void LsodarOSI::computeJacobianRhs(double t, DynamicalSystemsGraph& DSG0)
{
for (DSIterator it = OSIDynamicalSystems->begin(); it != OSIDynamicalSystems->end(); ++it)
{
SP::DynamicalSystem& ds = *it;
ds->computeJacobianRhsx(t);
if (_extraAdditionalTerms)
{
DynamicalSystemsGraph::VDescriptor dsgVD = DSG0.descriptor(ds);
_extraAdditionalTerms->addJacobianRhsContribution(DSG0, dsgVD, t, ds->getJacobianRhsx());
}
}
}
void D1MinusLinearOSI::initializeWorkVectorsForInteraction(Interaction &inter,
InteractionProperties& interProp,
DynamicalSystemsGraph & DSG)
{
DEBUG_BEGIN("D1MinusLinearOSI::initializeWorkVectorsForInteraction(Interaction &inter, InteractionProperties& interProp, DynamicalSystemsGraph & DSG)\n");
SP::DynamicalSystem ds1= interProp.source;
SP::DynamicalSystem ds2= interProp.target;
assert(ds1);
assert(ds2);
DEBUG_PRINTF("interaction number %i\n", inter.number());
VectorOfBlockVectors& DSlink = inter.linkToDSVariables();
if (!interProp.workVectors)
{
interProp.workVectors.reset(new VectorOfVectors);
interProp.workVectors->resize(D1MinusLinearOSI::WORK_INTERACTION_LENGTH);
}
if (!interProp.workBlockVectors)
{
interProp.workBlockVectors.reset(new VectorOfBlockVectors);
interProp.workBlockVectors->resize(D1MinusLinearOSI::BLOCK_WORK_LENGTH);
}
VectorOfVectors& inter_work = *interProp.workVectors;
VectorOfBlockVectors& inter_work_block = *interProp.workBlockVectors;
Relation &relation = *inter.relation();
RELATION::TYPES relationType = relation.getType();
inter_work[D1MinusLinearOSI::OSNSP_RHS].reset(new SiconosVector(inter.dimension()));
// Check if interations levels (i.e. y and lambda sizes) are compliant with the current osi.
_check_and_update_interaction_levels(inter);
// Initialize/allocate memory buffers in interaction.
inter.initializeMemory(_steps);
if (!(checkOSI(DSG.descriptor(ds1)) && checkOSI(DSG.descriptor(ds2))))
{
std::cout << "checkOSI(DSG.descriptor(ds1)): "
<< std::boolalpha
<< checkOSI(DSG.descriptor(ds1)) << std::endl;
std::cout << "checkOSI(DSG.descriptor(ds2)): "
<< std::boolalpha
<< checkOSI(DSG.descriptor(ds2)) << std::endl;
RuntimeException::selfThrow("D1MinusLinearOSI::initializeWorkVectorsForInteraction. The implementation is not correct for two different OSI for one interaction");
}
/* allocate and set work vectors for the osi */
unsigned int xfree = D1MinusLinearOSI::xfree;
DEBUG_PRINTF("ds1->number() %i\n",ds1->number());
DEBUG_PRINTF("ds2->number() %i\n",ds2->number());
if (ds1 != ds2)
{
DEBUG_PRINT("ds1 != ds2\n");
if ((!inter_work_block[xfree]) || (inter_work_block[xfree]->numberOfBlocks() !=2 ))
inter_work_block[xfree].reset(new BlockVector(2));
}
else
{
if ((!inter_work_block[xfree]) || (inter_work_block[xfree]->numberOfBlocks() !=1 ))
inter_work_block[xfree].reset(new BlockVector(1));
}
if(checkOSI(DSG.descriptor(ds1)))
{
DEBUG_PRINTF("ds1->number() %i is taken into account\n", ds1->number());
assert(DSG.properties(DSG.descriptor(ds1)).workVectors);
VectorOfVectors &workVds1 = *DSG.properties(DSG.descriptor(ds1)).workVectors;
