, mem, stack, context, nil)
switch op {
case ADD:
x, y := stack.pop(), stack.pop()
base.Add(x, y)
U256(base)
// pop result back on the stack
stack.push(base)
case SUB:
x, y := stack.pop(), stack.pop()
base.Sub(x, y)
U256(base)
// pop result back on the stack
stack.push(base)
case MUL:
x, y := stack.pop(), stack.pop()
base.Mul(x, y)
U256(base)
// pop result back on the stack
stack.push(base)
case DIV:
x, y := stack.pop(), stack.pop()
if y.Cmp(common.Big0) != 0 {
base.Div(x, y)
}
U256(base)
// pop result back on the stack
stack.push(base)
case SDIV:
x, y := S256(stack.pop()), S256(stack.pop())
if y.Cmp(common.Big0) == 0 {
base.Set(common.Big0)
} else {
n := new(big.Int)
if new(big.Int).Mul(x, y).Cmp(common.Big0) < 0 {
n.SetInt64(-1)
} else {
n.SetInt64(1)
}
base.Div(x.Abs(x), y.Abs(y)).Mul(base, n)
U256(base)
}
stack.push(base)
case MOD:
x, y := stack.pop(), stack.pop()
if y.Cmp(common.Big0) == 0 {
base.Set(common.Big0)
} else {
base.Mod(x, y)
}
U256(base)
stack.push(base)
case SMOD:
x, y := S256(stack.pop()), S256(stack.pop())
if y.Cmp(common.Big0) == 0 {
base.Set(common.Big0)
} else {
n := new(big.Int)
if x.Cmp(common.Big0) < 0 {
n.SetInt64(-1)
} else {
n.SetInt64(1)
}
base.Mod(x.Abs(x), y.Abs(y)).Mul(base, n)
U256(base)
}
stack.push(base)
case EXP:
x, y := stack.pop(), stack.pop()
base.Exp(x, y, Pow256)
U256(base)
stack.push(base)
case SIGNEXTEND:
back := stack.pop()
if back.Cmp(big.NewInt(31)) < 0 {
bit := uint(back.Uint64()*8 + 7)
num := stack.pop()
mask := new(big.Int).Lsh(common.Big1, bit)
mask.Sub(mask, common.Big1)
if common.BitTest(num, int(bit)) {
num.Or(num, mask.Not(mask))
} else {
num.And(num, mask)
}
num = U256(num)
stack.push(num)
}
case NOT:
stack.push(U256(new(big.Int).Not(stack.pop())))
case LT:
x, y := stack.pop(), stack.pop()
// x < y
if x.Cmp(y) < 0 {
stack.push(common.BigTrue)
} else {
stack.push(common.BigFalse)
}
case GT:
x, y := stack.pop(), stack.pop()
// x > y
if x.Cmp(y) > 0 {
stack.push(common.BigTrue)
} else {
stack.push(common.BigFalse)
}
case SLT:
x, y := S256(stack.pop()), S256(stack.pop())
// x < y
if x.Cmp(S256(y)) < 0 {
stack.push(common.BigTrue)
} else {
stack.push(common.BigFalse)
}
case SGT:
x, y := S256(stack.pop()), S256(stack.pop())
// x > y
if x.Cmp(y) > 0 {
stack.push(common.BigTrue)
} else {
stack.push(common.BigFalse)
}
case EQ:
x, y := stack.pop(), stack.pop()
// x == y
if x.Cmp(y) == 0 {
stack.push(common.BigTrue)
} else {
stack.push(common.BigFalse)
}
case ISZERO:
x := stack.pop()
if x.Cmp(common.BigFalse) > 0 {
stack.push(common.BigFalse)
} else {
stack.push(common.BigTrue)
}
case AND:
x, y := stack.pop(), stack.pop()
stack.push(base.And(x, y))
case OR:
x, y := stack.pop(), stack.pop()
stack.push(base.Or(x, y))
case XOR:
x, y := stack.pop(), stack.pop()
stack.push(base.Xor(x, y))
case BYTE:
th, val := stack.pop(), stack.pop()
if th.Cmp(big.NewInt(32)) < 0 {
byt := big.NewInt(int64(common.LeftPadBytes(val.Bytes(), 32)[th.Int64()]))
base.Set(byt)
} else {
base.Set(common.BigFalse)
}
stack.push(base)
case ADDMOD:
x := stack.pop()
y := stack.pop()
z := stack.pop()
if z.Cmp(Zero) > 0 {
add := new(big.Int).Add(x, y)
