void CompoundSymMatrix::PrintImpl(
const Journalist& jnlst,
EJournalLevel level,
EJournalCategory category,
const std::string& name,
Index indent,
const std::string& prefix
) const
{
jnlst.Printf(level, category, "\n");
jnlst.PrintfIndented(level, category, indent, "%sCompoundSymMatrix \"%s\" with %d rows and columns components:\n",
prefix.c_str(), name.c_str(), NComps_Dim());
for( Index irow = 0; irow < NComps_Dim(); irow++ )
{
for( Index jcol = 0; jcol <= irow; jcol++ )
{
jnlst.PrintfIndented(level, category, indent, "%sComponent for row %d and column %d:\n", prefix.c_str(), irow,
jcol);
if( ConstComp(irow, jcol) )
{
DBG_ASSERT(name.size() < 200);
char buffer[256];
Snprintf(buffer, 255, "%s[%d][%d]", name.c_str(), irow, jcol);
std::string term_name = buffer;
ConstComp(irow, jcol)->Print(&jnlst, level, category, term_name, indent + 1, prefix);
}
else
{
jnlst.PrintfIndented(level, category, indent, "%sThis component has not been set.\n", prefix.c_str());
}
}
}
}
void CompoundSymMatrix::ComputeRowAMaxImpl(
Vector& rows_norms,
bool init
) const
{
if( !matrices_valid_ )
{
matrices_valid_ = MatricesValid();
} DBG_ASSERT(matrices_valid_);
// The vector is assumed to be compound Vectors as well except if
// there is only one component
CompoundVector* comp_vec = dynamic_cast<CompoundVector*>(&rows_norms);
// A few sanity checks
if( comp_vec )
{
DBG_ASSERT(NComps_Dim() == comp_vec->NComps());
}
else
{
DBG_ASSERT(NComps_Dim() == 1);
}
for( Index jcol = 0; jcol < NComps_Dim(); jcol++ )
{
for( Index irow = 0; irow < NComps_Dim(); irow++ )
{
SmartPtr<Vector> vec_i;
if( comp_vec )
{
vec_i = comp_vec->GetCompNonConst(irow);
}
else
{
vec_i = &rows_norms;
} DBG_ASSERT(IsValid(vec_i));
if( jcol <= irow && ConstComp(irow, jcol) )
{
ConstComp(irow, jcol)->ComputeRowAMax(*vec_i, false);
}
else if( jcol > irow && ConstComp(jcol, irow) )
{
ConstComp(jcol, irow)->ComputeRowAMax(*vec_i, false);
}
}
}
}
CompoundSymMatrix::CompoundSymMatrix(const CompoundSymMatrixSpace* owner_space)
:
SymMatrix(owner_space),
owner_space_(owner_space),
matrices_valid_(false)
{
for (Index irow=0; irow<NComps_Dim(); irow++) {
std::vector< SmartPtr<Matrix> > row(irow+1);
std::vector< SmartPtr<const Matrix> > const_row(irow+1);
comps_.push_back(row);
const_comps_.push_back(const_row);
}
}
/** Internal method to return a non-const pointer to one of the comps */
Matrix* Comp(Index irow, Index jcol)
{
DBG_ASSERT(irow < NComps_Dim());
DBG_ASSERT(jcol <= irow);
// We shouldn't be asking for a non-const if this entry holds a
// const one...
