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started on Walker-Chae algorithm

tempestpy_adaptions
dehnert 7 years ago
parent
c77b9ce404
commit
5440d164b2
7 changed files with 303 additions and 81 deletions
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  1. 4
      src/storm/settings/modules/NativeEquationSolverSettings.cpp
  2. 2
      src/storm/settings/modules/NativeEquationSolverSettings.h
  3. 174
      src/storm/solver/NativeLinearEquationSolver.cpp
  4. 11
      src/storm/solver/NativeLinearEquationSolver.h
  5. 31
      src/storm/storage/SparseMatrix.cpp
  6. 11
      src/storm/storage/SparseMatrix.h
  7. 17
      src/storm/utility/vector.h

4
src/storm/settings/modules/NativeEquationSolverSettings.cpp
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@ -24,7 +24,7 @@ namespace storm {
const std::string NativeEquationSolverSettings::absoluteOptionName = "absolute";
NativeEquationSolverSettings::NativeEquationSolverSettings() : ModuleSettings(moduleName) {
std::vector<std::string> methods = { "jacobi", "gaussseidel", "sor" };
std::vector<std::string> methods = { "jacobi", "gaussseidel", "sor", "walkerchae" };
this->addOption(storm::settings::OptionBuilder(moduleName, techniqueOptionName, true, "The method to be used for solving linear equation systems with the native engine.").addArgument(storm::settings::ArgumentBuilder::createStringArgument("name", "The name of the method to use.").addValidatorString(ArgumentValidatorFactory::createMultipleChoiceValidator(methods)).setDefaultValueString("jacobi").build()).build());
this->addOption(storm::settings::OptionBuilder(moduleName, maximalIterationsOptionName, false, "The maximal number of iterations to perform before iterative solving is aborted.").setShortName(maximalIterationsOptionShortName).addArgument(storm::settings::ArgumentBuilder::createUnsignedIntegerArgument("count", "The maximal iteration count.").setDefaultValueUnsignedInteger(20000).build()).build());
@ -52,6 +52,8 @@ namespace storm {
return NativeEquationSolverSettings::LinearEquationMethod::GaussSeidel;
} else if (linearEquationSystemTechniqueAsString == "sor") {
return NativeEquationSolverSettings::LinearEquationMethod::SOR;
} else if (linearEquationSystemTechniqueAsString == "walkerchae") {
return NativeEquationSolverSettings::LinearEquationMethod::WalkerChae;
}
STORM_LOG_THROW(false, storm::exceptions::IllegalArgumentValueException, "Unknown solution technique '" << linearEquationSystemTechniqueAsString << "' selected.");
}

2
src/storm/settings/modules/NativeEquationSolverSettings.h
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@ -13,7 +13,7 @@ namespace storm {
class NativeEquationSolverSettings : public ModuleSettings {
public:
// An enumeration of all available methods for solving linear equations.
enum class LinearEquationMethod { Jacobi, GaussSeidel, SOR };
enum class LinearEquationMethod { Jacobi, GaussSeidel, SOR, WalkerChae };
// An enumeration of all available convergence criteria.
enum class ConvergenceCriterion { Absolute, Relative };

