PR rtl-optimization/26087
[official-gcc.git] / gcc / loop-iv.c
blobe234fd93b7993283edaa06a167021e60ed36fe3f
1 /* Rtl-level induction variable analysis.
2 Copyright (C) 2004, 2005 Free Software Foundation, Inc.
4 This file is part of GCC.
6 GCC is free software; you can redistribute it and/or modify it
7 under the terms of the GNU General Public License as published by the
8 Free Software Foundation; either version 2, or (at your option) any
9 later version.
11 GCC is distributed in the hope that it will be useful, but WITHOUT
12 ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
13 FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
14 for more details.
16 You should have received a copy of the GNU General Public License
17 along with GCC; see the file COPYING. If not, write to the Free
18 Software Foundation, 51 Franklin Street, Fifth Floor, Boston, MA
19 02110-1301, USA. */
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 variable is analyzed by walking the use-def chains. When a biv
27 is found, it is cached in the bivs hash table. When register is proved
28 to be a giv, its description is stored to DF_REF_DATA of the def reference.
30 The analysis works always with one loop -- you must call
31 iv_analysis_loop_init (loop) for it. All the other functions then work with
32 this loop. When you need to work with another loop, just call
33 iv_analysis_loop_init for it. When you no longer need iv analysis, call
34 iv_analysis_done () to clean up the memory.
36 The available functions are:
38 iv_analyze (insn, reg, iv): Stores the description of the induction variable
39 corresponding to the use of register REG in INSN to IV. Returns true if
40 REG is an induction variable in INSN. false otherwise.
41 If use of REG is not found in INSN, following insns are scanned (so that
42 we may call this function on insn returned by get_condition).
43 iv_analyze_result (insn, def, iv): Stores to IV the description of the iv
44 corresponding to DEF, which is a register defined in INSN.
45 iv_analyze_expr (insn, rhs, mode, iv): Stores to IV the description of iv
46 corresponding to expression EXPR evaluated at INSN. All registers used bu
47 EXPR must also be used in INSN.
48 iv_current_loop_df (): Returns the dataflow object for the current loop used
49 by iv analysis. */
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 /* Induction variable stored at the reference. */
96 #define DF_REF_IV(REF) ((struct rtx_iv *) DF_REF_DATA (REF))
97 #define DF_REF_IV_SET(REF, IV) DF_REF_DATA (REF) = (IV)
99 /* The current loop. */
101 static struct loop *current_loop;
103 /* Dataflow information for the current loop. */
105 static struct df *df = NULL;
107 /* Bivs of the current loop. */
109 static htab_t bivs;
111 /* Return the dataflow object for the current loop. */
112 struct df *
113 iv_current_loop_df (void)
115 return df;
118 static bool iv_analyze_op (rtx, rtx, struct rtx_iv *);
120 /* Dumps information about IV to FILE. */
122 extern void dump_iv_info (FILE *, struct rtx_iv *);
123 void
124 dump_iv_info (FILE *file, struct rtx_iv *iv)
126 if (!iv->base)
128 fprintf (file, "not simple");
129 return;
132 if (iv->step == const0_rtx
133 && !iv->first_special)
134 fprintf (file, "invariant ");
136 print_rtl (file, iv->base);
137 if (iv->step != const0_rtx)
139 fprintf (file, " + ");
140 print_rtl (file, iv->step);
141 fprintf (file, " * iteration");
143 fprintf (file, " (in %s)", GET_MODE_NAME (iv->mode));
145 if (iv->mode != iv->extend_mode)
146 fprintf (file, " %s to %s",
147 rtx_name[iv->extend],
148 GET_MODE_NAME (iv->extend_mode));
150 if (iv->mult != const1_rtx)
152 fprintf (file, " * ");
153 print_rtl (file, iv->mult);
155 if (iv->delta != const0_rtx)
157 fprintf (file, " + ");
158 print_rtl (file, iv->delta);
160 if (iv->first_special)
161 fprintf (file, " (first special)");
164 /* Generates a subreg to get the least significant part of EXPR (in mode
165 INNER_MODE) to OUTER_MODE. */
168 lowpart_subreg (enum machine_mode outer_mode, rtx expr,
169 enum machine_mode inner_mode)
171 return simplify_gen_subreg (outer_mode, expr, inner_mode,
172 subreg_lowpart_offset (outer_mode, inner_mode));
175 /* Checks whether REG is a well-behaved register. */
177 static bool
178 simple_reg_p (rtx reg)
180 unsigned r;
182 if (GET_CODE (reg) == SUBREG)
184 if (!subreg_lowpart_p (reg))
185 return false;
186 reg = SUBREG_REG (reg);
189 if (!REG_P (reg))
190 return false;
192 r = REGNO (reg);
193 if (HARD_REGISTER_NUM_P (r))
194 return false;
196 if (GET_MODE_CLASS (GET_MODE (reg)) != MODE_INT)
197 return false;
199 return true;
202 /* Clears the information about ivs stored in df. */
204 static void
205 clear_iv_info (void)
207 unsigned i, n_defs = DF_DEFS_SIZE (df);
208 struct rtx_iv *iv;
209 struct df_ref *def;
211 for (i = 0; i < n_defs; i++)
213 def = DF_DEFS_GET (df, i);
214 iv = DF_REF_IV (def);
215 if (!iv)
216 continue;
217 free (iv);
218 DF_REF_IV_SET (def, NULL);
221 htab_empty (bivs);
224 /* Returns hash value for biv B. */
226 static hashval_t
227 biv_hash (const void *b)
229 return ((const struct biv_entry *) b)->regno;
232 /* Compares biv B and register R. */
234 static int
235 biv_eq (const void *b, const void *r)
237 return ((const struct biv_entry *) b)->regno == REGNO ((rtx) r);
240 /* Prepare the data for an induction variable analysis of a LOOP. */
242 void
243 iv_analysis_loop_init (struct loop *loop)
245 basic_block *body = get_loop_body_in_dom_order (loop), bb;
246 bitmap blocks = BITMAP_ALLOC (NULL);
247 unsigned i;
248 bool first_time = (df == NULL);
250 current_loop = loop;
252 /* Clear the information from the analysis of the previous loop. */
253 if (first_time)
255 df = df_init (DF_HARD_REGS | DF_EQUIV_NOTES);
256 df_chain_add_problem (df, DF_UD_CHAIN);
257 bivs = htab_create (10, biv_hash, biv_eq, free);
259 else
260 clear_iv_info ();
262 for (i = 0; i < loop->num_nodes; i++)
264 bb = body[i];
265 bitmap_set_bit (blocks, bb->index);
267 df_set_blocks (df, blocks);
268 df_analyze (df);
269 BITMAP_FREE (blocks);
270 free (body);
273 /* Finds the definition of REG that dominates loop latch and stores
274 it to DEF. Returns false if there is not a single definition
275 dominating the latch. If REG has no definition in loop, DEF
276 is set to NULL and true is returned. */
278 static bool
279 latch_dominating_def (rtx reg, struct df_ref **def)
281 struct df_ref *single_rd = NULL, *adef;
282 unsigned regno = REGNO (reg);
283 struct df_reg_info *reg_info = DF_REG_DEF_GET (df, regno);
284 struct df_rd_bb_info *bb_info = DF_RD_BB_INFO (df, current_loop->latch);
286 for (adef = reg_info->reg_chain; adef; adef = adef->next_reg)
288 if (!bitmap_bit_p (bb_info->out, DF_REF_ID (adef)))
289 continue;
291 /* More than one reaching definition. */
292 if (single_rd)
293 return false;
295 if (!just_once_each_iteration_p (current_loop, DF_REF_BB (adef)))
296 return false;
298 single_rd = adef;
301 *def = single_rd;
302 return true;
305 /* Gets definition of REG reaching its use in INSN and stores it to DEF. */
307 static enum iv_grd_result
308 iv_get_reaching_def (rtx insn, rtx reg, struct df_ref **def)
310 struct df_ref *use, *adef;
311 basic_block def_bb, use_bb;
312 rtx def_insn;
313 bool dom_p;
315 *def = NULL;
316 if (!simple_reg_p (reg))
317 return GRD_INVALID;
318 if (GET_CODE (reg) == SUBREG)
319 reg = SUBREG_REG (reg);
320 gcc_assert (REG_P (reg));
322 use = df_find_use (df, insn, reg);
323 gcc_assert (use != NULL);
325 if (!DF_REF_CHAIN (use))
326 return GRD_INVARIANT;
328 /* More than one reaching def. */
329 if (DF_REF_CHAIN (use)->next)
330 return GRD_INVALID;
332 adef = DF_REF_CHAIN (use)->ref;
333 def_insn = DF_REF_INSN (adef);
334 def_bb = DF_REF_BB (adef);
335 use_bb = BLOCK_FOR_INSN (insn);
337 if (use_bb == def_bb)
338 dom_p = (DF_INSN_LUID (df, def_insn) < DF_INSN_LUID (df, insn));
339 else
340 dom_p = dominated_by_p (CDI_DOMINATORS, use_bb, def_bb);
342 if (dom_p)
344 *def = adef;
345 return GRD_SINGLE_DOM;
348 /* The definition does not dominate the use. This is still OK if
349 this may be a use of a biv, i.e. if the def_bb dominates loop
350 latch. */
351 if (just_once_each_iteration_p (current_loop, def_bb))
352 return GRD_MAYBE_BIV;
354 return GRD_INVALID;
357 /* Sets IV to invariant CST in MODE. Always returns true (just for
358 consistency with other iv manipulation functions that may fail). */
360 static bool
361 iv_constant (struct rtx_iv *iv, rtx cst, enum machine_mode mode)
363 if (mode == VOIDmode)
364 mode = GET_MODE (cst);
366 iv->mode = mode;
367 iv->base = cst;
