PR debug/42767
[official-gcc/alias-decl.git] / gcc / loop-iv.c
blob16e9a52697dafbd76784ff9fa706edefc8ac01f9
1 /* Rtl-level induction variable analysis.
2 Copyright (C) 2004, 2005, 2006, 2007, 2008, 2009
3 Free Software Foundation, Inc.
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 the
9 Free Software Foundation; either version 3, or (at your option) any
10 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 or
14 FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
15 for more details.
17 You should have received a copy of the GNU General Public License
18 along with GCC; see the file COPYING3. If not see
19 <http://www.gnu.org/licenses/>. */
21 /* This is a simple analysis of induction variables of the loop. The major use
22 is for determining the number of iterations of a loop for loop unrolling,
23 doloop optimization and branch prediction. The iv information is computed
24 on demand.
26 Induction variables are analyzed by walking the use-def chains. When
27 a basic induction variable (biv) is found, it is cached in the bivs
28 hash table. When register is proved to be a biv, its description
29 is stored to DF_REF_DATA of the def reference.
31 The analysis works always with one loop -- you must call
32 iv_analysis_loop_init (loop) for it. All the other functions then work with
33 this loop. When you need to work with another loop, just call
34 iv_analysis_loop_init for it. When you no longer need iv analysis, call
35 iv_analysis_done () to clean up the memory.
37 The available functions are:
39 iv_analyze (insn, reg, iv): Stores the description of the induction variable
40 corresponding to the use of register REG in INSN to IV. Returns true if
41 REG is an induction variable in INSN. false otherwise.
42 If use of REG is not found in INSN, following insns are scanned (so that
43 we may call this function on insn returned by get_condition).
44 iv_analyze_result (insn, def, iv): Stores to IV the description of the iv
45 corresponding to DEF, which is a register defined in INSN.
46 iv_analyze_expr (insn, rhs, mode, iv): Stores to IV the description of iv
47 corresponding to expression EXPR evaluated at INSN. All registers used bu
48 EXPR must also be used in INSN.
51 #include "config.h"
52 #include "system.h"
53 #include "coretypes.h"
54 #include "tm.h"
55 #include "rtl.h"
56 #include "hard-reg-set.h"
57 #include "obstack.h"
58 #include "basic-block.h"
59 #include "cfgloop.h"
60 #include "expr.h"
61 #include "intl.h"
62 #include "output.h"
63 #include "toplev.h"
64 #include "df.h"
65 #include "hashtab.h"
67 /* Possible return values of iv_get_reaching_def. */
69 enum iv_grd_result
71 /* More than one reaching def, or reaching def that does not
72 dominate the use. */
73 GRD_INVALID,
75 /* The use is trivial invariant of the loop, i.e. is not changed
76 inside the loop. */
77 GRD_INVARIANT,
79 /* The use is reached by initial value and a value from the
80 previous iteration. */
81 GRD_MAYBE_BIV,
83 /* The use has single dominating def. */
84 GRD_SINGLE_DOM
87 /* Information about a biv. */
89 struct biv_entry
91 unsigned regno; /* The register of the biv. */
92 struct rtx_iv iv; /* Value of the biv. */
95 static bool clean_slate = true;
97 static unsigned int iv_ref_table_size = 0;
99 /* Table of rtx_ivs indexed by the df_ref uid field. */
100 static struct rtx_iv ** iv_ref_table;
102 /* Induction variable stored at the reference. */
103 #define DF_REF_IV(REF) iv_ref_table[DF_REF_ID(REF)]
104 #define DF_REF_IV_SET(REF, IV) iv_ref_table[DF_REF_ID(REF)] = (IV)
106 /* The current loop. */
108 static struct loop *current_loop;
110 /* Bivs of the current loop. */
112 static htab_t bivs;
114 static bool iv_analyze_op (rtx, rtx, struct rtx_iv *);
116 /* Dumps information about IV to FILE. */
118 extern void dump_iv_info (FILE *, struct rtx_iv *);
119 void
120 dump_iv_info (FILE *file, struct rtx_iv *iv)
122 if (!iv->base)
124 fprintf (file, "not simple");
125 return;
128 if (iv->step == const0_rtx
129 && !iv->first_special)
130 fprintf (file, "invariant ");
132 print_rtl (file, iv->base);
133 if (iv->step != const0_rtx)
135 fprintf (file, " + ");
136 print_rtl (file, iv->step);
137 fprintf (file, " * iteration");
139 fprintf (file, " (in %s)", GET_MODE_NAME (iv->mode));
141 if (iv->mode != iv->extend_mode)
142 fprintf (file, " %s to %s",
143 rtx_name[iv->extend],
144 GET_MODE_NAME (iv->extend_mode));
146 if (iv->mult != const1_rtx)
148 fprintf (file, " * ");
149 print_rtl (file, iv->mult);
151 if (iv->delta != const0_rtx)
153 fprintf (file, " + ");
154 print_rtl (file, iv->delta);
156 if (iv->first_special)
157 fprintf (file, " (first special)");
160 /* Generates a subreg to get the least significant part of EXPR (in mode
161 INNER_MODE) to OUTER_MODE. */
164 lowpart_subreg (enum machine_mode outer_mode, rtx expr,
165 enum machine_mode inner_mode)
167 return simplify_gen_subreg (outer_mode, expr, inner_mode,
168 subreg_lowpart_offset (outer_mode, inner_mode));
171 static void
172 check_iv_ref_table_size (void)
174 if (iv_ref_table_size < DF_DEFS_TABLE_SIZE())
176 unsigned int new_size = DF_DEFS_TABLE_SIZE () + (DF_DEFS_TABLE_SIZE () / 4);
177 iv_ref_table = XRESIZEVEC (struct rtx_iv *, iv_ref_table, new_size);
178 memset (&iv_ref_table[iv_ref_table_size], 0,
179 (new_size - iv_ref_table_size) * sizeof (struct rtx_iv *));
180 iv_ref_table_size = new_size;
185 /* Checks whether REG is a well-behaved register. */
187 static bool
188 simple_reg_p (rtx reg)
190 unsigned r;
192 if (GET_CODE (reg) == SUBREG)
194 if (!subreg_lowpart_p (reg))
195 return false;
196 reg = SUBREG_REG (reg);
199 if (!REG_P (reg))
200 return false;
202 r = REGNO (reg);
203 if (HARD_REGISTER_NUM_P (r))
204 return false;
206 if (GET_MODE_CLASS (GET_MODE (reg)) != MODE_INT)
207 return false;
209 return true;
212 /* Clears the information about ivs stored in df. */
214 static void
215 clear_iv_info (void)
217 unsigned i, n_defs = DF_DEFS_TABLE_SIZE ();
218 struct rtx_iv *iv;
220 check_iv_ref_table_size ();
221 for (i = 0; i < n_defs; i++)
223 iv = iv_ref_table[i];
224 if (iv)
226 free (iv);
227 iv_ref_table[i] = NULL;
231 htab_empty (bivs);
234 /* Returns hash value for biv B. */
236 static hashval_t
237 biv_hash (const void *b)
239 return ((const struct biv_entry *) b)->regno;
242 /* Compares biv B and register R. */
244 static int
245 biv_eq (const void *b, const void *r)
247 return ((const struct biv_entry *) b)->regno == REGNO ((const_rtx) r);
250 /* Prepare the data for an induction variable analysis of a LOOP. */
252 void
253 iv_analysis_loop_init (struct loop *loop)
255 basic_block *body = get_loop_body_in_dom_order (loop), bb;
256 bitmap blocks = BITMAP_ALLOC (NULL);
257 unsigned i;
259 current_loop = loop;
261 /* Clear the information from the analysis of the previous loop. */
262 if (clean_slate)
264 df_set_flags (DF_EQ_NOTES + DF_DEFER_INSN_RESCAN);
265 bivs = htab_create (10, biv_hash, biv_eq, free);
266 clean_slate = false;
268 else
269 clear_iv_info ();
271 for (i = 0; i < loop->num_nodes; i++)
273 bb = body[i];
274 bitmap_set_bit (blocks, bb->index);
276 /* Get rid of the ud chains before processing the rescans. Then add
277 the problem back. */
278 df_remove_problem (df_chain);
279 df_process_deferred_rescans ();
280 df_chain_add_problem (DF_UD_CHAIN);
281 df_note_add_problem ();
282 df_set_blocks (blocks);
283 df_analyze ();
284 if (dump_file)
285 df_dump_region (dump_file);
287 check_iv_ref_table_size ();
288 BITMAP_FREE (blocks);
289 free (body);
292 /* Finds the definition of REG that dominates loop latch and stores
293 it to DEF. Returns false if there is not a single definition
294 dominating the latch. If REG has no definition in loop, DEF
295 is set to NULL and true is returned. */
297 static bool
298 latch_dominating_def (rtx reg, df_ref *def)
300 df_ref single_rd = NULL, adef;
301 unsigned regno = REGNO (reg);
302 struct df_rd_bb_info *bb_info = DF_RD_BB_INFO (current_loop->latch);
304 for (adef = DF_REG_DEF_CHAIN (regno); adef; adef = DF_REF_NEXT_REG (adef))
306 if (!bitmap_bit_p (df->blocks_to_analyze, DF_REF_BBNO (adef))
307 || !bitmap_bit_p (bb_info->out, DF_REF_ID (adef)))
308 continue;
310 /* More than one reaching definition. */
311 if (single_rd)
312 return false;
314 if (!just_once_each_iteration_p (current_loop, DF_REF_BB (adef)))
315 return false;
317 single_rd = adef;
320 *def = single_rd;
321 return true;
324 /* Gets definition of REG reaching its use in INSN and stores it to DEF. */
326 static enum iv_grd_result
327 iv_get_reaching_def (rtx insn, rtx reg, df_ref *def)
329 df_ref use, adef;
330 basic_block def_bb, use_bb;
331 rtx def_insn;
332 bool dom_p;
334 *def = NULL;
335 if (!simple_reg_p (reg))
336 return GRD_INVALID;
337 if (GET_CODE (reg) == SUBREG)
338 reg = SUBREG_REG (reg);
339 gcc_assert (REG_P (reg));
341 use = df_find_use (insn, reg);
342 gcc_assert (use != NULL);
344 if (!DF_REF_CHAIN (use))
345 return GRD_INVARIANT;
347 /* More than one reaching def. */
348 if (DF_REF_CHAIN (use)->next)
349 return GRD_INVALID;
351 adef = DF_REF_CHAIN (use)->ref;
353 /* We do not handle setting only part of the register. */
354 if (DF_REF_FLAGS (adef) & DF_REF_READ_WRITE)
355 return GRD_INVALID;
357 def_insn = DF_REF_INSN (adef);
358 def_bb = DF_REF_BB (adef);
359 use_bb = BLOCK_FOR_INSN (insn);
361 if (use_bb == def_bb)
