761 lines
16 KiB
C++
761 lines
16 KiB
C++
//+-------------------------------------------------------------------------
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//
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// Microsoft Windows
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//
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// Copyright (C) Microsoft Corporation, 1997 - 1997
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//
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// File: vrmatrx.cpp
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//
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//--------------------------------------------------------------------------
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#include <float.h>
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#include <math.h>
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#include <bitset>
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#include "vrmatrx.h"
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VRMATRIX VRMATRIX :: VrmatrixProject ( const VIMD & vimdRowColumnRetain ) const
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{
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// Returns the projection of this matrix defined by the rows and columns
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// in vimdRowColumnRetain.
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#define BSETSIZE 100
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size_t cDimMax = _cpp_max(CCol(),CRow());
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assert( cDimMax < BSETSIZE );
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// Build a bitset that keeps track of the rows and columns we're retaining
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bitset<BSETSIZE> bset;
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for ( int iRowCol = 0; iRowCol < vimdRowColumnRetain.size(); ++iRowCol)
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{
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bset[ vimdRowColumnRetain[iRowCol] ] = true;
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}
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int cCol = 0;
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int cRow = 0;
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for ( iRowCol = 0; iRowCol < cDimMax; iRowCol++ )
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{
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bool bKeep = bset[iRowCol];
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if ( cDimMax >= CCol() && bKeep )
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cCol++;
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if ( cDimMax >= CRow() && bKeep )
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cRow++;
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}
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// Make sure that a least one row and column are being retained
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if ( cCol == 0 || cRow == 0 )
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throw GMException(EC_MDVECT_MISUSE,"null matrix projection");
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// Construct the projection matrix
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VRMATRIX vrmatrix(cRow,cCol);
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int iRowProjection = 0;
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// Step through every element in this matrix, and insert into the
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// projection if the element is to be retained
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for ( int iRow = 0; iRow < CRow(); ++iRow )
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{
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if ( ! bset[iRow] )
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{
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// This row is excluded from the projection
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continue;
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}
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int iColProjection = 0;
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// This row is included... insert the members
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// of the row for every column in the projection
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for (int iCol = 0; iCol < CCol(); ++iCol )
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{
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if ( bset[iCol] )
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{
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vrmatrix(iRowProjection, iColProjection) = self(iRow,iCol);
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++iColProjection;
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}
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}
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++iRowProjection;
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}
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return vrmatrix;
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}
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VRMATRIXSQ VRMATRIXSQ :: VrmatrixProject ( const VIMD & vimdRowColumnRetain ) const
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{
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// Returns the projection of this matrix defined by the rows and columns
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// in vimdRowColumnRetain.
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#define BSETSIZE 100
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size_t cDimMax = _cpp_max(CCol(),CRow());
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assert( cDimMax < BSETSIZE );
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// Build a bitset that keeps track of the rows and columns we're retaining
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bitset<BSETSIZE> bset;
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for ( int iRowCol = 0; iRowCol < vimdRowColumnRetain.size(); ++iRowCol)
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{
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bset[ vimdRowColumnRetain[iRowCol] ] = true;
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}
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int cCol = 0;
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int cRow = 0;
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for ( iRowCol = 0; iRowCol < cDimMax; iRowCol++ )
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{
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bool bKeep = bset[iRowCol];
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if ( cDimMax >= CCol() && bKeep )
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cCol++;
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if ( cDimMax >= CRow() && bKeep )
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cRow++;
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}
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VRMATRIXSQ vrmatrix;
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// Make sure that a least one row and column are being retained
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if ( cCol > 0 && cRow > 0 )
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{
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// Initialize the projection matrix