368 iv->step = const0_rtx;
369 iv->first_special = false;
370 iv->extend = UNKNOWN;
371 iv->extend_mode = iv->mode;
372 iv->delta = const0_rtx;
373 iv->mult = const1_rtx;
375 return true;
378 /* Evaluates application of subreg to MODE on IV. */
380 static bool
381 iv_subreg (struct rtx_iv *iv, enum machine_mode mode)
383 /* If iv is invariant, just calculate the new value. */
384 if (iv->step == const0_rtx
385 && !iv->first_special)
387 rtx val = get_iv_value (iv, const0_rtx);
388 val = lowpart_subreg (mode, val, iv->extend_mode);
390 iv->base = val;
391 iv->extend = UNKNOWN;
392 iv->mode = iv->extend_mode = mode;
393 iv->delta = const0_rtx;
394 iv->mult = const1_rtx;
395 return true;
398 if (iv->extend_mode == mode)
399 return true;
401 if (GET_MODE_BITSIZE (mode) > GET_MODE_BITSIZE (iv->mode))
402 return false;
404 iv->extend = UNKNOWN;
405 iv->mode = mode;
407 iv->base = simplify_gen_binary (PLUS, iv->extend_mode, iv->delta,
408 simplify_gen_binary (MULT, iv->extend_mode,
409 iv->base, iv->mult));
410 iv->step = simplify_gen_binary (MULT, iv->extend_mode, iv->step, iv->mult);
411 iv->mult = const1_rtx;
412 iv->delta = const0_rtx;
413 iv->first_special = false;
415 return true;
418 /* Evaluates application of EXTEND to MODE on IV. */
420 static bool
421 iv_extend (struct rtx_iv *iv, enum rtx_code extend, enum machine_mode mode)
423 /* If iv is invariant, just calculate the new value. */
424 if (iv->step == const0_rtx
425 && !iv->first_special)
427 rtx val = get_iv_value (iv, const0_rtx);
428 val = simplify_gen_unary (extend, mode, val, iv->extend_mode);
430 iv->base = val;
431 iv->extend = UNKNOWN;
432 iv->mode = iv->extend_mode = mode;
433 iv->delta = const0_rtx;
434 iv->mult = const1_rtx;
435 return true;
438 if (mode != iv->extend_mode)
439 return false;
441 if (iv->extend != UNKNOWN
442 && iv->extend != extend)
443 return false;
445 iv->extend = extend;
447 return true;
450 /* Evaluates negation of IV. */
452 static bool
453 iv_neg (struct rtx_iv *iv)
455 if (iv->extend == UNKNOWN)
457 iv->base = simplify_gen_unary (NEG, iv->extend_mode,
458 iv->base, iv->extend_mode);
459 iv->step = simplify_gen_unary (NEG, iv->extend_mode,
460 iv->step, iv->extend_mode);
462 else
464 iv->delta = simplify_gen_unary (NEG, iv->extend_mode,
465 iv->delta, iv->extend_mode);
466 iv->mult = simplify_gen_unary (NEG, iv->extend_mode,
467 iv->mult, iv->extend_mode);
470 return true;
473 /* Evaluates addition or subtraction (according to OP) of IV1 to IV0. */
475 static bool
476 iv_add (struct rtx_iv *iv0, struct rtx_iv *iv1, enum rtx_code op)
478 enum machine_mode mode;
479 rtx arg;
481 /* Extend the constant to extend_mode of the other operand if necessary. */
482 if (iv0->extend == UNKNOWN
483 && iv0->mode == iv0->extend_mode
484 && iv0->step == const0_rtx
485 && GET_MODE_SIZE (iv0->extend_mode) < GET_MODE_SIZE (iv1->extend_mode))
487 iv0->extend_mode = iv1->extend_mode;
488 iv0->base = simplify_gen_unary (ZERO_EXTEND, iv0->extend_mode,
489 iv0->base, iv0->mode);
491 if (iv1->extend == UNKNOWN
492 && iv1->mode == iv1->extend_mode
493 && iv1->step == const0_rtx
494 && GET_MODE_SIZE (iv1->extend_mode) < GET_MODE_SIZE (iv0->extend_mode))
496 iv1->extend_mode = iv0->extend_mode;
497 iv1->base = simplify_gen_unary (ZERO_EXTEND, iv1->extend_mode,
498 iv1->base, iv1->mode);
501 mode = iv0->extend_mode;
502 if (mode != iv1->extend_mode)
503 return false;
505 if (iv0->extend == UNKNOWN && iv1->extend == UNKNOWN)
507 if (iv0->mode != iv1->mode)
508 return false;
510 iv0->base = simplify_gen_binary (op, mode, iv0->base, iv1->base);
511 iv0->step = simplify_gen_binary (op, mode, iv0->step, iv1->step);
513 return true;
516 /* Handle addition of constant. */
517 if (iv1->extend == UNKNOWN
518 && iv1->mode == mode
519 && iv1->step == const0_rtx)
521 iv0->delta = simplify_gen_binary (op, mode, iv0->delta, iv1->base);
522 return true;
525 if (iv0->extend == UNKNOWN
526 && iv0->mode == mode
527 && iv0->step == const0_rtx)
529 arg = iv0->base;
530 *iv0 = *iv1;
531 if (op == MINUS
532 && !iv_neg (iv0))
533 return false;
535 iv0->delta = simplify_gen_binary (PLUS, mode, iv0->delta, arg);
536 return true;
539 return false;
542 /* Evaluates multiplication of IV by constant CST. */
544 static bool
545 iv_mult (struct rtx_iv *iv, rtx mby)
547 enum machine_mode mode = iv->extend_mode;
549 if (GET_MODE (mby) != VOIDmode
550 && GET_MODE (mby) != mode)
551 return false;
553 if (iv->extend == UNKNOWN)
555 iv->base = simplify_gen_binary (MULT, mode, iv->base, mby);
556 iv->step = simplify_gen_binary (MULT, mode, iv->step, mby);
558 else
560 iv->delta = simplify_gen_binary (MULT, mode, iv->delta, mby);
561 iv->mult = simplify_gen_binary (MULT, mode, iv->mult, mby);
564 return true;
567 /* Evaluates shift of IV by constant CST. */
569 static bool
570 iv_shift (struct rtx_iv *iv, rtx mby)
572 enum machine_mode mode = iv->extend_mode;
574 if (GET_MODE (mby) != VOIDmode
575 && GET_MODE (mby) != mode)
576 return false;
578 if (iv->extend == UNKNOWN)
580 iv->base = simplify_gen_binary (ASHIFT, mode, iv->base, mby);
581 iv->step = simplify_gen_binary (ASHIFT, mode, iv->step, mby);
583 else
585 iv->delta = simplify_gen_binary (ASHIFT, mode, iv->delta, mby);
586 iv->mult = simplify_gen_binary (ASHIFT, mode, iv->mult, mby);
589 return true;
592 /* The recursive part of get_biv_step. Gets the value of the single value
593 defined by DEF wrto initial value of REG inside loop, in shape described
594 at get_biv_step. */
596 static bool
597 get_biv_step_1 (struct df_ref *def, rtx reg,
598 rtx *inner_step, enum machine_mode *inner_mode,
599 enum rtx_code *extend, enum machine_mode outer_mode,
600 rtx *outer_step)
602 rtx set, rhs, op0 = NULL_RTX, op1 = NULL_RTX;
603 rtx next, nextr, tmp;
604 enum rtx_code code;
605 rtx insn = DF_REF_INSN (def);
606 struct df_ref *next_def;
607 enum iv_grd_result res;
609 set = single_set (insn);
610 if (!set)
611 return false;
613 rhs = find_reg_equal_equiv_note (insn);
614 if (rhs)
615 rhs = XEXP (rhs, 0);
616 else
617 rhs = SET_SRC (set);
619 code = GET_CODE (rhs);
620 switch (code)
622 case SUBREG:
623 case REG:
624 next = rhs;
625 break;
627 case PLUS:
628 case MINUS:
629 op0 = XEXP (rhs, 0);
630 op1 = XEXP (rhs, 1);
632 if (code == PLUS && CONSTANT_P (op0))
634 tmp = op0; op0 = op1; op1 = tmp;
637 if (!simple_reg_p (op0)
638 || !CONSTANT_P (op1))
639 return false;
641 if (GET_MODE (rhs) != outer_mode)
643 /* ppc64 uses expressions like
645 (set x:SI (plus:SI (subreg:SI y:DI) 1)).
647 this is equivalent to
649 (set x':DI (plus:DI y:DI 1))
650 (set x:SI (subreg:SI (x':DI)). */
651 if (GET_CODE (op0) != SUBREG)
652 return false;
653 if (GET_MODE (SUBREG_REG (op0)) != outer_mode)
654 return false;
657 next = op0;
658 break;
660 case SIGN_EXTEND:
661 case ZERO_EXTEND:
662 if (GET_MODE (rhs) != outer_mode)
663 return false;
665 op0 = XEXP (rhs, 0);
666 if (!simple_reg_p (op0))
667 return false;
669 next = op0;
670 break;
672 default:
673 return false;
676 if (GET_CODE (next) == SUBREG)
678 if (!subreg_lowpart_p (next))
679 return false;
681 nextr = SUBREG_REG (next);
682 if (GET_MODE (nextr) != outer_mode)
683 return false;
685 else
686 nextr = next;
688 res = iv_get_reaching_def (insn, nextr, &next_def);
690 if (res == GRD_INVALID || res == GRD_INVARIANT)
691 return false;
693 if (res == GRD_MAYBE_BIV)
695 if (!rtx_equal_p (nextr, reg))
696 return false;
698 *inner_step = const0_rtx;
699 *extend = UNKNOWN;
700 *inner_mode = outer_mode;
701 *outer_step = const0_rtx;
703 else if (!get_biv_step_1 (next_def, reg,
704 inner_step, inner_mode, extend, outer_mode,
705 outer_step))
706 return false;
708 if (GET_CODE (next) == SUBREG)
710 enum machine_mode amode = GET_MODE (next);
712 if (GET_MODE_SIZE (amode) > GET_MODE_SIZE (*inner_mode))
713 return false;
715 *inner_mode = amode;
716 *inner_step = simplify_gen_binary (PLUS, outer_mode,
717 *inner_step, *outer_step);
718 *outer_step = const0_rtx;
719 *extend = UNKNOWN;
722 switch (code)
724 case REG:
725 case SUBREG:
726 break;
728 case PLUS:
729 case MINUS:
730 if (*inner_mode == outer_mode
731 /* See comment in previous switch. */
732 || GET_MODE (rhs) != outer_mode)
733 *inner_step = simplify_gen_binary (code, outer_mode,
734 *inner_step, op1);
735 else
736 *outer_step = simplify_gen_binary (code, outer_mode,
737 *outer_step, op1);
738 break;
740 case SIGN_EXTEND:
741 case ZERO_EXTEND:
742 gcc_assert (GET_MODE (op0) == *inner_mode
743 && *extend == UNKNOWN
744 && *outer_step == const0_rtx);
746 *extend = code;
747 break;
749 default:
750 return false;
753 return true;
