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OVI: seperated implementation from header file. Use a separate helper for computing the upper bounds.

tempestpy_adaptions
Tim Quatmann 4 years ago
parent
6e2dab0e0b
commit
990d1c9759
4 changed files with 449 additions and 291 deletions
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  1. 8
      src/storm/solver/IterativeMinMaxLinearEquationSolver.cpp
  2. 8
      src/storm/solver/NativeLinearEquationSolver.cpp
  3. 362
      src/storm/solver/helper/OptimisticValueIterationHelper.cpp
  4. 362
      src/storm/solver/helper/OptimisticValueIterationHelper.h

8
src/storm/solver/IterativeMinMaxLinearEquationSolver.cpp
View File

@ -402,11 +402,12 @@ namespace storm {
this->startMeasureProgress();
auto statusIters = storm::solver::helper::solveEquationsOptimisticValueIteration(env, lowerX, upperX, auxVector,
storm::solver::helper::OptimisticValueIterationHelper<ValueType> helper(*this->A);
auto statusIters = helper.solveEquationsOptimisticValueIteration(env, lowerX, upperX, auxVector, b,
[&] (std::vector<ValueType>*& y, std::vector<ValueType>*& yPrime, ValueType const& precision, bool const& relative, uint64_t const& i, uint64_t const& maxI) {
this->showProgressIterative(i);
return performValueIteration(env, dir, y, yPrime, b, precision, relative, guarantee, i, maxI, multiplicationStyle);
auto result = performValueIteration(env, dir, y, yPrime, b, precision, relative, guarantee, i, maxI, multiplicationStyle);
return std::make_pair(result.iterations, result.status);
},
[&] (std::vector<ValueType>* y, std::vector<ValueType>* yPrime, uint64_t const& i) {
this->showProgressIterative(i);
@ -423,6 +424,7 @@ namespace storm {
env.solver().minMax().getRelativeTerminationCriterion(),
storm::utility::convertNumber<ValueType>(env.solver().minMax().getPrecision()),
env.solver().minMax().getMaximalNumberOfIterations(),
dir,
relevantValues);
auto two = storm::utility::convertNumber<ValueType>(2.0);
storm::utility::vector::applyPointwise<ValueType, ValueType, ValueType>(*lowerX, *upperX, x, [&two] (ValueType const& a, ValueType const& b) -> ValueType { return (a + b) / two; });

8
src/storm/solver/NativeLinearEquationSolver.cpp
View File

@ -675,11 +675,12 @@ namespace storm {
std::vector<ValueType>* auxVector = this->cachedRowVector2.get();
this->startMeasureProgress();
auto statusIters = storm::solver::helper::solveEquationsOptimisticValueIteration(env, lowerX, upperX, auxVector,
storm::solver::helper::OptimisticValueIterationHelper<ValueType> helper(*this->A);
auto statusIters = helper.solveEquationsOptimisticValueIteration(env, lowerX, upperX, auxVector, b,
[&] (std::vector<ValueType>*& y, std::vector<ValueType>*& yPrime, ValueType const& precision, bool const& relative, uint64_t const& i, uint64_t const& maxI) {
this->showProgressIterative(i);
return performPowerIteration(env, y, yPrime, b, precision, relative, guarantee, i, maxI, multiplicationStyle);
auto result = performPowerIteration(env, y, yPrime, b, precision, relative, guarantee, i, maxI, multiplicationStyle);
return std::make_pair(result.iterations, result.status);
},
[&] (std::vector<ValueType>* y, std::vector<ValueType>* yPrime, uint64_t const& i) {
this->showProgressIterative(i);
@ -696,6 +697,7 @@ namespace storm {
env.solver().native().getRelativeTerminationCriterion(),
storm::utility::convertNumber<ValueType>(env.solver().native().getPrecision()),
env.solver().native().getMaximalNumberOfIterations(),
boost::none, // No optimization dir
relevantValues);
auto two = storm::utility::convertNumber<ValueType>(2.0);
storm::utility::vector::applyPointwise<ValueType, ValueType, ValueType>(*lowerX, *upperX, x, [&two] (ValueType const& a, ValueType const& b) -> ValueType { return (a + b) / two; });

362
src/storm/solver/helper/OptimisticValueIterationHelper.cpp
View File

@ -0,0 +1,362 @@
#include "OptimisticValueIterationHelper.h"
#include "storm/utility/vector.h"
#include "storm/utility/SignalHandler.h"
#include "storm/environment/solver/OviSolverEnvironment.h"
#include "storm/exceptions/NotSupportedException.h"
#include "storm/utility/macros.h"
namespace storm {
namespace solver {
namespace helper {
namespace oviinternal {
template<typename ValueType>
ValueType computeMaxAbsDiff(std::vector<ValueType> const& allOldValues, std::vector<ValueType> const& allNewValues, storm::storage::BitVector const& relevantValues) {
