/usr/include/octave-4.0.0/octave/sparse-dmsolve.cc is in liboctave-dev 4.0.0-3ubuntu9.
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Copyright (C) 2006-2015 David Bateman
This file is part of Octave.
Octave is free software; you can redistribute it and/or modify it
under the terms of the GNU General Public License as published by the
Free Software Foundation; either version 3 of the License, or (at your
option) any later version.
Octave is distributed in the hope that it will be useful, but WITHOUT
ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
for more details.
You should have received a copy of the GNU General Public License
along with Octave; see the file COPYING. If not, see
<http://www.gnu.org/licenses/>.
*/
#ifdef HAVE_CONFIG_H
#include <config.h>
#endif
#include <vector>
#include "MArray.h"
#include "MSparse.h"
#include "SparseQR.h"
#include "SparseCmplxQR.h"
#include "MatrixType.h"
#include "oct-sort.h"
#include "oct-locbuf.h"
#include "oct-inttypes.h"
template <class T>
static MSparse<T>
dmsolve_extract (const MSparse<T> &A, const octave_idx_type *Pinv,
const octave_idx_type *Q, octave_idx_type rst,
octave_idx_type rend, octave_idx_type cst,
octave_idx_type cend, octave_idx_type maxnz = -1,
bool lazy = false)
{
octave_idx_type nr = rend - rst;
octave_idx_type nc = cend - cst;
maxnz = (maxnz < 0 ? A.nnz () : maxnz);
octave_idx_type nz;
// Cast to uint64 to handle overflow in this multiplication
if (octave_uint64 (nr)*octave_uint64 (nc) < octave_uint64 (maxnz))
nz = nr*nc;
else
nz = maxnz;
MSparse<T> B (nr, nc, (nz < maxnz ? nz : maxnz));
// Some sparse functions can support lazy indexing (where elements
// in the row are in no particular order), even though octave in
// general can't. For those functions that can using it is a big
// win here in terms of speed.
if (lazy)
{
nz = 0;
for (octave_idx_type j = cst ; j < cend ; j++)
{
octave_idx_type qq = (Q ? Q[j] : j);
B.xcidx (j - cst) = nz;
for (octave_idx_type p = A.cidx (qq) ; p < A.cidx (qq+1) ; p++)
{
octave_quit ();
octave_idx_type r = (Pinv ? Pinv[A.ridx (p)] : A.ridx (p));
if (r >= rst && r < rend)
{
B.xdata (nz) = A.data (p);
B.xridx (nz++) = r - rst ;
}
}
}
B.xcidx (cend - cst) = nz ;
}
else
{
OCTAVE_LOCAL_BUFFER (T, X, rend - rst);
octave_sort<octave_idx_type> sort;
octave_idx_type *ri = B.xridx ();
nz = 0;
for (octave_idx_type j = cst ; j < cend ; j++)
{
octave_idx_type qq = (Q ? Q[j] : j);
B.xcidx (j - cst) = nz;
for (octave_idx_type p = A.cidx (qq) ; p < A.cidx (qq+1) ; p++)
{
octave_quit ();
octave_idx_type r = (Pinv ? Pinv[A.ridx (p)] : A.ridx (p));
if (r >= rst && r < rend)
{
X[r-rst] = A.data (p);
B.xridx (nz++) = r - rst ;
}
}
sort.sort (ri + B.xcidx (j - cst), nz - B.xcidx (j - cst));
for (octave_idx_type p = B.cidx (j - cst); p < nz; p++)
B.xdata (p) = X[B.xridx (p)];
}
B.xcidx (cend - cst) = nz ;
}
return B;
}
#if !defined (CXX_NEW_FRIEND_TEMPLATE_DECL)
static MSparse<double>
dmsolve_extract (const MSparse<double> &A, const octave_idx_type *Pinv,
const octave_idx_type *Q, octave_idx_type rst,
octave_idx_type rend, octave_idx_type cst,
octave_idx_type cend, octave_idx_type maxnz,
bool lazy);
static MSparse<Complex>
dmsolve_extract (const MSparse<Complex> &A, const octave_idx_type *Pinv,
const octave_idx_type *Q, octave_idx_type rst,
octave_idx_type rend, octave_idx_type cst,
octave_idx_type cend, octave_idx_type maxnz,
bool lazy);
#endif
template <class T>
static MArray<T>