756 /* Gets the operation on register REG inside loop, in shape
758 OUTER_STEP + EXTEND_{OUTER_MODE} (SUBREG_{INNER_MODE} (REG + INNER_STEP))
760 If the operation cannot be described in this shape, return false.
761 LAST_DEF is the definition of REG that dominates loop latch. */
763 static bool
764 get_biv_step (struct df_ref *last_def, rtx reg, rtx *inner_step,
765 enum machine_mode *inner_mode, enum rtx_code *extend,
766 enum machine_mode *outer_mode, rtx *outer_step)
768 *outer_mode = GET_MODE (reg);
770 if (!get_biv_step_1 (last_def, reg,
771 inner_step, inner_mode, extend, *outer_mode,
772 outer_step))
773 return false;
775 gcc_assert ((*inner_mode == *outer_mode) != (*extend != UNKNOWN));
776 gcc_assert (*inner_mode != *outer_mode || *outer_step == const0_rtx);
778 return true;
781 /* Records information that DEF is induction variable IV. */
783 static void
784 record_iv (struct df_ref *def, struct rtx_iv *iv)
786 struct rtx_iv *recorded_iv = XNEW (struct rtx_iv);
788 *recorded_iv = *iv;
789 DF_REF_IV_SET (def, recorded_iv);
792 /* If DEF was already analyzed for bivness, store the description of the biv to
793 IV and return true. Otherwise return false. */
795 static bool
796 analyzed_for_bivness_p (rtx def, struct rtx_iv *iv)
798 struct biv_entry *biv = htab_find_with_hash (bivs, def, REGNO (def));
800 if (!biv)
801 return false;
803 *iv = biv->iv;
804 return true;
807 static void
808 record_biv (rtx def, struct rtx_iv *iv)
810 struct biv_entry *biv = XNEW (struct biv_entry);
811 void **slot = htab_find_slot_with_hash (bivs, def, REGNO (def), INSERT);
813 biv->regno = REGNO (def);
814 biv->iv = *iv;
815 gcc_assert (!*slot);
816 *slot = biv;
819 /* Determines whether DEF is a biv and if so, stores its description
820 to *IV. */
822 static bool
823 iv_analyze_biv (rtx def, struct rtx_iv *iv)
825 rtx inner_step, outer_step;
826 enum machine_mode inner_mode, outer_mode;
827 enum rtx_code extend;
828 struct df_ref *last_def;
830 if (dump_file)
832 fprintf (dump_file, "Analyzing ");
833 print_rtl (dump_file, def);
834 fprintf (dump_file, " for bivness.\n");
837 if (!REG_P (def))
839 if (!CONSTANT_P (def))
840 return false;
842 return iv_constant (iv, def, VOIDmode);
845 if (!latch_dominating_def (def, &last_def))
847 if (dump_file)
848 fprintf (dump_file, " not simple.\n");
849 return false;
852 if (!last_def)
853 return iv_constant (iv, def, VOIDmode);
855 if (analyzed_for_bivness_p (def, iv))
857 if (dump_file)
858 fprintf (dump_file, " already analysed.\n");
859 return iv->base != NULL_RTX;
862 if (!get_biv_step (last_def, def, &inner_step, &inner_mode, &extend,
863 &outer_mode, &outer_step))
865 iv->base = NULL_RTX;
866 goto end;
869 /* Loop transforms base to es (base + inner_step) + outer_step,
870 where es means extend of subreg between inner_mode and outer_mode.
871 The corresponding induction variable is
873 es ((base - outer_step) + i * (inner_step + outer_step)) + outer_step */
875 iv->base = simplify_gen_binary (MINUS, outer_mode, def, outer_step);
876 iv->step = simplify_gen_binary (PLUS, outer_mode, inner_step, outer_step);
877 iv->mode = inner_mode;
878 iv->extend_mode = outer_mode;
879 iv->extend = extend;
880 iv->mult = const1_rtx;
881 iv->delta = outer_step;
882 iv->first_special = inner_mode != outer_mode;
884 end:
885 if (dump_file)
887 fprintf (dump_file, " ");
888 dump_iv_info (dump_file, iv);
889 fprintf (dump_file, "\n");
892 record_biv (def, iv);
893 return iv->base != NULL_RTX;
896 /* Analyzes expression RHS used at INSN and stores the result to *IV.
897 The mode of the induction variable is MODE. */
899 bool
900 iv_analyze_expr (rtx insn, rtx rhs, enum machine_mode mode, struct rtx_iv *iv)
902 rtx mby = NULL_RTX, tmp;
903 rtx op0 = NULL_RTX, op1 = NULL_RTX;
904 struct rtx_iv iv0, iv1;
905 enum rtx_code code = GET_CODE (rhs);
906 enum machine_mode omode = mode;
908 iv->mode = VOIDmode;
909 iv->base = NULL_RTX;
910 iv->step = NULL_RTX;
912 gcc_assert (GET_MODE (rhs) == mode || GET_MODE (rhs) == VOIDmode);
914 if (CONSTANT_P (rhs)
915 || REG_P (rhs)
916 || code == SUBREG)
918 if (!iv_analyze_op (insn, rhs, iv))
919 return false;
921 if (iv->mode == VOIDmode)
923 iv->mode = mode;
924 iv->extend_mode = mode;
927 return true;
930 switch (code)
932 case REG:
933 op0 = rhs;
934 break;
936 case SIGN_EXTEND:
937 case ZERO_EXTEND:
938 case NEG:
939 op0 = XEXP (rhs, 0);
940 omode = GET_MODE (op0);
941 break;
943 case PLUS:
944 case MINUS:
945 op0 = XEXP (rhs, 0);
946 op1 = XEXP (rhs, 1);
947 break;
949 case MULT:
950 op0 = XEXP (rhs, 0);
951 mby = XEXP (rhs, 1);
952 if (!CONSTANT_P (mby))
954 tmp = op0;
955 op0 = mby;
956 mby = tmp;
958 if (!CONSTANT_P (mby))
959 return false;
960 break;
962 case ASHIFT:
963 op0 = XEXP (rhs, 0);
964 mby = XEXP (rhs, 1);
965 if (!CONSTANT_P (mby))
966 return false;
967 break;
969 default:
970 return false;
973 if (op0
974 && !iv_analyze_expr (insn, op0, omode, &iv0))
975 return false;
977 if (op1
978 && !iv_analyze_expr (insn, op1, omode, &iv1))
979 return false;
981 switch (code)
983 case SIGN_EXTEND:
984 case ZERO_EXTEND:
985 if (!iv_extend (&iv0, code, mode))
986 return false;
987 break;
989 case NEG:
990 if (!iv_neg (&iv0))
991 return false;
992 break;
994 case PLUS:
995 case MINUS:
996 if (!iv_add (&iv0, &iv1, code))
997 return false;
998 break;
1000 case MULT:
1001 if (!iv_mult (&iv0, mby))
1002 return false;
1003 break;
1005 case ASHIFT:
1006 if (!iv_shift (&iv0, mby))
1007 return false;
1008 break;
1010 default:
1011 break;
1014 *iv = iv0;
1015 return iv->base != NULL_RTX;
1018 /* Analyzes iv DEF and stores the result to *IV. */
1020 static bool
1021 iv_analyze_def (struct df_ref *def, struct rtx_iv *iv)
1023 rtx insn = DF_REF_INSN (def);
1024 rtx reg = DF_REF_REG (def);
1025 rtx set, rhs;
1027 if (dump_file)
1029 fprintf (dump_file, "Analysing def of ");
1030 print_rtl (dump_file, reg);
1031 fprintf (dump_file, " in insn ");
1032 print_rtl_single (dump_file, insn);
1035 if (DF_REF_IV (def))
1037 if (dump_file)
1038 fprintf (dump_file, " already analysed.\n");
1039 *iv = *DF_REF_IV (def);
1040 return iv->base != NULL_RTX;
1043 iv->mode = VOIDmode;
1044 iv->base = NULL_RTX;
1045 iv->step = NULL_RTX;
1047 set = single_set (insn);
1048 if (!set || SET_DEST (set) != reg)
1049 return false;
1051 rhs = find_reg_equal_equiv_note (insn);
1052 if (rhs)
1053 rhs = XEXP (rhs, 0);
1054 else
1055 rhs = SET_SRC (set);
1057 iv_analyze_expr (insn, rhs, GET_MODE (reg), iv);
1058 record_iv (def, iv);
1060 if (dump_file)
1062 print_rtl (dump_file, reg);
1063 fprintf (dump_file, " in insn ");
1064 print_rtl_single (dump_file, insn);
1065 fprintf (dump_file, " is ");
1066 dump_iv_info (dump_file, iv);
1067 fprintf (dump_file, "\n");
1070 return iv->base != NULL_RTX;
1073 /* Analyzes operand OP of INSN and stores the result to *IV. */
1075 static bool
1076 iv_analyze_op (rtx insn, rtx op, struct rtx_iv *iv)
1078 struct df_ref *def = NULL;
1079 enum iv_grd_result res;
1081 if (dump_file)
1083 fprintf (dump_file, "Analysing operand ");
1084 print_rtl (dump_file, op);
1085 fprintf (dump_file, " of insn ");
1086 print_rtl_single (dump_file, insn);
1089 if (CONSTANT_P (op))
1090 res = GRD_INVARIANT;
1091 else if (GET_CODE (op) == SUBREG)
1093 if (!subreg_lowpart_p (op))
1094 return false;
1096 if (!iv_analyze_op (insn, SUBREG_REG (op), iv))
1097 return false;
1099 return iv_subreg (iv, GET_MODE (op));
1101 else
1103 res = iv_get_reaching_def (insn, op, &def);
1104 if (res == GRD_INVALID)
1106 if (dump_file)
1107 fprintf (dump_file, " not simple.\n");
1108 return false;
1112 if (res == GRD_INVARIANT)
1114 iv_constant (iv, op, VOIDmode);
1116 if (dump_file)
1118 fprintf (dump_file, " ");
1119 dump_iv_info (dump_file, iv);
1120 fprintf (dump_file, "\n");
1122 return true;
1125 if (res == GRD_MAYBE_BIV)
1126 return iv_analyze_biv (op, iv);
1128 return iv_analyze_def (def, iv);
1131 /* Analyzes value VAL at INSN and stores the result to *IV. */
1133 bool
1134 iv_analyze (rtx insn, rtx val, struct rtx_iv *iv)
1136 rtx reg;
1138 /* We must find the insn in that val is used, so that we get to UD chains.
