570 lines
16 KiB
C++
570 lines
16 KiB
C++
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//$$ bandmat.cpp Band matrix definitions
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// Copyright (C) 1991,2,3,4,9: R B Davies
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#define WANT_MATH // include.h will get math fns
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//#define WANT_STREAM
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#include "include.h"
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#include "newmat.h"
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#include "newmatrc.h"
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#ifdef use_namespace
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namespace NEWMAT {
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#endif
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#ifdef DO_REPORT
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#define REPORT { static ExeCounter ExeCount(__LINE__,10); ++ExeCount; }
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#else
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#define REPORT {}
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#endif
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static inline int my_min(int x, int y) { return x < y ? x : y; }
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static inline int my_max(int x, int y) { return x > y ? x : y; }
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BandMatrix::BandMatrix(const BaseMatrix& M)
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{
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REPORT // CheckConversion(M);
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// MatrixConversionCheck mcc;
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GeneralMatrix* gmx=((BaseMatrix&)M).Evaluate(MatrixType::BM);
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GetMatrix(gmx); CornerClear();
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}
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void BandMatrix::SetParameters(const GeneralMatrix* gmx)
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{
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REPORT
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MatrixBandWidth bw = gmx->BandWidth();
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lower = bw.lower; upper = bw.upper;
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}
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void BandMatrix::ReSize(int n, int lb, int ub)
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{
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REPORT
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Tracer tr("BandMatrix::ReSize");
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if (lb<0 || ub<0) Throw(ProgramException("Undefined bandwidth"));
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lower = (lb<=n) ? lb : n-1; upper = (ub<=n) ? ub : n-1;
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GeneralMatrix::ReSize(n,n,n*(lower+1+upper)); CornerClear();
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}
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// SimpleAddOK shows when we can add etc two matrices by a simple vector add
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// and when we can add one matrix into another
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// *gm must be the same type as *this
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// return 0 if simple add is OK
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// return 1 if we can add into *gm only
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// return 2 if we can add into *this only
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// return 3 if we can't add either way
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// For SP this will still be valid if we swap 1 and 2
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short BandMatrix::SimpleAddOK(const GeneralMatrix* gm)
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{
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const BandMatrix* bm = (const BandMatrix*)gm;
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if (bm->lower == lower && bm->upper == upper) { REPORT return 0; }
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else if (bm->lower >= lower && bm->upper >= upper) { REPORT return 1; }
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else if (bm->lower <= lower && bm->upper <= upper) { REPORT return 2; }
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else { REPORT return 3; }
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}
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short SymmetricBandMatrix::SimpleAddOK(const GeneralMatrix* gm)
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{
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const SymmetricBandMatrix* bm = (const SymmetricBandMatrix*)gm;
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if (bm->lower == lower) { REPORT return 0; }
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else if (bm->lower > lower) { REPORT return 1; }
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else { REPORT return 2; }
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}
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void UpperBandMatrix::ReSize(int n, int lb, int ub)
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{
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REPORT
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if (lb != 0)
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{
