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1 /* Calculate (post)dominators in slightly super-linear time.
2 Copyright (C) 2000, 2003, 2004, 2005 Free Software Foundation, Inc.
3 Contributed by Michael Matz (matz@ifh.de).
5 This file is part of GCC.
7 GCC is free software; you can redistribute it and/or modify it
8 under the terms of the GNU General Public License as published by
9 the Free Software Foundation; either version 2, or (at your option)
10 any later version.
12 GCC is distributed in the hope that it will be useful, but WITHOUT
13 ANY WARRANTY; without even the implied warranty of MERCHANTABILITY
14 or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public
15 License for more details.
17 You should have received a copy of the GNU General Public License
18 along with GCC; see the file COPYING. If not, write to the Free
19 Software Foundation, 51 Franklin Street, Fifth Floor, Boston, MA
20 02110-1301, USA. */
22 /* This file implements the well known algorithm from Lengauer and Tarjan
23 to compute the dominators in a control flow graph. A basic block D is said
24 to dominate another block X, when all paths from the entry node of the CFG
25 to X go also over D. The dominance relation is a transitive reflexive
26 relation and its minimal transitive reduction is a tree, called the
27 dominator tree. So for each block X besides the entry block exists a
28 block I(X), called the immediate dominator of X, which is the parent of X
29 in the dominator tree.
31 The algorithm computes this dominator tree implicitly by computing for
32 each block its immediate dominator. We use tree balancing and path
33 compression, so it's the O(e*a(e,v)) variant, where a(e,v) is the very
34 slowly growing functional inverse of the Ackerman function. */
47 /* Whether the dominators and the postdominators are available. */
50 /* We name our nodes with integers, beginning with 1. Zero is reserved for
51 'undefined' or 'end of list'. The name of each node is given by the dfs
52 number of the corresponding basic block. Please note, that we include the
53 artificial ENTRY_BLOCK (or EXIT_BLOCK in the post-dom case) in our lists to
54 support multiple entry points. Its dfs number is of course 1. */
56 /* Type of Basic Block aka. TBB */
59 /* We work in a poor-mans object oriented fashion, and carry an instance of
60 this structure through all our 'methods'. It holds various arrays
61 reflecting the (sub)structure of the flowgraph. Most of them are of type
62 TBB and are also indexed by TBB. */
64 struct dom_info
65 {
66 /* The parent of a node in the DFS tree. */
68 /* For a node x key[x] is roughly the node nearest to the root from which
69 exists a way to x only over nodes behind x. Such a node is also called
70 semidominator. */
72 /* The value in path_min[x] is the node y on the path from x to the root of
73 the tree x is in with the smallest key[y]. */
75 /* bucket[x] points to the first node of the set of nodes having x as key. */
77 /* And next_bucket[x] points to the next node. */
79 /* After the algorithm is done, dom[x] contains the immediate dominator
80 of x. */
83 /* The following few fields implement the structures needed for disjoint
84 sets. */
85 /* set_chain[x] is the next node on the path from x to the representant
86 of the set containing x. If set_chain[x]==0 then x is a root. */
88 /* set_size[x] is the number of elements in the set named by x. */
90 /* set_child[x] is used for balancing the tree representing a set. It can
91 be understood as the next sibling of x. */
94 /* If b is the number of a basic block (BB->index), dfs_order[b] is the
95 number of that node in DFS order counted from 1. This is an index
96 into most of the other arrays in this structure. */
98 /* If x is the DFS-index of a node which corresponds with a basic block,
99 dfs_to_bb[x] is that basic block. Note, that in our structure there are
100 more nodes that basic blocks, so only dfs_to_bb[dfs_order[bb->index]]==bb
101 is true for every basic block bb, but not the opposite. */
104 /* This is the next free DFS number when creating the DFS tree. */
106 /* The number of nodes in the DFS tree (==dfsnum-1). */
109 /* Blocks with bits set here have a fake edge to EXIT. These are used
110 to turn a DFS forest into a proper tree. */
111 bitmap fake_exit_edge;
112 };
125 /* Keeps track of the*/
128 /* Helper macro for allocating and initializing an array,
129 for aesthetic reasons. */
130 #define init_ar(var, type, num, content) \
131 do \
132 { \
134 if (! (content)) \
135 (var) = XCNEWVEC (type, num); \
136 else \
137 { \
138 (var) = XNEWVEC (type, (num)); \
139 for (i = 0; i < num; i++) \
140 (var)[i] = (content); \
141 } \
142 } \
143 while (0)
145 /* Allocate all needed memory in a pessimistic fashion (so we round up).
