/* 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 /** * Model checker based on Constrained Horn Clauses. * * A Solidity contract's CFG is encoded into a system of Horn clauses where * each block has a predicate and edges are rules. * * The entry block is the constructor which has no in-edges. * The constructor has one out-edge to an artificial block named _Interface_ * which has in/out-edges from/to all public functions. * * Loop invariants for Interface -> Interface' are state invariants. */ #pragma once #include #include #include #include #include #include #include #include namespace solidity::frontend { class CHC: public SMTEncoder { public: CHC( smt::EncodingContext& _context, langutil::ErrorReporter& _errorReporter, std::map const& _smtlib2Responses, ReadCallback::Callback const& _smtCallback, smtutil::SMTSolverChoice _enabledSolvers, std::optional timeout ); void analyze(SourceUnit const& _sources); std::map> const& safeTargets() const { return m_safeTargets; } std::map> const& unsafeTargets() const { return m_unsafeTargets; } /// This is used if the Horn solver is not directly linked into this binary. /// @returns a list of inputs to the Horn solver that were not part of the argument to /// the constructor. std::vector unhandledQueries() const; private: /// Visitor functions. //@{ bool visit(ContractDefinition const& _node) override; void endVisit(ContractDefinition const& _node) override; bool visit(FunctionDefinition const& _node) override; void endVisit(FunctionDefinition const& _node) override; bool visit(IfStatement const& _node) override; bool visit(WhileStatement const&) override; bool visit(ForStatement const&) override; void endVisit(FunctionCall const& _node) override; void endVisit(Break const& _node) override; void endVisit(Continue const& _node) override; void endVisit(IndexRangeAccess const& _node) override; void visitAssert(FunctionCall const& _funCall); void visitAddMulMod(FunctionCall const& _funCall) override; void internalFunctionCall(FunctionCall const& _funCall); void externalFunctionCall(FunctionCall const& _funCall); void externalFunctionCallToTrustedCode(FunctionCall const& _funCall); void unknownFunctionCall(FunctionCall const& _funCall); void makeArrayPopVerificationTarget(FunctionCall const& _arrayPop) override; /// Creates underflow/overflow verification targets. std::pair arithmeticOperation( Token _op, smtutil::Expression const& _left, smtutil::Expression const& _right, TypePointer const& _commonType, Expression const& _expression ) override; //@} /// Helpers. //@{ void resetSourceAnalysis(); void resetContractAnalysis(); void eraseKnowledge(); void clearIndices(ContractDefinition const* _contract, FunctionDefinition const* _function = nullptr) override; void setCurrentBlock(Predicate const& _block); std::set transactionVerificationTargetsIds(ASTNode const* _txRoot); //@} /// Sort helpers. //@{ smtutil::SortPointer sort(FunctionDefinition const& _function); smtutil::SortPointer sort(ASTNode const* _block); //@} /// Predicate helpers. //@{ /// @returns a new block of given _sort and _name. Predicate const* createSymbolicBlock(smtutil::SortPointer _sort, std::string const& _name, PredicateType _predType, ASTNode const* _node = nullptr); /// Creates summary predicates for all functions of all contracts /// in a given _source. void defineInterfacesAndSummaries(SourceUnit const& _source); /// Interface predicate over current variables. smtutil::Expression interface(); smtutil::Expression interface(ContractDefinition const& _contract); /// Error predicate over current variables. smtutil::Expression error(); smtutil::Expression error(unsigned _idx); /// Creates a block for the given _node. Predicate const* createBlock(ASTNode const* _node, PredicateType _predType, std::string const& _prefix = ""); /// Creates a call block for the given function _function from contract _contract. /// The contract is needed here because of inheritance. Predicate const* createSummaryBlock(FunctionDefinition const& _function, ContractDefinition const& _contract); /// Creates a new error block to be used by an assertion. /// Also registers the predicate. void createErrorBlock(); void connectBlocks(smtutil::Expression const& _from, smtutil::Expression const& _to, smtutil::Expression const& _constraints = smtutil::Expression(true)); /// @returns the symbolic values of the state variables at the beginning /// of the current transaction. std::vector initialStateVariables(); std::vector stateVariablesAtIndex(unsigned _index); std::vector stateVariablesAtIndex(unsigned _index, ContractDefinition const& _contract); /// @returns the current symbolic values of the current state variables. std::vector currentStateVariables(); std::vector currentStateVariables(ContractDefinition const& _contract); /// @returns the predicate name for a given node. std::string predicateName(ASTNode const* _node, ContractDefinition const* _contract = nullptr); /// @returns a predicate application after checking the predicate's type. smtutil::Expression predicate(Predicate const& _block); /// @returns the summary predicate for the called function. smtutil::Expression predicate(FunctionCall const& _funCall); /// @returns a predicate that defines a constructor summary. smtutil::Expression summary(ContractDefinition const& _contract); /// @returns a