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1 684 jeremybenn
/* Inlining decision heuristics.
2
   Copyright (C) 2003, 2004, 2007, 2008, 2009, 2010, 2011
3
   Free Software Foundation, Inc.
4
   Contributed by Jan Hubicka
5
 
6
This file is part of GCC.
7
 
8
GCC is free software; you can redistribute it and/or modify it under
9
the terms of the GNU General Public License as published by the Free
10
Software Foundation; either version 3, or (at your option) any later
11
version.
12
 
13
GCC is distributed in the hope that it will be useful, but WITHOUT ANY
14
WARRANTY; without even the implied warranty of MERCHANTABILITY or
15
FITNESS FOR A PARTICULAR PURPOSE.  See the GNU General Public License
16
for more details.
17
 
18
You should have received a copy of the GNU General Public License
19
along with GCC; see the file COPYING3.  If not see
20
<http://www.gnu.org/licenses/>.  */
21
 
22
/* Analysis used by the inliner and other passes limiting code size growth.
23
 
24
   We estimate for each function
25
     - function body size
26
     - average function execution time
27
     - inlining size benefit (that is how much of function body size
28
       and its call sequence is expected to disappear by inlining)
29
     - inlining time benefit
30
     - function frame size
31
   For each call
32
     - call statement size and time
33
 
34
   inlinie_summary datastructures store above information locally (i.e.
35
   parameters of the function itself) and globally (i.e. parameters of
36
   the function created by applying all the inline decisions already
37
   present in the callgraph).
38
 
39
   We provide accestor to the inline_summary datastructure and
40
   basic logic updating the parameters when inlining is performed.
41
 
42
   The summaries are context sensitive.  Context means
43
     1) partial assignment of known constant values of operands
44
     2) whether function is inlined into the call or not.
45
   It is easy to add more variants.  To represent function size and time
46
   that depends on context (i.e. it is known to be optimized away when
47
   context is known either by inlining or from IP-CP and clonning),
48
   we use predicates. Predicates are logical formulas in
49
   conjunctive-disjunctive form consisting of clauses. Clauses are bitmaps
50
   specifying what conditions must be true. Conditions are simple test
51
   of the form described above.
52
 
53
   In order to make predicate (possibly) true, all of its clauses must
54
   be (possibly) true. To make clause (possibly) true, one of conditions
55
   it mentions must be (possibly) true.  There are fixed bounds on
56
   number of clauses and conditions and all the manipulation functions
57
   are conservative in positive direction. I.e. we may lose precision
58
   by thinking that predicate may be true even when it is not.
59
 
60
   estimate_edge_size and estimate_edge_growth can be used to query
61
   function size/time in the given context.  inline_merge_summary merges
62
   properties of caller and callee after inlining.
63
 
64
   Finally pass_inline_parameters is exported.  This is used to drive
65
   computation of function parameters used by the early inliner. IPA
66
   inlined performs analysis via its analyze_function method. */
67
 
68
#include "config.h"
69
#include "system.h"
70
#include "coretypes.h"
71
#include "tm.h"
72
#include "tree.h"
73
#include "tree-inline.h"
74
#include "langhooks.h"
75
#include "flags.h"
76
#include "cgraph.h"
77
#include "diagnostic.h"
78
#include "gimple-pretty-print.h"
79
#include "timevar.h"
80
#include "params.h"
81
#include "tree-pass.h"
82
#include "coverage.h"
83
#include "ggc.h"
84
#include "tree-flow.h"
85
#include "ipa-prop.h"
86
#include "lto-streamer.h"
87
#include "data-streamer.h"
88
#include "tree-streamer.h"
89
#include "ipa-inline.h"
90
#include "alloc-pool.h"
91
 
92
/* Estimate runtime of function can easilly run into huge numbers with many
93
   nested loops.  Be sure we can compute time * INLINE_SIZE_SCALE * 2 in an
94
   integer.  For anything larger we use gcov_type.  */
95
#define MAX_TIME 500000
96
 
97
/* Number of bits in integer, but we really want to be stable across different
98
   hosts.  */
99
#define NUM_CONDITIONS 32
100
 
101
enum predicate_conditions
102
{
103
  predicate_false_condition = 0,
104
  predicate_not_inlined_condition = 1,
105
  predicate_first_dynamic_condition = 2
106
};
107
 
108
/* Special condition code we use to represent test that operand is compile time
109
   constant.  */
110
#define IS_NOT_CONSTANT ERROR_MARK
111
/* Special condition code we use to represent test that operand is not changed
112
   across invocation of the function.  When operand IS_NOT_CONSTANT it is always
113
   CHANGED, however i.e. loop invariants can be NOT_CHANGED given percentage
114
   of executions even when they are not compile time constants.  */
115
#define CHANGED IDENTIFIER_NODE
116
 
117
/* Holders of ipa cgraph hooks: */
118
static struct cgraph_node_hook_list *function_insertion_hook_holder;
119
static struct cgraph_node_hook_list *node_removal_hook_holder;
120
static struct cgraph_2node_hook_list *node_duplication_hook_holder;
121
static struct cgraph_2edge_hook_list *edge_duplication_hook_holder;
122
static struct cgraph_edge_hook_list *edge_removal_hook_holder;
123
static void inline_node_removal_hook (struct cgraph_node *, void *);
124
static void inline_node_duplication_hook (struct cgraph_node *,
125
                                          struct cgraph_node *, void *);
126
static void inline_edge_removal_hook (struct cgraph_edge *, void *);
127
static void inline_edge_duplication_hook (struct cgraph_edge *,
128
                                          struct cgraph_edge *,
129
                                          void *);
130
 
131
/* VECtor holding inline summaries.
132
   In GGC memory because conditions might point to constant trees.  */
133
VEC(inline_summary_t,gc) *inline_summary_vec;
134
VEC(inline_edge_summary_t,heap) *inline_edge_summary_vec;
135
 
136
/* Cached node/edge growths.  */
137
VEC(int,heap) *node_growth_cache;
138
VEC(edge_growth_cache_entry,heap) *edge_growth_cache;
139
 
140
/* Edge predicates goes here.  */
141
static alloc_pool edge_predicate_pool;
142
 
143
/* Return true predicate (tautology).
144
   We represent it by empty list of clauses.  */
145
 
146
static inline struct predicate
147
true_predicate (void)
148
{
149
  struct predicate p;
150
  p.clause[0]=0;
151
  return p;
152
}
153
 
154
 
155
/* Return predicate testing single condition number COND.  */
156
 
157
static inline struct predicate
158
single_cond_predicate (int cond)
159
{
160
  struct predicate p;
161
  p.clause[0]=1 << cond;
162
  p.clause[1]=0;
163
  return p;
164
}
165
 
166
 
167
/* Return false predicate.  First clause require false condition.  */
168
 
169
static inline struct predicate
170
false_predicate (void)
171
{
172
  return single_cond_predicate (predicate_false_condition);
173
}
174
 
175
 
176
/* Return true if P is (false).  */
177
 
178
static inline bool
179
true_predicate_p (struct predicate *p)
180
{
181
  return !p->clause[0];
182
}
183
 
184
 
185
/* Return true if P is (false).  */
186
 
187
static inline bool
188
false_predicate_p (struct predicate *p)
189
{
190
  if (p->clause[0] == (1 << predicate_false_condition))
191
    {
192
      gcc_checking_assert (!p->clause[1]
193
                           && p->clause[0] == 1 << predicate_false_condition);
194
      return true;
195
    }
196
  return false;
197
}
198
 
199
 
200
/* Return predicate that is set true when function is not inlined.  */
201
static inline struct predicate
202
not_inlined_predicate (void)
203
{
204
  return single_cond_predicate (predicate_not_inlined_condition);
205
}
206
 
207
 
208
/* Add condition to condition list CONDS.  */
209
 
210
static struct predicate
211
add_condition (struct inline_summary *summary, int operand_num,
212
               enum tree_code code, tree val)
213
{
214
  int i;
215
  struct condition *c;
216
  struct condition new_cond;
217
 
218
  for (i = 0; VEC_iterate (condition, summary->conds, i, c); i++)
219
    {
220
      if (c->operand_num == operand_num
221
          && c->code == code
222
          && c->val == val)
223
        return single_cond_predicate (i + predicate_first_dynamic_condition);
224
    }
225
  /* Too many conditions.  Give up and return constant true.  */
226
  if (i == NUM_CONDITIONS - predicate_first_dynamic_condition)
227
    return true_predicate ();
228
 
