atomic_dec_test_path: hack around assignments
[smatch.git] / flow.c
blob48755501e464eb0aa77e0a2c6a6a26618d3cdf27
1 /*
2 * Copyright (C) 2004 Linus Torvalds
3 */
5 ///
6 // Flow simplification
7 // -------------------
9 #include <string.h>
10 #include <stdarg.h>
11 #include <stdlib.h>
12 #include <stdio.h>
13 #include <stddef.h>
14 #include <assert.h>
16 #include "parse.h"
17 #include "expression.h"
18 #include "linearize.h"
19 #include "simplify.h"
20 #include "flow.h"
21 #include "target.h"
23 unsigned long bb_generation;
25 ///
26 // remove phi-sources from a removed edge
28 // :note: It's possible to have several edges between the same BBs.
29 // It's common with switches but it's also possible with branches.
30 // This function will only remove a single phi-source per edge.
31 int remove_phisources(struct basic_block *par, struct basic_block *old)
33 struct instruction *insn;
34 int changed = 0;
36 FOR_EACH_PTR(old->insns, insn) {
37 pseudo_t phi;
39 if (!insn->bb)
40 continue;
41 if (insn->opcode != OP_PHI)
42 return changed;
44 // found a phi-node in the target BB,
45 // now look after its phi-sources.
46 FOR_EACH_PTR(insn->phi_list, phi) {
47 struct instruction *phisrc = phi->def;
49 if (phi == VOID)
50 continue;
51 assert(phisrc->phi_node == insn);
52 if (phisrc->bb != par)
53 continue;
54 // found a phi-source corresponding to this edge:
55 // remove it but avoid the recursive killing.
56 REPLACE_CURRENT_PTR(phi, VOID);
57 remove_use(&phisrc->src);
58 phisrc->bb = NULL;
59 changed |= REPEAT_CSE;
60 // Only the first one must be removed.
61 goto next;
62 } END_FOR_EACH_PTR(phi);
63 next: ;
64 } END_FOR_EACH_PTR(insn);
65 return changed;
68 ///
69 // remove all phisources but the one corresponding to the given target
70 static int remove_other_phisources(struct basic_block *bb, struct multijmp_list *list, struct basic_block *target)
72 struct multijmp *jmp;
73 int changed = 0;
75 FOR_EACH_PTR(list, jmp) {
76 if (jmp->target == target) {
77 target = NULL;
78 continue;
80 changed |= remove_phisources(bb, jmp->target);
81 } END_FOR_EACH_PTR(jmp);
82 return changed;
86 * Dammit, if we have a phi-node followed by a conditional
87 * branch on that phi-node, we should damn well be able to
88 * do something about the source. Maybe.
90 static int rewrite_branch(struct basic_block *bb,
91 struct basic_block **ptr,
92 struct basic_block *old,
93 struct basic_block *new)
95 if (*ptr != old || new == old || !bb->ep)
96 return 0;
98 /* We might find new if-conversions or non-dominating CSEs */
99 /* we may also create new dead cycles */
100 repeat_phase |= REPEAT_CSE | REPEAT_CFG_CLEANUP;
101 *ptr = new;
102 replace_bb_in_list(&bb->children, old, new, 1);
103 remove_bb_from_list(&old->parents, bb, 1);
104 add_bb(&new->parents, bb);
105 return 1;
109 * Return the known truth value of a pseudo, or -1 if
110 * it's not known.
112 static int pseudo_truth_value(pseudo_t pseudo)
114 switch (pseudo->type) {
115 case PSEUDO_VAL:
116 return !!pseudo->value;
118 case PSEUDO_REG: {
119 struct instruction *insn = pseudo->def;
121 /* A symbol address is always considered true.. */
122 if (insn->opcode == OP_SYMADDR && insn->target == pseudo)
123 return 1;
125 /* Fall through */
126 default:
127 return -1;
132 * Does a basic block depend on the pseudos that "src" defines?
134 static int bb_depends_on(struct basic_block *target, struct basic_block *src)
136 pseudo_t pseudo;
138 FOR_EACH_PTR(src->defines, pseudo) {
139 if (pseudo_in_list(target->needs, pseudo))
140 return 1;
141 } END_FOR_EACH_PTR(pseudo);
142 return 0;
146 * This really should be handled by bb_depends_on()
147 * which efficiently check the dependence using the
148 * defines - needs liveness info. Problem is that
149 * there is no liveness done on OP_PHI & OP_PHISRC.
