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/* Control flow graph analysis code for GNU compiler. Copyright (C) 1987, 1988, 1992, 1993, 1994, 1995, 1996, 1997, 1998, 1999, 2000, 2001, 2003, 2004, 2005, 2006, 2007, 2008 Free Software Foundation, Inc. This file is part of GCC. GCC 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, or (at your option) any later version. GCC 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 GCC; see the file COPYING3. If not see <http://www.gnu.org/licenses/>. */ /* This file contains various simple utilities to analyze the CFG. */ #include "config.h" #include "system.h" #include "coretypes.h" #include "tm.h" #include "rtl.h" #include "obstack.h" #include "hard-reg-set.h" #include "basic-block.h" #include "insn-config.h" #include "recog.h" #include "toplev.h" #include "tm_p.h" #include "vec.h" #include "vecprim.h" #include "timevar.h" /* Store the data structures necessary for depth-first search. */ struct depth_first_search_dsS { /* stack for backtracking during the algorithm */ basic_block *stack; /* number of edges in the stack. That is, positions 0, ..., sp-1 have edges. */ unsigned int sp; /* record of basic blocks already seen by depth-first search */ sbitmap visited_blocks; }; typedef struct depth_first_search_dsS *depth_first_search_ds; static void flow_dfs_compute_reverse_init (depth_first_search_ds); static void flow_dfs_compute_reverse_add_bb (depth_first_search_ds, basic_block); static basic_block flow_dfs_compute_reverse_execute (depth_first_search_ds, basic_block); static void flow_dfs_compute_reverse_finish (depth_first_search_ds); static bool flow_active_insn_p (const_rtx); /* Like active_insn_p, except keep the return value clobber around even after reload. */ static bool flow_active_insn_p (const_rtx insn) { if (active_insn_p (insn)) return true; /* A clobber of the function return value exists for buggy programs that fail to return a value. Its effect is to keep the return value from being live across the entire function. If we allow it to be skipped, we introduce the possibility for register lifetime confusion. */ if (GET_CODE (PATTERN (insn)) == CLOBBER && REG_P (XEXP (PATTERN (insn), 0)) && REG_FUNCTION_VALUE_P (XEXP (PATTERN (insn), 0))) return true; return false; } /* Return true if the block has no effect and only forwards control flow to its single destination. */ bool forwarder_block_p (const_basic_block bb) { rtx insn; if (bb == EXIT_BLOCK_PTR || bb == ENTRY_BLOCK_PTR || !single_succ_p (bb)) return false; for (insn = BB_HEAD (bb); insn != BB_END (bb); insn = NEXT_INSN (insn)) if (INSN_P (insn) && flow_active_insn_p (insn)) return false; return (!INSN_P (insn) || (JUMP_P (insn) && simplejump_p (insn)) || !flow_active_insn_p (insn)); } /* Return nonzero if we can reach target from src by falling through. */ bool can_fallthru (basic_block src, basic_block target) { rtx insn = BB_END (src); rtx insn2; edge e; edge_iterator ei; if (target == EXIT_BLOCK_PTR) return true; if (src->next_bb != target) return 0; FOR_EACH_EDGE (e, ei, src->succs) if (e->dest == EXIT_BLOCK_PTR && e->flags & EDGE_FALLTHRU) return 0; insn2 = BB_HEAD (target); if (insn2 && !active_insn_p (insn2)) insn2 = next_active_insn (insn2); /* ??? Later we may add code to move jump tables offline. */ return next_active_insn (insn) == insn2; } /* Return nonzero if we could reach target from src by falling through, if the target was made adjacent. If we already have a fall-through edge to the exit block, we can't do that. */ bool could_fall_through (basic_block src, basic_block target) { edge e; edge_iterator ei; if (target == EXIT_BLOCK_PTR) return true; FOR_EACH_EDGE (e, ei, src->succs) if (e->dest == EXIT_BLOCK_PTR && e->flags & EDGE_FALLTHRU) return 0; return true; } /* Mark the back edges in DFS traversal. Return nonzero if a loop (natural or otherwise) is present. Inspired by Depth_First_Search_PP described in: Advanced Compiler Design and Implementation Steven Muchnick Morgan Kaufmann, 1997 and heavily borrowed from pre_and_rev_post_order_compute. */ bool mark_dfs_back_edges (void) { edge_iterator *stack; int *pre; int *post; int sp; int prenum = 1; int postnum = 1; sbitmap visited; bool found = false; /* Allocate