/* 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 #ifdef HAVE_Z3 #include #endif #include #include using namespace std; using namespace dev; using namespace langutil; using namespace dev::solidity; CHC::CHC( smt::EncodingContext& _context, ErrorReporter& _errorReporter, map const& _smtlib2Responses, ReadCallback::Callback const& _smtCallback ): SMTEncoder(_context), #ifdef HAVE_Z3 m_interface(make_shared()), #else m_interface(make_shared(_smtlib2Responses, _smtCallback)), #endif m_outerErrorReporter(_errorReporter) { (void)_smtlib2Responses; (void)_smtCallback; } void CHC::analyze(SourceUnit const& _source) { solAssert(_source.annotation().experimentalFeatures.count(ExperimentalFeature::SMTChecker), ""); #ifdef HAVE_Z3 auto z3Interface = dynamic_pointer_cast(m_interface); solAssert(z3Interface, ""); m_context.setSolver(z3Interface->z3Interface()); #else auto smtlib2Interface = dynamic_pointer_cast(m_interface); solAssert(smtlib2Interface, ""); m_context.setSolver(smtlib2Interface->smtlib2Interface()); #endif m_context.clear(); m_context.setAssertionAccumulation(false); m_variableUsage.setFunctionInlining(false); auto boolSort = make_shared(smt::Kind::Bool); auto genesisSort = make_shared( vector(), boolSort ); m_genesisPredicate = createSymbolicBlock(genesisSort, "genesis"); auto genesis = (*m_genesisPredicate)({}); addRule(genesis, genesis.name); _source.accept(*this); } vector CHC::unhandledQueries() const { if (auto smtlib2 = dynamic_pointer_cast(m_interface)) return smtlib2->unhandledQueries(); return {}; } bool CHC::visit(ContractDefinition const& _contract) { if (!shouldVisit(_contract)) return false; reset(); initContract(_contract); m_stateVariables = _contract.stateVariablesIncludingInherited(); for (auto const& var: m_stateVariables) // SMT solvers do not support function types as arguments. if (var->type()->category() == Type::Category::Function) m_stateSorts.push_back(make_shared(smt::Kind::Int)); else m_stateSorts.push_back(smt::smtSort(*var->type())); clearIndices(&_contract); string suffix = _contract.name() + "_" + to_string(_contract.id()); m_interfacePredicate = createSymbolicBlock(interfaceSort(), "interface_" + suffix); // TODO create static instances for Bool/Int sorts in SolverInterface. auto boolSort = make_shared(smt::Kind::Bool); auto errorFunctionSort = make_shared( vector(), boolSort ); m_errorPredicate = createSymbolicBlock(errorFunctionSort, "error_" + suffix); m_constructorPredicate = createSymbolicBlock(constructorSort(), "implicit_constructor_" + to_string(_contract.id())); auto stateExprs = currentStateVariables(); setCurrentBlock(*m_interfacePredicate, &stateExprs); SMTEncoder::visit(_contract); return false; } void CHC::endVisit(ContractDefinition const& _contract) { if (!shouldVisit(_contract)) return; for (auto const& var: m_stateVariables) { solAssert(m_context.knownVariable(*var), ""); m_context.setZeroValue(*var); } auto genesisPred = (*m_genesisPredicate)({}); auto implicitConstructor = (*m_constructorPredicate)(currentStateVariables()); connectBlocks(genesisPred, implicitConstructor); m_currentBlock = implicitConstructor; if (auto constructor = _contract.constructor()) constructor->accept(*this); else inlineConstructorHierarchy(_contract); connectBlocks(m_currentBlock, interface()); for (unsigned i = 0; i < m_verificationTargets.size(); ++i) { auto const& target = m_verificationTargets.at(i); auto errorAppl = error(i + 1); if (query(errorAppl, target->location())) m_safeAssertions.insert(target); } SMTEncoder::endVisit(_contract); } bool CHC::visit(FunctionDefinition const& _function) { if (!shouldVisit(_function)) return false; // This is the