MultiSource/Benchmarks/MallocBench/espresso/matrix.c - third_party/llvm-test-suite - Git at Google

 #include "port.h"
 #include "sparse_int.h"

 /*
  *  free-lists are only used if 'FAST_AND_LOOSE' is set; this is because
  *  we lose the debugging capability of libmm_t which trashes objects when
  *  they are free'd.  However, FAST_AND_LOOSE is much faster if matrices
  *  are created and freed frequently.
  */

 #ifdef FAST_AND_LOOSE
 sm_element *sm_element_freelist;
 sm_row *sm_row_freelist;
 sm_col *sm_col_freelist;
 #endif


 sm_matrix *
 sm_alloc()
 {
     register sm_matrix *A;

     A = ALLOC(sm_matrix, 1);
     A->rows = NIL(sm_row *);
     A->cols = NIL(sm_col *);
     A->nrows = A->ncols = 0;
     A->rows_size = A->cols_size = 0;
     A->first_row = A->last_row = NIL(sm_row);
     A->first_col = A->last_col = NIL(sm_col);
     A->user_word = NIL(char);		/* for our user ... */
     return A;
 }


 sm_matrix *
 sm_alloc_size(row, col)
 int row, col;
 {
     register sm_matrix *A;

     A = sm_alloc();
     sm_resize(A, row, col);
     return A;
 }


 void
 sm_free(A)
 sm_matrix *A;
 {
 #ifdef FAST_AND_LOOSE
     register sm_row *prow;

     if (A->first_row != 0) {
 	for(prow = A->first_row; prow != 0; prow = prow->next_row) {
 	    /* add the elements to the free list of elements */
 	    prow->last_col->next_col = sm_element_freelist;
 	    sm_element_freelist = prow->first_col;
 	}

 	/* Add the linked list of rows to the row-free-list */
 	A->last_row->next_row = sm_row_freelist;
 	sm_row_freelist = A->first_row;

 	/* Add the linked list of cols to the col-free-list */
 	A->last_col->next_col = sm_col_freelist;
 	sm_col_freelist = A->first_col;
     }
 #else
     register sm_row *prow, *pnext_row;
     register sm_col *pcol, *pnext_col;

     for(prow = A->first_row; prow != 0; prow = pnext_row) {
 	pnext_row = prow->next_row;
 	sm_row_free(prow);
     }
     for(pcol = A->first_col; pcol != 0; pcol = pnext_col) {
 	pnext_col = pcol->next_col;
 	pcol->first_row = pcol->last_row = NIL(sm_element);
 	sm_col_free(pcol);
     }
 #endif

     /* Free the arrays to map row/col numbers into pointers */
     FREE(A->rows);
     FREE(A->cols);
     FREE(A);
 }


 sm_matrix *
 sm_dup(A)
 sm_matrix *A;
 {
     register sm_row *prow;
     register sm_element *p;
     register sm_matrix *B;

     B = sm_alloc();
     if (A->last_row != 0) {
 	sm_resize(B, A->last_row->row_num, A->last_col->col_num);
 	for(prow = A->first_row; prow != 0; prow = prow->next_row) {
 	    for(p = prow->first_col; p != 0; p = p->next_col) {
 		(void) sm_insert(B, p->row_num, p->col_num);
 	    }
 	}
     }
     return B;
 }


 void
 sm_resize(A, row, col)
 register sm_matrix *A;
 int row, col;
 {
     register int i, new_size;

     if (row >= A->rows_size) {
 	new_size = MAX(A->rows_size*2, row+1);
 	A->rows = REALLOC(sm_row *, A->rows, new_size);
 	for(i = A->rows_size; i < new_size; i++) {
 	    A->rows[i] = NIL(sm_row);
 	}
 	A->rows_size = new_size;
     }

     if (col >= A->cols_size) {
 	new_size = MAX(A->cols_size*2, col+1);
 	A->cols = REALLOC(sm_col *, A->cols, new_size);
 	for(i = A->cols_size; i < new_size; i++) {
 	    A->cols[i] = NIL(sm_col);
 	}
 	A->cols_size = new_size;
     }
 }