229
  new_cond.operand_num = operand_num;
230
  new_cond.code = code;
231
  new_cond.val = val;
232
  VEC_safe_push (condition, gc, summary->conds, &new_cond);
233
  return single_cond_predicate (i + predicate_first_dynamic_condition);
234
}
235
 
236
 
237
/* Add clause CLAUSE into the predicate P.  */
238
 
239
static inline void
240
add_clause (conditions conditions, struct predicate *p, clause_t clause)
241
{
242
  int i;
243
  int i2;
244
  int insert_here = -1;
245
  int c1, c2;
246
 
247
  /* True clause.  */
248
  if (!clause)
249
    return;
250
 
251
  /* False clause makes the whole predicate false.  Kill the other variants.  */
252
  if (clause == (1 << predicate_false_condition))
253
    {
254
      p->clause[0] = (1 << predicate_false_condition);
255
      p->clause[1] = 0;
256
      return;
257
    }
258
  if (false_predicate_p (p))
259
    return;
260
 
261
  /* No one should be sily enough to add false into nontrivial clauses.  */
262
  gcc_checking_assert (!(clause & (1 << predicate_false_condition)));
263
 
264
  /* Look where to insert the clause.  At the same time prune out
265
     clauses of P that are implied by the new clause and thus
266
     redundant.  */
267
  for (i = 0, i2 = 0; i <= MAX_CLAUSES; i++)
268
    {
269
      p->clause[i2] = p->clause[i];
270
 
271
      if (!p->clause[i])
272
        break;
273
 
274
      /* If p->clause[i] implies clause, there is nothing to add.  */
275
      if ((p->clause[i] & clause) == p->clause[i])
276
        {
277
          /* We had nothing to add, none of clauses should've become
278
             redundant.  */
279
          gcc_checking_assert (i == i2);
280
          return;
281
        }
282
 
283
      if (p->clause[i] < clause && insert_here < 0)
284
        insert_here = i2;
285
 
286
      /* If clause implies p->clause[i], then p->clause[i] becomes redundant.
287
         Otherwise the p->clause[i] has to stay.  */
288
      if ((p->clause[i] & clause) != clause)
289
        i2++;
290
    }
291
 
292
  /* Look for clauses that are obviously true.  I.e.
293
     op0 == 5 || op0 != 5.  */
294
  for (c1 = predicate_first_dynamic_condition; c1 < NUM_CONDITIONS; c1++)
295
    {
296
      condition *cc1;
297
      if (!(clause & (1 << c1)))
298
        continue;
299
      cc1 = VEC_index (condition,
300
                       conditions,
301
                       c1 - predicate_first_dynamic_condition);
302
      /* We have no way to represent !CHANGED and !IS_NOT_CONSTANT
303
         and thus there is no point for looking for them.  */
304
      if (cc1->code == CHANGED
305
          || cc1->code == IS_NOT_CONSTANT)
306
        continue;
307
      for (c2 = c1 + 1; c2 <= NUM_CONDITIONS; c2++)
308
        if (clause & (1 << c2))
309
          {
310
            condition *cc1 = VEC_index (condition,
311
                                        conditions,
312
                                        c1 - predicate_first_dynamic_condition);
313
            condition *cc2 = VEC_index (condition,
314
                                        conditions,
315
                                        c2 - predicate_first_dynamic_condition);
316
            if (cc1->operand_num == cc2->operand_num
317
                && cc1->val == cc2->val
318
                && cc2->code != IS_NOT_CONSTANT
319
                && cc2->code != CHANGED
320
                && cc1->code == invert_tree_comparison
321
                    (cc2->code,
322
                     HONOR_NANS (TYPE_MODE (TREE_TYPE (cc1->val)))))
323
              return;
324
          }
325
    }
326
 
327
 
328
  /* We run out of variants.  Be conservative in positive direction.  */
329
  if (i2 == MAX_CLAUSES)
330
    return;
331
  /* Keep clauses in decreasing order. This makes equivalence testing easy.  */
332
  p->clause[i2 + 1] = 0;
333
  if (insert_here >= 0)
334
    for (;i2 > insert_here; i2--)
335
      p->clause[i2] = p->clause[i2 - 1];
336
  else
337
    insert_here = i2;
338
  p->clause[insert_here] = clause;
339
}
340
 
341
 
342
/* Return P & P2.  */
343
 
344
static struct predicate
345
and_predicates (conditions conditions,
346
                struct predicate *p, struct predicate *p2)
347
{
348
  struct predicate out = *p;
349
  int i;
350
 
351
  /* Avoid busy work.  */
352
  if (false_predicate_p (p2) || true_predicate_p (p))
353
    return *p2;
354
  if (false_predicate_p (p) || true_predicate_p (p2))
355
    return *p;
356
 
357
  /* See how far predicates match.  */
358
  for (i = 0; p->clause[i] && p->clause[i] == p2->clause[i]; i++)
359
    {
360
      gcc_checking_assert (i < MAX_CLAUSES);
361
    }
362
 
363
  /* Combine the predicates rest.  */
364
  for (; p2->clause[i]; i++)
365
    {
366
      gcc_checking_assert (i < MAX_CLAUSES);
367
      add_clause (conditions, &out, p2->clause[i]);
368
    }
369
  return out;
370
}
371
 
372
 
373
/* Return true if predicates are obviously equal.  */
374
 
375
static inline bool
376
predicates_equal_p (struct predicate *p, struct predicate *p2)
377
{
378
  int i;
379
  for (i = 0; p->clause[i]; i++)
380
    {
381
      gcc_checking_assert (i < MAX_CLAUSES);
382
      gcc_checking_assert (p->clause [i] > p->clause[i + 1]);
383
      gcc_checking_assert (!p2->clause[i]
384
                           || p2->clause [i] > p2->clause[i + 1]);
385
      if (p->clause[i] != p2->clause[i])
386
        return false;
387
    }
388
  return !p2->clause[i];
389
}
390
 
391
 
392
/* Return P | P2.  */
393
 
394
static struct predicate
395
or_predicates (conditions conditions, struct predicate *p, struct predicate *p2)
396
{
397
  struct predicate out = true_predicate ();
398
  int i,j;
399
 
400
  /* Avoid busy work.  */
401
  if (false_predicate_p (p2) || true_predicate_p (p))
402
    return *p;
403
  if (false_predicate_p (p) || true_predicate_p (p2))
404
    return *p2;
405
  if (predicates_equal_p (p, p2))
406
    return *p;
407
 
408
  /* OK, combine the predicates.  */
409
  for (i = 0; p->clause[i]; i++)
410
    for (j = 0; p2->clause[j]; j++)
411
      {
412
        gcc_checking_assert (i < MAX_CLAUSES && j < MAX_CLAUSES);
413
        add_clause (conditions, &out, p->clause[i] | p2->clause[j]);
414
      }
415
  return out;
416
}
417
 
418
 
419
/* Having partial truth assignment in POSSIBLE_TRUTHS, return false
420
   if predicate P is known to be false.  */
421
 
422
static bool
423
evaluate_predicate (struct predicate *p, clause_t possible_truths)
424
{
425
  int i;
426
 
427
  /* True remains true.  */
428
  if (true_predicate_p (p))
429
    return true;
430
 
431
  gcc_assert (!(possible_truths & (1 << predicate_false_condition)));
432
 
433
  /* See if we can find clause we can disprove.  */
434
  for (i = 0; p->clause[i]; i++)
435
    {
436
      gcc_checking_assert (i < MAX_CLAUSES);
437
      if (!(p->clause[i] & possible_truths))
438
        return false;
439
    }
440
  return true;
441
}
442
 
443
/* Return the probability in range 0...REG_BR_PROB_BASE that the predicated
444
   instruction will be recomputed per invocation of the inlined call.  */
445
 
446
static int
447
predicate_probability (conditions conds,
448
                       struct predicate *p, clause_t possible_truths,
449
                       VEC (inline_param_summary_t, heap) *inline_param_summary)
450
{
451
  int i;
452
  int combined_prob = REG_BR_PROB_BASE;
453
 
454
  /* True remains true.  */
455
  if (true_predicate_p (p))
456
    return REG_BR_PROB_BASE;
457
 