ValueType result = storm::utility::zero<ValueType>();
for (auto value : relevantValues) {
result = storm::utility::max<ValueType>(result, storm::utility::abs<ValueType>(allNewValues[value] - allOldValues[value]));
}
return result;
}
template<typename ValueType>
ValueType computeMaxAbsDiff(std::vector<ValueType> const& allOldValues, std::vector<ValueType> const& allNewValues) {
ValueType result = storm::utility::zero<ValueType>();
for (uint64_t i = 0; i < allOldValues.size(); ++i) {
result = storm::utility::max<ValueType>(result, storm::utility::abs<ValueType>(allNewValues[i] - allOldValues[i]));
}
return result;
}
template<typename ValueType>
ValueType computeMaxRelDiff(std::vector<ValueType> const& allOldValues, std::vector<ValueType> const& allNewValues, storm::storage::BitVector const& relevantValues) {
ValueType result = storm::utility::zero<ValueType>();
for (auto const& i : relevantValues) {
STORM_LOG_ASSERT(!storm::utility::isZero(allNewValues[i]) || storm::utility::isZero(allOldValues[i]), "Unexpected entry in iteration vector.");
if (!storm::utility::isZero(allNewValues[i])) {
result = storm::utility::max<ValueType>(result, storm::utility::abs<ValueType>(allNewValues[i] - allOldValues[i]) / allNewValues[i]);
}
}
return result;
}
template<typename ValueType>
ValueType computeMaxRelDiff(std::vector<ValueType> const& allOldValues, std::vector<ValueType> const& allNewValues) {
ValueType result = storm::utility::zero<ValueType>();
for (uint64_t i = 0; i < allOldValues.size(); ++i) {
STORM_LOG_ASSERT(!storm::utility::isZero(allNewValues[i]) || storm::utility::isZero(allOldValues[i]), "Unexpected entry in iteration vector.");
if (!storm::utility::isZero(allNewValues[i])) {
result = storm::utility::max<ValueType>(result, storm::utility::abs<ValueType>(allNewValues[i] - allOldValues[i]) / allNewValues[i]);
}
}
return result;
}
template<typename ValueType>
ValueType updateIterationPrecision(storm::Environment const& env, std::vector<ValueType> const& currentX, std::vector<ValueType> const& newX, bool const& relative, boost::optional<storm::storage::BitVector> const& relevantValues) {
auto factor = storm::utility::convertNumber<ValueType>(env.solver().ovi().getPrecisionUpdateFactor());
bool useRelevant = relevantValues.is_initialized() && env.solver().ovi().useRelevantValuesForPrecisionUpdate();
if (relative) {
return (useRelevant ? computeMaxRelDiff(newX, currentX, relevantValues.get()) : computeMaxRelDiff(newX, currentX)) * factor;
} else {
return (useRelevant ? computeMaxAbsDiff(newX, currentX, relevantValues.get()) : computeMaxAbsDiff(newX, currentX)) * factor;
}
}
template<typename ValueType>
void guessUpperBoundRelative(std::vector<ValueType> const& x, std::vector<ValueType> &target, ValueType const& relativeBoundGuessingScaler) {
storm::utility::vector::applyPointwise<ValueType, ValueType>(x, target, [&relativeBoundGuessingScaler] (ValueType const& argument) -> ValueType { return argument * relativeBoundGuessingScaler; });
}
template<typename ValueType>
void guessUpperBoundAbsolute(std::vector<ValueType> const& x, std::vector<ValueType> &target, ValueType const& precision) {
storm::utility::vector::applyPointwise<ValueType, ValueType>(x, target, [&precision] (ValueType const& argument) -> ValueType { return argument + precision; });
}
template <typename ValueType>
UpperBoundIterator<ValueType>::UpperBoundIterator(storm::storage::SparseMatrix<ValueType> const& matrix) {
STORM_LOG_THROW(static_cast<uint64_t>(std::numeric_limits<uint32_t>::max()) > matrix.getRowCount() + 1, storm::exceptions::NotSupportedException, "Matrix dimensions too large.");
STORM_LOG_THROW(static_cast<uint64_t>(std::numeric_limits<uint32_t>::max()) > matrix.getEntryCount(), storm::exceptions::NotSupportedException, "Matrix dimensions too large.");
matrixValues.reserve(matrix.getNonzeroEntryCount());
matrixColumns.reserve(matrix.getColumnCount());
rowIndications.reserve(matrix.getRowCount() + 1);
rowIndications.push_back(0);
for (IndexType r = 0; r < static_cast<IndexType>(matrix.getRowCount()); ++r) {
for (auto const& entry : matrix.getRow(r)) {
matrixValues.push_back(entry.getValue());
matrixColumns.push_back(entry.getColumn());
}
rowIndications.push_back(matrixValues.size());
}
if (!matrix.hasTrivialRowGrouping()) {