 /*
  *  insert -- insert a value into the matrix
  */
 sm_element *
 sm_insert(A, row, col)
 register sm_matrix *A;
 register int row, col;
 {
     register sm_row *prow;
     register sm_col *pcol;
     register sm_element *element;
     sm_element *save_element;

     if (row >= A->rows_size || col >= A->cols_size) {
 	sm_resize(A, row, col);
     }

     prow = A->rows[row];
     if (prow == NIL(sm_row)) {
 	prow = A->rows[row] = sm_row_alloc();
 	prow->row_num = row;
 	sorted_insert(sm_row, A->first_row, A->last_row, A->nrows,
 			next_row, prev_row, row_num, row, prow);
     }

     pcol = A->cols[col];
     if (pcol == NIL(sm_col)) {
 	pcol = A->cols[col] = sm_col_alloc();
 	pcol->col_num = col;
 	sorted_insert(sm_col, A->first_col, A->last_col, A->ncols,
 			next_col, prev_col, col_num, col, pcol);
     }

     /* get a new item, save its address */
     sm_element_alloc(element);
     save_element = element;

     /* insert it into the row list */
     sorted_insert(sm_element, prow->first_col, prow->last_col,
 		prow->length, next_col, prev_col, col_num, col, element);

     /* if it was used, also insert it into the column list */
     if (element == save_element) {
 	sorted_insert(sm_element, pcol->first_row, pcol->last_row,
 		pcol->length, next_row, prev_row, row_num, row, element);
     } else {
 	/* otherwise, it was already in matrix -- free element we allocated */
 	sm_element_free(save_element);
     }
     return element;
 }


 sm_element *
 sm_find(A, rownum, colnum)
 sm_matrix *A;
 int rownum, colnum;
 {
     sm_row *prow;
     sm_col *pcol;

     prow = sm_get_row(A, rownum);
     if (prow == NIL(sm_row)) {
 	return NIL(sm_element);
     } else {
 	pcol = sm_get_col(A, colnum);
 	if (pcol == NIL(sm_col)) {
 	    return NIL(sm_element);
 	}
 	if (prow->length < pcol->length) {
 	    return sm_row_find(prow, colnum);
 	} else {
 	    return sm_col_find(pcol, rownum);
 	}
     }
 }


 void
 sm_remove(A, rownum, colnum)
 sm_matrix *A;
 int rownum, colnum;
 {
     sm_remove_element(A, sm_find(A, rownum, colnum));
 }


 void
 sm_remove_element(A, p)
 register sm_matrix *A;
 register sm_element *p;
 {
     register sm_row *prow;
     register sm_col *pcol;

     if (p == 0) return;

     /* Unlink the element from its row */
     prow = sm_get_row(A, p->row_num);
     dll_unlink(p, prow->first_col, prow->last_col,
 			next_col, prev_col, prow->length);

     /* if no more elements in the row, discard the row header */
     if (prow->first_col == NIL(sm_element)) {
 	sm_delrow(A, p->row_num);
     }

     /* Unlink the element from its column */
     pcol = sm_get_col(A, p->col_num);
     dll_unlink(p, pcol->first_row, pcol->last_row,
 			next_row, prev_row, pcol->length);

     /* if no more elements in the column, discard the column header */
     if (pcol->first_row == NIL(sm_element)) {
 	sm_delcol(A, p->col_num);
     }

     sm_element_free(p);
 }

 void
 sm_delrow(A, i)
 sm_matrix *A;
 int i;
 {
     register sm_element *p, *pnext;
     sm_col *pcol;
     sm_row *prow;

     prow = sm_get_row(A, i);
     if (prow != NIL(sm_row)) {
 	/* walk across the row */
 	for(p = prow->first_col; p != 0; p = pnext) {
 	    pnext = p->next_col;