458
  if (false_predicate_p (p))
459
    return 0;
460
 
461
  gcc_assert (!(possible_truths & (1 << predicate_false_condition)));
462
 
463
  /* See if we can find clause we can disprove.  */
464
  for (i = 0; p->clause[i]; i++)
465
    {
466
      gcc_checking_assert (i < MAX_CLAUSES);
467
      if (!(p->clause[i] & possible_truths))
468
        return 0;
469
      else
470
        {
471
          int this_prob = 0;
472
          int i2;
473
          if (!inline_param_summary)
474
            return REG_BR_PROB_BASE;
475
          for (i2 = 0; i2 < NUM_CONDITIONS; i2++)
476
            if ((p->clause[i] & possible_truths) & (1 << i2))
477
              {
478
                if (i2 >= predicate_first_dynamic_condition)
479
                  {
480
                    condition *c = VEC_index
481
                                    (condition, conds,
482
                                     i2 - predicate_first_dynamic_condition);
483
                    if (c->code == CHANGED
484
                        && (c->operand_num
485
                            < (int) VEC_length (inline_param_summary_t,
486
                                                inline_param_summary)))
487
                      {
488
                        int iprob = VEC_index (inline_param_summary_t,
489
                                               inline_param_summary,
490
                                               c->operand_num)->change_prob;
491
                        this_prob = MAX (this_prob, iprob);
492
                      }
493
                    else
494
                      this_prob = REG_BR_PROB_BASE;
495
                   }
496
                 else
497
                   this_prob = REG_BR_PROB_BASE;
498
              }
499
          combined_prob = MIN (this_prob, combined_prob);
500
          if (!combined_prob)
501
            return 0;
502
        }
503
    }
504
  return combined_prob;
505
}
506
 
507
 
508
/* Dump conditional COND.  */
509
 
510
static void
511
dump_condition (FILE *f, conditions conditions, int cond)
512
{
513
  condition *c;
514
  if (cond == predicate_false_condition)
515
    fprintf (f, "false");
516
  else if (cond == predicate_not_inlined_condition)
517
    fprintf (f, "not inlined");
518
  else
519
    {
520
      c = VEC_index (condition, conditions,
521
                     cond - predicate_first_dynamic_condition);
522
      fprintf (f, "op%i", c->operand_num);
523
      if (c->code == IS_NOT_CONSTANT)
524
        {
525
          fprintf (f, " not constant");
526
          return;
527
        }
528
      if (c->code == CHANGED)
529
        {
530
          fprintf (f, " changed");
531
          return;
532
        }
533
      fprintf (f, " %s ", op_symbol_code (c->code));
534
      print_generic_expr (f, c->val, 1);
535
    }
536
}
537
 
538
 
539
/* Dump clause CLAUSE.  */
540
 
541
static void
542
dump_clause (FILE *f, conditions conds, clause_t clause)
543
{
544
  int i;
545
  bool found = false;
546
  fprintf (f, "(");
547
  if (!clause)
548
    fprintf (f, "true");
549
  for (i = 0; i < NUM_CONDITIONS; i++)
550
    if (clause & (1 << i))
551
      {
552
        if (found)
553
          fprintf (f, " || ");
554
        found = true;
555
        dump_condition (f, conds, i);
556
      }
557
  fprintf (f, ")");
558
}
559
 
560
 
561
/* Dump predicate PREDICATE.  */
562
 
563
static void
564
dump_predicate (FILE *f, conditions conds, struct predicate *pred)
565
{
566
  int i;
567
  if (true_predicate_p (pred))
568
    dump_clause (f, conds, 0);
569
  else
570
    for (i = 0; pred->clause[i]; i++)
571
      {
572
        if (i)
573
          fprintf (f, " && ");
574
        dump_clause (f, conds, pred->clause[i]);
575
      }
576
  fprintf (f, "\n");
577
}
578
 
579
 
580
/* Record SIZE and TIME under condition PRED into the inline summary.  */
581
 
582
static void
583
account_size_time (struct inline_summary *summary, int size, int time,
584
                   struct predicate *pred)
585
{
586
  size_time_entry *e;
587
  bool found = false;
588
  int i;
589
 
590
  if (false_predicate_p (pred))
591
    return;
592
 
593
  /* We need to create initial empty unconitional clause, but otherwie
594
     we don't need to account empty times and sizes.  */
595
  if (!size && !time && summary->entry)
596
    return;
597
 
598
  /* Watch overflow that might result from insane profiles.  */
599
  if (time > MAX_TIME * INLINE_TIME_SCALE)
600
    time = MAX_TIME * INLINE_TIME_SCALE;
601
  gcc_assert (time >= 0);
602
 
603
  for (i = 0; VEC_iterate (size_time_entry, summary->entry, i, e); i++)
604
    if (predicates_equal_p (&e->predicate, pred))
605
      {
606
        found = true;
607
        break;
608
      }
609
  if (i == 32)
610
    {
611
      i = 0;
612
      found = true;
613
      e = VEC_index (size_time_entry, summary->entry, 0);
614
      gcc_assert (!e->predicate.clause[0]);
615
    }
616
  if (dump_file && (dump_flags & TDF_DETAILS) && (time || size))
617
    {
618
      fprintf (dump_file, "\t\tAccounting size:%3.2f, time:%3.2f on %spredicate:",
619
               ((double)size) / INLINE_SIZE_SCALE,
620
               ((double)time) / INLINE_TIME_SCALE,
621
               found ? "" : "new ");
622
      dump_predicate (dump_file, summary->conds, pred);
623
    }
624
  if (!found)
625
    {
626
      struct size_time_entry new_entry;
627
      new_entry.size = size;
628
      new_entry.time = time;
629
      new_entry.predicate = *pred;
630
      VEC_safe_push (size_time_entry, gc, summary->entry, &new_entry);
631
    }
632
  else
633
    {
634
      e->size += size;
635
      e->time += time;
636
      if (e->time > MAX_TIME * INLINE_TIME_SCALE)
637
        e->time = MAX_TIME * INLINE_TIME_SCALE;
638
    }
639
}
640
 
641
/* Set predicate for edge E.  */
642
 
643
static void
644
edge_set_predicate (struct cgraph_edge *e, struct predicate *predicate)
645
{
646
  struct inline_edge_summary *es = inline_edge_summary (e);
647
  if (predicate && !true_predicate_p (predicate))
648
    {
649
      if (!es->predicate)
650
        es->predicate = (struct predicate *)pool_alloc (edge_predicate_pool);
651
      *es->predicate = *predicate;
652
    }
653
  else
654
    {
655
      if (es->predicate)
656
        pool_free (edge_predicate_pool, es->predicate);
657
      es->predicate = NULL;
658
    }
659
}
660
 
661
 
662
/* KNOWN_VALS is partial mapping of parameters of NODE to constant values.
663
   Return clause of possible truths. When INLINE_P is true, assume that
664
   we are inlining.
665
 
666
   ERROR_MARK means compile time invariant.  */
667
 
668
static clause_t
669
evaluate_conditions_for_known_args (struct cgraph_node *node,
670
                                    bool inline_p,
671
                                    VEC (tree, heap) *known_vals)
672
{
673
  clause_t clause = inline_p ? 0 : 1 << predicate_not_inlined_condition;
674
  struct inline_summary *info = inline_summary (node);
675
  int i;
676
  struct condition *c;
677
 
678
  for (i = 0; VEC_iterate (condition, info->conds, i, c); i++)
679
    {
680
      tree val;
681
      tree res;
682
 
683
      /* We allow call stmt to have fewer arguments than the callee
684
         function (especially for K&R style programs).  So bound
685
         check here.  */
686
      if (c->operand_num < (int)VEC_length (tree, known_vals))
687
        val = VEC_index (tree, known_vals, c->operand_num);
688
      else
689
        val = NULL;
690
 
691
      if (val == error_mark_node && c->code != CHANGED)
692
        val = NULL;
693
 
694
      if (!val)
695
        {
696
          clause |= 1 << (i + predicate_first_dynamic_condition);
697
          continue;
698
        }
699
      if (c->code == IS_NOT_CONSTANT || c->code == CHANGED)
700
        continue;
701
      res = fold_binary_to_constant (c->code, boolean_type_node, val, c->val);
702
      if (res
703
          && integer_zerop (res))
704
        continue;
705
      clause |= 1 << (i + predicate_first_dynamic_condition);
706
    }
707
  return clause;
708
}
709
 
