#include "graph.h" #include #include #include #include #include #include "vstack.h" #include "bitbool.h" //#define DEBUG #include "debug.h" /* static const cmph_uint8 bitmask[8] = { 1, 1 << 1, 1 << 2, 1 << 3, 1 << 4, 1 << 5, 1 << 6, 1 << 7 }; */ /* #define GETBIT(array, i) (array[(i) / 8] & bitmask[(i) % 8]) */ /* #define SETBIT(array, i) (array[(i) / 8] |= bitmask[(i) % 8]) */ /* #define UNSETBIT(array, i) (array[(i) / 8] &= (~(bitmask[(i) % 8]))) */ #define abs_edge(e, i) (e % g->nedges + i * g->nedges) struct __graph_t { cmph_uint32 nnodes; cmph_uint32 nedges; cmph_uint32 *edges; cmph_uint32 *first; cmph_uint32 *next; cmph_uint8 *critical_nodes; /* included -- Fabiano*/ cmph_uint32 ncritical_nodes; /* included -- Fabiano*/ cmph_uint32 cedges; int shrinking; }; static cmph_uint32 EMPTY = UINT_MAX; graph_t *graph_new(cmph_uint32 nnodes, cmph_uint32 nedges) { graph_t *graph = (graph_t *)malloc(sizeof(graph_t)); if (!graph) return NULL; graph->edges = (cmph_uint32 *)malloc(sizeof(cmph_uint32) * 2 * nedges); graph->next = (cmph_uint32 *)malloc(sizeof(cmph_uint32) * 2 * nedges); graph->first = (cmph_uint32 *)malloc(sizeof(cmph_uint32) * nnodes); graph->critical_nodes = NULL; /* included -- Fabiano*/ graph->ncritical_nodes = 0; /* included -- Fabiano*/ graph->nnodes = nnodes; graph->nedges = nedges; graph_clear_edges(graph); return graph; } void graph_destroy(graph_t *graph) { DEBUGP("Destroying graph\n"); free(graph->edges); free(graph->first); free(graph->next); free(graph->critical_nodes); /* included -- Fabiano*/ free(graph); return; } void graph_print(graph_t *g) { cmph_uint32 i, e; for (i = 0; i < g->nnodes; ++i) { DEBUGP("Printing edges connected to %u\n", i); e = g->first[i]; if (e != EMPTY) { printf("%u -> %u\n", g->edges[abs_edge(e, 0)], g->edges[abs_edge(e, 1)]); while ((e = g->next[e]) != EMPTY) { printf("%u -> %u\n", g->edges[abs_edge(e, 0)], g->edges[abs_edge(e, 1)]); } } } return; } void graph_add_edge(graph_t *g, cmph_uint32 v1, cmph_uint32 v2) { cmph_uint32 e = g->cedges; assert(v1 < g->nnodes); assert(v2 < g->nnodes); assert(e < g->nedges); assert(!g->shrinking); g->next[e] = g->first[v1]; g->first[v1] = e; g->edges[e] = v2; g->next[e + g->nedges] = g->first[v2]; g->first[v2] = e + g->nedges; g->edges[e + g->nedges] = v1; ++(g->cedges); } static int check_edge(graph_t *g, cmph_uint32 e, cmph_uint32 v1, cmph_uint32 v2) { DEBUGP("Checking edge %u %u looking for %u %u\n", g->edges[abs_edge(e, 0)], g->edges[abs_edge(e, 1)], v1, v2); if (g->edges[abs_edge(e, 0)] == v1 && g->edges[abs_edge(e, 1)] == v2) return 1; if (g->edges[abs_edge(e, 0)] == v2 && g->edges[abs_edge(e, 1)] == v1) return 1; return 0; } cmph_uint32 graph_edge_id(graph_t *g, cmph_uint32 v1, cmph_uint32 v2) { cmph_uint32 e; e = g->first[v1]; assert(e != EMPTY); if (check_edge(g, e, v1, v2)) return abs_edge(e, 0); do { e = g->next[e]; assert(e != EMPTY); } while (!check_edge(g, e, v1, v2)); return abs_edge(e, 0); } static void del_edge_point(graph_t *g, cmph_uint32 v1, cmph_uint32 v2) { cmph_uint32 e, prev; DEBUGP("Deleting edge point %u %u\n", v1, v2); e = g->first[v1]; if (check_edge(g, e, v1, v2)) { g->first[v1] = g->next[e]; //g->edges[e] = EMPTY; DEBUGP("Deleted\n"); return; } DEBUGP("Checking linked list\n"); do { prev = e; e = g->next[e]; assert(e != EMPTY); } while (!check_edge(g, e, v1, v2)); g->next[prev] = g->next[e]; //g->edges[e] = EMPTY; DEBUGP("Deleted\n"); } void graph_del_edge(graph_t *g, cmph_uint32 v1, cmph_uint32 v2) { g->shrinking = 1; del_edge_point(g, v1, v2); del_edge_point(g, v2, v1); } void graph_clear_edges(graph_t *g) { cmph_uint32 i; for (i = 0; i < g->nnodes; ++i) g->first[i] = EMPTY; for (i = 0; i < g->nedges*2; ++i) { g->edges[i] = EMPTY; g->next[i] = EMPTY; } g->cedges = 0; g->shrinking = 0; } static cmph_uint8 find_degree1_edge(graph_t *g, cmph_uint32 v, cmph_uint8 *deleted, cmph_uint32 *e) { cmph_uint32 edge = g->first[v]; cmph_uint8 found = 0; DEBUGP("Checking degree of vertex %u\n", v); if (edge == EMPTY) return 0; else if (!