the preorder and postorder number arrays. */ pre = XCNEWVEC (int, last_basic_block); post = XCNEWVEC (int, last_basic_block); /* Allocate stack for back-tracking up CFG. */ stack = XNEWVEC (edge_iterator, n_basic_blocks + 1); sp = 0; /* Allocate bitmap to track nodes that have been visited. */ visited = sbitmap_alloc (last_basic_block); /* None of the nodes in the CFG have been visited yet. */ sbitmap_zero (visited); /* Push the first edge on to the stack. */ stack[sp++] = ei_start (ENTRY_BLOCK_PTR->succs); while (sp) { edge_iterator ei; basic_block src; basic_block dest; /* Look at the edge on the top of the stack. */ ei = stack[sp - 1]; src = ei_edge (ei)->src; dest = ei_edge (ei)->dest; ei_edge (ei)->flags &= ~EDGE_DFS_BACK; /* Check if the edge destination has been visited yet. */ if (dest != EXIT_BLOCK_PTR && ! TEST_BIT (visited, dest->index)) { /* Mark that we have visited the destination. */ SET_BIT (visited, dest->index); pre[dest->index] = prenum++; if (EDGE_COUNT (dest->succs) > 0) { /* Since the DEST node has been visited for the first time, check its successors. */ stack[sp++] = ei_start (dest->succs); } else post[dest->index] = postnum++; } else { if (dest != EXIT_BLOCK_PTR && src != ENTRY_BLOCK_PTR && pre[src->index] >= pre[dest->index] && post[dest->index] == 0) ei_edge (ei)->flags |= EDGE_DFS_BACK, found = true; if (ei_one_before_end_p (ei) && src != ENTRY_BLOCK_PTR) post[src->index] = postnum++; if (!ei_one_before_end_p (ei)) ei_next (&stack[sp - 1]); else sp--; } } free (pre); free (post); free (stack); sbitmap_free (visited); return found; } /* Set the flag EDGE_CAN_FALLTHRU for edges that can be fallthru. */ void set_edge_can_fallthru_flag (void) { basic_block bb; FOR_EACH_BB (bb) { edge e; edge_iterator ei; FOR_EACH_EDGE (e, ei, bb->succs) { e->flags &= ~EDGE_CAN_FALLTHRU; /* The FALLTHRU edge is also CAN_FALLTHRU edge. */ if (e->flags & EDGE_FALLTHRU) e->flags |= EDGE_CAN_FALLTHRU; } /* If the BB ends with an invertible condjump all (2) edges are CAN_FALLTHRU edges. */ if (EDGE_COUNT (bb->succs) != 2) continue; if (!any_condjump_p (BB_END (bb))) continue; if (!invert_jump (BB_END (bb), JUMP_LABEL (BB_END (bb)), 0)) continue; invert_jump (BB_END (bb), JUMP_LABEL (BB_END (bb)), 0); EDGE_SUCC (bb, 0)->flags |= EDGE_CAN_FALLTHRU; EDGE_SUCC (bb, 1)->flags |= EDGE_CAN_FALLTHRU; } } /* Find unreachable blocks. An unreachable block will have 0 in the reachable bit in block->flags. A nonzero value indicates the block is reachable. */ void find_unreachable_blocks (void) { edge e; edge_iterator ei; basic_block *tos, *worklist, bb; tos = worklist = XNEWVEC (basic_block, n_basic_blocks); /* Clear all the reachability flags. */ FOR_EACH_BB (bb) bb->flags &= ~BB_REACHABLE; /* Add our starting points to the worklist. Almost always there will be only one. It isn't inconceivable that we might one day directly support Fortran alternate entry points. */ FOR_EACH_EDGE (e, ei, ENTRY_BLOCK_PTR->succs) { *tos++ = e->dest; /* Mark the block reachable. */ e->dest->flags |= BB_REACHABLE; } /* Iterate: find everything reachable from what we've already seen. */ while (tos != worklist) { basic_block b = *--tos; FOR_EACH_EDGE (e, ei, b->succs) { basic_block dest = e->dest; if (!(dest->flags & BB_REACHABLE)) { *tos++ = dest; dest->flags |= BB_REACHABLE; } } } free (worklist); } /* Functions to access an edge list with a vector representation. Enough data is kept such that given an index number, the pred and succ that edge represents can be determined, or given a pred and a succ, its index number can be returned. This allows algorithms which consume a lot of memory to represent the normally full matrix of edge (pred,succ) with a single indexed vector, edge (EDGE_INDEX (pred, succ)), with no wasted space in the client code due to sparse flow graphs. */ /* This functions initializes the edge list. Basically the entire flowgraph is processed, and all edges are assigned a number, and the data structure is filled in. */ struct edge_list * create_edge_list (void) { struct edge_list *elist; edge e; int num_edges; int block_count; basic_block bb; edge_iterator ei; block_count = n_basic_blocks; /* Include the entry and exit blocks. */ num_edges = 