174
src/storm/solver/NativeLinearEquationSolver.cpp
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@ -5,6 +5,7 @@
#include "storm/settings/SettingsManager.h"
#include "storm/settings/modules/NativeEquationSolverSettings.h"
#include "storm/utility/constants.h"
#include "storm/utility/vector.h"
#include "storm/exceptions/InvalidStateException.h"
#include "storm/exceptions/InvalidSettingsException.h"
@ -23,6 +24,8 @@ namespace storm {
method = SolutionMethod::Jacobi;
} else if (methodAsSetting == storm::settings::modules::NativeEquationSolverSettings::LinearEquationMethod::SOR) {
method = SolutionMethod::SOR;
} else if (methodAsSetting == storm::settings::modules::NativeEquationSolverSettings::LinearEquationMethod::WalkerChae) {
method = SolutionMethod::WalkerChae;
} else {
STORM_LOG_THROW(false, storm::exceptions::InvalidSettingsException, "The selected solution technique is invalid for this solver.");
}
@ -107,19 +110,14 @@ namespace storm {
clearCache();
}
template<typename ValueType>
bool NativeLinearEquationSolver<ValueType>::solveEquations(std::vector<ValueType>& x, std::vector<ValueType> const& b) const {
bool NativeLinearEquationSolver<ValueType>::solveEquationsSOR(std::vector<ValueType>& x, std::vector<ValueType> const& b, ValueType const& omega) const {
STORM_LOG_INFO("Solving linear equation system (" << x.size() << " rows) with NativeLinearEquationSolver (Gauss-Seidel, SOR omega = " << omega << ")");
if (!this->cachedRowVector) {
this->cachedRowVector = std::make_unique<std::vector<ValueType>>(getMatrixRowCount());
}
if (this->getSettings().getSolutionMethod() == NativeLinearEquationSolverSettings<ValueType>::SolutionMethod::SOR || this->getSettings().getSolutionMethod() == NativeLinearEquationSolverSettings<ValueType>::SolutionMethod::GaussSeidel) {
// Define the omega used for SOR.
ValueType omega = this->getSettings().getSolutionMethod() == NativeLinearEquationSolverSettings<ValueType>::SolutionMethod::SOR ? this->getSettings().getOmega() : storm::utility::one<ValueType>();
STORM_LOG_INFO("Solving linear equation system (" << x.size() << " rows) with NativeLinearEquationSolver (Gauss-Seidel, SOR omega = " << omega << ")");
// Set up additional environment variables.
uint_fast64_t iterationCount = 0;
bool converged = false;
@ -150,10 +148,16 @@ namespace storm {
}
return converged;
}
} else {
template<typename ValueType>
bool NativeLinearEquationSolver<ValueType>::solveEquationsJacobi(std::vector<ValueType>& x, std::vector<ValueType> const& b) const {
STORM_LOG_INFO("Solving linear equation system (" << x.size() << " rows) with NativeLinearEquationSolver (Jacobi)");
if (!this->cachedRowVector) {
this->cachedRowVector = std::make_unique<std::vector<ValueType>>(getMatrixRowCount());
}
// Get a Jacobi decomposition of the matrix A.
if (!jacobiDecomposition) {
jacobiDecomposition = std::make_unique<std::pair<storm::storage::SparseMatrix<ValueType>, std::vector<ValueType>>>(A->getJacobiDecomposition());
@ -200,8 +204,157 @@ namespace storm {
STORM_LOG_WARN("Iterative solver did not converge in " << iterationCount << " iterations.");
}
return iterationCount < this->getSettings().getMaximalNumberOfIterations();
return converged;
}
template<typename ValueType>
void NativeLinearEquationSolver<ValueType>::computeWalkerChaeMatrix() const {
storm::storage::BitVector columnsWithNegativeEntries(this->A->getColumnCount());
ValueType zero = storm::utility::zero<ValueType>();
for (auto const& e : *this->A) {
if (e.getValue() < zero) {
columnsWithNegativeEntries.set(e.getColumn());
}
}
std::vector<uint64_t> columnsWithNegativeEntriesBefore = columnsWithNegativeEntries.getNumberOfSetBitsBeforeIndices();
// We now build an extended equation system matrix that only has non-negative coefficients.
storm::storage::SparseMatrixBuilder<ValueType> builder;
uint64_t row = 0;
for (; row < this->A->getRowCount(); ++row) {
for (auto const& entry : this->A->getRow(row)) {
if (entry.getValue() < zero) {
builder.addNextValue(row, this->A->getRowCount() + columnsWithNegativeEntriesBefore[entry.getColumn()], -entry.getValue());
} else {
builder.addNextValue(row, entry.getColumn(), entry.getValue());
}
}
}
ValueType one = storm::utility::one<ValueType>();
for (auto column : columnsWithNegativeEntries) {
builder.addNextValue(row, column, one);
builder.addNextValue(row, this->A->getRowCount() + columnsWithNegativeEntriesBefore[column], one);
++row;
}
walkerChaeMatrix = std::make_unique<storm::storage::SparseMatrix<ValueType>>(builder.build());
}
template<typename ValueType>
bool NativeLinearEquationSolver<ValueType>::solveEquationsWalkerChae(std::vector<ValueType>& x, std::vector<ValueType> const& b) const {