rowGroupIndices = &matrix.getRowGroupIndices();
}
}
template <typename ValueType>
typename UpperBoundIterator<ValueType>::IterateResult UpperBoundIterator<ValueType>::iterate(std::vector<ValueType>& x, std::vector<ValueType> const& b, bool takeMinOfOldAndNew) {
return iterateInternal<false, storm::solver::OptimizationDirection::Minimize>(x, b, takeMinOfOldAndNew);
}
template <typename ValueType>
typename UpperBoundIterator<ValueType>::IterateResult UpperBoundIterator<ValueType>::iterate(storm::solver::OptimizationDirection const& dir, std::vector<ValueType>& x, std::vector<ValueType> const& b, bool takeMinOfOldAndNew) {
if (minimize(dir)) {
return iterateInternal<true, storm::solver::OptimizationDirection::Minimize>(x, b, takeMinOfOldAndNew);
} else {
return iterateInternal<true, storm::solver::OptimizationDirection::Maximize>(x, b, takeMinOfOldAndNew);
}
}
template <typename ValueType>
template<bool HasRowGroups, storm::solver::OptimizationDirection Dir>
typename UpperBoundIterator<ValueType>::IterateResult UpperBoundIterator<ValueType>::iterateInternal(std::vector<ValueType>& x, std::vector<ValueType> const& b, bool takeMinOfOldAndNew) {
// For each row compare the new upper bound candidate with the old one
bool newUpperBoundAlwaysHigherEqual = true;
bool newUpperBoundAlwaysLowerEqual = true;
// Do a backwards gauss-seidel style iteration
for (IndexType i = x.size(); i > 0;) {
--i;
ValueType newXi = HasRowGroups ? multiplyRowGroup<Dir>(i, b, x) : multiplyRow(i, b[i], x);
ValueType& oldXi = x[i];
if (newXi > oldXi) {
newUpperBoundAlwaysLowerEqual = false;
if (!takeMinOfOldAndNew) {
oldXi = newXi;
}
} else if (newXi != oldXi) {
assert(newXi < oldXi);
newUpperBoundAlwaysHigherEqual = false;
oldXi = newXi;
}
}
// Return appropriate result
if (newUpperBoundAlwaysLowerEqual) {
if (newUpperBoundAlwaysHigherEqual) {
return IterateResult::Equal;
} else {
return IterateResult::AlwaysLowerOrEqual;
}
} else {
if (newUpperBoundAlwaysHigherEqual) {
return IterateResult::AlwaysHigherOrEqual;
} else {
return IterateResult::Incomparable;
}
}
}
template <typename ValueType>
ValueType UpperBoundIterator<ValueType>::multiplyRow(IndexType const& rowIndex, ValueType const& bi, std::vector<ValueType> const& x) {
assert(rowIndex < rowIndications.size());
ValueType xRes = bi;
auto entryIt = matrixValues.begin() + rowIndications[rowIndex];
auto entryItE = matrixValues.begin() + rowIndications[rowIndex + 1];
auto colIt = matrixColumns.begin() + rowIndications[rowIndex];
for (; entryIt != entryItE; ++entryIt, ++colIt) {
xRes += *entryIt * x[*colIt];
}
return xRes;
}
template <typename ValueType>
template<storm::solver::OptimizationDirection Dir>
ValueType UpperBoundIterator<ValueType>::multiplyRowGroup(IndexType const& rowGroupIndex, std::vector<ValueType> const& b, std::vector<ValueType> const& x) {
STORM_LOG_ASSERT(rowGroupIndices != nullptr, "No row group indices available.");
auto row = (*rowGroupIndices)[rowGroupIndex];
auto const& groupEnd = (*rowGroupIndices)[rowGroupIndex + 1];
STORM_LOG_ASSERT(row < groupEnd, "Empty row group not expected.");
ValueType xRes = multiplyRow(row, b[row], x);
for (++row; row < groupEnd; ++row) {
ValueType xCur = multiplyRow(row, b[row], x);
xRes = minimize(Dir) ? std::min(xRes, xCur) : std::max(xRes, xCur);
}
return xRes;
}
}
template<typename ValueType>
OptimisticValueIterationHelper<ValueType>::OptimisticValueIterationHelper(storm::storage::SparseMatrix<ValueType> const& matrix) : upperBoundIterator(matrix) {
// Intentionally left empty.
}
template<typename ValueType>
std::pair<SolverStatus, uint64_t> OptimisticValueIterationHelper<ValueType>::solveEquationsOptimisticValueIteration(Environment const& env, std::vector<ValueType>* lowerX, std::vector<ValueType>* upperX, std::vector<ValueType>* auxVector, std::vector<ValueType> const& b, ValueIterationCallBackType const& valueIterationCallback, SingleIterationCallBackType const& singleIterationCallback, bool relative, ValueType precision, uint64_t maxOverallIterations, boost::optional<storm::solver::OptimizationDirection> dir, boost::optional<storm::storage::BitVector> relevantValues) {
STORM_LOG_ASSERT(lowerX->size() == upperX->size(), "Dimension missmatch.");
STORM_LOG_ASSERT(lowerX->size() == auxVector->size(), "Dimension missmatch.");
// As we will shuffle pointers around, let's store the original positions here.