146 This initializes the contents of DI, which already must be allocated. */
148 static void
150 {
171 }
173 #undef init_ar
175 /* Free all allocated memory in DI, but not DI itself. */
177 static void
179 {
192 }
194 /* The nonrecursive variant of creating a DFS tree. DI is our working
195 structure, BB the starting basic block for this tree and REVERSE
196 is true, if predecessors should be visited instead of successors of a
197 node. After this is done all nodes reachable from BB were visited, have
198 assigned their dfs number and are linked together to form a tree. */
200 static void
203 {
204 /* We call this _only_ if bb is not already visited. */
205 edge e;
210 /* Start block (ENTRY_BLOCK_PTR for forward problem, EXIT_BLOCK for backward
211 problem). */
212 basic_block en_block;
213 /* Ending block. */
214 basic_block ex_block;
219 /* Initialize our border blocks, and the first edge. */
221 {
225 }
226 else
227 {
231 }
233 /* When the stack is empty we break out of this loop. */
235 {
236 basic_block bn;
238 /* This loop traverses edges e in depth first manner, and fills the
239 stack. */
241 {
244 /* Deduce from E the current and the next block (BB and BN), and the
245 next edge. */
247 {
250 /* If the next node BN is either already visited or a border
251 block the current edge is useless, and simply overwritten
252 with the next edge out of the current node. */
254 {
257 }
260 }
261 else
262 {
265 {
268 }
271 }
275 /* Fill the DFS tree info calculatable _before_ recursing. */
278 else
284 /* Save the current point in the CFG on the stack, and recurse. */
287 }
293 /* OK. The edge-list was exhausted, meaning normally we would
294 end the recursion. After returning from the recursive call,
295 there were (may be) other statements which were run after a
296 child node was completely considered by DFS. Here is the
297 point to do it in the non-recursive variant.
298 E.g. The block just completed is in e->dest for forward DFS,
299 the block not yet completed (the parent of the one above)
300 in e->src. This could be used e.g. for computing the number of
301 descendants or the tree depth. */
303 }
305 }
307 /* The main entry for calculating the DFS tree or forest. DI is our working
308 structure and REVERSE is true, if we are interested in the reverse flow
309 graph. In that case the result is not necessarily a tree but a forest,
310 because there may be nodes from which the EXIT_BLOCK is unreachable. */
312 static void
314 {
315 /* The first block is the ENTRY_BLOCK (or EXIT_BLOCK if REVERSE). */
324 {
325 /* In the post-dom case we may have nodes without a path to EXIT_BLOCK.
326 They are reverse-unreachable. In the dom-case we disallow such
327 nodes, but in post-dom we have to deal with them.
329 There are two situations in which this occurs. First, noreturn
330 functions. Second, infinite loops. In the first case we need to
331 pretend that there is an edge to the exit block. In the second
332 case, we wind up with a forest. We need to process all noreturn
333 blocks before we know if we've got any infinite loops. */
335 basic_block b;
339 {
341 {
345 }
352 }
355 {
357 {
366 }
367 }
368 }
372 /* This aborts e.g. when there is _no_ path from ENTRY to EXIT at all. */
374 }
376 /* Compress the path from V to the root of its set and update path_min at the
377 same time. After compress(di, V) set_chain[V] is the root of the set V is
378 in and path_min[V] is the node with the smallest key[] value on the path
379 from V to that root. */
381 static void
383 {
384 /* Btw. It's not worth to unrecurse compress() as the depth is usually not
385 greater than 5 even for huge graphs (I've not seen call depth > 4).
