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csr.c
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csr.c
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/*!
* \file
*
* \brief Various routines with dealing with CSR matrices
*
* \author George Karypis
* \version\verbatim $Id: csr.c 21044 2017-05-24 22:50:32Z karypis $ \endverbatim
*/
#include <GKlib.h>
#define OMPMINOPS 50000
/*************************************************************************/
/*! Allocate memory for a CSR matrix and initializes it
\returns the allocated matrix. The various fields are set to NULL.
*/
/**************************************************************************/
gk_csr_t *gk_csr_Create()
{
gk_csr_t *mat=NULL;
if ((mat = (gk_csr_t *)gk_malloc(sizeof(gk_csr_t), "gk_csr_Create: mat")))
gk_csr_Init(mat);
return mat;
}
/*************************************************************************/
/*! Initializes the matrix
\param mat is the matrix to be initialized.
*/
/*************************************************************************/
void gk_csr_Init(gk_csr_t *mat)
{
memset(mat, 0, sizeof(gk_csr_t));
mat->nrows = mat->ncols = 0;
}
/*************************************************************************/
/*! Frees all the memory allocated for matrix.
\param mat is the matrix to be freed.
*/
/*************************************************************************/
void gk_csr_Free(gk_csr_t **mat)
{
if (*mat == NULL)
return;
gk_csr_FreeContents(*mat);
gk_free((void **)mat, LTERM);
}
/*************************************************************************/
/*! Frees only the memory allocated for the matrix's different fields and
sets them to NULL.
\param mat is the matrix whose contents will be freed.
*/
/*************************************************************************/
void gk_csr_FreeContents(gk_csr_t *mat)
{
gk_free((void *)&mat->rowptr, &mat->rowind, &mat->rowval,
&mat->rowids, &mat->rlabels, &mat->rmap,
&mat->colptr, &mat->colind, &mat->colval,
&mat->colids, &mat->clabels, &mat->cmap,
&mat->rnorms, &mat->cnorms, &mat->rsums, &mat->csums,
&mat->rsizes, &mat->csizes, &mat->rvols, &mat->cvols,
&mat->rwgts, &mat->cwgts,
LTERM);
}
/*************************************************************************/
/*! Returns a copy of a matrix.
\param mat is the matrix to be duplicated.
\returns the newly created copy of the matrix.
*/
/**************************************************************************/
gk_csr_t *gk_csr_Dup(gk_csr_t *mat)
{
gk_csr_t *nmat;
nmat = gk_csr_Create();
nmat->nrows = mat->nrows;
nmat->ncols = mat->ncols;
/* copy the row structure */
if (mat->rowptr)
nmat->rowptr = gk_zcopy(mat->nrows+1, mat->rowptr,
gk_zmalloc(mat->nrows+1, "gk_csr_Dup: rowptr"));
if (mat->rowids)
nmat->rowids = gk_icopy(mat->nrows, mat->rowids,
gk_imalloc(mat->nrows, "gk_csr_Dup: rowids"));
if (mat->rlabels)
nmat->rlabels = gk_icopy(mat->nrows, mat->rlabels,
gk_imalloc(mat->nrows, "gk_csr_Dup: rlabels"));
if (mat->rnorms)
nmat->rnorms = gk_fcopy(mat->nrows, mat->rnorms,
gk_fmalloc(mat->nrows, "gk_csr_Dup: rnorms"));
if (mat->rsums)
nmat->rsums = gk_fcopy(mat->nrows, mat->rsums,
gk_fmalloc(mat->nrows, "gk_csr_Dup: rsums"));
if (mat->rsizes)
nmat->rsizes = gk_fcopy(mat->nrows, mat->rsizes,
gk_fmalloc(mat->nrows, "gk_csr_Dup: rsizes"));
if (mat->rvols)
nmat->rvols = gk_fcopy(mat->nrows, mat->rvols,
gk_fmalloc(mat->nrows, "gk_csr_Dup: rvols"));
if (mat->rwgts)
nmat->rwgts = gk_fcopy(mat->nrows, mat->rwgts,
gk_fmalloc(mat->nrows, "gk_csr_Dup: rwgts"));
if (mat->rowind)
nmat->rowind = gk_icopy(mat->rowptr[mat->nrows], mat->rowind,
gk_imalloc(mat->rowptr[mat->nrows], "gk_csr_Dup: rowind"));
if (mat->rowval)
nmat->rowval = gk_fcopy(mat->rowptr[mat->nrows], mat->rowval,
gk_fmalloc(mat->rowptr[mat->nrows], "gk_csr_Dup: rowval"));
/* copy the col structure */
if (mat->colptr)
nmat->colptr = gk_zcopy(mat->ncols+1, mat->colptr,
gk_zmalloc(mat->ncols+1, "gk_csr_Dup: colptr"));
if (mat->colids)
nmat->colids = gk_icopy(mat->ncols, mat->colids,
gk_imalloc(mat->ncols, "gk_csr_Dup: colids"));
if (mat->clabels)
