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Update MonotonicityChecker

tempestpy_adaptions
Jip Spel 6 years ago
parent
commit
77a70179d3
  1. 618
      src/storm-pars/analysis/MonotonicityChecker.cpp
  2. 18
      src/storm-pars/analysis/MonotonicityChecker.h
  3. 87
      src/test/storm-pars/analysis/MonotonicityCheckerTest.cpp

618
src/storm-pars/analysis/MonotonicityChecker.cpp

@ -27,112 +27,35 @@
namespace storm { namespace storm {
namespace analysis { namespace analysis {
template <typename ValueType> template <typename ValueType>
MonotonicityChecker<ValueType>::MonotonicityChecker(std::shared_ptr<storm::models::ModelBase> model, std::vector<std::shared_ptr<storm::logic::Formula const>> formulas, bool validate) {
MonotonicityChecker<ValueType>::MonotonicityChecker(std::shared_ptr<storm::models::ModelBase> model, std::vector<std::shared_ptr<storm::logic::Formula const>> formulas, bool validate, uint_fast64_t numberOfSamples) {
outfile.open(filename, std::ios_base::app); outfile.open(filename, std::ios_base::app);
assert (model != nullptr);
this->model = model; this->model = model;
this->formulas = formulas; this->formulas = formulas;
this->validate = validate; this->validate = validate;
this->resultCheckOnSamples = std::map<carl::Variable, std::pair<bool, bool>>();
// TODO initialiseren van sample check
if (model != nullptr) {
std::shared_ptr<storm::models::sparse::Model<ValueType>> sparseModel = model->as<storm::models::sparse::Model<ValueType>>();
this->extender = new storm::analysis::LatticeExtender<ValueType>(sparseModel);
outfile << model->getNumberOfStates() << ", " << model->getNumberOfTransitions() << ", ";
// sampling
if ( model->isOfType(storm::models::ModelType::Dtmc)) {
this->resultCheckOnSamples = std::map<carl::Variable, std::pair<bool, bool>>(checkOnSamples(model->as<storm::models::sparse::Dtmc<ValueType>>(), numberOfSamples));
} else if (model->isOfType(storm::models::ModelType::Mdp)){
this->resultCheckOnSamples = std::map<carl::Variable, std::pair<bool, bool>>(checkOnSamples(model->as<storm::models::sparse::Mdp<ValueType>>(), numberOfSamples));
} }
std::shared_ptr<storm::models::sparse::Model<ValueType>> sparseModel = model->as<storm::models::sparse::Model<ValueType>>();
this->extender = new storm::analysis::LatticeExtender<ValueType>(sparseModel);
outfile << model->getNumberOfStates() << ", " << model->getNumberOfTransitions() << ", ";
outfile.close(); outfile.close();
totalWatch = storm::utility::Stopwatch(true);
} }
template <typename ValueType> template <typename ValueType>
std::map<storm::analysis::Lattice*, std::map<carl::Variable, std::pair<bool, bool>>> MonotonicityChecker<ValueType>::checkMonotonicity() { std::map<storm::analysis::Lattice*, std::map<carl::Variable, std::pair<bool, bool>>> MonotonicityChecker<ValueType>::checkMonotonicity() {
// TODO: check on samples or not?
totalWatch = storm::utility::Stopwatch(true);
auto latticeWatch = storm::utility::Stopwatch(true);
auto map = createLattice(); auto map = createLattice();
// STORM_PRINT(std::endl << "Time for creating lattice: " << latticeWatch << "." << std::endl << std::endl);
std::shared_ptr<storm::models::sparse::Model<ValueType>> sparseModel = model->as<storm::models::sparse::Model<ValueType>>(); std::shared_ptr<storm::models::sparse::Model<ValueType>> sparseModel = model->as<storm::models::sparse::Model<ValueType>>();
auto matrix = sparseModel->getTransitionMatrix(); auto matrix = sparseModel->getTransitionMatrix();
return checkMonotonicity(map, matrix); return checkMonotonicity(map, matrix);
} }
template <typename ValueType>
std::vector<storm::storage::ParameterRegion<ValueType>> MonotonicityChecker<ValueType>::checkAssumptionsOnRegion(std::vector<std::shared_ptr<storm::expressions::BinaryRelationExpression>> assumptions) {
assert (formulas[0]->isProbabilityOperatorFormula());
assert (formulas[0]->asProbabilityOperatorFormula().getSubformula().isUntilFormula() || formulas[0]->asProbabilityOperatorFormula().getSubformula().isEventuallyFormula());
Environment env = Environment();
std::shared_ptr<storm::models::sparse::Model<ValueType>> sparseModel = model->as<storm::models::sparse::Model<ValueType>>();
bool generateSplitEstimates = false;
bool allowModelSimplification = false;
auto task = storm::api::createTask<ValueType>(formulas[0], true);
// TODO: storm::RationalNumber or double?