1139 Since the function is sometimes called on result of get_condition,
1140 this does not necessarily have to be directly INSN; scan also the
1141 following insns. */
1142 if (simple_reg_p (val))
1144 if (GET_CODE (val) == SUBREG)
1145 reg = SUBREG_REG (val);
1146 else
1147 reg = val;
1149 while (!df_find_use (df, insn, reg))
1150 insn = NEXT_INSN (insn);
1153 return iv_analyze_op (insn, val, iv);
1156 /* Analyzes definition of DEF in INSN and stores the result to IV. */
1158 bool
1159 iv_analyze_result (rtx insn, rtx def, struct rtx_iv *iv)
1161 struct df_ref *adef;
1163 adef = df_find_def (df, insn, def);
1164 if (!adef)
1165 return false;
1167 return iv_analyze_def (adef, iv);
1170 /* Checks whether definition of register REG in INSN is a basic induction
1171 variable. IV analysis must have been initialized (via a call to
1172 iv_analysis_loop_init) for this function to produce a result. */
1174 bool
1175 biv_p (rtx insn, rtx reg)
1177 struct rtx_iv iv;
1178 struct df_ref *def, *last_def;
1180 if (!simple_reg_p (reg))
1181 return false;
1183 def = df_find_def (df, insn, reg);
1184 gcc_assert (def != NULL);
1185 if (!latch_dominating_def (reg, &last_def))
1186 return false;
1187 if (last_def != def)
1188 return false;
1190 if (!iv_analyze_biv (reg, &iv))
1191 return false;
1193 return iv.step != const0_rtx;
1196 /* Calculates value of IV at ITERATION-th iteration. */
1199 get_iv_value (struct rtx_iv *iv, rtx iteration)
1201 rtx val;
1203 /* We would need to generate some if_then_else patterns, and so far
1204 it is not needed anywhere. */
1205 gcc_assert (!iv->first_special);
1207 if (iv->step != const0_rtx && iteration != const0_rtx)
1208 val = simplify_gen_binary (PLUS, iv->extend_mode, iv->base,
1209 simplify_gen_binary (MULT, iv->extend_mode,
1210 iv->step, iteration));
1211 else
1212 val = iv->base;
1214 if (iv->extend_mode == iv->mode)
1215 return val;
1217 val = lowpart_subreg (iv->mode, val, iv->extend_mode);
1219 if (iv->extend == UNKNOWN)
1220 return val;
1222 val = simplify_gen_unary (iv->extend, iv->extend_mode, val, iv->mode);
1223 val = simplify_gen_binary (PLUS, iv->extend_mode, iv->delta,
1224 simplify_gen_binary (MULT, iv->extend_mode,
1225 iv->mult, val));
1227 return val;
1230 /* Free the data for an induction variable analysis. */
1232 void
1233 iv_analysis_done (void)
1235 if (df)
1237 clear_iv_info ();
1238 df_finish (df);
1239 df = NULL;
1240 htab_delete (bivs);
1241 bivs = NULL;
1245 /* Computes inverse to X modulo (1 << MOD). */
1247 static unsigned HOST_WIDEST_INT
1248 inverse (unsigned HOST_WIDEST_INT x, int mod)
1250 unsigned HOST_WIDEST_INT mask =
1251 ((unsigned HOST_WIDEST_INT) 1 << (mod - 1) << 1) - 1;
1252 unsigned HOST_WIDEST_INT rslt = 1;
1253 int i;
1255 for (i = 0; i < mod - 1; i++)
1257 rslt = (rslt * x) & mask;
1258 x = (x * x) & mask;
1261 return rslt;
1264 /* Tries to estimate the maximum number of iterations. */
1266 static unsigned HOST_WIDEST_INT
1267 determine_max_iter (struct niter_desc *desc)
1269 rtx niter = desc->niter_expr;
1270 rtx mmin, mmax, left, right;
1271 unsigned HOST_WIDEST_INT nmax, inc;
1273 if (GET_CODE (niter) == AND
1274 && GET_CODE (XEXP (niter, 0)) == CONST_INT)
1276 nmax = INTVAL (XEXP (niter, 0));
1277 if (!(nmax & (nmax + 1)))
1279 desc->niter_max = nmax;
1280 return nmax;
1284 get_mode_bounds (desc->mode, desc->signed_p, desc->mode, &mmin, &mmax);
1285 nmax = INTVAL (mmax) - INTVAL (mmin);
1287 if (GET_CODE (niter) == UDIV)
1289 if (GET_CODE (XEXP (niter, 1)) != CONST_INT)
1291 desc->niter_max = nmax;
1292 return nmax;
1294 inc = INTVAL (XEXP (niter, 1));
1295 niter = XEXP (niter, 0);
1297 else
1298 inc = 1;
1300 if (GET_CODE (niter) == PLUS)
1302 left = XEXP (niter, 0);
1303 right = XEXP (niter, 0);
1305 if (GET_CODE (right) == CONST_INT)
1306 right = GEN_INT (-INTVAL (right));
1308 else if (GET_CODE (niter) == MINUS)
1310 left = XEXP (niter, 0);
1311 right = XEXP (niter, 0);
1313 else
1315 left = niter;
1316 right = mmin;
1319 if (GET_CODE (left) == CONST_INT)
1320 mmax = left;
1321 if (GET_CODE (right) == CONST_INT)
1322 mmin = right;
1323 nmax = INTVAL (mmax) - INTVAL (mmin);
1325 desc->niter_max = nmax / inc;
1326 return nmax / inc;
1329 /* Checks whether register *REG is in set ALT. Callback for for_each_rtx. */
1331 static int
1332 altered_reg_used (rtx *reg, void *alt)
1334 if (!REG_P (*reg))
1335 return 0;
1337 return REGNO_REG_SET_P (alt, REGNO (*reg));
1340 /* Marks registers altered by EXPR in set ALT. */
1342 static void
1343 mark_altered (rtx expr, rtx by ATTRIBUTE_UNUSED, void *alt)
1345 if (GET_CODE (expr) == SUBREG)
1346 expr = SUBREG_REG (expr);
1347 if (!REG_P (expr))
1348 return;
1350 SET_REGNO_REG_SET (alt, REGNO (expr));
1353 /* Checks whether RHS is simple enough to process. */
1355 static bool
1356 simple_rhs_p (rtx rhs)
1358 rtx op0, op1;
1360 if (CONSTANT_P (rhs)
1361 || REG_P (rhs))
1362 return true;
1364 switch (GET_CODE (rhs))
1366 case PLUS:
1367 case MINUS:
1368 op0 = XEXP (rhs, 0);
1369 op1 = XEXP (rhs, 1);
1370 /* Allow reg + const sets only. */
1371 if (REG_P (op0) && CONSTANT_P (op1))
1372 return true;
1373 if (REG_P (op1) && CONSTANT_P (op0))
1374 return true;
1376 return false;
1378 default:
1379 return false;
1383 /* Simplifies *EXPR using assignment in INSN. ALTERED is the set of registers
1384 altered so far. */
1386 static void
1387 simplify_using_assignment (rtx insn, rtx *expr, regset altered)
1389 rtx set = single_set (insn);
1390 rtx lhs = NULL_RTX, rhs;
1391 bool ret = false;
1393 if (set)
1395 lhs = SET_DEST (set);
1396 if (!REG_P (lhs)
1397 || altered_reg_used (&lhs, altered))
1398 ret = true;
1400 else
1401 ret = true;
1403 note_stores (PATTERN (insn), mark_altered, altered);
1404 if (CALL_P (insn))
1406 int i;
1408 /* Kill all call clobbered registers. */
1409 for (i = 0; i < FIRST_PSEUDO_REGISTER; i++)
1410 if (TEST_HARD_REG_BIT (regs_invalidated_by_call, i))
1411 SET_REGNO_REG_SET (altered, i);
1414 if (ret)
1415 return;
1417 rhs = find_reg_equal_equiv_note (insn);
1418 if (rhs)
1419 rhs = XEXP (rhs, 0);
1420 else
1421 rhs = SET_SRC (set);
1423 if (!simple_rhs_p (rhs))
1424 return;
1426 if (for_each_rtx (&rhs, altered_reg_used, altered))
1427 return;
1429 *expr = simplify_replace_rtx (*expr, lhs, rhs);
1432 /* Checks whether A implies B. */
1434 static bool
1435 implies_p (rtx a, rtx b)
1437 rtx op0, op1, opb0, opb1, r;
1438 enum machine_mode mode;
1440 if (GET_CODE (a) == EQ)
1442 op0 = XEXP (a, 0);
1443 op1 = XEXP (a, 1);
1445 if (REG_P (op0))
1447 r = simplify_replace_rtx (b, op0, op1);
1448 if (r == const_true_rtx)
1449 return true;
1452 if (REG_P (op1))
1454 r = simplify_replace_rtx (b, op1, op0);
1455 if (r == const_true_rtx)
1456 return true;
1460 /* A < B implies A + 1 <= B. */
1461 if ((GET_CODE (a) == GT || GET_CODE (a) == LT)
1462 && (GET_CODE (b) == GE || GET_CODE (b) == LE))
1464 op0 = XEXP (a, 0);
1465 op1 = XEXP (a, 1);
1466 opb0 = XEXP (b, 0);
1467 opb1 = XEXP (b, 1);
1469 if (GET_CODE (a) == GT)
1471 r = op0;
1472 op0 = op1;
1473 op1 = r;
1476 if (GET_CODE (b) == GE)
1478 r = opb0;
1479 opb0 = opb1;
1480 opb1 = r;
1483 mode = GET_MODE (op0);
1484 if (mode != GET_MODE (opb0))
1485 mode = VOIDmode;
1486 else if (mode == VOIDmode)
1488 mode = GET_MODE (op1);
1489 if (mode != GET_MODE (opb1))
1490 mode = VOIDmode;
1493 if (mode != VOIDmode
1494 && rtx_equal_p (op1, opb1)
1495 && simplify_gen_binary (MINUS, mode, opb0, op0) == const1_rtx)
1496 return true;
1499 return false;
1502 /* Canonicalizes COND so that
1504 (1) Ensure that operands are ordered according to
1505 swap_commutative_operands_p.