std::vector<ValueType>* initLowerX = lowerX;
std::vector<ValueType>* initUpperX = upperX;
std::vector<ValueType>* initAux = auxVector;
uint64_t overallIterations = 0;
uint64_t lastValueIterationIterations = 0;
uint64_t currentVerificationIterations = 0;
uint64_t valueIterationInvocations = 0;
// Get some parameters for the algorithm
// 2
ValueType two = storm::utility::convertNumber<ValueType>(2.0);
// Use no termination guaranteed upper bound iteration method
bool noTerminationGuarantee = env.solver().ovi().useNoTerminationGuaranteeMinimumMethod();
// Desired max difference between upperX and lowerX
ValueType doublePrecision = precision * two;
// Upper bound only iterations
uint64_t upperBoundOnlyIterations = env.solver().ovi().getUpperBoundOnlyIterations();
ValueType relativeBoundGuessingScaler = (storm::utility::one<ValueType>() + storm::utility::convertNumber<ValueType>(env.solver().ovi().getUpperBoundGuessingFactor()) * precision);
// Initial precision for the value iteration calls
ValueType iterationPrecision = precision;
SolverStatus status = SolverStatus::InProgress;
while (status == SolverStatus::InProgress && overallIterations < maxOverallIterations) {
// Perform value iteration until convergence
++valueIterationInvocations;
auto result = valueIterationCallback(lowerX, auxVector, iterationPrecision, relative, overallIterations, maxOverallIterations);
lastValueIterationIterations = result.first;
overallIterations += result.first;
if (result.second != SolverStatus::Converged) {
status = result.second;
} else {
bool intervalIterationNeeded = false;
currentVerificationIterations = 0;
if (relative) {
oviinternal::guessUpperBoundRelative(*lowerX, *upperX, relativeBoundGuessingScaler);
} else {
oviinternal::guessUpperBoundAbsolute(*lowerX, *upperX, precision);
}
bool cancelGuess = false;
while (status == SolverStatus::InProgress && overallIterations < maxOverallIterations) {
++overallIterations;
++currentVerificationIterations;
// Perform value iteration stepwise for lower bound and guessed upper bound
// Upper bound iteration
auto upperBoundIterResult = dir ? upperBoundIterator.iterate(dir.get(), *upperX, b, !noTerminationGuarantee) : upperBoundIterator.iterate(*upperX, b, !noTerminationGuarantee);
if (upperBoundIterResult == oviinternal::UpperBoundIterator<ValueType>::IterateResult::AlwaysHigherOrEqual) {
// All values moved up (and did not stay the same)
// That means the guess for an upper bound is actually a lower bound
iterationPrecision = oviinternal::updateIterationPrecision(env, *auxVector, *upperX, relative, relevantValues);
// We assume to have a single fixed point. We can thus safely set the new lower bound, to the wrongly guessed upper bound
// Set lowerX to the upper bound candidate
std::swap(lowerX, upperX);
break;
} else if (upperBoundIterResult == oviinternal::UpperBoundIterator<ValueType>::IterateResult::AlwaysLowerOrEqual) {
// All values moved down (and stayed not the same)
// This is a valid upper bound. We still need to check the precision.
// We can safely use twice the requested precision, as we calculate the center of both vectors
bool reachedPrecision;
if (relevantValues) {
reachedPrecision = storm::utility::vector::equalModuloPrecision(*lowerX, *upperX, relevantValues.get(), doublePrecision, relative);
} else {
reachedPrecision = storm::utility::vector::equalModuloPrecision(*lowerX, *upperX, doublePrecision, relative);
}
if (reachedPrecision) {
status = SolverStatus::Converged;
break;
} else {
// From now on, we keep updating both bounds
intervalIterationNeeded = true;
}
// The following case below covers that both vectors (old and new) are equal.
// Theoretically, this means that the precise fixpoint has been reached. However, numerical instabilities can be tricky and this detection might be incorrect (see the haddad-monmege model).
// We therefore disable it. It is very unlikely that we guessed the right fixpoint anyway.
//} else if (upperBoundIterResult == oviinternal::UpperBoundIterator<ValueType>::IterateResult::Equal) {
// In this case, the guessed upper bound is the precise fixpoint
// status = SolverStatus::Converged;
// std::swap(lowerX, auxVector);
// break;
}
// Check whether we tried this guess for too long
ValueType scaledIterationCount = storm::utility::convertNumber<ValueType>(currentVerificationIterations) * storm::utility::convertNumber<ValueType>(env.solver().ovi().getMaxVerificationIterationFactor());
if (!intervalIterationNeeded && scaledIterationCount >= storm::utility::convertNumber<ValueType>(lastValueIterationIterations)) {
cancelGuess = true;
// In this case we will make one more iteration on the lower bound (mainly to obtain a new iterationPrecision)
}
// Lower bound iteration (only if needed)
if (cancelGuess || intervalIterationNeeded || currentVerificationIterations > upperBoundOnlyIterations) {
singleIterationCallback(lowerX, auxVector, overallIterations);
// At this point, auxVector contains the old values for the lower bound whereas lowerX contains the new ones.
// Check whether the upper and lower bounds have crossed, i.e., the upper bound is smaller than the lower bound.
bool valuesCrossed = false;
for (uint64_t i = 0; i < lowerX->size(); ++i) {
if ((*upperX)[i] < (*lowerX)[i]) {
valuesCrossed = true;
break;
}
}
if (cancelGuess || valuesCrossed) {
// A new guess is needed.
iterationPrecision = oviinternal::updateIterationPrecision(env, *auxVector, *lowerX, relative, relevantValues);
break;
}
}
}
if (storm::utility::resources::isTerminate()) {
status = SolverStatus::Aborted;
}
}
} // end while
// Swap the results into the output vectors.
if (initLowerX == lowerX) {
// lowerX is already at the correct position. We still have to care for upperX
if (initUpperX != upperX) {
// UpperX is not at the correct position. It has to be at the auxVector
assert(initAux == upperX);
std::swap(*initUpperX, *initAux);
}
} else if (initUpperX == upperX) {
// UpperX is already at the correct position.