nmat->clabels = gk_icopy(mat->ncols, mat->clabels,
gk_imalloc(mat->ncols, "gk_csr_Dup: clabels"));
if (mat->cnorms)
nmat->cnorms = gk_fcopy(mat->ncols, mat->cnorms,
gk_fmalloc(mat->ncols, "gk_csr_Dup: cnorms"));
if (mat->csums)
nmat->csums = gk_fcopy(mat->ncols, mat->csums,
gk_fmalloc(mat->ncols, "gk_csr_Dup: csums"));
if (mat->csizes)
nmat->csizes = gk_fcopy(mat->ncols, mat->csizes,
gk_fmalloc(mat->ncols, "gk_csr_Dup: csizes"));
if (mat->cvols)
nmat->cvols = gk_fcopy(mat->ncols, mat->cvols,
gk_fmalloc(mat->ncols, "gk_csr_Dup: cvols"));
if (mat->cwgts)
nmat->cwgts = gk_fcopy(mat->ncols, mat->cwgts,
gk_fmalloc(mat->ncols, "gk_csr_Dup: cwgts"));
if (mat->colind)
nmat->colind = gk_icopy(mat->colptr[mat->ncols], mat->colind,
gk_imalloc(mat->colptr[mat->ncols], "gk_csr_Dup: colind"));
if (mat->colval)
nmat->colval = gk_fcopy(mat->colptr[mat->ncols], mat->colval,
gk_fmalloc(mat->colptr[mat->ncols], "gk_csr_Dup: colval"));
return nmat;
}
/*************************************************************************/
/*! Returns a submatrix containint a set of consecutive rows.
\param mat is the original matrix.
\param rstart is the starting row.
\param nrows is the number of rows from rstart to extract.
\returns the row structure of the newly created submatrix.
*/
/**************************************************************************/
gk_csr_t *gk_csr_ExtractSubmatrix(gk_csr_t *mat, int rstart, int nrows)
{
ssize_t i;
gk_csr_t *nmat;
if (rstart+nrows > mat->nrows)
return NULL;
nmat = gk_csr_Create();
nmat->nrows = nrows;
nmat->ncols = mat->ncols;
/* copy the row structure */
if (mat->rowptr)
nmat->rowptr = gk_zcopy(nrows+1, mat->rowptr+rstart,
gk_zmalloc(nrows+1, "gk_csr_ExtractSubmatrix: rowptr"));
for (i=nrows; i>=0; i--)
nmat->rowptr[i] -= nmat->rowptr[0];
ASSERT(nmat->rowptr[0] == 0);
if (mat->rowids)
nmat->rowids = gk_icopy(nrows, mat->rowids+rstart,
gk_imalloc(nrows, "gk_csr_ExtractSubmatrix: rowids"));
if (mat->rnorms)
nmat->rnorms = gk_fcopy(nrows, mat->rnorms+rstart,
gk_fmalloc(nrows, "gk_csr_ExtractSubmatrix: rnorms"));
if (mat->rsums)
nmat->rsums = gk_fcopy(nrows, mat->rsums+rstart,
gk_fmalloc(nrows, "gk_csr_ExtractSubmatrix: rsums"));
ASSERT(nmat->rowptr[nrows] == mat->rowptr[rstart+nrows]-mat->rowptr[rstart]);
if (mat->rowind)
nmat->rowind = gk_icopy(mat->rowptr[rstart+nrows]-mat->rowptr[rstart],
mat->rowind+mat->rowptr[rstart],
gk_imalloc(mat->rowptr[rstart+nrows]-mat->rowptr[rstart],
"gk_csr_ExtractSubmatrix: rowind"));
if (mat->rowval)
nmat->rowval = gk_fcopy(mat->rowptr[rstart+nrows]-mat->rowptr[rstart],
mat->rowval+mat->rowptr[rstart],
gk_fmalloc(mat->rowptr[rstart+nrows]-mat->rowptr[rstart],
"gk_csr_ExtractSubmatrix: rowval"));
return nmat;
}
/*************************************************************************/
/*! Returns a submatrix containing a certain set of rows.
\param mat is the original matrix.
\param nrows is the number of rows to extract.
\param rind is the set of row numbers to extract.
\returns the row structure of the newly created submatrix.
*/
/**************************************************************************/
gk_csr_t *gk_csr_ExtractRows(gk_csr_t *mat, int nrows, int *rind)
{
ssize_t i, ii, j, nnz;
gk_csr_t *nmat;
nmat = gk_csr_Create();
nmat->nrows = nrows;
nmat->ncols = mat->ncols;
for (nnz=0, i=0; i<nrows; i++)
nnz += mat->rowptr[rind[i]+1]-mat->rowptr[rind[i]];
nmat->rowptr = gk_zmalloc(nmat->nrows+1, "gk_csr_ExtractPartition: rowptr");
nmat->rowind = gk_imalloc(nnz, "gk_csr_ExtractPartition: rowind");
nmat->rowval = gk_fmalloc(nnz, "gk_csr_ExtractPartition: rowval");
nmat->rowptr[0] = 0;
for (nnz=0, j=0, ii=0; ii<nrows; ii++) {
i = rind[ii];
gk_icopy(mat->rowptr[i+1]-mat->rowptr[i], mat->rowind+mat->rowptr[i], nmat->rowind+nnz);
gk_fcopy(mat->rowptr[i+1]-mat->rowptr[i], mat->rowval+mat->rowptr[i], nmat->rowval+nnz);
nnz += mat->rowptr[i+1]-mat->rowptr[i];
nmat->rowptr[++j] = nnz;
}
ASSERT(j == nmat->nrows);
return nmat;
}
/*************************************************************************/
/*! Returns a submatrix corresponding to a specified partitioning of rows.