base.Mod(add, z)
base = U256(base)
}
stack.push(base)
case MULMOD:
x := stack.pop()
y := stack.pop()
z := stack.pop()
if z.Cmp(Zero) > 0 {
mul := new(big.Int).Mul(x, y)
base.Mod(mul, z)
U256(base)
}
stack.push(base)
case SHA3:
offset, size := stack.pop(), stack.pop()
data := crypto.Sha3(mem.Get(offset.Int64(), size.Int64()))
stack.push(common.BigD(data))
case ADDRESS:
stack.push(common.Bytes2Big(context.Address().Bytes()))
case BALANCE:
addr := common.BigToAddress(stack.pop())
balance := statedb.GetBalance(addr)
stack.push(new(big.Int).Set(balance))
case ORIGIN:
origin := self.env.Origin()
stack.push(origin.Big())
case CALLER:
caller := context.caller.Address()
stack.push(common.Bytes2Big(caller.Bytes()))
case CALLVALUE:
stack.push(new(big.Int).Set(value))
case CALLDATALOAD:
data := getData(input, stack.pop(), common.Big32)
stack.push(common.Bytes2Big(data))
case CALLDATASIZE:
l := int64(len(input))
stack.push(big.NewInt(l))
case CALLDATACOPY:
var (
mOff = stack.pop()
cOff = stack.pop()
l = stack.pop()
)
data := getData(input, cOff, l)
mem.Set(mOff.Uint64(), l.Uint64(), data)
case CODESIZE, EXTCODESIZE:
var code []byte
if op == EXTCODESIZE {
addr := common.BigToAddress(stack.pop())
code = statedb.GetCode(addr)
} else {
code = context.Code
}
l := big.NewInt(int64(len(code)))
stack.push(l)
case CODECOPY, EXTCODECOPY:
var code []byte
if op == EXTCODECOPY {
addr := common.BigToAddress(stack.pop())
code = statedb.GetCode(addr)
} else {
code = context.Code
}
var (
mOff = stack.pop()
cOff = stack.pop()
l = stack.pop()
)
codeCopy := getData(code, cOff, l)
mem.Set(mOff.Uint64(), l.Uint64(), codeCopy)
case GASPRICE:
stack.push(new(big.Int).Set(context.Price))
case BLOCKHASH:
num := stack.pop()
n := new(big.Int).Sub(self.env.BlockNumber(), common.Big257)
if num.Cmp(n) > 0 && num.Cmp(self.env.BlockNumber()) < 0 {
stack.push(self.env.GetHash(num.Uint64()).Big())
} else {
stack.push(common.Big0)
}
case COINBASE:
coinbase := self.env.Coinbase()
stack.push(coinbase.Big())
case TIMESTAMP:
time := self.env.Time()
stack.push(new(big.Int).Set(time))
case NUMBER:
number := self.env.BlockNumber()
stack.push(U256(number))
case DIFFICULTY:
difficulty := self.env.Difficulty()
stack.push(new(big.Int).Set(difficulty))
case GASLIMIT:
stack.push(new(big.Int).Set(self.env.GasLimit()))
case PUSH1, PUSH2, PUSH3, PUSH4, PUSH5, PUSH6, PUSH7, PUSH8, PUSH9, PUSH10, PUSH11, PUSH12, PUSH13, PUSH14, PUSH15, PUSH16, PUSH17, PUSH18, PUSH19, PUSH20, PUSH21, PUSH22, PUSH23, PUSH24, PUSH25, PUSH26, PUSH27, PUSH28, PUSH29, PUSH30, PUSH31, PUSH32:
size := uint64(op - PUSH1 + 1)
byts := getData(code, new(big.Int).SetUint64(pc+1), new(big.Int).SetUint64(size))
// push value to stack
stack.push(common.Bytes2Big(byts))
pc += size
case POP:
stack.pop()
case DUP1, DUP2, DUP3, DUP4, DUP5, DUP6, DUP7, DUP8, DUP9, DUP10, DUP11, DUP12, DUP13, DUP14, DUP15, DUP16:
n := int(op - DUP1 + 1)
stack.dup(n)
case SWAP1, SWAP2, SWAP3, SWAP4, SWAP5, SWAP6, SWAP7, SWAP8, SWAP9, SWAP10, SWAP11, SWAP12, SWAP13, SWAP14, SWAP15, SWAP16:
n := int(op - SWAP1 + 2)
stack.swap(n)
case LOG0, LOG1, LOG2, LOG3, LOG4:
n := int(op - LOG0)