// We already know that lowerX is at the wrong position. It has to be at the auxVector
assert(initAux == lowerX);
std::swap(*initLowerX, *initAux);
} else if (initAux == auxVector) {
// We know that upperX and lowerX are swapped.
assert(initLowerX == upperX);
assert(initUpperX == lowerX);
std::swap(*initUpperX, *initLowerX);
} else {
// Now we know that all vectors are at the wrong position. There are only two possibilities left
if (initLowerX == upperX) {
assert(initUpperX == auxVector);
assert(initAux == lowerX);
std::swap(*initLowerX, *initAux);
std::swap(*initUpperX, *initAux);
} else {
assert(initLowerX == auxVector);
assert(initUpperX == lowerX);
assert (initAux == upperX);
std::swap(*initUpperX, *initAux);
std::swap(*initLowerX, *initAux);
}
}
if (overallIterations > maxOverallIterations) {
status = SolverStatus::MaximalIterationsExceeded;
}
return {status, overallIterations};
}
template class OptimisticValueIterationHelper<double>;
template class OptimisticValueIterationHelper<storm::RationalNumber>;
}
}
}

362
src/storm/solver/helper/OptimisticValueIterationHelper.h
View File

@ -3,312 +3,104 @@
#include <vector>
#include <boost/optional.hpp>
#include "storm/storage/SparseMatrix.h"
#include "storm/solver/OptimizationDirection.h"
#include "storm/solver/SolverStatus.h"
#include "storm/utility/vector.h"
#include "storm/utility/ProgressMeasurement.h"
#include "storm/utility/SignalHandler.h"
#include "storm/storage/BitVector.h"
#include "storm/environment/solver/MinMaxSolverEnvironment.h"
#include "storm/environment/solver/OviSolverEnvironment.h"
#include "storm/utility/macros.h"
namespace storm {
class Environment;
namespace solver {
namespace helper {
namespace oviinternal {
template<typename ValueType>
ValueType computeMaxAbsDiff(std::vector<ValueType> const& allOldValues, std::vector<ValueType> const& allNewValues, storm::storage::BitVector const& relevantValues) {
ValueType result = storm::utility::zero<ValueType>();
for (auto value : relevantValues) {
result = storm::utility::max<ValueType>(result, storm::utility::abs<ValueType>(allNewValues[value] - allOldValues[value]));
}
return result;
}
template<typename ValueType>
ValueType computeMaxAbsDiff(std::vector<ValueType> const& allOldValues, std::vector<ValueType> const& allNewValues) {
ValueType result = storm::utility::zero<ValueType>();
for (uint64_t i = 0; i < allOldValues.size(); ++i) {
result = storm::utility::max<ValueType>(result, storm::utility::abs<ValueType>(allNewValues[i] - allOldValues[i]));
}
return result;
}
template<typename ValueType>
ValueType computeMaxRelDiff(std::vector<ValueType> const& allOldValues, std::vector<ValueType> const& allNewValues, storm::storage::BitVector const& relevantValues) {
ValueType result = storm::utility::zero<ValueType>();
for (auto const& i : relevantValues) {
STORM_LOG_ASSERT(!storm::utility::isZero(allNewValues[i]) || storm::utility::isZero(allOldValues[i]), "Unexpected entry in iteration vector.");
if (!storm::utility::isZero(allNewValues[i])) {
result = storm::utility::max<ValueType>(result, storm::utility::abs<ValueType>(allNewValues[i] - allOldValues[i]) / allNewValues[i]);
}
}
return result;
}
template <typename ValueType>
class UpperBoundIterator {
public:
typedef uint32_t IndexType;
UpperBoundIterator(storm::storage::SparseMatrix<ValueType> const& matrix);
enum class IterateResult {
AlwaysHigherOrEqual,
AlwaysLowerOrEqual,
Equal,
Incomparable
};
IterateResult iterate(std::vector<ValueType>& x, std::vector<ValueType> const& b, bool takeMinOfOldAndNew);
IterateResult iterate(storm::solver::OptimizationDirection const& dir, std::vector<ValueType>& x, std::vector<ValueType> const& b, bool takeMinOfOldAndNew);
template<typename ValueType>
ValueType computeMaxRelDiff(std::vector<ValueType> const& allOldValues, std::vector<ValueType> const& allNewValues) {
ValueType result = storm::utility::zero<ValueType>();
for (uint64_t i = 0; i < allOldValues.size(); ++i) {
STORM_LOG_ASSERT(!storm::utility::isZero(allNewValues[i]) || storm::utility::isZero(allOldValues[i]), "Unexpected entry in iteration vector.");