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Tracer tr("UpperBandMatrix::ReSize");
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Throw(ProgramException("UpperBandMatrix with non-zero lower band" ));
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}
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BandMatrix::ReSize(n, lb, ub);
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}
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void LowerBandMatrix::ReSize(int n, int lb, int ub)
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{
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REPORT
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if (ub != 0)
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{
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Tracer tr("LowerBandMatrix::ReSize");
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Throw(ProgramException("LowerBandMatrix with non-zero upper band" ));
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}
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BandMatrix::ReSize(n, lb, ub);
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}
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void BandMatrix::ReSize(const GeneralMatrix& A)
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{
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REPORT
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int n = A.Nrows();
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if (n != A.Ncols())
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{
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Tracer tr("BandMatrix::ReSize(GM)");
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Throw(NotSquareException(*this));
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}
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MatrixBandWidth mbw = A.BandWidth();
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ReSize(n, mbw.Lower(), mbw.Upper());
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}
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bool BandMatrix::SameStorageType(const GeneralMatrix& A) const
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{
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if (Type() != A.Type()) { REPORT return false; }
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REPORT
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return BandWidth() == A.BandWidth();
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}
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void BandMatrix::ReSizeForAdd(const GeneralMatrix& A, const GeneralMatrix& B)
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{
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REPORT
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Tracer tr("BandMatrix::ReSizeForAdd");
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MatrixBandWidth A_BW = A.BandWidth(); MatrixBandWidth B_BW = B.BandWidth();
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if ((A_BW.Lower() < 0) | (A_BW.Upper() < 0) | (B_BW.Lower() < 0)
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| (A_BW.Upper() < 0))
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Throw(ProgramException("Can't ReSize to BandMatrix" ));
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// already know A and B are square
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ReSize(A.Nrows(), my_max(A_BW.Lower(), B_BW.Lower()),
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my_max(A_BW.Upper(), B_BW.Upper()));
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}
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void BandMatrix::ReSizeForSP(const GeneralMatrix& A, const GeneralMatrix& B)
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{
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REPORT
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Tracer tr("BandMatrix::ReSizeForSP");
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MatrixBandWidth A_BW = A.BandWidth(); MatrixBandWidth B_BW = B.BandWidth();
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if ((A_BW.Lower() < 0) | (A_BW.Upper() < 0) | (B_BW.Lower() < 0)
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| (A_BW.Upper() < 0))
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Throw(ProgramException("Can't ReSize to BandMatrix" ));
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// already know A and B are square
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ReSize(A.Nrows(), my_min(A_BW.Lower(), B_BW.Lower()),
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my_min(A_BW.Upper(), B_BW.Upper()));
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}
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void BandMatrix::operator=(const BaseMatrix& X)
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{
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REPORT // CheckConversion(X);
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// MatrixConversionCheck mcc;
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Eq(X,MatrixType::BM); CornerClear();
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}
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void BandMatrix::CornerClear() const
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{
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// set unused parts of BandMatrix to zero
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REPORT
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int i = lower; Real* s = store; int bw = lower + 1 + upper;
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while (i)
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{ int j = i--; Real* sj = s; s += bw; while (j--) *sj++ = 0.0; }