\param mat is the original matrix.
\param part is the partitioning vector of the rows.
\param pid is the partition ID that will be extracted.
\returns the row structure of the newly created submatrix.
*/
/**************************************************************************/
gk_csr_t *gk_csr_ExtractPartition(gk_csr_t *mat, int *part, int pid)
{
ssize_t i, j, nnz;
gk_csr_t *nmat;
nmat = gk_csr_Create();
nmat->nrows = 0;
nmat->ncols = mat->ncols;
for (nnz=0, i=0; i<mat->nrows; i++) {
if (part[i] == pid) {
nmat->nrows++;
nnz += mat->rowptr[i+1]-mat->rowptr[i];
}
}
nmat->rowptr = gk_zmalloc(nmat->nrows+1, "gk_csr_ExtractPartition: rowptr");
nmat->rowind = gk_imalloc(nnz, "gk_csr_ExtractPartition: rowind");
nmat->rowval = gk_fmalloc(nnz, "gk_csr_ExtractPartition: rowval");
nmat->rowptr[0] = 0;
for (nnz=0, j=0, i=0; i<mat->nrows; i++) {
if (part[i] == pid) {
gk_icopy(mat->rowptr[i+1]-mat->rowptr[i], mat->rowind+mat->rowptr[i], nmat->rowind+nnz);
gk_fcopy(mat->rowptr[i+1]-mat->rowptr[i], mat->rowval+mat->rowptr[i], nmat->rowval+nnz);
nnz += mat->rowptr[i+1]-mat->rowptr[i];
nmat->rowptr[++j] = nnz;
}
}
ASSERT(j == nmat->nrows);
return nmat;
}
/*************************************************************************/
/*! Splits the matrix into multiple sub-matrices based on the provided
color array.
\param mat is the original matrix.
\param color is an array of size equal to the number of non-zeros
in the matrix (row-wise structure). The matrix is split into
as many parts as the number of colors. For meaningfull results,
the colors should be numbered consecutively starting from 0.
\returns an array of matrices for each supplied color number.
*/
/**************************************************************************/
gk_csr_t **gk_csr_Split(gk_csr_t *mat, int *color)
{
ssize_t i, j;
int nrows, ncolors;
ssize_t *rowptr;
int *rowind;
float *rowval;
gk_csr_t **smats;
nrows = mat->nrows;
rowptr = mat->rowptr;
rowind = mat->rowind;
rowval = mat->rowval;
ncolors = gk_imax(rowptr[nrows], color, 1)+1;
smats = (gk_csr_t **)gk_malloc(sizeof(gk_csr_t *)*ncolors, "gk_csr_Split: smats");
for (i=0; i<ncolors; i++) {
smats[i] = gk_csr_Create();
smats[i]->nrows = mat->nrows;
smats[i]->ncols = mat->ncols;
smats[i]->rowptr = gk_zsmalloc(nrows+1, 0, "gk_csr_Split: smats[i]->rowptr");
}
for (i=0; i<nrows; i++) {
for (j=rowptr[i]; j<rowptr[i+1]; j++)
smats[color[j]]->rowptr[i]++;
}
for (i=0; i<ncolors; i++)
MAKECSR(j, nrows, smats[i]->rowptr);
for (i=0; i<ncolors; i++) {
smats[i]->rowind = gk_imalloc(smats[i]->rowptr[nrows], "gk_csr_Split: smats[i]->rowind");
smats[i]->rowval = gk_fmalloc(smats[i]->rowptr[nrows], "gk_csr_Split: smats[i]->rowval");
}
for (i=0; i<nrows; i++) {
for (j=rowptr[i]; j<rowptr[i+1]; j++) {
smats[color[j]]->rowind[smats[color[j]]->rowptr[i]] = rowind[j];
smats[color[j]]->rowval[smats[color[j]]->rowptr[i]] = rowval[j];
smats[color[j]]->rowptr[i]++;
}
}
for (i=0; i<ncolors; i++)
SHIFTCSR(j, nrows, smats[i]->rowptr);
return smats;
}
/**************************************************************************/
/*! Determines the format of the CSR matrix based on the extension.
\param filename is the name of the file.
\param the user-supplied format.
\returns the type. The extension of the file directly maps to the
name of the format.