151 * This function add the missing dependency checks.
153 static int bb_depends_on_phi(struct basic_block *target, struct basic_block *src)
155 struct instruction *insn;
156 FOR_EACH_PTR(src->insns, insn) {
157 if (!insn->bb)
158 continue;
159 if (insn->opcode != OP_PHI)
160 continue;
161 if (pseudo_in_list(target->needs, insn->target))
162 return 1;
163 } END_FOR_EACH_PTR(insn);
164 return 0;
168 // does the BB contains ignorable instructions but a final branch?
169 // :note: something could be done for phi-sources but ... we'll see.
170 static bool bb_is_forwarder(struct basic_block *bb)
172 struct instruction *insn;
174 FOR_EACH_PTR(bb->insns, insn) {
175 if (!insn->bb)
176 continue;
177 switch (insn->opcode) {
178 case OP_NOP:
179 case OP_INLINED_CALL:
180 continue;
181 case OP_CBR:
182 case OP_BR:
183 return true;
184 default:
185 goto out;
187 } END_FOR_EACH_PTR(insn);
188 out:
189 return false;
193 // check if the sources of a phi-node match with the parent BBs
194 static bool phi_check(struct instruction *node)
196 struct basic_block *bb;
197 pseudo_t phi;
199 PREPARE_PTR_LIST(node->bb->parents, bb);
200 FOR_EACH_PTR(node->phi_list, phi) {
201 if (phi == VOID || !phi->def)
202 continue;
203 if (phi->def->bb != bb)
204 return false;
205 NEXT_PTR_LIST(bb);
206 } END_FOR_EACH_PTR(phi);
207 if (bb)
208 return false;
209 FINISH_PTR_LIST(bb);
210 return true;
214 * When we reach here, we have:
215 * - a basic block that ends in a conditional branch and
216 * that has no side effects apart from the pseudos it
217 * may change.
218 * - the phi-node that the conditional branch depends on
219 * - full pseudo liveness information
221 * We need to check if any of the _sources_ of the phi-node
222 * may be constant, and not actually need this block at all.
224 static int try_to_simplify_bb(struct basic_block *bb, struct instruction *first, struct instruction *second)
226 int changed = 0;
227 pseudo_t phi;
228 int bogus;
231 * This a due to improper dominance tracking during
232 * simplify_symbol_usage()/conversion to SSA form.
233 * No sane simplification can be done when we have this.
235 bogus = !phi_check(first);
237 FOR_EACH_PTR(first->phi_list, phi) {
238 struct instruction *def = phi->def;
239 struct basic_block *source, *target;
240 pseudo_t pseudo;
241 struct instruction *br;
242 int cond;
244 if (!def)
245 continue;
246 source = def->bb;
247 pseudo = def->src1;
248 if (!pseudo || !source)
249 continue;
250 br = last_instruction(source->insns);
251 if (!br)
252 continue;
253 if (br->opcode != OP_CBR && br->opcode != OP_BR)
254 continue;
255 cond = pseudo_truth_value(pseudo);
256 if (cond < 0)
257 continue;
258 target = cond ? second->bb_true : second->bb_false;
259 if (bb_depends_on(target, bb))
260 continue;
261 if (bb_depends_on_phi(target, bb))
262 continue;
263 changed |= rewrite_branch(source, &br->bb_true, bb, target);
264 changed |= rewrite_branch(source, &br->bb_false, bb, target);
265 if (changed && !bogus)
266 kill_use(THIS_ADDRESS(phi));
267 } END_FOR_EACH_PTR(phi);
268 return changed;
271 static int bb_has_side_effects(struct basic_block *bb)
273 struct instruction *insn;
274 FOR_EACH_PTR(bb->insns, insn) {
275 if (!insn->bb)
276 continue;
277 switch (insn->opcode) {
278 case OP_CALL:
279 /* FIXME! This should take "const" etc into account */
280 return 1;
282 case OP_LOAD:
283 if (!insn->type)
284 return 1;
285 if (insn->is_volatile)
286 return 1;
287 continue;
289 case OP_STORE:
290 case OP_CONTEXT:
291 return 1;
293 case OP_ASM:
294 /* FIXME! This should take "volatile" etc into account */
295 return 1;
297 default:
298 continue;
300 } END_FOR_EACH_PTR(insn);
301 return 0;
304 static int simplify_phi_branch(struct basic_block *bb, struct instruction *br)
306 pseudo_t cond = br->cond;
307 struct instruction *def;
309 if (cond->type != PSEUDO_REG)
310 return 0;
311 def = cond->def;
312 if (def->bb != bb || def->opcode != OP_PHI)
313 return 0;
314 if (bb_has_side_effects(bb))
315 return 0;
316 return try_to_simplify_bb(bb, def, br);
319 static int simplify_branch_branch(struct basic_block *bb, struct instruction *br,
320 struct basic_block **target_p, int bb_true)
322 struct basic_block *target = *target_p, *final;
323 struct instruction *insn;
324 int retval;
326 if (target == bb)
327 return 0;
328 insn = last_instruction(target->insns);
329 if (!insn || insn->opcode != OP_CBR || insn->cond != br->cond)
330 return 0;
332 * Ahhah! We've found a branch to a branch on the same conditional!