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vrmatrix.Init(cRow,cCol);
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int iRowProjection = 0;
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// Step through every element in this matrix, and insert into the
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// projection if the element is to be retained
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for ( int iRow = 0; iRow < CRow(); ++iRow )
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{
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if ( ! bset[iRow] )
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{
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// This row is excluded from the projection
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continue;
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}
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int iColProjection = 0;
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// This row is included... insert the members
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// of the row for every column in the projection
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for (int iCol = 0; iCol < CCol(); ++iCol )
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{
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if ( bset[iCol] )
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{
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vrmatrix(iRowProjection, iColProjection) = self(iRow,iCol);
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++iColProjection;
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}
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}
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++iRowProjection;
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}
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}
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else
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{
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vrmatrix.Init(0,0);
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}
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return vrmatrix;
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}
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VLREAL VRMATRIX :: VectorRow ( int iRow ) const
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{
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// Return a copy of the iRow'th row vector of the matrix
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if ( iRow >= CRow() )
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throw GMException(EC_MDVECT_MISUSE,"invalid matrix projection");
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VLREAL vectorRowReturn;
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int cCol = CCol();
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vectorRowReturn.resize(cCol);
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const REAL* rgrealRowMatrix = & self(iRow,0);
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for ( int iCol = 0; iCol < cCol; cCol++ )
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{
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vectorRowReturn[iCol] = rgrealRowMatrix[iCol];
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}
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// *prv++ = *prm++;
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return vectorRowReturn;
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}
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VLREAL VRMATRIX :: VectorColumn ( int iCol ) const
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{
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// Return a copy of the iCol'th column vector of the matrix
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if ( iCol >= CCol() )
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throw GMException(EC_MDVECT_MISUSE,"invalid matrix projection");
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VLREAL vectorColReturn;
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int cRow = CRow();
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vectorColReturn.resize(cRow);
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const REAL* rgrealColMatrix = & self(0, iCol);
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for ( int iRow = 0; iRow < cRow; iRow++ )
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{
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vectorColReturn[iRow] = rgrealColMatrix[iRow];
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}
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return vectorColReturn;
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}
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VRMATRIX VRMATRIX :: VrmatrixTranspose () const
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{
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// Return the transpose of this matrix
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VRMATRIX vrmatrixTranspose( CCol(), CRow() );
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for ( int iRow = 0 ; iRow < CRow() ; iRow++ )
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{
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for ( int iCol = 0; iCol < CCol(); iCol++ )
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{
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vrmatrixTranspose(iCol,iRow) = self(iRow,iCol);
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}
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}
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return vrmatrixTranspose;
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}
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VRMATRIX VRMATRIX::operator * ( const VRMATRIX & matrix ) const
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{
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if ( ! BCanMultiply( matrix ) )
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throw GMException(EC_MDVECT_MISUSE,"invalid matrix multiplication");
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// Result matrix
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VRMATRIX mat( CRow(), matrix.CCol() );
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// Compute distance in flat array between adjacent
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// column items in secondary
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int icolInc = matrix.second.stride()[0];
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const REAL * prrow = & self(0,0);
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REAL * prmat = & mat(0,0);
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for (int irow = 0; irow < CRow(); irow++)
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{
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const REAL * prrowt;
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for ( int icol = 0; icol < matrix.CCol(); icol++ )
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{
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prrowt = prrow;
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assert( prrowt == & self(irow,0) );
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// First column element in "matrix"
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const REAL * prcol = & matrix(0,icol);
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// Compute the new element
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REAL r = 0.0;
