コード例 #1
0
ファイル: BandArpackSOE.cpp プロジェクト: lcpt/xc
//! @brief Sets the size of the system from the number of vertices in the graph.
int XC::BandArpackSOE::setSize(Graph &theGraph)
  {
    int result = 0;
    size= checkSize(theGraph);

    // determine the number of superdiagonals and subdiagonals
    theGraph.getBand(numSubD,numSuperD);

    const int newSize = size * (2*numSubD + numSuperD +1);
    if(newSize > A.Size())
      A.resize(newSize);
    A.Zero();
    factored = false;

    // invoke setSize() on the XC::Solver
    EigenSolver *theSolvr = this->getSolver();
    int solverOK = theSolvr->setSize();
    if(solverOK < 0)
      {
        std::cerr << "WARNING: BandArpackSOE::setSize :";
        std::cerr << " solver failed setSize()\n";
        return solverOK;
      }
    return result;
  }
コード例 #2
0
ファイル: SymArpackSOE.cpp プロジェクト: aceskpark/osfeo
int 
SymArpackSOE::setSize(Graph &theGraph)
{
    int result = 0;
    int oldSize = size;
    size = theGraph.getNumVertex();

    // fist itearte through the vertices of the graph to get nnz
    Vertex *theVertex;
    int newNNZ = 0;
    VertexIter &theVertices = theGraph.getVertices();
    while ((theVertex = theVertices()) != 0) {
        const ID &theAdjacency = theVertex->getAdjacency();
	newNNZ += theAdjacency.Size(); 
    }
    nnz = newNNZ;

    if (colA != 0)
      delete [] colA;

    colA = new int[newNNZ];	
    if (colA == 0) {
	opserr << "WARNING SymArpackSOE::SymArpackSOE :";
	opserr << " ran out of memory for colA with nnz = ";
      	opserr << newNNZ << " \n";
       	size = 0; nnz = 0;
       	result =  -1;
    } 
	
    factored = false;

    if (rowStartA != 0) 
      delete [] rowStartA;
    rowStartA = new int[size+1]; 
    if (rowStartA == 0) {
        opserr << "SymArpackSOE::ran out of memory for rowStartA." << endln;
        result = -1;
    }

    // fill in rowStartA and colA
    if (size != 0) {
        rowStartA[0] = 0;
        int startLoc = 0;
	int lastLoc = 0;

	for (int a=0; a<size; a++) {
	   theVertex = theGraph.getVertexPtr(a);
	   if (theVertex == 0) {
	        opserr << "WARNING:SymArpackSOE::setSize :";
	        opserr << " vertex " << a << " not in graph! - size set to 0\n";
	        size = 0;
	        return -1;
	   }

	   const ID &theAdjacency = theVertex->getAdjacency();
	   int idSize = theAdjacency.Size();
	
	// now we have to place the entries in the ID into order in colA
	   for (int i=0; i<idSize; i++) {
	      int row = theAdjacency(i);
	      bool foundPlace = false;
	 
	      for (int j=startLoc; j<lastLoc; j++)
	          if (colA[j] > row) { 
	      // move the entries already there one further on
	      // and place col in current location
	              for (int k=lastLoc; k>j; k--)
		          colA[k] = colA[k-1];
                      colA[j] = row;
		      foundPlace = true;
    	              j = lastLoc;
		  }
		  
	      if (foundPlace == false) // put in at the end
	      	   colA[lastLoc] = row;

	      lastLoc++;
	   }
	   rowStartA[a+1] = lastLoc;;	    
	   startLoc = lastLoc;
	}
    }

    // begin to choose different ordering schema.
    //   cout << "Enter DOF Numberer Type: \n";
    //   cout << "[1] Minimum Degree, [2] Nested Dissection, [3] RCM: ";
    int LSPARSE = 1;
    //   cin >> LSPARSE;

// call "C" function to form elimination tree and do the symbolic factorization.
//    nblks = symFactorization(rowStartA, colA, size, LSPARSE);
    nblks = symFactorization(rowStartA, colA, size, LSPARSE,
			     &xblk, &invp, &rowblks, &begblk, &first, &penv, &diag);

    // invoke setSize() on the Solver
    EigenSolver *theSolvr = this->getSolver();
    int solverOK = theSolvr->setSize();
    if (solverOK < 0) {
	opserr << "WARNING:BandArpackSOE::setSize :";
	opserr << " solver failed setSize()\n";
	return solverOK;
    } 


    return result;
}