710
 
711
/* Work out what conditions might be true at invocation of E.  */
712
 
713
static void
714
evaluate_properties_for_edge (struct cgraph_edge *e, bool inline_p,
715
                              clause_t *clause_ptr,
716
                              VEC (tree, heap) **known_vals_ptr,
717
                              VEC (tree, heap) **known_binfos_ptr)
718
{
719
  struct cgraph_node *callee = cgraph_function_or_thunk_node (e->callee, NULL);
720
  struct inline_summary *info = inline_summary (callee);
721
  VEC (tree, heap) *known_vals = NULL;
722
 
723
  if (clause_ptr)
724
    *clause_ptr = inline_p ? 0 : 1 << predicate_not_inlined_condition;
725
  if (known_vals_ptr)
726
    *known_vals_ptr = NULL;
727
  if (known_binfos_ptr)
728
    *known_binfos_ptr = NULL;
729
 
730
  if (ipa_node_params_vector
731
      && !e->call_stmt_cannot_inline_p
732
      && ((clause_ptr && info->conds) || known_vals_ptr || known_binfos_ptr))
733
    {
734
      struct ipa_node_params *parms_info;
735
      struct ipa_edge_args *args = IPA_EDGE_REF (e);
736
      struct inline_edge_summary *es = inline_edge_summary (e);
737
      int i, count = ipa_get_cs_argument_count (args);
738
 
739
      if (e->caller->global.inlined_to)
740
        parms_info = IPA_NODE_REF (e->caller->global.inlined_to);
741
      else
742
        parms_info = IPA_NODE_REF (e->caller);
743
 
744
      if (count && (info->conds || known_vals_ptr))
745
        VEC_safe_grow_cleared (tree, heap, known_vals, count);
746
      if (count && known_binfos_ptr)
747
        VEC_safe_grow_cleared (tree, heap, *known_binfos_ptr, count);
748
 
749
      for (i = 0; i < count; i++)
750
        {
751
          tree cst = ipa_value_from_jfunc (parms_info,
752
                                           ipa_get_ith_jump_func (args, i));
753
          if (cst)
754
            {
755
              if (known_vals && TREE_CODE (cst) != TREE_BINFO)
756
                VEC_replace (tree, known_vals, i, cst);
757
              else if (known_binfos_ptr != NULL && TREE_CODE (cst) == TREE_BINFO)
758
                VEC_replace (tree, *known_binfos_ptr, i, cst);
759
            }
760
          else if (inline_p
761
                   && !VEC_index (inline_param_summary_t,
762
                                  es->param,
763
                                  i)->change_prob)
764
            VEC_replace (tree, known_vals, i, error_mark_node);
765
        }
766
    }
767
 
768
  if (clause_ptr)
769
    *clause_ptr = evaluate_conditions_for_known_args (callee, inline_p,
770
                                                      known_vals);
771
 
772
  if (known_vals_ptr)
773
    *known_vals_ptr = known_vals;
774
  else
775
    VEC_free (tree, heap, known_vals);
776
}
777
 
778
 
779
/* Allocate the inline summary vector or resize it to cover all cgraph nodes. */
780
 
781
static void
782
inline_summary_alloc (void)
783
{
784
  if (!node_removal_hook_holder)
785
    node_removal_hook_holder =
786
      cgraph_add_node_removal_hook (&inline_node_removal_hook, NULL);
787
  if (!edge_removal_hook_holder)
788
    edge_removal_hook_holder =
789
      cgraph_add_edge_removal_hook (&inline_edge_removal_hook, NULL);
790
  if (!node_duplication_hook_holder)
791
    node_duplication_hook_holder =
792
      cgraph_add_node_duplication_hook (&inline_node_duplication_hook, NULL);
793
  if (!edge_duplication_hook_holder)
794
    edge_duplication_hook_holder =
795
      cgraph_add_edge_duplication_hook (&inline_edge_duplication_hook, NULL);
796
 
797
  if (VEC_length (inline_summary_t, inline_summary_vec)
798
      <= (unsigned) cgraph_max_uid)
799
    VEC_safe_grow_cleared (inline_summary_t, gc,
800
                           inline_summary_vec, cgraph_max_uid + 1);
801
  if (VEC_length (inline_edge_summary_t, inline_edge_summary_vec)
802
      <= (unsigned) cgraph_edge_max_uid)
803
    VEC_safe_grow_cleared (inline_edge_summary_t, heap,
804
                           inline_edge_summary_vec, cgraph_edge_max_uid + 1);
805
  if (!edge_predicate_pool)
806
    edge_predicate_pool = create_alloc_pool ("edge predicates",
807
                                             sizeof (struct predicate),
808
                                             10);
809
}
810
 
811
/* We are called multiple time for given function; clear
812
   data from previous run so they are not cumulated.  */
813
 
814
static void
815
reset_inline_edge_summary (struct cgraph_edge *e)
816
{
817
  if (e->uid
818
      < (int)VEC_length (inline_edge_summary_t, inline_edge_summary_vec))
819
    {
820
      struct inline_edge_summary *es = inline_edge_summary (e);
821
 
822
      es->call_stmt_size = es->call_stmt_time =0;
823
      if (es->predicate)
824
        pool_free (edge_predicate_pool, es->predicate);
825
      es->predicate = NULL;
826
      VEC_free (inline_param_summary_t, heap, es->param);
827
    }
828
}
829
 
830
/* We are called multiple time for given function; clear
831
   data from previous run so they are not cumulated.  */
832
 
833
static void
834
reset_inline_summary (struct cgraph_node *node)
835
{
836
  struct inline_summary *info = inline_summary (node);
837
  struct cgraph_edge *e;
838
 
839
  info->self_size = info->self_time = 0;
840
  info->estimated_stack_size = 0;
841
  info->estimated_self_stack_size = 0;
842
  info->stack_frame_offset = 0;
843
  info->size = 0;
844
  info->time = 0;
845
  VEC_free (condition, gc, info->conds);
846
  VEC_free (size_time_entry,gc, info->entry);
847
  for (e = node->callees; e; e = e->next_callee)
848
    reset_inline_edge_summary (e);
849
  for (e = node->indirect_calls; e; e = e->next_callee)
850
    reset_inline_edge_summary (e);
851
}
852
 
853
/* Hook that is called by cgraph.c when a node is removed.  */
854
 
855
static void
856
inline_node_removal_hook (struct cgraph_node *node, void *data ATTRIBUTE_UNUSED)
857
{
858
  struct inline_summary *info;
859
  if (VEC_length (inline_summary_t, inline_summary_vec)
860
      <= (unsigned)node->uid)
861
    return;
862
  info = inline_summary (node);
863
  reset_inline_summary (node);
864
  memset (info, 0, sizeof (inline_summary_t));
865
}
866
 
867
 
868
/* Hook that is called by cgraph.c when a node is duplicated.  */
869
 
870
static void
871
inline_node_duplication_hook (struct cgraph_node *src, struct cgraph_node *dst,
872
                              ATTRIBUTE_UNUSED void *data)
873
{
874
  struct inline_summary *info;
875
  inline_summary_alloc ();
876
  info = inline_summary (dst);
877
  memcpy (info, inline_summary (src),
878
          sizeof (struct inline_summary));
879
  /* TODO: as an optimization, we may avoid copying conditions
880
     that are known to be false or true.  */
881
  info->conds = VEC_copy (condition, gc, info->conds);
882
 
883
  /* When there are any replacements in the function body, see if we can figure
884
     out that something was optimized out.  */
885
  if (ipa_node_params_vector && dst->clone.tree_map)
886
    {
887
      VEC(size_time_entry,gc) *entry = info->entry;
888
      /* Use SRC parm info since it may not be copied yet.  */
889
      struct ipa_node_params *parms_info = IPA_NODE_REF (src);
890
      VEC (tree, heap) *known_vals = NULL;
891
      int count = ipa_get_param_count (parms_info);
892
      int i,j;
893
      clause_t possible_truths;
894
      struct predicate true_pred = true_predicate ();
895
      size_time_entry *e;
896
      int optimized_out_size = 0;
897
      gcov_type optimized_out_time = 0;
898
      bool inlined_to_p = false;
899
      struct cgraph_edge *edge;
900
 