// TODO: Also allow different models
STORM_LOG_THROW (sparseModel->isOfType(storm::models::ModelType::Dtmc), storm::exceptions::NotImplementedException,
"Checking assumptions on a region not implemented for this type of model");
auto modelChecker = storm::api::initializeParameterLiftingDtmcModelChecker<ValueType, storm::RationalNumber>(env, sparseModel, task, generateSplitEstimates, allowModelSimplification);
std::stack<std::pair<storm::storage::ParameterRegion<ValueType>, int>> regions;
std::vector<storm::storage::ParameterRegion<ValueType>> satRegions;
std::string regionText = "";
auto parameters = storm::models::sparse::getProbabilityParameters(*sparseModel);
for (auto itr = parameters.begin(); itr != parameters.end(); ++itr) {
if (regionText != "") {
regionText += ",";
}
// TODO: region bounds
regionText += "0.1 <= " + itr->name() + " <= 0.9";
}
auto initialRegion = storm::api::parseRegion<ValueType>(regionText, parameters);
regions.push(std::pair<storm::storage::ParameterRegion<ValueType>, int>(initialRegion,0));
while (!regions.empty()) {
auto lastElement = regions.top();
regions.pop();
storm::storage::ParameterRegion<ValueType> currentRegion = lastElement.first;
// TODO: depth
if (lastElement.second < 5) {
auto upperBound = modelChecker->getBound(env, currentRegion, storm::solver::OptimizationDirection::Maximize);
auto lowerBound = modelChecker->getBound(env, currentRegion, storm::solver::OptimizationDirection::Minimize);
std::vector<storm::RationalNumber> valuesUpper = upperBound->template asExplicitQuantitativeCheckResult<storm::RationalNumber>().getValueVector();
std::vector<storm::RationalNumber> valuesLower = lowerBound->template asExplicitQuantitativeCheckResult<storm::RationalNumber>().getValueVector();
bool assumptionsHold = true;
for (auto itr = assumptions.begin(); assumptionsHold && itr != assumptions.end(); ++itr) {
auto assumption = *itr;
if (assumption->getRelationType() == storm::expressions::BinaryRelationExpression::RelationType::Greater) {
auto state1 = std::stoi(
assumption->getFirstOperand()->asVariableExpression().getVariableName());
auto state2 = std::stoi(
assumption->getSecondOperand()->asVariableExpression().getVariableName());
assumptionsHold &= valuesLower[state1] >= valuesUpper[state2];
} else if (assumption->getRelationType() == storm::expressions::BinaryRelationExpression::RelationType::Equal) {
auto state1 = std::stoi(
assumption->getFirstOperand()->asVariableExpression().getVariableName());
auto state2 = std::stoi(
assumption->getSecondOperand()->asVariableExpression().getVariableName());
assumptionsHold &= valuesLower[state1] == valuesUpper[state2];
} else {
assert(false);
}
}
if (!assumptionsHold) {
std::vector<storm::storage::ParameterRegion<ValueType>> newRegions;
currentRegion.split(currentRegion.getCenterPoint(), newRegions);
for (auto itr = newRegions.begin(); itr != newRegions.end(); ++itr) {
regions.push(std::pair<storm::storage::ParameterRegion<ValueType>, int>(*itr,
lastElement.second +
1));
}
} else {
satRegions.push_back(currentRegion);
}
}
}
return satRegions;
}
template <typename ValueType> template <typename ValueType>
std::map<storm::analysis::Lattice*, std::map<carl::Variable, std::pair<bool, bool>>> MonotonicityChecker<ValueType>::checkMonotonicity(std::map<storm::analysis::Lattice*, std::vector<std::shared_ptr<storm::expressions::BinaryRelationExpression>>> map, storm::storage::SparseMatrix<ValueType> matrix) { std::map<storm::analysis::Lattice*, std::map<carl::Variable, std::pair<bool, bool>>> MonotonicityChecker<ValueType>::checkMonotonicity(std::map<storm::analysis::Lattice*, std::vector<std::shared_ptr<storm::expressions::BinaryRelationExpression>>> map, storm::storage::SparseMatrix<ValueType> matrix) {
storm::utility::Stopwatch monotonicityCheckWatch(true); storm::utility::Stopwatch monotonicityCheckWatch(true);
@ -142,8 +65,26 @@ namespace storm {
if (map.size() == 0) { if (map.size() == 0) {
// Nothing is known // Nothing is known
outfile << " No assumptions; ?";
// STORM_PRINT(std::endl << "Do not know about monotonicity" << std::endl);
outfile << " No assumptions -";
STORM_PRINT("No valid assumptions, couldn't build a sufficient lattice");
if (resultCheckOnSamples.size() != 0) {
STORM_PRINT("\n" << "Based results on samples");
} else {
outfile << " ?";
}
for (auto entry : resultCheckOnSamples) {
if (!entry.second.first && ! entry.second.second) {
outfile << " SX " << entry.first << " ";
} else if (entry.second.first && ! entry.second.second) {
outfile << " SI " << entry.first << " ";
} else if (entry.second.first && entry.second.second) {
outfile << " SC " << entry.first << " ";
} else {
outfile << " SD " << entry.first << " ";
}
}
} else { } else {
auto i = 0; auto i = 0;
for (auto itr = map.begin(); i < map.size() && itr != map.end(); ++itr) { for (auto itr = map.begin(); i < map.size() && itr != map.end(); ++itr) {
@ -160,43 +101,21 @@ namespace storm {
validSomewhere = itr2->second.first || itr2->second.second; validSomewhere = itr2->second.first || itr2->second.second;
} }
if (assumptions.size() > 0) { if (assumptions.size() > 0) {
// auto regions = checkAssumptionsOnRegion(assumptions);
// if (regions.size() > 0) {
// // STORM_PRINT("For regions: " << std::endl);
// bool first = true;
// for (auto itr2 = regions.begin(); itr2 != regions.end(); ++itr2) {
// if (first) {
// // STORM_PRINT(" ");
// first = false;
// }
// // STORM_PRINT(*itr2);
// outfile << (*itr2);
// }
// // STORM_PRINT(std::endl);
// outfile << ", ";
// } else {
// STORM_PRINT("Assumption(s): ");
bool first = true;
for (auto itr2 = assumptions.begin(); itr2 != assumptions.end(); ++itr2) {
if (!first) {
// STORM_PRINT(" ^ ");
outfile << (" ^ ");
} else {
first = false;
}
// STORM_PRINT(*(*itr2));
outfile << (*(*itr2));
bool first = true;
for (auto itr2 = assumptions.begin(); itr2 != assumptions.end(); ++itr2) {
if (!first) {
outfile << (" ^ ");
} else {
first = false;
} }
// STORM_PRINT(std::endl);
outfile << " - ";
// }
outfile << (*(*itr2));
}
outfile << " - ";
} else if (assumptions.size() == 0) { } else if (assumptions.size() == 0) {
outfile << "No assumptions - "; outfile << "No assumptions - ";
} }
if (validSomewhere && varsMonotone.size() == 0) { if (validSomewhere && varsMonotone.size() == 0) {
// STORM_PRINT("Result is constant" << std::endl);
outfile << "No params"; outfile << "No params";
} else if (validSomewhere) { } else if (validSomewhere) {
auto itr2 = varsMonotone.begin(); auto itr2 = varsMonotone.begin();
@ -204,21 +123,15 @@ namespace storm {
