/* glphbm.c */ /*********************************************************************** * This code is part of GLPK (GNU Linear Programming Kit). * * Copyright (C) 2000, 2001, 2002, 2003, 2004, 2005, 2006, 2007, 2008, * 2009, 2010, 2011 Andrew Makhorin, Department for Applied Informatics, * Moscow Aviation Institute, Moscow, Russia. All rights reserved. * E-mail: . * * GLPK 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. * * GLPK 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 GLPK. If not, see . ***********************************************************************/ #define _GLPSTD_ERRNO #define _GLPSTD_STDIO #include "glphbm.h" #include "glpenv.h" /*********************************************************************** * NAME * * hbm_read_mat - read sparse matrix in Harwell-Boeing format * * SYNOPSIS * * #include "glphbm.h" * HBM *hbm_read_mat(const char *fname); * * DESCRIPTION * * The routine hbm_read_mat reads a sparse matrix in the Harwell-Boeing * format from a text file whose name is the character string fname. * * Detailed description of the Harwell-Boeing format recognised by this * routine is given in the following report: * * I.S.Duff, R.G.Grimes, J.G.Lewis. User's Guide for the Harwell-Boeing * Sparse Matrix Collection (Release I), TR/PA/92/86, October 1992. * * RETURNS * * If no error occured, the routine hbm_read_mat returns a pointer to * a data structure containing the matrix. In case of error the routine * prints an appropriate error message and returns NULL. */ struct dsa { /* working area used by routine hbm_read_mat */ const char *fname; /* name of input text file */ FILE *fp; /* stream assigned to input text file */ int seqn; /* card sequential number */ char card[80+1]; /* card image buffer */ int fmt_p; /* scale factor */ int fmt_k; /* iterator */ int fmt_f; /* format code */ int fmt_w; /* field width */ int fmt_d; /* number of decimal places after point */ }; /*********************************************************************** * read_card - read next data card * * This routine reads the next 80-column card from the input text file * and stores its image into the character string card. If the card was * read successfully, the routine returns zero, otherwise non-zero. */ static int read_card(struct dsa *dsa) { int k, c; dsa->seqn++; memset(dsa->card, ' ', 80), dsa->card[80] = '\0'; k = 0; for (;;) { c = fgetc(dsa->fp); if (ferror(dsa->fp)) { xprintf("%s:%d: read error - %s\n", dsa->fname, dsa->seqn, strerror(errno)); return 1; } if (feof(dsa->fp)) { if (k == 0) xprintf("%s:%d: unexpected EOF\n", dsa->fname, dsa->seqn); else xprintf("%s:%d: missing final LF\n", dsa->fname, dsa->seqn); return 1; } if (c == '\r') continue; if (c == '\n') break; if (iscntrl(c)) { xprintf("%s:%d: invalid control character 0x%02X\n", dsa->fname, dsa->seqn, c); return 1; } if (k == 80) { xprintf("%s:%d: card image too long\n", dsa->fname, dsa->seqn); return 1; } dsa->card[k++] = (char)c; } return 0; } /*********************************************************************** * scan_int - scan integer value from the current card * * This routine scans an integer value from the