if (!storm::utility::isZero(allNewValues[i])) {
result = storm::utility::max<ValueType>(result, storm::utility::abs<ValueType>(allNewValues[i] - allOldValues[i]) / allNewValues[i]);
}
}
return result;
}
template<typename ValueType>
ValueType updateIterationPrecision(storm::Environment const& env, std::vector<ValueType> const& currentX, std::vector<ValueType> const& newX, bool const& relative, boost::optional<storm::storage::BitVector> const& relevantValues) {
auto factor = storm::utility::convertNumber<ValueType>(env.solver().ovi().getPrecisionUpdateFactor());
bool useRelevant = relevantValues.is_initialized() && env.solver().ovi().useRelevantValuesForPrecisionUpdate();
if (relative) {
return (useRelevant ? computeMaxRelDiff(newX, currentX, relevantValues.get()) : computeMaxRelDiff(newX, currentX)) * factor;
} else {
return (useRelevant ? computeMaxAbsDiff(newX, currentX, relevantValues.get()) : computeMaxAbsDiff(newX, currentX)) * factor;
}
}
template<typename ValueType>
void guessUpperBoundRelative(std::vector<ValueType> const& x, std::vector<ValueType> &target, ValueType const& relativeBoundGuessingScaler) {
storm::utility::vector::applyPointwise<ValueType, ValueType>(x, target, [&relativeBoundGuessingScaler] (ValueType const& argument) -> ValueType { return argument * relativeBoundGuessingScaler; });
}
template<typename ValueType>
void guessUpperBoundAbsolute(std::vector<ValueType> const& x, std::vector<ValueType> &target, ValueType const& precision) {
storm::utility::vector::applyPointwise<ValueType, ValueType>(x, target, [&precision] (ValueType const& argument) -> ValueType { return argument + precision; });
}
private:
template<bool HasRowGroups, storm::solver::OptimizationDirection Dir>
IterateResult iterateInternal(std::vector<ValueType>& x, std::vector<ValueType> const& b, bool takeMinOfOldAndNew);
ValueType multiplyRow(IndexType const& rowIndex, ValueType const& bi, std::vector<ValueType> const& x);
template<storm::solver::OptimizationDirection Dir>
ValueType multiplyRowGroup(IndexType const& rowGroupIndex, std::vector<ValueType> const& b, std::vector<ValueType> const& x);
std::vector<ValueType> matrixValues;
std::vector<IndexType> matrixColumns;
std::vector<IndexType> rowIndications;
std::vector<uint64_t> const* rowGroupIndices;
};
}
/*!
* Performs Optimistic value iteration.
* See https://arxiv.org/abs/1910.01100 for more information on this algorithm
*
* @tparam ValueType
* @tparam ValueType
* @param env
* @param lowerX Needs to be some arbitrary lower bound on the actual values initially
* @param upperX Does not need to be an upper bound initially
* @param auxVector auxiliary storage
* @param valueIterationCallback Function that should perform standard value iteration on the input vector
* @param singleIterationCallback Function that should perform a single value iteration step on the input vector e.g. ( x' = min/max(A*x + b))
* @param relevantValues If given, we only check the precision at the states with the given indices.
* @return The status upon termination as well as the number of iterations Also, the maximum (relative/absolute) difference between lowerX and upperX will be 2*epsilon
* with precision parameters as given by the environment env.
* @see Hartmanns, Kaminski: Optimistic Value Iteration. https://doi.org/10.1007/978-3-030-53291-8\_26
*/
template<typename ValueType, typename ValueIterationCallback, typename SingleIterationCallback>
std::pair<SolverStatus, uint64_t> solveEquationsOptimisticValueIteration(Environment const& env, std::vector<ValueType>* lowerX, std::vector<ValueType>* upperX, std::vector<ValueType>* auxVector, ValueIterationCallback const& valueIterationCallback, SingleIterationCallback const& singleIterationCallback, bool relative, ValueType precision, uint64_t maxOverallIterations, boost::optional<storm::storage::BitVector> relevantValues = boost::none) {
STORM_LOG_ASSERT(lowerX->size() == upperX->size(), "Dimension missmatch.");
STORM_LOG_ASSERT(lowerX->size() == auxVector->size(), "Dimension missmatch.");
// As we will shuffle pointers around, let's store the original positions here.