case for base constructor inlining. if (m_currentFunction) { solAssert(m_currentFunction->isConstructor(), ""); solAssert(_function.isConstructor(), ""); solAssert(_function.scope() != m_currentContract, ""); SMTEncoder::visit(_function); return false; } solAssert(!m_currentFunction, "Inlining internal function calls not yet implemented"); m_currentFunction = &_function; initFunction(_function); auto functionEntryBlock = createBlock(m_currentFunction); auto bodyBlock = createBlock(&m_currentFunction->body()); auto functionPred = predicate(*functionEntryBlock, currentFunctionVariables()); auto bodyPred = predicate(*bodyBlock); connectBlocks(m_currentBlock, functionPred); connectBlocks(functionPred, bodyPred); setCurrentBlock(*bodyBlock); SMTEncoder::visit(*m_currentFunction); return false; } void CHC::endVisit(FunctionDefinition const& _function) { if (!shouldVisit(_function)) return; // This is the case for base constructor inlining. if (m_currentFunction != &_function) { solAssert(m_currentFunction && m_currentFunction->isConstructor(), ""); solAssert(_function.isConstructor(), ""); solAssert(_function.scope() != m_currentContract, ""); } else { // We create an extra exit block for constructors that simply // connects to the interface in case an explicit constructor // exists in the hierarchy. // It is not connected directly here, as normal functions are, // because of the case where there are only implicit constructors. // This is done in endVisit(ContractDefinition). if (_function.isConstructor()) { auto constructorExit = createSymbolicBlock(interfaceSort(), "constructor_exit_" + to_string(_function.id())); connectBlocks(m_currentBlock, predicate(*constructorExit, currentStateVariables())); clearIndices(m_currentContract, m_currentFunction); auto stateExprs = currentStateVariables(); setCurrentBlock(*constructorExit, &stateExprs); } else { connectBlocks(m_currentBlock, interface()); clearIndices(m_currentContract, m_currentFunction); auto stateExprs = currentStateVariables(); setCurrentBlock(*m_interfacePredicate, &stateExprs); } m_currentFunction = nullptr; } SMTEncoder::endVisit(_function); } bool CHC::visit(IfStatement const& _if) { solAssert(m_currentFunction, ""); bool unknownFunctionCallWasSeen = m_unknownFunctionCallSeen; m_unknownFunctionCallSeen = false; solAssert(m_currentFunction, ""); auto const& functionBody = m_currentFunction->body(); auto ifHeaderBlock = createBlock(&_if, "if_header_"); auto trueBlock = createBlock(&_if.trueStatement(), "if_true_"); auto falseBlock = _if.falseStatement() ? createBlock(_if.falseStatement(), "if_false_") : nullptr; auto afterIfBlock = createBlock(&functionBody); connectBlocks(m_currentBlock, predicate(*ifHeaderBlock)); setCurrentBlock(*ifHeaderBlock); _if.condition().accept(*this); auto condition = expr(_if.condition()); connectBlocks(m_currentBlock, predicate(*trueBlock), condition); if (_if.falseStatement()) connectBlocks(m_currentBlock, predicate(*falseBlock), !condition); else connectBlocks(m_currentBlock, predicate(*afterIfBlock), !condition); setCurrentBlock(*trueBlock); _if.trueStatement().accept(*this); connectBlocks(m_currentBlock, predicate(*afterIfBlock)); if (_if.falseStatement()) { setCurrentBlock(*falseBlock); _if.falseStatement()->accept(*this); connectBlocks(m_currentBlock, predicate(*afterIfBlock)); } setCurrentBlock(*afterIfBlock); if (m_unknownFunctionCallSeen) eraseKnowledge(); m_unknownFunctionCallSeen = unknownFunctionCallWasSeen; return false; } bool CHC::visit(WhileStatement const& _while) { bool unknownFunctionCallWasSeen = m_unknownFunctionCallSeen; m_unknownFunctionCallSeen = false; solAssert(m_currentFunction, ""); auto