 	    /* unlink the item from the column (and delete it) */
 	    pcol = sm_get_col(A, p->col_num);
 	    sm_col_remove_element(pcol, p);

 	    /* discard the column if it is now empty */
 	    if (pcol->first_row == NIL(sm_element)) {
 		sm_delcol(A, pcol->col_num);
 	    }
 	}

 	/* discard the row -- we already threw away the elements */
 	A->rows[i] = NIL(sm_row);
 	dll_unlink(prow, A->first_row, A->last_row,
 				next_row, prev_row, A->nrows);
 	prow->first_col = prow->last_col = NIL(sm_element);
 	sm_row_free(prow);
     }
 }

 void
 sm_delcol(A, i)
 sm_matrix *A;
 int i;
 {
     register sm_element *p, *pnext;
     sm_row *prow;
     sm_col *pcol;

     pcol = sm_get_col(A, i);
     if (pcol != NIL(sm_col)) {
 	/* walk down the column */
 	for(p = pcol->first_row; p != 0; p = pnext) {
 	    pnext = p->next_row;

 	    /* unlink the element from the row (and delete it) */
 	    prow = sm_get_row(A, p->row_num);
 	    sm_row_remove_element(prow, p);

 	    /* discard the row if it is now empty */
 	    if (prow->first_col == NIL(sm_element)) {
 		sm_delrow(A, prow->row_num);
 	    }
 	}

 	/* discard the column -- we already threw away the elements */
 	A->cols[i] = NIL(sm_col);
 	dll_unlink(pcol, A->first_col, A->last_col,
 			    next_col, prev_col, A->ncols);
 	pcol->first_row = pcol->last_row = NIL(sm_element);
 	sm_col_free(pcol);
     }
 }

 void
 sm_copy_row(dest, dest_row, prow)
 register sm_matrix *dest;
 int dest_row;
 sm_row *prow;
 {
     register sm_element *p;

     for(p = prow->first_col; p != 0; p = p->next_col) {
 	(void) sm_insert(dest, dest_row, p->col_num);
     }
 }


 void
 sm_copy_col(dest, dest_col, pcol)
 register sm_matrix *dest;
 int dest_col;
 sm_col *pcol;
 {
     register sm_element *p;

     for(p = pcol->first_row; p != 0; p = p->next_row) {
 	(void) sm_insert(dest, dest_col, p->row_num);
     }
 }


 sm_row *
 sm_longest_row(A)
 sm_matrix *A;
 {
     register sm_row *large_row, *prow;
     register int max_length;

     max_length = 0;
     large_row = NIL(sm_row);
     for(prow = A->first_row; prow != 0; prow = prow->next_row) {
 	if (prow->length > max_length) {
 	    max_length = prow->length;
 	    large_row = prow;
 	}
     }
     return large_row;
 }


 sm_col *
 sm_longest_col(A)
 sm_matrix *A;
 {
     register sm_col *large_col, *pcol;
     register int max_length;

     max_length = 0;
     large_col = NIL(sm_col);
     for(pcol = A->first_col; pcol != 0; pcol = pcol->next_col) {
 	if (pcol->length > max_length) {
 	    max_length = pcol->length;
 	    large_col = pcol;
 	}
     }
     return large_col;
 }

 int
 sm_num_elements(A)
 sm_matrix *A;
 {
     register sm_row *prow;
     register int num;

     num = 0;
     sm_foreach_row(A, prow) {
 	num += prow->length;
     }
     return num;
 }

 int
 sm_read(fp, A)
 FILE *fp;
 sm_matrix **A;
 {
     int i, j, err;