333 * Now we just need to see if we can rewrite the branch..
335 retval = 0;
336 final = bb_true ? insn->bb_true : insn->bb_false;
337 if (bb_has_side_effects(target))
338 goto try_to_rewrite_target;
339 if (bb_depends_on(final, target))
340 goto try_to_rewrite_target;
341 if (bb_depends_on_phi(final, target))
342 return 0;
343 return rewrite_branch(bb, target_p, target, final);
345 try_to_rewrite_target:
347 * If we're the only parent, at least we can rewrite the
348 * now-known second branch.
350 if (bb_list_size(target->parents) != 1)
351 return retval;
352 convert_to_jump(insn, final);
353 return 1;
356 static int simplify_one_branch(struct basic_block *bb, struct instruction *br)
358 if (simplify_phi_branch(bb, br))
359 return 1;
360 return simplify_branch_branch(bb, br, &br->bb_true, 1) |
361 simplify_branch_branch(bb, br, &br->bb_false, 0);
364 static int simplify_branch_nodes(struct entrypoint *ep)
366 int changed = 0;
367 struct basic_block *bb;
369 FOR_EACH_PTR(ep->bbs, bb) {
370 struct instruction *br = last_instruction(bb->insns);
372 if (!br || br->opcode != OP_CBR)
373 continue;
374 changed |= simplify_one_branch(bb, br);
375 } END_FOR_EACH_PTR(bb);
376 return changed;
380 * This is called late - when we have intra-bb liveness information..
382 int simplify_flow(struct entrypoint *ep)
384 return simplify_branch_nodes(ep);
387 static inline void concat_user_list(struct pseudo_user_list *src, struct pseudo_user_list **dst)
389 copy_ptr_list((struct ptr_list **)dst, (struct ptr_list *)src);
392 void convert_instruction_target(struct instruction *insn, pseudo_t src)
394 pseudo_t target;
395 struct pseudo_user *pu;
397 * Go through the "insn->users" list and replace them all..
399 target = insn->target;
400 if (target == src)
401 return;
402 FOR_EACH_PTR(target->users, pu) {
403 if (*pu->userp != VOID) {
404 assert(*pu->userp == target);
405 *pu->userp = src;
407 } END_FOR_EACH_PTR(pu);
408 if (has_use_list(src))
409 concat_user_list(target->users, &src->users);
410 target->users = NULL;
413 static int overlapping_memop(struct instruction *a, struct instruction *b)
415 unsigned int a_start = bytes_to_bits(a->offset);
416 unsigned int b_start = bytes_to_bits(b->offset);
417 unsigned int a_size = a->size;
418 unsigned int b_size = b->size;
420 if (a_size + a_start <= b_start)
421 return 0;
422 if (b_size + b_start <= a_start)
423 return 0;
424 return 1;
427 static inline int same_memop(struct instruction *a, struct instruction *b)
429 return a->offset == b->offset && a->size == b->size;
432 static inline int distinct_symbols(pseudo_t a, pseudo_t b)
434 if (a->type != PSEUDO_SYM)
435 return 0;
436 if (b->type != PSEUDO_SYM)
437 return 0;
438 return a->sym != b->sym;
442 * Return 1 if "dom" dominates the access to "pseudo"
443 * in "insn".
445 * Return 0 if it doesn't, and -1 if you don't know.
