//===-- MetaSMTSolver.cpp -------------------------------------------------===// // // The KLEE Symbolic Virtual Machine // // This file is distributed under the University of Illinois Open Source // License. See LICENSE.TXT for details. // //===----------------------------------------------------------------------===// #include "klee/Config/config.h" #ifdef ENABLE_METASMT #include "MetaSMTSolver.h" #include "MetaSMTBuilder.h" #include "klee/Constraints.h" #include "klee/Internal/Support/ErrorHandling.h" #include "klee/Solver.h" #include "klee/SolverImpl.h" #include "klee/util/Assignment.h" #include "klee/util/ExprUtil.h" #include "llvm/Support/ErrorHandling.h" #include #ifdef METASMT_HAVE_Z3 #include #endif #ifdef METASMT_HAVE_BTOR #include #endif #ifdef METASMT_HAVE_CVC4 #include #endif #ifdef METASMT_HAVE_YICES2 #include #endif #ifdef METASMT_HAVE_STP #define Expr VCExpr #define Type VCType #define STP STP_Backend #define type_t STP_type_t #include #undef Expr #undef Type #undef STP #undef type_t #endif #include #include #include #include #include #include static unsigned char *shared_memory_ptr; static int shared_memory_id = 0; // Darwin by default has a very small limit on the maximum amount of shared // memory, which will quickly be exhausted by KLEE running its tests in // parallel. For now, we work around this by just requesting a smaller size -- // in practice users hitting this limit on counterexample sizes probably already // are hitting more serious scalability issues. #ifdef __APPLE__ static const unsigned shared_memory_size = 1 << 16; #else static const unsigned shared_memory_size = 1 << 20; #endif namespace klee { template class MetaSMTSolverImpl : public SolverImpl { private: SolverContext _meta_solver; MetaSMTSolver *_solver; MetaSMTBuilder *_builder; double _timeout; bool _useForked; SolverRunStatus _runStatusCode; public: MetaSMTSolverImpl(MetaSMTSolver *solver, bool useForked, bool optimizeDivides); virtual ~MetaSMTSolverImpl(); char *getConstraintLog(const Query &); void setCoreSolverTimeout(double timeout) { _timeout = timeout; } bool computeTruth(const Query &, bool &isValid); bool computeValue(const Query &, ref &result); bool computeInitialValues(const Query &query, const std::vector &objects, std::vector > &values, bool &hasSolution); SolverImpl::SolverRunStatus runAndGetCex(const Query &query, const std::vector &objects, std::vector > &values, bool &hasSolution); SolverImpl::SolverRunStatus runAndGetCexForked(const Query &query, const std::vector &objects, std::vector > &values, bool &hasSolution, double timeout); SolverRunStatus getOperationStatusCode(); SolverContext &get_meta_solver() { return (_meta_solver); }; }; template MetaSMTSolverImpl::MetaSMTSolverImpl( MetaSMTSolver *solver, bool useForked, bool optimizeDivides) : _solver(solver), _builder(new MetaSMTBuilder( _meta_solver, optimizeDivides)), _timeout(0.0), _useForked(useForked) { assert(_solver && "unable to create MetaSMTSolver"); assert(_builder && "unable to create MetaSMTBuilder"); if (_useForked) { shared_memory_id = shmget(IPC_PRIVATE, shared_memory_size, IPC_CREAT | 0700); assert(shared_memory_id >= 0 && "shmget failed"); shared_memory_ptr = (unsigned char *)shmat(shared_memory_id, NULL, 0); assert(shared_memory_ptr != (void *)-1 && "shmat failed"); shmctl(shared_memory_id, IPC_RMID, NULL); } } template MetaSMTSolverImpl::~MetaSMTSolverImpl() {} template char *MetaSMTSolverImpl::getConstraintLog(const Query &) { const char *msg = "Not supported"; char *buf = new char[strlen(msg) + 1]; strcpy(buf, msg); return (buf); } template bool MetaSMTSolverImpl::computeTruth(const Query &query, bool &isValid) { bool success = false; std::vector objects; std::vector > values; bool hasSolution; if (computeInitialValues(query, objects, values, hasSolution)) { // query.expr is valid iff !query.expr is not satisfiable isValid = !hasSolution; success = true; } return (success); } template bool MetaSMTSolverImpl::computeValue(const Query &query, ref &result) { bool success = false; std::vector objects; std::vector > values; bool hasSolution; // Find the object used in the expression, and compute an assignment for them. findSymbolicObjects(query.expr, objects); if (computeInitialValues(query.withFalse(), objects, values, hasSolution)) { assert(hasSolution && "state has invalid constraint set"); // Evaluate the expression with the computed assignment. Assignment a(objects, values); result = a.evaluate(query.expr); success = true; } return (success); } template bool MetaSMTSolverImpl::computeInitialValues( const Query &query, const std::vector &objects, std::vector > &values, bool &hasSolution) { _runStatusCode = SOLVER_RUN_STATUS_FAILURE; TimerStatIncrementer t(stats::queryTime); assert(_builder); ++stats::queries; ++stats::queryCounterexamples; bool success = true; if (_useForked) { _runStatusCode = runAndGetCexForked(query, objects, values, hasSolution, _timeout); success = ((SOLVER_RUN_STATUS_SUCCESS_SOLVABLE == _runStatusCode) || (SOLVER_RUN_STATUS_SUCCESS_UNSOLVABLE == _runStatusCode)); } else { _runStatusCode = runAndGetCex(query, objects, values, hasSolution); success = true; } if (success) { if (hasSolution) { ++stats::queriesInvalid; } else { ++stats::queriesValid; } } return (success); } template SolverImpl::SolverRunStatus MetaSMTSolverImpl::runAndGetCex( const Query &query, const std::vector &objects, std::vector > &values, bool &hasSolution) { // assume the constraints of the query for (ConstraintManager::const_iterator it = query.constraints.begin(), ie = query.constraints.end(); it != ie; ++it) { assumption(_meta_solver, _builder->construct(*it)); } // assume the negation of the query assumption(_meta_solver, _builder->construct(Expr::createIsZero(query.expr))); hasSolution = solve(_meta_solver); if (hasSolution) { values.reserve(objects.size()); for (std::vector::const_iterator it = objects.begin(), ie = objects.end(); it != ie; ++it) { const Array *array = *it; assert(array); typename SolverContext::result_type array_exp = _builder->getInitialArray(array); std::vector data; data.reserve(array->size); for (unsigned offset = 0; offset < array->size; offset++) { typename SolverContext::result_type elem_exp = evaluate( _meta_solver, metaSMT::logic::Array::select( array_exp, bvuint(offset, array->getDomain()))); unsigned char elem_value = metaSMT::read_value(_meta_solver, elem_exp); data.push_back(elem_value); } values.push_back(data); } } if (true == hasSolution) { return (SolverImpl::SOLVER_RUN_STATUS_SUCCESS_SOLVABLE); } else { return (SolverImpl::SOLVER_RUN_STATUS_SUCCESS_UNSOLVABLE); } } static void metaSMTTimeoutHandler(int x) { _exit(52); } template SolverImpl::SolverRunStatus MetaSMTSolverImpl::runAndGetCexForked( const Query &query, const std::vector &objects, std::vector > &values, bool &hasSolution, double timeout) { unsigned char *pos = shared_memory_ptr; unsigned sum = 0; for (std::vector::const_iterator it = objects.begin(), ie = objects.end(); it != ie; ++it) { sum += (*it)->size; } // sum += sizeof(uint64_t); sum += sizeof(stats::queryConstructs); assert(sum < shared_memory_size && "not enough shared memory for counterexample"); fflush(stdout); fflush(stderr); int pid = fork(); if (pid == -1) { klee_warning("fork failed (for metaSMT)"); return (SolverImpl::SOLVER_RUN_STATUS_FORK_FAILED); } if (pid == 0) { if (timeout) { ::alarm(0); /* Turn off alarm so we can safely set signal handler */ ::signal(SIGALRM, metaSMTTimeoutHandler); ::alarm(std::max(1, (int)timeout)); } // assert constraints as we are in a child process for (ConstraintManager::const_iterator it = query.constraints.begin(), ie = query.constraints.end(); it != ie; ++it) { assertion(_meta_solver, _builder->construct(*it)); // assumption(_meta_solver, _builder->construct(*it)); } // asssert the negation of the query as we