dmsolve_extract (const MArray<T> &m, const octave_idx_type *,
const octave_idx_type *, octave_idx_type r1,
octave_idx_type r2, octave_idx_type c1,
octave_idx_type c2)
{
r2 -= 1;
c2 -= 1;
if (r1 > r2) { std::swap (r1, r2); }
if (c1 > c2) { std::swap (c1, c2); }
octave_idx_type new_r = r2 - r1 + 1;
octave_idx_type new_c = c2 - c1 + 1;
MArray<T> result (dim_vector (new_r, new_c));
for (octave_idx_type j = 0; j < new_c; j++)
for (octave_idx_type i = 0; i < new_r; i++)
result.xelem (i, j) = m.elem (r1+i, c1+j);
return result;
}
#if !defined (CXX_NEW_FRIEND_TEMPLATE_DECL)
static MArray<double>
dmsolve_extract (const MArray<double> &m, const octave_idx_type *,
const octave_idx_type *, octave_idx_type r1,
octave_idx_type r2, octave_idx_type c1,
octave_idx_type c2)
static MArray<Complex>
dmsolve_extract (const MArray<Complex> &m, const octave_idx_type *,
const octave_idx_type *, octave_idx_type r1,
octave_idx_type r2, octave_idx_type c1,
octave_idx_type c2)
#endif
template <class T>
static void
dmsolve_insert (MArray<T> &a, const MArray<T> &b, const octave_idx_type *Q,
octave_idx_type r, octave_idx_type c)
{
T *ax = a.fortran_vec ();
const T *bx = b.fortran_vec ();
octave_idx_type anr = a.rows ();
octave_idx_type nr = b.rows ();
octave_idx_type nc = b.cols ();
for (octave_idx_type j = 0; j < nc; j++)
{
octave_idx_type aoff = (c + j) * anr;
octave_idx_type boff = j * nr;
for (octave_idx_type i = 0; i < nr; i++)
{
octave_quit ();
ax[Q[r + i] + aoff] = bx[i + boff];
}
}
}
#if !defined (CXX_NEW_FRIEND_TEMPLATE_DECL)
static void
dmsolve_insert (MArray<double> &a, const MArray<double> &b,
const octave_idx_type *Q, octave_idx_type r, octave_idx_type c);
static void
dmsolve_insert (MArray<Complex> &a, const MArray<Complex> &b,
const octave_idx_type *Q, octave_idx_type r, octave_idx_type c);
#endif
template <class T>
static void
dmsolve_insert (MSparse<T> &a, const MSparse<T> &b, const octave_idx_type *Q,
octave_idx_type r, octave_idx_type c)
{
octave_idx_type b_rows = b.rows ();
octave_idx_type b_cols = b.cols ();
octave_idx_type nr = a.rows ();
octave_idx_type nc = a.cols ();
OCTAVE_LOCAL_BUFFER (octave_idx_type, Qinv, nr);
for (octave_idx_type i = 0; i < nr; i++)
Qinv[Q[i]] = i;
// First count the number of elements in the final array
octave_idx_type nel = a.xcidx (c) + b.nnz ();
if (c + b_cols < nc)
nel += a.xcidx (nc) - a.xcidx (c + b_cols);
for (octave_idx_type i = c; i < c + b_cols; i++)
for (octave_idx_type j = a.xcidx (i); j < a.xcidx (i+1); j++)
if (Qinv[a.xridx (j)] < r || Qinv[a.xridx (j)] >= r + b_rows)
nel++;
OCTAVE_LOCAL_BUFFER (T, X, nr);
octave_sort<octave_idx_type> sort;
MSparse<T> tmp (a);
a = MSparse<T> (nr, nc, nel);
octave_idx_type *ri = a.xridx ();
for (octave_idx_type i = 0; i < tmp.cidx (c); i++)
{
a.xdata (i) = tmp.xdata (i);
a.xridx (i) = tmp.xridx (i);
}
for (octave_idx_type i = 0; i < c + 1; i++)
a.xcidx (i) = tmp.xcidx (i);
octave_idx_type ii = a.xcidx (c);
for (octave_idx_type i = c; i < c + b_cols; i++)
{
octave_quit ();
for (octave_idx_type j = tmp.xcidx (i); j < tmp.xcidx (i+1); j++)
if (Qinv[tmp.xridx (j)] < r || Qinv[tmp.xridx (j)] >= r + b_rows)
{
X[tmp.xridx (j)] = tmp.xdata (j);
a.xridx (ii++) = tmp.xridx (j);
}
octave_quit ();
for (octave_idx_type j = b.cidx (i-c); j < b.cidx (i-c+1); j++)
{
X[Q[r + b.ridx (j)]] = b.data (j);
a.xridx (ii++) = Q[r + b.ridx (j)];
}
sort.sort (ri + a.xcidx (i), ii - a.xcidx (i));
for (octave_idx_type p = a.xcidx (i); p < ii; p++)
