/*( 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 . */ /** * Base class to perform data flow analysis during AST walks. * Tracks assignments and is used as base class for both Rematerialiser and * Common Subexpression Eliminator. */ #include #include #include #include #include #include #include #include #include #include #include using namespace std; using namespace solidity; using namespace solidity::util; using namespace solidity::yul; DataFlowAnalyzer::DataFlowAnalyzer( Dialect const& _dialect, map _functionSideEffects ): m_dialect(_dialect), m_functionSideEffects(std::move(_functionSideEffects)), m_knowledgeBase(_dialect, m_value) { if (auto const* builtin = _dialect.memoryStoreFunction(YulString{})) m_storeFunctionName[static_cast(StoreLoadLocation::Memory)] = builtin->name; if (auto const* builtin = _dialect.memoryLoadFunction(YulString{})) m_loadFunctionName[static_cast(StoreLoadLocation::Memory)] = builtin->name; if (auto const* builtin = _dialect.storageStoreFunction(YulString{})) m_storeFunctionName[static_cast(StoreLoadLocation::Storage)] = builtin->name; if (auto const* builtin = _dialect.storageLoadFunction(YulString{})) m_loadFunctionName[static_cast(StoreLoadLocation::Storage)] = builtin->name; } void DataFlowAnalyzer::operator()(ExpressionStatement& _statement) { if (auto vars = isSimpleStore(StoreLoadLocation::Storage, _statement)) { ASTModifier::operator()(_statement); cxx20::erase_if(m_storage, mapTuple([&](auto&& key, auto&& value) { return !m_knowledgeBase.knownToBeDifferent(vars->first, key) && !m_knowledgeBase.knownToBeEqual(vars->second, value); })); m_storage[vars->first] = vars->second; } else if (auto vars = isSimpleStore(StoreLoadLocation::Memory, _statement)) { ASTModifier::operator()(_statement); cxx20::erase_if(m_memory, mapTuple([&](auto&& key, auto&& /* value */) { return !m_knowledgeBase.knownToBeDifferentByAtLeast32(vars->first, key); })); m_memory[vars->first] = vars->second; } else { clearKnowledgeIfInvalidated(_statement.expression); ASTModifier::operator()(_statement); } } void DataFlowAnalyzer::operator()(Assignment& _assignment) { set names; for (auto const& var: _assignment.variableNames) names.emplace(var.name); assertThrow(_assignment.value, OptimizerException, ""); clearKnowledgeIfInvalidated(*_assignment.value); visit(*_assignment.value); handleAssignment(names, _assignment.value.get(), false); } void DataFlowAnalyzer::operator()(VariableDeclaration& _varDecl) { set names; for (auto const& var: _varDecl.variables) names.emplace(var.name); m_variableScopes.back().variables += names; if (_varDecl.value) { clearKnowledgeIfInvalidated(*_varDecl.value); visit(*_varDecl.value); } handleAssignment(names, _varDecl.value.get(), true); } void DataFlowAnalyzer::operator()(If& _if) { clearKnowledgeIfInvalidated(*_if.condition); unordered_map storage = m_storage; unordered_map memory = m_memory; ASTModifier::operator()(_if); joinKnowledge(storage, memory); clearValues(assignedVariableNames(_if.body)); } void DataFlowAnalyzer::operator()(Switch& _switch) { clearKnowledgeIfInvalidated(*_switch.expression); visit(*_switch.expression); set assignedVariables; for (auto& _case: _switch.cases) { unordered_map storage = m_storage; unordered_map memory = m_memory; (*this)(_case.body); joinKnowledge(storage, memory); set variables = assignedVariableNames(_case.body); assignedVariables += variables; // This is a little too destructive, we could retain the old values. clearValues(variables); clearKnowledgeIfInvalidated(_case.body); } for (auto& _case: _switch.cases) clearKnowledgeIfInvalidated(_case.body); clearValues(assignedVariables); } void DataFlowAnalyzer::operator()(FunctionDefinition& _fun) { // Save all information. We might rather reinstantiate this class, // but this could be difficult if it is subclassed. ScopedSaveAndRestore valueResetter(m_value, {}); ScopedSaveAndRestore loopDepthResetter(m_loopDepth, 