     *A = sm_alloc();
     while (! feof(fp)) {
 	err = fscanf(fp, "%d %d", &i, &j);
 	if (err == EOF) {
 	    return 1;
 	} else if (err != 2) {
 	    return 0;
 	}
 	(void) sm_insert(*A, i, j);
     }
     return 1;
 }


 int
 sm_read_compressed(fp, A)
 FILE *fp;
 sm_matrix **A;
 {
     int i, j, k, nrows, ncols;
     unsigned long x;

     *A = sm_alloc();
     if (fscanf(fp, "%d %d", &nrows, &ncols) != 2) {
 	return 0;
     }
     sm_resize(*A, nrows, ncols);

     for(i = 0; i < nrows; i++) {
 	if (fscanf(fp, "%lx", &x) != 1) {
 	    return 0;
 	}
 	for(j = 0; j < ncols; j += 32) {
 	    if (fscanf(fp, "%lx", &x) != 1) {
 		return 0;
 	    }
 	    for(k = j; x != 0; x >>= 1, k++) {
 		if (x & 1) {
 		    (void) sm_insert(*A, i, k);
 		}
 	    }
 	}
     }
     return 1;
 }


 void
 sm_write(fp, A)
 FILE *fp;
 sm_matrix *A;
 {
     register sm_row *prow;
     register sm_element *p;

     for(prow = A->first_row; prow != 0; prow = prow->next_row) {
 	for(p = prow->first_col; p != 0; p = p->next_col) {
 	    (void) fprintf(fp, "%d %d\n", p->row_num, p->col_num);
 	}
     }
 }

 void
 sm_print(fp, A)
 FILE *fp;
 sm_matrix *A;
 {
     register sm_row *prow;
     register sm_col *pcol;
     int c;

     if (A->last_col->col_num >= 100) {
 	(void) fprintf(fp, "    ");
 	for(pcol = A->first_col; pcol != 0; pcol = pcol->next_col) {
 	    (void) fprintf(fp, "%d", (pcol->col_num / 100)%10);
 	}
 	putc('\n', fp);
     }

     if (A->last_col->col_num >= 10) {
 	(void) fprintf(fp, "    ");
 	for(pcol = A->first_col; pcol != 0; pcol = pcol->next_col) {
 	    (void) fprintf(fp, "%d", (pcol->col_num / 10)%10);
 	}
 	putc('\n', fp);
     }

     (void) fprintf(fp, "    ");
     for(pcol = A->first_col; pcol != 0; pcol = pcol->next_col) {
 	(void) fprintf(fp, "%d", pcol->col_num % 10);
     }
     putc('\n', fp);

     (void) fprintf(fp, "    ");
     for(pcol = A->first_col; pcol != 0; pcol = pcol->next_col) {
 	(void) fprintf(fp, "-");
     }
     putc('\n', fp);

     for(prow = A->first_row; prow != 0; prow = prow->next_row) {
 	(void) fprintf(fp, "%3d:", prow->row_num);

 	for(pcol = A->first_col; pcol != 0; pcol = pcol->next_col) {
 	    c = sm_row_find(prow, pcol->col_num) ? '1' : '.';
 	    putc(c, fp);
 	}
 	putc('\n', fp);
     }
 }


 void
 sm_dump(A, s, max)
 sm_matrix *A;
 char *s;
 int max;
 {
     FILE *fp = stdout;

     (void) fprintf(fp, "%s %d rows by %d cols\n", s, A->nrows, A->ncols);
     if (A->nrows < max) {
 	sm_print(fp, A);
     }
 }

 void
 sm_cleanup()
 {
 #ifdef FAST_AND_LOOSE
     register sm_element *p, *pnext;
     register sm_row *prow, *pnextrow;
     register sm_col *pcol, *pnextcol;

     for(p = sm_element_freelist; p != 0; p = pnext) {
 	pnext = p->next_col;
 	FREE(p);
     }
     sm_element_freelist = 0;

     for(prow = sm_row_freelist; prow != 0; prow = pnextrow) {
 	pnextrow = prow->next_row;
 	FREE(prow);
     }
     sm_row_freelist = 0;

     for(pcol = sm_col_freelist; pcol != 0; pcol = pnextcol) {
 	pnextcol = pcol->next_col;
 	FREE(pcol);
     }
     sm_col_freelist = 0;
 #endif
 }
	#include "port.h"
	#include "sparse_int.h"