447 int dominates(struct instruction *insn, struct instruction *dom, int local)
449 switch (dom->opcode) {
450 case OP_CALL: case OP_ENTRY:
451 return local ? 0 : -1;
452 case OP_LOAD: case OP_STORE:
453 break;
454 case OP_ASM:
455 if (dom->clobber_memory)
456 return -1;
457 if (dom->output_memory)
458 return -1;
459 return 0;
460 default:
461 return 0;
464 if (dom->src != insn->src) {
465 if (local)
466 return 0;
467 /* We don't think two explicitly different symbols ever alias */
468 if (distinct_symbols(insn->src, dom->src))
469 return 0;
470 /* We could try to do some alias analysis here */
471 return -1;
473 if (!same_memop(insn, dom)) {
474 if (!overlapping_memop(insn, dom))
475 return 0;
476 return -1;
478 return 1;
481 /* Kill a pseudo that is dead on exit from the bb */
482 // The context is:
483 // * the variable is not global but may have its address used (local/non-local)
484 // * the stores are only needed by others functions which would do some
485 // loads via the escaped address
486 // We start by the terminating BB (normal exit BB + no-return/unreachable)
487 // We walkup the BB' intruction backward
488 // * we're only concerned by loads, stores & calls
489 // * if we reach a call -> we have to stop if var is non-local
490 // * if we reach a load of our var -> we have to stop
491 // * if we reach a store of our var -> we can kill it, it's dead
492 // * we can ignore other stores & loads if the var is local
493 // * if we reach another store or load done via non-symbol access
494 // (so done via some address calculation) -> we have to stop
495 // If we reach the top of the BB we can recurse into the parents BBs.
496 static void kill_dead_stores_bb(pseudo_t pseudo, unsigned long generation, struct basic_block *bb, int local)
498 struct instruction *insn;
499 struct basic_block *parent;
501 if (bb->generation == generation)
502 return;
503 bb->generation = generation;
504 FOR_EACH_PTR_REVERSE(bb->insns, insn) {
505 if (!insn->bb)
506 continue;
507 switch (insn->opcode) {
508 case OP_LOAD:
509 if (insn->src == pseudo)
510 return;
511 break;
512 case OP_STORE:
513 if (insn->src == pseudo) {
514 kill_instruction_force(insn);
515 continue;
517 break;
518 case OP_CALL:
519 if (!local)
520 return;
521 default:
522 continue;
524 if (!local && insn->src->type != PSEUDO_SYM)
525 return;
526 } END_FOR_EACH_PTR_REVERSE(insn);
528 FOR_EACH_PTR(bb->parents, parent) {
529 if (bb_list_size(parent->children) > 1)
530 continue;
531 kill_dead_stores_bb(pseudo, generation, parent, local);
532 } END_FOR_EACH_PTR(parent);
535 void check_access(struct instruction *insn)
537 pseudo_t pseudo = insn->src;
539 if (insn->bb && pseudo->type == PSEUDO_SYM) {
540 int offset = insn->offset, bit = bytes_to_bits(offset) + insn->size;
541 struct symbol *sym = pseudo->sym;
543 if (sym->bit_size > 0 && (offset < 0 || bit > sym->bit_size)) {
544 if (insn->tainted)
545 return;
546 warning(insn->pos, "invalid access %s '%s' (%d %d)",
547 offset < 0 ? "below" : "past the end of",
548 show_ident(sym->ident), offset,
549 bits_to_bytes(sym->bit_size));
550 insn->tainted = 1;
555 static struct pseudo_user *first_user(pseudo_t p)
557 struct pseudo_user *pu;
558 FOR_EACH_PTR(p->users, pu) {
559 if (!pu)
560 continue;
561 return pu;
562 } END_FOR_EACH_PTR(pu);
563 return NULL;
566 void kill_dead_stores(struct entrypoint *ep, pseudo_t addr, int local)
568 unsigned long generation;