362 dom_p = (DF_INSN_LUID (def_insn) < DF_INSN_LUID (insn));
363 else
364 dom_p = dominated_by_p (CDI_DOMINATORS, use_bb, def_bb);
366 if (dom_p)
368 *def = adef;
369 return GRD_SINGLE_DOM;
372 /* The definition does not dominate the use. This is still OK if
373 this may be a use of a biv, i.e. if the def_bb dominates loop
374 latch. */
375 if (just_once_each_iteration_p (current_loop, def_bb))
376 return GRD_MAYBE_BIV;
378 return GRD_INVALID;
381 /* Sets IV to invariant CST in MODE. Always returns true (just for
382 consistency with other iv manipulation functions that may fail). */
384 static bool
385 iv_constant (struct rtx_iv *iv, rtx cst, enum machine_mode mode)
387 if (mode == VOIDmode)
388 mode = GET_MODE (cst);
390 iv->mode = mode;
391 iv->base = cst;
392 iv->step = const0_rtx;
393 iv->first_special = false;
394 iv->extend = UNKNOWN;
395 iv->extend_mode = iv->mode;
396 iv->delta = const0_rtx;
397 iv->mult = const1_rtx;
399 return true;
402 /* Evaluates application of subreg to MODE on IV. */
404 static bool
405 iv_subreg (struct rtx_iv *iv, enum machine_mode mode)
407 /* If iv is invariant, just calculate the new value. */
408 if (iv->step == const0_rtx
409 && !iv->first_special)
411 rtx val = get_iv_value (iv, const0_rtx);
412 val = lowpart_subreg (mode, val, iv->extend_mode);
414 iv->base = val;
415 iv->extend = UNKNOWN;
416 iv->mode = iv->extend_mode = mode;
417 iv->delta = const0_rtx;
418 iv->mult = const1_rtx;
419 return true;
422 if (iv->extend_mode == mode)
423 return true;
425 if (GET_MODE_BITSIZE (mode) > GET_MODE_BITSIZE (iv->mode))
426 return false;
428 iv->extend = UNKNOWN;
429 iv->mode = mode;
431 iv->base = simplify_gen_binary (PLUS, iv->extend_mode, iv->delta,
432 simplify_gen_binary (MULT, iv->extend_mode,
433 iv->base, iv->mult));
434 iv->step = simplify_gen_binary (MULT, iv->extend_mode, iv->step, iv->mult);
435 iv->mult = const1_rtx;
436 iv->delta = const0_rtx;
437 iv->first_special = false;
439 return true;
442 /* Evaluates application of EXTEND to MODE on IV. */
444 static bool
445 iv_extend (struct rtx_iv *iv, enum rtx_code extend, enum machine_mode mode)
447 /* If iv is invariant, just calculate the new value. */
448 if (iv->step == const0_rtx
449 && !iv->first_special)
451 rtx val = get_iv_value (iv, const0_rtx);
452 val = simplify_gen_unary (extend, mode, val, iv->extend_mode);
454 iv->base = val;
455 iv->extend = UNKNOWN;
456 iv->mode = iv->extend_mode = mode;
457 iv->delta = const0_rtx;
458 iv->mult = const1_rtx;
459 return true;
462 if (mode != iv->extend_mode)
463 return false;
465 if (iv->extend != UNKNOWN
466 && iv->extend != extend)
467 return false;
469 iv->extend = extend;
471 return true;
474 /* Evaluates negation of IV. */
476 static bool
477 iv_neg (struct rtx_iv *iv)
479 if (iv->extend == UNKNOWN)
481 iv->base = simplify_gen_unary (NEG, iv->extend_mode,
482 iv->base, iv->extend_mode);
483 iv->step = simplify_gen_unary (NEG, iv->extend_mode,
484 iv->step, iv->extend_mode);
486 else
488 iv->delta = simplify_gen_unary (NEG, iv->extend_mode,
489 iv->delta, iv->extend_mode);
490 iv->mult = simplify_gen_unary (NEG, iv->extend_mode,
491 iv->mult, iv->extend_mode);
494 return true;
497 /* Evaluates addition or subtraction (according to OP) of IV1 to IV0. */
499 static bool
500 iv_add (struct rtx_iv *iv0, struct rtx_iv *iv1, enum rtx_code op)
502 enum machine_mode mode;
503 rtx arg;
505 /* Extend the constant to extend_mode of the other operand if necessary. */
506 if (iv0->extend == UNKNOWN
507 && iv0->mode == iv0->extend_mode
508 && iv0->step == const0_rtx
509 && GET_MODE_SIZE (iv0->extend_mode) < GET_MODE_SIZE (iv1->extend_mode))
511 iv0->extend_mode = iv1->extend_mode;
512 iv0->base = simplify_gen_unary (ZERO_EXTEND, iv0->extend_mode,
513 iv0->base, iv0->mode);
515 if (iv1->extend == UNKNOWN
516 && iv1->mode == iv1->extend_mode
517 && iv1->step == const0_rtx
518 && GET_MODE_SIZE (iv1->extend_mode) < GET_MODE_SIZE (iv0->extend_mode))
520 iv1->extend_mode = iv0->extend_mode;
521 iv1->base = simplify_gen_unary (ZERO_EXTEND, iv1->extend_mode,
522 iv1->base, iv1->mode);
525 mode = iv0->extend_mode;
526 if (mode != iv1->extend_mode)
527 return false;
529 if (iv0->extend == UNKNOWN && iv1->extend == UNKNOWN)
531 if (iv0->mode != iv1->mode)
532 return false;
534 iv0->base = simplify_gen_binary (op, mode, iv0->base, iv1->base);
535 iv0->step = simplify_gen_binary (op, mode, iv0->step, iv1->step);
537 return true;
540 /* Handle addition of constant. */
541 if (iv1->extend == UNKNOWN
542 && iv1->mode == mode
543 && iv1->step == const0_rtx)
545 iv0->delta = simplify_gen_binary (op, mode, iv0->delta, iv1->base);
546 return true;
549 if (iv0->extend == UNKNOWN
550 && iv0->mode == mode
551 && iv0->step == const0_rtx)
553 arg = iv0->base;
554 *iv0 = *iv1;
555 if (op == MINUS
556 && !iv_neg (iv0))
557 return false;
559 iv0->delta = simplify_gen_binary (PLUS, mode, iv0->delta, arg);
560 return true;
563 return false;
566 /* Evaluates multiplication of IV by constant CST. */
568 static bool
569 iv_mult (struct rtx_iv *iv, rtx mby)
571 enum machine_mode mode = iv->extend_mode;
573 if (GET_MODE (mby) != VOIDmode
574 && GET_MODE (mby) != mode)
575 return false;
577 if (iv->extend == UNKNOWN)
579 iv->base = simplify_gen_binary (MULT, mode, iv->base, mby);
580 iv->step = simplify_gen_binary (MULT, mode, iv->step, mby);
582 else
584 iv->delta = simplify_gen_binary (MULT, mode, iv->delta, mby);
585 iv->mult = simplify_gen_binary (MULT, mode, iv->mult, mby);
588 return true;
591 /* Evaluates shift of IV by constant CST. */
593 static bool
594 iv_shift (struct rtx_iv *iv, rtx mby)
596 enum machine_mode mode = iv->extend_mode;
598 if (GET_MODE (mby) != VOIDmode
599 && GET_MODE (mby) != mode)
600 return false;
602 if (iv->extend == UNKNOWN)
604 iv->base = simplify_gen_binary (ASHIFT, mode, iv->base, mby);
605 iv->step = simplify_gen_binary (ASHIFT, mode, iv->step, mby);
607 else
609 iv->delta = simplify_gen_binary (ASHIFT, mode, iv->delta, mby);
610 iv->mult = simplify_gen_binary (ASHIFT, mode, iv->mult, mby);
613 return true;
616 /* The recursive part of get_biv_step. Gets the value of the single value
617 defined by DEF wrto initial value of REG inside loop, in shape described
618 at get_biv_step. */
620 static bool
621 get_biv_step_1 (df_ref def, rtx reg,
622 rtx *inner_step, enum machine_mode *inner_mode,
623 enum rtx_code *extend, enum machine_mode outer_mode,
624 rtx *outer_step)
626 rtx set, rhs, op0 = NULL_RTX, op1 = NULL_RTX;
627 rtx next, nextr, tmp;
628 enum rtx_code code;
629 rtx insn = DF_REF_INSN (def);
630 df_ref next_def;
631 enum iv_grd_result res;
633 set = single_set (insn);
634 if (!set)
635 return false;
637 rhs = find_reg_equal_equiv_note (insn);
638 if (rhs)
639 rhs = XEXP (rhs, 0);
640 else
641 rhs = SET_SRC (set);
643 code = GET_CODE (rhs);
644 switch (code)
646 case SUBREG:
647 case REG:
648 next = rhs;
649 break;
651 case PLUS:
652 case MINUS:
653 op0 = XEXP (rhs, 0);
654 op1 = XEXP (rhs, 1);
656 if (code == PLUS && CONSTANT_P (op0))
658 tmp = op0; op0 = op1; op1 = tmp;
661 if (!simple_reg_p (op0)
662 || !CONSTANT_P (op1))
663 return false;
665 if (GET_MODE (rhs) != outer_mode)
667 /* ppc64 uses expressions like
669 (set x:SI (plus:SI (subreg:SI y:DI) 1)).
671 this is equivalent to
673 (set x':DI (plus:DI y:DI 1))
674 (set x:SI (subreg:SI (x':DI)). */
675 if (GET_CODE (op0) != SUBREG)
676 return false;
677 if (GET_MODE (SUBREG_REG (op0)) != outer_mode)
678 return false;
681 next = op0;
682 break;
684 case SIGN_EXTEND:
685 case ZERO_EXTEND:
686 if (GET_MODE (rhs) != outer_mode)
687 return false;
689 op0 = XEXP (rhs, 0);
690 if (!simple_reg_p (op0))
691 return false;
693 next = op0;
694 break;
696 default:
697 return false;
700 if (GET_CODE (next) == SUBREG)
702 if (!subreg_lowpart_p (next))
703 return false;
705 nextr = SUBREG_REG (next);
706 if (GET_MODE (nextr) != outer_mode)
707 return false;
709 else
710 nextr = next;
712 res = iv_get_reaching_def (insn, nextr, &next_def);
714 if (res == GRD_INVALID || res == GRD_INVARIANT)
715 return false;
717 if (res == GRD_MAYBE_BIV)
719 if (!rtx_equal_p (nextr, reg))
720 return false;
722 *inner_step = const0_rtx;
723 *extend = UNKNOWN;
724 *inner_mode = outer_mode;
725 *outer_step = const0_rtx;
727 else if (!get_biv_step_1 (next_def, reg,
728 inner_step, inner_mode, extend, outer_mode,
729 outer_step))
730 return false;
732 if (GET_CODE (next) == SUBREG)
734 enum machine_mode amode = GET_MODE (next);
736 if (GET_MODE_SIZE (amode) > GET_MODE_SIZE (*inner_mode))
737 return false;
739 *inner_mode = amode;
740 *inner_step = simplify_gen_binary (PLUS, outer_mode,
741 *inner_step, *outer_step);
742 *outer_step = const0_rtx;
743 *extend = UNKNOWN;
746 switch (code)
748 case REG:
749 case SUBREG:
750 break;
752 case PLUS:
753 case MINUS:
754 if (*inner_mode == outer_mode
755 /* See comment in previous switch. */
756 || GET_MODE (rhs) != outer_mode)
757 *inner_step = simplify_gen_binary (code, outer_mode,
758 *inner_step, op1);
759 else
760 *outer_step = simplify_gen_binary (code, outer_mode,
761 *outer_step, op1);
762 break;
764 case SIGN_EXTEND:
765 case ZERO_EXTEND:
766 gcc_assert (GET_MODE (op0) == *inner_mode
767 && *extend == UNKNOWN
768 && *outer_step == const0_rtx);
770 *extend = code;
771 break;
773 default:
774 return false;
777 return true;
