openethereum/ethcore/src/evm/jit.rs

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// Copyright 2015-2017 Parity Technologies (UK) Ltd.
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// This file is part of Parity.
// Parity is free software: you can redistribute it and/or modify
// it under the terms of the GNU General Public License as published by
// the Free Software Foundation, either version 3 of the License, or
// (at your option) any later version.
// Parity 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 General Public License for more details.
// You should have received a copy of the GNU General Public License
// along with Parity. If not, see <http://www.gnu.org/licenses/>.
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//! Just in time compiler execution environment.
use util::*;
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use evmjit;
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use evm::{self, GasLeft};
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use types::executed::CallType;
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/// Should be used to convert jit types to ethcore
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trait FromJit<T>: Sized {
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fn from_jit(input: T) -> Self;
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}
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/// Should be used to covert ethcore types to jit
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trait IntoJit<T> {
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fn into_jit(self) -> T;
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}
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impl<'a> FromJit<&'a evmjit::I256> for U256 {
fn from_jit(input: &'a evmjit::I256) -> Self {
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unsafe {
let mut res: U256 = mem::uninitialized();
ptr::copy(input.words.as_ptr(), res.0.as_mut_ptr(), 4);
res
}
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}
}
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impl<'a> FromJit<&'a evmjit::I256> for H256 {
fn from_jit(input: &'a evmjit::I256) -> Self {
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let u = U256::from_jit(input);
H256::from(&u)
}
}
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impl<'a> FromJit<&'a evmjit::I256> for Address {
fn from_jit(input: &'a evmjit::I256) -> Self {
Address::from(H256::from_jit(input))
}
}
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impl<'a> FromJit<&'a evmjit::H256> for H256 {
fn from_jit(input: &'a evmjit::H256) -> Self {
H256::from_jit(&evmjit::I256::from(input.clone()))
}
}
impl<'a> FromJit<&'a evmjit::H256> for Address {
fn from_jit(input: &'a evmjit::H256) -> Self {
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Address::from(H256::from_jit(input))
}
}
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impl IntoJit<evmjit::I256> for U256 {
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fn into_jit(self) -> evmjit::I256 {
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unsafe {
let mut res: evmjit::I256 = mem::uninitialized();
ptr::copy(self.0.as_ptr(), res.words.as_mut_ptr(), 4);
res
}
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}
}
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impl IntoJit<evmjit::I256> for H256 {
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fn into_jit(self) -> evmjit::I256 {
let mut ret = [0; 4];
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let len = self.len();
for i in 0..len {
let rev = len - 1 - i;
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let pos = rev / 8;
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ret[pos] += (self[i] as u64) << ((rev % 8) * 8);
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}
evmjit::I256 { words: ret }
}
}
impl IntoJit<evmjit::H256> for H256 {
fn into_jit(self) -> evmjit::H256 {
let i: evmjit::I256 = self.into_jit();
From::from(i)
}
}
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impl IntoJit<evmjit::I256> for Address {
fn into_jit(self) -> evmjit::I256 {
H256::from(self).into_jit()
}
}
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impl IntoJit<evmjit::H256> for Address {
fn into_jit(self) -> evmjit::H256 {
H256::from(self).into_jit()
}
}
/// Externalities adapter. Maps callbacks from evmjit to externalities trait.
///
/// Evmjit doesn't have to know about children execution failures.
/// This adapter 'catches' them and moves upstream.