a.xdata (p) = X[a.xridx (p)];
a.xcidx (i+1) = ii;
}
for (octave_idx_type i = c + b_cols; i < nc; i++)
{
for (octave_idx_type j = tmp.xcidx (i); j < tmp.cidx (i+1); j++)
{
a.xdata (ii) = tmp.xdata (j);
a.xridx (ii++) = tmp.xridx (j);
}
a.xcidx (i+1) = ii;
}
}
#if !defined (CXX_NEW_FRIEND_TEMPLATE_DECL)
static void
dmsolve_insert (MSparse<double> &a, const SparseMatrix &b,
const octave_idx_type *Q, octave_idx_type r, octave_idx_type c);
static void
dmsolve_insert (MSparse<Complex> &a, const MSparse<Complex> &b,
const octave_idx_type *Q, octave_idx_type r, octave_idx_type c);
#endif
template <class T, class RT>
static void
dmsolve_permute (MArray<RT> &a, const MArray<T>& b, const octave_idx_type *p)
{
octave_idx_type b_nr = b.rows ();
octave_idx_type b_nc = b.cols ();
const T *Bx = b.fortran_vec ();
a.resize (dim_vector (b_nr, b_nc));
RT *Btx = a.fortran_vec ();
for (octave_idx_type j = 0; j < b_nc; j++)
{
octave_idx_type off = j * b_nr;
for (octave_idx_type i = 0; i < b_nr; i++)
{
octave_quit ();
Btx[p[i] + off] = Bx[ i + off];
}
}
}
#if !defined (CXX_NEW_FRIEND_TEMPLATE_DECL)
static void
dmsolve_permute (MArray<double> &a, const MArray<double>& b,
const octave_idx_type *p);
static void
dmsolve_permute (MArray<Complex> &a, const MArray<double>& b,
const octave_idx_type *p);
static void
dmsolve_permute (MArray<Complex> &a, const MArray<Complex>& b,
const octave_idx_type *p);
#endif
template <class T, class RT>
static void
dmsolve_permute (MSparse<RT> &a, const MSparse<T>& b, const octave_idx_type *p)
{
octave_idx_type b_nr = b.rows ();
octave_idx_type b_nc = b.cols ();
octave_idx_type b_nz = b.nnz ();
octave_idx_type nz = 0;
a = MSparse<RT> (b_nr, b_nc, b_nz);
octave_sort<octave_idx_type> sort;
octave_idx_type *ri = a.xridx ();
OCTAVE_LOCAL_BUFFER (RT, X, b_nr);
a.xcidx (0) = 0;
for (octave_idx_type j = 0; j < b_nc; j++)
{
for (octave_idx_type i = b.cidx (j); i < b.cidx (j+1); i++)
{
octave_quit ();
octave_idx_type r = p[b.ridx (i)];
X[r] = b.data (i);
a.xridx (nz++) = p[b.ridx (i)];
}
sort.sort (ri + a.xcidx (j), nz - a.xcidx (j));
for (octave_idx_type i = a.cidx (j); i < nz; i++)
{
octave_quit ();
a.xdata (i) = X[a.xridx (i)];
}
a.xcidx (j+1) = nz;
}
}
#if !defined (CXX_NEW_FRIEND_TEMPLATE_DECL)
static void
dmsolve_permute (MSparse<double> &a, const MSparse<double>& b,
const octave_idx_type *p);
static void
dmsolve_permute (MSparse<Complex> &a, const MSparse<double>& b,
const octave_idx_type *p);
static void
dmsolve_permute (MSparse<Complex> &a, const MSparse<Complex>& b,
const octave_idx_type *p);
#endif
static void
solve_singularity_warning (double)
{
// Dummy singularity handler so that LU solver doesn't flag
// an error for numerically rank defficient matrices
}
template <class RT, class ST, class T>
RT
dmsolve (const ST &a, const T &b, octave_idx_type &info)
{
#ifdef HAVE_CXSPARSE
octave_idx_type nr = a.rows ();
octave_idx_type nc = a.cols ();
octave_idx_type b_nr = b.rows ();
octave_idx_type b_nc = b.cols ();
RT retval;
if (nr < 0 || nc < 0 || nr != b_nr)
(*current_liboctave_error_handler)
("matrix dimension mismatch in solution of minimum norm problem");
else if (nr == 0 || nc == 0 || b_nc == 0)
retval = RT (nc, b_nc, 0.0);
else
{
octave_idx_type nnz_remaining = a.nnz ();
CXSPARSE_DNAME () csm;
csm.m = nr;
csm.n = nc;
csm.x = 0;
csm.nz = -1;
csm.nzmax = a.nnz ();
// Cast away const on A, with full knowledge that CSparse won't touch it.