780 /* Gets the operation on register REG inside loop, in shape
782 OUTER_STEP + EXTEND_{OUTER_MODE} (SUBREG_{INNER_MODE} (REG + INNER_STEP))
784 If the operation cannot be described in this shape, return false.
785 LAST_DEF is the definition of REG that dominates loop latch. */
787 static bool
788 get_biv_step (df_ref last_def, rtx reg, rtx *inner_step,
789 enum machine_mode *inner_mode, enum rtx_code *extend,
790 enum machine_mode *outer_mode, rtx *outer_step)
792 *outer_mode = GET_MODE (reg);
794 if (!get_biv_step_1 (last_def, reg,
795 inner_step, inner_mode, extend, *outer_mode,
796 outer_step))
797 return false;
799 gcc_assert ((*inner_mode == *outer_mode) != (*extend != UNKNOWN));
800 gcc_assert (*inner_mode != *outer_mode || *outer_step == const0_rtx);
802 return true;
805 /* Records information that DEF is induction variable IV. */
807 static void
808 record_iv (df_ref def, struct rtx_iv *iv)
810 struct rtx_iv *recorded_iv = XNEW (struct rtx_iv);
812 *recorded_iv = *iv;
813 check_iv_ref_table_size ();
814 DF_REF_IV_SET (def, recorded_iv);
817 /* If DEF was already analyzed for bivness, store the description of the biv to
818 IV and return true. Otherwise return false. */
820 static bool
821 analyzed_for_bivness_p (rtx def, struct rtx_iv *iv)
823 struct biv_entry *biv =
824 (struct biv_entry *) htab_find_with_hash (bivs, def, REGNO (def));
826 if (!biv)
827 return false;
829 *iv = biv->iv;
830 return true;
833 static void
834 record_biv (rtx def, struct rtx_iv *iv)
836 struct biv_entry *biv = XNEW (struct biv_entry);
837 void **slot = htab_find_slot_with_hash (bivs, def, REGNO (def), INSERT);
839 biv->regno = REGNO (def);
840 biv->iv = *iv;
841 gcc_assert (!*slot);
842 *slot = biv;
845 /* Determines whether DEF is a biv and if so, stores its description
846 to *IV. */
848 static bool
849 iv_analyze_biv (rtx def, struct rtx_iv *iv)
851 rtx inner_step, outer_step;
852 enum machine_mode inner_mode, outer_mode;
853 enum rtx_code extend;
854 df_ref last_def;
856 if (dump_file)
858 fprintf (dump_file, "Analyzing ");
859 print_rtl (dump_file, def);
860 fprintf (dump_file, " for bivness.\n");
863 if (!REG_P (def))
865 if (!CONSTANT_P (def))
866 return false;
868 return iv_constant (iv, def, VOIDmode);
871 if (!latch_dominating_def (def, &last_def))
873 if (dump_file)
874 fprintf (dump_file, " not simple.\n");
875 return false;
878 if (!last_def)
879 return iv_constant (iv, def, VOIDmode);
881 if (analyzed_for_bivness_p (def, iv))
883 if (dump_file)
884 fprintf (dump_file, " already analysed.\n");
885 return iv->base != NULL_RTX;
888 if (!get_biv_step (last_def, def, &inner_step, &inner_mode, &extend,
889 &outer_mode, &outer_step))
891 iv->base = NULL_RTX;
892 goto end;
895 /* Loop transforms base to es (base + inner_step) + outer_step,
896 where es means extend of subreg between inner_mode and outer_mode.
897 The corresponding induction variable is
899 es ((base - outer_step) + i * (inner_step + outer_step)) + outer_step */
901 iv->base = simplify_gen_binary (MINUS, outer_mode, def, outer_step);
902 iv->step = simplify_gen_binary (PLUS, outer_mode, inner_step, outer_step);
903 iv->mode = inner_mode;
904 iv->extend_mode = outer_mode;
905 iv->extend = extend;
906 iv->mult = const1_rtx;
907 iv->delta = outer_step;
908 iv->first_special = inner_mode != outer_mode;
910 end:
911 if (dump_file)
913 fprintf (dump_file, " ");
914 dump_iv_info (dump_file, iv);
915 fprintf (dump_file, "\n");
918 record_biv (def, iv);
919 return iv->base != NULL_RTX;
922 /* Analyzes expression RHS used at INSN and stores the result to *IV.
923 The mode of the induction variable is MODE. */
925 bool
926 iv_analyze_expr (rtx insn, rtx rhs, enum machine_mode mode, struct rtx_iv *iv)
928 rtx mby = NULL_RTX, tmp;
929 rtx op0 = NULL_RTX, op1 = NULL_RTX;
930 struct rtx_iv iv0, iv1;
931 enum rtx_code code = GET_CODE (rhs);
932 enum machine_mode omode = mode;
934 iv->mode = VOIDmode;
935 iv->base = NULL_RTX;
936 iv->step = NULL_RTX;
938 gcc_assert (GET_MODE (rhs) == mode || GET_MODE (rhs) == VOIDmode);
940 if (CONSTANT_P (rhs)
941 || REG_P (rhs)
942 || code == SUBREG)
944 if (!iv_analyze_op (insn, rhs, iv))
945 return false;
947 if (iv->mode == VOIDmode)
949 iv->mode = mode;
950 iv->extend_mode = mode;
953 return true;
956 switch (code)
958 case REG:
959 op0 = rhs;
960 break;
962 case SIGN_EXTEND:
963 case ZERO_EXTEND:
964 case NEG:
965 op0 = XEXP (rhs, 0);
966 omode = GET_MODE (op0);
967 break;
969 case PLUS:
970 case MINUS:
971 op0 = XEXP (rhs, 0);
972 op1 = XEXP (rhs, 1);
973 break;
975 case MULT:
976 op0 = XEXP (rhs, 0);
977 mby = XEXP (rhs, 1);
978 if (!CONSTANT_P (mby))
980 tmp = op0;
981 op0 = mby;
982 mby = tmp;
984 if (!CONSTANT_P (mby))
985 return false;
986 break;
988 case ASHIFT:
989 op0 = XEXP (rhs, 0);
990 mby = XEXP (rhs, 1);
991 if (!CONSTANT_P (mby))
992 return false;
993 break;
995 default:
996 return false;
999 if (op0
1000 && !iv_analyze_expr (insn, op0, omode, &iv0))
1001 return false;
1003 if (op1
1004 && !iv_analyze_expr (insn, op1, omode, &iv1))
1005 return false;
1007 switch (code)
1009 case SIGN_EXTEND:
1010 case ZERO_EXTEND:
1011 if (!iv_extend (&iv0, code, mode))
1012 return false;
1013 break;
1015 case NEG:
1016 if (!iv_neg (&iv0))
1017 return false;
1018 break;
1020 case PLUS:
1021 case MINUS:
1022 if (!iv_add (&iv0, &iv1, code))
1023 return false;
1024 break;
1026 case MULT:
1027 if (!iv_mult (&iv0, mby))
1028 return false;
1029 break;
1031 case ASHIFT:
1032 if (!iv_shift (&iv0, mby))
1033 return false;
1034 break;
1036 default:
1037 break;
1040 *iv = iv0;
1041 return iv->base != NULL_RTX;
1044 /* Analyzes iv DEF and stores the result to *IV. */
1046 static bool
1047 iv_analyze_def (df_ref def, struct rtx_iv *iv)
1049 rtx insn = DF_REF_INSN (def);
1050 rtx reg = DF_REF_REG (def);
1051 rtx set, rhs;
1053 if (dump_file)
1055 fprintf (dump_file, "Analyzing def of ");
1056 print_rtl (dump_file, reg);
1057 fprintf (dump_file, " in insn ");
1058 print_rtl_single (dump_file, insn);
1061 check_iv_ref_table_size ();
1062 if (DF_REF_IV (def))
1064 if (dump_file)
1065 fprintf (dump_file, " already analysed.\n");
1066 *iv = *DF_REF_IV (def);
1067 return iv->base != NULL_RTX;
1070 iv->mode = VOIDmode;
1071 iv->base = NULL_RTX;
1072 iv->step = NULL_RTX;
1074 if (!REG_P (reg))
1075 return false;
1077 set = single_set (insn);
1078 if (!set)
1079 return false;
1081 if (!REG_P (SET_DEST (set)))
1082 return false;
1084 gcc_assert (SET_DEST (set) == reg);
1085 rhs = find_reg_equal_equiv_note (insn);
1086 if (rhs)
1087 rhs = XEXP (rhs, 0);
1088 else
1089 rhs = SET_SRC (set);
1091 iv_analyze_expr (insn, rhs, GET_MODE (reg), iv);
1092 record_iv (def, iv);
1094 if (dump_file)
1096 print_rtl (dump_file, reg);
1097 fprintf (dump_file, " in insn ");
1098 print_rtl_single (dump_file, insn);
1099 fprintf (dump_file, " is ");
1100 dump_iv_info (dump_file, iv);
1101 fprintf (dump_file, "\n");
1104 return iv->base != NULL_RTX;
1107 /* Analyzes operand OP of INSN and stores the result to *IV. */
1109 static bool
1110 iv_analyze_op (rtx insn, rtx op, struct rtx_iv *iv)
1112 df_ref def = NULL;
1113 enum iv_grd_result res;
1115 if (dump_file)
1117 fprintf (dump_file, "Analyzing operand ");
1118 print_rtl (dump_file, op);
1119 fprintf (dump_file, " of insn ");
1120 print_rtl_single (dump_file, insn);
1123 if (function_invariant_p (op))
1124 res = GRD_INVARIANT;
1125 else if (GET_CODE (op) == SUBREG)
1127 if (!subreg_lowpart_p (op))
1128 return false;
1130 if (!iv_analyze_op (insn, SUBREG_REG (op), iv))
1131 return false;
1133 return iv_subreg (iv, GET_MODE (op));
1135 else
1137 res = iv_get_reaching_def (insn, op, &def);
1138 if (res == GRD_INVALID)
1140 if (dump_file)
1141 fprintf (dump_file, " not simple.\n");
1142 return false;
1146 if (res == GRD_INVARIANT)
1148 iv_constant (iv, op, VOIDmode);
1150 if (dump_file)
1152 fprintf (dump_file, " ");
1153 dump_iv_info (dump_file, iv);
1154 fprintf (dump_file, "\n");
1156 return true;
1159 if (res == GRD_MAYBE_BIV)
1160 return iv_analyze_biv (op, iv);
1162 return iv_analyze_def (def, iv);
1165 /* Analyzes value VAL at INSN and stores the result to *IV. */
1167 bool
1168 iv_analyze (rtx insn, rtx val, struct rtx_iv *iv)
1170 rtx reg;
1172 /* We must find the insn in that val is used, so that we get to UD chains.