if (resultCheckOnSamples.find(itr2->first) != resultCheckOnSamples.end() && if (resultCheckOnSamples.find(itr2->first) != resultCheckOnSamples.end() &&
(!resultCheckOnSamples[itr2->first].first && (!resultCheckOnSamples[itr2->first].first &&
!resultCheckOnSamples[itr2->first].second)) { !resultCheckOnSamples[itr2->first].second)) {
// STORM_PRINT(" - Not monotone in: " << itr2->first << std::endl);
outfile << "X " << itr2->first; outfile << "X " << itr2->first;
} else { } else {
if (itr2->second.first && itr2->second.second) { if (itr2->second.first && itr2->second.second) {
// STORM_PRINT(" - Constant in" << itr2->first << std::endl);
outfile << "C " << itr2->first; outfile << "C " << itr2->first;
} else if (itr2->second.first) { } else if (itr2->second.first) {
// STORM_PRINT(" - Monotone increasing in: " << itr2->first << std::endl);
outfile << "I " << itr2->first; outfile << "I " << itr2->first;
} else if (itr2->second.second) { } else if (itr2->second.second) {
// STORM_PRINT(" - Monotone decreasing in: " << itr2->first << std::endl);
outfile << "D " << itr2->first; outfile << "D " << itr2->first;
} else { } else {
// STORM_PRINT(" - Do not know if monotone incr/decreasing in: " << itr2->first << std::endl);
outfile << "? " << itr2->first; outfile << "? " << itr2->first;
} }
} }
@ -244,7 +157,6 @@ namespace storm {
monotonicityCheckWatch.stop(); monotonicityCheckWatch.stop();
outfile << monotonicityCheckWatch << ", "; outfile << monotonicityCheckWatch << ", ";
// STORM_PRINT(std::endl << "Time for monotonicity check on lattice: " << monotonicityCheckWatch << "." << std::endl << std::endl);
outfile.close(); outfile.close();
return result; return result;
} }
@ -283,7 +195,6 @@ namespace storm {
assert(false); assert(false);
} }
latticeWatch.stop(); latticeWatch.stop();
// STORM_PRINT(std::endl << "Total time for lattice creation: " << latticeWatch << "." << std::endl << std::endl);
outfile.open(filename, std::ios_base::app); outfile.open(filename, std::ios_base::app);
outfile << latticeWatch << ", "; outfile << latticeWatch << ", ";
outfile.close(); outfile.close();
@ -300,7 +211,7 @@ namespace storm {
assert (lattice->getAddedStates()->size() == lattice->getAddedStates()->getNumberOfSetBits()); assert (lattice->getAddedStates()->size() == lattice->getAddedStates()->getNumberOfSetBits());
result.insert(std::pair<storm::analysis::Lattice*, std::vector<std::shared_ptr<storm::expressions::BinaryRelationExpression>>>(lattice, assumptions)); result.insert(std::pair<storm::analysis::Lattice*, std::vector<std::shared_ptr<storm::expressions::BinaryRelationExpression>>>(lattice, assumptions));
} else { } else {
// Make the three assumptions
auto assumptionTriple = assumptionMaker->createAndCheckAssumption(val1, val2, lattice); auto assumptionTriple = assumptionMaker->createAndCheckAssumption(val1, val2, lattice);
assert (assumptionTriple.size() == 3); assert (assumptionTriple.size() == 3);
auto itr = assumptionTriple.begin(); auto itr = assumptionTriple.begin();
@ -310,152 +221,55 @@ namespace storm {
++itr; ++itr;
auto assumption3 = *itr; auto assumption3 = *itr;
auto assumptionsCopy = std::vector<std::shared_ptr<storm::expressions::BinaryRelationExpression>>(
assumptions);
auto assumptionsCopy2 = std::vector<std::shared_ptr<storm::expressions::BinaryRelationExpression>>(
assumptions);
if (assumption1.second != AssumptionStatus::INVALID) {
auto latticeCopy = new Lattice(lattice);
auto assumptionsCopy = std::vector<std::shared_ptr<storm::expressions::BinaryRelationExpression>>(assumptions);
auto latticeCopy = new storm::analysis::Lattice(lattice);
auto latticeCopy2 = new storm::analysis::Lattice(lattice);
assumptions.push_back(assumption1.first);
assumptionsCopy.push_back(assumption2.first);
assumptionsCopy2.push_back(assumption3.first);
if (assumption1.second == AssumptionStatus::UNKNOWN) {
// only add assumption to the set of assumptions if it is unknown if it is valid
assumptionsCopy.push_back(assumption1.first);
}
auto criticalTuple = extender->extendLattice(lattice, assumption1.first);
if (assumption1.second != AssumptionStatus::INVALID && somewhereMonotonicity(std::get<0>(criticalTuple))) {
auto map = extendLatticeWithAssumptions(std::get<0>(criticalTuple), assumptionMaker,
std::get<1>(criticalTuple), std::get<2>(criticalTuple),
assumptions);
result.insert(map.begin(), map.end());
auto criticalTuple = extender->extendLattice(latticeCopy, assumption1.first);
if (somewhereMonotonicity(std::get<0>(criticalTuple))) {
auto map = extendLatticeWithAssumptions(std::get<0>(criticalTuple), assumptionMaker,
std::get<1>(criticalTuple), std::get<2>(criticalTuple),
assumptionsCopy);
result.insert(map.begin(), map.end());
}
} }
// TODO: checkend at ie niet invalid is
criticalTuple = extender->extendLattice(latticeCopy, assumption2.first);
if (assumption2.second != AssumptionStatus::INVALID && somewhereMonotonicity(std::get<0>(criticalTuple))) {
auto map = extendLatticeWithAssumptions(std::get<0>(criticalTuple), assumptionMaker,
std::get<1>(criticalTuple), std::get<2>(criticalTuple),
assumptionsCopy);
result.insert(map.begin(), map.end());
}
criticalTuple = extender->extendLattice(latticeCopy2, assumption3.first);
if (assumption3.second != AssumptionStatus::INVALID && somewhereMonotonicity(std::get<0>(criticalTuple))) {
auto map = extendLatticeWithAssumptions(std::get<0>(criticalTuple), assumptionMaker,
std::get<1>(criticalTuple), std::get<2>(criticalTuple),
assumptionsCopy2);
result.insert(map.begin(), map.end());
if (assumption2.second != AssumptionStatus::INVALID) {
auto latticeCopy = new Lattice(lattice);
auto assumptionsCopy = std::vector<std::shared_ptr<storm::expressions::BinaryRelationExpression>>(assumptions);
if (assumption2.second == AssumptionStatus::UNKNOWN) {
assumptionsCopy.push_back(assumption2.first);
}
auto criticalTuple = extender->extendLattice(latticeCopy, assumption2.first);
if (somewhereMonotonicity(std::get<0>(criticalTuple))) {
auto map = extendLatticeWithAssumptions(std::get<0>(criticalTuple), assumptionMaker,
std::get<1>(criticalTuple), std::get<2>(criticalTuple),
assumptionsCopy);
result.insert(map.begin(), map.end());
}
} }
if (assumption3.second != AssumptionStatus::INVALID) {
// Here we can use the original lattice and assumptions set
if (assumption3.second == AssumptionStatus::UNKNOWN) {
assumptions.push_back(assumption3.first);
}
// if (!assumption1.second && !assumption2.second && !assumption3.second) {
// // Both assumption cannot be validated, so we need to keep them both
// // TODO: hier niet verder gaan als je iets gevonden hebt?