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i = upper; s = store + storage;
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while (i)
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{ int j = i--; Real* sj = s; s -= bw; while (j--) *(--sj) = 0.0; }
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}
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MatrixBandWidth MatrixBandWidth::operator+(const MatrixBandWidth& bw) const
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{
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REPORT
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int l = bw.lower; int u = bw.upper;
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l = (lower < 0 || l < 0) ? -1 : (lower > l) ? lower : l;
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u = (upper < 0 || u < 0) ? -1 : (upper > u) ? upper : u;
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return MatrixBandWidth(l,u);
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}
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MatrixBandWidth MatrixBandWidth::operator*(const MatrixBandWidth& bw) const
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{
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REPORT
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int l = bw.lower; int u = bw.upper;
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l = (lower < 0 || l < 0) ? -1 : lower+l;
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u = (upper < 0 || u < 0) ? -1 : upper+u;
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return MatrixBandWidth(l,u);
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}
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MatrixBandWidth MatrixBandWidth::minimum(const MatrixBandWidth& bw) const
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{
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REPORT
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int l = bw.lower; int u = bw.upper;
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if ((lower >= 0) && ( (l < 0) || (l > lower) )) l = lower;
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if ((upper >= 0) && ( (u < 0) || (u > upper) )) u = upper;
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return MatrixBandWidth(l,u);
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}
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UpperBandMatrix::UpperBandMatrix(const BaseMatrix& M)
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{
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REPORT // CheckConversion(M);
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// MatrixConversionCheck mcc;
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GeneralMatrix* gmx=((BaseMatrix&)M).Evaluate(MatrixType::UB);
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GetMatrix(gmx); CornerClear();
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}
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void UpperBandMatrix::operator=(const BaseMatrix& X)
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{
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REPORT // CheckConversion(X);
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// MatrixConversionCheck mcc;
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Eq(X,MatrixType::UB); CornerClear();
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}
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LowerBandMatrix::LowerBandMatrix(const BaseMatrix& M)
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{
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REPORT // CheckConversion(M);
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// MatrixConversionCheck mcc;
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GeneralMatrix* gmx=((BaseMatrix&)M).Evaluate(MatrixType::LB);
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GetMatrix(gmx); CornerClear();
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}
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void LowerBandMatrix::operator=(const BaseMatrix& X)
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{
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REPORT // CheckConversion(X);
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// MatrixConversionCheck mcc;
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Eq(X,MatrixType::LB); CornerClear();
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}
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BandLUMatrix::BandLUMatrix(const BaseMatrix& m)
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{
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REPORT
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Tracer tr("BandLUMatrix");
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storage2 = 0; store2 = 0; // in event of exception during build
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GeneralMatrix* gm = ((BaseMatrix&)m).Evaluate(MatrixType::BM);
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m1 = ((BandMatrix*)gm)->lower; m2 = ((BandMatrix*)gm)->upper;
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GetMatrix(gm);
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if (nrows!=ncols) Throw(NotSquareException(*this));
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d = true; sing = false;
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indx = new int [nrows]; MatrixErrorNoSpace(indx);
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MONITOR_INT_NEW("Index (BndLUMat)",nrows,indx)
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storage2 = nrows * m1;
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store2 = new Real [storage2]; MatrixErrorNoSpace(store2);
