/* This file is part of solidity. solidity 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. solidity 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 solidity. If not, see . */ // SPDX-License-Identifier: GPL-3.0 /** * @file PeepholeOptimiser.cpp * Performs local optimising code changes to assembly. */ #include #include #include using namespace std; using namespace solidity; using namespace solidity::evmasm; // TODO: Extend this to use the tools from ExpressionClasses.cpp namespace { struct OptimiserState { AssemblyItems const& items; size_t i; std::back_insert_iterator out; }; template struct FunctionParameterCount; template struct FunctionParameterCount { static constexpr auto value = sizeof...(Args); }; template struct SimplePeepholeOptimizerMethod { template static bool applyRule(AssemblyItems::const_iterator _in, back_insert_iterator _out, index_sequence) { return Method::applySimple(_in[Indices]..., _out); } static bool apply(OptimiserState& _state) { static constexpr size_t WindowSize = FunctionParameterCount::value - 1; if ( _state.i + WindowSize <= _state.items.size() && applyRule(_state.items.begin() + static_cast(_state.i), _state.out, make_index_sequence{}) ) { _state.i += WindowSize; return true; } else return false; } }; struct Identity: SimplePeepholeOptimizerMethod { static bool applySimple(AssemblyItem const& _item, std::back_insert_iterator _out) { *_out = _item; return true; } }; struct PushPop: SimplePeepholeOptimizerMethod { static bool applySimple(AssemblyItem const& _push, AssemblyItem const& _pop, std::back_insert_iterator) { auto t = _push.type(); return _pop == Instruction::POP && ( SemanticInformation::isDupInstruction(_push) || t == Push || t == PushTag || t == PushSub || t == PushSubSize || t == PushProgramSize || t == PushData || t == PushLibraryAddress ); } }; struct OpPop: SimplePeepholeOptimizerMethod { static bool applySimple( AssemblyItem const& _op, AssemblyItem const& _pop, std::back_insert_iterator _out ) { if (_pop == Instruction::POP && _op.type() == Operation) { Instruction instr = _op.instruction(); if (instructionInfo(instr).ret == 1 && !instructionInfo(instr).sideEffects) { for (int j = 0; j < instructionInfo(instr).args; j++) *_out = {Instruction::POP, _op.location()}; return true; } } return false; } }; struct OpStop: SimplePeepholeOptimizerMethod { static bool applySimple( AssemblyItem const& _op, AssemblyItem const& _stop, std::back_insert_iterator _out ) { if (_stop == Instruction::STOP) { if (_op.type() == Operation) { Instruction instr = _op.instruction(); if (!instructionInfo(instr).sideEffects) { *_out = {Instruction::STOP, _op.location()}; return true; } } else if (_op.type() == Push) { *_out = {Instruction::STOP, _op.location()}; return true; } } return false; } }; struct OpReturnRevert: SimplePeepholeOptimizerMethod { static bool applySimple( AssemblyItem const& _op, AssemblyItem const& _push, AssemblyItem const& _pushOrDup, AssemblyItem const& _returnRevert, std::back_insert_iterator _out ) { if ( (_returnRevert == Instruction::RETURN || _returnRevert == Instruction::REVERT) && _push.type() == Push && (_pushOrDup.type() == Push || _pushOrDup == dupInstruction(1)) ) if ( (_op.type() == Operation && !instructionInfo(_op.instruction()).sideEffects) || _op.type() == Push ) { *_out = _push; *_out = _pushOrDup; *_out = _returnRevert; return true; } return false; } }; struct DoubleSwap: SimplePeepholeOptimizerMethod { static size_t applySimple(AssemblyItem const& _s1, AssemblyItem const& _s2, std::back_insert_iterator) { return _s1 == _s2 && SemanticInformation::isSwapInstruction(_s1); } }; struct DoublePush: SimplePeepholeOptimizerMethod { static bool applySimple(AssemblyItem const& _push1, AssemblyItem const& _push2, std::back_insert_iterator _out) { if (_push1.type() == Push && _push2.type() == Push && _push1.data() == _push2.data()) { *_out = _push1; *_out = {Instruction::DUP1, _push2.location()}; return true; } else return false; } }; struct CommutativeSwap: SimplePeepholeOptimizerMethod { static bool applySimple(AssemblyItem const& _swap, AssemblyItem const& _op, std::back_insert_iterator _out) { // Remove SWAP1 if following instruction is commutative if ( _swap == Instruction::SWAP1 && SemanticInformation::isCommutativeOperation(_op) ) { *_out = _op; return true; } else return false; } }; struct SwapComparison: SimplePeepholeOptimizerMethod { static bool applySimple(AssemblyItem const& _swap, AssemblyItem const& _op, std::back_insert_iterator _out) { static map const swappableOps{ { Instruction::LT, Instruction::GT }, { Instruction::GT, Instruction::LT }, { Instruction::SLT, Instruction::SGT }, { Instruction::SGT, Instruction::SLT } }; if ( _swap == Instruction::SWAP1 && _op.type() == Operation && swappableOps.count(_op.instruction()) ) { *_out = swappableOps.at(_op.instruction()); return true; } else return false; } }; /// Remove swapN after dupN struct DupSwap: SimplePeepholeOptimizerMethod { static size_t applySimple( AssemblyItem const& _dupN, AssemblyItem const& _swapN, std::back_insert_iterator _out ) { if ( SemanticInformation::isDupInstruction(_dupN) && SemanticInformation::isSwapInstruction(_swapN) && getDupNumber(_dupN.instruction()) == getSwapNumber(_swapN.instruction()) ) { *_out = _dupN; return true; } else return false; } }; struct IsZeroIsZeroJumpI: SimplePeepholeOptimizerMethod { static size_t applySimple( AssemblyItem const& _iszero1, AssemblyItem const& _iszero2, AssemblyItem const& _pushTag, AssemblyItem const& _jumpi, std::back_insert_iterator _out ) { if ( _iszero1 == Instruction::ISZERO && _iszero2 == Instruction::ISZERO && _pushTag.type() == PushTag && _jumpi == Instruction::JUMPI ) { *_out = _pushTag; *_out = _jumpi; return true; } else return false; } }; struct EqIsZeroJumpI: SimplePeepholeOptimizerMethod { static size_t applySimple( AssemblyItem const& _eq, AssemblyItem const& _iszero, AssemblyItem const& _pushTag, AssemblyItem const& _jumpi, std::back_insert_iterator _out ) { if ( _eq == Instruction::EQ && _iszero == Instruction::ISZERO && _pushTag.type() == PushTag && _jumpi == Instruction::JUMPI ) { *_out = AssemblyItem(Instruction::SUB, _eq.location()); *_out = _pushTag; *_out = _jumpi; return true; } else return false; } }; // push_tag_1 jumpi push_tag_2 jump tag_1: -> iszero push_tag_2 jumpi tag_1: struct DoubleJump: SimplePeepholeOptimizerMethod { static size_t applySimple( AssemblyItem const& _pushTag1, AssemblyItem const& _jumpi, AssemblyItem const& _pushTag2, AssemblyItem const& _jump, AssemblyItem const& _tag1, std::back_insert_iterator _out ) { if ( _pushTag1.type() == PushTag && _jumpi == Instruction::JUMPI && _pushTag2.type() == PushTag && _jump == Instruction::JUMP && _tag1.type() == Tag && _pushTag1.data() == _tag1.data() ) { *_out = AssemblyItem(Instruction::ISZERO, _jumpi.location()); *_out = _pushTag2; *_out = _jumpi; *_out = _tag1; return true; } else return false; } }; struct JumpToNext: SimplePeepholeOptimizerMethod { static size_t applySimple( AssemblyItem const& _pushTag, AssemblyItem const& _jump, AssemblyItem const& _tag, std::back_insert_iterator _out ) { if ( _pushTag.type() == PushTag && (_jump == Instruction::JUMP || _jump == Instruction::JUMPI) && _tag.type() == Tag && _pushTag.data() == _tag.data() ) { if (_jump == Instruction::JUMPI) *_out = AssemblyItem(Instruction::POP, _jump.location()); *_out = _tag; return true; } else return false; } }; struct TagConjunctions: SimplePeepholeOptimizerMethod { static bool applySimple( AssemblyItem const& _pushTag, AssemblyItem const& _pushConstant, AssemblyItem const& _and, std::back_insert_iterator _out ) { if (_and != Instruction::AND) return false; if ( _pushTag.type() == PushTag && _pushConstant.type() == Push && (_pushConstant.data() & u256(0xFFFFFFFF)) == u256(0xFFFFFFFF) ) { *_out = _pushTag; return true; } else if ( // tag and constant are swapped _pushConstant.type() == PushTag && _pushTag.type() == Push && (_pushTag.data() & u256(0xFFFFFFFF)) == u256(0xFFFFFFFF) ) { *_out = _pushConstant; return true; } else return false; } }; struct TruthyAnd: SimplePeepholeOptimizerMethod { static bool applySimple( AssemblyItem const& _push, AssemblyItem const& _not, AssemblyItem const& _and, std::back_insert_iterator ) { return ( _push.type() == Push && _push.data() == 0 && _not == Instruction::NOT && _and == Instruction::AND ); } }; /// Removes everything after a JUMP (or similar) until the next JUMPDEST. struct UnreachableCode { static bool apply(OptimiserState& _state) { auto it = _state.items.begin() + static_cast(_state.i); auto end = _state.items.end(); if (it == end) return false; if ( it[0] != Instruction::JUMP && it[0] != Instruction::RETURN && it[0] != Instruction::STOP && it[0] != Instruction::INVALID && it[0] != Instruction::SELFDESTRUCT && it[0] != Instruction::REVERT ) return false; ptrdiff_t i = 1; while (it + i != end && it[i].type() != Tag) i++; if (i > 1) { *_state.out = it[0]; _state.i += static_cast(i); return true; } else return false; } }; void applyMethods(OptimiserState&) { assertThrow(false, OptimizerException, "Peephole optimizer failed to apply identity."); } template void applyMethods(OptimiserState& _state, Method, OtherMethods... _other) { if (!Method::apply(_state)) applyMethods(_state, _other...); } size_t numberOfPops(AssemblyItems const& _items) { return static_cast(std::count(_items.begin(), _items.end(), Instruction::POP)); } } bool PeepholeOptimiser::optimise() { // Avoid referencing immutables too early by using approx. counting in bytesRequired() auto const approx = evmasm::Precision::Approximate; OptimiserState state {m_items, 0, std::back_inserter(m_optimisedItems)}; while (state.i < m_items.size()) applyMethods( state, PushPop(), OpPop(), OpStop(), OpReturnRevert(), DoublePush(), DoubleSwap(), CommutativeSwap(), SwapComparison(), DupSwap(), IsZeroIsZeroJumpI(), EqIsZeroJumpI(), DoubleJump(), JumpToNext(), UnreachableCode(), TagConjunctions(), TruthyAnd(), Identity() ); if (m_optimisedItems.size() < m_items.size() || ( m_optimisedItems.size() == m_items.size() && ( evmasm::bytesRequired(m_optimisedItems, 3, approx) < evmasm::bytesRequired(m_items, 3, approx) || numberOfPops(m_optimisedItems) > numberOfPops(m_items) ) )) { m_items = std::move(m_optimisedItems); return true; } else return false; }