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for (int i = 0; i < CCol(); i++)
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{
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assert( prcol == & matrix(i,icol) );
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r += *prcol * *prrowt++;
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prcol += icolInc;
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}
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// Store it
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*prmat++ = r;
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}
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prrow = prrowt;
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}
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return mat;
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}
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VRMATRIX & VRMATRIX::operator += ( const VRMATRIX & vrmatrixAdd )
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{
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// Add vrmatrixAdd to this matrix
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// Make sure the matrices are of the same dimension
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if (! BSameDimension(vrmatrixAdd) )
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throw GMException(EC_MDVECT_MISUSE,"inapplicable matrix operator");
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// Perform a flat add between all the elements in the matricies
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int crealTotal = second._Totlen();
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REAL* rgrealSelf = &self(0,0);
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const REAL* rgrealMatrixAdd = &vrmatrixAdd(0,0);
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for ( int ireal = 0 ; ireal < crealTotal ; ireal++ )
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{
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rgrealSelf[ireal] += rgrealMatrixAdd[ireal];
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}
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return self;
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}
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VRMATRIX & VRMATRIX::operator -= ( const VRMATRIX & vrmatrixMatrixSubtract )
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{
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// Subtract vrmatrixAdd from this matrix
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// Make sure the matrices are of the same dimension
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if ( ! BSameDimension( vrmatrixMatrixSubtract ) )
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throw GMException(EC_MDVECT_MISUSE,"inapplicable matrix operator");
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// Perform a flat subtration between all the elements in the matricies
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int crealTotal = second._Totlen();
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REAL* rgrealSelf = &self(0,0);
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const REAL* rgrealMatrixSubtract = &vrmatrixMatrixSubtract(0,0);
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for ( int ireal = 0 ; ireal < crealTotal ; ireal++ )
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{
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rgrealSelf[ireal] -= rgrealMatrixSubtract[ireal];
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}
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return self;
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}
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VRMATRIX & VRMATRIX::operator *= ( REAL rScalar )
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{
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// Multiply each element in the matrix by rScalar
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int crealTotal = second._Totlen();
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REAL* rgrealSelf = &self(0,0);
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for ( int ireal = 0 ; ireal < crealTotal ; ireal++ )
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{
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rgrealSelf[ireal] *= rScalar;
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}
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return self;
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}
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VRMATRIX & VRMATRIX::operator += ( REAL rScalar )
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{
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// Add rScalar to each element in the matrix
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int crealTotal = second._Totlen();
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REAL* rgrealSelf = &self(0,0);
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for ( int ireal = 0 ; ireal < crealTotal ; ireal++ )
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{
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rgrealSelf[ireal] += rScalar;
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}
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return self;
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}
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VRMATRIX & VRMATRIX::operator -= ( REAL rScalar )
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{
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// Subtract rScalar from each element in the matrix
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int crealTotal = second._Totlen();
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REAL* rgrealSelf = &self(0,0);
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for ( int ireal = 0 ; ireal < crealTotal ; ireal++ )
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{
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rgrealSelf[ireal] -= rScalar;
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}
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return self;
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}
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VRMATRIX & VRMATRIX::operator /= ( REAL rScalar )
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{
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// Divide each element in the matrix by rScalar
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int crealTotal = second._Totlen();
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REAL* rgrealSelf = &self(0,0);
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for ( int ireal = 0 ; ireal < crealTotal ; ireal++ )
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{
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rgrealSelf[ireal] /= rScalar;
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}
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return self;
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}
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VRMATRIXSQ :: VRMATRIXSQ ( const VLREAL & vrColumn, const VLREAL & vrRow )
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{
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// Constructor for square matrices that takes a column and row vector.
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// The initial state of this matrix is the product of the input
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// vectors.