1506 (2) (LE x const) will be replaced with (LT x <const+1>) and similarly
1507 for GE, GEU, and LEU. */
1510 canon_condition (rtx cond)
1512 rtx tem;
1513 rtx op0, op1;
1514 enum rtx_code code;
1515 enum machine_mode mode;
1517 code = GET_CODE (cond);
1518 op0 = XEXP (cond, 0);
1519 op1 = XEXP (cond, 1);
1521 if (swap_commutative_operands_p (op0, op1))
1523 code = swap_condition (code);
1524 tem = op0;
1525 op0 = op1;
1526 op1 = tem;
1529 mode = GET_MODE (op0);
1530 if (mode == VOIDmode)
1531 mode = GET_MODE (op1);
1532 gcc_assert (mode != VOIDmode);
1534 if (GET_CODE (op1) == CONST_INT
1535 && GET_MODE_CLASS (mode) != MODE_CC
1536 && GET_MODE_BITSIZE (mode) <= HOST_BITS_PER_WIDE_INT)
1538 HOST_WIDE_INT const_val = INTVAL (op1);
1539 unsigned HOST_WIDE_INT uconst_val = const_val;
1540 unsigned HOST_WIDE_INT max_val
1541 = (unsigned HOST_WIDE_INT) GET_MODE_MASK (mode);
1543 switch (code)
1545 case LE:
1546 if ((unsigned HOST_WIDE_INT) const_val != max_val >> 1)
1547 code = LT, op1 = gen_int_mode (const_val + 1, GET_MODE (op0));
1548 break;
1550 /* When cross-compiling, const_val might be sign-extended from
1551 BITS_PER_WORD to HOST_BITS_PER_WIDE_INT */
1552 case GE:
1553 if ((HOST_WIDE_INT) (const_val & max_val)
1554 != (((HOST_WIDE_INT) 1
1555 << (GET_MODE_BITSIZE (GET_MODE (op0)) - 1))))
1556 code = GT, op1 = gen_int_mode (const_val - 1, mode);
1557 break;
1559 case LEU:
1560 if (uconst_val < max_val)
1561 code = LTU, op1 = gen_int_mode (uconst_val + 1, mode);
1562 break;
1564 case GEU:
1565 if (uconst_val != 0)
1566 code = GTU, op1 = gen_int_mode (uconst_val - 1, mode);
1567 break;
1569 default:
1570 break;
1574 if (op0 != XEXP (cond, 0)
1575 || op1 != XEXP (cond, 1)
1576 || code != GET_CODE (cond)
1577 || GET_MODE (cond) != SImode)
1578 cond = gen_rtx_fmt_ee (code, SImode, op0, op1);
1580 return cond;
1583 /* Tries to use the fact that COND holds to simplify EXPR. ALTERED is the
1584 set of altered regs. */
1586 void
1587 simplify_using_condition (rtx cond, rtx *expr, regset altered)
1589 rtx rev, reve, exp = *expr;
1591 if (!COMPARISON_P (exp))
1592 return;
1594 /* If some register gets altered later, we do not really speak about its
1595 value at the time of comparison. */
1596 if (altered
1597 && for_each_rtx (&cond, altered_reg_used, altered))
1598 return;
1600 rev = reversed_condition (cond);
1601 reve = reversed_condition (exp);
1603 cond = canon_condition (cond);
1604 exp = canon_condition (exp);
1605 if (rev)
1606 rev = canon_condition (rev);
1607 if (reve)
1608 reve = canon_condition (reve);
1610 if (rtx_equal_p (exp, cond))
1612 *expr = const_true_rtx;
1613 return;
1617 if (rev && rtx_equal_p (exp, rev))
1619 *expr = const0_rtx;
1620 return;
1623 if (implies_p (cond, exp))
1625 *expr = const_true_rtx;
1626 return;
1629 if (reve && implies_p (cond, reve))
1631 *expr = const0_rtx;
1632 return;
1635 /* A proof by contradiction. If *EXPR implies (not cond), *EXPR must
1636 be false. */
1637 if (rev && implies_p (exp, rev))
1639 *expr = const0_rtx;
1640 return;
1643 /* Similarly, If (not *EXPR) implies (not cond), *EXPR must be true. */
1644 if (rev && reve && implies_p (reve, rev))
1646 *expr = const_true_rtx;
1647 return;
1650 /* We would like to have some other tests here. TODO. */
1652 return;
1655 /* Use relationship between A and *B to eventually eliminate *B.
1656 OP is the operation we consider. */
1658 static void
1659 eliminate_implied_condition (enum rtx_code op, rtx a, rtx *b)
1661 switch (op)
1663 case AND:
1664 /* If A implies *B, we may replace *B by true. */
1665 if (implies_p (a, *b))
1666 *b = const_true_rtx;
1667 break;
1669 case IOR:
1670 /* If *B implies A, we may replace *B by false. */
1671 if (implies_p (*b, a))
1672 *b = const0_rtx;
1673 break;
1675 default:
1676 gcc_unreachable ();
1680 /* Eliminates the conditions in TAIL that are implied by HEAD. OP is the
1681 operation we consider. */
1683 static void
1684 eliminate_implied_conditions (enum rtx_code op, rtx *head, rtx tail)
1686 rtx elt;
1688 for (elt = tail; elt; elt = XEXP (elt, 1))
1689 eliminate_implied_condition (op, *head, &XEXP (elt, 0));
1690 for (elt = tail; elt; elt = XEXP (elt, 1))
1691 eliminate_implied_condition (op, XEXP (elt, 0), head);
1694 /* Simplifies *EXPR using initial values at the start of the LOOP. If *EXPR
1695 is a list, its elements are assumed to be combined using OP. */
1697 static void
1698 simplify_using_initial_values (struct loop *loop, enum rtx_code op, rtx *expr)
1700 rtx head, tail, insn;
1701 rtx neutral, aggr;
1702 regset altered;
1703 edge e;
1705 if (!*expr)
1706 return;
1708 if (CONSTANT_P (*expr))
1709 return;
1711 if (GET_CODE (*expr) == EXPR_LIST)
1713 head = XEXP (*expr, 0);
1714 tail = XEXP (*expr, 1);
1716 eliminate_implied_conditions (op, &head, tail);
1718 switch (op)
1720 case AND:
1721 neutral = const_true_rtx;
1722 aggr = const0_rtx;
1723 break;
1725 case IOR:
1726 neutral = const0_rtx;
1727 aggr = const_true_rtx;
1728 break;
1730 default:
1731 gcc_unreachable ();
1734 simplify_using_initial_values (loop, UNKNOWN, &head);
1735 if (head == aggr)
1737 XEXP (*expr, 0) = aggr;
1738 XEXP (*expr, 1) = NULL_RTX;
1739 return;
1741 else if (head == neutral)
1743 *expr = tail;
1744 simplify_using_initial_values (loop, op, expr);
1745 return;
1747 simplify_using_initial_values (loop, op, &tail);
1749 if (tail && XEXP (tail, 0) == aggr)
1751 *expr = tail;
1752 return;
1755 XEXP (*expr, 0) = head;
1756 XEXP (*expr, 1) = tail;
1757 return;
1760 gcc_assert (op == UNKNOWN);
1762 e = loop_preheader_edge (loop);
1763 if (e->src == ENTRY_BLOCK_PTR)
1764 return;
1766 altered = ALLOC_REG_SET (&reg_obstack);
1768 while (1)
1770 insn = BB_END (e->src);
1771 if (any_condjump_p (insn))
1773 rtx cond = get_condition (BB_END (e->src), NULL, false, true);
1775 if (cond && (e->flags & EDGE_FALLTHRU))
1776 cond = reversed_condition (cond);
1777 if (cond)
1779 simplify_using_condition (cond, expr, altered);
1780 if (CONSTANT_P (*expr))
1782 FREE_REG_SET (altered);
1783 return;
1788 FOR_BB_INSNS_REVERSE (e->src, insn)
1790 if (!INSN_P (insn))
1791 continue;
1793 simplify_using_assignment (insn, expr, altered);
1794 if (CONSTANT_P (*expr))
1796 FREE_REG_SET (altered);
1797 return;
1801 if (!single_pred_p (e->src)
1802 || single_pred (e->src) == ENTRY_BLOCK_PTR)
1803 break;
1804 e = single_pred_edge (e->src);
1807 FREE_REG_SET (altered);
1810 /* Transforms invariant IV into MODE. Adds assumptions based on the fact
1811 that IV occurs as left operands of comparison COND and its signedness
1812 is SIGNED_P to DESC. */
1814 static void
1815 shorten_into_mode (struct rtx_iv *iv, enum machine_mode mode,
1816 enum rtx_code cond, bool signed_p, struct niter_desc *desc)
1818 rtx mmin, mmax, cond_over, cond_under;
1820 get_mode_bounds (mode, signed_p, iv->extend_mode, &mmin, &mmax);
1821 cond_under = simplify_gen_relational (LT, SImode, iv->extend_mode,
1822 iv->base, mmin);
1823 cond_over = simplify_gen_relational (GT, SImode, iv->extend_mode,
1824 iv->base, mmax);
1826 switch (cond)
1828 case LE:
1829 case LT:
1830 case LEU:
1831 case LTU:
1832 if (cond_under != const0_rtx)
1833 desc->infinite =
1834 alloc_EXPR_LIST (0, cond_under, desc->infinite);
1835 if (cond_over != const0_rtx)
1836 desc->noloop_assumptions =
1837 alloc_EXPR_LIST (0, cond_over, desc->noloop_assumptions);
1838 break;
1840 case GE:
1841 case GT:
1842 case GEU:
1843 case GTU:
1844 if (cond_over != const0_rtx)
1845 desc->infinite =
1846 alloc_EXPR_LIST (0, cond_over, desc->infinite);
1847 if (cond_under != const0_rtx)
1848 desc->noloop_assumptions =
1849 alloc_EXPR_LIST (0, cond_under, desc->noloop_assumptions);
1850 break;
1852 case NE:
1853 if (cond_over != const0_rtx)
1854 desc->infinite =
1855 alloc_EXPR_LIST (0, cond_over, desc->infinite);
1856 if (cond_under != const0_rtx)
1857 desc->infinite =
1858 alloc_EXPR_LIST (0, cond_under, desc->infinite);
1859 break;
1861 default:
1862 gcc_unreachable ();
1865 iv->mode = mode;
1866 iv->extend = signed_p ? SIGN_EXTEND : ZERO_EXTEND;
1869 /* Transforms IV0 and IV1 compared by COND so that they are both compared as
1870 subregs of the same mode if possible (sometimes it is necessary to add
1871 some assumptions to DESC). */
1873 static bool
1874 canonicalize_iv_subregs (struct rtx_iv *iv0, struct rtx_iv *iv1,
1875 enum rtx_code cond, struct niter_desc *desc)
1877 enum machine_mode comp_mode;
1878 bool signed_p;
1880 /* If the ivs behave specially in the first iteration, or are
1881 added/multiplied after extending, we ignore them. */
1882 if (iv0->first_special || iv0->mult != const1_rtx || iv0->delta != const0_rtx)
1883 return false;
1884 if (iv1->first_special || iv1->mult != const1_rtx || iv1->delta != const0_rtx)
1885 return false;
1887 /* If there is some extend, it must match signedness of the comparison. */
1888 switch (cond)
1890 case LE:
1891 case LT:
1892 if (iv0->extend == ZERO_EXTEND
1893 || iv1->extend == ZERO_EXTEND)
1894 return false;
1895 signed_p = true;
1896 break;
1898 case LEU:
1899 case LTU:
1900 if (iv0->extend == SIGN_EXTEND
1901 || iv1->extend == SIGN_EXTEND)
1902 return false;
1903 signed_p = false;
1904 break;
1906 case NE:
1907 if (iv0->extend != UNKNOWN
1908 && iv1->extend != UNKNOWN
1909 && iv0->extend != iv1->extend)
1910 return false;
1912 signed_p = false;
1913 if (iv0->extend != UNKNOWN)
1914 signed_p = iv0->extend == SIGN_EXTEND;
1915 if (iv1->extend != UNKNOWN)
1916 signed_p = iv1->extend == SIGN_EXTEND;
1917 break;
1919 default:
1920 gcc_unreachable ();
1923 /* Values of both variables should be computed in the same mode. These
1924 might indeed be different, if we have comparison like
1926 (compare (subreg:SI (iv0)) (subreg:SI (iv1)))
1928 and iv0 and iv1 are both ivs iterating in SI mode, but calculated
1929 in different modes. This does not seem impossible to handle, but
1930 it hardly ever occurs in practice.