predicate that defines a function summary. smtutil::Expression summary(FunctionDefinition const& _function); smtutil::Expression summary(FunctionDefinition const& _function, ContractDefinition const& _contract); //@} /// Solver related. //@{ /// Adds Horn rule to the solver. void addRule(smtutil::Expression const& _rule, std::string const& _ruleName); /// @returns if query is unsatisfiable (safe). /// @returns otherwise. std::pair query(smtutil::Expression const& _query, langutil::SourceLocation const& _location); void verificationTargetEncountered(ASTNode const* const _errorNode, VerificationTarget::Type _type, smtutil::Expression const& _errorCondition); void checkVerificationTargets(); // Forward declaration. Definition is below. struct CHCVerificationTarget; void checkAssertTarget(ASTNode const* _scope, CHCVerificationTarget const& _target); void checkAndReportTarget( CHCVerificationTarget const& _target, langutil::ErrorId _errorReporterId, std::string _satMsg, std::string _unknownMsg = "" ); std::optional generateCounterexample(smtutil::CHCSolverInterface::CexGraph const& _graph, std::string const& _root); /// @returns a set of pairs _var = _value separated by _separator. template std::string formatVariableModel(std::vector const& _variables, std::vector> const& _values, std::string const& _separator) const { solAssert(_variables.size() == _values.size(), ""); std::vector assignments; for (unsigned i = 0; i < _values.size(); ++i) { auto var = _variables.at(i); if (var && _values.at(i)) assignments.emplace_back(var->name() + " = " + *_values.at(i)); } return boost::algorithm::join(assignments, _separator); } /// @returns a DAG in the dot format. /// Used for debugging purposes. std::string cex2dot(smtutil::CHCSolverInterface::CexGraph const& _graph); //@} /// Misc. //@{ /// @returns a prefix to be used in a new unique block name /// and increases the block counter. std::string uniquePrefix(); /// @returns a suffix to be used by contract related predicates. std::string contractSuffix(ContractDefinition const& _contract); /// @returns a new unique error id associated with _expr and stores /// it into m_errorIds. unsigned newErrorId(); smt::SymbolicState& state(); smt::SymbolicIntVariable& errorFlag(); //@} /// Predicates. //@{ /// Constructor summary predicate, exists after the constructor /// (implicit or explicit) and before the interface. Predicate const* m_constructorSummaryPredicate = nullptr; /// Artificial Interface predicate. /// Single entry block for all functions. std::map m_interfaces; /// Nondeterministic interfaces. /// These are used when the analyzed contract makes external calls to unknown code, /// which means that the analyzed contract can potentially be called /// nondeterministically. std::map m_nondetInterfaces; /// Artificial Error predicate. /// Single error block for all assertions. Predicate const* m_errorPredicate = nullptr; /// Function predicates. std::map> m_summaries; //@} /// Variables. //@{ /// State variables. /// Used to create all predicates. std::vector m_stateVariables; //@} /// Verification targets. //@{ struct CHCVerificationTarget: VerificationTarget { unsigned const errorId; ASTNode const* const errorNode; }; /// Query placeholder stores information necessary to create the final query edge in the CHC system. /// It is combined with the unique error id (and error type) to create a complete Verification Target. struct CHCQueryPlaceholder { smtutil::Expression const constraints; smtutil::Expression const errorExpression; smtutil::Expression const fromPredicate; }; /// Query placeholders for constructors, if the key has type ContractDefinition*, /// or external functions, if the key has type FunctionDefinition*. /// A placeholder is created for each possible context of a function (e.g. multiple contracts in contract inheritance hierarchy). std::map, smt::EncodingContext::IdCompare> m_queryPlaceholders; /// Records verification conditions IDs per function encountered during an analysis of that function. /// The key is the ASTNode of the function where the verification condition has been encountered, /// or the ASTNode of the contract if the verification condition happens inside an implicit constructor. std::map, smt::EncodingContext::IdCompare> m_functionTargetIds; /// Helper mapping unique IDs to actual verification targets. std::map m_verificationTargets; /// Targets proven safe. std::map> m_safeTargets; /// Targets proven unsafe. std::map> m_unsafeTargets; //@} /// Control-flow. //@{ FunctionDefinition const* m_currentFunction = nullptr; std::map, smt::EncodingContext::IdCompare> m_callGraph; /// The current block. smtutil::Expression m_currentBlock = smtutil::Expression(true); /// Counter to generate unique block names. unsigned m_blockCounter = 0; /// Whether a function call was seen in the current scope. bool m_unknownFunctionCallSeen = false; /// Block where a loop break should go to. Predicate const* m_breakDest; /// Block where a loop continue should go to. Predicate const* m_continueDest; //@} /// CHC solver. std::unique_ptr m_interface; /// ErrorReporter that comes from CompilerStack. langutil::ErrorReporter& m_outerErrorReporter; /// SMT solvers that are chosen at runtime. smtutil::SMTSolverChoice m_enabledSolvers; /// SMT query timeout in seconds. std::optional m_queryTimeout; }; }