(GETBIT(deleted, abs_edge(edge, 0)))) { found = 1; *e = edge; } while(1) { edge = g->next[edge]; if (edge == EMPTY) break; if (GETBIT(deleted, abs_edge(edge, 0))) continue; if (found) return 0; DEBUGP("Found first edge\n"); *e = edge; found = 1; } return found; } static void cyclic_del_edge(graph_t *g, cmph_uint32 v, cmph_uint8 *deleted) { cmph_uint32 e = 0; cmph_uint8 degree1; cmph_uint32 v1 = v; cmph_uint32 v2 = 0; degree1 = find_degree1_edge(g, v1, deleted, &e); if (!degree1) return; while(1) { DEBUGP("Deleting edge %u (%u->%u)\n", e, g->edges[abs_edge(e, 0)], g->edges[abs_edge(e, 1)]); SETBIT(deleted, abs_edge(e, 0)); v2 = g->edges[abs_edge(e, 0)]; if (v2 == v1) v2 = g->edges[abs_edge(e, 1)]; DEBUGP("Checking if second endpoint %u has degree 1\n", v2); degree1 = find_degree1_edge(g, v2, deleted, &e); if (degree1) { DEBUGP("Inspecting vertex %u\n", v2); v1 = v2; } else break; } } int graph_is_cyclic(graph_t *g) { cmph_uint32 i; cmph_uint32 v; cmph_uint8 *deleted = (cmph_uint8 *)malloc((g->nedges*sizeof(cmph_uint8))/8 + 1); size_t deleted_len = g->nedges/8 + 1; memset(deleted, 0, deleted_len); DEBUGP("Looking for cycles in graph with %u vertices and %u edges\n", g->nnodes, g->nedges); for (v = 0; v < g->nnodes; ++v) { cyclic_del_edge(g, v, deleted); } for (i = 0; i < g->nedges; ++i) { if (!(GETBIT(deleted, i))) { DEBUGP("Edge %u %u->%u was not deleted\n", i, g->edges[i], g->edges[i + g->nedges]); free(deleted); return 1; } } free(deleted); return 0; } cmph_uint8 graph_node_is_critical(graph_t * g, cmph_uint32 v) /* included -- Fabiano */ { return (cmph_uint8)GETBIT(g->critical_nodes,v); } void graph_obtain_critical_nodes(graph_t *g) /* included -- Fabiano*/ { cmph_uint32 i; cmph_uint32 v; cmph_uint8 *deleted = (cmph_uint8 *)malloc((g->nedges*sizeof(cmph_uint8))/8+1); size_t deleted_len = g->nedges/8 + 1; memset(deleted, 0, deleted_len); free(g->critical_nodes); g->critical_nodes = (cmph_uint8 *)malloc((g->nnodes*sizeof(cmph_uint8))/8 + 1); g->ncritical_nodes = 0; memset(g->critical_nodes, 0, (g->nnodes*sizeof(cmph_uint8))/8 + 1); DEBUGP("Looking for the 2-core in graph with %u vertices and %u edges\n", g->nnodes, g->nedges); for (v = 0; v < g->nnodes; ++v) { cyclic_del_edge(g, v, deleted); } for (i = 0; i < g->nedges; ++i) { if (!(GETBIT(deleted,i))) { DEBUGP("Edge %u %u->%u belongs to the 2-core\n", i, g->edges[i], g->edges[i + g->nedges]); if(!(GETBIT(g->critical_nodes,g->edges[i]))) { g->ncritical_nodes ++; SETBIT(g->critical_nodes,g->edges[i]); } if(!(GETBIT(g->critical_nodes,g->edges[i + g->nedges]))) { g->ncritical_nodes ++; SETBIT(g->critical_nodes,g->edges[i + g->nedges]); } } } free(deleted); } cmph_uint8 graph_contains_edge(graph_t *g, cmph_uint32 v1, cmph_uint32 v2) /* included -- Fabiano*/ { cmph_uint32 e; e = g->first[v1]; if(e == EMPTY) return 0; if (check_edge(g, e, v1, v2)) return 1; do { e = g->next[e]; if(e == EMPTY) return 0; } while (!check_edge(g, e, v1, v2)); return 1; } cmph_uint32 graph_vertex_id(graph_t *g, cmph_uint32 e, cmph_uint32 id) /* included -- Fabiano*/ { return (g->edges[e + id*g->nedges]); } cmph_uint32 graph_ncritical_nodes(graph_t *g) /* included -- Fabiano*/ { return g->ncritical_nodes; } graph_iterator_t graph_neighbors_it(graph_t *g, cmph_uint32 v) { graph_iterator_t it; it.vertex = v; it.edge = g->first[v]; return it; } cmph_uint32 graph_next_neighbor(graph_t *g, graph_iterator_t* it) { cmph_uint32 ret; if(it->edge == EMPTY) return GRAPH_NO_NEIGHBOR; if (g->edges[it->edge] == it->vertex) ret = g->edges[it->edge + g->nedges]; else ret = g->edges[it->edge]; it->edge = g->next[it->edge]; return ret; }