forked from bartvdbraak/blender
Brecht Van Lommel
0b12e61040
This helps to improve the accuracy of UV unwrapping and laplacian deform for high poly meshes, which could get warped quite badly. It's not much slower, doubles are pretty fast on modern CPUs, but it does double memory usage. This seems acceptable as otherwise high poly meshes would not work correctly anyway. Fixes T39004.
236 lines
5.7 KiB
C
236 lines
5.7 KiB
C
/** \file opennl/superlu/smyblas2.c
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* \ingroup opennl
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*/
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/*
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* -- SuperLU routine (version 2.0) --
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* Univ. of California Berkeley, Xerox Palo Alto Research Center,
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* and Lawrence Berkeley National Lab.
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* November 15, 1997
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*
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*/
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/*
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* File name: smyblas2.c
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* Purpose:
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* Level 2 BLAS operations: solves and matvec, written in C.
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* Note:
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* This is only used when the system lacks an efficient BLAS library.
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*/
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/*
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* Solves a dense UNIT lower triangular system. The unit lower
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* triangular matrix is stored in a 2D array M(1:nrow,1:ncol).
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* The solution will be returned in the rhs vector.
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*/
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/* local prototypes*/
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void slsolve ( int, int, double *, double *);
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void susolve ( int, int, double *, double *);
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void smatvec ( int, int, int, double *, double *, double *);
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void slsolve ( int ldm, int ncol, double *M, double *rhs )
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{
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int k;
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double x0, x1, x2, x3, x4, x5, x6, x7;
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double *M0;
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register double *Mki0, *Mki1, *Mki2, *Mki3, *Mki4, *Mki5, *Mki6, *Mki7;
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register int firstcol = 0;
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M0 = &M[0];
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while ( firstcol < ncol - 7 ) { /* Do 8 columns */
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Mki0 = M0 + 1;
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Mki1 = Mki0 + ldm + 1;
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Mki2 = Mki1 + ldm + 1;
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Mki3 = Mki2 + ldm + 1;
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Mki4 = Mki3 + ldm + 1;
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Mki5 = Mki4 + ldm + 1;
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Mki6 = Mki5 + ldm + 1;
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Mki7 = Mki6 + ldm + 1;
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x0 = rhs[firstcol];
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x1 = rhs[firstcol+1] - x0 * *Mki0++;
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x2 = rhs[firstcol+2] - x0 * *Mki0++ - x1 * *Mki1++;
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x3 = rhs[firstcol+3] - x0 * *Mki0++ - x1 * *Mki1++ - x2 * *Mki2++;
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x4 = rhs[firstcol+4] - x0 * *Mki0++ - x1 * *Mki1++ - x2 * *Mki2++
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- x3 * *Mki3++;
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x5 = rhs[firstcol+5] - x0 * *Mki0++ - x1 * *Mki1++ - x2 * *Mki2++
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- x3 * *Mki3++ - x4 * *Mki4++;
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x6 = rhs[firstcol+6] - x0 * *Mki0++ - x1 * *Mki1++ - x2 * *Mki2++
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- x3 * *Mki3++ - x4 * *Mki4++ - x5 * *Mki5++;
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x7 = rhs[firstcol+7] - x0 * *Mki0++ - x1 * *Mki1++ - x2 * *Mki2++
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- x3 * *Mki3++ - x4 * *Mki4++ - x5 * *Mki5++
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- x6 * *Mki6++;
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rhs[++firstcol] = x1;
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rhs[++firstcol] = x2;
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rhs[++firstcol] = x3;
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rhs[++firstcol] = x4;
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rhs[++firstcol] = x5;
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rhs[++firstcol] = x6;
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rhs[++firstcol] = x7;
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++firstcol;
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for (k = firstcol; k < ncol; k++)
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rhs[k] = rhs[k] - x0 * *Mki0++ - x1 * *Mki1++
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- x2 * *Mki2++ - x3 * *Mki3++
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- x4 * *Mki4++ - x5 * *Mki5++
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- x6 * *Mki6++ - x7 * *Mki7++;
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M0 += 8 * ldm + 8;
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}
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while ( firstcol < ncol - 3 ) { /* Do 4 columns */
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Mki0 = M0 + 1;
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Mki1 = Mki0 + ldm + 1;
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Mki2 = Mki1 + ldm + 1;
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Mki3 = Mki2 + ldm + 1;
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x0 = rhs[firstcol];
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x1 = rhs[firstcol+1] - x0 * *Mki0++;
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x2 = rhs[firstcol+2] - x0 * *Mki0++ - x1 * *Mki1++;
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x3 = rhs[firstcol+3] - x0 * *Mki0++ - x1 * *Mki1++ - x2 * *Mki2++;
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rhs[++firstcol] = x1;
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rhs[++firstcol] = x2;
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rhs[++firstcol] = x3;
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++firstcol;
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for (k = firstcol; k < ncol; k++)
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rhs[k] = rhs[k] - x0 * *Mki0++ - x1 * *Mki1++
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- x2 * *Mki2++ - x3 * *Mki3++;
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M0 += 4 * ldm + 4;
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}
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if ( firstcol < ncol - 1 ) { /* Do 2 columns */
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Mki0 = M0 + 1;
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Mki1 = Mki0 + ldm + 1;
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x0 = rhs[firstcol];
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x1 = rhs[firstcol+1] - x0 * *Mki0++;
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rhs[++firstcol] = x1;
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++firstcol;
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for (k = firstcol; k < ncol; k++)
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rhs[k] = rhs[k] - x0 * *Mki0++ - x1 * *Mki1++;
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}
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}
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/*
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* Solves a dense upper triangular system. The upper triangular matrix is
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* stored in a 2-dim array M(1:ldm,1:ncol). The solution will be returned
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* in the rhs vector.