*/
/**************************************************************************/
int gk_csr_DetermineFormat(char *filename, int format)
{
if (format != GK_CSR_FMT_AUTO)
return format;
format = GK_CSR_FMT_CSR;
char *extension = gk_getextname(filename);
if (!strcmp(extension, "csr"))
format = GK_CSR_FMT_CSR;
else if (!strcmp(extension, "ijv"))
format = GK_CSR_FMT_IJV;
else if (!strcmp(extension, "cluto"))
format = GK_CSR_FMT_CLUTO;
else if (!strcmp(extension, "metis"))
format = GK_CSR_FMT_METIS;
else if (!strcmp(extension, "binrow"))
format = GK_CSR_FMT_BINROW;
else if (!strcmp(extension, "bincol"))
format = GK_CSR_FMT_BINCOL;
else if (!strcmp(extension, "bijv"))
format = GK_CSR_FMT_BIJV;
gk_free((void **)&extension, LTERM);
return format;
}
/**************************************************************************/
/*! Reads a CSR matrix from the supplied file and stores it the matrix's
forward structure.
\param filename is the file that stores the data.
\param format is either GK_CSR_FMT_METIS, GK_CSR_FMT_CLUTO,
GK_CSR_FMT_CSR, GK_CSR_FMT_BINROW, GK_CSR_FMT_BINCOL
specifying the type of the input format.
The GK_CSR_FMT_CSR does not contain a header
line, whereas the GK_CSR_FMT_BINROW is a binary format written
by gk_csr_Write() using the same format specifier.
\param readvals is either 1 or 0, indicating if the CSR file contains
values or it does not. It only applies when GK_CSR_FMT_CSR is
used.
\param numbering is either 1 or 0, indicating if the numbering of the
indices start from 1 or 0, respectively. If they start from 1,
they are automatically decreamented during input so that they
will start from 0. It only applies when GK_CSR_FMT_CSR is
used.
\returns the matrix that was read.
*/
/**************************************************************************/
gk_csr_t *gk_csr_Read(char *filename, int format, int readvals, int numbering)
{
ssize_t i, k, l;
size_t nfields, nrows, ncols, nnz, fmt, ncon;
size_t lnlen;
ssize_t *rowptr;
int *rowind, *iinds, *jinds, ival;
float *rowval=NULL, *vals, fval;
int readsizes, readwgts;
char *line=NULL, *head, *tail, fmtstr[256];
FILE *fpin;
gk_csr_t *mat=NULL;
format = gk_csr_DetermineFormat(filename, format);
if (!gk_fexists(filename))
gk_errexit(SIGERR, "File %s does not exist!\n", filename);
switch (format) {
case GK_CSR_FMT_BINROW:
mat = gk_csr_Create();
fpin = gk_fopen(filename, "rb", "gk_csr_Read: fpin");
if (fread(&(mat->nrows), sizeof(int32_t), 1, fpin) != 1)
gk_errexit(SIGERR, "Failed to read the nrows from file %s!\n", filename);
if (fread(&(mat->ncols), sizeof(int32_t), 1, fpin) != 1)
gk_errexit(SIGERR, "Failed to read the ncols from file %s!\n", filename);
mat->rowptr = gk_zmalloc(mat->nrows+1, "gk_csr_Read: rowptr");
if (fread(mat->rowptr, sizeof(ssize_t), mat->nrows+1, fpin) != mat->nrows+1)
gk_errexit(SIGERR, "Failed to read the rowptr from file %s!\n", filename);
mat->rowind = gk_imalloc(mat->rowptr[mat->nrows], "gk_csr_Read: rowind");
if (fread(mat->rowind, sizeof(int32_t), mat->rowptr[mat->nrows], fpin) != mat->rowptr[mat->nrows])
gk_errexit(SIGERR, "Failed to read the rowind from file %s!\n", filename);
if (readvals == 1) {
mat->rowval = gk_fmalloc(mat->rowptr[mat->nrows], "gk_csr_Read: rowval");
if (fread(mat->rowval, sizeof(float), mat->rowptr[mat->nrows], fpin) != mat->rowptr[mat->nrows])
gk_errexit(SIGERR, "Failed to read the rowval from file %s!\n", filename);
}
gk_fclose(fpin);
return mat;
break;
case GK_CSR_FMT_BINCOL:
mat = gk_csr_Create();
fpin = gk_fopen(filename, "rb", "gk_csr_Read: fpin");
if (fread(&(mat->nrows), sizeof(int32_t), 1, fpin) != 1)
gk_errexit(SIGERR, "Failed to read the nrows from file %s!\n", filename);
if (fread(&(mat->ncols), sizeof(int32_t), 1, fpin) != 1)