topics := make([]common.Hash, n)
mStart, mSize := stack.pop(), stack.pop()
for i := 0; i < n; i++ {
topics[i] = common.BigToHash(stack.pop())
}
data := mem.Get(mStart.Int64(), mSize.Int64())
log := state.NewLog(context.Address(), topics, data, self.env.BlockNumber().Uint64())
self.env.AddLog(log)
case MLOAD:
offset := stack.pop()
val := common.BigD(mem.Get(offset.Int64(), 32))
stack.push(val)
case MSTORE:
// pop value of the stack
mStart, val := stack.pop(), stack.pop()
mem.Set(mStart.Uint64(), 32, common.BigToBytes(val, 256))
case MSTORE8:
off, val := stack.pop().Int64(), stack.pop().Int64()
mem.store[off] = byte(val & 0xff)
case SLOAD:
loc := common.BigToHash(stack.pop())
val := statedb.GetState(context.Address(), loc).Big()
stack.push(val)
case SSTORE:
loc := common.BigToHash(stack.pop())
val := stack.pop()
statedb.SetState(context.Address(), loc, common.BigToHash(val))
case JUMP:
if err := jump(pc, stack.pop()); err != nil {
return nil, err
}
continue
case JUMPI:
pos, cond := stack.pop(), stack.pop()
if cond.Cmp(common.BigTrue) >= 0 {
if err := jump(pc, pos); err != nil {
return nil, err
}
continue
}
case JUMPDEST:
case PC:
stack.push(new(big.Int).SetUint64(pc))
case MSIZE:
stack.push(big.NewInt(int64(mem.Len())))
case GAS:
stack.push(new(big.Int).Set(context.Gas))
case CREATE:
var (
value = stack.pop()
offset, size = stack.pop(), stack.pop()
input = mem.Get(offset.Int64(), size.Int64())
gas = new(big.Int).Set(context.Gas)
addr common.Address
)
context.UseGas(context.Gas)
ret, suberr, ref := self.env.Create(context, input, gas, price, value)
if suberr != nil {
stack.push(common.BigFalse)
} else {
// gas < len(ret) * CreateDataGas == NO_CODE
dataGas := big.NewInt(int64(len(ret)))
dataGas.Mul(dataGas, params.CreateDataGas)
if context.UseGas(dataGas) {
ref.SetCode(ret)
}
addr = ref.Address()
stack.push(addr.Big())
}
case CALL, CALLCODE:
gas := stack.pop()
// pop gas and value of the stack.
addr, value := stack.pop(), stack.pop()
value = U256(value)
// pop input size and offset
inOffset, inSize := stack.pop(), stack.pop()
// pop return size and offset
retOffset, retSize := stack.pop(), stack.pop()
address := common.BigToAddress(addr)
// Get the arguments from the memory
args := mem.Get(inOffset.Int64(), inSize.Int64())
if len(value.Bytes()) > 0 {
gas.Add(gas, params.CallStipend)
}
var (
ret []byte
err error
)
if op == CALLCODE {
ret, err = self.env.CallCode(context, address, args, gas, price, value)
} else {
ret, err = self.env.Call(context, address, args, gas, price, value)
}
if err != nil {
stack.push(common.BigFalse)
} else {
stack.push(common.BigTrue)
mem.Set(retOffset.Uint64(), retSize.Uint64(), ret)
}
case RETURN:
offset, size := stack.pop(), stack.pop()
ret := mem.GetPtr(offset.Int64(), size.Int64())
return context.Return(ret), nil
case SUICIDE:
receiver := statedb.GetOrNewStateObject(common.BigToAddress(stack.pop()))
balance := statedb.GetBalance(context.Address())
receiver.AddBalance(balance)
statedb.Delete(context.Address())
fallthrough
case STOP: // Stop the context
return context.Return(nil), nil
default:
return nil, fmt.Errorf("Invalid opcode %x", op)
}
pc++
}
}