const& functionBody = m_currentFunction->body(); auto namePrefix = string(_while.isDoWhile() ? "do_" : "") + "while"; auto loopHeaderBlock = createBlock(&_while, namePrefix + "_header_"); auto loopBodyBlock = createBlock(&_while.body(), namePrefix + "_body_"); auto afterLoopBlock = createBlock(&functionBody); auto outerBreakDest = m_breakDest; auto outerContinueDest = m_continueDest; m_breakDest = afterLoopBlock.get(); m_continueDest = loopHeaderBlock.get(); if (_while.isDoWhile()) _while.body().accept(*this); connectBlocks(m_currentBlock, predicate(*loopHeaderBlock)); setCurrentBlock(*loopHeaderBlock); _while.condition().accept(*this); auto condition = expr(_while.condition()); connectBlocks(m_currentBlock, predicate(*loopBodyBlock), condition); connectBlocks(m_currentBlock, predicate(*afterLoopBlock), !condition); // Loop body visit. setCurrentBlock(*loopBodyBlock); _while.body().accept(*this); m_breakDest = outerBreakDest; m_continueDest = outerContinueDest; // Back edge. connectBlocks(m_currentBlock, predicate(*loopHeaderBlock)); setCurrentBlock(*afterLoopBlock); if (m_unknownFunctionCallSeen) eraseKnowledge(); m_unknownFunctionCallSeen = unknownFunctionCallWasSeen; return false; } bool CHC::visit(ForStatement const& _for) { bool unknownFunctionCallWasSeen = m_unknownFunctionCallSeen; m_unknownFunctionCallSeen = false; solAssert(m_currentFunction, ""); auto const& functionBody = m_currentFunction->body(); auto loopHeaderBlock = createBlock(&_for, "for_header_"); auto loopBodyBlock = createBlock(&_for.body(), "for_body_"); auto afterLoopBlock = createBlock(&functionBody); auto postLoop = _for.loopExpression(); auto postLoopBlock = postLoop ? createBlock(postLoop, "for_post_") : nullptr; auto outerBreakDest = m_breakDest; auto outerContinueDest = m_continueDest; m_breakDest = afterLoopBlock.get(); m_continueDest = postLoop ? postLoopBlock.get() : loopHeaderBlock.get(); if (auto init = _for.initializationExpression()) init->accept(*this); connectBlocks(m_currentBlock, predicate(*loopHeaderBlock)); setCurrentBlock(*loopHeaderBlock); auto condition = smt::Expression(true); if (auto forCondition = _for.condition()) { forCondition->accept(*this); condition = expr(*forCondition); } connectBlocks(m_currentBlock, predicate(*loopBodyBlock), condition); connectBlocks(m_currentBlock, predicate(*afterLoopBlock), !condition); // Loop body visit. setCurrentBlock(*loopBodyBlock); _for.body().accept(*this); if (postLoop) { connectBlocks(m_currentBlock, predicate(*postLoopBlock)); setCurrentBlock(*postLoopBlock); postLoop->accept(*this); } m_breakDest = outerBreakDest; m_continueDest = outerContinueDest; // Back edge. connectBlocks(m_currentBlock, predicate(*loopHeaderBlock)); setCurrentBlock(*afterLoopBlock); if (m_unknownFunctionCallSeen) eraseKnowledge(); m_unknownFunctionCallSeen = unknownFunctionCallWasSeen; return false; } void CHC::endVisit(FunctionCall const& _funCall) { solAssert(_funCall.annotation().kind != FunctionCallKind::Unset, ""); if (_funCall.annotation().kind != FunctionCallKind::FunctionCall) { SMTEncoder::endVisit(_funCall); return; } FunctionType const& funType = dynamic_cast(*_funCall.expression().annotation().type); switch (funType.kind()) { case FunctionType::Kind::Assert: visitAssert(_funCall); SMTEncoder::endVisit(_funCall); break; case FunctionType::Kind::Internal: case FunctionType::Kind::External: case FunctionType::Kind::DelegateCall: case FunctionType::Kind::BareCall: case FunctionType::Kind::BareCallCode: case FunctionType::Kind::BareDelegateCall: case FunctionType::Kind::BareStaticCall: case FunctionType::Kind::Creation: case FunctionType::Kind::KECCAK256: case