final/MultiSource/Benchmarks/MallocBench/espresso/indep.c - external/llvm.org/test-suite - Git at Google

 #include "mincov_int.h"

 static sm_matrix *build_intersection_matrix();


 #if 0
 /*
  *  verify that all rows in 'indep' are actually independent !
  */
 static int
 verify_indep_set(A, indep)
 sm_matrix *A;
 sm_row *indep;
 {
     register sm_row *prow, *prow1;
     register sm_element *p, *p1;

     for(p = indep->first_col; p != 0; p = p->next_col) {
 	prow = sm_get_row(A, p->col_num);
 	for(p1 = p->next_col; p1 != 0; p1 = p1->next_col) {
 	    prow1 = sm_get_row(A, p1->col_num);
 	    if (sm_row_intersects(prow, prow1)) {
 		return 0;
 	    }
 	}
     }
     return 1;
 }
 #endif

 solution_t *
 sm_maximal_independent_set(A, weight)
 sm_matrix *A;
 int *weight;
 {
     register sm_row *best_row, *prow;
     register sm_element *p;
     int least_weight;
     sm_row *save;
     sm_matrix *B;
     solution_t *indep;

     indep = solution_alloc();
     B = build_intersection_matrix(A);

     while (B->nrows > 0) {
 	/*  Find the row which is disjoint from a maximum number of rows */
 	best_row = B->first_row;
 	for(prow = B->first_row->next_row; prow != 0; prow = prow->next_row) {
 	    if (prow->length < best_row->length) {
 		best_row = prow;
 	    }
 	}

 	/* Find which element in this row has least weight */
 	if (weight == NIL(int)) {
 	    least_weight = 1;
 	} else {
 	    prow = sm_get_row(A, best_row->row_num);
 	    least_weight = weight[prow->first_col->col_num];
 	    for(p = prow->first_col->next_col; p != 0; p = p->next_col) {
 		if (weight[p->col_num] < least_weight) {
 		    least_weight = weight[p->col_num];
 		}
 	    }
 	}
 	indep->cost += least_weight;
 	(void) sm_row_insert(indep->row, best_row->row_num);

 	/*  Discard the rows which intersect this row */
 	save = sm_row_dup(best_row);
 	for(p = save->first_col; p != 0; p = p->next_col) {
 	    sm_delrow(B, p->col_num);
 	    sm_delcol(B, p->col_num);
 	}
 	sm_row_free(save);
     }

     sm_free(B);

 /*
     if (! verify_indep_set(A, indep->row)) {
 	fail("sm_maximal_independent_set: row set is not independent");
     }
 */
     return indep;
 }

 static sm_matrix *
 build_intersection_matrix(A)
 sm_matrix *A;
 {
     register sm_row *prow, *prow1;
     register sm_element *p, *p1;
     register sm_col *pcol;
     sm_matrix *B;

     /* Build row-intersection matrix */
     B = sm_alloc();
     for(prow = A->first_row; prow != 0; prow = prow->next_row) {

 	/* Clear flags on all rows we can reach from row 'prow' */
 	for(p = prow->first_col; p != 0; p = p->next_col) {
 	    pcol = sm_get_col(A, p->col_num);
 	    for(p1 = pcol->first_row; p1 != 0; p1 = p1->next_row) {
 		prow1 = sm_get_row(A, p1->row_num);
 		prow1->flag = 0;
 	    }
 	}

 	/* Now record which rows can be reached */
 	for(p = prow->first_col; p != 0; p = p->next_col) {
 	    pcol = sm_get_col(A, p->col_num);
 	    for(p1 = pcol->first_row; p1 != 0; p1 = p1->next_row) {
 		prow1 = sm_get_row(A, p1->row_num);
 		if (! prow1->flag) {
 		    prow1->flag = 1;
 		    (void) sm_insert(B, prow->row_num, prow1->row_num);
 		}
 	    }
 	}
     }

     return B;
 }
	#include "mincov_int.h"

	static sm_matrix *build_intersection_matrix();


	#if 0
	/*
	* verify that all rows in 'indep' are actually independent !
	*/
	static int
	verify_indep_set(A, indep)
	sm_matrix *A;
	sm_row *indep;
	{
	register sm_row prow, prow1;
	register sm_element p, p1;

	for(p = indep->first_col; p != 0; p = p->next_col) {
	prow = sm_get_row(A, p->col_num);
	for(p1 = p->next_col; p1 != 0; p1 = p1->next_col) {
	prow1 = sm_get_row(A, p1->col_num);
	if (sm_row_intersects(prow, prow1)) {
	return 0;
	}
	}
	}
	return 1;
	}
	#endif

	solution_t *
	sm_maximal_independent_set(A, weight)
	sm_matrix *A;
	int *weight;
	{
	register sm_row best_row, prow;
	register sm_element *p;
	int least_weight;
	sm_row *save;
	sm_matrix *B;
	solution_t *indep;

	indep = solution_alloc();
	B = build_intersection_matrix(A);

	while (B->nrows > 0) {
	/* Find the row which is disjoint from a maximum number of rows */
	best_row = B->first_row;
	for(prow = B->first_row->next_row; prow != 0; prow = prow->next_row) {
	if (prow->length < best_row->length) {
	best_row = prow;
	}
	}

	/* Find which element in this row has least weight */
	if (weight == NIL(int)) {
	least_weight = 1;
	} else {
	prow = sm_get_row(A, best_row->row_num);
	least_weight = weight[prow->first_col->col_num];
	for(p = prow->first_col->next_col; p != 0; p = p->next_col) {
	if (weight[p->col_num] < least_weight) {
	least_weight = weight[p->col_num];
	}
	}
	}
	indep->cost += least_weight;
	(void) sm_row_insert(indep->row, best_row->row_num);

	/* Discard the rows which intersect this row */
	save = sm_row_dup(best_row);
	for(p = save->first_col; p != 0; p = p->next_col) {
	sm_delrow(B, p->col_num);
	sm_delcol(B, p->col_num);
	}
	sm_row_free(save);
	}

	sm_free(B);

	/*
	if (! verify_indep_set(A, indep->row)) {
	fail("sm_maximal_independent_set: row set is not independent");
	}
	*/
	return indep;
	}

	static sm_matrix *
	build_intersection_matrix(A)
	sm_matrix *A;
	{
	register sm_row prow, prow1;
	register sm_element p, p1;
	register sm_col *pcol;
	sm_matrix *B;

	/* Build row-intersection matrix */
	B = sm_alloc();
	for(prow = A->first_row; prow != 0; prow = prow->next_row) {

	/* Clear flags on all rows we can reach from row 'prow' */
	for(p = prow->first_col; p != 0; p = p->next_col) {
	pcol = sm_get_col(A, p->col_num);
	for(p1 = pcol->first_row; p1 != 0; p1 = p1->next_row) {
	prow1 = sm_get_row(A, p1->row_num);
	prow1->flag = 0;
	}
	}

	/* Now record which rows can be reached */
	for(p = prow->first_col; p != 0; p = p->next_col) {
	pcol = sm_get_col(A, p->col_num);
	for(p1 = pcol->first_row; p1 != 0; p1 = p1->next_row) {
	prow1 = sm_get_row(A, p1->row_num);
	if (! prow1->flag) {
	prow1->flag = 1;
	(void) sm_insert(B, prow->row_num, prow1->row_num);
	}
	}
	}
	}

	return B;
	}