1173 Since the function is sometimes called on result of get_condition,
1174 this does not necessarily have to be directly INSN; scan also the
1175 following insns. */
1176 if (simple_reg_p (val))
1178 if (GET_CODE (val) == SUBREG)
1179 reg = SUBREG_REG (val);
1180 else
1181 reg = val;
1183 while (!df_find_use (insn, reg))
1184 insn = NEXT_INSN (insn);
1187 return iv_analyze_op (insn, val, iv);
1190 /* Analyzes definition of DEF in INSN and stores the result to IV. */
1192 bool
1193 iv_analyze_result (rtx insn, rtx def, struct rtx_iv *iv)
1195 df_ref adef;
1197 adef = df_find_def (insn, def);
1198 if (!adef)
1199 return false;
1201 return iv_analyze_def (adef, iv);
1204 /* Checks whether definition of register REG in INSN is a basic induction
1205 variable. IV analysis must have been initialized (via a call to
1206 iv_analysis_loop_init) for this function to produce a result. */
1208 bool
1209 biv_p (rtx insn, rtx reg)
1211 struct rtx_iv iv;
1212 df_ref def, last_def;
1214 if (!simple_reg_p (reg))
1215 return false;
1217 def = df_find_def (insn, reg);
1218 gcc_assert (def != NULL);
1219 if (!latch_dominating_def (reg, &last_def))
1220 return false;
1221 if (last_def != def)
1222 return false;
1224 if (!iv_analyze_biv (reg, &iv))
1225 return false;
1227 return iv.step != const0_rtx;
1230 /* Calculates value of IV at ITERATION-th iteration. */
1233 get_iv_value (struct rtx_iv *iv, rtx iteration)
1235 rtx val;
1237 /* We would need to generate some if_then_else patterns, and so far
1238 it is not needed anywhere. */
1239 gcc_assert (!iv->first_special);
1241 if (iv->step != const0_rtx && iteration != const0_rtx)
1242 val = simplify_gen_binary (PLUS, iv->extend_mode, iv->base,
1243 simplify_gen_binary (MULT, iv->extend_mode,
1244 iv->step, iteration));
1245 else
1246 val = iv->base;
1248 if (iv->extend_mode == iv->mode)
1249 return val;
1251 val = lowpart_subreg (iv->mode, val, iv->extend_mode);
1253 if (iv->extend == UNKNOWN)
1254 return val;
1256 val = simplify_gen_unary (iv->extend, iv->extend_mode, val, iv->mode);
1257 val = simplify_gen_binary (PLUS, iv->extend_mode, iv->delta,
1258 simplify_gen_binary (MULT, iv->extend_mode,
1259 iv->mult, val));
1261 return val;
1264 /* Free the data for an induction variable analysis. */
1266 void
1267 iv_analysis_done (void)
1269 if (!clean_slate)
1271 clear_iv_info ();
1272 clean_slate = true;
1273 df_finish_pass (true);
1274 htab_delete (bivs);
1275 free (iv_ref_table);
1276 iv_ref_table = NULL;
1277 iv_ref_table_size = 0;
1278 bivs = NULL;
1282 /* Computes inverse to X modulo (1 << MOD). */
1284 static unsigned HOST_WIDEST_INT
1285 inverse (unsigned HOST_WIDEST_INT x, int mod)
1287 unsigned HOST_WIDEST_INT mask =
1288 ((unsigned HOST_WIDEST_INT) 1 << (mod - 1) << 1) - 1;
1289 unsigned HOST_WIDEST_INT rslt = 1;
1290 int i;
1292 for (i = 0; i < mod - 1; i++)
1294 rslt = (rslt * x) & mask;
1295 x = (x * x) & mask;
1298 return rslt;
1301 /* Checks whether register *REG is in set ALT. Callback for for_each_rtx. */
1303 static int
1304 altered_reg_used (rtx *reg, void *alt)
1306 if (!REG_P (*reg))
1307 return 0;
1309 return REGNO_REG_SET_P ((bitmap) alt, REGNO (*reg));
1312 /* Marks registers altered by EXPR in set ALT. */
1314 static void
1315 mark_altered (rtx expr, const_rtx by ATTRIBUTE_UNUSED, void *alt)
1317 if (GET_CODE (expr) == SUBREG)
1318 expr = SUBREG_REG (expr);
1319 if (!REG_P (expr))
1320 return;
1322 SET_REGNO_REG_SET ((bitmap) alt, REGNO (expr));
1325 /* Checks whether RHS is simple enough to process. */
1327 static bool
1328 simple_rhs_p (rtx rhs)
1330 rtx op0, op1;
1332 if (function_invariant_p (rhs)
1333 || (REG_P (rhs) && !HARD_REGISTER_P (rhs)))
1334 return true;
1336 switch (GET_CODE (rhs))
1338 case PLUS:
1339 case MINUS:
1340 case AND:
1341 op0 = XEXP (rhs, 0);
1342 op1 = XEXP (rhs, 1);
1343 /* Allow reg OP const and reg OP reg. */
1344 if (!(REG_P (op0) && !HARD_REGISTER_P (op0))
1345 && !function_invariant_p (op0))
1346 return false;
1347 if (!(REG_P (op1) && !HARD_REGISTER_P (op1))
1348 && !function_invariant_p (op1))
1349 return false;
1351 return true;
1353 case ASHIFT:
1354 case ASHIFTRT:
1355 case LSHIFTRT:
1356 case MULT:
1357 op0 = XEXP (rhs, 0);
1358 op1 = XEXP (rhs, 1);
1359 /* Allow reg OP const. */
1360 if (!(REG_P (op0) && !HARD_REGISTER_P (op0)))
1361 return false;
1362 if (!function_invariant_p (op1))
1363 return false;
1365 return true;
1367 default:
1368 return false;
1372 /* If REG has a single definition, replace it with its known value in EXPR.
1373 Callback for for_each_rtx. */
1375 static int
1376 replace_single_def_regs (rtx *reg, void *expr1)
1378 unsigned regno;
1379 df_ref adef;
1380 rtx set, src;
1381 rtx *expr = (rtx *)expr1;
1383 if (!REG_P (*reg))
1384 return 0;
1386 regno = REGNO (*reg);
1387 for (;;)
1389 rtx note;
1390 adef = DF_REG_DEF_CHAIN (regno);
1391 if (adef == NULL || DF_REF_NEXT_REG (adef) != NULL
1392 || DF_REF_IS_ARTIFICIAL (adef))
1393 return -1;
1395 set = single_set (DF_REF_INSN (adef));
1396 if (set == NULL || !REG_P (SET_DEST (set))
1397 || REGNO (SET_DEST (set)) != regno)
1398 return -1;
1400 note = find_reg_equal_equiv_note (DF_REF_INSN (adef));
1402 if (note && function_invariant_p (XEXP (note, 0)))
1404 src = XEXP (note, 0);
1405 break;
1407 src = SET_SRC (set);
1409 if (REG_P (src))
1411 regno = REGNO (src);
1412 continue;
1414 break;
1416 if (!function_invariant_p (src))
1417 return -1;
1419 *expr = simplify_replace_rtx (*expr, *reg, src);
1420 return 1;
1423 /* A subroutine of simplify_using_initial_values, this function examines INSN
1424 to see if it contains a suitable set that we can use to make a replacement.
1425 If it is suitable, return true and set DEST and SRC to the lhs and rhs of
1426 the set; return false otherwise. */
1428 static bool
1429 suitable_set_for_replacement (rtx insn, rtx *dest, rtx *src)
1431 rtx set = single_set (insn);
1432 rtx lhs = NULL_RTX, rhs;
1434 if (!set)
1435 return false;
1437 lhs = SET_DEST (set);
1438 if (!REG_P (lhs))
1439 return false;
1441 rhs = find_reg_equal_equiv_note (insn);
1442 if (rhs)
1443 rhs = XEXP (rhs, 0);
1444 else
1445 rhs = SET_SRC (set);
1447 if (!simple_rhs_p (rhs))
1448 return false;
1450 *dest = lhs;
1451 *src = rhs;
1452 return true;
1455 /* Using the data returned by suitable_set_for_replacement, replace DEST
1456 with SRC in *EXPR and return the new expression. Also call
1457 replace_single_def_regs if the replacement changed something. */
1458 static void
1459 replace_in_expr (rtx *expr, rtx dest, rtx src)
1461 rtx old = *expr;
1462 *expr = simplify_replace_rtx (*expr, dest, src);
1463 if (old == *expr)
1464 return;
1465 while (for_each_rtx (expr, replace_single_def_regs, expr) != 0)
1466 continue;
1469 /* Checks whether A implies B. */
1471 static bool
1472 implies_p (rtx a, rtx b)
1474 rtx op0, op1, opb0, opb1, r;
1475 enum machine_mode mode;
1477 if (GET_CODE (a) == EQ)
1479 op0 = XEXP (a, 0);
1480 op1 = XEXP (a, 1);
1482 if (REG_P (op0))
1484 r = simplify_replace_rtx (b, op0, op1);
1485 if (r == const_true_rtx)
1486 return true;
1489 if (REG_P (op1))
1491 r = simplify_replace_rtx (b, op1, op0);
1492 if (r == const_true_rtx)
1493 return true;
1497 if (b == const_true_rtx)
1498 return true;
1500 if ((GET_RTX_CLASS (GET_CODE (a)) != RTX_COMM_COMPARE
1501 && GET_RTX_CLASS (GET_CODE (a)) != RTX_COMPARE)
1502 || (GET_RTX_CLASS (GET_CODE (b)) != RTX_COMM_COMPARE
1503 && GET_RTX_CLASS (GET_CODE (b)) != RTX_COMPARE))
1504 return false;
1506 op0 = XEXP (a, 0);
1507 op1 = XEXP (a, 1);
1508 opb0 = XEXP (b, 0);
1509 opb1 = XEXP (b, 1);
1511 mode = GET_MODE (op0);
1512 if (mode != GET_MODE (opb0))
1513 mode = VOIDmode;
1514 else if (mode == VOIDmode)
1516 mode = GET_MODE (op1);
1517 if (mode != GET_MODE (opb1))
1518 mode = VOIDmode;
1521 /* A < B implies A + 1 <= B. */
1522 if ((GET_CODE (a) == GT || GET_CODE (a) == LT)
1523 && (GET_CODE (b) == GE || GET_CODE (b) == LE))
1526 if (GET_CODE (a) == GT)
1528 r = op0;
1529 op0 = op1;
1530 op1 = r;
1533 if (GET_CODE (b) == GE)
1535 r = opb0;
1536 opb0 = opb1;
1537 opb1 = r;
1540 if (SCALAR_INT_MODE_P (mode)
1541 && rtx_equal_p (op1, opb1)
1542 && simplify_gen_binary (MINUS, mode, opb0, op0) == const1_rtx)
1543 return true;
1544 return false;
1547 /* A < B or A > B imply A != B. TODO: Likewise
1548 A + n < B implies A != B + n if neither wraps. */
1549 if (GET_CODE (b) == NE
1550 && (GET_CODE (a) == GT || GET_CODE (a) == GTU
1551 || GET_CODE (a) == LT || GET_CODE (a) == LTU))
1553 if (rtx_equal_p (op0, opb0)
1554 && rtx_equal_p (op1, opb1))
1555 return true;
1558 /* For unsigned comparisons, A != 0 implies A > 0 and A >= 1. */
1559 if (GET_CODE (a) == NE
1560 && op1 == const0_rtx)
1562 if ((GET_CODE (b) == GTU
1563 && opb1 == const0_rtx)
1564 || (GET_CODE (b) == GEU
1565 && opb1 == const1_rtx))
1566 return rtx_equal_p (op0, opb0);
1569 /* A != N is equivalent to A - (N + 1) <u -1. */
1570 if (GET_CODE (a) == NE
1571 && CONST_INT_P (op1)
1572 && GET_CODE (b) == LTU
1573 && opb1 == constm1_rtx
1574 && GET_CODE (opb0) == PLUS
1575 && CONST_INT_P (XEXP (opb0, 1))
1576 /* Avoid overflows. */
1577 && ((unsigned HOST_WIDE_INT) INTVAL (XEXP (opb0, 1))
1578 != ((unsigned HOST_WIDE_INT)1
1579 << (HOST_BITS_PER_WIDE_INT - 1)) - 1)
1580 && INTVAL (XEXP (opb0, 1)) + 1 == -INTVAL (op1))
1581 return rtx_equal_p (op0, XEXP (opb0, 0));
1583 /* Likewise, A != N implies A - N > 0. */
1584 if (GET_CODE (a) == NE
1585 && CONST_INT_P (op1))
1587 if (GET_CODE (b) == GTU
1588 && GET_CODE (opb0) == PLUS
1589 && opb1 == const0_rtx
1590 && CONST_INT_P (XEXP (opb0, 1))
1591 /* Avoid overflows. */
1592 && ((unsigned HOST_WIDE_INT) INTVAL (XEXP (opb0, 1))
1593 != ((unsigned HOST_WIDE_INT) 1 << (HOST_BITS_PER_WIDE_INT - 1)))
1594 && rtx_equal_p (XEXP (opb0, 0), op0))
1595 return INTVAL (op1) == -INTVAL (XEXP (opb0, 1));
1596 if (GET_CODE (b) == GEU
1597 && GET_CODE (opb0) == PLUS
1598 && opb1 == const1_rtx
1599 && CONST_INT_P (XEXP (opb0, 1))
1600 /* Avoid overflows. */
1601 && ((unsigned HOST_WIDE_INT) INTVAL (XEXP (opb0, 1))
1602 != ((unsigned HOST_WIDE_INT) 1 << (HOST_BITS_PER_WIDE_INT - 1)))
1603 && rtx_equal_p (XEXP (opb0, 0), op0))
1604 return INTVAL (op1) == -INTVAL (XEXP (opb0, 1));
1607 /* A >s X, where X is positive, implies A <u Y, if Y is negative. */
1608 if ((GET_CODE (a) == GT || GET_CODE (a) == GE)
1609 && CONST_INT_P (op1)
1610 && ((GET_CODE (a) == GT && op1 == constm1_rtx)
1611 || INTVAL (op1) >= 0)
1612 && GET_CODE (b) == LTU
1613 && CONST_INT_P (opb1)
1614 && rtx_equal_p (op0, opb0))
1615 return INTVAL (opb1) < 0;
1617 return false;
1620 /* Canonicalizes COND so that
1622 (1) Ensure that operands are ordered according to
1623 swap_commutative_operands_p.