1932 The only exception is the case when one of operands is invariant.
1933 For example pentium 3 generates comparisons like
1934 (lt (subreg:HI (reg:SI)) 100). Here we assign HImode to 100, but we
1935 definitely do not want this prevent the optimization. */
1936 comp_mode = iv0->extend_mode;
1937 if (GET_MODE_BITSIZE (comp_mode) < GET_MODE_BITSIZE (iv1->extend_mode))
1938 comp_mode = iv1->extend_mode;
1940 if (iv0->extend_mode != comp_mode)
1942 if (iv0->mode != iv0->extend_mode
1943 || iv0->step != const0_rtx)
1944 return false;
1946 iv0->base = simplify_gen_unary (signed_p ? SIGN_EXTEND : ZERO_EXTEND,
1947 comp_mode, iv0->base, iv0->mode);
1948 iv0->extend_mode = comp_mode;
1951 if (iv1->extend_mode != comp_mode)
1953 if (iv1->mode != iv1->extend_mode
1954 || iv1->step != const0_rtx)
1955 return false;
1957 iv1->base = simplify_gen_unary (signed_p ? SIGN_EXTEND : ZERO_EXTEND,
1958 comp_mode, iv1->base, iv1->mode);
1959 iv1->extend_mode = comp_mode;
1962 /* Check that both ivs belong to a range of a single mode. If one of the
1963 operands is an invariant, we may need to shorten it into the common
1964 mode. */
1965 if (iv0->mode == iv0->extend_mode
1966 && iv0->step == const0_rtx
1967 && iv0->mode != iv1->mode)
1968 shorten_into_mode (iv0, iv1->mode, cond, signed_p, desc);
1970 if (iv1->mode == iv1->extend_mode
1971 && iv1->step == const0_rtx
1972 && iv0->mode != iv1->mode)
1973 shorten_into_mode (iv1, iv0->mode, swap_condition (cond), signed_p, desc);
1975 if (iv0->mode != iv1->mode)
1976 return false;
1978 desc->mode = iv0->mode;
1979 desc->signed_p = signed_p;
1981 return true;
1984 /* Computes number of iterations of the CONDITION in INSN in LOOP and stores
1985 the result into DESC. Very similar to determine_number_of_iterations
1986 (basically its rtl version), complicated by things like subregs. */
1988 static void
1989 iv_number_of_iterations (struct loop *loop, rtx insn, rtx condition,
1990 struct niter_desc *desc)
1992 rtx op0, op1, delta, step, bound, may_xform, tmp, tmp0, tmp1;
1993 struct rtx_iv iv0, iv1, tmp_iv;
1994 rtx assumption, may_not_xform;
1995 enum rtx_code cond;
1996 enum machine_mode mode, comp_mode;
1997 rtx mmin, mmax, mode_mmin, mode_mmax;
1998 unsigned HOST_WIDEST_INT s, size, d, inv;
1999 HOST_WIDEST_INT up, down, inc, step_val;
2000 int was_sharp = false;
2001 rtx old_niter;
2002 bool step_is_pow2;
2004 /* The meaning of these assumptions is this:
2005 if !assumptions
2006 then the rest of information does not have to be valid
2007 if noloop_assumptions then the loop does not roll
2008 if infinite then this exit is never used */
2010 desc->assumptions = NULL_RTX;
2011 desc->noloop_assumptions = NULL_RTX;
2012 desc->infinite = NULL_RTX;
2013 desc->simple_p = true;
2015 desc->const_iter = false;
2016 desc->niter_expr = NULL_RTX;
2017 desc->niter_max = 0;
2019 cond = GET_CODE (condition);
2020 gcc_assert (COMPARISON_P (condition));
2022 mode = GET_MODE (XEXP (condition, 0));
2023 if (mode == VOIDmode)
2024 mode = GET_MODE (XEXP (condition, 1));
2025 /* The constant comparisons should be folded. */
2026 gcc_assert (mode != VOIDmode);
2028 /* We only handle integers or pointers. */
2029 if (GET_MODE_CLASS (mode) != MODE_INT
2030 && GET_MODE_CLASS (mode) != MODE_PARTIAL_INT)
2031 goto fail;
2033 op0 = XEXP (condition, 0);
2034 if (!iv_analyze (insn, op0, &iv0))
2035 goto fail;
2036 if (iv0.extend_mode == VOIDmode)
2037 iv0.mode = iv0.extend_mode = mode;
2039 op1 = XEXP (condition, 1);
2040 if (!iv_analyze (insn, op1, &iv1))
2041 goto fail;
2042 if (iv1.extend_mode == VOIDmode)
2043 iv1.mode = iv1.extend_mode = mode;
2045 if (GET_MODE_BITSIZE (iv0.extend_mode) > HOST_BITS_PER_WIDE_INT
2046 || GET_MODE_BITSIZE (iv1.extend_mode) > HOST_BITS_PER_WIDE_INT)
2047 goto fail;
2049 /* Check condition and normalize it. */
2051 switch (cond)
2053 case GE:
2054 case GT:
2055 case GEU:
2056 case GTU:
2057 tmp_iv = iv0; iv0 = iv1; iv1 = tmp_iv;
2058 cond = swap_condition (cond);
2059 break;
2060 case NE:
2061 case LE:
2062 case LEU:
2063 case LT:
2064 case LTU:
2065 break;
2066 default:
2067 goto fail;
2070 /* Handle extends. This is relatively nontrivial, so we only try in some
2071 easy cases, when we can canonicalize the ivs (possibly by adding some
2072 assumptions) to shape subreg (base + i * step). This function also fills
2073 in desc->mode and desc->signed_p. */
2075 if (!canonicalize_iv_subregs (&iv0, &iv1, cond, desc))
2076 goto fail;
2078 comp_mode = iv0.extend_mode;
2079 mode = iv0.mode;
2080 size = GET_MODE_BITSIZE (mode);
2081 get_mode_bounds (mode, (cond == LE || cond == LT), comp_mode, &mmin, &mmax);
2082 mode_mmin = lowpart_subreg (mode, mmin, comp_mode);
2083 mode_mmax = lowpart_subreg (mode, mmax, comp_mode);
2085 if (GET_CODE (iv0.step) != CONST_INT || GET_CODE (iv1.step) != CONST_INT)
2086 goto fail;
2088 /* We can take care of the case of two induction variables chasing each other
2089 if the test is NE. I have never seen a loop using it, but still it is
2090 cool. */
2091 if (iv0.step != const0_rtx && iv1.step != const0_rtx)
2093 if (cond != NE)
2094 goto fail;
2096 iv0.step = simplify_gen_binary (MINUS, comp_mode, iv0.step, iv1.step);
2097 iv1.step = const0_rtx;
2100 /* This is either infinite loop or the one that ends immediately, depending
2101 on initial values. Unswitching should remove this kind of conditions. */
2102 if (iv0.step == const0_rtx && iv1.step == const0_rtx)
2103 goto fail;
2105 if (cond != NE)
2107 if (iv0.step == const0_rtx)
2108 step_val = -INTVAL (iv1.step);
2109 else
2110 step_val = INTVAL (iv0.step);
2112 /* Ignore loops of while (i-- < 10) type. */
2113 if (step_val < 0)
2114 goto fail;
2116 step_is_pow2 = !(step_val & (step_val - 1));
2118 else
2120 /* We do not care about whether the step is power of two in this
2121 case. */
2122 step_is_pow2 = false;
2123 step_val = 0;
2126 /* Some more condition normalization. We must record some assumptions
2127 due to overflows. */
2128 switch (cond)
2130 case LT:
2131 case LTU:
2132 /* We want to take care only of non-sharp relationals; this is easy,
2133 as in cases the overflow would make the transformation unsafe
2134 the loop does not roll. Seemingly it would make more sense to want
2135 to take care of sharp relationals instead, as NE is more similar to
2136 them, but the problem is that here the transformation would be more
2137 difficult due to possibly infinite loops. */
2138 if (iv0.step == const0_rtx)
2140 tmp = lowpart_subreg (mode, iv0.base, comp_mode);
2141 assumption = simplify_gen_relational (EQ, SImode, mode, tmp,
2142 mode_mmax);
2143 if (assumption == const_true_rtx)
2144 goto zero_iter_simplify;
2145 iv0.base = simplify_gen_binary (PLUS, comp_mode,
2146 iv0.base, const1_rtx);
2148 else
2150 tmp = lowpart_subreg (mode, iv1.base, comp_mode);
2151 assumption = simplify_gen_relational (EQ, SImode, mode, tmp,
2152 mode_mmin);
2153 if (assumption == const_true_rtx)
2154 goto zero_iter_simplify;
2155 iv1.base = simplify_gen_binary (PLUS, comp_mode,
2156 iv1.base, constm1_rtx);
2159 if (assumption != const0_rtx)
2160 desc->noloop_assumptions =
2161 alloc_EXPR_LIST (0, assumption, desc->noloop_assumptions);
2162 cond = (cond == LT) ? LE : LEU;
2164 /* It will be useful to be able to tell the difference once more in
2165 LE -> NE reduction. */
2166 was_sharp = true;
2167 break;
2168 default: ;
2171 /* Take care of trivially infinite loops. */
2172 if (cond != NE)
2174 if (iv0.step == const0_rtx)
2176 tmp = lowpart_subreg (mode, iv0.base, comp_mode);
2177 if (rtx_equal_p (tmp, mode_mmin))
2179 desc->infinite =
2180 alloc_EXPR_LIST (0, const_true_rtx, NULL_RTX);
2181 /* Fill in the remaining fields somehow. */
2182 goto zero_iter_simplify;
2185 else
2187 tmp = lowpart_subreg (mode, iv1.base, comp_mode);
2188 if (rtx_equal_p (tmp, mode_mmax))
2190 desc->infinite =
2191 alloc_EXPR_LIST (0, const_true_rtx, NULL_RTX);
2192 /* Fill in the remaining fields somehow. */
2193 goto zero_iter_simplify;
2198 /* If we can we want to take care of NE conditions instead of size
2199 comparisons, as they are much more friendly (most importantly
2200 this takes care of special handling of loops with step 1). We can
2201 do it if we first check that upper bound is greater or equal to