FunctionType::Kind::ECRecover: case FunctionType::Kind::SHA256: case FunctionType::Kind::RIPEMD160: case FunctionType::Kind::BlockHash: case FunctionType::Kind::AddMod: case FunctionType::Kind::MulMod: SMTEncoder::endVisit(_funCall); unknownFunctionCall(_funCall); break; default: SMTEncoder::endVisit(_funCall); break; } createReturnedExpressions(_funCall); } void CHC::endVisit(Break const& _break) { solAssert(m_breakDest, ""); connectBlocks(m_currentBlock, predicate(*m_breakDest)); auto breakGhost = createBlock(&_break, "break_ghost_"); m_currentBlock = predicate(*breakGhost); } void CHC::endVisit(Continue const& _continue) { solAssert(m_continueDest, ""); connectBlocks(m_currentBlock, predicate(*m_continueDest)); auto continueGhost = createBlock(&_continue, "continue_ghost_"); m_currentBlock = predicate(*continueGhost); } void CHC::visitAssert(FunctionCall const& _funCall) { auto const& args = _funCall.arguments(); solAssert(args.size() == 1, ""); solAssert(args.front()->annotation().type->category() == Type::Category::Bool, ""); createErrorBlock(); smt::Expression assertNeg = !(m_context.expression(*args.front())->currentValue()); connectBlocks(m_currentBlock, error(), currentPathConditions() && assertNeg); m_verificationTargets.push_back(&_funCall); } void CHC::unknownFunctionCall(FunctionCall const&) { /// Function calls are not handled at the moment, /// so always erase knowledge. /// TODO remove when function calls get predicates/blocks. eraseKnowledge(); /// Used to erase outer scope knowledge in loops and ifs. /// TODO remove when function calls get predicates/blocks. m_unknownFunctionCallSeen = true; } void CHC::reset() { m_stateSorts.clear(); m_stateVariables.clear(); m_verificationTargets.clear(); m_safeAssertions.clear(); m_unknownFunctionCallSeen = false; m_breakDest = nullptr; m_continueDest = nullptr; } void CHC::eraseKnowledge() { resetStateVariables(); m_context.resetVariables([&](VariableDeclaration const& _variable) { return _variable.hasReferenceOrMappingType(); }); } bool CHC::shouldVisit(ContractDefinition const& _contract) const { if ( _contract.isLibrary() || _contract.isInterface() ) return false; return true; } bool CHC::shouldVisit(FunctionDefinition const& _function) const { if ( _function.isPublic() && _function.isImplemented() ) return true; return false; } void CHC::setCurrentBlock( smt::SymbolicFunctionVariable const& _block, vector const* _arguments ) { m_context.popSolver(); solAssert(m_currentContract, ""); clearIndices(m_currentContract, m_currentFunction); m_context.pushSolver(); if (_arguments) m_currentBlock = predicate(_block, *_arguments); else m_currentBlock = predicate(_block); } smt::SortPointer CHC::constructorSort() { // TODO this will change once we support function calls. return interfaceSort(); } smt::SortPointer CHC::interfaceSort() { auto boolSort = make_shared(smt::Kind::Bool); return make_shared( m_stateSorts, boolSort ); } smt::SortPointer CHC::sort(FunctionDefinition const& _function) { auto boolSort = make_shared(smt::Kind::Bool); vector varSorts; for (auto const& var: _function.parameters() + _function.returnParameters()) { // SMT solvers do not support function types as arguments. if (var->type()->category() == Type::Category::Function) varSorts.push_back(make_shared(smt::Kind::Int)); else varSorts.push_back(smt::smtSort(*var->type())); } return make_shared( m_stateSorts + varSorts, boolSort ); } smt::SortPointer CHC::sort(ASTNode const* _node) { if (auto funDef = dynamic_cast(_node)) return sort(*funDef); auto fSort = dynamic_pointer_cast(sort(*m_currentFunction)); solAssert(fSort, ""); auto boolSort = make_shared(smt::Kind::Bool); vector