0; /* Determine the number of edges in the flow graph by counting successor edges on each basic block. */ FOR_BB_BETWEEN (bb, ENTRY_BLOCK_PTR, EXIT_BLOCK_PTR, next_bb) { num_edges += EDGE_COUNT (bb->succs); } elist = XNEW (struct edge_list); elist->num_blocks = block_count; elist->num_edges = num_edges; elist->index_to_edge = XNEWVEC (edge, num_edges); num_edges = 0; /* Follow successors of blocks, and register these edges. */ FOR_BB_BETWEEN (bb, ENTRY_BLOCK_PTR, EXIT_BLOCK_PTR, next_bb) FOR_EACH_EDGE (e, ei, bb->succs) elist->index_to_edge[num_edges++] = e; return elist; } /* This function free's memory associated with an edge list. */ void free_edge_list (struct edge_list *elist) { if (elist) { free (elist->index_to_edge); free (elist); } } /* This function provides debug output showing an edge list. */ void print_edge_list (FILE *f, struct edge_list *elist) { int x; fprintf (f, "Compressed edge list, %d BBs + entry & exit, and %d edges\n", elist->num_blocks, elist->num_edges); for (x = 0; x < elist->num_edges; x++) { fprintf (f, " %-4d - edge(", x); if (INDEX_EDGE_PRED_BB (elist, x) == ENTRY_BLOCK_PTR) fprintf (f, "entry,"); else fprintf (f, "%d,", INDEX_EDGE_PRED_BB (elist, x)->index); if (INDEX_EDGE_SUCC_BB (elist, x) == EXIT_BLOCK_PTR) fprintf (f, "exit)\n"); else fprintf (f, "%d)\n", INDEX_EDGE_SUCC_BB (elist, x)->index); } } /* This function provides an internal consistency check of an edge list, verifying that all edges are present, and that there are no extra edges. */ void verify_edge_list (FILE *f, struct edge_list *elist) { int pred, succ, index; edge e; basic_block bb, p, s; edge_iterator ei; FOR_BB_BETWEEN (bb, ENTRY_BLOCK_PTR, EXIT_BLOCK_PTR, next_bb) { FOR_EACH_EDGE (e, ei, bb->succs) { pred = e->src->index; succ = e->dest->index; index = EDGE_INDEX (elist, e->src, e->dest); if (index == EDGE_INDEX_NO_EDGE) { fprintf (f, "*p* No index for edge from %d to %d\n", pred, succ); continue; } if (INDEX_EDGE_PRED_BB (elist, index)->index != pred) fprintf (f, "*p* Pred for index %d should be %d not %d\n", index, pred, INDEX_EDGE_PRED_BB (elist, index)->index); if (INDEX_EDGE_SUCC_BB (elist, index)->index != succ) fprintf (f, "*p* Succ for index %d should be %d not %d\n", index, succ, INDEX_EDGE_SUCC_BB (elist, index)->index); } } /* We've verified that all the edges are in the list, now lets make sure there are no spurious edges in the list. */ FOR_BB_BETWEEN (p, ENTRY_BLOCK_PTR, EXIT_BLOCK_PTR, next_bb) FOR_BB_BETWEEN (s, ENTRY_BLOCK_PTR->next_bb, NULL, next_bb) { int found_edge = 0; FOR_EACH_EDGE (e, ei, p->succs) if (e->dest == s) { found_edge = 1; break; } FOR_EACH_EDGE (e, ei, s->preds) if (e->src == p) { found_edge = 1; break; } if (EDGE_INDEX (elist, p, s) == EDGE_INDEX_NO_EDGE && found_edge != 0) fprintf (f, "*** Edge (%d, %d) appears to not have an index\n", p->index, s->index); if (EDGE_INDEX (elist, p, s) != EDGE_INDEX_NO_EDGE && found_edge == 0) fprintf (f, "*** Edge (%d, %d) has index %d, but there is no edge\n", p->index, s->index, EDGE_INDEX (elist, p, s)); } } /* Given PRED and SUCC blocks, return the edge which connects the blocks. If no such edge exists, return NULL. */ edge find_edge (basic_block pred, basic_block succ) { edge e; edge_iterator ei; if (EDGE_COUNT (pred->succs) <= EDGE_COUNT (succ->preds)) { FOR_EACH_EDGE (e, ei, pred->succs) if (e->dest == succ) return e; } else { FOR_EACH_EDGE (e, ei, succ->preds) if (e->src == pred) return e; } return NULL; } /* This routine will determine what, if any, edge there is between a specified predecessor and successor. */ int find_edge_index (struct edge_list *edge_list, basic_block pred, basic_block succ) { int x; for (x = 0; x < NUM_EDGES (edge_list); x++) if (INDEX_EDGE_PRED_BB (edge_list, x) == pred && INDEX_EDGE_SUCC_BB (edge_list, x) == succ) return x; return (EDGE_INDEX_NO_EDGE); } /* Dump the list of basic blocks in the bitmap NODES. */ void flow_nodes_print (const char *str, const_sbitmap nodes, FILE *file) { unsigned int node = 0; sbitmap_iterator sbi; if (! nodes) return; fprintf (file, "%s { ", str); EXECUTE_IF_SET_IN_SBITMAP (nodes, 0, node, sbi) fprintf (file, "%d ", node); fputs ("}\n", file); } /* Dump the list of edges in the array EDGE_LIST. */ void