569 struct basic_block *bb;
571 switch (pseudo_user_list_size(addr->users)) {
572 case 0:
573 return;
574 case 1:
575 if (local) {
576 struct pseudo_user *pu = first_user(addr);
577 struct instruction *insn = pu->insn;
578 if (insn->opcode == OP_STORE) {
579 kill_instruction_force(insn);
580 return;
583 default:
584 break;
587 generation = ++bb_generation;
588 FOR_EACH_PTR(ep->bbs, bb) {
589 if (bb->children)
590 continue;
591 kill_dead_stores_bb(addr, generation, bb, local);
592 } END_FOR_EACH_PTR(bb);
595 static void mark_bb_reachable(struct basic_block *bb, unsigned long generation)
597 struct basic_block *child;
599 if (bb->generation == generation)
600 return;
601 bb->generation = generation;
602 FOR_EACH_PTR(bb->children, child) {
603 mark_bb_reachable(child, generation);
604 } END_FOR_EACH_PTR(child);
607 static void kill_defs(struct instruction *insn)
609 pseudo_t target = insn->target;
611 if (!has_use_list(target))
612 return;
613 if (target->def != insn)
614 return;
616 convert_instruction_target(insn, VOID);
619 void kill_bb(struct basic_block *bb)
621 struct instruction *insn;
622 struct basic_block *child, *parent;
624 FOR_EACH_PTR(bb->insns, insn) {
625 if (!insn->bb)
626 continue;
627 kill_instruction_force(insn);
628 kill_defs(insn);
630 * We kill unreachable instructions even if they
631 * otherwise aren't "killable" (e.g. volatile loads)
633 } END_FOR_EACH_PTR(insn);
634 bb->insns = NULL;
636 FOR_EACH_PTR(bb->children, child) {
637 remove_bb_from_list(&child->parents, bb, 0);
638 } END_FOR_EACH_PTR(child);
639 bb->children = NULL;
641 FOR_EACH_PTR(bb->parents, parent) {
642 remove_bb_from_list(&parent->children, bb, 0);
643 } END_FOR_EACH_PTR(parent);
644 bb->parents = NULL;
647 void kill_unreachable_bbs(struct entrypoint *ep)
649 struct basic_block *bb;
650 unsigned long generation = ++bb_generation;
652 mark_bb_reachable(ep->entry->bb, generation);
653 FOR_EACH_PTR(ep->bbs, bb) {
654 if (bb->generation == generation)
655 continue;
656 /* Mark it as being dead */
657 kill_bb(bb);
658 bb->ep = NULL;
659 DELETE_CURRENT_PTR(bb);
660 } END_FOR_EACH_PTR(bb);
661 PACK_PTR_LIST(&ep->bbs);
664 static int rewrite_parent_branch(struct basic_block *bb, struct basic_block *old, struct basic_block *new)
666 int changed = 0;
667 struct instruction *insn = last_instruction(bb->insns);
669 if (!insn)
670 return 0;
672 /* Infinite loops: let's not "optimize" them.. */
673 if (old == new)
674 return 0;
676 switch (insn->opcode) {
677 case OP_CBR:
678 changed |= rewrite_branch(bb, &insn->bb_false, old, new);
679 /* fall through */
680 case OP_BR:
681 changed |= rewrite_branch(bb, &insn->bb_true, old, new);
682 assert(changed);
683 return changed;
684 case OP_SWITCH: {
685 struct multijmp *jmp;
686 FOR_EACH_PTR(insn->multijmp_list, jmp) {
687 changed |= rewrite_branch(bb, &jmp->target, old, new);
688 } END_FOR_EACH_PTR(jmp);
689 assert(changed);
690 return changed;
692 default:
693 return 0;
697 static struct basic_block * rewrite_branch_bb(struct basic_block *bb, struct instruction *br)
699 struct basic_block *parent;
700 struct basic_block *target = br->bb_true;
702 if (br->opcode == OP_CBR) {
703 pseudo_t cond = br->cond;
704 if (cond->type != PSEUDO_VAL)
705 return NULL;
706 target = cond->value ? target : br->bb_false;
710 * We can't do FOR_EACH_PTR() here, because the parent list
711 * may change when we rewrite the parent.