gk_errexit(SIGERR, "Failed to read the ncols from file %s!\n", filename);
mat->colptr = gk_zmalloc(mat->ncols+1, "gk_csr_Read: colptr");
if (fread(mat->colptr, sizeof(ssize_t), mat->ncols+1, fpin) != mat->ncols+1)
gk_errexit(SIGERR, "Failed to read the colptr from file %s!\n", filename);
mat->colind = gk_imalloc(mat->colptr[mat->ncols], "gk_csr_Read: colind");
if (fread(mat->colind, sizeof(int32_t), mat->colptr[mat->ncols], fpin) != mat->colptr[mat->ncols])
gk_errexit(SIGERR, "Failed to read the colind from file %s!\n", filename);
if (readvals) {
mat->colval = gk_fmalloc(mat->colptr[mat->ncols], "gk_csr_Read: colval");
if (fread(mat->colval, sizeof(float), mat->colptr[mat->ncols], fpin) != mat->colptr[mat->ncols])
gk_errexit(SIGERR, "Failed to read the colval from file %s!\n", filename);
}
gk_fclose(fpin);
return mat;
break;
case GK_CSR_FMT_IJV:
gk_getfilestats(filename, &nrows, &nnz, NULL, NULL);
if (readvals == 1 && 3*nrows != nnz)
gk_errexit(SIGERR, "Error: The number of numbers (%zd %d) in the input file is not a multiple of 3.\n", nnz, readvals);
if (readvals == 0 && 2*nrows != nnz)
gk_errexit(SIGERR, "Error: The number of numbers (%zd %d) in the input file is not a multiple of 2.\n", nnz, readvals);
nnz = nrows;
numbering = (numbering ? - 1 : 0);
/* read the data into three arrays */
iinds = gk_i32malloc(nnz, "iinds");
jinds = gk_i32malloc(nnz, "jinds");
vals = (readvals ? gk_fmalloc(nnz, "vals") : NULL);
fpin = gk_fopen(filename, "r", "gk_csr_Read: fpin");
for (nrows=0, ncols=0, i=0; i<nnz; i++) {
if (readvals) {
if (fscanf(fpin, "%d %d %f", &iinds[i], &jinds[i], &vals[i]) != 3)
gk_errexit(SIGERR, "Error: Failed to read (i, j, val) for nnz: %zd.\n", i);
}
else {
if (fscanf(fpin, "%d %d", &iinds[i], &jinds[i]) != 2)
gk_errexit(SIGERR, "Error: Failed to read (i, j) value for nnz: %zd.\n", i);
}
iinds[i] += numbering;
jinds[i] += numbering;
if (nrows < iinds[i])
nrows = iinds[i];
if (ncols < jinds[i])
ncols = jinds[i];
}
nrows++;
ncols++;
gk_fclose(fpin);
/* convert (i, j, v) into a CSR matrix */
mat = gk_csr_Create();
mat->nrows = nrows;
mat->ncols = ncols;
rowptr = mat->rowptr = gk_zsmalloc(nrows+1, 0, "rowptr");
rowind = mat->rowind = gk_i32malloc(nnz, "rowind");
if (readvals)
rowval = mat->rowval = gk_fmalloc(nnz, "rowval");
for (i=0; i<nnz; i++)
rowptr[iinds[i]]++;
MAKECSR(i, nrows, rowptr);
for (i=0; i<nnz; i++) {
rowind[rowptr[iinds[i]]] = jinds[i];
if (readvals)
rowval[rowptr[iinds[i]]] = vals[i];
rowptr[iinds[i]]++;
}
SHIFTCSR(i, nrows, rowptr);
gk_free((void **)&iinds, &jinds, &vals, LTERM);
return mat;
break;
case GK_CSR_FMT_BIJV:
mat = gk_csr_Create();
fpin = gk_fopen(filename, "rb", "gk_csr_Read: fpin");
if (fread(&(mat->nrows), sizeof(int32_t), 1, fpin) != 1)
gk_errexit(SIGERR, "Failed to read the nrows from file %s!\n", filename);
if (fread(&(mat->ncols), sizeof(int32_t), 1, fpin) != 1)
gk_errexit(SIGERR, "Failed to read the ncols from file %s!\n", filename);
if (fread(&nnz, sizeof(size_t), 1, fpin) != 1)
gk_errexit(SIGERR, "Failed to read the nnz from file %s!\n", filename);
if (fread(&readvals, sizeof(int32_t), 1, fpin) != 1)
gk_errexit(SIGERR, "Failed to read the readvals from file %s!\n", filename);
/* read the data into three arrays */
iinds = gk_i32malloc(nnz, "iinds");
jinds = gk_i32malloc(nnz, "jinds");
vals = (readvals ? gk_fmalloc(nnz, "vals") : NULL);
for (i=0; i<nnz; i++) {
if (fread(&(iinds[i]), sizeof(int32_t), 1, fpin) != 1)
gk_errexit(SIGERR, "Failed to read iinds[i] from file %s!\n", filename);
if (fread(&(jinds[i]), sizeof(int32_t), 1, fpin) != 1)
gk_errexit(SIGERR, "Failed to read jinds[i] from file %s!\n", filename);
if (readvals) {