flow_edge_list_print (const char *str, const edge *edge_list, int num_edges, FILE *file) { int i; if (! edge_list) return; fprintf (file, "%s { ", str); for (i = 0; i < num_edges; i++) fprintf (file, "%d->%d ", edge_list[i]->src->index, edge_list[i]->dest->index); fputs ("}\n", file); } /* This routine will remove any fake predecessor edges for a basic block. When the edge is removed, it is also removed from whatever successor list it is in. */ static void remove_fake_predecessors (basic_block bb) { edge e; edge_iterator ei; for (ei = ei_start (bb->preds); (e = ei_safe_edge (ei)); ) { if ((e->flags & EDGE_FAKE) == EDGE_FAKE) remove_edge (e); else ei_next (&ei); } } /* This routine will remove all fake edges from the flow graph. If we remove all fake successors, it will automatically remove all fake predecessors. */ void remove_fake_edges (void) { basic_block bb; FOR_BB_BETWEEN (bb, ENTRY_BLOCK_PTR->next_bb, NULL, next_bb) remove_fake_predecessors (bb); } /* This routine will remove all fake edges to the EXIT_BLOCK. */ void remove_fake_exit_edges (void) { remove_fake_predecessors (EXIT_BLOCK_PTR); } /* This function will add a fake edge between any block which has no successors, and the exit block. Some data flow equations require these edges to exist. */ void add_noreturn_fake_exit_edges (void) { basic_block bb; FOR_EACH_BB (bb) if (EDGE_COUNT (bb->succs) == 0) make_single_succ_edge (bb, EXIT_BLOCK_PTR, EDGE_FAKE); } /* This function adds a fake edge between any infinite loops to the exit block. Some optimizations require a path from each node to the exit node. See also Morgan, Figure 3.10, pp. 82-83. The current implementation is ugly, not attempting to minimize the number of inserted fake edges. To reduce the number of fake edges to insert, add fake edges from _innermost_ loops containing only nodes not reachable from the exit block. */ void connect_infinite_loops_to_exit (void) { basic_block unvisited_block = EXIT_BLOCK_PTR; struct depth_first_search_dsS dfs_ds; /* Perform depth-first search in the reverse graph to find nodes reachable from the exit block. */ flow_dfs_compute_reverse_init (&dfs_ds); flow_dfs_compute_reverse_add_bb (&dfs_ds, EXIT_BLOCK_PTR); /* Repeatedly add fake edges, updating the unreachable nodes. */ while (1) { unvisited_block = flow_dfs_compute_reverse_execute (&dfs_ds, unvisited_block); if (!unvisited_block) break; make_edge (unvisited_block, EXIT_BLOCK_PTR, EDGE_FAKE); flow_dfs_compute_reverse_add_bb (&dfs_ds, unvisited_block); } flow_dfs_compute_reverse_finish (&dfs_ds); return; } /* Compute reverse top sort order. This is computing a post order numbering of the graph. If INCLUDE_ENTRY_EXIT is true, then then ENTRY_BLOCK and EXIT_BLOCK are included. If DELETE_UNREACHABLE is true, unreachable blocks are deleted. */ int post_order_compute (int *post_order, bool include_entry_exit, bool delete_unreachable) { edge_iterator *stack; int sp; int post_order_num = 0; sbitmap visited; int count; if (include_entry_exit) post_order[post_order_num++] = EXIT_BLOCK; /* Allocate stack for back-tracking up CFG. */ stack = XNEWVEC (edge_iterator, n_basic_blocks + 1); sp = 0; /* Allocate bitmap to track nodes that have been visited. */ visited = sbitmap_alloc (last_basic_block); /* None of the nodes in the CFG have been visited yet. */ sbitmap_zero (visited); /* Push the first edge on to the stack. */ stack[sp++] = ei_start (ENTRY_BLOCK_PTR->succs); while (sp) { edge_iterator ei; basic_block src; basic_block dest; /* Look at the edge on the top of the stack. */ ei = stack[sp - 1]; src = ei_edge (ei)->src; dest = ei_edge (ei)->dest; /* Check if the edge destination has been visited yet. */ if (dest != EXIT_BLOCK_PTR && ! TEST_BIT (visited, dest->index)) { /* Mark that we have visited the destination. */ SET_BIT (visited, dest->index); if (EDGE_COUNT (dest->succs) > 0) /* Since the DEST node has been visited for the first time, check its successors. */ stack[sp++] = ei_start (dest->succs); else post_order[post_order_num++] = dest->index; } else { if (ei_one_before_end_p (ei) && src != ENTRY_BLOCK_PTR) post_order[post_order_num++] = src->index; if (!ei_one_before_end_p (ei)) ei_next (&stack[sp - 1]); else sp--; } } if (include_entry_exit) { post_order[post_order_num++] = ENTRY_BLOCK; count = post_order_num; } else count = post_order_num + 2; /* Delete the unreachable blocks if some were found and we are supposed to do it. */ if (delete_unreachable && (count != n_basic_blocks)) { basic_block b; basic_block next_bb; for (b = ENTRY_BLOCK_PTR->next_bb; b != EXIT_BLOCK_PTR; b = next_bb) { next_bb = b->next_bb; if (!