// auto assumptionsCopy = std::vector<std::shared_ptr<storm::expressions::BinaryRelationExpression>>(
// assumptions);
// auto assumptionsCopy2 = std::vector<std::shared_ptr<storm::expressions::BinaryRelationExpression>>(
// assumptions);
// auto latticeCopy = new storm::analysis::Lattice(lattice);
// auto latticeCopy2 = new storm::analysis::Lattice(lattice);
// assumptions.push_back(assumption1.first);
// assumptionsCopy.push_back(assumption2.first);
// assumptionsCopy2.push_back(assumption3.first);
//
// auto criticalTuple = extender->extendLattice(lattice, assumption1.first);
// if (somewhereMonotonicity(std::get<0>(criticalTuple))) {
// auto map = extendLatticeWithAssumptions(std::get<0>(criticalTuple), assumptionMaker,
// std::get<1>(criticalTuple), std::get<2>(criticalTuple),
// assumptions);
// result.insert(map.begin(), map.end());
// }
//
// criticalTuple = extender->extendLattice(latticeCopy, assumption2.first);
// if (somewhereMonotonicity(std::get<0>(criticalTuple))) {
// auto map = extendLatticeWithAssumptions(std::get<0>(criticalTuple), assumptionMaker,
// std::get<1>(criticalTuple), std::get<2>(criticalTuple),
// assumptionsCopy);
// result.insert(map.begin(), map.end());
// }
// criticalTuple = extender->extendLattice(latticeCopy2, assumption3.first);
// if (somewhereMonotonicity(std::get<0>(criticalTuple))) {
// auto map = extendLatticeWithAssumptions(std::get<0>(criticalTuple), assumptionMaker,
// std::get<1>(criticalTuple), std::get<2>(criticalTuple),
// assumptionsCopy2);
// result.insert(map.begin(), map.end());
// }
//// }
// } else if (!assumption3.second && assumption1.second && assumption2.second) {
//// assert (false);
// //TODO Both assumptions hold --> should not happen if we change it to < instead of <=
// auto assumption = assumptionMaker->createEqualAssumption(val1, val2);
// if (!validate) {
// assumptions.push_back(assumption);
// }
// // if validate is true and both hold, then they must be valid, so no need to add to assumptions
// auto criticalTuple = extender->extendLattice(lattice, assumption);
// if (somewhereMonotonicity(std::get<0>(criticalTuple))) {
// result = extendLatticeWithAssumptions(std::get<0>(criticalTuple), assumptionMaker, std::get<1>(criticalTuple), std::get<2>(criticalTuple), assumptions);
// }
// } else if (!assumption3.second && !assumption2.second && assumption1.second) {
// if (!validate) {
//// assert(false);
// assumptions.push_back(assumption1.first);
// }
// // if validate is true and both hold, then they must be valid, so no need to add to assumptions
//
// auto criticalTuple = extender->extendLattice(lattice, assumption1.first);
//
// if (somewhereMonotonicity(std::get<0>(criticalTuple))) {
// result = extendLatticeWithAssumptions(std::get<0>(criticalTuple), assumptionMaker, std::get<1>(criticalTuple), std::get<2>(criticalTuple), assumptions);
// }
//
// } else if (!assumption3.second && !assumption1.second && assumption2.second){
//// assert (assumption2.second);
// if (!validate) {
// assumptions.push_back(assumption2.first);
// }
// // if validate is true and both hold, then they must be valid, so no need to add to assumptions
// auto criticalTuple = extender->extendLattice(lattice, assumption2.first);
// if (somewhereMonotonicity(std::get<0>(criticalTuple))) {
// result = extendLatticeWithAssumptions(std::get<0>(criticalTuple), assumptionMaker, std::get<1>(criticalTuple), std::get<2>(criticalTuple), assumptions);
// }
// } else {
// // TODO: should not happen
// STORM_LOG_WARN("All assumptions are true");// {" << *(assumption1.first) <<", " << *(assumption2.first) << ", " << *(assumption3.first) << "}" << std::endl);
// // Both assumption cannot be validated, so we need to keep them both
// // TODO: hier niet verder gaan als je iets gevonden hebt?
// auto assumptionsCopy = std::vector<std::shared_ptr<storm::expressions::BinaryRelationExpression>>(
// assumptions);
// auto assumptionsCopy2 = std::vector<std::shared_ptr<storm::expressions::BinaryRelationExpression>>(
// assumptions);
// auto latticeCopy = new storm::analysis::Lattice(lattice);
// auto latticeCopy2 = new storm::analysis::Lattice(lattice);
// assumptions.push_back(assumption1.first);
// assumptionsCopy.push_back(assumption2.first);
// assumptionsCopy2.push_back(assumption2.first);
//
// auto criticalTuple = extender->extendLattice(lattice, assumption1.first);
// if (somewhereMonotonicity(std::get<0>(criticalTuple))) {
// auto map = extendLatticeWithAssumptions(std::get<0>(criticalTuple), assumptionMaker,
// std::get<1>(criticalTuple), std::get<2>(criticalTuple),
// assumptions);
// result.insert(map.begin(), map.end());
// }
//
// criticalTuple = extender->extendLattice(latticeCopy, assumption2.first);
// if (somewhereMonotonicity(std::get<0>(criticalTuple))) {
// auto map = extendLatticeWithAssumptions(std::get<0>(criticalTuple), assumptionMaker,
// std::get<1>(criticalTuple), std::get<2>(criticalTuple),
// assumptionsCopy);
// result.insert(map.begin(), map.end());
// }
// criticalTuple = extender->extendLattice(latticeCopy2, assumption3.first);
// if (somewhereMonotonicity(std::get<0>(criticalTuple))) {
// auto map = extendLatticeWithAssumptions(std::get<0>(criticalTuple), assumptionMaker,
// std::get<1>(criticalTuple), std::get<2>(criticalTuple),
// assumptionsCopy2);
// result.insert(map.begin(), map.end());
// }
// }
auto criticalTuple = extender->extendLattice(lattice, assumption3.first);
if (somewhereMonotonicity(std::get<0>(criticalTuple))) {
auto map = extendLatticeWithAssumptions(std::get<0>(criticalTuple), assumptionMaker,
std::get<1>(criticalTuple), std::get<2>(criticalTuple),
assumptions);
result.insert(map.begin(), map.end());
}
}
} }
return result; return result;
} }
@ -474,17 +288,17 @@ namespace storm {
template <typename ValueType> template <typename ValueType>
