/* 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 . */ #include #include #include #include #include #include #include #include #include #include #include using namespace std; using namespace solidity; using namespace solidity::yul; namespace { vector generateMemoryStore( Dialect const& _dialect, shared_ptr const& _debugData, YulString _mpos, Expression _value ) { BuiltinFunction const* memoryStoreFunction = _dialect.memoryStoreFunction(_dialect.defaultType); yulAssert(memoryStoreFunction, ""); vector result; result.emplace_back(ExpressionStatement{_debugData, FunctionCall{ _debugData, Identifier{_debugData, memoryStoreFunction->name}, { Literal{_debugData, LiteralKind::Number, _mpos, {}}, move(_value) } }}); return result; } FunctionCall generateMemoryLoad(Dialect const& _dialect, std::shared_ptr const& _debugData, YulString _mpos) { BuiltinFunction const* memoryLoadFunction = _dialect.memoryLoadFunction(_dialect.defaultType); yulAssert(memoryLoadFunction, ""); return FunctionCall{ _debugData, Identifier{_debugData, memoryLoadFunction->name}, { Literal{ _debugData, LiteralKind::Number, _mpos, {} } } }; } } void StackToMemoryMover::run( OptimiserStepContext& _context, u256 _reservedMemory, map const& _memorySlots, uint64_t _numRequiredSlots, Block& _block ) { VariableMemoryOffsetTracker memoryOffsetTracker(_reservedMemory, _memorySlots, _numRequiredSlots); StackToMemoryMover stackToMemoryMover( _context, memoryOffsetTracker, util::applyMap( allFunctionDefinitions(_block), util::mapTuple([](YulString _name, FunctionDefinition const* _funDef) { return make_pair(_name, _funDef->returnVariables); }), map{} ) ); stackToMemoryMover(_block); _block.statements += move(stackToMemoryMover.m_newFunctionDefinitions); } StackToMemoryMover::StackToMemoryMover( OptimiserStepContext& _context, VariableMemoryOffsetTracker const& _memoryOffsetTracker, map _functionReturnVariables ): m_context(_context), m_memoryOffsetTracker(_memoryOffsetTracker), m_nameDispenser(_context.dispenser), m_functionReturnVariables(move(_functionReturnVariables)) { auto const* evmDialect = dynamic_cast(&_context.dialect); yulAssert( evmDialect && evmDialect->providesObjectAccess(), "StackToMemoryMover can only be run on objects using the EVMDialect with object access." ); } void StackToMemoryMover::operator()(FunctionDefinition& _functionDefinition) { // It is important to first visit the function body, so that it doesn't replace the memory inits for // variable arguments we might generate below. ASTModifier::operator()(_functionDefinition); vector memoryVariableInits; // All function parameters with a memory slot are moved at the beginning of the function body. for (TypedName const& param: _functionDefinition.parameters) if (auto slot = m_memoryOffsetTracker(param.name)) memoryVariableInits += generateMemoryStore( m_context.dialect, param.debugData, *slot, Identifier{param.debugData, param.name} ); // All memory return variables have to be initialized to zero in memory. for (TypedName const& returnVariable: _functionDefinition.returnVariables) if (auto slot = m_memoryOffsetTracker(returnVariable.name)) memoryVariableInits += generateMemoryStore( m_context.dialect, returnVariable.debugData, *slot, Literal{returnVariable.debugData, LiteralKind::Number, "0"_yulstring, {}} ); // Special case of a function with a single return argument that needs to move to memory. if (_functionDefinition.returnVariables.size() == 1 && m_memoryOffsetTracker(_functionDefinition.returnVariables.front().name)) { TypedNameList stackParameters = _functionDefinition.parameters | ranges::views::filter( not_fn(m_memoryOffsetTracker) ) | ranges::to; // Generate new function without return variable and with only the non-moved parameters. YulString newFunctionName = m_context.dispenser.newName(_functionDefinition.name); m_newFunctionDefinitions.emplace_back(FunctionDefinition{ _functionDefinition.debugData, newFunctionName, stackParameters, {}, move(_functionDefinition.body) }); // Generate new names for the arguments to maintain disambiguation. std::map newArgumentNames; for (TypedName const& _var: stackParameters) newArgumentNames[_var.name] = m_context.dispenser.newName(_var.name); for (auto& parameter: _functionDefinition.parameters) parameter.name = util::valueOrDefault(newArgumentNames, parameter.name, parameter.name); // Replace original function by a call to the new function and an assignment to the return variable from memory. _functionDefinition.body = Block{_functionDefinition.debugData, move(memoryVariableInits)}; _functionDefinition.body.statements.emplace_back(ExpressionStatement{ _functionDefinition.debugData, FunctionCall{ _functionDefinition.debugData, Identifier{_functionDefinition.debugData, newFunctionName}, stackParameters | ranges::views::transform([&](TypedName const& _arg) { return Expression{Identifier{_arg.debugData, newArgumentNames.at(_arg.name)}}; }) | ranges::to> } }); _functionDefinition.body.statements.emplace_back(Assignment{ _functionDefinition.debugData, {Identifier{_functionDefinition.debugData, _functionDefinition.returnVariables.front().name}}, make_unique(generateMemoryLoad( m_context.dialect, _functionDefinition.debugData, *m_memoryOffsetTracker(_functionDefinition.returnVariables.front().name) )) }); return; } if (!memoryVariableInits.empty()) _functionDefinition.body.statements = move(memoryVariableInits) + move(_functionDefinition.body.statements); _functionDefinition.returnVariables = _functionDefinition.returnVariables | ranges::views::filter( not_fn(m_memoryOffsetTracker) ) | ranges::to; } void StackToMemoryMover::operator()(Block& _block) { using OptionalStatements = optional>; auto rewriteAssignmentOrVariableDeclarationLeftHandSide = [this]( auto& _stmt, auto& _lhsVars ) -> OptionalStatements { using StatementType = decay_t; auto debugData = _stmt.debugData; if (_lhsVars.size() == 1) { if (optional offset = m_memoryOffsetTracker(_lhsVars.front().name)) return generateMemoryStore( m_context.dialect, debugData, *offset, _stmt.value ? *move(_stmt.value) : Literal{debugData, LiteralKind::Number, "0"_yulstring, {}} ); else return {}; } vector> rhsMemorySlots; if (_stmt.value) { FunctionCall const* functionCall = get_if(_stmt.value.get()); yulAssert(functionCall, ""); if (m_context.dialect.builtin(functionCall->functionName.name)) rhsMemorySlots = vector>(_lhsVars.size(), nullopt); else rhsMemorySlots = m_functionReturnVariables.at(functionCall->functionName.name) | ranges::views::transform(m_memoryOffsetTracker) | ranges::to>>; } else rhsMemorySlots = vector>(_lhsVars.size(), nullopt); // Nothing to do, if the right-hand-side remains entirely on the stack and // none of the variables in the left-hand-side are moved. if ( ranges::none_of(rhsMemorySlots, [](optional const& _slot) { return _slot.has_value(); }) && !util::contains_if(_lhsVars, m_memoryOffsetTracker) ) return {}; vector memoryAssignments; vector variableAssignments; VariableDeclaration tempDecl{debugData, {}, move(_stmt.value)}; yulAssert(rhsMemorySlots.size() == _lhsVars.size(), ""); for (auto&& [lhsVar, rhsSlot]: ranges::views::zip(_lhsVars, rhsMemorySlots)) { unique_ptr rhs; if (rhsSlot) rhs = make_unique(generateMemoryLoad(m_context.dialect, debugData, *rhsSlot)); else { YulString tempVarName = m_nameDispenser.newName(lhsVar.name); tempDecl.variables.emplace_back(TypedName{lhsVar.debugData, tempVarName, {}}); rhs = make_unique(Identifier{debugData, tempVarName}); } if (optional offset = m_memoryOffsetTracker(lhsVar.name)) memoryAssignments += generateMemoryStore( m_context.dialect, _stmt.debugData, *offset, move(*rhs) ); else variableAssignments.emplace_back(StatementType{ debugData, { move(lhsVar) }, move(rhs) }); } vector result; if (tempDecl.variables.empty()) result.emplace_back(ExpressionStatement{debugData, *move(tempDecl.value)}); else result.emplace_back(move(tempDecl)); reverse(memoryAssignments.begin(), memoryAssignments.end()); result += move(memoryAssignments); reverse(variableAssignments.begin(), variableAssignments.end()); result += move(variableAssignments); return OptionalStatements{move(result)}; }; util::iterateReplacing( _block.statements, [&](Statement& _statement) -> OptionalStatements { visit(_statement); if (auto* assignment = get_if(&_statement)) return rewriteAssignmentOrVariableDeclarationLeftHandSide(*assignment, assignment->variableNames); else if (auto* varDecl = get_if(&_statement)) return rewriteAssignmentOrVariableDeclarationLeftHandSide(*varDecl, varDecl->variables); return {}; } ); } void StackToMemoryMover::visit(Expression& _expression) { ASTModifier::visit(_expression); if (Identifier* identifier = get_if(&_expression)) if (optional offset = m_memoryOffsetTracker(identifier->name)) _expression = generateMemoryLoad(m_context.dialect, identifier->debugData, *offset); } optional StackToMemoryMover::VariableMemoryOffsetTracker::operator()(YulString _variable) const { if (m_memorySlots.count(_variable)) { uint64_t slot = m_memorySlots.at(_variable); yulAssert(slot < m_numRequiredSlots, ""); return YulString{toCompactHexWithPrefix(m_reservedMemory + 32 * (m_numRequiredSlots - slot - 1))}; } else return nullopt; } optional StackToMemoryMover::VariableMemoryOffsetTracker::operator()(TypedName const& _variable) const { return (*this)(_variable.name); } optional StackToMemoryMover::VariableMemoryOffsetTracker::operator()(Identifier const& _variable) const { return (*this)(_variable.name); }