(TEST_BIT (visited, b->index))) delete_basic_block (b); } tidy_fallthru_edges (); } free (stack); sbitmap_free (visited); return post_order_num; } /* Helper routine for inverted_post_order_compute. BB has to belong to a region of CFG unreachable by inverted traversal from the exit. i.e. there's no control flow path from ENTRY to EXIT that contains this BB. This can happen in two cases - if there's an infinite loop or if there's a block that has no successor (call to a function with no return). Some RTL passes deal with this condition by calling connect_infinite_loops_to_exit () and/or add_noreturn_fake_exit_edges (). However, those methods involve modifying the CFG itself which may not be desirable. Hence, we deal with the infinite loop/no return cases by identifying a unique basic block that can reach all blocks in such a region by inverted traversal. This function returns a basic block that guarantees that all blocks in the region are reachable by starting an inverted traversal from the returned block. */ static basic_block dfs_find_deadend (basic_block bb) { sbitmap visited = sbitmap_alloc (last_basic_block); sbitmap_zero (visited); for (;;) { SET_BIT (visited, bb->index); if (EDGE_COUNT (bb->succs) == 0 || TEST_BIT (visited, EDGE_SUCC (bb, 0)->dest->index)) { sbitmap_free (visited); return bb; } bb = EDGE_SUCC (bb, 0)->dest; } gcc_unreachable (); } /* Compute the reverse top sort order of the inverted CFG i.e. starting from the exit block and following the edges backward (from successors to predecessors). This ordering can be used for forward dataflow problems among others. This function assumes that all blocks in the CFG are reachable from the ENTRY (but not necessarily from EXIT). If there's an infinite loop, a simple inverted traversal starting from the blocks with no successors can't visit all blocks. To solve this problem, we first do inverted traversal starting from the blocks with no successor. And if there's any block left that's not visited by the regular inverted traversal from EXIT, those blocks are in such problematic region. Among those, we find one block that has any visited predecessor (which is an entry into such a region), and start looking for a "dead end" from that block and do another inverted traversal from that block. */ int inverted_post_order_compute (int *post_order) { basic_block bb; edge_iterator *stack; int sp; int post_order_num = 0; sbitmap visited; /* Allocate stack for back-tracking up CFG. */ stack = XNEWVEC (edge_iterator, n_basic_blocks + 1); sp = 0; /* Allocate bitmap to track nodes that have been visited. */ visited = sbitmap_alloc (last_basic_block); /* None of the nodes in the CFG have been visited yet. */ sbitmap_zero (visited); /* Put all blocks that have no successor into the initial work list. */ FOR_BB_BETWEEN (bb, ENTRY_BLOCK_PTR, NULL, next_bb) if (EDGE_COUNT (bb->succs) == 0) { /* Push the initial edge on to the stack. */ if (EDGE_COUNT (bb->preds) > 0) { stack[sp++] = ei_start (bb->preds); SET_BIT (visited, bb->index); } } do { bool has_unvisited_bb = false; /* The inverted traversal loop. */ while (sp) { edge_iterator ei; basic_block pred; /* Look at the edge on the top of the stack. */ ei = stack[sp - 1]; bb = ei_edge (ei)->dest; pred = ei_edge (ei)->src; /* Check if the predecessor has been visited yet. */ if (! TEST_BIT (visited, pred->index)) { /* Mark that we have visited the destination. */ SET_BIT (visited, pred->index); if (EDGE_COUNT (pred->preds) > 0) /* Since the predecessor node has been visited for the first time, check its predecessors. */ stack[sp++] = ei_start (pred->preds); else post_order[post_order_num++] = pred->index; } else { if (bb != EXIT_BLOCK_PTR && ei_one_before_end_p (ei)) post_order[post_order_num++] = bb->index; if (!ei_one_before_end_p (ei)) ei_next (&stack[sp - 1]); else sp--; } } /* Detect