std::vector<ValueType>* initLowerX = lowerX;
std::vector<ValueType>* initUpperX = upperX;
std::vector<ValueType>* initAux = auxVector;
uint64_t overallIterations = 0;
uint64_t lastValueIterationIterations = 0;
uint64_t currentVerificationIterations = 0;
uint64_t valueIterationInvocations = 0;
// Get some parameters for the algorithm
// 2
ValueType two = storm::utility::convertNumber<ValueType>(2.0);
// Use no termination guaranteed upper bound iteration method
bool noTerminationGuarantee = env.solver().ovi().useNoTerminationGuaranteeMinimumMethod();
// Desired max difference between upperX and lowerX
ValueType doublePrecision = precision * two;
// Upper bound only iterations
uint64_t upperBoundOnlyIterations = env.solver().ovi().getUpperBoundOnlyIterations();
ValueType relativeBoundGuessingScaler = (storm::utility::one<ValueType>() + storm::utility::convertNumber<ValueType>(env.solver().ovi().getUpperBoundGuessingFactor()) * precision);
// Initial precision for the value iteration calls
ValueType iterationPrecision = precision;
template<typename ValueType>
class OptimisticValueIterationHelper {
public:
OptimisticValueIterationHelper(storm::storage::SparseMatrix<ValueType> const& matrix);
SolverStatus status = SolverStatus::InProgress;
while (status == SolverStatus::InProgress && overallIterations < maxOverallIterations) {
// Perform value iteration until convergence
++valueIterationInvocations;
auto result = valueIterationCallback(lowerX, auxVector, iterationPrecision, relative, overallIterations, maxOverallIterations);
lastValueIterationIterations = result.iterations;
overallIterations += result.iterations;
if (result.status != SolverStatus::Converged) {
status = result.status;
} else {
bool intervalIterationNeeded = false;
currentVerificationIterations = 0;
if (relative) {
oviinternal::guessUpperBoundRelative(*lowerX, *upperX, relativeBoundGuessingScaler);
} else {
oviinternal::guessUpperBoundAbsolute(*lowerX, *upperX, precision);
}
bool cancelGuess = false;
while (status == SolverStatus::InProgress && overallIterations < maxOverallIterations) {
++overallIterations;
++currentVerificationIterations;
// Perform value iteration stepwise for lower bound and guessed upper bound
// Upper bound iteration
singleIterationCallback(upperX, auxVector, overallIterations);
// At this point, auxVector contains the old values for the upper bound whereas upperX contains the new ones.
// Compare the new upper bound candidate with the old one
bool newUpperBoundAlwaysHigherEqual = true;
bool newUpperBoundAlwaysLowerEqual = true;
if (noTerminationGuarantee) {
bool cancelOuterScan = false;
for (uint64_t i = 0; i < upperX->size() && !cancelOuterScan; ++i) {
if ((*upperX)[i] < (*auxVector)[i]) {
newUpperBoundAlwaysHigherEqual = false;
for (++i; i < upperX->size(); ++i) {
if ((*upperX)[i] > (*auxVector)[i]) {
newUpperBoundAlwaysLowerEqual = false;
cancelOuterScan = true;
break;
}
}
} else if ((*upperX)[i] != (*auxVector)[i]) {
newUpperBoundAlwaysLowerEqual = false;
for (++i; i < upperX->size(); ++i) {
if ((*upperX)[i] < (*auxVector)[i]) {
newUpperBoundAlwaysHigherEqual = false;
cancelOuterScan = true;
break;
}
}
}
}
} else {
for (uint64_t i = 0; i < upperX->size(); ++i) {
if ((*upperX)[i] < (*auxVector)[i]) {
newUpperBoundAlwaysHigherEqual = false;
} else if ((*upperX)[i] != (*auxVector)[i]) {
newUpperBoundAlwaysLowerEqual = false;
std::swap((*upperX)[i], (*auxVector)[i]);
}
}
}
if (newUpperBoundAlwaysHigherEqual && !newUpperBoundAlwaysLowerEqual) {
// All values moved up or stayed the same
// That means the guess for an upper bound is actually a lower bound
iterationPrecision = oviinternal::updateIterationPrecision(env, *auxVector, *upperX, relative, relevantValues);
// We assume to have a single fixed point. We can thus safely set the new lower bound, to the wrongly guessed upper bound
// Set lowerX to the upper bound candidate
std::swap(lowerX, upperX);
break;
} else if (newUpperBoundAlwaysLowerEqual && !newUpperBoundAlwaysHigherEqual) {
// All values moved down or stayed the same and we have a maximum difference of twice the requested precision
// We can safely use twice the requested precision, as we calculate the center of both vectors
bool reachedPrecision;
if (relevantValues) {
reachedPrecision = storm::utility::vector::equalModuloPrecision(*lowerX, *upperX, relevantValues.get(), doublePrecision, relative);
} else {
reachedPrecision = storm::utility::vector::equalModuloPrecision(*lowerX, *upperX, doublePrecision, relative);
}
if (reachedPrecision) {
status = SolverStatus::Converged;
break;
} else {
// From now on, we keep updating both bounds
intervalIterationNeeded = true;
}
// The following case below covers that bouth vectors (old and new) are equal.
// Theoretically, this means that the precise fixpoint has been reached. However, numerical instabilities can be tricky and this detection might be incorrect (see the haddad-monmege model).
// We therefore disable it. It is very unlikely that we guessed the right fixpoint anyway.
//} else if (newUpperBoundAlwaysHigherEqual && newUpperBoundAlwaysLowerEqual) {
// In this case, the guessed upper bound is the precise fixpoint
// status = SolverStatus::Converged;
// std::swap(lowerX, auxVector);
// break;
}
// At this point, the old upper bounds (auxVector) are not needed anymore.