// Prevents the methods below making a copy of the data.
csm.p = const_cast<octave_idx_type *>(a.cidx ());
csm.i = const_cast<octave_idx_type *>(a.ridx ());
#if defined (CS_VER) && (CS_VER >= 2)
CXSPARSE_DNAME (d) *dm = CXSPARSE_DNAME(_dmperm) (&csm, 0);
octave_idx_type *p = dm->p;
octave_idx_type *q = dm->q;
#else
CXSPARSE_DNAME (d) *dm = CXSPARSE_DNAME(_dmperm) (&csm);
octave_idx_type *p = dm->P;
octave_idx_type *q = dm->Q;
#endif
OCTAVE_LOCAL_BUFFER (octave_idx_type, pinv, nr);
for (octave_idx_type i = 0; i < nr; i++)
pinv[p[i]] = i;
RT btmp;
dmsolve_permute (btmp, b, pinv);
info = 0;
retval.resize (nc, b_nc);
// Leading over-determined block
if (dm->rr[2] < nr && dm->cc[3] < nc)
{
ST m = dmsolve_extract (a, pinv, q, dm->rr[2], nr, dm->cc[3], nc,
nnz_remaining, true);
nnz_remaining -= m.nnz ();
RT mtmp =
qrsolve (m, dmsolve_extract (btmp, 0, 0, dm->rr[2], b_nr, 0,
b_nc), info);
dmsolve_insert (retval, mtmp, q, dm->cc[3], 0);
if (dm->rr[2] > 0 && !info)
{
m = dmsolve_extract (a, pinv, q, 0, dm->rr[2],
dm->cc[3], nc, nnz_remaining, true);
nnz_remaining -= m.nnz ();
RT ctmp = dmsolve_extract (btmp, 0, 0, 0,
dm->rr[2], 0, b_nc);
btmp.insert (ctmp - m * mtmp, 0, 0);
}
}
// Structurally non-singular blocks
// FIXME: Should use fine Dulmange-Mendelsohn decomposition here.
if (dm->rr[1] < dm->rr[2] && dm->cc[2] < dm->cc[3] && !info)
{
ST m = dmsolve_extract (a, pinv, q, dm->rr[1], dm->rr[2],
dm->cc[2], dm->cc[3], nnz_remaining, false);
nnz_remaining -= m.nnz ();
RT btmp2 = dmsolve_extract (btmp, 0, 0, dm->rr[1], dm->rr[2],
0, b_nc);
double rcond = 0.0;
MatrixType mtyp (MatrixType::Full);
RT mtmp = m.solve (mtyp, btmp2, info, rcond,
solve_singularity_warning, false);
if (info != 0)
{
info = 0;
mtmp = qrsolve (m, btmp2, info);
}
dmsolve_insert (retval, mtmp, q, dm->cc[2], 0);
if (dm->rr[1] > 0 && !info)
{
m = dmsolve_extract (a, pinv, q, 0, dm->rr[1], dm->cc[2],
dm->cc[3], nnz_remaining, true);
nnz_remaining -= m.nnz ();
RT ctmp = dmsolve_extract (btmp, 0, 0, 0,
dm->rr[1], 0, b_nc);
btmp.insert (ctmp - m * mtmp, 0, 0);
}
}
// Trailing under-determined block
if (dm->rr[1] > 0 && dm->cc[2] > 0 && !info)
{
ST m = dmsolve_extract (a, pinv, q, 0, dm->rr[1], 0,
dm->cc[2], nnz_remaining, true);
RT mtmp =
qrsolve (m, dmsolve_extract (btmp, 0, 0, 0, dm->rr[1] , 0,
b_nc), info);
dmsolve_insert (retval, mtmp, q, 0, 0);
}
CXSPARSE_DNAME (_dfree) (dm);
}
return retval;
#else
(*current_liboctave_error_handler)
("CXSPARSE unavailable; cannot solve minimum norm problem");
return RT ();
#endif
}
#if !defined (CXX_NEW_FRIEND_TEMPLATE_DECL)
extern Matrix
dmsolve (const SparseMatrix &a, const Matrix &b,
octave_idx_type &info);
extern ComplexMatrix
dmsolve (const SparseMatrix &a, const ComplexMatrix &b,
octave_idx_type &info);
extern ComplexMatrix
dmsolve (const SparseComplexMatrix &a, const Matrix &b,
octave_idx_type &info);
extern ComplexMatrix
dmsolve (const SparseComplexMatrix &a, const ComplexMatrix &b,
octave_idx_type &info);
extern SparseMatrix
dmsolve (const SparseMatrix &a, const SparseMatrix &b,
octave_idx_type &info);
extern SparseComplexMatrix
dmsolve (const SparseMatrix &a, const SparseComplexMatrix &b,
octave_idx_type &info);
extern SparseComplexMatrix
dmsolve (const SparseComplexMatrix &a, const SparseMatrix &b,
octave_idx_type &info);
extern SparseComplexMatrix
dmsolve (const SparseComplexMatrix &a, const SparseComplexMatrix &b,
octave_idx_type &info);
#endif
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