current card, where fld * is the name of the field, pos is the position of the field, width is * the width of the field, val points to a location to which the scanned * value should be stored. If the value was scanned successfully, the * routine returns zero, otherwise non-zero. */ static int scan_int(struct dsa *dsa, char *fld, int pos, int width, int *val) { char str[80+1]; xassert(1 <= width && width <= 80); memcpy(str, dsa->card + pos, width), str[width] = '\0'; if (str2int(strspx(str), val)) { xprintf("%s:%d: field `%s' contains invalid value `%s'\n", dsa->fname, dsa->seqn, fld, str); return 1; } return 0; } /*********************************************************************** * parse_fmt - parse Fortran format specification * * This routine parses the Fortran format specification represented as * character string which fmt points to and stores format elements into * appropriate static locations. Should note that not all valid Fortran * format specifications may be recognised. If the format specification * was recognised, the routine returns zero, otherwise non-zero. */ static int parse_fmt(struct dsa *dsa, char *fmt) { int k, s, val; char str[80+1]; /* first character should be left parenthesis */ if (fmt[0] != '(') fail: { xprintf("hbm_read_mat: format `%s' not recognised\n", fmt); return 1; } k = 1; /* optional scale factor */ dsa->fmt_p = 0; if (isdigit((unsigned char)fmt[k])) { s = 0; while (isdigit((unsigned char)fmt[k])) { if (s == 80) goto fail; str[s++] = fmt[k++]; } str[s] = '\0'; if (str2int(str, &val)) goto fail; if (toupper((unsigned char)fmt[k]) != 'P') goto iter; dsa->fmt_p = val, k++; if (!(0 <= dsa->fmt_p && dsa->fmt_p <= 255)) goto fail; /* optional comma may follow scale factor */ if (fmt[k] == ',') k++; } /* optional iterator */ dsa->fmt_k = 1; if (isdigit((unsigned char)fmt[k])) { s = 0; while (isdigit((unsigned char)fmt[k])) { if (s == 80) goto fail; str[s++] = fmt[k++]; } str[s] = '\0'; if (str2int(str, &val)) goto fail; iter: dsa->fmt_k = val; if (!(1 <= dsa->fmt_k && dsa->fmt_k <= 255)) goto fail; } /* format code */ dsa->fmt_f = toupper((unsigned char)fmt[k++]); if (!(dsa->fmt_f == 'D' || dsa->fmt_f == 'E' || dsa->fmt_f == 'F' || dsa->fmt_f == 'G' || dsa->fmt_f == 'I')) goto fail; /* field width */ if (!isdigit((unsigned char)fmt[k])) goto fail; s = 0; while (isdigit((unsigned char)fmt[k])) { if (s == 80) goto fail; str[s++] = fmt[k++]; } str[s] = '\0'; if (str2int(str, &dsa->fmt_w)) goto fail; if (!(1 <= dsa->fmt_w && dsa->fmt_w <= 255)) goto fail; /* optional number of decimal places after point */ dsa->fmt_d = 0; if (fmt[k] == '.') { k++; if (!isdigit((unsigned char)fmt[k])) goto fail; s = 0; while (isdigit((unsigned char)fmt[k])) { if (s == 80) goto fail; str[s++] = fmt[k++]; } str[s] = '\0'; if (str2int(str, &dsa->fmt_d)) goto fail; if (!(0 <= dsa->fmt_d && dsa->fmt_d <= 255)) goto fail; } /* last character should be right parenthesis */ if (!