Exemple #1
0
/*
Dump dom set, pdom set, idom, ipdom.
'dump_dom_tree': set to be true to dump dominate 
	tree, and post dominate Tree.
*/
void DGRAPH::dump_dom(FILE * h, bool dump_dom_tree)
{
	if (h == NULL) return;
	fprintf(h, "\n\n\n\n========= DUMP DOM/PDOM/IDOM/IPDOM =======");
	INT c;
	for (VERTEX * v = m_vertexs.get_first(c); 
		 v != NULL; v = m_vertexs.get_next(c)) {
		INT vid = VERTEX_id(v);
		fprintf(h, "\nVERTEX(%d) dom: ", vid);
		BITSET * bs;
		if ((bs = m_dom_set.get(vid)) != NULL) {
			for (INT id = bs->get_first(); id != -1 ; id = bs->get_next(id)) {
				if (id != vid) {
					fprintf(h, "%d ", id);
				}
			}
		}
		fprintf(h, "\n     pdom: ");
		if ((bs = m_pdom_set.get(vid)) != NULL) {
			for (INT id = bs->get_first(); id != -1; id = bs->get_next(id)) {
				if (id != vid) {
					fprintf(h, "%d ", id);
				}
			}
		}
		if (m_idom_set.get(vid) != 0) {
			fprintf(h, "\n     idom: %d", m_idom_set.get(vid));
		} else {
			fprintf(h, "\n");
		}

		if (m_ipdom_set.get(vid) != 0) {
			fprintf(h, "\n     ipdom: %d", m_ipdom_set.get(vid));
		} else {
			fprintf(h, "\n");
		}
	} //end for each vertexs
	fprintf(h, "\n");
	fflush(h);

	if (dump_dom_tree) {
		GRAPH dom;
		get_dom_tree(dom);
		dom.dump_vcg("graph_dom_tree.vcg");
		dom.erasure();
		get_pdom_tree(dom);
		dom.dump_vcg("graph_pdom_tree.vcg");
	}
}
Exemple #2
0
void CDG::build(IN OUT OPT_CTX & oc, DGRAPH & cfg)
{
	if (cfg.get_vertex_num() == 0) { return; }
	START_TIMER("CDG");
	IS_TRUE0(OPTC_is_cfg_valid(oc));
	m_ru->check_valid_and_recompute(&oc, OPT_PDOM, OPT_UNDEF);

	GRAPH pdom_tree;
	cfg.get_pdom_tree(pdom_tree);
	if (pdom_tree.get_vertex_num() == 0) { return; }

	SVECTOR<UINT> top_order;
	pdom_tree.sort_in_toplog_order(top_order, false);
	//dump_vec(top_order);

	BITSET_MGR bs_mgr;
	SVECTOR<BITSET*> cd_set;
	for (INT j = 0; j <= top_order.get_last_idx(); j++) {
		UINT ii = top_order.get(j);
		VERTEX * v = cfg.get_vertex(ii);
		IS_TRUE0(v != NULL);
		add_vertex(VERTEX_id(v));
		BITSET * cd_of_v = cd_set.get(VERTEX_id(v));
		if (cd_of_v == NULL) {
			cd_of_v = bs_mgr.create();
			cd_set.set(VERTEX_id(v), cd_of_v);
		}

		EDGE_C * in = VERTEX_in_list(v);
		while (in != NULL) {
			VERTEX * pred = EDGE_from(EC_edge(in));
			if (VERTEX_id(v) != ((DGRAPH&)cfg).get_ipdom(VERTEX_id(pred))) {
				cd_of_v->bunion(VERTEX_id(pred));
				//if (pred != v)
				{
					add_edge(VERTEX_id(pred), VERTEX_id(v));
				}
			}
			in = EC_next(in);
		}
		INT c;
		for (VERTEX * z = cfg.get_first_vertex(c);
			 z != NULL; z = cfg.get_next_vertex(c)) {
			if (((DGRAPH&)cfg).get_ipdom(VERTEX_id(z)) == VERTEX_id(v)) {
				BITSET * cd = cd_set.get(VERTEX_id(z));
				if (cd == NULL) {
					cd = bs_mgr.create();
					cd_set.set(VERTEX_id(z), cd);
				}
				for (INT i = cd->get_first(); i != -1; i = cd->get_next(i)) {
					if (VERTEX_id(v) != ((DGRAPH&)cfg).get_ipdom(i)) {
						cd_of_v->bunion(i);
						//if (i != (INT)VERTEX_id(v))
						{
							add_edge(i, VERTEX_id(v));
						}
					}
				}
			}
		}
	} //end for

	OPTC_is_cdg_valid(oc) = true;
	END_TIMER();
}
Exemple #3
0
/*
Remove transitive edge.
e.g: Given edges of G, there are v1->v2->v3, v1->v3, then v1->v3 named
transitive edge.