std::map<carl::Variable, std::pair<bool, bool>> MonotonicityChecker<ValueType>::analyseMonotonicity(uint_fast64_t j, storm::analysis::Lattice* lattice, storm::storage::SparseMatrix<ValueType> matrix) { std::map<carl::Variable, std::pair<bool, bool>> MonotonicityChecker<ValueType>::analyseMonotonicity(uint_fast64_t j, storm::analysis::Lattice* lattice, storm::storage::SparseMatrix<ValueType> matrix) {
// storm::utility::Stopwatch analyseWatch(true);
std::map<carl::Variable, std::pair<bool, bool>> varsMonotone; std::map<carl::Variable, std::pair<bool, bool>> varsMonotone;
// go over all rows, check for each row local monotonicity
for (uint_fast64_t i = 0; i < matrix.getColumnCount(); ++i) { for (uint_fast64_t i = 0; i < matrix.getColumnCount(); ++i) {
// go over all rows
auto row = matrix.getRow(i); auto row = matrix.getRow(i);
// only enter if you are in a state with at least two successors (so there must be successors, // only enter if you are in a state with at least two successors (so there must be successors,
// and first prob shouldnt be 1)
// and first prob shouldn't be 1)
if (row.begin() != row.end() && !row.begin()->getValue().isOne()) { if (row.begin() != row.end() && !row.begin()->getValue().isOne()) {
std::map<uint_fast64_t, ValueType> transitions; std::map<uint_fast64_t, ValueType> transitions;
// Gather all states which are reached with a non constant probability
auto states = new storm::storage::BitVector(matrix.getColumnCount()); auto states = new storm::storage::BitVector(matrix.getColumnCount());
std::set<carl::Variable> vars; std::set<carl::Variable> vars;
for (auto const& entry : row) { for (auto const& entry : row) {
@ -498,94 +312,79 @@ namespace storm {
} }
} }
auto sortedStates = lattice->sortStates(states);
if (sortedStates[sortedStates.size() - 1] == matrix.getColumnCount()) {\
// states are not properly sorted
for (auto itr = vars.begin(); itr != vars.end(); ++itr) {
// if (resultCheckOnSamples.find(*itr) != resultCheckOnSamples.end() &&
// (!resultCheckOnSamples[*itr].first && !resultCheckOnSamples[*itr].second)) {
// if (varsMonotone.find(*itr) == varsMonotone.end()) {
// varsMonotone[*itr].first = false;
// varsMonotone[*itr].second = false;
// }
// } else {
if (varsMonotone.find(*itr) == varsMonotone.end()) {
varsMonotone[*itr].first = true;
varsMonotone[*itr].second = true;
}
std::pair<bool, bool> *value = &varsMonotone.find(*itr)->second;
std::pair<bool, bool> old = *value;
// Copy info from checkOnSamples
for (auto itr = vars.begin(); itr != vars.end(); ++itr) {
assert (resultCheckOnSamples.find(*itr) != resultCheckOnSamples.end());
if (varsMonotone.find(*itr) == varsMonotone.end()) {
varsMonotone[*itr].first = resultCheckOnSamples[*itr].first;
varsMonotone[*itr].second = resultCheckOnSamples[*itr].second;
} else {
varsMonotone[*itr].first &= resultCheckOnSamples[*itr].first;
varsMonotone[*itr].second &= resultCheckOnSamples[*itr].second;
}
}
// Sort the states based on the lattice
auto sortedStates = lattice->sortStates(states);
if (sortedStates[sortedStates.size() - 1] == matrix.getColumnCount()) {
// If the states are not all sorted, we still might obtain some monotonicity
for (auto var: vars) {
// current value of monotonicity
std::pair<bool, bool> *value = &varsMonotone.find(var)->second;
for (auto itr2 = transitions.begin(); itr2 != transitions.end(); ++itr2) {
for (auto itr3 = transitions.begin(); itr3 != transitions.end(); ++itr3) {
// Go over all transitions to successor states, compare all of them
for (auto itr2 = transitions.begin(); (value->first || value->second)
&& itr2 != transitions.end(); ++itr2) {
for (auto itr3 = transitions.begin(); (value->first || value->second)
&& itr3 != transitions.end(); ++itr3) {
if (itr2->first < itr3->first) { if (itr2->first < itr3->first) {
auto derivative2 = getDerivative(itr2->second, *itr);
auto derivative3 = getDerivative(itr3->second, *itr);
auto derivative2 = getDerivative(itr2->second, var);
auto derivative3 = getDerivative(itr3->second, var);
auto compare = lattice->compare(itr2->first, itr3->first); auto compare = lattice->compare(itr2->first, itr3->first);
if (compare == storm::analysis::Lattice::ABOVE) {
// As the first state (itr2) is above the second state (itr3) it is sufficient to look at the derivative of itr2.
if (compare == Lattice::ABOVE) {
// As the first state (itr2) is above the second state (itr3) it
// is sufficient to look at the derivative of itr2.
std::pair<bool, bool> mon2; std::pair<bool, bool> mon2;
if (derivative2.isConstant()) {
mon2 = std::pair<bool, bool>(derivative2.constantPart() >= 0,
derivative2.constantPart() <= 0);
} else {
mon2 = checkDerivative(derivative2);
}
mon2 = checkDerivative(derivative2);
value->first &= mon2.first; value->first &= mon2.first;
value->second &= mon2.second; value->second &= mon2.second;
} else if (compare == storm::analysis::Lattice::BELOW) {
// As the second state (itr3) is above the first state (itr2) it is sufficient to look at the derivative of itr3.
} else if (compare == Lattice::BELOW) {
// As the second state (itr3) is above the first state (itr2) it
// is sufficient to look at the derivative of itr3.
std::pair<bool, bool> mon3; std::pair<bool, bool> mon3;
if (derivative2.isConstant()) {
mon3 = std::pair<bool, bool>(derivative3.constantPart() >= 0,
derivative3.constantPart() <= 0);
} else {
mon3 = checkDerivative(derivative3);
}
mon3 = checkDerivative(derivative3);
value->first &= mon3.first; value->first &= mon3.first;
value->second &= mon3.second; value->second &= mon3.second;
} else if (compare == storm::analysis::Lattice::SAME) {
assert (false);
// TODO: klopt dit
} else if (compare == Lattice::SAME) {
// Behaviour doesn't matter, as the states are at the same level. // Behaviour doesn't matter, as the states are at the same level.