713 while ((parent = first_basic_block(bb->parents)) != NULL) {
714 if (!rewrite_parent_branch(parent, bb, target))
715 return NULL;
717 return target;
720 static void vrfy_bb_in_list(struct basic_block *bb, struct basic_block_list *list)
722 if (bb) {
723 struct basic_block *tmp;
724 int no_bb_in_list = 0;
726 FOR_EACH_PTR(list, tmp) {
727 if (bb == tmp)
728 return;
729 } END_FOR_EACH_PTR(tmp);
730 assert(no_bb_in_list);
734 static void vrfy_parents(struct basic_block *bb)
736 struct basic_block *tmp;
737 FOR_EACH_PTR(bb->parents, tmp) {
738 vrfy_bb_in_list(bb, tmp->children);
739 } END_FOR_EACH_PTR(tmp);
742 static void vrfy_children(struct basic_block *bb)
744 struct basic_block *tmp;
745 struct instruction *br = last_instruction(bb->insns);
747 if (!br) {
748 assert(!bb->children);
749 return;
751 switch (br->opcode) {
752 struct multijmp *jmp;
753 case OP_CBR:
754 vrfy_bb_in_list(br->bb_false, bb->children);
755 /* fall through */
756 case OP_BR:
757 vrfy_bb_in_list(br->bb_true, bb->children);
758 break;
759 case OP_SWITCH:
760 case OP_COMPUTEDGOTO:
761 FOR_EACH_PTR(br->multijmp_list, jmp) {
762 vrfy_bb_in_list(jmp->target, bb->children);
763 } END_FOR_EACH_PTR(jmp);
764 break;
765 default:
766 break;
769 FOR_EACH_PTR(bb->children, tmp) {
770 vrfy_bb_in_list(bb, tmp->parents);
771 } END_FOR_EACH_PTR(tmp);
774 static void vrfy_bb_flow(struct basic_block *bb)
776 vrfy_children(bb);
777 vrfy_parents(bb);
780 void vrfy_flow(struct entrypoint *ep)
782 struct basic_block *bb;
783 struct basic_block *entry = ep->entry->bb;
785 FOR_EACH_PTR(ep->bbs, bb) {
786 if (bb == entry)
787 entry = NULL;
788 vrfy_bb_flow(bb);
789 } END_FOR_EACH_PTR(bb);
790 assert(!entry);
794 // change a switch or a conditional branch into a branch
795 int convert_to_jump(struct instruction *insn, struct basic_block *target)
797 struct basic_block *bb = insn->bb;
798 struct basic_block *child;
799 int changed = REPEAT_CSE;
801 switch (insn->opcode) {
802 case OP_CBR:
803 changed |= remove_phisources(insn->bb, insn->bb_true == target ? insn->bb_false : insn->bb_true);
804 break;
805 case OP_SWITCH:
806 changed |= remove_other_phisources(insn->bb, insn->multijmp_list, target);
807 break;
809 kill_use(&insn->cond);
810 insn->bb_true = target;
811 insn->bb_false = NULL;
812 insn->cond = NULL;
813 insn->size = 0;
814 insn->opcode = OP_BR;
816 FOR_EACH_PTR(bb->children, child) {
817 if (child == target) {
818 target = NULL; // leave first occurence
819 continue;
821 DELETE_CURRENT_PTR(child);
822 remove_bb_from_list(&child->parents, bb, 1);
823 changed |= REPEAT_CFG_CLEANUP;
824 } END_FOR_EACH_PTR(child);
825 PACK_PTR_LIST(&bb->children);
826 repeat_phase |= changed;
827 return changed;
830 static int retarget_parents(struct basic_block *bb, struct basic_block *target)
832 struct basic_block *parent;
835 * We can't do FOR_EACH_PTR() here, because the parent list
836 * may change when we rewrite the parent.