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// Make sure the vectors are of the same length
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if ( vrColumn.size() != vrRow.size() )
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throw GMException(EC_MDVECT_MISUSE,"invalid matrix multiplication");
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Init( vrColumn.size() );
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REAL * prm = & self(0,0);
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for ( int iRow = 0; iRow < CRow(); iRow++ )
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{
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for ( int iCol = 0; iCol < CCol(); iCol++ )
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{
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*prm++ = vrColumn[iCol] * vrRow[iRow];
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}
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}
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}
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VRMATRIXSQ & VRMATRIXSQ::operator *= (const VRMATRIXSQ& matrix)
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{
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if ( matrix.CRow() != CRow()
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|| matrix.CCol() != CRow() )
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throw GMException(EC_MDVECT_MISUSE,"invalid matrix multiplication");
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// Temporary row for partial result
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VLREAL vrrow;
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vrrow.resize(CCol());
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// Compute distance in flat array between rows
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int icolInc = matrix.second.stride()[0];
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REAL * prrow = & self(0,0);
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const REAL * prmat = & matrix(0,0);
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REAL * prtemp0 = & vrrow[0];
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for (int irow = 0; irow < CRow(); irow++)
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{
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REAL * prtemp = prtemp0;
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for ( int icol = 0; icol < matrix.CCol(); icol++ )
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{
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const REAL * prrowt = prrow;
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assert( prrowt == & self(irow,0) );
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// First column element in "matrix"
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const REAL * prcol = & matrix(0,icol);
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// Compute the new element
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REAL r = 0.0;
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for (int i = 0; i < CCol(); i++)
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{
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assert( prcol == & matrix(i,icol) );
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r += *prcol * *prrowt++;
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prcol += icolInc;
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}
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// Store it temporary row vector
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*prtemp++ = r;
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}
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// Update row in self
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prtemp = prtemp0;
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for ( int icol2 = 0; icol2 < CCol(); icol2++ )
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{
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*prrow++ = *prtemp++;
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}
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}
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return self;
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}
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void VRMATRIXSQ::LUDBackSub (const VRMATRIXSQ& matrix)
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{
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if ( ! matrix.BIsLUDecomposed() )
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throw GMException(EC_MDVECT_MISUSE,"matrix not in L-U decomposed form");
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for (int icol = 0; icol < CCol(); icol++)
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{
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int irowNZ = -1;
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for (int irow = 0; irow < CRow(); irow++)
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{
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int irowMax = matrix._vimdRow[irow];
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REAL probSum = self(irowMax,icol);
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self(irowMax,icol) = self(irow,icol);
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if (irowNZ != -1)
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{
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for (int iMul = irowNZ; iMul < irow; iMul++)
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probSum -= matrix(irow,iMul) * self(iMul,icol);
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}
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else if (probSum != 0.0)
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irowNZ = irow;
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self(irow,icol) = probSum;
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}
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for ( irow = CRow(); irow-- > 0; )
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{
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REAL probSum = self(irow,icol);
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for (int iMul = irow + 1; iMul < CRow(); iMul++)
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probSum -= matrix(irow,iMul) * self(iMul,icol);
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self(irow,icol) = probSum / matrix(irow,irow);
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}
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}
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}