// Check whether we tried this guess for too long
ValueType scaledIterationCount = storm::utility::convertNumber<ValueType>(currentVerificationIterations) * storm::utility::convertNumber<ValueType>(env.solver().ovi().getMaxVerificationIterationFactor());
if (!intervalIterationNeeded && scaledIterationCount >= storm::utility::convertNumber<ValueType>(lastValueIterationIterations)) {
cancelGuess = true;
// In this case we will make one more iteration on the lower bound (mainly to obtain a new iterationPrecision)
}
// Lower bound iteration (only if needed)
if (cancelGuess || intervalIterationNeeded || currentVerificationIterations > upperBoundOnlyIterations) {
singleIterationCallback(lowerX, auxVector, overallIterations);
// At this point, auxVector contains the old values for the lower bound whereas lowerX contains the new ones.
// Check whether the upper and lower bounds have crossed, i.e., the upper bound is smaller than the lower bound.
bool valuesCrossed = false;
for (uint64_t i = 0; i < lowerX->size(); ++i) {
if ((*upperX)[i] < (*lowerX)[i]) {
valuesCrossed = true;
break;
}
}
if (cancelGuess || valuesCrossed) {
// A new guess is needed.
iterationPrecision = oviinternal::updateIterationPrecision(env, *auxVector, *lowerX, relative, relevantValues);
break;
}
}
}
if (storm::utility::resources::isTerminate()) {
status = SolverStatus::Aborted;
}
}
} // end while
/*!
* Return type of value iteration callback.
* The first component shall be the number of performed iterations, the second component is the final convergence status.
*/
typedef std::pair<uint64_t, storm::solver::SolverStatus> ValueIterationReturnType;
// Swap the results into the output vectors.
if (initLowerX == lowerX) {
// lowerX is already at the correct position. We still have to care for upperX
if (initUpperX != upperX) {
// UpperX is not at the correct position. It has to be at the auxVector
assert(initAux == upperX);
std::swap(*initUpperX, *initAux);
}
} else if (initUpperX == upperX) {
// UpperX is already at the correct position.
// We already know that lowerX is at the wrong position. It has to be at the auxVector
assert(initAux == lowerX);
std::swap(*initLowerX, *initAux);
} else if (initAux == auxVector) {
// We know that upperX and lowerX are swapped.
assert(initLowerX == upperX);
assert(initUpperX == lowerX);
std::swap(*initUpperX, *initLowerX);
} else {
// Now we know that all vectors are at the wrong position. There are only two possibilities left
if (initLowerX == upperX) {
assert(initUpperX == auxVector);
assert(initAux == lowerX);
std::swap(*initLowerX, *initAux);
std::swap(*initUpperX, *initAux);
} else {
assert(initLowerX == auxVector);
assert(initUpperX == lowerX);
assert (initAux == upperX);
std::swap(*initUpperX, *initAux);
std::swap(*initLowerX, *initAux);
}
}
/*!
* Value iteration callback. Performs conventional value iteration for the given input.
* @pre y points to a vector that contains starting values
* @post y points to a vector that contains resulting values
* @param yPrime points to auxiliary storage
* @param precision is the target precision
* @param relative sets whether relative precision is considered
* @param maxI the maximal number of iterations to perform
*/
typedef std::function<ValueIterationReturnType(std::vector<ValueType>*& y, std::vector<ValueType>*& yPrime, ValueType const& precision, bool const& relative, uint64_t const& i, uint64_t const& maxI)> ValueIterationCallBackType;
if (overallIterations > maxOverallIterations) {
status = SolverStatus::MaximalIterationsExceeded;
}
/*!
* Should perform a single value iteration step (using conventional value iteration).
* @pre y points to a vector that contains starting values
* @post y points to a vector that contains resulting values
* @param yPrime points to auxiliary storage
* @param currI the current iteration (can be used to display progress within the callback)
*/
typedef std::function<void(std::vector<ValueType>* y, std::vector<ValueType>* yPrime, uint64_t const& currI)> SingleIterationCallBackType;
return {status, overallIterations};
}
/*!
* @param env
* @param lowerX Needs to be some arbitrary lower bound on the actual values initially
* @param upperX Does not need to be an upper bound initially
* @param auxVector auxiliary storage (same size as lowerX and upperX)
* @param b the values added to each matrix row (the b in A*x+b)
* @param valueIterationCallback Function that should perform standard value iteration on the input vector
* @param singleIterationCallback Function that should perform a single value iteration step on the input vector e.g. ( x' = min/max(A*x + b))
* @param dir The optimization direction
* @param relevantValues If given, we only check the precision at the states with the given indices.
* @return The status upon termination as well as the number of iterations Also, the maximum (relative/absolute) difference between lowerX and upperX will be 2*epsilon
* with the provided precision parameters.
*/
std::pair<SolverStatus, uint64_t> solveEquationsOptimisticValueIteration(Environment const& env, std::vector<ValueType>* lowerX, std::vector<ValueType>* upperX, std::vector<ValueType>* auxVector, std::vector<ValueType> const& b, ValueIterationCallBackType const& valueIterationCallback, SingleIterationCallBackType const& singleIterationCallback, bool relative, ValueType precision, uint64_t maxOverallIterations, boost::optional<storm::solver::OptimizationDirection> dir, boost::optional<storm::storage::BitVector> relevantValues = boost::none);
private:
oviinternal::UpperBoundIterator<ValueType> upperBoundIterator;
};
}
}
}
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