STORM_LOG_INFO("Solving linear equation system (" << x.size() << " rows) with NativeLinearEquationSolver (WalkerChae)");
// (1) Compute an equivalent equation system that has only non-negative coefficients.
if (!walkerChaeMatrix) {
std::cout << *this->A << std::endl;
computeWalkerChaeMatrix();
std::cout << *walkerChaeMatrix << std::endl;
}
// (2) Enlarge the vectors x and b to account for additional variables.
x.resize(walkerChaeMatrix->getRowCount());
if (walkerChaeMatrix->getRowCount() > this->A->getRowCount() && !walkerChaeB) {
walkerChaeB = std::make_unique<std::vector<ValueType>>(b);
walkerChaeB->resize(x.size());
}
// Choose a value for t in the algorithm.
ValueType t = storm::utility::convertNumber<ValueType>(1000);
// Precompute some data.
std::vector<ValueType> columnSums(x.size());
for (auto const& e : *walkerChaeMatrix) {
STORM_LOG_ASSERT(e.getValue() >= storm::utility::zero<ValueType>(), "Expecting only non-negative entries in WalkerChae matrix.");
columnSums[e.getColumn()] += e.getValue();
}
// Square the error bound, so we can use it to check for convergence. We take the squared error, because we
// do not want to compute the root in the 2-norm computation.
ValueType squaredErrorBound = storm::utility::pow(this->getSettings().getPrecision(), 2);
// Create a vector that always holds Ax.
std::vector<ValueType> currentAx(x.size());
walkerChaeMatrix->multiplyWithVector(x, currentAx);
// Create an auxiliary vector that intermediately stores the result of the Walker-Chae step.
std::vector<ValueType> tmpX(x.size());
// Set up references to the x-vectors used in the iteration loop.
std::vector<ValueType>* currentX = &x;
std::vector<ValueType>* nextX = &tmpX;
// Prepare a function that adds t to its input.
auto addT = [t] (ValueType const& value) { return value + t; };
// (3) Perform iterations until convergence.
bool converged = false;
uint64_t iterations = 0;
while (!converged && iterations < this->getSettings().getMaximalNumberOfIterations()) {
// Perform one Walker-Chae step.
A->performWalkerChaeStep(*currentX, columnSums, *walkerChaeB, currentAx, *nextX);
// Compute new Ax.
A->multiplyWithVector(*nextX, currentAx);
// Check for convergence.
converged = storm::utility::vector::computeSquaredNorm2Difference(currentAx, *walkerChaeB);
// If the method did not yet converge, we need to update the value of Ax.
if (!converged) {
// TODO: scale matrix diagonal entries with t and add them to *walkerChaeB.
// Add t to all entries of x.
storm::utility::vector::applyPointwise(x, x, addT);
}
std::swap(currentX, nextX);
// Increase iteration count so we can abort if convergence is too slow.
++iterations;
}
// If the last iteration did not write to the original x we have to swap the contents, because the
// output has to be written to the input parameter x.
if (currentX == &tmpX) {
std::swap(x, *currentX);
}
if (!this->isCachingEnabled()) {
clearCache();
}
if (converged) {
STORM_LOG_INFO("Iterative solver converged in " << iterations << " iterations.");
} else {
STORM_LOG_WARN("Iterative solver did not converge in " << iterations << " iterations.");
}
// Resize the solution to the right size.
x.resize(this->A->getRowCount());
// Finalize solution vector.
storm::utility::vector::applyPointwise(x, x, [&t,iterations] (ValueType const& value) { return value - iterations * t; } );
if (!this->isCachingEnabled()) {
clearCache();
}
return converged;
}
template<typename ValueType>
bool NativeLinearEquationSolver<ValueType>::solveEquations(std::vector<ValueType>& x, std::vector<ValueType> const& b) const {
if (this->getSettings().getSolutionMethod() == NativeLinearEquationSolverSettings<ValueType>::SolutionMethod::SOR || this->getSettings().getSolutionMethod() == NativeLinearEquationSolverSettings<ValueType>::SolutionMethod::GaussSeidel) {
return this->solveEquationsSOR(x, b, this->getSettings().getSolutionMethod() == NativeLinearEquationSolverSettings<ValueType>::SolutionMethod::SOR ? this->getSettings().getOmega() : storm::utility::one<ValueType>());
} else if (this->getSettings().getSolutionMethod() == NativeLinearEquationSolverSettings<ValueType>::SolutionMethod::Jacobi) {
return this->solveEquationsJacobi(x, b);
} else if (this->getSettings().getSolutionMethod() == NativeLinearEquationSolverSettings<ValueType>::SolutionMethod::WalkerChae) {
return this->solveEquationsWalkerChae(x, b);
}
STORM_LOG_THROW(false, storm::exceptions::InvalidSettingsException, "Unknown solving technique.");
return false;
}
template<typename ValueType>
@ -271,6 +424,7 @@ namespace storm {
template<typename ValueType>
void NativeLinearEquationSolver<ValueType>::clearCache() const {
jacobiDecomposition.reset();
walkerChaeMatrix.reset();
LinearEquationSolver<ValueType>::clearCache();
}