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struct ExtAdapter<'a> {
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ext: &'a mut evm::Ext,
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address: Address
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}
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impl<'a> ExtAdapter<'a> {
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fn new(ext: &'a mut evm::Ext, address: Address) -> Self {
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ExtAdapter {
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ext: ext,
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address: address
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}
}
}
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impl<'a> evmjit::Ext for ExtAdapter<'a> {
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fn sload(&self, key: *const evmjit::I256, out_value: *mut evmjit::I256) {
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unsafe {
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let i = H256::from_jit(&*key);
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let o = self.ext.storage_at(&i);
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*out_value = o.into_jit();
}
}
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fn sstore(&mut self, key: *const evmjit::I256, value: *const evmjit::I256) {
let key = unsafe { H256::from_jit(&*key) };
let value = unsafe { H256::from_jit(&*value) };
let old_value = self.ext.storage_at(&key);
// if SSTORE nonzero -> zero, increment refund count
if !old_value.is_zero() && value.is_zero() {
self.ext.inc_sstore_clears();
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}
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self.ext.set_storage(key, value);
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}
fn balance(&self, address: *const evmjit::H256, out_value: *mut evmjit::I256) {
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unsafe {
let a = Address::from_jit(&*address);
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let o = self.ext.balance(&a);
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*out_value = o.into_jit();
}
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}
fn blockhash(&self, number: *const evmjit::I256, out_hash: *mut evmjit::H256) {
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unsafe {
let n = U256::from_jit(&*number);
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let o = self.ext.blockhash(&n);
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*out_hash = o.into_jit();
}
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}
fn create(&mut self,
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io_gas: *mut u64,
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value: *const evmjit::I256,
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init_beg: *const u8,
init_size: u64,
address: *mut evmjit::H256) {
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let gas = unsafe { U256::from(*io_gas) };
let value = unsafe { U256::from_jit(&*value) };
let code = unsafe { slice::from_raw_parts(init_beg, init_size as usize) };
// check if balance is sufficient and we are not too deep
if self.ext.balance(&self.address) >= value && self.ext.depth() < self.ext.schedule().max_depth {
match self.ext.create(&gas, &value, code) {
evm::ContractCreateResult::Created(new_address, gas_left) => unsafe {
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*address = new_address.into_jit();
*io_gas = gas_left.low_u64();
},
evm::ContractCreateResult::Failed => unsafe {
*address = Address::new().into_jit();
*io_gas = 0;
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}
}
} else {
unsafe { *address = Address::new().into_jit(); }
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}
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}
fn call(&mut self,
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io_gas: *mut u64,
call_gas: u64,
sender_address: *const evmjit::H256,
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receive_address: *const evmjit::H256,
code_address: *const evmjit::H256,
transfer_value: *const evmjit::I256,
// We are ignoring apparent value - it's handled in externalities.
_apparent_value: *const evmjit::I256,
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in_beg: *const u8,
in_size: u64,
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out_beg: *mut u8,
out_size: u64) -> bool {
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let mut gas = unsafe { U256::from(*io_gas) };
let mut call_gas = U256::from(call_gas);
let mut gas_cost = call_gas;
let sender_address = unsafe { Address::from_jit(&*sender_address) };
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let receive_address = unsafe { Address::from_jit(&*receive_address) };
let code_address = unsafe { Address::from_jit(&*code_address) };
let transfer_value = unsafe { U256::from_jit(&*transfer_value) };
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// receive address and code address are the same in normal calls
let is_callcode = receive_address != code_address;
let is_delegatecall = is_callcode && sender_address != receive_address;
let value = if is_delegatecall { None } else { Some(transfer_value) };
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if !is_callcode && !self.ext.exists(&code_address) {
gas_cost = gas_cost + U256::from(self.ext.schedule().call_new_account_gas);
}
if transfer_value > U256::zero() {
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assert!(self.ext.schedule().call_value_transfer_gas > self.ext.schedule().call_stipend, "overflow possible");
gas_cost = gas_cost + U256::from(self.ext.schedule().call_value_transfer_gas);
call_gas = call_gas + U256::from(self.ext.schedule().call_stipend);
}
if gas_cost > gas {
unsafe {
*io_gas = -1i64 as u64;
return false;
}
}
gas = gas - gas_cost;
// check if balance is sufficient and we are not too deep
if self.ext.balance(&self.address) < transfer_value || self.ext.depth() >= self.ext.schedule().max_depth {
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unsafe {
*io_gas = (gas + call_gas).low_u64();
return false;
}
}
let call_type = match (is_callcode, is_delegatecall) {
(_, true) => CallType::DelegateCall,
(true, false) => CallType::CallCode,
(false, false) => CallType::Call,
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};
match self.ext.call(
&call_gas,
&sender_address,
&receive_address,
value,
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unsafe { slice::from_raw_parts(in_beg, in_size as usize) },
&code_address,
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unsafe { slice::from_raw_parts_mut(out_beg, out_size as usize) },
call_type,
) {
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evm::MessageCallResult::Success(gas_left) => unsafe {
*io_gas = (gas + gas_left).low_u64();
true
},
evm::MessageCallResult::Failed => unsafe {
*io_gas = gas.low_u64();
false
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}
}
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}
fn log(&mut self,
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beg: *const u8,
size: u64,
topic1: *const evmjit::H256,
topic2: *const evmjit::H256,
topic3: *const evmjit::H256,
topic4: *const evmjit::H256) {
unsafe {
let mut topics = vec![];
if !topic1.is_null() {
topics.push(H256::from_jit(&*topic1));
}
if !topic2.is_null() {
topics.push(H256::from_jit(&*topic2));
}
if !topic3.is_null() {
topics.push(H256::from_jit(&*topic3));
}
if !topic4.is_null() {
topics.push(H256::from_jit(&*topic4));
}
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let bytes_ref: &[u8] = slice::from_raw_parts(beg, size as usize);
self.ext.log(topics, bytes_ref);
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}
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}
fn extcode(&self, address: *const evmjit::H256, size: *mut u64) -> *const u8 {
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unsafe {
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let code = self.ext.extcode(&Address::from_jit(&*address));
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*size = code.len() as u64;
let ptr = code.as_ptr();
mem::forget(code);
ptr
}
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}
}
#[derive(Default)]
pub struct JitEvm {
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context: Option<evmjit::ContextHandle>,
}
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impl evm::Evm for JitEvm {
fn exec(&mut self, params: ActionParams, ext: &mut evm::Ext) -> evm::Result<GasLeft> {
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// Dirty hack. This is unsafe, but we interact with ffi, so it's justified.