	/*
	* free-lists are only used if 'FAST_AND_LOOSE' is set; this is because
	* we lose the debugging capability of libmm_t which trashes objects when
	* they are free'd. However, FAST_AND_LOOSE is much faster if matrices
	* are created and freed frequently.
	*/

	#ifdef FAST_AND_LOOSE
	sm_element *sm_element_freelist;
	sm_row *sm_row_freelist;
	sm_col *sm_col_freelist;
	#endif


	sm_matrix *
	sm_alloc()
	{
	register sm_matrix *A;

	A = ALLOC(sm_matrix, 1);
	A->rows = NIL(sm_row *);
	A->cols = NIL(sm_col *);
	A->nrows = A->ncols = 0;
	A->rows_size = A->cols_size = 0;
	A->first_row = A->last_row = NIL(sm_row);
	A->first_col = A->last_col = NIL(sm_col);
	A->user_word = NIL(char); /* for our user ... */
	return A;
	}


	sm_matrix *
	sm_alloc_size(row, col)
	int row, col;
	{
	register sm_matrix *A;

	A = sm_alloc();
	sm_resize(A, row, col);
	return A;
	}


	void
	sm_free(A)
	sm_matrix *A;
	{
	#ifdef FAST_AND_LOOSE
	register sm_row *prow;

	if (A->first_row != 0) {
	for(prow = A->first_row; prow != 0; prow = prow->next_row) {
	/* add the elements to the free list of elements */
	prow->last_col->next_col = sm_element_freelist;
	sm_element_freelist = prow->first_col;
	}

	/* Add the linked list of rows to the row-free-list */
	A->last_row->next_row = sm_row_freelist;
	sm_row_freelist = A->first_row;

	/* Add the linked list of cols to the col-free-list */
	A->last_col->next_col = sm_col_freelist;
	sm_col_freelist = A->first_col;
	}
	#else
	register sm_row prow, pnext_row;
	register sm_col pcol, pnext_col;

	for(prow = A->first_row; prow != 0; prow = pnext_row) {
	pnext_row = prow->next_row;
	sm_row_free(prow);
	}
	for(pcol = A->first_col; pcol != 0; pcol = pnext_col) {
	pnext_col = pcol->next_col;
	pcol->first_row = pcol->last_row = NIL(sm_element);
	sm_col_free(pcol);
	}
	#endif

	/* Free the arrays to map row/col numbers into pointers */
	FREE(A->rows);
	FREE(A->cols);
	FREE(A);
	}


	sm_matrix *
	sm_dup(A)
	sm_matrix *A;
	{
	register sm_row *prow;
	register sm_element *p;
	register sm_matrix *B;

	B = sm_alloc();
	if (A->last_row != 0) {
	sm_resize(B, A->last_row->row_num, A->last_col->col_num);
	for(prow = A->first_row; prow != 0; prow = prow->next_row) {
	for(p = prow->first_col; p != 0; p = p->next_col) {
	(void) sm_insert(B, p->row_num, p->col_num);
	}
	}
	}
	return B;
	}


	void
	sm_resize(A, row, col)
	register sm_matrix *A;
	int row, col;
	{
	register int i, new_size;

	if (row >= A->rows_size) {
	new_size = MAX(A->rows_size*2, row+1);
	A->rows = REALLOC(sm_row *, A->rows, new_size);
	for(i = A->rows_size; i < new_size; i++) {
	A->rows[i] = NIL(sm_row);
	}
	A->rows_size = new_size;
	}

	if (col >= A->cols_size) {
	new_size = MAX(A->cols_size*2, col+1);
	A->cols = REALLOC(sm_col *, A->cols, new_size);
	for(i = A->cols_size; i < new_size; i++) {
	A->cols[i] = NIL(sm_col);
	}
	A->cols_size = new_size;
	}
	}