901
      info->entry = 0;
902
      VEC_safe_grow_cleared (tree, heap, known_vals, count);
903
      for (i = 0; i < count; i++)
904
        {
905
          tree t = ipa_get_param (parms_info, i);
906
          struct ipa_replace_map *r;
907
 
908
          for (j = 0;
909
               VEC_iterate (ipa_replace_map_p, dst->clone.tree_map, j, r);
910
               j++)
911
            {
912
              if (r->old_tree == t
913
                  && r->replace_p
914
                  && !r->ref_p)
915
                {
916
                  VEC_replace (tree, known_vals, i, r->new_tree);
917
                  break;
918
                }
919
            }
920
        }
921
      possible_truths = evaluate_conditions_for_known_args (dst,
922
                                                            false, known_vals);
923
      VEC_free (tree, heap, known_vals);
924
 
925
      account_size_time (info, 0, 0, &true_pred);
926
 
927
      /* Remap size_time vectors.
928
         Simplify the predicate by prunning out alternatives that are known
929
         to be false.
930
         TODO: as on optimization, we can also eliminate conditions known
931
         to be true.  */
932
      for (i = 0; VEC_iterate (size_time_entry, entry, i, e); i++)
933
        {
934
          struct predicate new_predicate = true_predicate ();
935
          for (j = 0; e->predicate.clause[j]; j++)
936
            if (!(possible_truths & e->predicate.clause[j]))
937
              {
938
                new_predicate = false_predicate ();
939
                break;
940
              }
941
            else
942
              add_clause (info->conds, &new_predicate,
943
                          possible_truths & e->predicate.clause[j]);
944
          if (false_predicate_p (&new_predicate))
945
            {
946
              optimized_out_size += e->size;
947
              optimized_out_time += e->time;
948
            }
949
          else
950
            account_size_time (info, e->size, e->time, &new_predicate);
951
        }
952
 
953
      /* Remap edge predicates with the same simplification as above.
954
         Also copy constantness arrays.   */
955
      for (edge = dst->callees; edge; edge = edge->next_callee)
956
        {
957
          struct predicate new_predicate = true_predicate ();
958
          struct inline_edge_summary *es = inline_edge_summary (edge);
959
 
960
          if (!edge->inline_failed)
961
            inlined_to_p = true;
962
          if (!es->predicate)
963
            continue;
964
          for (j = 0; es->predicate->clause[j]; j++)
965
            if (!(possible_truths & es->predicate->clause[j]))
966
              {
967
                new_predicate = false_predicate ();
968
                break;
969
              }
970
            else
971
              add_clause (info->conds, &new_predicate,
972
                          possible_truths & es->predicate->clause[j]);
973
          if (false_predicate_p (&new_predicate)
974
              && !false_predicate_p (es->predicate))
975
            {
976
              optimized_out_size += es->call_stmt_size * INLINE_SIZE_SCALE;
977
              optimized_out_time += (es->call_stmt_time
978
                                     * (INLINE_TIME_SCALE / CGRAPH_FREQ_BASE)
979
                                     * edge->frequency);
980
              edge->frequency = 0;
981
            }
982
          *es->predicate = new_predicate;
983
        }
984
 
985
      /* Remap indirect edge predicates with the same simplificaiton as above.
986
         Also copy constantness arrays.   */
987
      for (edge = dst->indirect_calls; edge; edge = edge->next_callee)
988
        {
989
          struct predicate new_predicate = true_predicate ();
990
          struct inline_edge_summary *es = inline_edge_summary (edge);
991
 
992
          if (!edge->inline_failed)
993
            inlined_to_p = true;
994
          if (!es->predicate)
995
            continue;
996
          for (j = 0; es->predicate->clause[j]; j++)
997
            if (!(possible_truths & es->predicate->clause[j]))
998
              {
999
                new_predicate = false_predicate ();
1000
                break;
1001
              }
1002
            else
1003
              add_clause (info->conds, &new_predicate,
1004
                          possible_truths & es->predicate->clause[j]);
1005
          if (false_predicate_p (&new_predicate)
1006
              && !false_predicate_p (es->predicate))
1007
            {
1008
              optimized_out_size += es->call_stmt_size * INLINE_SIZE_SCALE;
1009
              optimized_out_time += (es->call_stmt_time
1010
                                     * (INLINE_TIME_SCALE / CGRAPH_FREQ_BASE)
1011
                                     * edge->frequency);
1012
              edge->frequency = 0;
1013
            }
1014
          *es->predicate = new_predicate;
1015
        }
1016
 
1017
      /* If inliner or someone after inliner will ever start producing
1018
         non-trivial clones, we will get trouble with lack of information
1019
         about updating self sizes, because size vectors already contains
1020
         sizes of the calees.  */
1021
      gcc_assert (!inlined_to_p
1022
                  || (!optimized_out_size && !optimized_out_time));
1023
 
1024
      info->size -= optimized_out_size / INLINE_SIZE_SCALE;
1025
      info->self_size -= optimized_out_size / INLINE_SIZE_SCALE;
1026
      gcc_assert (info->size > 0);
1027
      gcc_assert (info->self_size > 0);
1028
 
1029
      optimized_out_time /= INLINE_TIME_SCALE;
1030
      if (optimized_out_time > MAX_TIME)
1031
        optimized_out_time = MAX_TIME;
1032
      info->time -= optimized_out_time;
1033
      info->self_time -= optimized_out_time;
1034
      if (info->time < 0)
1035
        info->time = 0;
1036
      if (info->self_time < 0)
1037
        info->self_time = 0;
1038
    }
1039
  else
1040
    info->entry = VEC_copy (size_time_entry, gc, info->entry);
1041
}
1042
 
1043
 
1044
/* Hook that is called by cgraph.c when a node is duplicated.  */
1045
 
1046
static void
1047
inline_edge_duplication_hook (struct cgraph_edge *src, struct cgraph_edge *dst,
1048
                              ATTRIBUTE_UNUSED void *data)
1049
{
1050
  struct inline_edge_summary *info;
1051
  struct inline_edge_summary *srcinfo;
1052
  inline_summary_alloc ();
1053
  info = inline_edge_summary (dst);
1054
  srcinfo = inline_edge_summary (src);
1055
  memcpy (info, srcinfo,
1056
          sizeof (struct inline_edge_summary));
1057
  info->predicate = NULL;
1058
  edge_set_predicate (dst, srcinfo->predicate);
1059
  info->param = VEC_copy (inline_param_summary_t, heap, srcinfo->param);
1060
}
1061
 
1062
 
1063
/* Keep edge cache consistent across edge removal.  */
1064
 
1065
static void
1066
inline_edge_removal_hook (struct cgraph_edge *edge, void *data ATTRIBUTE_UNUSED)
1067
{
1068
  if (edge_growth_cache)
1069
    reset_edge_growth_cache (edge);
1070
  reset_inline_edge_summary (edge);
1071
}
1072
 
1073
 
1074
/* Initialize growth caches.  */
1075
 
1076
void
1077
initialize_growth_caches (void)
1078
{
1079
  if (cgraph_edge_max_uid)
1080
    VEC_safe_grow_cleared (edge_growth_cache_entry, heap, edge_growth_cache,
1081
                           cgraph_edge_max_uid);
1082
  if (cgraph_max_uid)
1083
    VEC_safe_grow_cleared (int, heap, node_growth_cache, cgraph_max_uid);
1084
}
1085
 
1086
 
1087
/* Free growth caches.  */
1088
 
1089
void
1090
free_growth_caches (void)
1091
{
1092
  VEC_free (edge_growth_cache_entry, heap, edge_growth_cache);
1093
  edge_growth_cache = 0;
1094
  VEC_free (int, heap, node_growth_cache);
1095
  node_growth_cache = 0;
1096
}
1097
 
1098
 
1099
/* Dump edge summaries associated to NODE and recursively to all clones.
1100
   Indent by INDENT.  */
1101
 
1102
static void
1103
dump_inline_edge_summary (FILE * f, int indent, struct cgraph_node *node,
1104
                          struct inline_summary *info)
1105
{
1106
  struct cgraph_edge *edge;
1107
  for (edge = node->callees; edge; edge = edge->next_callee)
1108
    {
1109
      struct inline_edge_summary *es = inline_edge_summary (edge);
1110
      struct cgraph_node *callee = cgraph_function_or_thunk_node (edge->callee, NULL);
1111
      int i;
1112
 