386 Also performance wise compress() ranges _far_ behind eval(). */
389 {
394 }
395 }
397 /* Compress the path from V to the set root of V if needed (when the root has
398 changed since the last call). Returns the node with the smallest key[]
399 value on the path from V to the root. */
403 {
404 /* The representant of the set V is in, also called root (as the set
405 representation is a tree). */
408 /* V itself is the root. */
412 /* Compress only if necessary. */
414 {
417 }
421 else
423 }
425 /* This essentially merges the two sets of V and W, giving a single set with
426 the new root V. The internal representation of these disjoint sets is a
427 balanced tree. Currently link(V,W) is only used with V being the parent
428 of W. */
430 static void
432 {
435 /* Rebalance the tree. */
437 {
440 {
443 }
444 else
445 {
448 }
449 }
454 {
458 }
460 /* Merge all subtrees. */
462 {
465 }
466 }
468 /* This calculates the immediate dominators (or post-dominators if REVERSE is
469 true). DI is our working structure and should hold the DFS forest.
470 On return the immediate dominator to node V is in di->dom[V]. */
472 static void
474 {
476 basic_block en_block;
481 else
484 /* Go backwards in DFS order, to first look at the leafs. */
487 {
489 edge e;
497 {
498 /* If this block has a fake edge to exit, process that first. */
500 {
504 }
505 }
507 /* Search all direct predecessors for the smallest node with a path
508 to them. That way we have the smallest node with also a path to
509 us only over nodes behind us. In effect we search for our
510 semidominator. */
512 {
513 TBB k1;
514 basic_block b;
522 {
523 do_fake_exit_edge:
525 }
526 else
529 /* Call eval() only if really needed. If k1 is above V in DFS tree,
530 then we know, that eval(k1) == k1 and key[k1] == k1. */
537 }
544 /* Transform semidominators into dominators. */
546 {
550 else
552 }
553 /* We don't need to cleanup next_bucket[]. */
555 v--;
556 }
558 /* Explicitly define the dominators. */
563 }
565 /* Assign dfs numbers starting from NUM to NODE and its sons. */
567 static void
569 {
575 {
579 }
582 }
584 /* Compute the data necessary for fast resolving of dominator queries in a
585 static dominator tree. */
587 static void
589 {
591 basic_block bb;
599 {
602 }
605 }
607 /* The main entry point into this module. DIR is set depending on whether
608 we want to compute dominators or postdominators. */
610 void
612 {
614 basic_block b;
620 {
624 {
626 }
634 {
639 }
643 }
646 }
648 /* Free dominance information for direction DIR. */
649 void
651 {
652 basic_block bb;
658 {
661 }
666 }
668 /* Return the immediate dominator of basic block BB. */
669 basic_block
671 {
680 }
682 /* Set the immediate dominator of the block possibly removing
683 existing edge. NULL can be used to remove any edge. */
686 basic_block dominated_by)
687 {
693 {
697 }
704 }
706 /* Store all basic blocks immediately dominated by BB into BBS and return
707 their number. */
708 int
710 {
717 {
720 }
723 n++;
731 }
733 /* Find all basic blocks that are immediately dominated (in direction DIR)
734 by some block between N_REGION ones stored in REGION, except for blocks
735 in the REGION itself. The found blocks are stored to DOMS and their number
736 is returned. */
738 unsigned
741 {
743 basic_block dom;
749 dom;
757 }
759 /* Redirect all edges pointing to BB to TO. */
760 void
762 basic_block to)
763 {
772 {
777 }
781 }
783 /* Find first basic block in the tree dominating both BB1 and BB2. */
784 basic_block
786 {
795 }
798 /* Find the nearest common dominator for the basic blocks in BLOCKS,
799 using dominance direction DIR. */
801 basic_block
803 {
805 bitmap_iterator bi;
806 basic_block dom;
815 }
817 /* Given a dominator tree, we can determine whether one thing
818 dominates another in constant time by using two DFS numbers:
820 1. The number for when we visit a node on the way down the tree
821 2. The number for when we visit a node on the way back up the tree
823 You can view these as bounds for the range of dfs numbers the
824 nodes in the subtree of the dominator tree rooted at that node
825 will contain.