	/*
	* insert -- insert a value into the matrix
	*/
	sm_element *
	sm_insert(A, row, col)
	register sm_matrix *A;
	register int row, col;
	{
	register sm_row *prow;
	register sm_col *pcol;
	register sm_element *element;
	sm_element *save_element;

	if (row >= A->rows_size \|\| col >= A->cols_size) {
	sm_resize(A, row, col);
	}

	prow = A->rows[row];
	if (prow == NIL(sm_row)) {
	prow = A->rows[row] = sm_row_alloc();
	prow->row_num = row;
	sorted_insert(sm_row, A->first_row, A->last_row, A->nrows,
	next_row, prev_row, row_num, row, prow);
	}

	pcol = A->cols[col];
	if (pcol == NIL(sm_col)) {
	pcol = A->cols[col] = sm_col_alloc();
	pcol->col_num = col;
	sorted_insert(sm_col, A->first_col, A->last_col, A->ncols,
	next_col, prev_col, col_num, col, pcol);
	}

	/* get a new item, save its address */
	sm_element_alloc(element);
	save_element = element;

	/* insert it into the row list */
	sorted_insert(sm_element, prow->first_col, prow->last_col,
	prow->length, next_col, prev_col, col_num, col, element);

	/* if it was used, also insert it into the column list */
	if (element == save_element) {
	sorted_insert(sm_element, pcol->first_row, pcol->last_row,
	pcol->length, next_row, prev_row, row_num, row, element);
	} else {
	/* otherwise, it was already in matrix -- free element we allocated */
	sm_element_free(save_element);
	}
	return element;
	}


	sm_element *
	sm_find(A, rownum, colnum)
	sm_matrix *A;
	int rownum, colnum;
	{
	sm_row *prow;
	sm_col *pcol;

	prow = sm_get_row(A, rownum);
	if (prow == NIL(sm_row)) {
	return NIL(sm_element);
	} else {
	pcol = sm_get_col(A, colnum);
	if (pcol == NIL(sm_col)) {
	return NIL(sm_element);
	}
	if (prow->length < pcol->length) {
	return sm_row_find(prow, colnum);
	} else {
	return sm_col_find(pcol, rownum);
	}
	}
	}


	void
	sm_remove(A, rownum, colnum)
	sm_matrix *A;
	int rownum, colnum;
	{
	sm_remove_element(A, sm_find(A, rownum, colnum));
	}



	void
	sm_remove_element(A, p)
	register sm_matrix *A;
	register sm_element *p;
	{
	register sm_row *prow;
	register sm_col *pcol;

	if (p == 0) return;

	/* Unlink the element from its row */
	prow = sm_get_row(A, p->row_num);
	dll_unlink(p, prow->first_col, prow->last_col,
	next_col, prev_col, prow->length);

	/* if no more elements in the row, discard the row header */
	if (prow->first_col == NIL(sm_element)) {
	sm_delrow(A, p->row_num);
	}

	/* Unlink the element from its column */
	pcol = sm_get_col(A, p->col_num);
	dll_unlink(p, pcol->first_row, pcol->last_row,
	next_row, prev_row, pcol->length);

	/* if no more elements in the column, discard the column header */
	if (pcol->first_row == NIL(sm_element)) {
	sm_delcol(A, p->col_num);
	}

	sm_element_free(p);
	}

	void
	sm_delrow(A, i)
	sm_matrix *A;
	int i;
	{
	register sm_element p, pnext;
	sm_col *pcol;
	sm_row *prow;

	prow = sm_get_row(A, i);
	if (prow != NIL(sm_row)) {
	/* walk across the row */
	for(p = prow->first_col; p != 0; p = pnext) {
	pnext = p->next_col;