1113
      fprintf (f, "%*s%s/%i %s\n%*s  loop depth:%2i freq:%4i size:%2i time: %2i callee size:%2i stack:%2i",
1114
               indent, "", cgraph_node_name (callee),
1115
               callee->uid,
1116
               !edge->inline_failed ? "inlined"
1117
               : cgraph_inline_failed_string (edge->inline_failed),
1118
               indent, "",
1119
               es->loop_depth,
1120
               edge->frequency,
1121
               es->call_stmt_size,
1122
               es->call_stmt_time,
1123
               (int)inline_summary (callee)->size / INLINE_SIZE_SCALE,
1124
               (int)inline_summary (callee)->estimated_stack_size);
1125
 
1126
      if (es->predicate)
1127
        {
1128
          fprintf (f, " predicate: ");
1129
          dump_predicate (f, info->conds, es->predicate);
1130
        }
1131
      else
1132
          fprintf (f, "\n");
1133
      if (es->param)
1134
        for (i = 0; i < (int)VEC_length (inline_param_summary_t, es->param);
1135
             i++)
1136
          {
1137
            int prob = VEC_index (inline_param_summary_t,
1138
                                  es->param, i)->change_prob;
1139
 
1140
            if (!prob)
1141
              fprintf (f, "%*s op%i is compile time invariant\n",
1142
                       indent + 2, "", i);
1143
            else if (prob != REG_BR_PROB_BASE)
1144
              fprintf (f, "%*s op%i change %f%% of time\n", indent + 2, "", i,
1145
                       prob * 100.0 / REG_BR_PROB_BASE);
1146
          }
1147
      if (!edge->inline_failed)
1148
        {
1149
          fprintf (f, "%*sStack frame offset %i, callee self size %i,"
1150
                   " callee size %i\n",
1151
                   indent+2, "",
1152
                   (int)inline_summary (callee)->stack_frame_offset,
1153
                   (int)inline_summary (callee)->estimated_self_stack_size,
1154
                   (int)inline_summary (callee)->estimated_stack_size);
1155
          dump_inline_edge_summary (f, indent+2, callee, info);
1156
        }
1157
    }
1158
  for (edge = node->indirect_calls; edge; edge = edge->next_callee)
1159
    {
1160
      struct inline_edge_summary *es = inline_edge_summary (edge);
1161
      fprintf (f, "%*sindirect call loop depth:%2i freq:%4i size:%2i"
1162
               " time: %2i",
1163
               indent, "",
1164
               es->loop_depth,
1165
               edge->frequency,
1166
               es->call_stmt_size,
1167
               es->call_stmt_time);
1168
      if (es->predicate)
1169
        {
1170
          fprintf (f, "predicate: ");
1171
          dump_predicate (f, info->conds, es->predicate);
1172
        }
1173
      else
1174
        fprintf (f, "\n");
1175
    }
1176
}
1177
 
1178
 
1179
void
1180
dump_inline_summary (FILE * f, struct cgraph_node *node)
1181
{
1182
  if (node->analyzed)
1183
    {
1184
      struct inline_summary *s = inline_summary (node);
1185
      size_time_entry *e;
1186
      int i;
1187
      fprintf (f, "Inline summary for %s/%i", cgraph_node_name (node),
1188
               node->uid);
1189
      if (DECL_DISREGARD_INLINE_LIMITS (node->decl))
1190
        fprintf (f, " always_inline");
1191
      if (s->inlinable)
1192
        fprintf (f, " inlinable");
1193
      fprintf (f, "\n  self time:       %i\n",
1194
               s->self_time);
1195
      fprintf (f, "  global time:     %i\n", s->time);
1196
      fprintf (f, "  self size:       %i\n",
1197
               s->self_size);
1198
      fprintf (f, "  global size:     %i\n", s->size);
1199
      fprintf (f, "  self stack:      %i\n",
1200
               (int) s->estimated_self_stack_size);
1201
      fprintf (f, "  global stack:    %i\n",
1202
               (int) s->estimated_stack_size);
1203
      for (i = 0;
1204
           VEC_iterate (size_time_entry, s->entry, i, e);
1205
           i++)
1206
        {
1207
          fprintf (f, "    size:%f, time:%f, predicate:",
1208
                   (double) e->size / INLINE_SIZE_SCALE,
1209
                   (double) e->time / INLINE_TIME_SCALE);
1210
          dump_predicate (f, s->conds, &e->predicate);
1211
        }
1212
      fprintf (f, "  calls:\n");
1213
      dump_inline_edge_summary (f, 4, node, s);
1214
      fprintf (f, "\n");
1215
    }
1216
}
1217
 
1218
DEBUG_FUNCTION void
1219
debug_inline_summary (struct cgraph_node *node)
1220
{
1221
  dump_inline_summary (stderr, node);
1222
}
1223
 
1224
void
1225
dump_inline_summaries (FILE *f)
1226
{
1227
  struct cgraph_node *node;
1228
 
1229
  for (node = cgraph_nodes; node; node = node->next)
1230
    if (node->analyzed && !node->global.inlined_to)
1231
      dump_inline_summary (f, node);
1232
}
1233
 
1234
/* Give initial reasons why inlining would fail on EDGE.  This gets either
1235
   nullified or usually overwritten by more precise reasons later.  */
1236
 
1237
void
1238
initialize_inline_failed (struct cgraph_edge *e)
1239
{
1240
  struct cgraph_node *callee = e->callee;
1241
 
1242
  if (e->indirect_unknown_callee)
1243
    e->inline_failed = CIF_INDIRECT_UNKNOWN_CALL;
1244
  else if (!callee->analyzed)
1245
    e->inline_failed = CIF_BODY_NOT_AVAILABLE;
1246
  else if (callee->local.redefined_extern_inline)
1247
    e->inline_failed = CIF_REDEFINED_EXTERN_INLINE;
1248
  else if (e->call_stmt_cannot_inline_p)
1249
    e->inline_failed = CIF_MISMATCHED_ARGUMENTS;
1250
  else
1251
    e->inline_failed = CIF_FUNCTION_NOT_CONSIDERED;
1252
}
1253
 
1254
/* Callback of walk_aliased_vdefs.  Flags that it has been invoked to the
1255
   boolean variable pointed to by DATA.  */
1256
 
1257
static bool
1258
mark_modified (ao_ref *ao ATTRIBUTE_UNUSED, tree vdef ATTRIBUTE_UNUSED,
1259
                     void *data)
1260
{
1261
  bool *b = (bool *) data;
1262
  *b = true;
1263
  return true;
1264
}
1265
 
1266
/* If OP reffers to value of function parameter, return
1267
   the corresponding parameter.  */
1268
 
1269
static tree
1270
unmodified_parm (gimple stmt, tree op)
1271
{
1272
  /* SSA_NAME referring to parm default def?  */
1273
  if (TREE_CODE (op) == SSA_NAME
1274
      && SSA_NAME_IS_DEFAULT_DEF (op)
1275
      && TREE_CODE (SSA_NAME_VAR (op)) == PARM_DECL)
1276
    return SSA_NAME_VAR (op);
1277
  /* Non-SSA parm reference?  */
1278
  if (TREE_CODE (op) == PARM_DECL)
1279
    {
1280
      bool modified = false;
1281
 
1282
      ao_ref refd;
1283
      ao_ref_init (&refd, op);
1284
      walk_aliased_vdefs (&refd, gimple_vuse (stmt), mark_modified, &modified,
1285
                          NULL);
1286
      if (!modified)
1287
        return op;
1288
    }
1289
  /* Assignment from a parameter?  */
1290
  if (TREE_CODE (op) == SSA_NAME
1291
      && !SSA_NAME_IS_DEFAULT_DEF (op)
1292
      && gimple_assign_single_p (SSA_NAME_DEF_STMT (op)))
1293
    return unmodified_parm (SSA_NAME_DEF_STMT (op),
1294
                            gimple_assign_rhs1 (SSA_NAME_DEF_STMT (op)));
1295
  return NULL;
1296
}
1297
 
1298
/* See if statement might disappear after inlining.
1299
 
1300
   1 - half of statements goes away
1301
   2 - for sure it is eliminated.
1302
   We are not terribly sophisticated, basically looking for simple abstraction
1303
   penalty wrappers.  */
1304
 