} else { } else {
// As the relation between the states is unknown, we can't claim anything about the monotonicity.
value->first = false;
value->second = false;
// only if derivatives are the same we can continue
if (derivative2 != derivative3) {
// As the relation between the states is unknown, we can't claim
// anything about the monotonicity.
value->first = false;
value->second = false;
}
} }
} }
// }
} }
} }
} }
} else { } else {
// The states are all sorted
for (auto var : vars) { for (auto var : vars) {
// if (resultCheckOnSamples.find(*itr) != resultCheckOnSamples.end() &&
// (!resultCheckOnSamples[*itr].first && !resultCheckOnSamples[*itr].second)) {
// if (varsMonotone.find(*itr) == varsMonotone.end()) {
// varsMonotone[*itr].first = false;
// varsMonotone[*itr].second = false;
// }
// } else {
if (varsMonotone.find(var) == varsMonotone.end()) {
varsMonotone[var].first = true;
varsMonotone[var].second = true;
}
std::pair<bool, bool> *value = &varsMonotone.find(var)->second; std::pair<bool, bool> *value = &varsMonotone.find(var)->second;
bool change = false; bool change = false;
for (auto const &i : sortedStates) { for (auto const &i : sortedStates) {
// auto res = checkDerivative(transitions[i].derivative(var));
auto res = checkDerivative(getDerivative(transitions[i], var)); auto res = checkDerivative(getDerivative(transitions[i], var));
change = change || (!(value->first && value->second) // they do not hold both change = change || (!(value->first && value->second) // they do not hold both
&& ((value->first && !res.first)
|| (value->second && !res.second)));
&& ((value->first && !res.first)
|| (value->second && !res.second)));
if (change) { if (change) {
value->first &= res.second; value->first &= res.second;
@ -598,84 +397,19 @@ namespace storm {
break; break;
} }
} }
} }
} }
} }
} }
// analyseWatch.stop();
// STORM_PRINT(std::endl << "Time to check monotonicity based on the lattice: " << analyseWatch << "." << std::endl << std::endl);
// outfile << analyseWatch << "; ";
return varsMonotone; return varsMonotone;
} }
// template <typename ValueType>
// std::pair<bool, bool> MonotonicityChecker<ValueType>::checkDerivative(ValueType derivative) {
// bool monIncr = false;
// bool monDecr = false;
//
// if (derivative.isZero()) {
// monIncr = true;
// monDecr = true;
// } else if (derivative.isConstant()) {
// monIncr = derivative.constantPart() >= 0;
// monDecr = derivative.constantPart() <= 0;
// } else {
//
// std::shared_ptr<storm::utility::solver::SmtSolverFactory> smtSolverFactory = std::make_shared<storm::utility::solver::MathsatSmtSolverFactory>();
// std::shared_ptr<storm::expressions::ExpressionManager> manager(
// new storm::expressions::ExpressionManager());
//
// storm::solver::Z3SmtSolver s(*manager);
// storm::solver::SmtSolver::CheckResult smtResult = storm::solver::SmtSolver::CheckResult::Unknown;
//
// std::set<carl::Variable> variables = derivative.gatherVariables();
//
//
// for (auto variable : variables) {
// manager->declareRationalVariable(variable.name());
//
// }
// storm::expressions::Expression exprBounds = manager->boolean(true);
// auto managervars = manager->getVariables();
// for (auto var : managervars) {
// exprBounds = exprBounds && manager->rational(0) < var && var < manager->rational(1);
// }
//
// auto converter = storm::expressions::RationalFunctionToExpression<ValueType>(manager);
//
// storm::expressions::Expression exprToCheck1 =
// converter.toExpression(derivative) >= manager->rational(0);
// s.add(exprBounds);
// s.add(exprToCheck1);
// smtResult = s.check();
// monIncr = smtResult == storm::solver::SmtSolver::CheckResult::Sat;
//
// storm::expressions::Expression exprToCheck2 =
// converter.toExpression(derivative) <= manager->rational(0);
// s.reset();
// smtResult = storm::solver::SmtSolver::CheckResult::Unknown;
// s.add(exprBounds);
// s.add(exprToCheck2);
// smtResult = s.check();
// monDecr = smtResult == storm::solver::SmtSolver::CheckResult::Sat;
// if (monIncr && monDecr) {
// monIncr = false;
// monDecr = false;
// }
// }
// assert (!(monIncr && monDecr) || derivative.isZero());
//
// return std::pair<bool, bool>(monIncr, monDecr);
// }
template <typename ValueType> template <typename ValueType>
bool MonotonicityChecker<ValueType>::somewhereMonotonicity(storm::analysis::Lattice* lattice) {
bool MonotonicityChecker<ValueType>::somewhereMonotonicity(Lattice* lattice) {
std::shared_ptr<storm::models::sparse::Model<ValueType>> sparseModel = model->as<storm::models::sparse::Model<ValueType>>(); std::shared_ptr<storm::models::sparse::Model<ValueType>> sparseModel = model->as<storm::models::sparse::Model<ValueType>>();
auto matrix = sparseModel->getTransitionMatrix(); auto matrix = sparseModel->getTransitionMatrix();
// TODO: tussenresultaten hergebruiken
std::map<carl::Variable, std::pair<bool, bool>> varsMonotone; std::map<carl::Variable, std::pair<bool, bool>> varsMonotone;
for (uint_fast64_t i = 0; i < matrix.getColumnCount(); ++i) { for (uint_fast64_t i = 0; i < matrix.getColumnCount(); ++i) {
@ -691,46 +425,54 @@ namespace storm {
auto val = first.getValue(); auto val = first.getValue();
auto vars = val.gatherVariables(); auto vars = val.gatherVariables();
// Copy info from checkOnSamples
for (auto itr = vars.begin(); itr != vars.end(); ++itr) { for (auto itr = vars.begin(); itr != vars.end(); ++itr) {
assert (resultCheckOnSamples.find(*itr) != resultCheckOnSamples.end());
if (varsMonotone.find(*itr) == varsMonotone.end()) { if (varsMonotone.find(*itr) == varsMonotone.end()) {
varsMonotone[*itr].first = true;
varsMonotone[*itr].second = true;
varsMonotone[*itr].first = resultCheckOnSamples[*itr].first;
varsMonotone[*itr].second = resultCheckOnSamples[*itr].second;
} else {
varsMonotone[*itr].first &= resultCheckOnSamples[*itr].first;
varsMonotone[*itr].second &= resultCheckOnSamples[*itr].second;
} }
std::pair<bool, bool> *value = &varsMonotone.find(*itr)->second;
std::pair<bool, bool> old = *value;
// TODO deze ook aanpassen aan deel met smt solver
for (auto itr2 = transitions.begin(); itr2 != transitions.end(); ++itr2) {
for (auto itr3 = transitions.begin(); itr3 != transitions.end(); ++itr3) {
auto derivative2 = itr2->second.derivative(*itr);
auto derivative3 = itr3->second.derivative(*itr);
auto compare = lattice->compare(itr2->first, itr3->first);
if (compare == storm::analysis::Lattice::ABOVE) {
// As the first state (itr2) is above the second state (itr3) it is sufficient to look at the derivative of itr2.