varSorts; for (auto const& var: m_currentFunction->localVariables()) { // SMT solvers do not support function types as arguments. if (var->type()->category() == Type::Category::Function) varSorts.push_back(make_shared(smt::Kind::Int)); else varSorts.push_back(smt::smtSort(*var->type())); } return make_shared( fSort->domain + varSorts, boolSort ); } unique_ptr CHC::createSymbolicBlock(smt::SortPointer _sort, string const& _name) { auto block = make_unique( _sort, _name, m_context ); m_interface->registerRelation(block->currentFunctionValue()); return block; } smt::Expression CHC::interface() { vector paramExprs; for (auto const& var: m_stateVariables) paramExprs.push_back(m_context.variable(*var)->currentValue()); return (*m_interfacePredicate)(paramExprs); } smt::Expression CHC::error() { return (*m_errorPredicate)({}); } smt::Expression CHC::error(unsigned _idx) { return m_errorPredicate->functionValueAtIndex(_idx)({}); } unique_ptr CHC::createBlock(ASTNode const* _node, string const& _prefix) { return createSymbolicBlock(sort(_node), "block_" + uniquePrefix() + "_" + _prefix + predicateName(_node)); } void CHC::createErrorBlock() { solAssert(m_errorPredicate, ""); m_errorPredicate->increaseIndex(); m_interface->registerRelation(m_errorPredicate->currentFunctionValue()); } void CHC::connectBlocks(smt::Expression const& _from, smt::Expression const& _to, smt::Expression const& _constraints) { smt::Expression edge = smt::Expression::implies( _from && m_context.assertions() && _constraints, _to ); addRule(edge, _from.name + "_to_" + _to.name); } vector CHC::currentStateVariables() { solAssert(m_currentContract, ""); vector exprs; for (auto const& var: m_stateVariables) exprs.push_back(m_context.variable(*var)->currentValue()); return exprs; } vector CHC::currentFunctionVariables() { vector paramExprs; if (m_currentFunction) for (auto const& var: m_currentFunction->parameters() + m_currentFunction->returnParameters()) paramExprs.push_back(m_context.variable(*var)->currentValue()); return currentStateVariables() + paramExprs; } vector CHC::currentBlockVariables() { vector paramExprs; if (m_currentFunction) for (auto const& var: m_currentFunction->localVariables()) paramExprs.push_back(m_context.variable(*var)->currentValue()); return currentFunctionVariables() + paramExprs; } string CHC::predicateName(ASTNode const* _node) { string prefix; if (auto funDef = dynamic_cast(_node)) { prefix += TokenTraits::toString(funDef->kind()); if (!funDef->name().empty()) prefix += "_" + funDef->name() + "_"; } return prefix + to_string(_node->id()); } smt::Expression CHC::predicate(smt::SymbolicFunctionVariable const& _block) { return _block(currentBlockVariables()); } smt::Expression CHC::predicate( smt::SymbolicFunctionVariable const& _block, vector const& _arguments ) { return _block(_arguments); } void CHC::addRule(smt::Expression const& _rule, string const& _ruleName) { m_interface->addRule(_rule, _ruleName); } bool CHC::query(smt::Expression const& _query, langutil::SourceLocation const& _location) { smt::CheckResult result; vector values; tie(result, values) = m_interface->query(_query); switch (result) { case smt::CheckResult::SATISFIABLE: break; case smt::CheckResult::UNSATISFIABLE: return true; case smt::CheckResult::UNKNOWN: break; case smt::CheckResult::CONFLICTING: m_outerErrorReporter.warning(_location, "At least two SMT solvers provided conflicting answers. Results might not be sound."); break; case smt::CheckResult::ERROR: m_outerErrorReporter.warning(_location, "Error trying to invoke SMT solver."); break; } return false; } string CHC::uniquePrefix() { return to_string(m_blockCounter++); }