1305
static int
1306
eliminated_by_inlining_prob (gimple stmt)
1307
{
1308
  enum gimple_code code = gimple_code (stmt);
1309
 
1310
  if (!optimize)
1311
    return 0;
1312
 
1313
  switch (code)
1314
    {
1315
      case GIMPLE_RETURN:
1316
        return 2;
1317
      case GIMPLE_ASSIGN:
1318
        if (gimple_num_ops (stmt) != 2)
1319
          return 0;
1320
 
1321
        /* Casts of parameters, loads from parameters passed by reference
1322
           and stores to return value or parameters are often free after
1323
           inlining dua to SRA and further combining.
1324
           Assume that half of statements goes away.  */
1325
        if (gimple_assign_rhs_code (stmt) == CONVERT_EXPR
1326
            || gimple_assign_rhs_code (stmt) == NOP_EXPR
1327
            || gimple_assign_rhs_code (stmt) == VIEW_CONVERT_EXPR
1328
            || gimple_assign_rhs_class (stmt) == GIMPLE_SINGLE_RHS)
1329
          {
1330
            tree rhs = gimple_assign_rhs1 (stmt);
1331
            tree lhs = gimple_assign_lhs (stmt);
1332
            tree inner_rhs = get_base_address (rhs);
1333
            tree inner_lhs = get_base_address (lhs);
1334
            bool rhs_free = false;
1335
            bool lhs_free = false;
1336
 
1337
            if (!inner_rhs)
1338
              inner_rhs = rhs;
1339
            if (!inner_lhs)
1340
              inner_lhs = lhs;
1341
 
1342
            /* Reads of parameter are expected to be free.  */
1343
            if (unmodified_parm (stmt, inner_rhs))
1344
              rhs_free = true;
1345
 
1346
            /* When parameter is not SSA register because its address is taken
1347
               and it is just copied into one, the statement will be completely
1348
               free after inlining (we will copy propagate backward).   */
1349
            if (rhs_free && is_gimple_reg (lhs))
1350
              return 2;
1351
 
1352
            /* Reads of parameters passed by reference
1353
               expected to be free (i.e. optimized out after inlining).  */
1354
            if (TREE_CODE(inner_rhs) == MEM_REF
1355
                && unmodified_parm (stmt, TREE_OPERAND (inner_rhs, 0)))
1356
              rhs_free = true;
1357
 
1358
            /* Copying parameter passed by reference into gimple register is
1359
               probably also going to copy propagate, but we can't be quite
1360
               sure.  */
1361
            if (rhs_free && is_gimple_reg (lhs))
1362
              lhs_free = true;
1363
 
1364
            /* Writes to parameters, parameters passed by value and return value
1365
               (either dirrectly or passed via invisible reference) are free.
1366
 
1367
               TODO: We ought to handle testcase like
1368
               struct a {int a,b;};
1369
               struct a
1370
               retrurnsturct (void)
1371
                 {
1372
                   struct a a ={1,2};
1373
                   return a;
1374
                 }
1375
 
1376
               This translate into:
1377
 
1378
               retrurnsturct ()
1379
                 {
1380
                   int a$b;
1381
                   int a$a;
1382
                   struct a a;
1383
                   struct a D.2739;
1384
 
1385
                 <bb 2>:
1386
                   D.2739.a = 1;
1387
                   D.2739.b = 2;
1388
                   return D.2739;
1389
 
1390
                 }
1391
               For that we either need to copy ipa-split logic detecting writes
1392
               to return value.  */
1393
            if (TREE_CODE (inner_lhs) == PARM_DECL
1394
                || TREE_CODE (inner_lhs) == RESULT_DECL
1395
                || (TREE_CODE(inner_lhs) == MEM_REF
1396
                     && (unmodified_parm (stmt, TREE_OPERAND (inner_lhs, 0))
1397
                         || (TREE_CODE (TREE_OPERAND (inner_lhs, 0)) == SSA_NAME
1398
                             && TREE_CODE (SSA_NAME_VAR
1399
                                            (TREE_OPERAND (inner_lhs, 0)))
1400
                             == RESULT_DECL))))
1401
              lhs_free = true;
1402
            if (lhs_free
1403
                && (is_gimple_reg (rhs) || is_gimple_min_invariant (rhs)))
1404
              rhs_free = true;
1405
            if (lhs_free && rhs_free)
1406
              return 1;
1407
          }
1408
        return 0;
1409
      default:
1410
        return 0;
1411
    }
1412
}
1413
 
1414
 
1415
/* If BB ends by a conditional we can turn into predicates, attach corresponding
1416
   predicates to the CFG edges.   */
1417
 
1418
static void
1419
set_cond_stmt_execution_predicate (struct ipa_node_params *info,
1420
                                   struct inline_summary *summary,
1421
                                   basic_block bb)
1422
{
1423
  gimple last;
1424
  tree op;
1425
  int index;
1426
  enum tree_code code, inverted_code;
1427
  edge e;
1428
  edge_iterator ei;
1429
  gimple set_stmt;
1430
  tree op2;
1431
  tree parm;
1432
  tree base;
1433
 
1434
  last = last_stmt (bb);
1435
  if (!last
1436
      || gimple_code (last) != GIMPLE_COND)
1437
    return;
1438
  if (!is_gimple_ip_invariant (gimple_cond_rhs (last)))
1439
    return;
1440
  op = gimple_cond_lhs (last);
1441
  /* TODO: handle conditionals like
1442
     var = op0 < 4;
1443
     if (var != 0).  */
1444
  parm = unmodified_parm (last, op);
1445
  if (parm)
1446
    {
1447
      index = ipa_get_param_decl_index (info, parm);
1448
      if (index == -1)
1449
        return;
1450
      code = gimple_cond_code (last);
1451
      inverted_code
1452
         = invert_tree_comparison (code,
1453
                                   HONOR_NANS (TYPE_MODE (TREE_TYPE (op))));
1454
 
1455
      FOR_EACH_EDGE (e, ei, bb->succs)
1456
        {
1457
          struct predicate p = add_condition (summary,
1458
                                              index,
1459
                                              e->flags & EDGE_TRUE_VALUE
1460
                                              ? code : inverted_code,
1461
                                              gimple_cond_rhs (last));
1462
          e->aux = pool_alloc (edge_predicate_pool);
1463
          *(struct predicate *)e->aux = p;
1464
        }
1465
    }
1466
 
1467
  if (TREE_CODE (op) != SSA_NAME)
1468
    return;
1469
  /* Special case
1470
     if (builtin_constant_p (op))
1471
       constant_code
1472
     else
1473
       nonconstant_code.
1474
     Here we can predicate nonconstant_code.  We can't
1475
     really handle constant_code since we have no predicate
1476
     for this and also the constant code is not known to be
1477
     optimized away when inliner doen't see operand is constant.
1478
     Other optimizers might think otherwise.  */
1479
  set_stmt = SSA_NAME_DEF_STMT (op);
1480
  if (!gimple_call_builtin_p (set_stmt, BUILT_IN_CONSTANT_P)
1481
      || gimple_call_num_args (set_stmt) != 1)
1482
    return;
1483
  op2 = gimple_call_arg (set_stmt, 0);
1484
  base = get_base_address (op2);
1485
  parm = unmodified_parm (set_stmt, base ? base : op2);
1486
  if (!parm)
1487
    return;
1488
  index = ipa_get_param_decl_index (info, parm);
1489
  if (index == -1)
1490
    return;
1491
  if (gimple_cond_code (last) != NE_EXPR
1492
      || !integer_zerop (gimple_cond_rhs (last)))
1493
    return;
1494
  FOR_EACH_EDGE (e, ei, bb->succs)
1495
    if (e->flags & EDGE_FALSE_VALUE)
1496
      {
1497
        struct predicate p = add_condition (summary,
1498
                                            index,
1499
                                            IS_NOT_CONSTANT,
1500
                                            NULL);
1501
        e->aux = pool_alloc (edge_predicate_pool);
1502
        *(struct predicate *)e->aux = p;
1503
      }
1504
}
1505
 
1506
 
1507
/* If BB ends by a switch we can turn into predicates, attach corresponding
1508
   predicates to the CFG edges.   */
1509
 