0u); ScopedSaveAndRestore referencesResetter(m_references, {}); ScopedSaveAndRestore storageResetter(m_storage, {}); ScopedSaveAndRestore memoryResetter(m_memory, {}); pushScope(true); for (auto const& parameter: _fun.parameters) m_variableScopes.back().variables.emplace(parameter.name); for (auto const& var: _fun.returnVariables) { m_variableScopes.back().variables.emplace(var.name); handleAssignment({var.name}, nullptr, true); } ASTModifier::operator()(_fun); // Note that the contents of return variables, storage and memory at this point // might be incorrect due to the fact that the DataFlowAnalyzer ignores the ``leave`` // statement. popScope(); } void DataFlowAnalyzer::operator()(ForLoop& _for) { // If the pre block was not empty, // we would have to deal with more complicated scoping rules. assertThrow(_for.pre.statements.empty(), OptimizerException, ""); ++m_loopDepth; AssignmentsSinceContinue assignmentsSinceCont; assignmentsSinceCont(_for.body); set assignedVariables = assignedVariableNames(_for.body) + assignedVariableNames(_for.post); clearValues(assignedVariables); // break/continue are tricky for storage and thus we almost always clear here. clearKnowledgeIfInvalidated(*_for.condition); clearKnowledgeIfInvalidated(_for.post); clearKnowledgeIfInvalidated(_for.body); visit(*_for.condition); (*this)(_for.body); clearValues(assignmentsSinceCont.names()); clearKnowledgeIfInvalidated(_for.body); (*this)(_for.post); clearValues(assignedVariables); clearKnowledgeIfInvalidated(*_for.condition); clearKnowledgeIfInvalidated(_for.post); clearKnowledgeIfInvalidated(_for.body); --m_loopDepth; } void DataFlowAnalyzer::operator()(Block& _block) { size_t numScopes = m_variableScopes.size(); pushScope(false); ASTModifier::operator()(_block); popScope(); assertThrow(numScopes == m_variableScopes.size(), OptimizerException, ""); } void DataFlowAnalyzer::handleAssignment(set const& _variables, Expression* _value, bool _isDeclaration) { if (!_isDeclaration) clearValues(_variables); MovableChecker movableChecker{m_dialect, &m_functionSideEffects}; if (_value) movableChecker.visit(*_value); else for (auto const& var: _variables) assignValue(var, &m_zero); if (_value && _variables.size() == 1) { YulString name = *_variables.begin(); // Expression has to be movable and cannot contain a reference // to the variable that will be assigned to. if (movableChecker.movable() && !movableChecker.referencedVariables().count(name)) assignValue(name, _value); } auto const& referencedVariables = movableChecker.referencedVariables(); for (auto const& name: _variables) { m_references[name] = referencedVariables; if (!_isDeclaration) { // assignment to slot denoted by "name" m_storage.erase(name); // assignment to slot contents denoted by "name" cxx20::erase_if(m_storage, mapTuple([&name](auto&& /* key */, auto&& value) { return value == name; })); // assignment to slot denoted by "name" m_memory.erase(name); // assignment to slot contents denoted by "name" cxx20::erase_if(m_memory, mapTuple([&name](auto&& /* key */, auto&& value) { return value == name; })); } } if (_value && _variables.size() == 1) { YulString variable = *_variables.begin(); if (!movableChecker.referencedVariables().count(variable)) { // This might erase additional knowledge about the slot. // On the other hand, if we knew the value in the slot // already, then the sload() / mload() would have been replaced by a variable anyway. if (auto key = isSimpleLoad(StoreLoadLocation::Memory, *_value)) m_memory[*key] = variable; else if (auto key = isSimpleLoad(StoreLoadLocation::Storage, *_value)) m_storage[*key] = variable; } } } void DataFlowAnalyzer::pushScope(bool _functionScope) { m_variableScopes.emplace_back(_functionScope); } void DataFlowAnalyzer::popScope() { for (auto const& name: m_variableScopes.back().variables) { m_value.erase(name); m_references.erase(name); } m_variableScopes.pop_back(); } void DataFlowAnalyzer::clearValues(set _variables) { // All variables that reference variables to be cleared also have to be // cleared, but not recursively, since only the value of the original // variables changes. Example: // let a := 1 // let b := a // let c := b // let a := 2 // add(b, c) // In the last line, we can replace c by b, but not b by a. // // This cannot be easily tested since the substitutions will be done // one by one on the fly, and the last line will just be add(1, 1) // First clear storage knowledge, because we do not have to clear // storage knowledge of variables whose expression has changed, // since the value is still unchanged. auto eraseCondition = mapTuple([&_variables](auto&& key, auto&& value) { return _variables.count(key) || _variables.count(value); }); cxx20::erase_if(m_storage, eraseCondition); cxx20::erase_if(m_memory, eraseCondition); // Also clear variables that reference variables to be cleared. for (auto const& variableToClear: _variables) for (auto const& [ref, names]: m_references) if (names.count(variableToClear)) _variables.emplace(ref); // Clear the value and update the reference relation. for (auto const& name: _variables) { m_value.erase(name); m_references.erase(name); } } void DataFlowAnalyzer::assignValue(YulString _variable, Expression const* _value) { m_value[_variable] = {_value, m_loopDepth}; } void DataFlowAnalyzer::clearKnowledgeIfInvalidated(Block const& _block) { SideEffectsCollector sideEffects(m_dialect, _block, &m_functionSideEffects); if (sideEffects.invalidatesStorage()) m_storage.clear(); if (sideEffects.invalidatesMemory()) m_memory.clear(); } void DataFlowAnalyzer::clearKnowledgeIfInvalidated(Expression const& _expr) { SideEffectsCollector sideEffects(m_dialect, _expr, &m_functionSideEffects); if (sideEffects.invalidatesStorage()) m_storage.clear(); if (sideEffects.invalidatesMemory()) m_memory.clear(); } void DataFlowAnalyzer::joinKnowledge( unordered_map const& _olderStorage, unordered_map const& _olderMemory ) { joinKnowledgeHelper(m_storage, _olderStorage); joinKnowledgeHelper(m_memory, _olderMemory); } void DataFlowAnalyzer::joinKnowledgeHelper( std::unordered_map& _this, std::unordered_map const& _older ) { // We clear if the key does not exist in the older map or if the value is different. // This also works for memory because _older is an "older version" // of m_memory and thus any overlapping write would have cleared the keys // that are not known to be different inside m_memory already. cxx20::erase_if(_this, mapTuple([&_older](auto&& key, auto&& currentValue){ YulString const* oldValue = valueOrNullptr(_older, key); return !oldValue || *oldValue != currentValue; })); } bool DataFlowAnalyzer::inScope(YulString _variableName) const { for (auto const& scope: m_variableScopes | ranges::views::reverse) { if (scope.variables.count(_variableName)) return true; if (scope.isFunction) return false; } return false; } optional DataFlowAnalyzer::valueOfIdentifier(YulString const& _name) { if (m_value.count(_name)) if (Literal const* literal = get_if(m_value.at(_name).value)) return valueOfLiteral(*literal); return nullopt; } std::optional> DataFlowAnalyzer::isSimpleStore( StoreLoadLocation _location, ExpressionStatement const& _statement ) const { if (FunctionCall const* funCall = get_if(&_statement.expression)) if (funCall->functionName.name == m_storeFunctionName[static_cast(_location)]) if (Identifier const* key = std::get_if(&funCall->arguments.front())) if (Identifier const* value = std::get_if(&funCall->arguments.back())) return make_pair(key->name, value->name); return {}; } std::optional DataFlowAnalyzer::isSimpleLoad( StoreLoadLocation _location, Expression const& _expression ) const { if (FunctionCall const* funCall = get_if(&_expression)) if (funCall->functionName.name == m_loadFunctionName[static_cast(_location)]) if (Identifier const* key = std::get_if(&funCall->arguments.front())) return key->name; return {}; }