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MONITOR_REAL_NEW("Make (BandLUMat)",storage2,store2)
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ludcmp();
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}
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BandLUMatrix::~BandLUMatrix()
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{
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REPORT
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MONITOR_INT_DELETE("Index (BndLUMat)",nrows,indx)
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MONITOR_REAL_DELETE("Delete (BndLUMt)",storage2,store2)
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delete [] indx; delete [] store2;
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}
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MatrixType BandLUMatrix::Type() const { REPORT return MatrixType::BC; }
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LogAndSign BandLUMatrix::LogDeterminant() const
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{
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REPORT
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if (sing) return 0.0;
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Real* a = store; int w = m1+1+m2; LogAndSign sum; int i = nrows;
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// while (i--) { sum *= *a; a += w; }
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if (i) for (;;) { sum *= *a; if (!(--i)) break; a += w; }
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if (!d) sum.ChangeSign(); return sum;
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}
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GeneralMatrix* BandMatrix::MakeSolver()
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{
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REPORT
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GeneralMatrix* gm = new BandLUMatrix(*this);
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MatrixErrorNoSpace(gm); gm->ReleaseAndDelete(); return gm;
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}
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void BandLUMatrix::ludcmp()
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{
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REPORT
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Real* a = store2; int i = storage2;
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// clear store2 - so unused locations are always zero -
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// required by operator==
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while (i--) *a++ = 0.0;
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a = store;
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i = m1; int j = m2; int k; int n = nrows; int w = m1 + 1 + m2;
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while (i)
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{
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Real* ai = a + i;
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k = ++j; while (k--) *a++ = *ai++;
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k = i--; while (k--) *a++ = 0.0;
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}
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a = store; int l = m1;
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for (k=0; k<n; k++)
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{
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Real x = *a; i = k; Real* aj = a;
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if (l < n) l++;
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for (j=k+1; j<l; j++)
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{ aj += w; if (fabs(x) < fabs(*aj)) { x = *aj; i = j; } }
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indx[k] = i;
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if (x==0) { sing = true; return; }
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if (i!=k)
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{
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d = !d; Real* ak = a; Real* ai = store + i * w; j = w;
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while (j--) { x = *ak; *ak++ = *ai; *ai++ = x; }
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}
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aj = a + w; Real* m = store2 + m1 * k;
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for (j=k+1; j<l; j++)
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{
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*m++ = x = *aj / *a; i = w; Real* ak = a;
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while (--i) { Real* aj1 = aj++; *aj1 = *aj - x * *(++ak); }
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*aj++ = 0.0;
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}
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a += w;
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}
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}
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void BandLUMatrix::lubksb(Real* B, int mini)
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{
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REPORT
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Tracer tr("BandLUMatrix::lubksb");
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if (sing) Throw(SingularException(*this));
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int n = nrows; int l = m1; int w = m1 + 1 + m2;
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for (int k=0; k<n; k++)