1624 (2) (LE x const) will be replaced with (LT x <const+1>) and similarly
1625 for GE, GEU, and LEU. */
1628 canon_condition (rtx cond)
1630 rtx tem;
1631 rtx op0, op1;
1632 enum rtx_code code;
1633 enum machine_mode mode;
1635 code = GET_CODE (cond);
1636 op0 = XEXP (cond, 0);
1637 op1 = XEXP (cond, 1);
1639 if (swap_commutative_operands_p (op0, op1))
1641 code = swap_condition (code);
1642 tem = op0;
1643 op0 = op1;
1644 op1 = tem;
1647 mode = GET_MODE (op0);
1648 if (mode == VOIDmode)
1649 mode = GET_MODE (op1);
1650 gcc_assert (mode != VOIDmode);
1652 if (CONST_INT_P (op1)
1653 && GET_MODE_CLASS (mode) != MODE_CC
1654 && GET_MODE_BITSIZE (mode) <= HOST_BITS_PER_WIDE_INT)
1656 HOST_WIDE_INT const_val = INTVAL (op1);
1657 unsigned HOST_WIDE_INT uconst_val = const_val;
1658 unsigned HOST_WIDE_INT max_val
1659 = (unsigned HOST_WIDE_INT) GET_MODE_MASK (mode);
1661 switch (code)
1663 case LE:
1664 if ((unsigned HOST_WIDE_INT) const_val != max_val >> 1)
1665 code = LT, op1 = gen_int_mode (const_val + 1, GET_MODE (op0));
1666 break;
1668 /* When cross-compiling, const_val might be sign-extended from
1669 BITS_PER_WORD to HOST_BITS_PER_WIDE_INT */
1670 case GE:
1671 if ((HOST_WIDE_INT) (const_val & max_val)
1672 != (((HOST_WIDE_INT) 1
1673 << (GET_MODE_BITSIZE (GET_MODE (op0)) - 1))))
1674 code = GT, op1 = gen_int_mode (const_val - 1, mode);
1675 break;
1677 case LEU:
1678 if (uconst_val < max_val)
1679 code = LTU, op1 = gen_int_mode (uconst_val + 1, mode);
1680 break;
1682 case GEU:
1683 if (uconst_val != 0)
1684 code = GTU, op1 = gen_int_mode (uconst_val - 1, mode);
1685 break;
1687 default:
1688 break;
1692 if (op0 != XEXP (cond, 0)
1693 || op1 != XEXP (cond, 1)
1694 || code != GET_CODE (cond)
1695 || GET_MODE (cond) != SImode)
1696 cond = gen_rtx_fmt_ee (code, SImode, op0, op1);
1698 return cond;
1701 /* Tries to use the fact that COND holds to simplify EXPR. ALTERED is the
1702 set of altered regs. */
1704 void
1705 simplify_using_condition (rtx cond, rtx *expr, regset altered)
1707 rtx rev, reve, exp = *expr;
1709 /* If some register gets altered later, we do not really speak about its
1710 value at the time of comparison. */
1711 if (altered
1712 && for_each_rtx (&cond, altered_reg_used, altered))
1713 return;
1715 if (GET_CODE (cond) == EQ
1716 && REG_P (XEXP (cond, 0)) && CONSTANT_P (XEXP (cond, 1)))
1718 *expr = simplify_replace_rtx (*expr, XEXP (cond, 0), XEXP (cond, 1));
1719 return;
1722 if (!COMPARISON_P (exp))
1723 return;
1725 rev = reversed_condition (cond);
1726 reve = reversed_condition (exp);
1728 cond = canon_condition (cond);
1729 exp = canon_condition (exp);
1730 if (rev)
1731 rev = canon_condition (rev);
1732 if (reve)
1733 reve = canon_condition (reve);
1735 if (rtx_equal_p (exp, cond))
1737 *expr = const_true_rtx;
1738 return;
1741 if (rev && rtx_equal_p (exp, rev))
1743 *expr = const0_rtx;
1744 return;
1747 if (implies_p (cond, exp))
1749 *expr = const_true_rtx;
1750 return;
1753 if (reve && implies_p (cond, reve))
1755 *expr = const0_rtx;
1756 return;
1759 /* A proof by contradiction. If *EXPR implies (not cond), *EXPR must
1760 be false. */
1761 if (rev && implies_p (exp, rev))
1763 *expr = const0_rtx;
1764 return;
1767 /* Similarly, If (not *EXPR) implies (not cond), *EXPR must be true. */
1768 if (rev && reve && implies_p (reve, rev))
1770 *expr = const_true_rtx;
1771 return;
1774 /* We would like to have some other tests here. TODO. */
1776 return;
1779 /* Use relationship between A and *B to eventually eliminate *B.
1780 OP is the operation we consider. */
1782 static void
1783 eliminate_implied_condition (enum rtx_code op, rtx a, rtx *b)
1785 switch (op)
1787 case AND:
1788 /* If A implies *B, we may replace *B by true. */
1789 if (implies_p (a, *b))
1790 *b = const_true_rtx;
1791 break;
1793 case IOR:
1794 /* If *B implies A, we may replace *B by false. */
1795 if (implies_p (*b, a))
1796 *b = const0_rtx;
1797 break;
1799 default:
1800 gcc_unreachable ();
1804 /* Eliminates the conditions in TAIL that are implied by HEAD. OP is the
1805 operation we consider. */
1807 static void
1808 eliminate_implied_conditions (enum rtx_code op, rtx *head, rtx tail)
1810 rtx elt;
1812 for (elt = tail; elt; elt = XEXP (elt, 1))
1813 eliminate_implied_condition (op, *head, &XEXP (elt, 0));
1814 for (elt = tail; elt; elt = XEXP (elt, 1))
1815 eliminate_implied_condition (op, XEXP (elt, 0), head);
1818 /* Simplifies *EXPR using initial values at the start of the LOOP. If *EXPR
1819 is a list, its elements are assumed to be combined using OP. */
1821 static void
1822 simplify_using_initial_values (struct loop *loop, enum rtx_code op, rtx *expr)
1824 bool expression_valid;
1825 rtx head, tail, insn, cond_list, last_valid_expr;
1826 rtx neutral, aggr;
1827 regset altered, this_altered;
1828 edge e;
1830 if (!*expr)
1831 return;
1833 if (CONSTANT_P (*expr))
1834 return;
1836 if (GET_CODE (*expr) == EXPR_LIST)
1838 head = XEXP (*expr, 0);
1839 tail = XEXP (*expr, 1);
1841 eliminate_implied_conditions (op, &head, tail);
1843 switch (op)
1845 case AND:
1846 neutral = const_true_rtx;
1847 aggr = const0_rtx;
1848 break;
1850 case IOR:
1851 neutral = const0_rtx;
1852 aggr = const_true_rtx;
1853 break;
1855 default:
1856 gcc_unreachable ();
1859 simplify_using_initial_values (loop, UNKNOWN, &head);
1860 if (head == aggr)
1862 XEXP (*expr, 0) = aggr;
1863 XEXP (*expr, 1) = NULL_RTX;
1864 return;
1866 else if (head == neutral)
1868 *expr = tail;
1869 simplify_using_initial_values (loop, op, expr);
1870 return;
1872 simplify_using_initial_values (loop, op, &tail);
1874 if (tail && XEXP (tail, 0) == aggr)
1876 *expr = tail;
1877 return;
1880 XEXP (*expr, 0) = head;
1881 XEXP (*expr, 1) = tail;
1882 return;
1885 gcc_assert (op == UNKNOWN);
1887 for (;;)
1888 if (for_each_rtx (expr, replace_single_def_regs, expr) == 0)
1889 break;
1890 if (CONSTANT_P (*expr))
1891 return;
1893 e = loop_preheader_edge (loop);
1894 if (e->src == ENTRY_BLOCK_PTR)
1895 return;
1897 altered = ALLOC_REG_SET (&reg_obstack);
1898 this_altered = ALLOC_REG_SET (&reg_obstack);
1900 expression_valid = true;
1901 last_valid_expr = *expr;
1902 cond_list = NULL_RTX;
1903 while (1)
1905 insn = BB_END (e->src);
1906 if (any_condjump_p (insn))
1908 rtx cond = get_condition (BB_END (e->src), NULL, false, true);
1910 if (cond && (e->flags & EDGE_FALLTHRU))
1911 cond = reversed_condition (cond);
1912 if (cond)
1914 rtx old = *expr;
1915 simplify_using_condition (cond, expr, altered);
1916 if (old != *expr)
1918 rtx note;
1919 if (CONSTANT_P (*expr))
1920 goto out;
1921 for (note = cond_list; note; note = XEXP (note, 1))
1923 simplify_using_condition (XEXP (note, 0), expr, altered);
1924 if (CONSTANT_P (*expr))
1925 goto out;
1928 cond_list = alloc_EXPR_LIST (0, cond, cond_list);
1932 FOR_BB_INSNS_REVERSE (e->src, insn)
1934 rtx src, dest;
1935 rtx old = *expr;
1937 if (!INSN_P (insn))
1938 continue;
1940 CLEAR_REG_SET (this_altered);
1941 note_stores (PATTERN (insn), mark_altered, this_altered);
1942 if (CALL_P (insn))
1944 int i;
1946 /* Kill all call clobbered registers. */
1947 for (i = 0; i < FIRST_PSEUDO_REGISTER; i++)
1948 if (TEST_HARD_REG_BIT (regs_invalidated_by_call, i))
1949 SET_REGNO_REG_SET (this_altered, i);
1952 if (suitable_set_for_replacement (insn, &dest, &src))
1954 rtx *pnote, *pnote_next;
1956 replace_in_expr (expr, dest, src);
1957 if (CONSTANT_P (*expr))
1958 goto out;
1960 for (pnote = &cond_list; *pnote; pnote = pnote_next)
1962 rtx note = *pnote;
1963 rtx old_cond = XEXP (note, 0);
1965 pnote_next = &XEXP (note, 1);
1966 replace_in_expr (&XEXP (note, 0), dest, src);
1968 /* We can no longer use a condition that has been simplified
1969 to a constant, and simplify_using_condition will abort if
1970 we try. */
1971 if (CONSTANT_P (XEXP (note, 0)))
1973 *pnote = *pnote_next;
1974 pnote_next = pnote;
1975 free_EXPR_LIST_node (note);
1977 /* Retry simplifications with this condition if either the
1978 expression or the condition changed. */
1979 else if (old_cond != XEXP (note, 0) || old != *expr)
1980 simplify_using_condition (XEXP (note, 0), expr, altered);
1983 else
1984 /* If we did not use this insn to make a replacement, any overlap
1985 between stores in this insn and our expression will cause the
1986 expression to become invalid. */
1987 if (for_each_rtx (expr, altered_reg_used, this_altered))
1988 goto out;
1990 if (CONSTANT_P (*expr))
1991 goto out;
1993 IOR_REG_SET (altered, this_altered);
1995 /* If the expression now contains regs that have been altered, we
1996 can't return it to the caller. However, it is still valid for
1997 further simplification, so keep searching to see if we can
1998 eventually turn it into a constant. */
1999 if (for_each_rtx (expr, altered_reg_used, altered))
2000 expression_valid = false;
2001 if (expression_valid)
2002 last_valid_expr = *expr;
2005 if (!single_pred_p (e->src)
2006 || single_pred (e->src) == ENTRY_BLOCK_PTR)
2007 break;
2008 e = single_pred_edge (e->src);
2011 out:
2012 free_EXPR_LIST_list (&cond_list);
2013 if (!CONSTANT_P (*expr))
2014 *expr = last_valid_expr;
2015 FREE_REG_SET (altered);
2016 FREE_REG_SET (this_altered);
2019 /* Transforms invariant IV into MODE. Adds assumptions based on the fact
2020 that IV occurs as left operands of comparison COND and its signedness
2021 is SIGNED_P to DESC. */
2023 static void
2024 shorten_into_mode (struct rtx_iv *iv, enum machine_mode mode,
2025 enum rtx_code cond, bool signed_p, struct niter_desc *desc)
2027 rtx mmin, mmax, cond_over, cond_under;
2029 get_mode_bounds (mode, signed_p, iv->extend_mode, &mmin, &mmax);
2030 cond_under = simplify_gen_relational (LT, SImode, iv->extend_mode,
2031 iv->base, mmin);
2032 cond_over = simplify_gen_relational (GT, SImode, iv->extend_mode,
