// Copyright 2015, 2016 Ethcore (UK) Ltd. // 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 . //! Evm interface. use common::*; use evm::Ext; /// Evm errors. #[derive(Debug)] pub enum Error { /// `OutOfGas` is returned when transaction execution runs out of gas. /// The state should be reverted to the state from before the /// transaction execution. But it does not mean that transaction /// was invalid. Balance still should be transfered and nonce /// should be increased. OutOfGas, /// `BadJumpDestination` is returned when execution tried to move /// to position that wasn't marked with JUMPDEST instruction BadJumpDestination { /// Position the code tried to jump to. destination: usize }, /// `BadInstructions` is returned when given instruction is not supported BadInstruction { /// Unrecognized opcode instruction: u8, }, /// `StackUnderflow` when there is not enough stack elements to execute instruction StackUnderflow { /// Invoked instruction instruction: &'static str, /// How many stack elements was requested by instruction wanted: usize, /// How many elements were on stack on_stack: usize }, /// When execution would exceed defined Stack Limit OutOfStack { /// Invoked instruction instruction: &'static str, /// How many stack elements instruction wanted to push wanted: usize, /// What was the stack limit limit: usize }, /// Returned on evm internal error. Should never be ignored during development. /// Likely to cause consensus issues. #[allow(dead_code)] // created only by jit Internal, } /// A specialized version of Result over EVM errors. pub type Result = ::std::result::Result; /// Gas Left: either it is a known value, or it needs to be computed by processing /// a return instruction. #[derive(Debug, PartialEq, Eq, PartialOrd, Ord)] pub enum GasLeft<'a> { /// Known gas left Known(U256), /// Return instruction must be processed. NeedsReturn(U256, &'a [u8]), } /// Types that can be "finalized" using an EVM. /// /// In practice, this is just used to define an inherent impl on /// `Reult>`. pub trait Finalize { /// Consume the externalities, call return if necessary, and produce a final amount of gas left. fn finalize(self, ext: E) -> Result; } impl<'a> Finalize for Result> { fn finalize(self, ext: E) -> Result { match self { Ok(GasLeft::Known(gas)) => Ok(gas), Ok(GasLeft::NeedsReturn(gas, ret_code)) => ext.ret(&gas, ret_code), Err(err) => Err(err), } } } /// Cost calculation type. For low-gas usage we calculate costs using usize instead of U256 pub trait CostType: ops::Mul + ops::Div + ops::Add + ops::Sub + ops::Shr + ops::Shl + cmp::Ord + Sized + From + Copy { /// Converts this cost into `U256` fn as_u256(&self) -> U256; /// Tries to fit `U256` into this `Cost` type fn from_u256(val: U256) -> Result; /// 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 division: `self*other/div` /// Should not overflow on intermediate steps fn overflow_mul_div(self, other: Self, div: Self) -> (Self, bool); } impl CostType for U256 { fn as_u256(&self) -> U256 { *self } fn from_u256(val: U256) -> Result { Ok(val) } fn as_usize(&self) -> usize { self.as_u64() as usize } fn overflow_add(self, other: Self) -> (Self, bool) { Uint::overflowing_add(self, other) } fn overflow_mul(self, other: Self) -> (Self, bool) { Uint::overflowing_mul(self, other) } fn overflow_mul_div(self, other: Self, div: Self) -> (Self, bool) { let x = self.full_mul(other); let (U512(parts), o) = Uint::overflowing_div(x, U512::from(div)); let overflow = (parts[4] | parts[5] | parts[6] | parts[7]) > 0; ( U256([parts[0], parts[1], parts[2], parts[3]]), o | overflow ) } } impl CostType for usize { fn as_u256(&self) -> U256 { U256::from(*self) } fn from_u256(val: U256) -> Result { if U256::from(val.low_u64()) != val { return Err(Error::OutOfGas); } Ok(val.low_u64() as usize) } 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_div(self, other: Self, div: Self) -> (Self, bool) { let (c, o) = U128::from(self).overflowing_mul(U128::from(other)); let (U128(parts), o1) = c.overflowing_div(U128::from(div)); let result = parts[0] as usize; let overflow = o | o1 | (parts[1] > 0) | (parts[0] > result as u64); (result, overflow) } } /// Evm interface pub trait Evm { /// This function should be used to execute transaction. /// /// It returns either an error, a known amount of gas left, or parameters to be used /// to compute the final gas left. fn exec(&mut self, params: ActionParams, ext: &mut Ext) -> Result; } #[test] fn should_calculate_overflow_mul_div_without_overflow() { // given let num = 10_000_000; // when let (res1, o1) = U256::from(num).overflow_mul_div(U256::from(num), U256::from(num)); let (res2, o2) = num.overflow_mul_div(num, num); // then assert_eq!(res1, U256::from(num)); assert!(!o1); assert_eq!(res2, num); assert!(!o2); } #[test] fn should_calculate_overflow_mul_div_with_overflow() { // given let max = ::std::u64::MAX; let num1 = U256([max, max, max, max]); let num2 = ::std::usize::MAX; // when let (res1, o1) = num1.overflow_mul_div(num1, num1 - U256::from(2)); let (res2, o2) = num2.overflow_mul_div(num2, num2 - 2); // then // (x+2)^2/x = (x^2 + 4x + 4)/x = x + 4 + 4/x ~ (MAX-2) + 4 + 0 = 1 assert_eq!(res2, 1); assert!(o2); assert_eq!(res1, U256::from(1)); assert!(o1); }