if (fread(&(vals[i]), sizeof(float), 1, fpin) != 1)
gk_errexit(SIGERR, "Failed to read vals[i] from file %s!\n", filename);
}
//printf("%d %d\n", iinds[i], jinds[i]);
}
gk_fclose(fpin);
/* convert (i, j, v) into a CSR matrix */
rowptr = mat->rowptr = gk_zsmalloc(mat->nrows+1, 0, "rowptr");
rowind = mat->rowind = gk_i32malloc(nnz, "rowind");
if (readvals)
rowval = mat->rowval = gk_fmalloc(nnz, "rowval");
for (i=0; i<nnz; i++)
rowptr[iinds[i]]++;
MAKECSR(i, mat->nrows, rowptr);
for (i=0; i<nnz; i++) {
rowind[rowptr[iinds[i]]] = jinds[i];
if (readvals)
rowval[rowptr[iinds[i]]] = vals[i];
rowptr[iinds[i]]++;
}
SHIFTCSR(i, mat->nrows, rowptr);
gk_free((void **)&iinds, &jinds, &vals, LTERM);
return mat;
break;
/* the following are handled by a common input code, that comes after the switch */
case GK_CSR_FMT_CLUTO:
fpin = gk_fopen(filename, "r", "gk_csr_Read: fpin");
do {
if (gk_getline(&line, &lnlen, fpin) <= 0)
gk_errexit(SIGERR, "Premature end of input file: file:%s\n", filename);
} while (line[0] == '%');
if (sscanf(line, "%zu %zu %zu", &nrows, &ncols, &nnz) != 3)
gk_errexit(SIGERR, "Header line must contain 3 integers.\n");
readsizes = 0;
readwgts = 0;
readvals = 1;
numbering = 1;
break;
case GK_CSR_FMT_METIS:
fpin = gk_fopen(filename, "r", "gk_csr_Read: fpin");
do {
if (gk_getline(&line, &lnlen, fpin) <= 0)
gk_errexit(SIGERR, "Premature end of input file: file:%s\n", filename);
} while (line[0] == '%');
fmt = ncon = 0;
nfields = sscanf(line, "%zu %zu %zu %zu", &nrows, &nnz, &fmt, &ncon);
if (nfields < 2)
gk_errexit(SIGERR, "Header line must contain at least 2 integers (#vtxs and #edges).\n");
ncols = nrows;
nnz *= 2;
if (fmt > 111)
gk_errexit(SIGERR, "Cannot read this type of file format [fmt=%zu]!\n", fmt);
sprintf(fmtstr, "%03zu", fmt%1000);
readsizes = (fmtstr[0] == '1');
readwgts = (fmtstr[1] == '1');
readvals = (fmtstr[2] == '1');
numbering = 1;
ncon = (ncon == 0 ? 1 : ncon);
break;
case GK_CSR_FMT_CSR:
readsizes = 0;
readwgts = 0;
gk_getfilestats(filename, &nrows, &nnz, NULL, NULL);
if (readvals == 1 && nnz%2 == 1)
gk_errexit(SIGERR, "Error: The number of numbers (%zd %d) in the input file is not even.\n", nnz, readvals);
if (readvals == 1)
nnz = nnz/2;
fpin = gk_fopen(filename, "r", "gk_csr_Read: fpin");
break;
default:
gk_errexit(SIGERR, "Unknown csr format.\n");
return NULL;
}
mat = gk_csr_Create();
mat->nrows = nrows;
rowptr = mat->rowptr = gk_zmalloc(nrows+1, "gk_csr_Read: rowptr");
rowind = mat->rowind = gk_imalloc(nnz, "gk_csr_Read: rowind");
if (readvals != 2)
rowval = mat->rowval = gk_fsmalloc(nnz, 1.0, "gk_csr_Read: rowval");
if (readsizes)
mat->rsizes = gk_fsmalloc(nrows, 0.0, "gk_csr_Read: rsizes");
if (readwgts)
mat->rwgts = gk_fsmalloc(nrows*ncon, 0.0, "gk_csr_Read: rwgts");
/*----------------------------------------------------------------------
* Read the sparse matrix file
*---------------------------------------------------------------------*/
numbering = (numbering ? -1 : 0);
for (ncols=0, rowptr[0]=0, k=0, i=0; i<nrows; i++) {
do {
if (gk_getline(&line, &lnlen, fpin) == -1)
gk_errexit(SIGERR, "Premature end of input file: file while reading row %d\n", i);
} while (line[0] == '%');
head = line;
tail = NULL;
/* Read vertex sizes */
if (readsizes) {
#ifdef __MSC__
mat->rsizes[i] = (float)strtod(head, &tail);
#else
mat->rsizes[i] = strtof(head, &tail);
#endif
if (tail == head)
gk_errexit(SIGERR, "The line for vertex %zd does not have size information\n", i+1);
if (mat->rsizes[i] < 0)
errexit("The size for vertex %zd must be >= 0\n", i+1);
head = tail;
}
/* Read vertex weights */
if (readwgts) {
for (l=0; l<ncon; l++) {
#ifdef __MSC__
mat->rwgts[i*ncon+l] = (float)strtod(head, &tail);
#else
mat->rwgts[i*ncon+l] = strtof(head, &tail);