(fmt[k] == ')' && fmt[k+1] == '\0')) goto fail; return 0; } /*********************************************************************** * read_int_array - read array of integer type * * This routine reads an integer array from the input text file, where * name is array name, fmt is Fortran format specification that controls * reading, n is number of array elements, val is array of integer type. * If the array was read successful, the routine returns zero, otherwise * non-zero. */ static int read_int_array(struct dsa *dsa, char *name, char *fmt, int n, int val[]) { int k, pos; char str[80+1]; if (parse_fmt(dsa, fmt)) return 1; if (!(dsa->fmt_f == 'I' && dsa->fmt_w <= 80 && dsa->fmt_k * dsa->fmt_w <= 80)) { xprintf( "%s:%d: can't read array `%s' - invalid format `%s'\n", dsa->fname, dsa->seqn, name, fmt); return 1; } for (k = 1, pos = INT_MAX; k <= n; k++, pos++) { if (pos >= dsa->fmt_k) { if (read_card(dsa)) return 1; pos = 0; } memcpy(str, dsa->card + dsa->fmt_w * pos, dsa->fmt_w); str[dsa->fmt_w] = '\0'; strspx(str); if (str2int(str, &val[k])) { xprintf( "%s:%d: can't read array `%s' - invalid value `%s'\n", dsa->fname, dsa->seqn, name, str); return 1; } } return 0; } /*********************************************************************** * read_real_array - read array of real type * * This routine reads a real array from the input text file, where name * is array name, fmt is Fortran format specification that controls * reading, n is number of array elements, val is array of real type. * If the array was read successful, the routine returns zero, otherwise * non-zero. */ static int read_real_array(struct dsa *dsa, char *name, char *fmt, int n, double val[]) { int k, pos; char str[80+1], *ptr; if (parse_fmt(dsa, fmt)) return 1; if (!(dsa->fmt_f != 'I' && dsa->fmt_w <= 80 && dsa->fmt_k * dsa->fmt_w <= 80)) { xprintf( "%s:%d: can't read array `%s' - invalid format `%s'\n", dsa->fname, dsa->seqn, name, fmt); return 1; } for (k = 1, pos = INT_MAX; k <= n; k++, pos++) { if (pos >= dsa->fmt_k) { if (read_card(dsa)) return 1; pos = 0; } memcpy(str, dsa->card + dsa->fmt_w * pos, dsa->fmt_w); str[dsa->fmt_w] = '\0'; strspx(str); if (strchr(str, '.') == NULL && strcmp(str, "0")) { xprintf("%s(%d): can't read array `%s' - value `%s' has no " "decimal point\n", dsa->fname, dsa->seqn, name, str); return 1; } /* sometimes lower case letters appear */ for (ptr = str; *ptr; ptr++) *ptr = (char)toupper((unsigned char)*ptr); ptr = strchr(str, 'D'); if (ptr != NULL) *ptr = 'E'; /* value may appear with decimal exponent but without letters E or D (for example, -123.456-012), so missing letter should be inserted */ ptr = strchr(str+1, '+'); if (ptr == NULL) ptr = strchr(str+1, '-'); if (ptr != NULL && *(ptr-1) != 'E') { xassert(strlen(str) < 80); memmove(ptr+1, ptr, strlen(ptr)+1); *ptr = 'E'; } if (str2num(str, &val[k])) { xprintf( "%s:%d: can't read array `%s' - invalid value `%s'\n", dsa->fname, dsa->seqn, name, str); return 1; } } return 0; } HBM *hbm_read_mat(const char *fname) { struct dsa _dsa, *dsa = &_dsa; HBM *hbm = NULL; dsa->fname = fname; xprintf("hbm_read_mat: reading matrix from `%s'...