11
src/storm/solver/NativeLinearEquationSolver.h
View File

@ -12,7 +12,7 @@ namespace storm {
class NativeLinearEquationSolverSettings {
public:
enum class SolutionMethod {
Jacobi, GaussSeidel, SOR
Jacobi, GaussSeidel, SOR, WalkerChae
};
NativeLinearEquationSolverSettings();
@ -65,6 +65,12 @@ namespace storm {
virtual uint64_t getMatrixRowCount() const override;
virtual uint64_t getMatrixColumnCount() const override;
virtual bool solveEquationsSOR(std::vector<ValueType>& x, std::vector<ValueType> const& b, ValueType const& omega) const;
virtual bool solveEquationsJacobi(std::vector<ValueType>& x, std::vector<ValueType> const& b) const;
virtual bool solveEquationsWalkerChae(std::vector<ValueType>& x, std::vector<ValueType> const& b) const;
void computeWalkerChaeMatrix() const;
// If the solver takes posession of the matrix, we store the moved matrix in this member, so it gets deleted
// when the solver is destructed.
std::unique_ptr<storm::storage::SparseMatrix<ValueType>> localA;
@ -78,6 +84,9 @@ namespace storm {
// cached auxiliary data
mutable std::unique_ptr<std::pair<storm::storage::SparseMatrix<ValueType>, std::vector<ValueType>>> jacobiDecomposition;
mutable std::unique_ptr<storm::storage::SparseMatrix<ValueType>> walkerChaeMatrix;
mutable std::unique_ptr<std::vector<ValueType>> walkerChaeB;
};
template<typename ValueType>

31
src/storm/storage/SparseMatrix.cpp
View File

@ -18,6 +18,7 @@
#include "storm/exceptions/InvalidStateException.h"
#include "storm/exceptions/NotImplementedException.h"
#include "storm/exceptions/NotSupportedException.h"
#include "storm/exceptions/InvalidArgumentException.h"
#include "storm/exceptions/OutOfRangeException.h"
@ -1455,7 +1456,35 @@ namespace storm {
#ifdef STORM_HAVE_CARL
template<>
void SparseMatrix<Interval>::performSuccessiveOverRelaxationStep(Interval, std::vector<Interval>&, std::vector<Interval> const&) const {
STORM_LOG_THROW(false, storm::exceptions::NotImplementedException, "This operation is not supported.");
STORM_LOG_THROW(false, storm::exceptions::NotSupportedException, "This operation is not supported.");
}
#endif
template<typename ValueType>
void SparseMatrix<ValueType>::performWalkerChaeStep(std::vector<ValueType> const& x, std::vector<ValueType> const& columnSums, std::vector<ValueType> const& b, std::vector<ValueType> const& ax, std::vector<ValueType>& result) const {
const_iterator it = this->begin();
const_iterator ite;
std::vector<index_type>::const_iterator rowIterator = rowIndications.begin();
typename std::vector<ValueType>::iterator resultIterator = result.begin();
typename std::vector<ValueType>::iterator resultIteratorEnd = result.end();
typename std::vector<ValueType>::const_iterator xIterator = x.begin();
typename std::vector<ValueType>::const_iterator columnSumsIterator = columnSums.begin();
for (; resultIterator != resultIteratorEnd; ++rowIterator, ++resultIterator, ++xIterator, ++columnSumsIterator) {
*resultIterator = storm::utility::zero<ValueType>();
for (ite = this->begin() + *(rowIterator + 1); it != ite; ++it) {
*resultIterator += it->getValue() * (b[it->getColumn()] / ax[it->getColumn()]);
}
*resultIterator *= (*xIterator / *columnSumsIterator);
}
}
#ifdef STORM_HAVE_CARL
template<>
void SparseMatrix<Interval>::performWalkerChaeStep(std::vector<Interval> const& x, std::vector<Interval> const& columnSums, std::vector<Interval> const& b, std::vector<Interval> const& ax, std::vector<Interval>& result) const {
STORM_LOG_THROW(false, storm::exceptions::NotSupportedException, "This operation is not supported.");
}
#endif

11
src/storm/storage/SparseMatrix.h
View File

@ -848,6 +848,17 @@ namespace storm {
*/
void performSuccessiveOverRelaxationStep(ValueType omega, std::vector<ValueType>& x, std::vector<ValueType> const& b) const;
/*!
* Performs one step of the Walker-Chae technique.
*
* @param x The current solution vector.
* @param columnSums The sums of the entries of the individual columns.
* @param b The 'right-hand side' of the problem.
* @param ax A vector resulting from multiplying the current matrix with the vector x.
* @param result The vector to which to write the result.
*/
void performWalkerChaeStep(std::vector<ValueType> const& x, std::vector<ValueType> const& columnSums, std::vector<ValueType> const& b, std::vector<ValueType> const& ax, std::vector<ValueType>& result) const;
/*!
* Computes the sum of the entries in a given row.
*

17
src/storm/utility/vector.h
View File

@ -822,6 +822,23 @@ namespace storm {
return true;
}
template<class T>
T computeSquaredNorm2Difference(std::vector<T> const& b1, std::vector<T> const& b2) {
STORM_LOG_ASSERT(b1.size() == b2.size(), "Vector sizes mismatch.");
T result = storm::utility::zero<T>();
auto b1It = b1.begin();
auto b1Ite = b1.end();
auto b2It = b2.begin();
for (; b1It != b1Ite; ++b1It, ++b2It) {
result += storm::utility::pow(*b1It - *b2It, 2);
}
return result;
}
/*!
* Takes the input vector and ensures that all entries conform to the bounds.
*/
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