openethereum/ethcore/evm/src/evm.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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//! Evm interface.
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use std::{ops, cmp, fmt};
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use bigint::prelude::{U128, U256, U512};
use vm::{Ext, Result, ReturnData, GasLeft, Error};
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/// Finalization result. Gas Left: either it is a known value, or it needs to be computed by processing
/// a return instruction.
#[derive(Debug)]
pub struct FinalizationResult {
/// Final amount of gas left.
pub gas_left: U256,
/// Apply execution state changes or revert them.
pub apply_state: bool,
/// Return data buffer.
pub return_data: ReturnData,
}
/// Types that can be "finalized" using an EVM.
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///
/// In practice, this is just used to define an inherent impl on
/// `Reult<GasLeft<'a>>`.
pub trait Finalize {
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/// Consume the externalities, call return if necessary, and produce call result.
fn finalize<E: Ext>(self, ext: E) -> Result<FinalizationResult>;
}
impl Finalize for Result<GasLeft> {
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fn finalize<E: Ext>(self, ext: E) -> Result<FinalizationResult> {
match self {
Ok(GasLeft::Known(gas_left)) => Ok(FinalizationResult { gas_left: gas_left, apply_state: true, return_data: ReturnData::empty() }),
Ok(GasLeft::NeedsReturn {gas_left, data, apply_state}) => ext.ret(&gas_left, &data, apply_state).map(|gas_left| FinalizationResult {
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gas_left: gas_left,
apply_state: apply_state,
return_data: data,
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}),
Err(err) => Err(err),
}
}
}
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/// Cost calculation type. For low-gas usage we calculate costs using usize instead of U256
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pub trait CostType: Sized + From<usize> + Copy
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+ ops::Mul<Output=Self> + ops::Div<Output=Self> + ops::Add<Output=Self> +ops::Sub<Output=Self>
+ ops::Shr<usize, Output=Self> + ops::Shl<usize, Output=Self>
+ cmp::Ord + fmt::Debug {
/// Converts this cost into `U256`
fn as_u256(&self) -> U256;
/// Tries to fit `U256` into this `Cost` type
fn from_u256(val: U256) -> Result<Self>;
/// Convert to usize (may panic)
fn as_usize(&self) -> usize;
/// Add with overflow
fn overflow_add(self, other: Self) -> (Self, bool);
/// Multiple with overflow
fn overflow_mul(self, other: Self) -> (Self, bool);
/// Single-step full multiplication and shift: `(self*other) >> shr`
/// Should not overflow on intermediate steps
fn overflow_mul_shr(self, other: Self, shr: usize) -> (Self, bool);
}
impl CostType for U256 {
fn as_u256(&self) -> U256 {
*self
}
fn from_u256(val: U256) -> Result<Self> {
Ok(val)
}
fn as_usize(&self) -> usize {
self.as_u64() as usize
}
fn overflow_add(self, other: Self) -> (Self, bool) {
self.overflowing_add(other)
}
fn overflow_mul(self, other: Self) -> (Self, bool) {
self.overflowing_mul(other)
}
fn overflow_mul_shr(self, other: Self, shr: usize) -> (Self, bool) {
let x = self.full_mul(other);
let U512(parts) = x;
let overflow = (parts[4] | parts[5] | parts[6] | parts[7]) > 0;
let U512(parts) = x >> shr;
(
U256([parts[0], parts[1], parts[2], parts[3]]),
overflow
)
}
}
impl CostType for usize {
fn as_u256(&self) -> U256 {
U256::from(*self)
}
fn from_u256(val: U256) -> Result<Self> {
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let res = val.low_u64() as usize;
// validate if value fits into usize
if U256::from(res) != val {
return Err(Error::OutOfGas);
}
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Ok(res)
}
fn as_usize(&self) -> usize {
*self
}
fn overflow_add(self, other: Self) -> (Self, bool) {
self.overflowing_add(other)
}
fn overflow_mul(self, other: Self) -> (Self, bool) {
self.overflowing_mul(other)
}
fn overflow_mul_shr(self, other: Self, shr: usize) -> (Self, bool) {
let (c, o) = U128::from(self).overflowing_mul(U128::from(other));
let U128(parts) = c;
let overflow = o | (parts[1] > 0);
let U128(parts) = c >> shr;
let result = parts[0] as usize;
let overflow = overflow | (parts[0] > result as u64);
(result, overflow)
}
}
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#[cfg(test)]
mod tests {
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use bigint::prelude::U256;
use super::CostType;
#[test]
fn should_calculate_overflow_mul_shr_without_overflow() {
// given
let num = 1048576;
// when
let (res1, o1) = U256::from(num).overflow_mul_shr(U256::from(num), 20);
let (res2, o2) = num.overflow_mul_shr(num, 20);
// then
assert_eq!(res1, U256::from(num));
assert!(!o1);
assert_eq!(res2, num);
assert!(!o2);
}
#[test]
fn should_calculate_overflow_mul_shr_with_overflow() {
// given
let max = u64::max_value();
let num1 = U256([max, max, max, max]);
let num2 = usize::max_value();
// when
let (res1, o1) = num1.overflow_mul_shr(num1, 256);
let (res2, o2) = num2.overflow_mul_shr(num2, 64);
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// then
assert_eq!(res2, num2 - 1);
assert!(o2);
assert_eq!(res1, !U256::zero() - U256::one());
assert!(o1);
}
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#[test]
fn should_validate_u256_to_usize_conversion() {
// given
let v = U256::from(usize::max_value()) + U256::from(1);
// when
let res = usize::from_u256(v);
// then
assert!(res.is_err());
}
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}