838 while ((parent = first_basic_block(bb->parents))) {
839 if (!rewrite_parent_branch(parent, bb, target))
840 return 0;
842 kill_bb(bb);
843 return REPEAT_CFG_CLEANUP;
846 static void remove_merging_phisrc(struct instruction *insn, struct basic_block *bot)
848 struct instruction *node = insn->phi_node;
849 pseudo_t phi;
851 if (!node) {
852 kill_instruction(insn);
853 return;
856 FOR_EACH_PTR(node->phi_list, phi) {
857 struct instruction *phisrc;
859 if (phi == VOID)
860 continue;
861 phisrc = phi->def;
862 if (phisrc->bb == bot) {
863 kill_instruction(insn);
864 return;
866 } END_FOR_EACH_PTR(phi);
869 static void remove_merging_phi(struct basic_block *top, struct instruction *insn)
871 pseudo_t phi;
873 FOR_EACH_PTR(insn->phi_list, phi) {
874 struct instruction *def;
876 if (phi == VOID)
877 continue;
879 def = phi->def;
880 if (def->bb != top)
881 continue;
883 convert_instruction_target(insn, def->src);
884 kill_instruction(def);
885 kill_instruction(insn);
886 } END_FOR_EACH_PTR(phi);
890 // merge two BBs
891 // @top: the first BB to be merged
892 // @bot: the second BB to be merged
893 static int merge_bb(struct basic_block *top, struct basic_block *bot)
895 struct instruction *insn;
896 struct basic_block *bb;
898 if (top == bot)
899 return 0;
901 top->children = bot->children;
902 bot->children = NULL;
903 bot->parents = NULL;
905 FOR_EACH_PTR(top->children, bb) {
906 replace_bb_in_list(&bb->parents, bot, top, 1);
907 } END_FOR_EACH_PTR(bb);
909 FOR_EACH_PTR(top->insns, insn) {
910 if (!insn->bb)
911 continue;
912 if (insn->opcode != OP_PHISOURCE)
913 continue;
914 remove_merging_phisrc(insn, bot);
915 } END_FOR_EACH_PTR(insn);
917 kill_instruction(delete_last_instruction(&top->insns));
918 FOR_EACH_PTR(bot->insns, insn) {
919 if (!insn->bb)
920 continue;
921 assert(insn->bb == bot);
922 switch (insn->opcode) {
923 case OP_PHI:
924 remove_merging_phi(top, insn);
925 continue;
927 insn->bb = top;
928 add_instruction(&top->insns, insn);
929 } END_FOR_EACH_PTR(insn);
930 bot->insns = NULL;
931 bot->ep = NULL;
932 return REPEAT_CFG_CLEANUP;
936 // early simplification of the CFG
937 // Three things are done here:
938 // # inactive BB are removed
939 // # branches to a 'forwarder' BB are redirected to the forwardee.
940 // # merge single-child/single-parent BBs.
941 int simplify_cfg_early(struct entrypoint *ep)
943 struct basic_block *bb;
944 int changed = 0;
946 FOR_EACH_PTR_REVERSE(ep->bbs, bb) {
947 struct instruction *insn;
948 struct basic_block *tgt;
950 if (!bb->ep) {
951 DELETE_CURRENT_PTR(bb);
952 changed = REPEAT_CFG_CLEANUP;
953 continue;
956 insn = last_instruction(bb->insns);
957 if (!insn)
958 continue;
959 switch (insn->opcode) {
960 case OP_BR:
961 tgt = insn->bb_true;
962 if (bb_is_forwarder(bb))
963 changed |= retarget_parents(bb, tgt);
964 else if (bb_list_size(tgt->parents) == 1)
965 changed |= merge_bb(bb, tgt);
966 break;
968 } END_FOR_EACH_PTR_REVERSE(bb);
969 return changed;
972 void pack_basic_blocks(struct entrypoint *ep)
974 struct basic_block *bb;
976 /* See if we can merge a bb into another one.. */
977 FOR_EACH_PTR(ep->bbs, bb) {
978 struct instruction *first;
979 struct basic_block *parent, *child, *last;
981 if (!bb_reachable(bb))
982 continue;
985 * Just a branch?
987 FOR_EACH_PTR(bb->insns, first) {
988 if (!first->bb)
989 continue;
990 switch (first->opcode) {
991 case OP_NOP:
992 case OP_INLINED_CALL:
993 continue;
994 case OP_CBR:
995 case OP_BR: {
996 struct basic_block *replace;
997 replace = rewrite_branch_bb(bb, first);
998 if (replace) {
999 kill_bb(bb);
1000 goto no_merge;
1003 /* fallthrough */
1004 default:
1005 goto out;
1007 } END_FOR_EACH_PTR(first);
1009 out:
1011 * See if we only have one parent..
1013 last = NULL;
1014 FOR_EACH_PTR(bb->parents, parent) {
1015 if (last) {
1016 if (last != parent)
1017 goto no_merge;
1018 continue;
1020 last = parent;
1021 } END_FOR_EACH_PTR(parent);
1023 parent = last;
1024 if (!parent || parent == bb)
1025 continue;
1028 * Goodie. See if the parent can merge..
1030 FOR_EACH_PTR(parent->children, child) {
1031 if (child != bb)
1032 goto no_merge;
1033 } END_FOR_EACH_PTR(child);
1035 repeat_phase |= merge_bb(parent, bb);
1037 no_merge:
1038 /* nothing to do */;
1039 } END_FOR_EACH_PTR(bb);