std::pair<bool,bool> mon2;
if (derivative2.isConstant()) {
mon2 = std::pair<bool,bool>(derivative2.constantPart() >= 0, derivative2.constantPart() <=0);
} else {
}
for (auto var: vars) {
// current value of monotonicity
std::pair<bool, bool> *value = &varsMonotone.find(var)->second;
// Go over all transitions to successor states, compare all of them
for (auto itr2 = transitions.begin(); (value->first || value->second)
&& itr2 != transitions.end(); ++itr2) {
for (auto itr3 = transitions.begin(); (value->first || value->second)
&& itr3 != transitions.end(); ++itr3) {
if (itr2->first < itr3->first) {
auto derivative2 = getDerivative(itr2->second, var);
auto derivative3 = getDerivative(itr3->second, var);
auto compare = lattice->compare(itr2->first, itr3->first);
if (compare == Lattice::ABOVE) {
// As the first state (itr2) is above the second state (itr3) it
// is sufficient to look at the derivative of itr2.
std::pair<bool, bool> mon2;
mon2 = checkDerivative(derivative2); mon2 = checkDerivative(derivative2);
}
value->first &= mon2.first;
value->second &= mon2.second;
} else if (compare == storm::analysis::Lattice::BELOW) {
// As the second state (itr3) is above the first state (itr2) it is sufficient to look at the derivative of itr3.
std::pair<bool,bool> mon3;
if (derivative2.isConstant()) {
mon3 = std::pair<bool,bool>(derivative3.constantPart() >= 0, derivative3.constantPart() <=0);
} else {
value->first &= mon2.first;
value->second &= mon2.second;
} else if (compare == Lattice::BELOW) {
// As the second state (itr3) is above the first state (itr2) it
// is sufficient to look at the derivative of itr3.
std::pair<bool, bool> mon3;
mon3 = checkDerivative(derivative3); mon3 = checkDerivative(derivative3);
value->first &= mon3.first;
value->second &= mon3.second;
} else if (compare == Lattice::SAME) {
// Behaviour doesn't matter, as the states are at the same level.
} else {
// As the relation between the states is unknown, we don't do anything
} }
value->first &= mon3.first;
value->second &= mon3.second;
} else if (compare == storm::analysis::Lattice::SAME) {
// TODO: klopt dit
// Behaviour doesn't matter, as the states are at the same level.
} else {
// As the relation between the states is unknown, we don't do anything
} }
} }
} }
@ -804,7 +546,7 @@ namespace storm {
initial += values[i]; initial += values[i];
} }
float diff = previous - initial; float diff = previous - initial;
// TODO: define precission
// TODO: define precision
if (previous != -1 && diff > 0.000005 && diff < -0.000005) { if (previous != -1 && diff > 0.000005 && diff < -0.000005) {
monDecr &= previous >= initial; monDecr &= previous >= initial;
monIncr &= previous <= initial; monIncr &= previous <= initial;
@ -815,7 +557,6 @@ namespace storm {
} }
samplesWatch.stop(); samplesWatch.stop();
// STORM_PRINT(std::endl << "Time to check monotonicity on samples: " << samplesWatch << "." << std::endl << std::endl);
resultCheckOnSamples = result; resultCheckOnSamples = result;
return result; return result;
} }
@ -886,7 +627,6 @@ namespace storm {
} }
samplesWatch.stop(); samplesWatch.stop();
// STORM_PRINT(std::endl << "Time to check monotonicity on samples: " << samplesWatch << "." << std::endl << std::endl);
resultCheckOnSamples = result; resultCheckOnSamples = result;
return result; return result;
} }

18
src/storm-pars/analysis/MonotonicityChecker.h

@ -31,7 +31,7 @@ namespace storm {
class MonotonicityChecker { class MonotonicityChecker {
public: public:
MonotonicityChecker(std::shared_ptr<storm::models::ModelBase> model, std::vector<std::shared_ptr<storm::logic::Formula const>> formulas, bool validate);
MonotonicityChecker(std::shared_ptr<storm::models::ModelBase> model, std::vector<std::shared_ptr<storm::logic::Formula const>> formulas, bool validate, uint_fast64_t numberOfSamples = 100);
/*! /*!
* Checks for all lattices in the map if they are monotone increasing or monotone decreasing. * Checks for all lattices in the map if they are monotone increasing or monotone decreasing.
* *
@ -111,10 +111,6 @@ namespace storm {
assert (s.check() == storm::solver::SmtSolver::CheckResult::Sat); assert (s.check() == storm::solver::SmtSolver::CheckResult::Sat);
s.add(exprToCheck); s.add(exprToCheck);
monDecr = s.check() == storm::solver::SmtSolver::CheckResult::Unsat; monDecr = s.check() == storm::solver::SmtSolver::CheckResult::Unsat;
// if (monIncr && monDecr) {
// monIncr = false;
// monDecr = false;
// }
} }
assert (!(monIncr && monDecr) || derivative.isZero()); assert (!(monIncr && monDecr) || derivative.isZero());
@ -123,9 +119,9 @@ namespace storm {
private: private:
//TODO: variabele type //TODO: variabele type
std::map<carl::Variable, std::pair<bool, bool>> analyseMonotonicity(uint_fast64_t i, storm::analysis::Lattice* lattice, storm::storage::SparseMatrix<ValueType> matrix) ;
std::map<carl::Variable, std::pair<bool, bool>> analyseMonotonicity(uint_fast64_t i, Lattice* lattice, storm::storage::SparseMatrix<ValueType> matrix) ;
std::map<storm::analysis::Lattice*, std::vector<std::shared_ptr<storm::expressions::BinaryRelationExpression>>> createLattice();
std::map<Lattice*, std::vector<std::shared_ptr<storm::expressions::BinaryRelationExpression>>> createLattice();
std::map<carl::Variable, std::pair<bool, bool>> checkOnSamples(std::shared_ptr<storm::models::sparse::Dtmc<ValueType>> model, uint_fast64_t numberOfSamples); std::map<carl::Variable, std::pair<bool, bool>> checkOnSamples(std::shared_ptr<storm::models::sparse::Dtmc<ValueType>> model, uint_fast64_t numberOfSamples);
@ -135,9 +131,7 @@ namespace storm {
ValueType getDerivative(ValueType function, carl::Variable var); ValueType getDerivative(ValueType function, carl::Variable var);
std::vector<storm::storage::ParameterRegion<ValueType>> checkAssumptionsOnRegion(std::vector<std::shared_ptr<storm::expressions::BinaryRelationExpression>> assumptions);
std::map<storm::analysis::Lattice*, std::vector<std::shared_ptr<storm::expressions::BinaryRelationExpression>>> extendLatticeWithAssumptions(storm::analysis::Lattice* lattice, storm::analysis::AssumptionMaker<ValueType>* assumptionMaker, uint_fast64_t val1, uint_fast64_t val2, std::vector<std::shared_ptr<storm::expressions::BinaryRelationExpression>> assumptions);