inter_work_block[xfree]->setVectorPtr(0,workVds1[D1MinusLinearOSI::FREE]);
}
if (ds1 != ds2)
{
DEBUG_PRINT("ds1 != ds2\n");
if(checkOSI(DSG.descriptor(ds2)))
{
DEBUG_PRINTF("ds2->number() %i is taken into account\n",ds2->number());
assert(DSG.properties(DSG.descriptor(ds2)).workVectors);
VectorOfVectors &workVds2 = *DSG.properties(DSG.descriptor(ds2)).workVectors;
inter_work_block[xfree]->setVectorPtr(1,workVds2[D1MinusLinearOSI::FREE]);
}
}
DEBUG_EXPR(inter_work_block[xfree]->display(););
void SchatzmanPaoliOSI::initializeWorkVectorsForInteraction(Interaction &inter,
InteractionProperties& interProp,
DynamicalSystemsGraph & DSG)
{
SP::DynamicalSystem ds1= interProp.source;
SP::DynamicalSystem ds2= interProp.target;
assert(ds1);
assert(ds2);
VectorOfBlockVectors& DSlink = inter.linkToDSVariables();
if (!interProp.workVectors)
{
interProp.workVectors.reset(new VectorOfVectors);
interProp.workVectors->resize(SchatzmanPaoliOSI::WORK_INTERACTION_LENGTH);
}
if (!interProp.workBlockVectors)
{
interProp.workBlockVectors.reset(new VectorOfBlockVectors);
interProp.workBlockVectors->resize(SchatzmanPaoliOSI::BLOCK_WORK_LENGTH);
}
VectorOfVectors& inter_work = *interProp.workVectors;
VectorOfBlockVectors& inter_work_block = *interProp.workBlockVectors;
Relation &relation = *inter.relation();
inter_work[SchatzmanPaoliOSI::OSNSP_RHS].reset(new SiconosVector(inter.dimension()));
RELATION::TYPES relationType = relation.getType();
// Check if interations levels (i.e. y and lambda sizes) are compliant with the current osi.
_check_and_update_interaction_levels(inter);
// Initialize/allocate memory buffers in interaction.
inter.initializeMemory(_steps);
if (!(checkOSI(DSG.descriptor(ds1)) && checkOSI(DSG.descriptor(ds2))))
{
RuntimeException::selfThrow("SchatzmanPaoliOSI::initializeWorkVectorsForInteraction. The implementation is not correct for two different OSI for one interaction");
}
/* allocate and set work vectors for the osi */
VectorOfVectors &workVds1 = *DSG.properties(DSG.descriptor(ds1)).workVectors;
if (relationType == Lagrangian)
{
LagrangianDS& lds = *std11::static_pointer_cast<LagrangianDS> (ds1);
DSlink[LagrangianR::p0].reset(new BlockVector());
DSlink[LagrangianR::p0]->insertPtr(lds.p(0));
inter_work_block[SchatzmanPaoliOSI::xfree].reset(new BlockVector());
inter_work_block[SchatzmanPaoliOSI::xfree]->insertPtr(workVds1[SchatzmanPaoliOSI::FREE]);
}
else if (relationType == NewtonEuler)
{
inter_work_block[SchatzmanPaoliOSI::xfree].reset(new BlockVector());
inter_work_block[SchatzmanPaoliOSI::xfree]->insertPtr(workVds1[SchatzmanPaoliOSI::FREE]);
}
if (ds1 != ds2)
{
VectorOfVectors &workVds2 = *DSG.properties(DSG.descriptor(ds2)).workVectors;
if (relationType == Lagrangian)
{
inter_work_block[SchatzmanPaoliOSI::xfree]->insertPtr(workVds2[SchatzmanPaoliOSI::FREE]);
LagrangianDS& lds = *std11::static_pointer_cast<LagrangianDS> (ds2);
DSlink[LagrangianR::p0]->insertPtr(lds.p(0));
}
else if (relationType == NewtonEuler)
{
inter_work_block[SchatzmanPaoliOSI::xfree]->insertPtr(workVds2[SchatzmanPaoliOSI::FREE]);
}
}
}