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{
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int i = indx[k];
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if (i!=k) { Real x=B[k]; B[k]=B[i]; B[i]=x; }
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if (l<n) l++;
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Real* m = store2 + k*m1; Real* b = B+k; Real* bi = b;
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for (i=k+1; i<l; i++) *(++bi) -= *m++ * *b;
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}
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l = -m1;
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for (int i = n-1; i>=mini; i--)
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{
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Real* b = B + i; Real* bk = b; Real x = *bk;
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Real* a = store + w*i; Real y = *a;
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int k = l+m1; while (k--) x -= *(++a) * *(++bk);
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*b = x / y;
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if (l < m2) l++;
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}
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}
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void BandLUMatrix::Solver(MatrixColX& mcout, const MatrixColX& mcin)
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{
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REPORT
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int i = mcin.skip; Real* el = mcin.data-i; Real* el1=el;
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while (i--) *el++ = 0.0;
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el += mcin.storage; i = nrows - mcin.skip - mcin.storage;
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while (i--) *el++ = 0.0;
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lubksb(el1, mcout.skip);
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}
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// Do we need check for entirely zero output?
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void UpperBandMatrix::Solver(MatrixColX& mcout,
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const MatrixColX& mcin)
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{
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REPORT
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int i = mcin.skip-mcout.skip; Real* elx = mcin.data-i;
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while (i-- > 0) *elx++ = 0.0;
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int nr = mcin.skip+mcin.storage;
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elx = mcin.data+mcin.storage; Real* el = elx;
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int j = mcout.skip+mcout.storage-nr; i = nr-mcout.skip;
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while (j-- > 0) *elx++ = 0.0;
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Real* Ael = store + (upper+1)*(i-1)+1; j = 0;
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if (i > 0) for(;;)
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{
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elx = el; Real sum = 0.0; int jx = j;
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while (jx--) sum += *(--Ael) * *(--elx);
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elx--; *elx = (*elx - sum) / *(--Ael);
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if (--i <= 0) break;
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if (j<upper) Ael -= upper - (++j); else el--;
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}
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}
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void LowerBandMatrix::Solver(MatrixColX& mcout,
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const MatrixColX& mcin)
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{
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REPORT
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int i = mcin.skip-mcout.skip; Real* elx = mcin.data-i;
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while (i-- > 0) *elx++ = 0.0;
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int nc = mcin.skip; i = nc+mcin.storage; elx = mcin.data+mcin.storage;
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int nr = mcout.skip+mcout.storage; int j = nr-i; i = nr-nc;
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while (j-- > 0) *elx++ = 0.0;
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Real* el = mcin.data; Real* Ael = store + (lower+1)*nc + lower; j = 0;
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if (i > 0) for(;;)
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{
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elx = el; Real sum = 0.0; int jx = j;
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while (jx--) sum += *Ael++ * *elx++;
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*elx = (*elx - sum) / *Ael++;
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if (--i <= 0) break;
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if (j<lower) Ael += lower - (++j); else el++;
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}
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}
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LogAndSign BandMatrix::LogDeterminant() const
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{
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REPORT
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BandLUMatrix C(*this); return C.LogDeterminant();
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}