#endif
if (tail == head)
errexit("The line for vertex %zd does not have enough weights "
"for the %d constraints.\n", i+1, ncon);
if (mat->rwgts[i*ncon+l] < 0)
errexit("The weight vertex %zd and constraint %zd must be >= 0\n", i+1, l);
head = tail;
}
}
/* Read the rest of the row */
while (1) {
ival = (int)strtol(head, &tail, 0);
if (tail == head)
break;
head = tail;
if ((rowind[k] = ival + numbering) < 0)
gk_errexit(SIGERR, "Error: Invalid column number %d at row %zd.\n", ival, i);
ncols = gk_max(rowind[k], ncols);
if (readvals == 1) {
#ifdef __MSC__
fval = (float)strtod(head, &tail);
#else
fval = strtof(head, &tail);
#endif
if (tail == head)
gk_errexit(SIGERR, "Value could not be found for column! Row:%zd, NNZ:%zd\n", i, k);
head = tail;
rowval[k] = fval;
}
k++;
}
rowptr[i+1] = k;
}
if (format == GK_CSR_FMT_METIS) {
ASSERT(ncols+1 == mat->nrows);
mat->ncols = mat->nrows;
}
else {
mat->ncols = ncols+1;
}
if (k != nnz)
gk_errexit(SIGERR, "gk_csr_Read: Something wrong with the number of nonzeros in "
"the input file. NNZ=%zd, ActualNNZ=%zd.\n", nnz, k);
gk_fclose(fpin);
gk_free((void **)&line, LTERM);
return mat;
}
/**************************************************************************/
/*! Writes the row-based structure of a matrix into a file.
\param mat is the matrix to be written,
\param filename is the name of the output file.
\param format is one of: GK_CSR_FMT_CLUTO, GK_CSR_FMT_CSR,
GK_CSR_FMT_BINROW, GK_CSR_FMT_BINCOL, GK_CSR_FMT_BIJV.
\param writevals is either 1 or 0 indicating if the values will be
written or not. This is only applicable when GK_CSR_FMT_CSR
is used.
\param numbering is either 1 or 0 indicating if the internal 0-based
numbering will be shifted by one or not during output. This
is only applicable when GK_CSR_FMT_CSR is used.
*/
/**************************************************************************/
void gk_csr_Write(gk_csr_t *mat, char *filename, int format, int writevals, int numbering)
{
ssize_t i, j;
int32_t edge[2];
FILE *fpout;
format = gk_csr_DetermineFormat(filename, format);
switch (format) {
case GK_CSR_FMT_METIS:
if (mat->nrows != mat->ncols || mat->rowptr[mat->nrows]%2 == 1)
gk_errexit(SIGERR, "METIS output format requires a square symmetric matrix.\n");
if (filename)
fpout = gk_fopen(filename, "w", "gk_csr_Write: fpout");
else
fpout = stdout;
fprintf(fpout, "%d %zd\n", mat->nrows, mat->rowptr[mat->nrows]/2);
for (i=0; i<mat->nrows; i++) {
for (j=mat->rowptr[i]; j<mat->rowptr[i+1]; j++)
fprintf(fpout, " %d", mat->rowind[j]+1);
fprintf(fpout, "\n");
}
if (filename)
gk_fclose(fpout);
break;
case GK_CSR_FMT_BINROW:
if (filename == NULL)
gk_errexit(SIGERR, "The filename parameter cannot be NULL.\n");
fpout = gk_fopen(filename, "wb", "gk_csr_Write: fpout");
fwrite(&(mat->nrows), sizeof(int32_t), 1, fpout);
fwrite(&(mat->ncols), sizeof(int32_t), 1, fpout);
fwrite(mat->rowptr, sizeof(ssize_t), mat->nrows+1, fpout);
fwrite(mat->rowind, sizeof(int32_t), mat->rowptr[mat->nrows], fpout);
if (writevals)
fwrite(mat->rowval, sizeof(float), mat->rowptr[mat->nrows], fpout);
gk_fclose(fpout);
return;
break;
case GK_CSR_FMT_BINCOL:
if (filename == NULL)
gk_errexit(SIGERR, "The filename parameter cannot be NULL.\n");
fpout = gk_fopen(filename, "wb", "gk_csr_Write: fpout");
fwrite(&(mat->nrows), sizeof(int32_t), 1, fpout);
fwrite(&(mat->ncols), sizeof(int32_t), 1, fpout);
fwrite(mat->colptr, sizeof(ssize_t), mat->ncols+1, fpout);
fwrite(mat->colind, sizeof(int32_t), mat->colptr[mat->ncols], fpout);
if (writevals)
fwrite(mat->colval, sizeof(float), mat->colptr[mat->ncols], fpout);
gk_fclose(fpout);
return;
break;
case GK_CSR_FMT_IJV:
if (filename == NULL)