Algo: 
	INPUT: Graph with N edges.
	1. Sort vertices in topological order.
	2. Associate each edges with indicator respective, 
	   and recording them in one matrix(N*N) 	   
		e.g: e1:v0->v2, e2:v1->v2, e3:v0->v1
			  0   1    2
			0 --  e3   e1 
			1 --  --   e2
			2 --  --   --

	3. Scan vertices according to toplogical order, 
	   remove all edges which the target-node has been 
	   marked at else rows.
		e.g: There are dependence edges: v0->v1, v0->v2.
		 If v1->v2 has been marked, we said v0->v2 is removable, 
		 and the same goes for the rest of edges.
*/
void GRAPH::remove_transitive_edge()
{
	BITSET_MGR bs_mgr;
	SVECTOR<UINT> vex_vec;
	sort_in_toplog_order(vex_vec, true);
	SVECTOR<UINT> vid2pos_in_bitset_map; //Map from VERTEX-ID to BITSET.
	INT i;

	//Mapping vertex id to its position in 'vex_vec'.
	for (i = 0; i <= vex_vec.get_last_idx(); i++) {
		vid2pos_in_bitset_map.set(vex_vec.get(i), i); 
	}

	//Associate each edges with indicator respective.
	UINT vex_num = get_vertex_num();
	SVECTOR<BITSET*> edge_indicator; //container of bitset.
	INT c;
	for (EDGE * e = m_edges.get_first(c); e != NULL; e = m_edges.get_next(c)) {
		UINT from = VERTEX_id(EDGE_from(e));
		UINT to = VERTEX_id(EDGE_to(e));
	
		UINT frompos = vid2pos_in_bitset_map.get(from);
		BITSET * bs = edge_indicator.get(frompos);
		if (bs == NULL) {
			bs = bs_mgr.create();
			edge_indicator.set(frompos, bs);
		}
		
		//Each from-vertex is associated with 
		//a bitset to record all to-vertices.
		bs->bunion(vid2pos_in_bitset_map.get(to));
	} //end for each of edge
	
	//Scanning vertexs in topological order.
	for (i = 0; i < vex_vec.get_last_idx(); i++) {
		//Get the successor vector.
		BITSET * bs = edge_indicator.get(i); 
		if (bs != NULL && bs->get_elem_count() >= 2) {
			//Do NOT remove the first edge. Position in bitset 
			//has been sorted in topological order.
			for (INT pos_i = bs->get_first(); pos_i >= 0; 
				 pos_i = bs->get_next(pos_i)) {
				INT kid_from_vid = vex_vec.get(pos_i);
				INT kid_from_pos = vid2pos_in_bitset_map.get(kid_from_vid);

				//Get bitset that 'pos_i' associated.
				BITSET * kid_from_bs = edge_indicator.get(kid_from_pos);
				if (kid_from_bs != NULL) {
					for (INT pos_j = bs->get_next(pos_i); pos_j >= 0; 
						 pos_j = bs->get_next(pos_j)) {
						if (kid_from_bs->is_contain(pos_j)) {
							//The edge 'i->pos_j' is redundant.
							INT to_vid = vex_vec.get(pos_j);
							UINT src_vid = vex_vec.get(i);
							remove_edge(get_edge(src_vid, to_vid));
							bs->diff(pos_j);
						}
					}
				} //end if
			} //end for
		} //end if
	} //end for each vertex
}
Exemple #4
0
bool DGRAPH::compute_ipdom()
{
	bool change = true;

	//Initialize ipdom-set for each BB.
	m_ipdom_set.clean();