2033 iv->base, mmax);
2035 switch (cond)
2037 case LE:
2038 case LT:
2039 case LEU:
2040 case LTU:
2041 if (cond_under != const0_rtx)
2042 desc->infinite =
2043 alloc_EXPR_LIST (0, cond_under, desc->infinite);
2044 if (cond_over != const0_rtx)
2045 desc->noloop_assumptions =
2046 alloc_EXPR_LIST (0, cond_over, desc->noloop_assumptions);
2047 break;
2049 case GE:
2050 case GT:
2051 case GEU:
2052 case GTU:
2053 if (cond_over != const0_rtx)
2054 desc->infinite =
2055 alloc_EXPR_LIST (0, cond_over, desc->infinite);
2056 if (cond_under != const0_rtx)
2057 desc->noloop_assumptions =
2058 alloc_EXPR_LIST (0, cond_under, desc->noloop_assumptions);
2059 break;
2061 case NE:
2062 if (cond_over != const0_rtx)
2063 desc->infinite =
2064 alloc_EXPR_LIST (0, cond_over, desc->infinite);
2065 if (cond_under != const0_rtx)
2066 desc->infinite =
2067 alloc_EXPR_LIST (0, cond_under, desc->infinite);
2068 break;
2070 default:
2071 gcc_unreachable ();
2074 iv->mode = mode;
2075 iv->extend = signed_p ? SIGN_EXTEND : ZERO_EXTEND;
2078 /* Transforms IV0 and IV1 compared by COND so that they are both compared as
2079 subregs of the same mode if possible (sometimes it is necessary to add
2080 some assumptions to DESC). */
2082 static bool
2083 canonicalize_iv_subregs (struct rtx_iv *iv0, struct rtx_iv *iv1,
2084 enum rtx_code cond, struct niter_desc *desc)
2086 enum machine_mode comp_mode;
2087 bool signed_p;
2089 /* If the ivs behave specially in the first iteration, or are
2090 added/multiplied after extending, we ignore them. */
2091 if (iv0->first_special || iv0->mult != const1_rtx || iv0->delta != const0_rtx)
2092 return false;
2093 if (iv1->first_special || iv1->mult != const1_rtx || iv1->delta != const0_rtx)
2094 return false;
2096 /* If there is some extend, it must match signedness of the comparison. */
2097 switch (cond)
2099 case LE:
2100 case LT:
2101 if (iv0->extend == ZERO_EXTEND
2102 || iv1->extend == ZERO_EXTEND)
2103 return false;
2104 signed_p = true;
2105 break;
2107 case LEU:
2108 case LTU:
2109 if (iv0->extend == SIGN_EXTEND
2110 || iv1->extend == SIGN_EXTEND)
2111 return false;
2112 signed_p = false;
2113 break;
2115 case NE:
2116 if (iv0->extend != UNKNOWN
2117 && iv1->extend != UNKNOWN
2118 && iv0->extend != iv1->extend)
2119 return false;
2121 signed_p = false;
2122 if (iv0->extend != UNKNOWN)
2123 signed_p = iv0->extend == SIGN_EXTEND;
2124 if (iv1->extend != UNKNOWN)
2125 signed_p = iv1->extend == SIGN_EXTEND;
2126 break;
2128 default:
2129 gcc_unreachable ();
2132 /* Values of both variables should be computed in the same mode. These
2133 might indeed be different, if we have comparison like
2135 (compare (subreg:SI (iv0)) (subreg:SI (iv1)))
2137 and iv0 and iv1 are both ivs iterating in SI mode, but calculated
2138 in different modes. This does not seem impossible to handle, but
2139 it hardly ever occurs in practice.
2141 The only exception is the case when one of operands is invariant.
2142 For example pentium 3 generates comparisons like
2143 (lt (subreg:HI (reg:SI)) 100). Here we assign HImode to 100, but we
2144 definitely do not want this prevent the optimization. */
2145 comp_mode = iv0->extend_mode;
2146 if (GET_MODE_BITSIZE (comp_mode) < GET_MODE_BITSIZE (iv1->extend_mode))
2147 comp_mode = iv1->extend_mode;
2149 if (iv0->extend_mode != comp_mode)
2151 if (iv0->mode != iv0->extend_mode
2152 || iv0->step != const0_rtx)
2153 return false;
2155 iv0->base = simplify_gen_unary (signed_p ? SIGN_EXTEND : ZERO_EXTEND,
2156 comp_mode, iv0->base, iv0->mode);
2157 iv0->extend_mode = comp_mode;
2160 if (iv1->extend_mode != comp_mode)
2162 if (iv1->mode != iv1->extend_mode
2163 || iv1->step != const0_rtx)
2164 return false;
2166 iv1->base = simplify_gen_unary (signed_p ? SIGN_EXTEND : ZERO_EXTEND,
2167 comp_mode, iv1->base, iv1->mode);
2168 iv1->extend_mode = comp_mode;
2171 /* Check that both ivs belong to a range of a single mode. If one of the
2172 operands is an invariant, we may need to shorten it into the common
2173 mode. */
2174 if (iv0->mode == iv0->extend_mode
2175 && iv0->step == const0_rtx
2176 && iv0->mode != iv1->mode)
2177 shorten_into_mode (iv0, iv1->mode, cond, signed_p, desc);
2179 if (iv1->mode == iv1->extend_mode
2180 && iv1->step == const0_rtx
2181 && iv0->mode != iv1->mode)
2182 shorten_into_mode (iv1, iv0->mode, swap_condition (cond), signed_p, desc);
2184 if (iv0->mode != iv1->mode)
2185 return false;
2187 desc->mode = iv0->mode;
2188 desc->signed_p = signed_p;
2190 return true;
2193 /* Tries to estimate the maximum number of iterations in LOOP, and store the
2194 result in DESC. This function is called from iv_number_of_iterations with
2195 a number of fields in DESC already filled in. OLD_NITER is the original
2196 expression for the number of iterations, before we tried to simplify it. */
2198 static unsigned HOST_WIDEST_INT
2199 determine_max_iter (struct loop *loop, struct niter_desc *desc, rtx old_niter)
2201 rtx niter = desc->niter_expr;
2202 rtx mmin, mmax, cmp;
2203 unsigned HOST_WIDEST_INT nmax, inc;
2205 if (GET_CODE (niter) == AND
2206 && CONST_INT_P (XEXP (niter, 0)))
2208 nmax = INTVAL (XEXP (niter, 0));
2209 if (!(nmax & (nmax + 1)))
2211 desc->niter_max = nmax;
2212 return nmax;
2216 get_mode_bounds (desc->mode, desc->signed_p, desc->mode, &mmin, &mmax);
2217 nmax = INTVAL (mmax) - INTVAL (mmin);
2219 if (GET_CODE (niter) == UDIV)
2221 if (!CONST_INT_P (XEXP (niter, 1)))
2223 desc->niter_max = nmax;
2224 return nmax;
2226 inc = INTVAL (XEXP (niter, 1));
2227 niter = XEXP (niter, 0);
2229 else
2230 inc = 1;
2232 /* We could use a binary search here, but for now improving the upper
2233 bound by just one eliminates one important corner case. */
2234 cmp = simplify_gen_relational (desc->signed_p ? LT : LTU, VOIDmode,
2235 desc->mode, old_niter, mmax);
2236 simplify_using_initial_values (loop, UNKNOWN, &cmp);
2237 if (cmp == const_true_rtx)
2239 nmax--;
2241 if (dump_file)
2242 fprintf (dump_file, ";; improved upper bound by one.\n");
2244 desc->niter_max = nmax / inc;
2245 return nmax / inc;
2248 /* Computes number of iterations of the CONDITION in INSN in LOOP and stores
2249 the result into DESC. Very similar to determine_number_of_iterations
2250 (basically its rtl version), complicated by things like subregs. */
2252 static void
2253 iv_number_of_iterations (struct loop *loop, rtx insn, rtx condition,
2254 struct niter_desc *desc)
2256 rtx op0, op1, delta, step, bound, may_xform, tmp, tmp0, tmp1;
2257 struct rtx_iv iv0, iv1, tmp_iv;
2258 rtx assumption, may_not_xform;
2259 enum rtx_code cond;
2260 enum machine_mode mode, comp_mode;
2261 rtx mmin, mmax, mode_mmin, mode_mmax;
2262 unsigned HOST_WIDEST_INT s, size, d, inv;
2263 HOST_WIDEST_INT up, down, inc, step_val;
2264 int was_sharp = false;
2265 rtx old_niter;
2266 bool step_is_pow2;
2268 /* The meaning of these assumptions is this:
2269 if !assumptions
2270 then the rest of information does not have to be valid
2271 if noloop_assumptions then the loop does not roll
2272 if infinite then this exit is never used */
2274 desc->assumptions = NULL_RTX;
2275 desc->noloop_assumptions = NULL_RTX;
2276 desc->infinite = NULL_RTX;
2277 desc->simple_p = true;
2279 desc->const_iter = false;
2280 desc->niter_expr = NULL_RTX;
2281 desc->niter_max = 0;
2283 cond = GET_CODE (condition);
2284 gcc_assert (COMPARISON_P (condition));
2286 mode = GET_MODE (XEXP (condition, 0));
2287 if (mode == VOIDmode)
2288 mode = GET_MODE (XEXP (condition, 1));
2289 /* The constant comparisons should be folded. */
2290 gcc_assert (mode != VOIDmode);
2292 /* We only handle integers or pointers. */
2293 if (GET_MODE_CLASS (mode) != MODE_INT
2294 && GET_MODE_CLASS (mode) != MODE_PARTIAL_INT)
2295 goto fail;
2297 op0 = XEXP (condition, 0);
2298 if (!iv_analyze (insn, op0, &iv0))
2299 goto fail;
2300 if (iv0.extend_mode == VOIDmode)
2301 iv0.mode = iv0.extend_mode = mode;
2303 op1 = XEXP (condition, 1);
2304 if (!iv_analyze (insn, op1, &iv1))
2305 goto fail;
2306 if (iv1.extend_mode == VOIDmode)
2307 iv1.mode = iv1.extend_mode = mode;
2309 if (GET_MODE_BITSIZE (iv0.extend_mode) > HOST_BITS_PER_WIDE_INT
2310 || GET_MODE_BITSIZE (iv1.extend_mode) > HOST_BITS_PER_WIDE_INT)
2311 goto fail;
2313 /* Check condition and normalize it. */
2315 switch (cond)
2317 case GE:
2318 case GT:
2319 case GEU:
2320 case GTU:
2321 tmp_iv = iv0; iv0 = iv1; iv1 = tmp_iv;
2322 cond = swap_condition (cond);
2323 break;
2324 case NE:
2325 case LE:
2326 case LEU:
2327 case LT:
2328 case LTU:
2329 break;
2330 default:
2331 goto fail;
2334 /* Handle extends. This is relatively nontrivial, so we only try in some
2335 easy cases, when we can canonicalize the ivs (possibly by adding some
2336 assumptions) to shape subreg (base + i * step). This function also fills
2337 in desc->mode and desc->signed_p. */
2339 if (!canonicalize_iv_subregs (&iv0, &iv1, cond, desc))
2340 goto fail;
2342 comp_mode = iv0.extend_mode;
2343 mode = iv0.mode;
2344 size = GET_MODE_BITSIZE (mode);
2345 get_mode_bounds (mode, (cond == LE || cond == LT), comp_mode, &mmin, &mmax);
2346 mode_mmin = lowpart_subreg (mode, mmin, comp_mode);
2347 mode_mmax = lowpart_subreg (mode, mmax, comp_mode);
2349 if (!CONST_INT_P (iv0.step) || !CONST_INT_P (iv1.step))
2350 goto fail;
2352 /* We can take care of the case of two induction variables chasing each other
2353 if the test is NE. I have never seen a loop using it, but still it is
2354 cool. */
2355 if (iv0.step != const0_rtx && iv1.step != const0_rtx)
2357 if (cond != NE)
2358 goto fail;
2360 iv0.step = simplify_gen_binary (MINUS, comp_mode, iv0.step, iv1.step);
2361 iv1.step = const0_rtx;
2364 /* This is either infinite loop or the one that ends immediately, depending