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void VRMATRIXSQ::LUDecompose( bool bUseTinyIfSingular )
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{
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// Perform L-U decomposition; throw exception if singular
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// If "use tiny" is set, pivots at zero are replaced with
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// RTINY value (1.0e-20)
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// Check that this matrix is not already LU decomposed
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if ( BIsLUDecomposed() )
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throw GMException(EC_MDVECT_MISUSE,"matrix is already in L-U decomposed form");
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if (CRow() == 0)
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return; // trivial case
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int cDim = CRow();
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_vimdRow.resize(cDim);
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VLREAL vlrealOverMax;
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vlrealOverMax.resize(cDim);
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_iSign = 1;
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for (int iRow = 0; iRow < cDim; iRow++)
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{
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REAL realMax = 0.0;
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for (int iCol = 0; iCol < cDim; iCol++)
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{
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REAL realAbs = fabs(self(iRow,iCol));
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if (realAbs > realMax)
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realMax = realAbs;
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}
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if (realMax == 0.0)
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{
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// Every element in the row is zero: this is a singular matrix
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throw GMException(EC_MDVECT_MISUSE,"matrix is singular");
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}
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vlrealOverMax[iRow] = 1.0 / realMax;
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}
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for (int iCol = 0; iCol < cDim; iCol++)
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{
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for (int iRow = 0; iRow < iCol; iRow++)
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{
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REAL realSum = self(iRow,iCol);
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for (int iMul = 0; iMul < iRow; iMul++)
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realSum -= self(iRow,iMul) * self(iMul,iCol);
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self(iRow,iCol) = realSum;
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}
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REAL realMax = 0.0;
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int iRowMax = 0;
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for ( iRow = iCol; iRow < cDim; iRow++)
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{
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REAL realSum = self(iRow,iCol);
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for (int iMul = 0; iMul < iCol; iMul++)
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realSum -= self(iRow,iMul) * self(iMul,iCol);
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self(iRow,iCol) = realSum;
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REAL realAbs = vlrealOverMax[iRow] * fabs(realSum);
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if (realAbs >= realMax)
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{
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realMax = realAbs;
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iRowMax = iRow;
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}
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}
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if (iRowMax != iCol)
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{
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// we need to interchange rows
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|
_iSign *= -1;
|
|
vlrealOverMax[iRowMax] = vlrealOverMax[iCol];
|
|
InterchangeRows(iRowMax,iCol);
|
|
}
|
|
|
|
_vimdRow[iCol] = iRowMax;
|
|
|
|
REAL & rPivot = self(iCol,iCol);
|
|
|
|
if ( rPivot == 0.0 )
|
|
{
|
|
if ( ! bUseTinyIfSingular )
|
|
{
|
|
// This is a singular matrix: throw exceptioin
|
|
throw GMException(EC_MDVECT_MISUSE,"matrix is singular");
|
|
}
|
|
|
|
rPivot = RTINY;
|
|
}
|
|
|
|
REAL rScale = 1.0 / rPivot;
|
|
|
|
for ( iRow = iCol + 1; iRow < cDim; iRow++)
|
|
self(iRow,iCol) *= rScale;
|
|
}
|
|
}
|
|
|
|
void VRMATRIXSQ::Invert( bool bUseTinyIfSingular )
|
|
{
|
|
// Invert; throw exception if singular. If not in L-U form,
|
|
// L-U Decomp is called.
|
|
|
|
if ( ! BIsLUDecomposed() )
|
|
{
|
|
LUDecompose( bUseTinyIfSingular );
|
|
}
|
|
|
|
VRMATRIXSQ matrixOne(CRow());
|
|
|
|
// Create the identity matrix
|
|
|
|
for (int iDim1 = 0; iDim1 < CRow(); iDim1++)
|
|
{
|
|
for (int iDim2 = 0; iDim2 < CRow(); iDim2++)
|
|
matrixOne(iDim1, iDim2) = iDim1 == iDim2 ? 1.0 : 0.0;
|
|
}
|
|
|
|
matrixOne.LUDBackSub(self);
|
|
|
|
for ( iDim1 = 0; iDim1 < CRow(); iDim1++)
|
|
{
|
|
for (int iDim2 = 0; iDim2 < CRow(); iDim2++)
|
|
self(iDim1, iDim2) = matrixOne(iDim1, iDim2);
|
|
}
|
|
|
|
// Clear l-u decomp values
|
|
_vimdRow.resize(0);
|
|
}
|
|
|
|
DBL VRMATRIXSQ::DblDeterminant()
|
|
{
|
|
DBL dblDet = _iSign;
|
|
|
|
if ( CRow() > 0 && ! BIsLUDecomposed() )
|
|
LUDecompose();
|
|
|
|
// Once the matrix has been LU decomposed, the determinant can be
|
|
// obtained by simply multiplying the elements of the diagonal
|
|
|
|
for (int iRow = 0; iRow < CRow(); iRow++)
|
|
{
|
|
dblDet *= self(iRow,iRow);
|
|
}
|
|
|
|
return dblDet;
|
|
}
|
|
|
|
DBL VRMATRIXSQ :: DblAddLogDiagonal() const
|
|
// Adds the log of each element in the diagonal and returns the sum.
|
|
{
|
|
DBL dblLogDiag = 0;
|
|
// bool bPositive = _iSign == 1;
|
|
bool bPositive = 1;
|
|
|
|
for (int iRow = 0; iRow < CRow(); iRow++)
|
|
{
|
|
if (self(iRow,iRow) < 0)
|
|
bPositive = !bPositive;
|
|
|
|
// Assert that the element is not zero. We should probably
|
|
// throw an exception here instead.