gk_errexit(SIGERR, "The filename parameter cannot be NULL.\n");
fpout = gk_fopen(filename, "w", "gk_csr_Write: fpout");
numbering = (numbering ? 1 : 0);
for (i=0; i<mat->nrows; i++) {
for (j=mat->rowptr[i]; j<mat->rowptr[i+1]; j++) {
if (writevals)
fprintf(fpout, "%zd %d %.8f\n", i+numbering, mat->rowind[j]+numbering, mat->rowval[j]);
else
fprintf(fpout, "%zd %d\n", i+numbering, mat->rowind[j]+numbering);
}
}
gk_fclose(fpout);
return;
break;
case GK_CSR_FMT_BIJV:
if (filename == NULL)
gk_errexit(SIGERR, "The filename parameter cannot be NULL.\n");
fpout = gk_fopen(filename, "wb", "gk_csr_Write: fpout");
fwrite(&(mat->nrows), sizeof(int32_t), 1, fpout);
fwrite(&(mat->ncols), sizeof(int32_t), 1, fpout);
fwrite(&(mat->rowptr[mat->nrows]), sizeof(size_t), 1, fpout);
fwrite(&writevals, sizeof(int32_t), 1, fpout);
for (i=0; i<mat->nrows; i++) {
edge[0] = i;
for (j=mat->rowptr[i]; j<mat->rowptr[i+1]; j++) {
edge[1] = mat->rowind[j];
fwrite(edge, sizeof(int32_t), 2, fpout);
if (writevals)
fwrite(&(mat->rowval[j]), sizeof(float), 1, fpout);
}
}
gk_fclose(fpout);
return;
break;
default:
if (filename)
fpout = gk_fopen(filename, "w", "gk_csr_Write: fpout");
else
fpout = stdout;
if (format == GK_CSR_FMT_CLUTO) {
fprintf(fpout, "%d %d %zd\n", mat->nrows, mat->ncols, mat->rowptr[mat->nrows]);
writevals = 1;
numbering = 1;
}
for (i=0; i<mat->nrows; i++) {
for (j=mat->rowptr[i]; j<mat->rowptr[i+1]; j++) {
fprintf(fpout, " %d", mat->rowind[j]+(numbering ? 1 : 0));
if (writevals)
fprintf(fpout, " %f", mat->rowval[j]);
}
fprintf(fpout, "\n");
}
if (filename)
gk_fclose(fpout);
}
}
/*************************************************************************/
/*! Prunes certain rows/columns of the matrix. The prunning takes place
by analyzing the row structure of the matrix. The prunning takes place
by removing rows/columns but it does not affect the numbering of the
remaining rows/columns.
\param mat the matrix to be prunned,
\param what indicates if the rows (GK_CSR_ROW) or the columns (GK_CSR_COL)
of the matrix will be prunned,
\param minf is the minimum number of rows (columns) that a column (row) must
be present in order to be kept,
\param maxf is the maximum number of rows (columns) that a column (row) must
be present at in order to be kept.
\returns the prunned matrix consisting only of its row-based structure.
The input matrix is not modified.
*/
/**************************************************************************/
gk_csr_t *gk_csr_Prune(gk_csr_t *mat, int what, int minf, int maxf)
{
ssize_t i, j, nnz;
int nrows, ncols;
ssize_t *rowptr, *nrowptr;
int *rowind, *nrowind, *collen;
float *rowval, *nrowval;
gk_csr_t *nmat;
nmat = gk_csr_Create();
nrows = nmat->nrows = mat->nrows;
ncols = nmat->ncols = mat->ncols;
rowptr = mat->rowptr;
rowind = mat->rowind;
rowval = mat->rowval;
nrowptr = nmat->rowptr = gk_zmalloc(nrows+1, "gk_csr_Prune: nrowptr");
nrowind = nmat->rowind = gk_imalloc(rowptr[nrows], "gk_csr_Prune: nrowind");
nrowval = nmat->rowval = gk_fmalloc(rowptr[nrows], "gk_csr_Prune: nrowval");
switch (what) {
case GK_CSR_COL:
collen = gk_ismalloc(ncols, 0, "gk_csr_Prune: collen");
for (i=0; i<nrows; i++) {
for (j=rowptr[i]; j<rowptr[i+1]; j++) {
ASSERT(rowind[j] < ncols);
collen[rowind[j]]++;
}
}
for (i=0; i<ncols; i++)
collen[i] = (collen[i] >= minf && collen[i] <= maxf ? 1 : 0);
nrowptr[0] = 0;
for (nnz=0, i=0; i<nrows; i++) {
for (j=rowptr[i]; j<rowptr[i+1]; j++) {
if (collen[rowind[j]]) {
nrowind[nnz] = rowind[j];
nrowval[nnz] = rowval[j];
nnz++;
}
}
nrowptr[i+1] = nnz;
}
gk_free((void **)&collen, LTERM);
break;
case GK_CSR_ROW:
nrowptr[0] = 0;
for (nnz=0, i=0; i<nrows; i++) {
if (rowptr[i+1]-rowptr[i] >= minf && rowptr[i+1]-rowptr[i] <= maxf) {