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Implemented Prob1E algorithm for nondeterministic models. Added comparison operator to bit vector.

tempestpy_adaptions
dehnert 12 years ago
parent
commit
7d7edc5a05
  1. 39
      src/storage/BitVector.h
  2. 7
      src/storm.cpp
  3. 71
      src/utility/GraphAnalyzer.h

39
src/storage/BitVector.h

@ -136,7 +136,7 @@ public:
* Copy Constructor. Performs a deep copy of the given bit vector.
* @param bv A reference to the bit vector to be copied.
*/
BitVector(const BitVector &bv) : bucketCount(bv.bucketCount), bitCount(bv.bitCount), endIterator(*this, bitCount, bitCount, false), truncateMask((1ll << (bitCount & mod64mask)) - 1ll) {
BitVector(BitVector const& bv) : bucketCount(bv.bucketCount), bitCount(bv.bitCount), endIterator(*this, bitCount, bitCount, false), truncateMask((1ll << (bitCount & mod64mask)) - 1ll) {
LOG4CPLUS_WARN(logger, "Invoking copy constructor.");
bucketArray = new uint64_t[bucketCount];
std::copy(bv.bucketArray, bv.bucketArray + this->bucketCount, this->bucketArray);
@ -152,6 +152,25 @@ public:
}
}
// Equality Operator
/*!
* Compares the given bit vector with the current one.
*/
bool operator==(BitVector const& bv) {
// If the lengths of the vectors do not match, they are considered unequal.
if (this->bitCount != bv.bitCount) return false;
// If the lengths match, we compare the buckets one by one.
for (uint_fast64_t index = 0; index < this->bucketCount; ++index) {
if (this->bucketArray[index] != bv.bucketArray[index]) {
return false;
}
}
// All buckets were equal, so the bit vectors are equal.
return true;
}
//! Assignment Operator
/*!
* Assigns the given bit vector to the current bit vector by a deep copy.
@ -159,7 +178,7 @@ public:
* @return A reference to this bit vector after it has been assigned the
* given bit vector by means of a deep copy.
*/
BitVector& operator=(const BitVector& bv) {
BitVector& operator=(BitVector const& bv) {
if (this->bucketArray != nullptr) {
delete[] this->bucketArray;
}
@ -239,7 +258,7 @@ public:
* @param bv A reference to the bit vector to use for the operation.
* @return A bit vector corresponding to the logical "and" of the two bit vectors.
*/
BitVector operator &(const BitVector &bv) const {
BitVector operator&(BitVector const& bv) const {
uint_fast64_t minSize = (bv.bitCount < this->bitCount) ? bv.bitCount : this->bitCount;
// Create resulting bit vector and perform the operation on the individual elements.
@ -259,7 +278,7 @@ public:
* @return A reference to the current bit vector corresponding to the logical "and"
* of the two bit vectors.
*/
BitVector operator &=(const BitVector bv) {
BitVector operator&=(BitVector const& bv) {
uint_fast64_t minSize = (bv.bucketCount < this->bucketCount) ? bv.bucketCount : this->bucketCount;
for (uint_fast64_t i = 0; i < minSize; ++i) {
@ -276,7 +295,7 @@ public:
* @param bv A reference to the bit vector to use for the operation.
* @return A bit vector corresponding to the logical "or" of the two bit vectors.
*/
BitVector operator |(const BitVector &bv) const {
BitVector operator|(BitVector const& bv) const {
uint_fast64_t minSize = (bv.bitCount < this->bitCount) ? bv.bitCount : this->bitCount;
// Create resulting bit vector and perform the operation on the individual elements.
@ -297,7 +316,7 @@ public:
* @return A reference to the current bit vector corresponding to the logical "or"
* of the two bit vectors.
*/
BitVector& operator |=(const BitVector bv) {
BitVector& operator|=(BitVector const& bv) {
uint_fast64_t minSize = (bv.bucketCount < this->bucketCount) ? bv.bucketCount : this->bucketCount;
for (uint_fast64_t i = 0; i < minSize; ++i) {
@ -315,7 +334,7 @@ public:
* @param bv A reference to the bit vector to use for the operation.
* @return A bit vector corresponding to the logical "xor" of the two bit vectors.
*/
BitVector operator ^(const BitVector &bv) const {
BitVector operator^(BitVector const& bv) const {
uint_fast64_t minSize = (bv.bitCount < this->bitCount) ? bv.bitCount : this->bitCount;
// Create resulting bit vector and perform the operation on the individual elements.
@ -332,7 +351,7 @@ public:
* Performs a logical "not" on the bit vector.
* @return A bit vector corresponding to the logical "not" of the bit vector.
*/
BitVector operator ~() const {
BitVector operator~() const {
// Create resulting bit vector and perform the operation on the individual elements.
BitVector result(this->bitCount);
for (uint_fast64_t i = 0; i < this->bucketCount; ++i) {
@ -360,7 +379,7 @@ public:
* @param bv A reference to the bit vector to use for the operation.
* @return A bit vector corresponding to the logical "implies" of the two bit vectors.
*/
BitVector implies(const BitVector& bv) const {
BitVector implies(BitVector const& bv) const {
uint_fast64_t minSize = (bv.bitCount < this->bitCount) ? bv.bitCount : this->bitCount;
// Create resulting bit vector and perform the operation on the individual elements.
@ -377,7 +396,7 @@ public:
* Adds all indices of bits set to one to the provided list.
* @param list The list to which to append the indices.
*/
void getList(std::vector<uint_fast64_t>& list) const {
void addSetIndicesToList(std::vector<uint_fast64_t>& list) const {
for (auto index : *this) {
list.push_back(index);
}

