#include "src/modelchecker/prctl/SparseMdpPrctlModelChecker.h" #include "src/utility/constants.h" #include "src/utility/macros.h" #include "src/utility/vector.h" #include "src/utility/graph.h" #include "src/modelchecker/results/ExplicitQualitativeCheckResult.h" #include "src/modelchecker/results/ExplicitQuantitativeCheckResult.h" #include "src/modelchecker/prctl/helper/SparseMdpPrctlHelper.h" #include "src/solver/LpSolver.h" #include "src/settings/modules/GeneralSettings.h" #include "src/exceptions/InvalidStateException.h" #include "src/exceptions/InvalidPropertyException.h" #include "src/storage/expressions/Expressions.h" #include "src/storage/MaximalEndComponentDecomposition.h" #include "src/exceptions/InvalidArgumentException.h" namespace storm { namespace modelchecker { template SparseMdpPrctlModelChecker::SparseMdpPrctlModelChecker(SparseMdpModelType const& model) : SparsePropositionalModelChecker(model), minMaxLinearEquationSolverFactory(new storm::utility::solver::MinMaxLinearEquationSolverFactory()) { // Intentionally left empty. } template SparseMdpPrctlModelChecker::SparseMdpPrctlModelChecker(SparseMdpModelType const& model, std::unique_ptr>&& minMaxLinearEquationSolverFactory) : SparsePropositionalModelChecker(model), minMaxLinearEquationSolverFactory(std::move(minMaxLinearEquationSolverFactory)) { // Intentionally left empty. } template bool SparseMdpPrctlModelChecker::canHandle(storm::logic::Formula const& formula) const { return formula.isPctlStateFormula() || formula.isPctlPathFormula() || formula.isRewardPathFormula(); } template std::unique_ptr SparseMdpPrctlModelChecker::computeBoundedUntilProbabilities(storm::logic::BoundedUntilFormula const& pathFormula, bool qualitative, boost::optional const& optimalityType) { STORM_LOG_THROW(optimalityType, storm::exceptions::InvalidArgumentException, "Formula needs to specify whether minimal or maximal values are to be computed on nondeterministic model."); std::unique_ptr leftResultPointer = this->check(pathFormula.getLeftSubformula()); std::unique_ptr rightResultPointer = this->check(pathFormula.getRightSubformula()); ExplicitQualitativeCheckResult const& leftResult = leftResultPointer->asExplicitQualitativeCheckResult(); ExplicitQualitativeCheckResult const& rightResult = rightResultPointer->asExplicitQualitativeCheckResult(); std::vector numericResult = storm::modelchecker::helper::SparseMdpPrctlHelper::computeBoundedUntilProbabilities(optimalityType.get() == storm::logic::OptimalityType::Minimize, this->getModel().getTransitionMatrix(), this->getModel().getBackwardTransitions(), leftResult.getTruthValuesVector(), rightResult.getTruthValuesVector(), pathFormula.getDiscreteTimeBound(), *minMaxLinearEquationSolverFactory); return std::unique_ptr(new ExplicitQuantitativeCheckResult(std::move(numericResult))); } template std::unique_ptr SparseMdpPrctlModelChecker::computeNextProbabilities(storm::logic::NextFormula const& pathFormula, bool qualitative, boost::optional const& optimalityType) { STORM_LOG_THROW(optimalityType, storm::exceptions::InvalidArgumentException, "Formula needs to specify whether minimal or maximal values are to be computed on nondeterministic model."); std::unique_ptr subResultPointer = this->check(pathFormula.getSubformula()); ExplicitQualitativeCheckResult const& subResult = subResultPointer->asExplicitQualitativeCheckResult(); std::vector numericResult = storm::modelchecker::helper::SparseMdpPrctlHelper::computeNextProbabilities(optimalityType.get() == storm::logic::OptimalityType::Minimize, this->getModel().getTransitionMatrix(), subResult.getTruthValuesVector(), *minMaxLinearEquationSolverFactory); return std::unique_ptr(new ExplicitQuantitativeCheckResult(std::move(numericResult))); } template std::unique_ptr SparseMdpPrctlModelChecker::computeUntilProbabilities(storm::logic::UntilFormula const& pathFormula, bool qualitative, boost::optional const& optimalityType) { STORM_LOG_THROW(optimalityType, storm::exceptions::InvalidArgumentException, "Formula needs to specify whether minimal or maximal values are to be computed on nondeterministic model."); std::unique_ptr leftResultPointer = this->check(pathFormula.getLeftSubformula()); std::unique_ptr rightResultPointer = this->check(pathFormula.getRightSubformula()); ExplicitQualitativeCheckResult const& leftResult = leftResultPointer->asExplicitQualitativeCheckResult(); ExplicitQualitativeCheckResult const& rightResult = rightResultPointer->asExplicitQualitativeCheckResult(); std::vector numericResult = storm::modelchecker::helper::SparseMdpPrctlHelper::computeUntilProbabilities(optimalityType.get() == storm::logic::OptimalityType::Minimize, this->getModel().getTransitionMatrix(), this->getModel().getBackwardTransitions(), leftResult.getTruthValuesVector(), rightResult.getTruthValuesVector(), qualitative, *minMaxLinearEquationSolverFactory); return std::unique_ptr(new ExplicitQuantitativeCheckResult(std::move(numericResult))); } template std::unique_ptr SparseMdpPrctlModelChecker::computeCumulativeRewards(storm::logic::CumulativeRewardFormula const& rewardPathFormula, boost::optional const& rewardModelName, bool qualitative, boost::optional const& optimalityType) { STORM_LOG_THROW(optimalityType, storm::exceptions::InvalidArgumentException, "Formula needs to specify whether minimal or maximal values are to be computed on nondeterministic model."); STORM_LOG_THROW(rewardPathFormula.hasDiscreteTimeBound(), storm::exceptions::InvalidArgumentException, "Formula needs to have a discrete time bound."); std::vector numericResult = storm::modelchecker::helper::SparseMdpPrctlHelper::computeCumulativeRewards(optimalityType.get() == storm::logic::OptimalityType::Minimize, this->getModel().getTransitionMatrix(), rewardModelName ? this->getModel().getRewardModel(rewardModelName.get()) : this->getModel().getRewardModel(""), rewardPathFormula.getDiscreteTimeBound(), *minMaxLinearEquationSolverFactory); return std::unique_ptr(new ExplicitQuantitativeCheckResult(std::move(numericResult))); } template std::unique_ptr SparseMdpPrctlModelChecker::computeInstantaneousRewards(storm::logic::InstantaneousRewardFormula const& rewardPathFormula, boost::optional const& rewardModelName, bool qualitative, boost::optional const& optimalityType) { STORM_LOG_THROW(optimalityType, storm::exceptions::InvalidArgumentException, "Formula needs to specify whether minimal or maximal values are to be computed on nondeterministic model."); STORM_LOG_THROW(rewardPathFormula.hasDiscreteTimeBound(), storm::exceptions::InvalidArgumentException, "Formula needs to have a discrete time bound."); std::vector numericResult = storm::modelchecker::helper::SparseMdpPrctlHelper::computeInstantaneousRewards(optimalityType.get() == storm::logic::OptimalityType::Minimize, this->getModel().getTransitionMatrix(), rewardModelName ? this->getModel().getRewardModel(rewardModelName.get()) : this->getModel().getRewardModel(""), rewardPathFormula.getDiscreteTimeBound(), *minMaxLinearEquationSolverFactory); return std::unique_ptr(new ExplicitQuantitativeCheckResult(std::move(numericResult))); } template std::unique_ptr SparseMdpPrctlModelChecker::computeReachabilityRewards(storm::logic::ReachabilityRewardFormula const& rewardPathFormula, boost::optional const& rewardModelName, bool qualitative, boost::optional const& optimalityType) { STORM_LOG_THROW(optimalityType, storm::exceptions::InvalidArgumentException, "Formula needs to specify whether minimal or maximal values are to be computed on nondeterministic model."); std::unique_ptr subResultPointer = this->check(rewardPathFormula.getSubformula()); ExplicitQualitativeCheckResult const& subResult = subResultPointer->asExplicitQualitativeCheckResult(); std::vector numericResult = storm::modelchecker::helper::SparseMdpPrctlHelper::computeReachabilityRewards(optimalityType.get() == storm::logic::OptimalityType::Minimize, this->getModel().getTransitionMatrix(), this->getModel().getBackwardTransitions(), rewardModelName ? this->getModel().getRewardModel(rewardModelName.get()) : this->getModel().getRewardModel(""), subResult.getTruthValuesVector(), qualitative, *minMaxLinearEquationSolverFactory); return std::unique_ptr(new ExplicitQuantitativeCheckResult(std::move(numericResult))); } template std::unique_ptr SparseMdpPrctlModelChecker::computeLongRunAverage(storm::logic::StateFormula const& stateFormula, bool qualitative, boost::optional const& optimalityType) { STORM_LOG_THROW(optimalityType, storm::exceptions::InvalidArgumentException, "Formula needs to specify whether minimal or maximal values are to be computed on nondeterministic model."); std::unique_ptr subResultPointer = this->check(stateFormula); ExplicitQualitativeCheckResult const& subResult = subResultPointer->asExplicitQualitativeCheckResult(); std::vector numericResult = storm::modelchecker::helper::SparseMdpPrctlHelper::computeLongRunAverage(optimalityType.get() == storm::logic::OptimalityType::Minimize, this->getModel().getTransitionMatrix(), this->getModel().getBackwardTransitions(), subResult.getTruthValuesVector(), qualitative, *minMaxLinearEquationSolverFactory); return std::unique_ptr(new ExplicitQuantitativeCheckResult(std::move(numericResult))); } template class SparseMdpPrctlModelChecker>; } }