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let ext_adapter: ExtAdapter<'static> = unsafe { ::std::mem::transmute(ExtAdapter::new(ext, params.address.clone())) };
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let mut ext_handle = evmjit::ExtHandle::new(ext_adapter);
assert!(params.gas <= U256::from(i64::max_value() as u64), "evmjit max gas is 2 ^ 63");
assert!(params.gas_price <= U256::from(i64::max_value() as u64), "evmjit max gas is 2 ^ 63");
let call_data = params.data.unwrap_or_else(Vec::new);
let code = params.code.unwrap_or_else(Vec::new);
let mut data = evmjit::RuntimeDataHandle::new();
data.gas = params.gas.low_u64() as i64;
data.gas_price = params.gas_price.low_u64() as i64;
data.call_data = call_data.as_ptr();
data.call_data_size = call_data.len() as u64;
mem::forget(call_data);
data.code = code.as_ptr();
data.code_size = code.len() as u64;
data.code_hash = code.sha3().into_jit();
mem::forget(code);
data.address = params.address.into_jit();
data.caller = params.sender.into_jit();
data.origin = params.origin.into_jit();
data.transfer_value = match params.value {
ActionValue::Transfer(val) => val.into_jit(),
ActionValue::Apparent(val) => val.into_jit()
};
data.apparent_value = data.transfer_value;
let mut schedule = evmjit::ScheduleHandle::new();
schedule.have_delegate_call = ext.schedule().have_delegate_call;
data.author = ext.env_info().author.clone().into_jit();
data.difficulty = ext.env_info().difficulty.into_jit();
data.gas_limit = ext.env_info().gas_limit.into_jit();
data.number = ext.env_info().number;
// don't really know why jit timestamp is int..
data.timestamp = ext.env_info().timestamp as i64;
self.context = Some(unsafe { evmjit::ContextHandle::new(data, schedule, &mut ext_handle) });
let mut context = self.context.as_mut().expect("context handle set on the prior line; qed");
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let res = context.exec();
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match res {
evmjit::ReturnCode::Stop => Ok(GasLeft::Known(U256::from(context.gas_left()))),
evmjit::ReturnCode::Return =>
Ok(GasLeft::NeedsReturn(U256::from(context.gas_left()), context.output_data())),
evmjit::ReturnCode::Suicide => {
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ext.suicide(&Address::from_jit(&context.suicide_refund_address()));
Ok(GasLeft::Known(U256::from(context.gas_left())))
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},
evmjit::ReturnCode::OutOfGas => Err(evm::Error::OutOfGas),
_err => Err(evm::Error::Internal)
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}
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}
}
#[test]
fn test_to_and_from_u256() {
let u = U256::from_str("d4e56740f876aef8c010b86a40d5f56745a118d0906a34e69aec8c0db1cb8fa3").unwrap();
let j = u.into_jit();
let u2 = U256::from_jit(&j);
assert_eq!(u, u2);
}
#[test]
fn test_to_and_from_h256() {
let h = H256::from_str("d4e56740f876aef8c010b86a40d5f56745a118d0906a34e69aec8c0db1cb8fa3").unwrap();
let j: ::evmjit::I256 = h.clone().into_jit();
let h2 = H256::from_jit(&j);
assert_eq!(h, h2);
let j: ::evmjit::H256 = h.clone().into_jit();
let h2 = H256::from_jit(&j);
assert_eq!(h, h2);
}
#[test]
fn test_to_and_from_address() {
let a = Address::from_str("2adc25665018aa1fe0e6bc666dac8fc2697ff9ba").unwrap();
let j: ::evmjit::I256 = a.clone().into_jit();
let a2 = Address::from_jit(&j);
assert_eq!(a, a2);
let j: ::evmjit::H256 = a.clone().into_jit();
let a2 = Address::from_jit(&j);
assert_eq!(a, a2);
}