any infinite loop and activate the kludge. Note that this doesn't check EXIT_BLOCK itself since EXIT_BLOCK is always added after the outer do-while loop. */ FOR_BB_BETWEEN (bb, ENTRY_BLOCK_PTR, EXIT_BLOCK_PTR, next_bb) if (!TEST_BIT (visited, bb->index)) { has_unvisited_bb = true; if (EDGE_COUNT (bb->preds) > 0) { edge_iterator ei; edge e; basic_block visited_pred = NULL; /* Find an already visited predecessor. */ FOR_EACH_EDGE (e, ei, bb->preds) { if (TEST_BIT (visited, e->src->index)) visited_pred = e->src; } if (visited_pred) { basic_block be = dfs_find_deadend (bb); gcc_assert (be != NULL); SET_BIT (visited, be->index); stack[sp++] = ei_start (be->preds); break; } } } if (has_unvisited_bb && sp == 0) { /* No blocks are reachable from EXIT at all. Find a dead-end from the ENTRY, and restart the iteration. */ basic_block be = dfs_find_deadend (ENTRY_BLOCK_PTR); gcc_assert (be != NULL); SET_BIT (visited, be->index); stack[sp++] = ei_start (be->preds); } /* The only case the below while fires is when there's an infinite loop. */ } while (sp); /* EXIT_BLOCK is always included. */ post_order[post_order_num++] = EXIT_BLOCK; free (stack); sbitmap_free (visited); return post_order_num; } /* Compute the depth first search order and store in the array PRE_ORDER if nonzero, marking the nodes visited in VISITED. If REV_POST_ORDER is nonzero, return the reverse completion number for each node. Returns the number of nodes visited. A depth first search tries to get as far away from the starting point as quickly as possible. pre_order is a really a preorder numbering of the graph. rev_post_order is really a reverse postorder numbering of the graph. */ int pre_and_rev_post_order_compute (int *pre_order, int *rev_post_order, bool include_entry_exit) { edge_iterator *stack; int sp; int pre_order_num = 0; int rev_post_order_num = n_basic_blocks - 1; sbitmap visited; /* Allocate stack for back-tracking up CFG. */ stack = XNEWVEC (edge_iterator, n_basic_blocks + 1); sp = 0; if (include_entry_exit) { if (pre_order) pre_order[pre_order_num] = ENTRY_BLOCK; pre_order_num++; if (rev_post_order) rev_post_order[rev_post_order_num--] = ENTRY_BLOCK; } else rev_post_order_num -= NUM_FIXED_BLOCKS; /* Allocate bitmap to track nodes that have been visited. */ visited = sbitmap_alloc (last_basic_block); /* None of the nodes in the CFG have been visited yet. */ sbitmap_zero (visited); /* Push the first edge on to the stack. */ stack[sp++] = ei_start (ENTRY_BLOCK_PTR->succs); while (sp) { edge_iterator ei; basic_block src; basic_block dest; /* Look at the edge on the top of the stack. */ ei = stack[sp - 1]; src = ei_edge (ei)->src; dest = ei_edge (ei)->dest; /* Check if the edge destination has been visited yet. */ if (dest != EXIT_BLOCK_PTR && ! TEST_BIT (visited, dest->index)) { /* Mark that we have visited the destination. */ SET_BIT (visited, dest->index); if (pre_order) pre_order[pre_order_num] = dest->index; pre_order_num++; if (EDGE_COUNT (dest->succs) > 0) /* Since the DEST node has been visited for the first time, check its successors. */ stack[sp++] = ei_start (dest->succs); else if (rev_post_order) /* There are no successors for the DEST node so assign its reverse completion number. */ rev_post_order[rev_post_order_num--] = dest->index; } else { if (ei_one_before_end_p (ei) && src != ENTRY_BLOCK_PTR && rev_post_order) /* There are no more successors for the SRC node so assign its reverse completion number. */ rev_post_order[rev_post_order_num--] = src->index; if (!ei_one_before_end_p (ei)) ei_next (&stack[sp - 1]); else sp--; } } free (stack); sbitmap_free (visited); if (include_entry_exit) { if (pre_order) pre_order[pre_order_num] = EXIT_BLOCK; pre_order_num++; if (rev_post_order) rev_post_order[rev_post_order_num--] = EXIT_BLOCK; /* The number of nodes visited should be the number of blocks. */ gcc_assert (pre_order_num == n_basic_blocks); } else /* The number of nodes visited should be the number of blocks minus the entry and exit blocks which are not visited here. */ gcc_assert (pre_order_num == n_basic_blocks - NUM_FIXED_BLOCKS); return pre_order_num; } /* Compute the depth first search order on the _reverse_ graph and store in the array DFS_ORDER, marking