std::map<Lattice*, std::vector<std::shared_ptr<storm::expressions::BinaryRelationExpression>>> extendLatticeWithAssumptions(Lattice* lattice, AssumptionMaker<ValueType>* assumptionMaker, uint_fast64_t val1, uint_fast64_t val2, std::vector<std::shared_ptr<storm::expressions::BinaryRelationExpression>> assumptions);
std::shared_ptr<storm::models::ModelBase> model; std::shared_ptr<storm::models::ModelBase> model;
@ -147,13 +141,11 @@ namespace storm {
std::map<carl::Variable, std::pair<bool, bool>> resultCheckOnSamples; std::map<carl::Variable, std::pair<bool, bool>> resultCheckOnSamples;
storm::analysis::LatticeExtender<ValueType> *extender;
LatticeExtender<ValueType> *extender;
std::ofstream outfile; std::ofstream outfile;
std::string filename = "results.txt"; std::string filename = "results.txt";
storm::utility::Stopwatch totalWatch;
}; };
} }
} }

87
src/test/storm-pars/analysis/MonotonicityCheckerTest.cpp

@ -80,93 +80,6 @@ TEST(MonotonicityCheckerTest, Derivative_checker) {
EXPECT_FALSE(functionRes.second); EXPECT_FALSE(functionRes.second);
} }
TEST(MonotonicityCheckerTest, Monotone_no_model) {
std::shared_ptr<storm::models::ModelBase> model;
std::vector<std::shared_ptr<storm::logic::Formula const>> formulas;
auto checker = storm::analysis::MonotonicityChecker<storm::RationalFunction>(model, formulas, false);
// Build lattice
auto numberOfStates = 4;
auto above = storm::storage::BitVector(numberOfStates);
above.set(1);
auto below = storm::storage::BitVector(numberOfStates);
below.set(0);
auto initialMiddle = storm::storage::BitVector(numberOfStates);
auto lattice = storm::analysis::Lattice(&above, &below, &initialMiddle, numberOfStates);
lattice.add(2);
lattice.add(3);
// Build map
std::vector<std::shared_ptr<storm::expressions::BinaryRelationExpression>> assumptions;
std::map<storm::analysis::Lattice*, std::vector<std::shared_ptr<storm::expressions::BinaryRelationExpression>>> map;
map.insert(std::pair<storm::analysis::Lattice*, std::vector<std::shared_ptr<storm::expressions::BinaryRelationExpression>>>(&lattice, assumptions));
// Build matrix
auto builder = storm::storage::SparseMatrixBuilder<storm::RationalFunction>(numberOfStates, numberOfStates, 4);
std::shared_ptr<storm::RawPolynomialCache> cache = std::make_shared<storm::RawPolynomialCache>();
carl::StringParser parser;
parser.setVariables({"p", "q"});
auto func = storm::RationalFunction(storm::Polynomial(parser.template parseMultivariatePolynomial<storm::RationalFunctionCoefficient>("p"), cache));
auto funcMin = storm::RationalFunction(storm::RationalFunction(1)-func);
builder.addNextValue(2, 1, func);
builder.addNextValue(2, 0, funcMin);
func = storm::RationalFunction(storm::Polynomial(parser.template parseMultivariatePolynomial<storm::RationalFunctionCoefficient>("q"), cache));
funcMin = storm::RationalFunction(storm::RationalFunction(1)-func);
builder.addNextValue(3, 1, funcMin);
builder.addNextValue(3, 0, func);
storm::storage::SparseMatrix<storm::RationalFunction> matrix = builder.build();
std::map<storm::analysis::Lattice*, std::map<carl::Variable, std::pair<bool, bool>>> result = checker.checkMonotonicity(map, matrix);
ASSERT_EQ(1, result.size());
ASSERT_EQ(2, result.begin()->second.size());
auto entry1 = result.begin()->second.begin();
auto entry2 = ++ (result.begin()->second.begin());
ASSERT_EQ("p", entry1->first.name());
EXPECT_TRUE(entry1->second.first);
EXPECT_FALSE(entry1->second.second);
EXPECT_FALSE(entry2->second.first);
EXPECT_TRUE(entry2->second.second);
}
TEST(MonotonicityCheckerTest, Not_monotone_no_model) {
std::shared_ptr<storm::models::ModelBase> model;
std::vector<std::shared_ptr<storm::logic::Formula const>> formulas;
auto checker = storm::analysis::MonotonicityChecker<storm::RationalFunction>(model, formulas, false);
// Build lattice
auto numberOfStates = 4;
auto above = storm::storage::BitVector(numberOfStates);
above.set(1);
auto below = storm::storage::BitVector(numberOfStates);
below.set(0);
auto initialMiddle = storm::storage::BitVector(numberOfStates);
auto lattice = storm::analysis::Lattice(&above, &below, &initialMiddle, numberOfStates);
lattice.add(2);
lattice.add(3);
// Build map
std::vector<std::shared_ptr<storm::expressions::BinaryRelationExpression>> assumptions;
std::map<storm::analysis::Lattice*, std::vector<std::shared_ptr<storm::expressions::BinaryRelationExpression>>> map;
map.insert(std::pair<storm::analysis::Lattice*, std::vector<std::shared_ptr<storm::expressions::BinaryRelationExpression>>>(&lattice, assumptions));
// Build matrix
auto builder = storm::storage::SparseMatrixBuilder<storm::RationalFunction>(numberOfStates, numberOfStates, 4);
std::shared_ptr<storm::RawPolynomialCache> cache = std::make_shared<storm::RawPolynomialCache>();
carl::StringParser parser;
parser.setVariables({"p", "q"});
auto func = storm::RationalFunction(storm::Polynomial(parser.template parseMultivariatePolynomial<storm::RationalFunctionCoefficient>("p"), cache));
auto funcMin = storm::RationalFunction(storm::RationalFunction(1)-func);
builder.addNextValue(2, 1, func);
builder.addNextValue(2, 0, funcMin);
builder.addNextValue(3, 1, funcMin);
builder.addNextValue(3, 0, func);
auto matrix = builder.build();
auto result = checker.checkMonotonicity(map, matrix);
ASSERT_EQ(1, result.size());
ASSERT_EQ(1, result.begin()->second.size());
auto entry1 = result.begin()->second.begin();
ASSERT_EQ("p", entry1->first.name());
EXPECT_FALSE(entry1->second.first);
EXPECT_FALSE(entry1->second.second);
}
TEST(MonotonicityCheckerTest, Brp_with_bisimulation) { TEST(MonotonicityCheckerTest, Brp_with_bisimulation) {
std::string programFile = STORM_TEST_RESOURCES_DIR "/pdtmc/brp16_2.pm"; std::string programFile = STORM_TEST_RESOURCES_DIR "/pdtmc/brp16_2.pm";
std::string formulaAsString = "P=? [F s=4 & i=N ]"; std::string formulaAsString = "P=? [F s=4 & i=N ]";

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