2365 on initial values. Unswitching should remove this kind of conditions. */
2366 if (iv0.step == const0_rtx && iv1.step == const0_rtx)
2367 goto fail;
2369 if (cond != NE)
2371 if (iv0.step == const0_rtx)
2372 step_val = -INTVAL (iv1.step);
2373 else
2374 step_val = INTVAL (iv0.step);
2376 /* Ignore loops of while (i-- < 10) type. */
2377 if (step_val < 0)
2378 goto fail;
2380 step_is_pow2 = !(step_val & (step_val - 1));
2382 else
2384 /* We do not care about whether the step is power of two in this
2385 case. */
2386 step_is_pow2 = false;
2387 step_val = 0;
2390 /* Some more condition normalization. We must record some assumptions
2391 due to overflows. */
2392 switch (cond)
2394 case LT:
2395 case LTU:
2396 /* We want to take care only of non-sharp relationals; this is easy,
2397 as in cases the overflow would make the transformation unsafe
2398 the loop does not roll. Seemingly it would make more sense to want
2399 to take care of sharp relationals instead, as NE is more similar to
2400 them, but the problem is that here the transformation would be more
2401 difficult due to possibly infinite loops. */
2402 if (iv0.step == const0_rtx)
2404 tmp = lowpart_subreg (mode, iv0.base, comp_mode);
2405 assumption = simplify_gen_relational (EQ, SImode, mode, tmp,
2406 mode_mmax);
2407 if (assumption == const_true_rtx)
2408 goto zero_iter_simplify;
2409 iv0.base = simplify_gen_binary (PLUS, comp_mode,
2410 iv0.base, const1_rtx);
2412 else
2414 tmp = lowpart_subreg (mode, iv1.base, comp_mode);
2415 assumption = simplify_gen_relational (EQ, SImode, mode, tmp,
2416 mode_mmin);
2417 if (assumption == const_true_rtx)
2418 goto zero_iter_simplify;
2419 iv1.base = simplify_gen_binary (PLUS, comp_mode,
2420 iv1.base, constm1_rtx);
2423 if (assumption != const0_rtx)
2424 desc->noloop_assumptions =
2425 alloc_EXPR_LIST (0, assumption, desc->noloop_assumptions);
2426 cond = (cond == LT) ? LE : LEU;
2428 /* It will be useful to be able to tell the difference once more in
2429 LE -> NE reduction. */
2430 was_sharp = true;
2431 break;
2432 default: ;
2435 /* Take care of trivially infinite loops. */
2436 if (cond != NE)
2438 if (iv0.step == const0_rtx)
2440 tmp = lowpart_subreg (mode, iv0.base, comp_mode);
2441 if (rtx_equal_p (tmp, mode_mmin))
2443 desc->infinite =
2444 alloc_EXPR_LIST (0, const_true_rtx, NULL_RTX);
2445 /* Fill in the remaining fields somehow. */
2446 goto zero_iter_simplify;
2449 else
2451 tmp = lowpart_subreg (mode, iv1.base, comp_mode);
2452 if (rtx_equal_p (tmp, mode_mmax))
2454 desc->infinite =
2455 alloc_EXPR_LIST (0, const_true_rtx, NULL_RTX);
2456 /* Fill in the remaining fields somehow. */
2457 goto zero_iter_simplify;
2462 /* If we can we want to take care of NE conditions instead of size
2463 comparisons, as they are much more friendly (most importantly
2464 this takes care of special handling of loops with step 1). We can
2465 do it if we first check that upper bound is greater or equal to
2466 lower bound, their difference is constant c modulo step and that
2467 there is not an overflow. */
2468 if (cond != NE)
2470 if (iv0.step == const0_rtx)
2471 step = simplify_gen_unary (NEG, comp_mode, iv1.step, comp_mode);
2472 else
2473 step = iv0.step;
2474 delta = simplify_gen_binary (MINUS, comp_mode, iv1.base, iv0.base);
2475 delta = lowpart_subreg (mode, delta, comp_mode);
2476 delta = simplify_gen_binary (UMOD, mode, delta, step);
2477 may_xform = const0_rtx;
2478 may_not_xform = const_true_rtx;
2480 if (CONST_INT_P (delta))
2482 if (was_sharp && INTVAL (delta) == INTVAL (step) - 1)
2484 /* A special case. We have transformed condition of type
2485 for (i = 0; i < 4; i += 4)
2486 into
2487 for (i = 0; i <= 3; i += 4)
2488 obviously if the test for overflow during that transformation
2489 passed, we cannot overflow here. Most importantly any
2490 loop with sharp end condition and step 1 falls into this
2491 category, so handling this case specially is definitely
2492 worth the troubles. */
2493 may_xform = const_true_rtx;
2495 else if (iv0.step == const0_rtx)
2497 bound = simplify_gen_binary (PLUS, comp_mode, mmin, step);
2498 bound = simplify_gen_binary (MINUS, comp_mode, bound, delta);
2499 bound = lowpart_subreg (mode, bound, comp_mode);
2500 tmp = lowpart_subreg (mode, iv0.base, comp_mode);
2501 may_xform = simplify_gen_relational (cond, SImode, mode,
2502 bound, tmp);
2503 may_not_xform = simplify_gen_relational (reverse_condition (cond),
2504 SImode, mode,
2505 bound, tmp);
2507 else
2509 bound = simplify_gen_binary (MINUS, comp_mode, mmax, step);
2510 bound = simplify_gen_binary (PLUS, comp_mode, bound, delta);
2511 bound = lowpart_subreg (mode, bound, comp_mode);
2512 tmp = lowpart_subreg (mode, iv1.base, comp_mode);
2513 may_xform = simplify_gen_relational (cond, SImode, mode,
2514 tmp, bound);
2515 may_not_xform = simplify_gen_relational (reverse_condition (cond),
2516 SImode, mode,
2517 tmp, bound);
2521 if (may_xform != const0_rtx)
2523 /* We perform the transformation always provided that it is not
2524 completely senseless. This is OK, as we would need this assumption
2525 to determine the number of iterations anyway. */
2526 if (may_xform != const_true_rtx)
2528 /* If the step is a power of two and the final value we have
2529 computed overflows, the cycle is infinite. Otherwise it
2530 is nontrivial to compute the number of iterations. */
2531 if (step_is_pow2)
2532 desc->infinite = alloc_EXPR_LIST (0, may_not_xform,
2533 desc->infinite);
2534 else
2535 desc->assumptions = alloc_EXPR_LIST (0, may_xform,
2536 desc->assumptions);
2539 /* We are going to lose some information about upper bound on
2540 number of iterations in this step, so record the information
2541 here. */
2542 inc = INTVAL (iv0.step) - INTVAL (iv1.step);
2543 if (CONST_INT_P (iv1.base))
2544 up = INTVAL (iv1.base);
2545 else
2546 up = INTVAL (mode_mmax) - inc;
2547 down = INTVAL (CONST_INT_P (iv0.base)
2548 ? iv0.base
2549 : mode_mmin);
2550 desc->niter_max = (up - down) / inc + 1;
2552 if (iv0.step == const0_rtx)
2554 iv0.base = simplify_gen_binary (PLUS, comp_mode, iv0.base, delta);
2555 iv0.base = simplify_gen_binary (MINUS, comp_mode, iv0.base, step);
2557 else
2559 iv1.base = simplify_gen_binary (MINUS, comp_mode, iv1.base, delta);
2560 iv1.base = simplify_gen_binary (PLUS, comp_mode, iv1.base, step);
2563 tmp0 = lowpart_subreg (mode, iv0.base, comp_mode);
2564 tmp1 = lowpart_subreg (mode, iv1.base, comp_mode);
2565 assumption = simplify_gen_relational (reverse_condition (cond),
2566 SImode, mode, tmp0, tmp1);
2567 if (assumption == const_true_rtx)
2568 goto zero_iter_simplify;
2569 else if (assumption != const0_rtx)
2570 desc->noloop_assumptions =
2571 alloc_EXPR_LIST (0, assumption, desc->noloop_assumptions);
2572 cond = NE;
2576 /* Count the number of iterations. */
2577 if (cond == NE)
2579 /* Everything we do here is just arithmetics modulo size of mode. This
2580 makes us able to do more involved computations of number of iterations
2581 than in other cases. First transform the condition into shape
2582 s * i <> c, with s positive. */
2583 iv1.base = simplify_gen_binary (MINUS, comp_mode, iv1.base, iv0.base);
2584 iv0.base = const0_rtx;
2585 iv0.step = simplify_gen_binary (MINUS, comp_mode, iv0.step, iv1.step);
2586 iv1.step = const0_rtx;
2587 if (INTVAL (iv0.step) < 0)
2589 iv0.step = simplify_gen_unary (NEG, comp_mode, iv0.step, mode);
2590 iv1.base = simplify_gen_unary (NEG, comp_mode, iv1.base, mode);
2592 iv0.step = lowpart_subreg (mode, iv0.step, comp_mode);
2594 /* Let nsd (s, size of mode) = d. If d does not divide c, the loop
2595 is infinite. Otherwise, the number of iterations is
2596 (inverse(s/d) * (c/d)) mod (size of mode/d). */
2597 s = INTVAL (iv0.step); d = 1;
2598 while (s % 2 != 1)
2600 s /= 2;
2601 d *= 2;
2602 size--;
2604 bound = GEN_INT (((unsigned HOST_WIDEST_INT) 1 << (size - 1 ) << 1) - 1);
2606 tmp1 = lowpart_subreg (mode, iv1.base, comp_mode);
2607 tmp = simplify_gen_binary (UMOD, mode, tmp1, GEN_INT (d));
2608 assumption = simplify_gen_relational (NE, SImode, mode, tmp, const0_rtx);
2609 desc->infinite = alloc_EXPR_LIST (0, assumption, desc->infinite);
2611 tmp = simplify_gen_binary (UDIV, mode, tmp1, GEN_INT (d));
2612 inv = inverse (s, size);
2613 tmp = simplify_gen_binary (MULT, mode, tmp, gen_int_mode (inv, mode));
2614 desc->niter_expr = simplify_gen_binary (AND, mode, tmp, bound);
2616 else
2618 if (iv1.step == const0_rtx)
2619 /* Condition in shape a + s * i <= b
2620 We must know that b + s does not overflow and a <= b + s and then we
2621 can compute number of iterations as (b + s - a) / s. (It might
2622 seem that we in fact could be more clever about testing the b + s
2623 overflow condition using some information about b - a mod s,
2624 but it was already taken into account during LE -> NE transform). */
2626 step = iv0.step;
2627 tmp0 = lowpart_subreg (mode, iv0.base, comp_mode);
2628 tmp1 = lowpart_subreg (mode, iv1.base, comp_mode);
2630 bound = simplify_gen_binary (MINUS, mode, mode_mmax,
2631 lowpart_subreg (mode, step,
2632 comp_mode));
2633 if (step_is_pow2)
2635 rtx t0, t1;
2637 /* If s is power of 2, we know that the loop is infinite if
2638 a % s <= b % s and b + s overflows. */
2639 assumption = simplify_gen_relational (reverse_condition (cond),
2640 SImode, mode,
2641 tmp1, bound);
2643 t0 = simplify_gen_binary (UMOD, mode, copy_rtx (tmp0), step);
2644 t1 = simplify_gen_binary (UMOD, mode, copy_rtx (tmp1), step);
2645 tmp = simplify_gen_relational (cond, SImode, mode, t0, t1);
2646 assumption = simplify_gen_binary (AND, SImode, assumption, tmp);
2647 desc->infinite =
2648 alloc_EXPR_LIST (0, assumption, desc->infinite);
2650 else
2652 assumption = simplify_gen_relational (cond, SImode, mode,