\n", dsa->fname); dsa->fp = fopen(dsa->fname, "r"); if (dsa->fp == NULL) { xprintf("hbm_read_mat: unable to open `%s' - %s\n", dsa->fname, strerror(errno)); goto fail; } dsa->seqn = 0; hbm = xmalloc(sizeof(HBM)); memset(hbm, 0, sizeof(HBM)); /* read the first heading card */ if (read_card(dsa)) goto fail; memcpy(hbm->title, dsa->card, 72), hbm->title[72] = '\0'; strtrim(hbm->title); xprintf("%s\n", hbm->title); memcpy(hbm->key, dsa->card+72, 8), hbm->key[8] = '\0'; strspx(hbm->key); xprintf("key = %s\n", hbm->key); /* read the second heading card */ if (read_card(dsa)) goto fail; if (scan_int(dsa, "totcrd", 0, 14, &hbm->totcrd)) goto fail; if (scan_int(dsa, "ptrcrd", 14, 14, &hbm->ptrcrd)) goto fail; if (scan_int(dsa, "indcrd", 28, 14, &hbm->indcrd)) goto fail; if (scan_int(dsa, "valcrd", 42, 14, &hbm->valcrd)) goto fail; if (scan_int(dsa, "rhscrd", 56, 14, &hbm->rhscrd)) goto fail; xprintf("totcrd = %d; ptrcrd = %d; indcrd = %d; valcrd = %d; rhsc" "rd = %d\n", hbm->totcrd, hbm->ptrcrd, hbm->indcrd, hbm->valcrd, hbm->rhscrd); /* read the third heading card */ if (read_card(dsa)) goto fail; memcpy(hbm->mxtype, dsa->card, 3), hbm->mxtype[3] = '\0'; if (strchr("RCP", hbm->mxtype[0]) == NULL || strchr("SUHZR", hbm->mxtype[1]) == NULL || strchr("AE", hbm->mxtype[2]) == NULL) { xprintf("%s:%d: matrix type `%s' not recognised\n", dsa->fname, dsa->seqn, hbm->mxtype); goto fail; } if (scan_int(dsa, "nrow", 14, 14, &hbm->nrow)) goto fail; if (scan_int(dsa, "ncol", 28, 14, &hbm->ncol)) goto fail; if (scan_int(dsa, "nnzero", 42, 14, &hbm->nnzero)) goto fail; if (scan_int(dsa, "neltvl", 56, 14, &hbm->neltvl)) goto fail; xprintf("mxtype = %s; nrow = %d; ncol = %d; nnzero = %d; neltvl =" " %d\n", hbm->mxtype, hbm->nrow, hbm->ncol, hbm->nnzero, hbm->neltvl); /* read the fourth heading card */ if (read_card(dsa)) goto fail; memcpy(hbm->ptrfmt, dsa->card, 16), hbm->ptrfmt[16] = '\0'; strspx(hbm->ptrfmt); memcpy(hbm->indfmt, dsa->card+16, 16), hbm->indfmt[16] = '\0'; strspx(hbm->indfmt); memcpy(hbm->valfmt, dsa->card+32, 20), hbm->valfmt[20] = '\0'; strspx(hbm->valfmt); memcpy(hbm->rhsfmt, dsa->card+52, 20), hbm->rhsfmt[20] = '\0'; strspx(hbm->rhsfmt); xprintf("ptrfmt = %s; indfmt = %s; valfmt = %s; rhsfmt = %s\n", hbm->ptrfmt, hbm->indfmt, hbm->valfmt, hbm->rhsfmt); /* read the fifth heading card (optional) */ if (hbm->rhscrd <= 0) { strcpy(hbm->rhstyp, "???"); hbm->nrhs = 0; hbm->nrhsix = 0; } else { if (read_card(dsa)) goto fail; memcpy(hbm->rhstyp, dsa->card, 3), hbm->rhstyp[3] = '\0'; if (scan_int(dsa, "nrhs", 14, 14, &hbm->nrhs)) goto fail; if (scan_int(dsa, "nrhsix", 28, 14, &hbm->nrhsix)) goto fail; xprintf("rhstyp = `%s'; nrhs = %d; nrhsix = %d\n", hbm->rhstyp, hbm->nrhs, hbm->nrhsix); } /* read matrix structure */ hbm->colptr = xcalloc(1+hbm->ncol+1, sizeof(int)); if (read_int_array(dsa, "colptr", hbm->ptrfmt, hbm->ncol+1, hbm->colptr)) goto fail; hbm->rowind = xcalloc(1+hbm->nnzero, sizeof(int)); if (read_int_array(dsa, "rowind", hbm->indfmt, hbm->nnzero, hbm->rowind)) goto fail; /* read matrix values */ if (hbm->valcrd <= 0) goto done; if (hbm->mxtype[2] == 'A') { /* assembled matrix */ hbm->values = xcalloc(1+hbm->nnzero, sizeof(double)); if (read_real_array(dsa, "values", hbm->valfmt, hbm->nnzero, hbm->values)) goto fail; } else { /* elemental (unassembled) matrix */ hbm->values = xcalloc(1+hbm->neltvl, sizeof(double)); if (read_real_array(dsa, "values", hbm->valfmt, hbm->neltvl, hbm->values)) goto fail; } /* read right-hand sides */ if (hbm->nrhs <= 0) goto done; if (hbm->rhstyp[0] == 'F') { /* dense format */ hbm->nrhsvl = hbm->nrow * hbm->nrhs; hbm->rhsval = xcalloc(1+hbm->nrhsvl, sizeof(double)); if (read_real_array(dsa, "rhsval", hbm->rhsfmt, hbm->nrhsvl, hbm->rhsval)) goto fail; } else if (hbm->rhstyp[0] == 'M' && hbm->mxtype[2] == 'A') { /* sparse format */ /* read pointers */ hbm->rhsptr = xcalloc(1+hbm->nrhs+1, sizeof(int)); if (read_int_array(dsa, "rhsptr", hbm->ptrfmt, hbm->nrhs+1, hbm->rhsptr)) goto fail; /* read sparsity pattern */ hbm->rhsind = xcalloc(1+hbm->nrhsix, sizeof(int)); if (read_int_array(dsa, "rhsind", hbm->indfmt, hbm->nrhsix, hbm->rhsind)) goto fail; /* read values */ hbm->rhsval = xcalloc(1+hbm->nrhsix, sizeof(double)); if (read_real_array(dsa, "rhsval", hbm->rhsfmt, hbm->nrhsix, hbm->rhsval)) goto fail; } else if (hbm->rhstyp[0] == 'M' && hbm->mxtype[2] == 'E') { /* elemental format */ hbm->rhsval = xcalloc(1+hbm->nrhsvl, sizeof(double)); if (read_real_array(dsa, "rhsval", hbm->rhsfmt, hbm->nrhsvl, hbm->rhsval)) goto fail; } else { xprintf("%s:%d: right-hand side type `%c' not recognised\n", dsa->fname, dsa->seqn, hbm->rhstyp[0]); goto fail; } /* read starting guesses */ if (hbm->rhstyp[1] == 'G') { hbm->nguess = hbm->nrow * hbm->nrhs; hbm->sguess = xcalloc(1+hbm->nguess, sizeof(double)); if (read_real_array(dsa, "sguess", hbm->rhsfmt, hbm->nguess, hbm->sguess)) goto fail; } /* read solution vectors */ if (hbm->rhstyp[2] == 'X') { hbm->nexact = hbm->nrow * hbm->nrhs; hbm->xexact = xcalloc(1+hbm->nexact, sizeof(double)); if (read_real_array(dsa, "xexact", hbm->rhsfmt, hbm->nexact, hbm->xexact)) goto fail; } done: /* reading has been completed */ xprintf("hbm_read_mat: %d cards were read\n", dsa->seqn); fclose(dsa->fp); return hbm; fail: /* something wrong in Danish kingdom */ if (hbm != NULL) { if (hbm->colptr != NULL) xfree(hbm->colptr); if (hbm->rowind != NULL) xfree(hbm->rowind); if (hbm->rhsptr != NULL) xfree(hbm->rhsptr); if (hbm->rhsind != NULL) xfree(hbm->rhsind); if (hbm->values != NULL) xfree(hbm->values); if (hbm->rhsval != NULL) xfree(hbm->rhsval); if (hbm->sguess != NULL) xfree(hbm->sguess); if (hbm->xexact != NULL) xfree(hbm->xexact); xfree(hbm); } if (dsa->fp != NULL) fclose(dsa->fp); return NULL; } /*********************************************************************** * NAME * * hbm_free_mat - free sparse matrix in Harwell-Boeing format * * SYNOPSIS * * #include "glphbm.h" * void hbm_free_mat(HBM *hbm); * * DESCRIPTION * * The hbm_free_mat routine frees all the memory allocated to the data * structure containing a sparse matrix in the Harwell-Boeing format. */ void hbm_free_mat(HBM *hbm) { if (hbm->colptr != NULL) xfree(hbm->colptr); if (hbm->rowind != NULL) xfree(hbm->rowind); if (hbm->rhsptr != NULL) xfree(hbm->rhsptr); if (hbm->rhsind != NULL) xfree(hbm->rhsind); if (hbm->values != NULL) xfree(hbm->values); if (hbm->rhsval != NULL) xfree(hbm->rhsval); if (hbm->sguess != NULL) xfree(hbm->sguess); if (hbm->xexact != NULL) xfree(hbm->xexact); xfree(hbm); return; } /* eof */