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*/
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void
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susolve ( ldm, ncol, M, rhs )
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int ldm; /* in */
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int ncol; /* in */
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double *M; /* in */
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double *rhs; /* modified */
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{
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double xj;
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int jcol, j, irow;
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jcol = ncol - 1;
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for (j = 0; j < ncol; j++) {
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xj = rhs[jcol] / M[jcol + jcol*ldm]; /* M(jcol, jcol) */
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rhs[jcol] = xj;
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for (irow = 0; irow < jcol; irow++)
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rhs[irow] -= xj * M[irow + jcol*ldm]; /* M(irow, jcol) */
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jcol--;
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}
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}
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/*
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* Performs a dense matrix-vector multiply: Mxvec = Mxvec + M * vec.
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* The input matrix is M(1:nrow,1:ncol); The product is returned in Mxvec[].
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*/
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void smatvec ( ldm, nrow, ncol, M, vec, Mxvec )
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int ldm; /* in -- leading dimension of M */
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int nrow; /* in */
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int ncol; /* in */
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double *M; /* in */
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double *vec; /* in */
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double *Mxvec; /* in/out */
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{
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double vi0, vi1, vi2, vi3, vi4, vi5, vi6, vi7;
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double *M0;
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register double *Mki0, *Mki1, *Mki2, *Mki3, *Mki4, *Mki5, *Mki6, *Mki7;
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register int firstcol = 0;
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int k;
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M0 = &M[0];
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while ( firstcol < ncol - 7 ) { /* Do 8 columns */
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Mki0 = M0;
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Mki1 = Mki0 + ldm;
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Mki2 = Mki1 + ldm;
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Mki3 = Mki2 + ldm;
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Mki4 = Mki3 + ldm;
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Mki5 = Mki4 + ldm;
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Mki6 = Mki5 + ldm;
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Mki7 = Mki6 + ldm;
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vi0 = vec[firstcol++];
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vi1 = vec[firstcol++];
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vi2 = vec[firstcol++];
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vi3 = vec[firstcol++];
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vi4 = vec[firstcol++];
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vi5 = vec[firstcol++];
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vi6 = vec[firstcol++];
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vi7 = vec[firstcol++];
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for (k = 0; k < nrow; k++)
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Mxvec[k] += vi0 * *Mki0++ + vi1 * *Mki1++
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+ vi2 * *Mki2++ + vi3 * *Mki3++
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+ vi4 * *Mki4++ + vi5 * *Mki5++
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+ vi6 * *Mki6++ + vi7 * *Mki7++;
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M0 += 8 * ldm;
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}
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while ( firstcol < ncol - 3 ) { /* Do 4 columns */
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Mki0 = M0;
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Mki1 = Mki0 + ldm;
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Mki2 = Mki1 + ldm;
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Mki3 = Mki2 + ldm;
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vi0 = vec[firstcol++];
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vi1 = vec[firstcol++];
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vi2 = vec[firstcol++];
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vi3 = vec[firstcol++];
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for (k = 0; k < nrow; k++)
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Mxvec[k] += vi0 * *Mki0++ + vi1 * *Mki1++
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+ vi2 * *Mki2++ + vi3 * *Mki3++ ;
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M0 += 4 * ldm;
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}
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while ( firstcol < ncol ) { /* Do 1 column */
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Mki0 = M0;
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vi0 = vec[firstcol++];
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for (k = 0; k < nrow; k++)
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Mxvec[k] += vi0 * *Mki0++;
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M0 += ldm;
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}
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}
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