	//Processing in reverse-topological order.
	INT c;
	for (VERTEX * v = m_vertexs.get_last(c); 
		 v != NULL; v = m_vertexs.get_prev(c)) {
		INT cur_id = VERTEX_id(v);
		if (is_graph_exit(v)) {
			continue;
		} else if (m_pdom_set.get(cur_id)->get_elem_count() > 1) {			
			BITSET * p = m_pdom_set.get(cur_id);
			IS_TRUE(p != NULL, ("should compute pdom first"));
			if (p->get_elem_count() == 1) {
				//There is no ipdom if 'pdom' set only contain itself.
				IS_TRUE0(m_ipdom_set.get(cur_id) == 0);
				continue;
			}
			p->diff(cur_id);

			#define TRICKY_METHOD
			#ifdef TRICKY_METHOD
			INT i;
			for (i = p->get_first(); i != -1; i = p->get_next(i)) {
				if (m_pdom_set.get(i)->is_equal(*p)) {
					IS_TRUE0(m_ipdom_set.get(cur_id) == 0);
					m_ipdom_set.set(cur_id, i);
					break;
				}
			}
			//IS_TRUE(i != -1, ("not find ipdom")); //Not find.
			#else
			/*
			//Then , we can find a node which is not 
			//post-dominate any other elems reside in 'tmp'.
			for (INT i = tmp.get_first(); i != -1; i = tmp.get_next(i)) {
				for (INT j = tmp.get_first(); j != -1; j = tmp.get_next(j)) {
					if (i == j) {
						continue;
					}
					if (m_pdom_set.get(j)->is_contain(i)) {
						tmp.diff(i);
						i = tmp.get_first();
						j = i;
					} //end if
				} //end for 
			} //end for
			//There is only one elemment in 'tmp'
			IS_TRUE(tmp.get_elem_count() == 1, ("illegal in compute_ipdom"));
			INT i = tmp.get_first();
			IS_TRUE(i != -1, ("cannot find ipdom of BB:%d", cur_id));
			IS_TRUE(m_ipdom_set.get(cur_id) == 0, 
					("recompute ipdom for BB:%d", cur_id));
			m_ipdom_set.set(cur_id, i);
			*/
			#endif
			p->bunion(cur_id);
		} //end else if
	} //end for
	return true;
}
Exemple #5
0
bool DGRAPH::compute_idom()
{
	bool change = true;

	//Initialize idom-set for each BB.
	m_idom_set.clean(); 

	//Access with topological order.
	INT c;
	for (VERTEX * v = m_vertexs.get_first(c); 
		 v != NULL; v = m_vertexs.get_next(c)) { 
		INT cur_id = VERTEX_id(v);
		if (is_graph_entry(v)) {
			continue;
		} else if (m_dom_set.get(cur_id)->get_elem_count() >= 2) {
			BITSET * p = m_dom_set.get(cur_id);
			IS_TRUE(p != NULL, ("should compute dom first"));
			if (p->get_elem_count() == 1) {
				//There is no idom if 'dom' set only contain itself.
				IS_TRUE0(m_idom_set.get(cur_id) == 0);
				continue;
			}
			p->diff(cur_id);
							
			#define TRICKY_METHOD
			#ifdef TRICKY_METHOD
			INT i;
			for (i = p->get_first(); i != -1; i = p->get_next(i)) {
				if (m_dom_set.get(i)->is_equal(*p)) {
					IS_TRUE0(m_idom_set.get(cur_id) == 0);
					m_idom_set.set(cur_id, i);
					break;
				}
			}
			IS_TRUE(i != -1, ("not find idom?"));
			#else
			/*
			We can find a node that is not dominate any other elems in 'tmp'.
			INT i;
			for (i = tmp.get_first(); i != -1; i = tmp.get_next(i)) {
				for (INT j = tmp.get_first(); j != -1; j = tmp.get_next(j)) {
					if (i == j) {
						continue;
					}
					if (m_dom_set.get(j)->is_contain(i)) {
						tmp.diff(i);
						//Search 'tmp' over again.
						i = tmp.get_first();
						j = i;
					}
				}
			}

			//There is only one elemment in 'tmp'
			i = tmp.get_first();
			IS_TRUE(i != -1, ("cannot find idom of BB:%d", cur_id));
			IS_TRUE(m_idom_set.get(cur_id) == 0, ("recompute idom for BB:%d", cur_id));
			m_idom_set.set(cur_id, i);
			*/
			#endif
			p->bunion(cur_id);
		} //end else if 
	} //end for
	return true;
}