|
|
|
|
assert(self(iRow,iRow) != 0);
|
|
|
|
dblLogDiag += log (fabs(self(iRow,iRow)));
|
|
}
|
|
|
|
if (!bPositive)
|
|
{
|
|
// Got a negative determinant, so we can't take the log... throw
|
|
// an exception
|
|
|
|
return false;
|
|
}
|
|
|
|
return dblLogDiag;
|
|
}
|
|
|
|
|
|
DBL VRMATRIXSQ :: DblLogDeterminant()
|
|
{
|
|
// Return the log of the determinant. If not in L-U form,
|
|
// L-U Decomp is called. Throws exception if negative.
|
|
|
|
if ( CRow() > 0 && ! BIsLUDecomposed() )
|
|
LUDecompose();
|
|
|
|
DBL dblLogDet = 0;
|
|
bool bPositive = _iSign == 1;
|
|
|
|
for (int iRow = 0; iRow < CRow(); iRow++)
|
|
{
|
|
if (self(iRow,iRow) < 0)
|
|
bPositive = !bPositive;
|
|
|
|
// Assert that the deterninant is not zero. We should probably
|
|
// throw an exception here instead.
|
|
|
|
assert(self(iRow,iRow) != 0);
|
|
|
|
dblLogDet += log (fabs(self(iRow,iRow)));
|
|
}
|
|
|
|
if (!bPositive)
|
|
{
|
|
// Got a negative determinant, so we can't take the log... throw
|
|
// an exception
|
|
|
|
return false;
|
|
}
|
|
|
|
return dblLogDet;
|
|
}
|
|
|
|
void VRMATRIXSQ :: GetLUDecompose( VRMATRIXSQ & vmatrixResult, bool bUseTinyIfSingular ) const
|
|
{
|
|
// Set vrmatResult to be the result of performing an L-U
|
|
// decomposition on the matrix. Will throw exception if
|
|
// the matrix is singular
|
|
// If "use tiny" is set, pivots at zero are replaced with
|
|
// RTINY value (1.0e-20)
|
|
|
|
// Copy this matrix into vmatrixResult...
|
|
vmatrixResult = self;
|
|
|
|
// .. and perform the decomposition
|
|
vmatrixResult.LUDecompose( bUseTinyIfSingular );
|
|
}
|
|
|
|
void VRMATRIXSQ :: GetInverse( VRMATRIXSQ & vmatrixResult, bool bUseTinyIfSingular ) const
|
|
{
|
|
// Set vrmatResult to the inverse of the matrix.
|
|
// Will throw an exception if the matrix is singular.
|
|
|
|
// Copy this matrix into vmatrixResult...
|
|
vmatrixResult = self;
|
|
|
|
/// ...and invert
|
|
vmatrixResult.Invert( bUseTinyIfSingular );
|
|
}
|
|
|
|
void VRMATRIXSQ :: GetDblDeterminant( DBL& dblDeterminant, VRMATRIXSQ & vmatrixResult ) const
|
|
{
|
|
// Get the determinant without modifying (LU decomposing) the matrix.
|
|
// vmatrixResult will contain the LU decomposed version of the matrix.
|
|
|
|
// Copy this matrix into vmatrixResult...
|
|
vmatrixResult = self;
|
|
dblDeterminant = vmatrixResult.DblDeterminant();
|
|
}
|
|
|
|
void VRMATRIXSQ :: GetDblLogDeterminant( DBL& dblLogDeterminant, VRMATRIXSQ & vmatrixResult ) const
|
|
{
|
|
// Get the log of determinant without modifying (LU decomposing) the matrix.
|
|
// vmatrixResult will contain the LU decomposed version of the matrix.
|
|
|
|
vmatrixResult = self;
|
|
dblLogDeterminant = vmatrixResult.DblLogDeterminant();
|
|
}
|