	/* unlink the item from the column (and delete it) */
	pcol = sm_get_col(A, p->col_num);
	sm_col_remove_element(pcol, p);

	/* discard the column if it is now empty */
	if (pcol->first_row == NIL(sm_element)) {
	sm_delcol(A, pcol->col_num);
	}
	}

	/* discard the row -- we already threw away the elements */
	A->rows[i] = NIL(sm_row);
	dll_unlink(prow, A->first_row, A->last_row,
	next_row, prev_row, A->nrows);
	prow->first_col = prow->last_col = NIL(sm_element);
	sm_row_free(prow);
	}
	}

	void
	sm_delcol(A, i)
	sm_matrix *A;
	int i;
	{
	register sm_element p, pnext;
	sm_row *prow;
	sm_col *pcol;

	pcol = sm_get_col(A, i);
	if (pcol != NIL(sm_col)) {
	/* walk down the column */
	for(p = pcol->first_row; p != 0; p = pnext) {
	pnext = p->next_row;

	/* unlink the element from the row (and delete it) */
	prow = sm_get_row(A, p->row_num);
	sm_row_remove_element(prow, p);

	/* discard the row if it is now empty */
	if (prow->first_col == NIL(sm_element)) {
	sm_delrow(A, prow->row_num);
	}
	}

	/* discard the column -- we already threw away the elements */
	A->cols[i] = NIL(sm_col);
	dll_unlink(pcol, A->first_col, A->last_col,
	next_col, prev_col, A->ncols);
	pcol->first_row = pcol->last_row = NIL(sm_element);
	sm_col_free(pcol);
	}
	}

	void
	sm_copy_row(dest, dest_row, prow)
	register sm_matrix *dest;
	int dest_row;
	sm_row *prow;
	{
	register sm_element *p;

	for(p = prow->first_col; p != 0; p = p->next_col) {
	(void) sm_insert(dest, dest_row, p->col_num);
	}
	}


	void
	sm_copy_col(dest, dest_col, pcol)
	register sm_matrix *dest;
	int dest_col;
	sm_col *pcol;
	{
	register sm_element *p;

	for(p = pcol->first_row; p != 0; p = p->next_row) {
	(void) sm_insert(dest, dest_col, p->row_num);
	}
	}


	sm_row *
	sm_longest_row(A)
	sm_matrix *A;
	{
	register sm_row large_row, prow;
	register int max_length;

	max_length = 0;
	large_row = NIL(sm_row);
	for(prow = A->first_row; prow != 0; prow = prow->next_row) {
	if (prow->length > max_length) {
	max_length = prow->length;
	large_row = prow;
	}
	}
	return large_row;
	}


	sm_col *
	sm_longest_col(A)
	sm_matrix *A;
	{
	register sm_col large_col, pcol;
	register int max_length;

	max_length = 0;
	large_col = NIL(sm_col);
	for(pcol = A->first_col; pcol != 0; pcol = pcol->next_col) {
	if (pcol->length > max_length) {
	max_length = pcol->length;
	large_col = pcol;
	}
	}
	return large_col;
	}

	int
	sm_num_elements(A)
	sm_matrix *A;
	{
	register sm_row *prow;
	register int num;

	num = 0;
	sm_foreach_row(A, prow) {
	num += prow->length;
	}
	return num;
	}

	int
	sm_read(fp, A)
	FILE *fp;
	sm_matrix **A;
	{
	int i, j, err;

	*A = sm_alloc();
	while (! feof(fp)) {
	err = fscanf(fp, "%d %d", &i, &j);
	if (err == EOF) {
	return 1;
	} else if (err != 2) {
	return 0;
	}
	(void) sm_insert(*A, i, j);
	}
	return 1;
	}


	int
	sm_read_compressed(fp, A)
	FILE *fp;
	sm_matrix **A;
	{
	int i, j, k, nrows, ncols;
	unsigned long x;