2202 lower bound, their difference is constant c modulo step and that
2203 there is not an overflow. */
2204 if (cond != NE)
2206 if (iv0.step == const0_rtx)
2207 step = simplify_gen_unary (NEG, comp_mode, iv1.step, comp_mode);
2208 else
2209 step = iv0.step;
2210 delta = simplify_gen_binary (MINUS, comp_mode, iv1.base, iv0.base);
2211 delta = lowpart_subreg (mode, delta, comp_mode);
2212 delta = simplify_gen_binary (UMOD, mode, delta, step);
2213 may_xform = const0_rtx;
2214 may_not_xform = const_true_rtx;
2216 if (GET_CODE (delta) == CONST_INT)
2218 if (was_sharp && INTVAL (delta) == INTVAL (step) - 1)
2220 /* A special case. We have transformed condition of type
2221 for (i = 0; i < 4; i += 4)
2222 into
2223 for (i = 0; i <= 3; i += 4)
2224 obviously if the test for overflow during that transformation
2225 passed, we cannot overflow here. Most importantly any
2226 loop with sharp end condition and step 1 falls into this
2227 category, so handling this case specially is definitely
2228 worth the troubles. */
2229 may_xform = const_true_rtx;
2231 else if (iv0.step == const0_rtx)
2233 bound = simplify_gen_binary (PLUS, comp_mode, mmin, step);
2234 bound = simplify_gen_binary (MINUS, comp_mode, bound, delta);
2235 bound = lowpart_subreg (mode, bound, comp_mode);
2236 tmp = lowpart_subreg (mode, iv0.base, comp_mode);
2237 may_xform = simplify_gen_relational (cond, SImode, mode,
2238 bound, tmp);
2239 may_not_xform = simplify_gen_relational (reverse_condition (cond),
2240 SImode, mode,
2241 bound, tmp);
2243 else
2245 bound = simplify_gen_binary (MINUS, comp_mode, mmax, step);
2246 bound = simplify_gen_binary (PLUS, comp_mode, bound, delta);
2247 bound = lowpart_subreg (mode, bound, comp_mode);
2248 tmp = lowpart_subreg (mode, iv1.base, comp_mode);
2249 may_xform = simplify_gen_relational (cond, SImode, mode,
2250 tmp, bound);
2251 may_not_xform = simplify_gen_relational (reverse_condition (cond),
2252 SImode, mode,
2253 tmp, bound);
2257 if (may_xform != const0_rtx)
2259 /* We perform the transformation always provided that it is not
2260 completely senseless. This is OK, as we would need this assumption
2261 to determine the number of iterations anyway. */
2262 if (may_xform != const_true_rtx)
2264 /* If the step is a power of two and the final value we have
2265 computed overflows, the cycle is infinite. Otherwise it
2266 is nontrivial to compute the number of iterations. */
2267 if (step_is_pow2)
2268 desc->infinite = alloc_EXPR_LIST (0, may_not_xform,
2269 desc->infinite);
2270 else
2271 desc->assumptions = alloc_EXPR_LIST (0, may_xform,
2272 desc->assumptions);
2275 /* We are going to lose some information about upper bound on
2276 number of iterations in this step, so record the information
2277 here. */
2278 inc = INTVAL (iv0.step) - INTVAL (iv1.step);
2279 if (GET_CODE (iv1.base) == CONST_INT)
2280 up = INTVAL (iv1.base);
2281 else
2282 up = INTVAL (mode_mmax) - inc;
2283 down = INTVAL (GET_CODE (iv0.base) == CONST_INT
2284 ? iv0.base
2285 : mode_mmin);
2286 desc->niter_max = (up - down) / inc + 1;
2288 if (iv0.step == const0_rtx)
2290 iv0.base = simplify_gen_binary (PLUS, comp_mode, iv0.base, delta);
2291 iv0.base = simplify_gen_binary (MINUS, comp_mode, iv0.base, step);
2293 else
2295 iv1.base = simplify_gen_binary (MINUS, comp_mode, iv1.base, delta);
2296 iv1.base = simplify_gen_binary (PLUS, comp_mode, iv1.base, step);
2299 tmp0 = lowpart_subreg (mode, iv0.base, comp_mode);
2300 tmp1 = lowpart_subreg (mode, iv1.base, comp_mode);
2301 assumption = simplify_gen_relational (reverse_condition (cond),
2302 SImode, mode, tmp0, tmp1);
2303 if (assumption == const_true_rtx)
2304 goto zero_iter_simplify;
2305 else if (assumption != const0_rtx)
2306 desc->noloop_assumptions =
2307 alloc_EXPR_LIST (0, assumption, desc->noloop_assumptions);
2308 cond = NE;
2312 /* Count the number of iterations. */
2313 if (cond == NE)
2315 /* Everything we do here is just arithmetics modulo size of mode. This
2316 makes us able to do more involved computations of number of iterations
2317 than in other cases. First transform the condition into shape
2318 s * i <> c, with s positive. */
2319 iv1.base = simplify_gen_binary (MINUS, comp_mode, iv1.base, iv0.base);
2320 iv0.base = const0_rtx;
2321 iv0.step = simplify_gen_binary (MINUS, comp_mode, iv0.step, iv1.step);
2322 iv1.step = const0_rtx;
2323 if (INTVAL (iv0.step) < 0)
2325 iv0.step = simplify_gen_unary (NEG, comp_mode, iv0.step, mode);
2326 iv1.base = simplify_gen_unary (NEG, comp_mode, iv1.base, mode);
2328 iv0.step = lowpart_subreg (mode, iv0.step, comp_mode);
2330 /* Let nsd (s, size of mode) = d. If d does not divide c, the loop
2331 is infinite. Otherwise, the number of iterations is
2332 (inverse(s/d) * (c/d)) mod (size of mode/d). */
2333 s = INTVAL (iv0.step); d = 1;
2334 while (s % 2 != 1)
2336 s /= 2;
2337 d *= 2;
2338 size--;
2340 bound = GEN_INT (((unsigned HOST_WIDEST_INT) 1 << (size - 1 ) << 1) - 1);
2342 tmp1 = lowpart_subreg (mode, iv1.base, comp_mode);
2343 tmp = simplify_gen_binary (UMOD, mode, tmp1, GEN_INT (d));
2344 assumption = simplify_gen_relational (NE, SImode, mode, tmp, const0_rtx);
2345 desc->infinite = alloc_EXPR_LIST (0, assumption, desc->infinite);
2347 tmp = simplify_gen_binary (UDIV, mode, tmp1, GEN_INT (d));
2348 inv = inverse (s, size);
2349 tmp = simplify_gen_binary (MULT, mode, tmp, gen_int_mode (inv, mode));
2350 desc->niter_expr = simplify_gen_binary (AND, mode, tmp, bound);
2352 else
2354 if (iv1.step == const0_rtx)
2355 /* Condition in shape a + s * i <= b
2356 We must know that b + s does not overflow and a <= b + s and then we
2357 can compute number of iterations as (b + s - a) / s. (It might
2358 seem that we in fact could be more clever about testing the b + s
2359 overflow condition using some information about b - a mod s,
2360 but it was already taken into account during LE -> NE transform). */
2362 step = iv0.step;
2363 tmp0 = lowpart_subreg (mode, iv0.base, comp_mode);
2364 tmp1 = lowpart_subreg (mode, iv1.base, comp_mode);
2366 bound = simplify_gen_binary (MINUS, mode, mode_mmax,
2367 lowpart_subreg (mode, step,
2368 comp_mode));
2369 if (step_is_pow2)
2371 rtx t0, t1;
2373 /* If s is power of 2, we know that the loop is infinite if
2374 a % s <= b % s and b + s overflows. */
2375 assumption = simplify_gen_relational (reverse_condition (cond),
2376 SImode, mode,
2377 tmp1, bound);
2379 t0 = simplify_gen_binary (UMOD, mode, copy_rtx (tmp0), step);
2380 t1 = simplify_gen_binary (UMOD, mode, copy_rtx (tmp1), step);
2381 tmp = simplify_gen_relational (cond, SImode, mode, t0, t1);
2382 assumption = simplify_gen_binary (AND, SImode, assumption, tmp);
2383 desc->infinite =
2384 alloc_EXPR_LIST (0, assumption, desc->infinite);
2386 else
2388 assumption = simplify_gen_relational (cond, SImode, mode,
2389 tmp1, bound);
2390 desc->assumptions =
2391 alloc_EXPR_LIST (0, assumption, desc->assumptions);
2394 tmp = simplify_gen_binary (PLUS, comp_mode, iv1.base, iv0.step);
2395 tmp = lowpart_subreg (mode, tmp, comp_mode);
2396 assumption = simplify_gen_relational (reverse_condition (cond),
2397 SImode, mode, tmp0, tmp);
2399 delta = simplify_gen_binary (PLUS, mode, tmp1, step);
2400 delta = simplify_gen_binary (MINUS, mode, delta, tmp0);
2402 else
2404 /* Condition in shape a <= b - s * i
2405 We must know that a - s does not overflow and a - s <= b and then
2406 we can again compute number of iterations as (b - (a - s)) / s. */
2407 step = simplify_gen_unary (NEG, mode, iv1.step, mode);
2408 tmp0 = lowpart_subreg (mode, iv0.base, comp_mode);
2409 tmp1 = lowpart_subreg (mode, iv1.base, comp_mode);
2411 bound = simplify_gen_binary (PLUS, mode, mode_mmin,
2412 lowpart_subreg (mode, step, comp_mode));
2413 if (step_is_pow2)
2415 rtx t0, t1;
2417 /* If s is power of 2, we know that the loop is infinite if
2418 a % s <= b % s and a - s overflows. */
2419 assumption = simplify_gen_relational (reverse_condition (cond),
2420 SImode, mode,
2421 bound, tmp0);
2423 t0 = simplify_gen_binary (UMOD, mode, copy_rtx (tmp0), step);
2424 t1 = simplify_gen_binary (UMOD, mode, copy_rtx (tmp1), step);
2425 tmp = simplify_gen_relational (cond, SImode, mode, t0, t1);
2426 assumption = simplify_gen_binary (AND, SImode, assumption, tmp);