827 The dominator tree is always a simple acyclic tree, so there are
828 only three possible relations two nodes in the dominator tree have
829 to each other:
831 1. Node A is above Node B (and thus, Node A dominates node B)
833 A
834 |
835 C
836 / \
837 B D
840 In the above case, DFS_Number_In of A will be <= DFS_Number_In of
841 B, and DFS_Number_Out of A will be >= DFS_Number_Out of B. This is
842 because we must hit A in the dominator tree *before* B on the walk
843 down, and we will hit A *after* B on the walk back up
845 2. Node A is below node B (and thus, node B dominates node A)
848 B
849 |
850 A
851 / \
852 C D
854 In the above case, DFS_Number_In of A will be >= DFS_Number_In of
855 B, and DFS_Number_Out of A will be <= DFS_Number_Out of B.
857 This is because we must hit A in the dominator tree *after* B on
858 the walk down, and we will hit A *before* B on the walk back up
860 3. Node A and B are siblings (and thus, neither dominates the other)
862 C
863 |
864 D
865 / \
866 A B
868 In the above case, DFS_Number_In of A will *always* be <=
869 DFS_Number_In of B, and DFS_Number_Out of A will *always* be <=
870 DFS_Number_Out of B. This is because we will always finish the dfs
871 walk of one of the subtrees before the other, and thus, the dfs
872 numbers for one subtree can't intersect with the range of dfs
873 numbers for the other subtree. If you swap A and B's position in
874 the dominator tree, the comparison changes direction, but the point
875 is that both comparisons will always go the same way if there is no
876 dominance relationship.
878 Thus, it is sufficient to write
880 A_Dominates_B (node A, node B)
881 {
882 return DFS_Number_In(A) <= DFS_Number_In(B)
883 && DFS_Number_Out (A) >= DFS_Number_Out(B);
884 }
886 A_Dominated_by_B (node A, node B)
887 {
888 return DFS_Number_In(A) >= DFS_Number_In(A)
889 && DFS_Number_Out (A) <= DFS_Number_Out(B);
890 } */
892 /* Return TRUE in case BB1 is dominated by BB2. */
893 bool
895 {
905 }
907 /* Verify invariants of dominator structure. */
908 void
910 {
912 basic_block bb;
917 {
918 basic_block dom_bb;
919 basic_block imm_bb;
924 {
927 else
931 }
932 }
935 {
937 {
939 {
942 }
943 }
944 }
947 }
949 /* Determine immediate dominator (or postdominator, according to DIR) of BB,
950 assuming that dominators of other blocks are correct. We also use it to
951 recompute the dominators in a restricted area, by iterating it until it
952 reaches a fixed point. */
954 basic_block
956 {
958 edge e;
959 edge_iterator ei;
964 {
966 {
967 /* Ignore the predecessors that either are not reachable from
968 the entry block, or whose dominator was not determined yet. */
974 }
975 }
976 else
977 {
979 {
982 }
983 }
986 }
988 /* Iteratively recount dominators of BBS. The change is supposed to be local
989 and not to grow further. */
990 void
992 {
1002 {
1005 {
1009 {
1012 }
1013 }
1014 }
1018 }
1020 void
1022 {
1032 }
1034 void
1036 {
1045 }
1047 /* Returns the first son of BB in the dominator or postdominator tree
1048 as determined by DIR. */
1050 basic_block
1052 {
1056 }
1058 /* Returns the next dominance son after BB in the dominator or postdominator
1059 tree as determined by DIR, or NULL if it was the last one. */
1061 basic_block
1063 {
1067 }
1069 /* Returns true if dominance information for direction DIR is available. */
1071 bool
1073 {
1075 }
1077 void
1079 {
1084 }