DBG_ASSERT(IsNull(const_comps_[irow][jcol]));
if (IsValid(comps_[irow][jcol])) {
return GetRawPtr(comps_[irow][jcol]);
}
return NULL;
}
/** Internal method to return a const pointer to one of the comps */
const Matrix* ConstComp(Index irow, Index jcol) const
{
DBG_ASSERT(irow < NComps_Dim());
DBG_ASSERT(jcol <= irow);
if (IsValid(comps_[irow][jcol])) {
return GetRawPtr(comps_[irow][jcol]);
}
else if (IsValid(const_comps_[irow][jcol])) {
return GetRawPtr(const_comps_[irow][jcol]);
}
return NULL;
}
void CompoundSymMatrix::SetCompNonConst(Index irow, Index jcol,
Matrix& matrix)
{
DBG_ASSERT(!matrices_valid_);
DBG_ASSERT(irow < NComps_Dim());
DBG_ASSERT(jcol <= irow);
// Matrices on the diagonal must be symmetric
DBG_ASSERT( irow != jcol || dynamic_cast<SymMatrix*>(&matrix));
DBG_ASSERT(owner_space_->GetCompSpace(irow, jcol)->IsMatrixFromSpace(matrix));
const_comps_[irow][jcol] = NULL;
comps_[irow][jcol] = &matrix;
ObjectChanged();
}
CompoundSymMatrix* CompoundSymMatrixSpace::MakeNewCompoundSymMatrix() const
{
if (!dimensions_set_) {
dimensions_set_ = DimensionsSet();
}
DBG_ASSERT(dimensions_set_);
CompoundSymMatrix* mat = new CompoundSymMatrix(this);
for(Index i=0; i<NComps_Dim(); i++) {
for (Index j=0; j<=i; j++) {
if (allocate_block_[i][j]) {
mat->SetCompNonConst(i, j, *GetCompSpace(i, j)->MakeNew());
}
}
}
return mat;
}
bool CompoundSymMatrix::MatricesValid() const
{
// Check to make sure we have matrices everywhere the space has matrices
// We already check that the matrix agrees with the block space
// in the SetComp methods
bool retValue = true;
for (Index i=0; i<NComps_Dim(); i++) {
for (Index j=0; j<=i; j++) {
if ( (!ConstComp(i, j) && IsValid(owner_space_->GetCompSpace(i,j)))
|| (ConstComp(i, j) && IsNull(owner_space_->GetCompSpace(i,j))) ) {
retValue = false;
break;
}
}
}
return retValue;
}
bool CompoundSymMatrix::HasValidNumbersImpl() const
{
if (!matrices_valid_) {
matrices_valid_ = MatricesValid();
}
DBG_ASSERT(matrices_valid_);
for (Index irow=0; irow<NComps_Dim(); irow++) {
for (Index jcol=0; jcol<=irow; jcol++) {
if (ConstComp(irow,jcol)) {
if (!ConstComp(irow,jcol)->HasValidNumbers()) {
return false;
}
}
}
}
return true;
}
void CompoundSymMatrix::MultVectorImpl(Number alpha, const Vector &x,
Number beta, Vector &y) const
{
if (!matrices_valid_) {
matrices_valid_ = MatricesValid();
}
DBG_ASSERT(matrices_valid_);
// The vectors are assumed to be compound Vectors as well
const CompoundVector* comp_x = dynamic_cast<const CompoundVector*>(&x);
CompoundVector* comp_y = dynamic_cast<CompoundVector*>(&y);
// A few sanity checks
if (comp_x) {
DBG_ASSERT(NComps_Dim()==comp_x->NComps());
}
else {
DBG_ASSERT(NComps_Dim() == 1);
}
if (comp_y) {
DBG_ASSERT(NComps_Dim()==comp_y->NComps());
}
else {
DBG_ASSERT(NComps_Dim() == 1);
}
// Take care of the y part of the addition
if( beta!=0.0 ) {
y.Scal(beta);
}
else {
y.Set(0.0); // In case y hasn't been initialized yet
}
for (Index irow=0; irow<NComps_Dim(); irow++) {
SmartPtr<Vector> y_i;
if (comp_y) {
y_i = comp_y->GetCompNonConst(irow);
}
else {
y_i = &y;
}
DBG_ASSERT(IsValid(y_i));
for (Index jcol=0; jcol<=irow; jcol++) {
SmartPtr<const Vector> x_j;
if (comp_x) {
x_j = comp_x->GetComp(irow);
}
else {
x_j = &x;
}
DBG_ASSERT(IsValid(x_j));
if (ConstComp(irow,jcol)) {
ConstComp(irow,jcol)->MultVector(alpha, *comp_x->GetComp(jcol),
1., *comp_y->GetCompNonConst(irow));
}
}
for (Index jcol = irow+1; jcol < NComps_Dim(); jcol++) {
if (ConstComp(jcol,irow)) {
ConstComp(jcol,irow)->TransMultVector(alpha, *comp_x->GetComp(jcol),
1., *comp_y->GetCompNonConst(irow));
}
}
}
}