2427 desc->infinite =
2428 alloc_EXPR_LIST (0, assumption, desc->infinite);
2430 else
2432 assumption = simplify_gen_relational (cond, SImode, mode,
2433 bound, tmp0);
2434 desc->assumptions =
2435 alloc_EXPR_LIST (0, assumption, desc->assumptions);
2438 tmp = simplify_gen_binary (PLUS, comp_mode, iv0.base, iv1.step);
2439 tmp = lowpart_subreg (mode, tmp, comp_mode);
2440 assumption = simplify_gen_relational (reverse_condition (cond),
2441 SImode, mode,
2442 tmp, tmp1);
2443 delta = simplify_gen_binary (MINUS, mode, tmp0, step);
2444 delta = simplify_gen_binary (MINUS, mode, tmp1, delta);
2446 if (assumption == const_true_rtx)
2447 goto zero_iter_simplify;
2448 else if (assumption != const0_rtx)
2449 desc->noloop_assumptions =
2450 alloc_EXPR_LIST (0, assumption, desc->noloop_assumptions);
2451 delta = simplify_gen_binary (UDIV, mode, delta, step);
2452 desc->niter_expr = delta;
2455 old_niter = desc->niter_expr;
2457 simplify_using_initial_values (loop, AND, &desc->assumptions);
2458 if (desc->assumptions
2459 && XEXP (desc->assumptions, 0) == const0_rtx)
2460 goto fail;
2461 simplify_using_initial_values (loop, IOR, &desc->noloop_assumptions);
2462 simplify_using_initial_values (loop, IOR, &desc->infinite);
2463 simplify_using_initial_values (loop, UNKNOWN, &desc->niter_expr);
2465 /* Rerun the simplification. Consider code (created by copying loop headers)
2467 i = 0;
2469 if (0 < n)
2473 i++;
2474 } while (i < n);
2477 The first pass determines that i = 0, the second pass uses it to eliminate
2478 noloop assumption. */
2480 simplify_using_initial_values (loop, AND, &desc->assumptions);
2481 if (desc->assumptions
2482 && XEXP (desc->assumptions, 0) == const0_rtx)
2483 goto fail;
2484 simplify_using_initial_values (loop, IOR, &desc->noloop_assumptions);
2485 simplify_using_initial_values (loop, IOR, &desc->infinite);
2486 simplify_using_initial_values (loop, UNKNOWN, &desc->niter_expr);
2488 if (desc->noloop_assumptions
2489 && XEXP (desc->noloop_assumptions, 0) == const_true_rtx)
2490 goto zero_iter;
2492 if (GET_CODE (desc->niter_expr) == CONST_INT)
2494 unsigned HOST_WIDEST_INT val = INTVAL (desc->niter_expr);
2496 desc->const_iter = true;
2497 desc->niter_max = desc->niter = val & GET_MODE_MASK (desc->mode);
2499 else
2501 if (!desc->niter_max)
2502 desc->niter_max = determine_max_iter (desc);
2504 /* simplify_using_initial_values does a copy propagation on the registers
2505 in the expression for the number of iterations. This prolongs life
2506 ranges of registers and increases register pressure, and usually
2507 brings no gain (and if it happens to do, the cse pass will take care
2508 of it anyway). So prevent this behavior, unless it enabled us to
2509 derive that the number of iterations is a constant. */
2510 desc->niter_expr = old_niter;
2513 return;
2515 zero_iter_simplify:
2516 /* Simplify the assumptions. */
2517 simplify_using_initial_values (loop, AND, &desc->assumptions);
2518 if (desc->assumptions
2519 && XEXP (desc->assumptions, 0) == const0_rtx)
2520 goto fail;
2521 simplify_using_initial_values (loop, IOR, &desc->infinite);
2523 /* Fallthru. */
2524 zero_iter:
2525 desc->const_iter = true;
2526 desc->niter = 0;
2527 desc->niter_max = 0;
2528 desc->noloop_assumptions = NULL_RTX;
2529 desc->niter_expr = const0_rtx;
2530 return;
2532 fail:
2533 desc->simple_p = false;
2534 return;
2537 /* Checks whether E is a simple exit from LOOP and stores its description
2538 into DESC. */
2540 static void
2541 check_simple_exit (struct loop *loop, edge e, struct niter_desc *desc)
2543 basic_block exit_bb;
2544 rtx condition, at;
2545 edge ein;
2547 exit_bb = e->src;
2548 desc->simple_p = false;
2550 /* It must belong directly to the loop. */
2551 if (exit_bb->loop_father != loop)
2552 return;
2554 /* It must be tested (at least) once during any iteration. */
2555 if (!dominated_by_p (CDI_DOMINATORS, loop->latch, exit_bb))
2556 return;
2558 /* It must end in a simple conditional jump. */
2559 if (!any_condjump_p (BB_END (exit_bb)))
2560 return;
2562 ein = EDGE_SUCC (exit_bb, 0);
2563 if (ein == e)
2564 ein = EDGE_SUCC (exit_bb, 1);
2566 desc->out_edge = e;
2567 desc->in_edge = ein;
2569 /* Test whether the condition is suitable. */
2570 if (!(condition = get_condition (BB_END (ein->src), &at, false, false)))
2571 return;
2573 if (ein->flags & EDGE_FALLTHRU)
2575 condition = reversed_condition (condition);
2576 if (!condition)
2577 return;
2580 /* Check that we are able to determine number of iterations and fill
2581 in information about it. */
2582 iv_number_of_iterations (loop, at, condition, desc);
2585 /* Finds a simple exit of LOOP and stores its description into DESC. */
2587 void
2588 find_simple_exit (struct loop *loop, struct niter_desc *desc)
2590 unsigned i;
2591 basic_block *body;
2592 edge e;
2593 struct niter_desc act;
2594 bool any = false;
2595 edge_iterator ei;
2597 desc->simple_p = false;
2598 body = get_loop_body (loop);
2600 for (i = 0; i < loop->num_nodes; i++)
2602 FOR_EACH_EDGE (e, ei, body[i]->succs)
2604 if (flow_bb_inside_loop_p (loop, e->dest))
2605 continue;
2607 check_simple_exit (loop, e, &act);
2608 if (!act.simple_p)
2609 continue;
2611 if (!any)
2612 any = true;
2613 else
2615 /* Prefer constant iterations; the less the better. */
2616 if (!act.const_iter
2617 || (desc->const_iter && act.niter >= desc->niter))
2618 continue;
2620 /* Also if the actual exit may be infinite, while the old one
2621 not, prefer the old one. */
2622 if (act.infinite && !desc->infinite)
2623 continue;
2626 *desc = act;
2630 if (dump_file)
2632 if (desc->simple_p)
2634 fprintf (dump_file, "Loop %d is simple:\n", loop->num);
2635 fprintf (dump_file, " simple exit %d -> %d\n",
2636 desc->out_edge->src->index,
2637 desc->out_edge->dest->index);
2638 if (desc->assumptions)
2640 fprintf (dump_file, " assumptions: ");
2641 print_rtl (dump_file, desc->assumptions);
2642 fprintf (dump_file, "\n");
2644 if (desc->noloop_assumptions)
2646 fprintf (dump_file, " does not roll if: ");
2647 print_rtl (dump_file, desc->noloop_assumptions);
2648 fprintf (dump_file, "\n");
2650 if (desc->infinite)
2652 fprintf (dump_file, " infinite if: ");
2653 print_rtl (dump_file, desc->infinite);
2654 fprintf (dump_file, "\n");
2657 fprintf (dump_file, " number of iterations: ");
2658 print_rtl (dump_file, desc->niter_expr);
2659 fprintf (dump_file, "\n");
2661 fprintf (dump_file, " upper bound: ");
2662 fprintf (dump_file, HOST_WIDEST_INT_PRINT_DEC, desc->niter_max);
2663 fprintf (dump_file, "\n");
2665 else
2666 fprintf (dump_file, "Loop %d is not simple.\n", loop->num);
2669 free (body);
2672 /* Creates a simple loop description of LOOP if it was not computed
2673 already. */
2675 struct niter_desc *
2676 get_simple_loop_desc (struct loop *loop)
2678 struct niter_desc *desc = simple_loop_desc (loop);
2680 if (desc)
2681 return desc;
2683 desc = XNEW (struct niter_desc);
2684 iv_analysis_loop_init (loop);
2685 find_simple_exit (loop, desc);
2686 loop->aux = desc;
2688 if (desc->simple_p && (desc->assumptions || desc->infinite))
2690 const char *wording;
2692 /* Assume that no overflow happens and that the loop is finite.
2693 We already warned at the tree level if we ran optimizations there. */
2694 if (!flag_tree_loop_optimize && warn_unsafe_loop_optimizations)
2696 if (desc->infinite)
2698 wording =
2699 flag_unsafe_loop_optimizations
2700 ? N_("assuming that the loop is not infinite")
2701 : N_("cannot optimize possibly infinite loops");
2702 warning (OPT_Wunsafe_loop_optimizations, "%s",
2703 gettext (wording));
2705 if (desc->assumptions)
2707 wording =
2708 flag_unsafe_loop_optimizations
2709 ? N_("assuming that the loop counter does not overflow")
2710 : N_("cannot optimize loop, the loop counter may overflow");
2711 warning (OPT_Wunsafe_loop_optimizations, "%s",
2712 gettext (wording));
2716 if (flag_unsafe_loop_optimizations)
2718 desc->assumptions = NULL_RTX;
2719 desc->infinite = NULL_RTX;
2723 return desc;
2726 /* Releases simple loop description for LOOP. */
2728 void
2729 free_simple_loop_desc (struct loop *loop)
2731 struct niter_desc *desc = simple_loop_desc (loop);
2733 if (!desc)
2734 return;
2736 free (desc);
2737 loop->aux = NULL;