the nodes visited in VISITED. Returns the number of nodes visited. The computation is split into three pieces: flow_dfs_compute_reverse_init () creates the necessary data structures. flow_dfs_compute_reverse_add_bb () adds a basic block to the data structures. The block will start the search. flow_dfs_compute_reverse_execute () continues (or starts) the search using the block on the top of the stack, stopping when the stack is empty. flow_dfs_compute_reverse_finish () destroys the necessary data structures. Thus, the user will probably call ..._init(), call ..._add_bb() to add a beginning basic block to the stack, call ..._execute(), possibly add another bb to the stack and again call ..._execute(), ..., and finally call _finish(). */ /* Initialize the data structures used for depth-first search on the reverse graph. If INITIALIZE_STACK is nonzero, the exit block is added to the basic block stack. DATA is the current depth-first search context. If INITIALIZE_STACK is nonzero, there is an element on the stack. */ static void flow_dfs_compute_reverse_init (depth_first_search_ds data) { /* Allocate stack for back-tracking up CFG. */ data->stack = XNEWVEC (basic_block, n_basic_blocks); data->sp = 0; /* Allocate bitmap to track nodes that have been visited. */ data->visited_blocks = sbitmap_alloc (last_basic_block); /* None of the nodes in the CFG have been visited yet. */ sbitmap_zero (data->visited_blocks); return; } /* Add the specified basic block to the top of the dfs data structures. When the search continues, it will start at the block. */ static void flow_dfs_compute_reverse_add_bb (depth_first_search_ds data, basic_block bb) { data->stack[data->sp++] = bb; SET_BIT (data->visited_blocks, bb->index); } /* Continue the depth-first search through the reverse graph starting with the block at the stack's top and ending when the stack is empty. Visited nodes are marked. Returns an unvisited basic block, or NULL if there is none available. */ static basic_block flow_dfs_compute_reverse_execute (depth_first_search_ds data, basic_block last_unvisited) { basic_block bb; edge e; edge_iterator ei; while (data->sp > 0) { bb = data->stack[--data->sp]; /* Perform depth-first search on adjacent vertices. */ FOR_EACH_EDGE (e, ei, bb->preds) if (!TEST_BIT (data->visited_blocks, e->src->index)) flow_dfs_compute_reverse_add_bb (data, e->src); } /* Determine if there are unvisited basic blocks. */ FOR_BB_BETWEEN (bb, last_unvisited, NULL, prev_bb) if (!TEST_BIT (data->visited_blocks, bb->index)) return bb; return NULL; } /* Destroy the data structures needed for depth-first search on the reverse graph. */ static void flow_dfs_compute_reverse_finish (depth_first_search_ds data) { free (data->stack); sbitmap_free (data->visited_blocks); } /* Performs dfs search from BB over vertices satisfying PREDICATE; if REVERSE, go against direction of edges. Returns number of blocks found and their list in RSLT. RSLT can contain at most RSLT_MAX items. */ int dfs_enumerate_from (basic_block bb, int reverse, bool (*predicate) (const_basic_block, const void *), basic_block *rslt, int rslt_max, const void *data) { basic_block *st, lbb; int sp = 0, tv = 0; unsigned size; /* A bitmap to keep track of visited blocks. Allocating it each time this function is called is not possible, since dfs_enumerate_from is often used on small (almost) disjoint parts of cfg (bodies of loops), and allocating a large sbitmap would lead to quadratic behavior. */ static sbitmap visited; static unsigned v_size; #define MARK_VISITED(BB) (SET_BIT (visited, (BB)->index)) #define UNMARK_VISITED(BB) (RESET_BIT (visited, (BB)->index)) #define VISITED_P(BB) (TEST_BIT (visited, (BB)->index)) /* Resize the VISITED sbitmap if necessary. */ size = last_basic_block; if (size < 10) size = 10; if (!visited) { visited = sbitmap_alloc (size); sbitmap_zero (visited); v_size = size; } else if (v_size < size) { /* Ensure that we increase the size of the sbitmap exponentially. */ if (2 * v_size > size) size = 2 * v_size; visited = sbitmap_resize (visited, size, 0); v_size = size; } st = XCNEWVEC (basic_block, rslt_max); rslt[tv++] = st[sp++] = bb; MARK_VISITED (bb); while (sp) { edge e; edge_iterator ei; lbb = st[--sp]; if (reverse) { FOR_EACH_EDGE (e, ei, lbb->preds) if (!VISITED_P (e->src) && predicate (e->src, data)) { gcc_assert (tv != rslt_max); rslt[tv++] = st[sp++] = e->src; MARK_VISITED (e->src); } } else { FOR_EACH_EDGE (e, ei, lbb->succs) if (!VISITED_P (e->dest) && predicate (e->dest, data)) { gcc_assert (tv != rslt_max); rslt[tv++] = st[sp++] = e->dest; MARK_VISITED (e->dest); } } } free (st); for (sp = 0; sp < tv; sp++) UNMARK_VISITED (rslt[sp]); return tv; #undef MARK_VISITED #undef UNMARK_VISITED #undef VISITED_P } /* Compute dominance frontiers, ala Harvey, Ferrante, et al. This algorithm can be found in Timothy Harvey's PhD thesis, at http://www.cs.rice.edu/~harv/dissertation.pdf in the section on iterative dominance algorithms. First, we identify each join point, j (any node with more than one incoming edge is a join point). We then examine each predecessor, p, of j and walk up the dominator tree starting at p. We stop the walk when we reach j's immediate dominator - j is in the dominance frontier of each of the nodes in the walk, except for j's immediate dominator. Intuitively, all of the rest of j's dominators are shared by j's predecessors as well. Since they dominate j, they will not have j in their dominance frontiers. The number of nodes touched by this algorithm is equal to the size of the dominance frontiers, no more, no less. */ static void compute_dominance_frontiers_1 (bitmap *frontiers) { edge p; edge_iterator ei; basic_block b; FOR_EACH_BB (b) { if (EDGE_COUNT (b->preds) >= 2) { FOR_EACH_EDGE (p, ei, b->preds) { basic_block runner = p->src; basic_block domsb; if (runner == ENTRY_BLOCK_PTR) continue; domsb = get_immediate_dominator (CDI_DOMINATORS, b); while (runner != domsb) { if (bitmap_bit_p (frontiers[runner->index], b->index)) break; bitmap_set_bit (frontiers[runner->index], b->index); runner = get_immediate_dominator (CDI_DOMINATORS, runner); } } } } } void compute_dominance_frontiers (bitmap *frontiers) { timevar_push (TV_DOM_FRONTIERS); compute_dominance_frontiers_1 (frontiers); timevar_pop (TV_DOM_FRONTIERS); } /* Given a set of blocks with variable definitions (DEF_BLOCKS), return a bitmap with all the blocks in the iterated dominance frontier of the blocks in DEF_BLOCKS. DFS contains dominance frontier information as returned by compute_dominance_frontiers. The resulting set of blocks are the potential sites where PHI nodes are needed. The caller is responsible for freeing the memory allocated for the return value. */ bitmap compute_idf (bitmap def_blocks, bitmap *dfs) { bitmap_iterator bi; unsigned bb_index, i; VEC(int,heap) *work_stack; bitmap phi_insertion_points; work_stack = VEC_alloc (int, heap, n_basic_blocks); phi_insertion_points = BITMAP_ALLOC (NULL); /* Seed the work list with all the blocks in DEF_BLOCKS. We use VEC_quick_push here for speed. This is safe because we know that the number of definition blocks is no greater than the number of basic blocks, which is the initial capacity of WORK_STACK. */ EXECUTE_IF_SET_IN_BITMAP (def_blocks, 0, bb_index, bi) VEC_quick_push (int, work_stack, bb_index); /* Pop a block off the worklist, add every block that appears in the original block's DF that we have not already processed to the worklist. Iterate until the worklist is empty. Blocks which are added to the worklist are potential sites for PHI nodes. */ while (VEC_length (int, work_stack) > 0) { bb_index = VEC_pop (int, work_stack); /* Since the registration of NEW -> OLD name mappings is done separately from the call to update_ssa, when updating the SSA form, the basic blocks where new and/or old names are defined may have disappeared by CFG cleanup calls. In this case, we may pull a non-existing block from the work stack. */ gcc_assert (bb_index < (unsigned) last_basic_block); EXECUTE_IF_AND_COMPL_IN_BITMAP (dfs[bb_index], phi_insertion_points, 0, i, bi) { /* Use a safe push because if there is a definition of VAR in every basic block, then WORK_STACK may eventually have more than N_BASIC_BLOCK entries. */ VEC_safe_push (int, heap, work_stack, i); bitmap_set_bit (phi_insertion_points, i); } } VEC_free (int, heap, work_stack); return phi_insertion_points; }
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