	*A = sm_alloc();
	if (fscanf(fp, "%d %d", &nrows, &ncols) != 2) {
	return 0;
	}
	sm_resize(*A, nrows, ncols);

	for(i = 0; i < nrows; i++) {
	if (fscanf(fp, "%lx", &x) != 1) {
	return 0;
	}
	for(j = 0; j < ncols; j += 32) {
	if (fscanf(fp, "%lx", &x) != 1) {
	return 0;
	}
	for(k = j; x != 0; x >>= 1, k++) {
	if (x & 1) {
	(void) sm_insert(*A, i, k);
	}
	}
	}
	}
	return 1;
	}


	void
	sm_write(fp, A)
	FILE *fp;
	sm_matrix *A;
	{
	register sm_row *prow;
	register sm_element *p;

	for(prow = A->first_row; prow != 0; prow = prow->next_row) {
	for(p = prow->first_col; p != 0; p = p->next_col) {
	(void) fprintf(fp, "%d %d\n", p->row_num, p->col_num);
	}
	}
	}

	void
	sm_print(fp, A)
	FILE *fp;
	sm_matrix *A;
	{
	register sm_row *prow;
	register sm_col *pcol;
	int c;

	if (A->last_col->col_num >= 100) {
	(void) fprintf(fp, " ");
	for(pcol = A->first_col; pcol != 0; pcol = pcol->next_col) {
	(void) fprintf(fp, "%d", (pcol->col_num / 100)%10);
	}
	putc('\n', fp);
	}

	if (A->last_col->col_num >= 10) {
	(void) fprintf(fp, " ");
	for(pcol = A->first_col; pcol != 0; pcol = pcol->next_col) {
	(void) fprintf(fp, "%d", (pcol->col_num / 10)%10);
	}
	putc('\n', fp);
	}

	(void) fprintf(fp, " ");
	for(pcol = A->first_col; pcol != 0; pcol = pcol->next_col) {
	(void) fprintf(fp, "%d", pcol->col_num % 10);
	}
	putc('\n', fp);

	(void) fprintf(fp, " ");
	for(pcol = A->first_col; pcol != 0; pcol = pcol->next_col) {
	(void) fprintf(fp, "-");
	}
	putc('\n', fp);

	for(prow = A->first_row; prow != 0; prow = prow->next_row) {
	(void) fprintf(fp, "%3d:", prow->row_num);

	for(pcol = A->first_col; pcol != 0; pcol = pcol->next_col) {
	c = sm_row_find(prow, pcol->col_num) ? '1' : '.';
	putc(c, fp);
	}
	putc('\n', fp);
	}
	}


	void
	sm_dump(A, s, max)
	sm_matrix *A;
	char *s;
	int max;
	{
	FILE *fp = stdout;

	(void) fprintf(fp, "%s %d rows by %d cols\n", s, A->nrows, A->ncols);
	if (A->nrows < max) {
	sm_print(fp, A);
	}
	}

	void
	sm_cleanup()
	{
	#ifdef FAST_AND_LOOSE
	register sm_element p, pnext;
	register sm_row prow, pnextrow;
	register sm_col pcol, pnextcol;

	for(p = sm_element_freelist; p != 0; p = pnext) {
	pnext = p->next_col;
	FREE(p);
	}
	sm_element_freelist = 0;

	for(prow = sm_row_freelist; prow != 0; prow = pnextrow) {
	pnextrow = prow->next_row;
	FREE(prow);
	}
	sm_row_freelist = 0;

	for(pcol = sm_col_freelist; pcol != 0; pcol = pnextcol) {
	pnextcol = pcol->next_col;
	FREE(pcol);
	}
	sm_col_freelist = 0;
	#endif
	}