7
src/storm.cpp

@ -215,8 +215,6 @@ void testCheckingDice(storm::models::Mdp<double>& mdp) {
storm::utility::GraphAnalyzer::performProb01Max(mdp, *trueStates, *targetStates, statesWithProbability0, statesWithProbability1);
std::cout << statesWithProbability0->toString() << std::endl << statesWithProbability1->toString() << std::endl;
delete statesWithProbability0;
delete statesWithProbability1;
delete trueStates;
@ -255,10 +253,15 @@ int main(const int argc, const char* argv[]) {
if (!parseOptions(argc, argv)) {
return 0;
}
LOG4CPLUS_INFO(logger, "StoRM was invoked.");
printHeader(argc, argv);
testChecking();
cleanUp();
LOG4CPLUS_INFO(logger, "StoRM quit.");
return 0;
}

71
src/utility/GraphAnalyzer.h

@ -79,7 +79,7 @@ public:
// Initialize the stack used for the DFS with the states
std::vector<uint_fast64_t> stack;
stack.reserve(model.getNumberOfStates());
psiStates.getList(stack);
psiStates.addSetIndicesToList(stack);
// Perform the actual DFS.
while(!stack.empty()) {
@ -182,7 +182,7 @@ public:
// Initialize the stack used for the DFS with the states
std::vector<uint_fast64_t> stack;
stack.reserve(model.getNumberOfStates());
psiStates.getList(stack);
psiStates.addSetIndicesToList(stack);
// Perform the actual DFS.
while(!stack.empty()) {
@ -202,7 +202,71 @@ public:
template <class T>
static void performProb1E(storm::models::AbstractNondeterministicModel<T>& model, storm::storage::BitVector const& phiStates, storm::storage::BitVector const& psiStates, storm::storage::BitVector* statesWithProbability1) {
// Check for valid parameters.
if (statesWithProbability1 == nullptr) {
LOG4CPLUS_ERROR(logger, "Parameter 'statesWithProbability1' must not be null.");
throw storm::exceptions::InvalidArgumentException("Parameter 'statesWithProbability1' must not be null.");
}
// Get some temporaries for convenience.
std::shared_ptr<storm::storage::SparseMatrix<T>> transitionMatrix = model.getTransitionMatrix();
std::shared_ptr<std::vector<uint_fast64_t>> nondeterministicChoiceIndices = model.getNondeterministicChoiceIndices();
// Get the backwards transition relation from the model to ease the search.
storm::models::GraphTransitions<T> backwardTransitions(model.getTransitionMatrix(), model.getNondeterministicChoiceIndices(), false);
storm::storage::BitVector* currentStates = new storm::storage::BitVector(model.getNumberOfStates(), true);
std::vector<uint_fast64_t> stack;
stack.reserve(model.getNumberOfStates());
bool done = false;
while (!done) {
stack.clear();
storm::storage::BitVector* nextStates = new storm::storage::BitVector(psiStates);
psiStates.addSetIndicesToList(stack);
while (!stack.empty()) {
uint_fast64_t currentState = stack.back();
stack.pop_back();
for(auto it = backwardTransitions.beginStateSuccessorsIterator(currentState); it != backwardTransitions.endStateSuccessorsIterator(currentState); ++it) {
if (phiStates.get(*it) && !nextStates->get(*it)) {
// Check whether the predecessor has at only successors in the current state set for one of the
// nondeterminstic choices.
for (auto rowIt = nondeterministicChoiceIndices->begin() + *it; rowIt != nondeterministicChoiceIndices->begin() + *it + 1; ++rowIt) {
bool allSuccessorsInCurrentStates = true;
for (auto colIt = transitionMatrix->beginConstColumnIterator(*rowIt); colIt != transitionMatrix->endConstColumnIterator(*rowIt); ++colIt) {
if (currentStates->get(*colIt)) {
allSuccessorsInCurrentStates = false;
break;
}
}
// If all successors for a given nondeterministic choice are in the current state set, we
// add it to the set of states for the next iteration and perform a backward search from
// that state.
if (allSuccessorsInCurrentStates) {
nextStates->set(*it, true);
stack.push_back(*it);
break;
}
}
}
}
}
// Check whether we need to perform an additional iteration.
if (*currentStates == *nextStates) {
done = true;
} else {
*currentStates = *nextStates;
}
}
*statesWithProbability1 = *currentStates;
delete currentStates;
}
template <class T>
@ -230,6 +294,7 @@ public:
throw storm::exceptions::InvalidArgumentException("Parameter 'statesWithProbability0' must not be null.");
}
// Get some temporaries for convenience.
std::shared_ptr<storm::storage::SparseMatrix<T>> transitionMatrix = model.getTransitionMatrix();
std::shared_ptr<std::vector<uint_fast64_t>> nondeterministicChoiceIndices = model.getNondeterministicChoiceIndices();
@ -242,7 +307,7 @@ public:
// Initialize the stack used for the DFS with the states
std::vector<uint_fast64_t> stack;
stack.reserve(model.getNumberOfStates());
psiStates.getList(stack);
psiStates.addSetIndicesToList(stack);
// Perform the actual DFS.
while(!stack.empty()) {

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