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LogAndSign LowerBandMatrix::LogDeterminant() const
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{
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REPORT
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int i = nrows; LogAndSign sum; Real* s = store + lower; int j = lower + 1;
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// while (i--) { sum *= *s; s += j; }
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if (i) for (;;) { sum *= *s; if (!(--i)) break; s += j; }
|
||
|
((GeneralMatrix&)*this).tDelete(); return sum;
|
||
|
}
|
||
|
|
||
|
LogAndSign UpperBandMatrix::LogDeterminant() const
|
||
|
{
|
||
|
REPORT
|
||
|
int i = nrows; LogAndSign sum; Real* s = store; int j = upper + 1;
|
||
|
// while (i--) { sum *= *s; s += j; }
|
||
|
if (i) for (;;) { sum *= *s; if (!(--i)) break; s += j; }
|
||
|
((GeneralMatrix&)*this).tDelete(); return sum;
|
||
|
}
|
||
|
|
||
|
GeneralMatrix* SymmetricBandMatrix::MakeSolver()
|
||
|
{
|
||
|
REPORT
|
||
|
GeneralMatrix* gm = new BandLUMatrix(*this);
|
||
|
MatrixErrorNoSpace(gm); gm->ReleaseAndDelete(); return gm;
|
||
|
}
|
||
|
|
||
|
SymmetricBandMatrix::SymmetricBandMatrix(const BaseMatrix& M)
|
||
|
{
|
||
|
REPORT // CheckConversion(M);
|
||
|
// MatrixConversionCheck mcc;
|
||
|
GeneralMatrix* gmx=((BaseMatrix&)M).Evaluate(MatrixType::SB);
|
||
|
GetMatrix(gmx);
|
||
|
}
|
||
|
|
||
|
GeneralMatrix* SymmetricBandMatrix::Transpose(TransposedMatrix*, MatrixType mt)
|
||
|
{ REPORT return Evaluate(mt); }
|
||
|
|
||
|
LogAndSign SymmetricBandMatrix::LogDeterminant() const
|
||
|
{
|
||
|
REPORT
|
||
|
BandLUMatrix C(*this); return C.LogDeterminant();
|
||
|
}
|
||
|
|
||
|
void SymmetricBandMatrix::SetParameters(const GeneralMatrix* gmx)
|
||
|
{ REPORT lower = gmx->BandWidth().lower; }
|
||
|
|
||
|
void SymmetricBandMatrix::ReSize(int n, int lb)
|
||
|
{
|
||
|
REPORT
|
||
|
Tracer tr("SymmetricBandMatrix::ReSize");
|
||
|
if (lb<0) Throw(ProgramException("Undefined bandwidth"));
|
||
|
lower = (lb<=n) ? lb : n-1;
|
||
|
GeneralMatrix::ReSize(n,n,n*(lower+1));
|
||
|
}
|
||
|
|
||
|
void SymmetricBandMatrix::ReSize(const GeneralMatrix& A)
|
||
|
{
|
||
|
REPORT
|
||
|
int n = A.Nrows();
|
||
|
if (n != A.Ncols())
|
||
|
{
|
||
|
Tracer tr("SymmetricBandMatrix::ReSize(GM)");
|
||
|
Throw(NotSquareException(*this));
|
||
|
}
|
||
|
MatrixBandWidth mbw = A.BandWidth(); int b = mbw.Lower();
|
||
|
if (b != mbw.Upper())
|
||
|
{
|
||
|
Tracer tr("SymmetricBandMatrix::ReSize(GM)");
|
||
|
Throw(ProgramException("Upper and lower band-widths not equal"));
|
||
|
}
|
||
|
ReSize(n, b);
|
||
|
}
|
||
|
|
||
|
bool SymmetricBandMatrix::SameStorageType(const GeneralMatrix& A) const
|
||
|
{
|
||
|
if (Type() != A.Type()) { REPORT return false; }
|
||
|
REPORT
|
||
|
return BandWidth() == A.BandWidth();
|
||
|
}
|
||
|
|
||
|
void SymmetricBandMatrix::ReSizeForAdd(const GeneralMatrix& A,
|
||
|
const GeneralMatrix& B)
|
||
|
{
|
||
|
REPORT
|
||
|
Tracer tr("SymmetricBandMatrix::ReSizeForAdd");
|
||
|
MatrixBandWidth A_BW = A.BandWidth(); MatrixBandWidth B_BW = B.BandWidth();
|
||
|
if ((A_BW.Lower() < 0) | (B_BW.Lower() < 0))
|
||
|
Throw(ProgramException("Can't ReSize to SymmetricBandMatrix" ));
|
||
|
// already know A and B are square
|
||
|
ReSize(A.Nrows(), my_max(A_BW.Lower(), B_BW.Lower()));
|
||
|
}
|
||
|
|
||
|
void SymmetricBandMatrix::ReSizeForSP(const GeneralMatrix& A,
|
||
|
const GeneralMatrix& B)
|
||
|
{
|
||
|
REPORT
|
||
|
Tracer tr("SymmetricBandMatrix::ReSizeForSP");
|
||
|
MatrixBandWidth A_BW = A.BandWidth(); MatrixBandWidth B_BW = B.BandWidth();
|
||
|
if ((A_BW.Lower() < 0) | (B_BW.Lower() < 0))
|
||
|
Throw(ProgramException("Can't ReSize to SymmetricBandMatrix" ));
|
||
|
// already know A and B are square
|
||
|
ReSize(A.Nrows(), my_min(A_BW.Lower(), B_BW.Lower()));
|
||
|
}
|
||
|
|
||
|
|
||
|
void SymmetricBandMatrix::operator=(const BaseMatrix& X)
|
||
|
{
|
||
|
REPORT // CheckConversion(X);
|
||
|
// MatrixConversionCheck mcc;
|
||
|
Eq(X,MatrixType::SB);
|
||
|
}
|
||
|
|
||
|
void SymmetricBandMatrix::CornerClear() const
|
||
|
{
|
||
|
// set unused parts of BandMatrix to zero
|
||
|
REPORT
|
||
|
int i = lower; Real* s = store; int bw = lower + 1;
|
||
|
if (i) for(;;)
|
||
|
{
|
||
|
int j = i;
|
||
|
Real* sj = s;
|
||
|
while (j--) *sj++ = 0.0;
|
||
|
if (!(--i)) break;
|
||
|
s += bw;
|
||
|
}
|
||
|
}
|
||
|
|
||
|
MatrixBandWidth SymmetricBandMatrix::BandWidth() const
|
||
|
{ REPORT return MatrixBandWidth(lower,lower); }
|
||
|
|
||
|
inline Real square(Real x) { return x*x; }
|
||
|
|
||
|
|
||
|
Real SymmetricBandMatrix::SumSquare() const
|
||
|
{
|
||
|
REPORT
|
||
|
CornerClear();
|
||
|
Real sum1=0.0; Real sum2=0.0; Real* s=store; int i=nrows; int l=lower;
|
||
|
while (i--)
|
||
|
{ int j = l; while (j--) sum2 += square(*s++); sum1 += square(*s++); }
|
||
|
((GeneralMatrix&)*this).tDelete(); return sum1 + 2.0 * sum2;
|
||
|
}
|
||
|
|
||
|
Real SymmetricBandMatrix::SumAbsoluteValue() const
|
||
|
{
|
||
|
REPORT
|
||
|
CornerClear();
|
||
|
Real sum1=0.0; Real sum2=0.0; Real* s=store; int i=nrows; int l=lower;
|
||
|
while (i--)
|
||
|
{ int j = l; while (j--) sum2 += fabs(*s++); sum1 += fabs(*s++); }
|
||
|
((GeneralMatrix&)*this).tDelete(); return sum1 + 2.0 * sum2;
|
||
|
}
|
||
|
|
||
|
Real SymmetricBandMatrix::Sum() const
|
||
|
{
|
||
|
REPORT
|
||
|
CornerClear();
|
||
|
Real sum1=0.0; Real sum2=0.0; Real* s=store; int i=nrows; int l=lower;
|
||
|
while (i--)
|
||
|
{ int j = l; while (j--) sum2 += *s++; sum1 += *s++; }
|
||
|
((GeneralMatrix&)*this).tDelete(); return sum1 + 2.0 * sum2;
|
||
|
}
|
||
|
|
||
|
|
||
|
#ifdef use_namespace
|
||
|
}
|
||
|
#endif
|
||
|
|