2653 tmp1, bound);
2654 desc->assumptions =
2655 alloc_EXPR_LIST (0, assumption, desc->assumptions);
2658 tmp = simplify_gen_binary (PLUS, comp_mode, iv1.base, iv0.step);
2659 tmp = lowpart_subreg (mode, tmp, comp_mode);
2660 assumption = simplify_gen_relational (reverse_condition (cond),
2661 SImode, mode, tmp0, tmp);
2663 delta = simplify_gen_binary (PLUS, mode, tmp1, step);
2664 delta = simplify_gen_binary (MINUS, mode, delta, tmp0);
2666 else
2668 /* Condition in shape a <= b - s * i
2669 We must know that a - s does not overflow and a - s <= b and then
2670 we can again compute number of iterations as (b - (a - s)) / s. */
2671 step = simplify_gen_unary (NEG, mode, iv1.step, mode);
2672 tmp0 = lowpart_subreg (mode, iv0.base, comp_mode);
2673 tmp1 = lowpart_subreg (mode, iv1.base, comp_mode);
2675 bound = simplify_gen_binary (PLUS, mode, mode_mmin,
2676 lowpart_subreg (mode, step, comp_mode));
2677 if (step_is_pow2)
2679 rtx t0, t1;
2681 /* If s is power of 2, we know that the loop is infinite if
2682 a % s <= b % s and a - s overflows. */
2683 assumption = simplify_gen_relational (reverse_condition (cond),
2684 SImode, mode,
2685 bound, tmp0);
2687 t0 = simplify_gen_binary (UMOD, mode, copy_rtx (tmp0), step);
2688 t1 = simplify_gen_binary (UMOD, mode, copy_rtx (tmp1), step);
2689 tmp = simplify_gen_relational (cond, SImode, mode, t0, t1);
2690 assumption = simplify_gen_binary (AND, SImode, assumption, tmp);
2691 desc->infinite =
2692 alloc_EXPR_LIST (0, assumption, desc->infinite);
2694 else
2696 assumption = simplify_gen_relational (cond, SImode, mode,
2697 bound, tmp0);
2698 desc->assumptions =
2699 alloc_EXPR_LIST (0, assumption, desc->assumptions);
2702 tmp = simplify_gen_binary (PLUS, comp_mode, iv0.base, iv1.step);
2703 tmp = lowpart_subreg (mode, tmp, comp_mode);
2704 assumption = simplify_gen_relational (reverse_condition (cond),
2705 SImode, mode,
2706 tmp, tmp1);
2707 delta = simplify_gen_binary (MINUS, mode, tmp0, step);
2708 delta = simplify_gen_binary (MINUS, mode, tmp1, delta);
2710 if (assumption == const_true_rtx)
2711 goto zero_iter_simplify;
2712 else if (assumption != const0_rtx)
2713 desc->noloop_assumptions =
2714 alloc_EXPR_LIST (0, assumption, desc->noloop_assumptions);
2715 delta = simplify_gen_binary (UDIV, mode, delta, step);
2716 desc->niter_expr = delta;
2719 old_niter = desc->niter_expr;
2721 simplify_using_initial_values (loop, AND, &desc->assumptions);
2722 if (desc->assumptions
2723 && XEXP (desc->assumptions, 0) == const0_rtx)
2724 goto fail;
2725 simplify_using_initial_values (loop, IOR, &desc->noloop_assumptions);
2726 simplify_using_initial_values (loop, IOR, &desc->infinite);
2727 simplify_using_initial_values (loop, UNKNOWN, &desc->niter_expr);
2729 /* Rerun the simplification. Consider code (created by copying loop headers)
2731 i = 0;
2733 if (0 < n)
2737 i++;
2738 } while (i < n);
2741 The first pass determines that i = 0, the second pass uses it to eliminate
2742 noloop assumption. */
2744 simplify_using_initial_values (loop, AND, &desc->assumptions);
2745 if (desc->assumptions
2746 && XEXP (desc->assumptions, 0) == const0_rtx)
2747 goto fail;
2748 simplify_using_initial_values (loop, IOR, &desc->noloop_assumptions);
2749 simplify_using_initial_values (loop, IOR, &desc->infinite);
2750 simplify_using_initial_values (loop, UNKNOWN, &desc->niter_expr);
2752 if (desc->noloop_assumptions
2753 && XEXP (desc->noloop_assumptions, 0) == const_true_rtx)
2754 goto zero_iter;
2756 if (CONST_INT_P (desc->niter_expr))
2758 unsigned HOST_WIDEST_INT val = INTVAL (desc->niter_expr);
2760 desc->const_iter = true;
2761 desc->niter_max = desc->niter = val & GET_MODE_MASK (desc->mode);
2763 else
2765 if (!desc->niter_max)
2766 desc->niter_max = determine_max_iter (loop, desc, old_niter);
2768 /* simplify_using_initial_values does a copy propagation on the registers
2769 in the expression for the number of iterations. This prolongs life
2770 ranges of registers and increases register pressure, and usually
2771 brings no gain (and if it happens to do, the cse pass will take care
2772 of it anyway). So prevent this behavior, unless it enabled us to
2773 derive that the number of iterations is a constant. */
2774 desc->niter_expr = old_niter;
2777 return;
2779 zero_iter_simplify:
2780 /* Simplify the assumptions. */
2781 simplify_using_initial_values (loop, AND, &desc->assumptions);
2782 if (desc->assumptions
2783 && XEXP (desc->assumptions, 0) == const0_rtx)
2784 goto fail;
2785 simplify_using_initial_values (loop, IOR, &desc->infinite);
2787 /* Fallthru. */
2788 zero_iter:
2789 desc->const_iter = true;
2790 desc->niter = 0;
2791 desc->niter_max = 0;
2792 desc->noloop_assumptions = NULL_RTX;
2793 desc->niter_expr = const0_rtx;
2794 return;
2796 fail:
2797 desc->simple_p = false;
2798 return;
2801 /* Checks whether E is a simple exit from LOOP and stores its description
2802 into DESC. */
2804 static void
2805 check_simple_exit (struct loop *loop, edge e, struct niter_desc *desc)
2807 basic_block exit_bb;
2808 rtx condition, at;
2809 edge ein;
2811 exit_bb = e->src;
2812 desc->simple_p = false;
2814 /* It must belong directly to the loop. */
2815 if (exit_bb->loop_father != loop)
2816 return;
2818 /* It must be tested (at least) once during any iteration. */
2819 if (!dominated_by_p (CDI_DOMINATORS, loop->latch, exit_bb))
2820 return;
2822 /* It must end in a simple conditional jump. */
2823 if (!any_condjump_p (BB_END (exit_bb)))
2824 return;
2826 ein = EDGE_SUCC (exit_bb, 0);
2827 if (ein == e)
2828 ein = EDGE_SUCC (exit_bb, 1);
2830 desc->out_edge = e;
2831 desc->in_edge = ein;
2833 /* Test whether the condition is suitable. */
2834 if (!(condition = get_condition (BB_END (ein->src), &at, false, false)))
2835 return;
2837 if (ein->flags & EDGE_FALLTHRU)
2839 condition = reversed_condition (condition);
2840 if (!condition)
2841 return;
2844 /* Check that we are able to determine number of iterations and fill
2845 in information about it. */
2846 iv_number_of_iterations (loop, at, condition, desc);
2849 /* Finds a simple exit of LOOP and stores its description into DESC. */
2851 void
2852 find_simple_exit (struct loop *loop, struct niter_desc *desc)
2854 unsigned i;
2855 basic_block *body;
2856 edge e;
2857 struct niter_desc act;
2858 bool any = false;
2859 edge_iterator ei;
2861 desc->simple_p = false;
2862 body = get_loop_body (loop);
2864 for (i = 0; i < loop->num_nodes; i++)
2866 FOR_EACH_EDGE (e, ei, body[i]->succs)
2868 if (flow_bb_inside_loop_p (loop, e->dest))
2869 continue;
2871 check_simple_exit (loop, e, &act);
2872 if (!act.simple_p)
2873 continue;
2875 if (!any)
2876 any = true;
2877 else
2879 /* Prefer constant iterations; the less the better. */
2880 if (!act.const_iter
2881 || (desc->const_iter && act.niter >= desc->niter))
2882 continue;
2884 /* Also if the actual exit may be infinite, while the old one
2885 not, prefer the old one. */
2886 if (act.infinite && !desc->infinite)
2887 continue;
2890 *desc = act;
2894 if (dump_file)
2896 if (desc->simple_p)
2898 fprintf (dump_file, "Loop %d is simple:\n", loop->num);
2899 fprintf (dump_file, " simple exit %d -> %d\n",
2900 desc->out_edge->src->index,
2901 desc->out_edge->dest->index);
2902 if (desc->assumptions)
2904 fprintf (dump_file, " assumptions: ");
2905 print_rtl (dump_file, desc->assumptions);
2906 fprintf (dump_file, "\n");
2908 if (desc->noloop_assumptions)
2910 fprintf (dump_file, " does not roll if: ");
2911 print_rtl (dump_file, desc->noloop_assumptions);
2912 fprintf (dump_file, "\n");
2914 if (desc->infinite)
2916 fprintf (dump_file, " infinite if: ");
2917 print_rtl (dump_file, desc->infinite);
2918 fprintf (dump_file, "\n");
2921 fprintf (dump_file, " number of iterations: ");
2922 print_rtl (dump_file, desc->niter_expr);
2923 fprintf (dump_file, "\n");
2925 fprintf (dump_file, " upper bound: ");
2926 fprintf (dump_file, HOST_WIDEST_INT_PRINT_DEC, desc->niter_max);
2927 fprintf (dump_file, "\n");
2929 else
2930 fprintf (dump_file, "Loop %d is not simple.\n", loop->num);
2933 free (body);
2936 /* Creates a simple loop description of LOOP if it was not computed
2937 already. */
2939 struct niter_desc *
2940 get_simple_loop_desc (struct loop *loop)
2942 struct niter_desc *desc = simple_loop_desc (loop);
2944 if (desc)
2945 return desc;
2947 /* At least desc->infinite is not always initialized by
2948 find_simple_loop_exit. */
2949 desc = XCNEW (struct niter_desc);
2950 iv_analysis_loop_init (loop);
2951 find_simple_exit (loop, desc);
2952 loop->aux = desc;
2954 if (desc->simple_p && (desc->assumptions || desc->infinite))
2956 const char *wording;
2958 /* Assume that no overflow happens and that the loop is finite.
2959 We already warned at the tree level if we ran optimizations there. */
2960 if (!flag_tree_loop_optimize && warn_unsafe_loop_optimizations)
2962 if (desc->infinite)
2964 wording =
2965 flag_unsafe_loop_optimizations
2966 ? N_("assuming that the loop is not infinite")
2967 : N_("cannot optimize possibly infinite loops");
2968 warning (OPT_Wunsafe_loop_optimizations, "%s",
2969 gettext (wording));
2971 if (desc->assumptions)
2973 wording =
2974 flag_unsafe_loop_optimizations
2975 ? N_("assuming that the loop counter does not overflow")
2976 : N_("cannot optimize loop, the loop counter may overflow");
2977 warning (OPT_Wunsafe_loop_optimizations, "%s",
2978 gettext (wording));
2982 if (flag_unsafe_loop_optimizations)
2984 desc->assumptions = NULL_RTX;
2985 desc->infinite = NULL_RTX;
2989 return desc;
2992 /* Releases simple loop description for LOOP. */
2994 void
2995 free_simple_loop_desc (struct loop *loop)
2997 struct niter_desc *desc = simple_loop_desc (loop);
2999 if (!desc)
3000 return;
3002 free (desc);
3003 loop->aux = NULL;