are in a child process assertion(_meta_solver, _builder->construct(Expr::createIsZero(query.expr))); unsigned res = solve(_meta_solver); if (res) { for (std::vector::const_iterator it = objects.begin(), ie = objects.end(); it != ie; ++it) { const Array *array = *it; assert(array); typename SolverContext::result_type array_exp = _builder->getInitialArray(array); for (unsigned offset = 0; offset < array->size; offset++) { typename SolverContext::result_type elem_exp = evaluate( _meta_solver, metaSMT::logic::Array::select( array_exp, bvuint(offset, array->getDomain()))); unsigned char elem_value = metaSMT::read_value(_meta_solver, elem_exp); *pos++ = elem_value; } } } assert((uint64_t *)pos); *((uint64_t *)pos) = stats::queryConstructs; _exit(!res); } else { int status; pid_t res; do { res = waitpid(pid, &status, 0); } while (res < 0 && errno == EINTR); if (res < 0) { klee_warning("waitpid() for metaSMT failed"); return (SolverImpl::SOLVER_RUN_STATUS_WAITPID_FAILED); } // From timed_run.py: It appears that linux at least will on // "occasion" return a status when the process was terminated by a // signal, so test signal first. if (WIFSIGNALED(status) || !WIFEXITED(status)) { klee_warning( "error: metaSMT did not return successfully (status = %d) \n", WTERMSIG(status)); return (SolverImpl::SOLVER_RUN_STATUS_INTERRUPTED); } int exitcode = WEXITSTATUS(status); if (exitcode == 0) { hasSolution = true; } else if (exitcode == 1) { hasSolution = false; } else if (exitcode == 52) { klee_warning("metaSMT timed out"); return (SolverImpl::SOLVER_RUN_STATUS_TIMEOUT); } else { klee_warning("metaSMT did not return a recognized code"); return (SolverImpl::SOLVER_RUN_STATUS_UNEXPECTED_EXIT_CODE); } if (hasSolution) { values = std::vector >(objects.size()); unsigned i = 0; for (std::vector::const_iterator it = objects.begin(), ie = objects.end(); it != ie; ++it) { const Array *array = *it; assert(array); std::vector &data = values[i++]; data.insert(data.begin(), pos, pos + array->size); pos += array->size; } } stats::queryConstructs += (*((uint64_t *)pos) - stats::queryConstructs); if (true == hasSolution) { return SolverImpl::SOLVER_RUN_STATUS_SUCCESS_SOLVABLE; } else { return SolverImpl::SOLVER_RUN_STATUS_SUCCESS_UNSOLVABLE; } } } template SolverImpl::SolverRunStatus MetaSMTSolverImpl::getOperationStatusCode() { return _runStatusCode; } template MetaSMTSolver::MetaSMTSolver(bool useForked, bool optimizeDivides) : Solver(new MetaSMTSolverImpl(this, useForked, optimizeDivides)) {} template MetaSMTSolver::~MetaSMTSolver() {} template char *MetaSMTSolver::getConstraintLog(const Query &query) { return (impl->getConstraintLog(query)); } template void MetaSMTSolver::setCoreSolverTimeout(double timeout) { impl->setCoreSolverTimeout(timeout); } Solver *createMetaSMTSolver() { using namespace metaSMT; Solver *coreSolver = NULL; std::string backend; switch (MetaSMTBackend) { #ifdef METASMT_HAVE_STP case METASMT_BACKEND_STP: backend = "STP"; coreSolver = new MetaSMTSolver >( UseForkedCoreSolver, CoreSolverOptimizeDivides); break; #endif #ifdef METASMT_HAVE_Z3 case METASMT_BACKEND_Z3: backend = "Z3"; coreSolver = new MetaSMTSolver >( UseForkedCoreSolver, CoreSolverOptimizeDivides); break; #endif #ifdef METASMT_HAVE_BTOR case METASMT_BACKEND_BOOLECTOR: backend = "Boolector"; coreSolver = new MetaSMTSolver >( UseForkedCoreSolver, CoreSolverOptimizeDivides); break; #endif #ifdef METASMT_HAVE_CVC4 case METASMT_BACKEND_CVC4: backend = "CVC4"; coreSolver = new MetaSMTSolver >( UseForkedCoreSolver, CoreSolverOptimizeDivides); break; #endif #ifdef METASMT_HAVE_YICES2 case METASMT_BACKEND_YICES2: backend = "Yices2"; coreSolver = new MetaSMTSolver >( UseForkedCoreSolver, CoreSolverOptimizeDivides); break; #endif default: llvm_unreachable("Unrecognised MetaSMT backend"); break; }; klee_message("Starting MetaSMTSolver(%s)", backend.c_str()); return coreSolver; } } #endif // ENABLE_METASMT