1510
static void
1511
set_switch_stmt_execution_predicate (struct ipa_node_params *info,
1512
                                   struct inline_summary *summary,
1513
                                   basic_block bb)
1514
{
1515
  gimple last;
1516
  tree op;
1517
  int index;
1518
  edge e;
1519
  edge_iterator ei;
1520
  size_t n;
1521
  size_t case_idx;
1522
  tree parm;
1523
 
1524
  last = last_stmt (bb);
1525
  if (!last
1526
      || gimple_code (last) != GIMPLE_SWITCH)
1527
    return;
1528
  op = gimple_switch_index (last);
1529
  parm = unmodified_parm (last, op);
1530
  if (!parm)
1531
    return;
1532
  index = ipa_get_param_decl_index (info, parm);
1533
  if (index == -1)
1534
    return;
1535
 
1536
  FOR_EACH_EDGE (e, ei, bb->succs)
1537
    {
1538
      e->aux = pool_alloc (edge_predicate_pool);
1539
      *(struct predicate *)e->aux = false_predicate ();
1540
    }
1541
  n = gimple_switch_num_labels(last);
1542
  for (case_idx = 0; case_idx < n; ++case_idx)
1543
    {
1544
      tree cl = gimple_switch_label (last, case_idx);
1545
      tree min, max;
1546
      struct predicate p;
1547
 
1548
      e = find_edge (bb, label_to_block (CASE_LABEL (cl)));
1549
      min = CASE_LOW (cl);
1550
      max = CASE_HIGH (cl);
1551
 
1552
      /* For default we might want to construct predicate that none
1553
         of cases is met, but it is bit hard to do not having negations
1554
         of conditionals handy.  */
1555
      if (!min && !max)
1556
        p = true_predicate ();
1557
      else if (!max)
1558
        p = add_condition (summary, index,
1559
                           EQ_EXPR,
1560
                           min);
1561
      else
1562
        {
1563
          struct predicate p1, p2;
1564
          p1 = add_condition (summary, index,
1565
                              GE_EXPR,
1566
                              min);
1567
          p2 = add_condition (summary, index,
1568
                              LE_EXPR,
1569
                              max);
1570
          p = and_predicates (summary->conds, &p1, &p2);
1571
        }
1572
      *(struct predicate *)e->aux
1573
        = or_predicates (summary->conds, &p, (struct predicate *)e->aux);
1574
    }
1575
}
1576
 
1577
 
1578
/* For each BB in NODE attach to its AUX pointer predicate under
1579
   which it is executable.  */
1580
 
1581
static void
1582
compute_bb_predicates (struct cgraph_node *node,
1583
                       struct ipa_node_params *parms_info,
1584
                       struct inline_summary *summary)
1585
{
1586
  struct function *my_function = DECL_STRUCT_FUNCTION (node->decl);
1587
  bool done = false;
1588
  basic_block bb;
1589
 
1590
  FOR_EACH_BB_FN (bb, my_function)
1591
    {
1592
      set_cond_stmt_execution_predicate (parms_info, summary, bb);
1593
      set_switch_stmt_execution_predicate (parms_info, summary, bb);
1594
    }
1595
 
1596
  /* Entry block is always executable.  */
1597
  ENTRY_BLOCK_PTR_FOR_FUNCTION (my_function)->aux
1598
    = pool_alloc (edge_predicate_pool);
1599
  *(struct predicate *)ENTRY_BLOCK_PTR_FOR_FUNCTION (my_function)->aux
1600
    = true_predicate ();
1601
 
1602
  /* A simple dataflow propagation of predicates forward in the CFG.
1603
     TODO: work in reverse postorder.  */
1604
  while (!done)
1605
    {
1606
      done = true;
1607
      FOR_EACH_BB_FN (bb, my_function)
1608
        {
1609
          struct predicate p = false_predicate ();
1610
          edge e;
1611
          edge_iterator ei;
1612
          FOR_EACH_EDGE (e, ei, bb->preds)
1613
            {
1614
              if (e->src->aux)
1615
                {
1616
                  struct predicate this_bb_predicate
1617
                     = *(struct predicate *)e->src->aux;
1618
                  if (e->aux)
1619
                    this_bb_predicate
1620
                       = and_predicates (summary->conds, &this_bb_predicate,
1621
                                         (struct predicate *)e->aux);
1622
                  p = or_predicates (summary->conds, &p, &this_bb_predicate);
1623
                  if (true_predicate_p (&p))
1624
                    break;
1625
                }
1626
            }
1627
          if (false_predicate_p (&p))
1628
            gcc_assert (!bb->aux);
1629
          else
1630
            {
1631
              if (!bb->aux)
1632
                {
1633
                  done = false;
1634
                  bb->aux = pool_alloc (edge_predicate_pool);
1635
                  *((struct predicate *)bb->aux) = p;
1636
                }
1637
              else if (!predicates_equal_p (&p, (struct predicate *)bb->aux))
1638
                {
1639
                  done = false;
1640
                  *((struct predicate *)bb->aux) = p;
1641
                }
1642
            }
1643
        }
1644
    }
1645
}
1646
 
1647
 
1648
/* We keep info about constantness of SSA names.  */
1649
 
1650
typedef struct predicate predicate_t;
1651
DEF_VEC_O (predicate_t);
1652
DEF_VEC_ALLOC_O (predicate_t, heap);
1653
 
1654
 
1655
/* Return predicate specifying when the STMT might have result that is not
1656
   a compile time constant.  */
1657
 
1658
static struct predicate
1659
will_be_nonconstant_predicate (struct ipa_node_params *info,
1660
                               struct inline_summary *summary,
1661
                               gimple stmt,
1662
                               VEC (predicate_t, heap) *nonconstant_names)
1663
 
1664
{
1665
  struct predicate p = true_predicate ();
1666
  ssa_op_iter iter;
1667
  tree use;
1668
  struct predicate op_non_const;
1669
  bool is_load;
1670
 
1671
  /* What statments might be optimized away
1672
     when their arguments are constant
1673
     TODO: also trivial builtins.
1674
     builtin_constant_p is already handled later.  */
1675
  if (gimple_code (stmt) != GIMPLE_ASSIGN
1676
      && gimple_code (stmt) != GIMPLE_COND
1677
      && gimple_code (stmt) != GIMPLE_SWITCH)
1678
    return p;
1679
 
1680
  /* Stores will stay anyway.  */
1681
  if (gimple_vdef (stmt))
1682
    return p;
1683
 
1684
  is_load = gimple_vuse (stmt) != NULL;
1685
 
1686
  /* Loads can be optimized when the value is known.  */
1687
  if (is_load)
1688
    {
1689
      tree op = gimple_assign_rhs1 (stmt);
1690
      tree base = get_base_address (op);
1691
      tree parm;
1692
 
1693
      gcc_assert (gimple_assign_single_p (stmt));
1694
      if (!base)
1695
        return p;
1696
      parm = unmodified_parm (stmt, base);
1697
      if (!parm )
1698
        return p;
1699
      if (ipa_get_param_decl_index (info, parm) < 0)
1700
        return p;
1701
    }
1702
 
1703
  /* See if we understand all operands before we start
1704
     adding conditionals.  */
1705
  FOR_EACH_SSA_TREE_OPERAND (use, stmt, iter, SSA_OP_USE)
1706
    {
1707
      tree parm = unmodified_parm (stmt, use);
1708
      /* For arguments we can build a condition.  */
1709
      if (parm && ipa_get_param_decl_index (info, parm) >= 0)
1710
        continue;
1711
      if (TREE_CODE (use) != SSA_NAME)
1712
        return p;
1713
      /* If we know when operand is constant,
1714
         we still can say something useful.  */
1715
      if (!true_predicate_p (VEC_index (predicate_t, nonconstant_names,
1716
                                        SSA_NAME_VERSION (use))))
1717
        continue;
1718
      return p;
1719
    }
1720
  op_non_const = false_predicate ();
1721
  if (is_load)
1722
    {
1723
      tree parm = unmodified_parm
1724
                    (stmt, get_base_address (gimple_assign_rhs1 (stmt)));
1725
      p = add_condition (summary,
1726
                         ipa_get_param_decl_index (info, parm),
1727
                         CHANGED, NULL);
1728
      op_non_const = or_predicates (summary->conds, &p, &op_non_const);
1729
    }
1730
  FOR_EACH_SSA_TREE_OPERAND (use, stmt, iter, SSA_OP_USE)
1731
    {
1732
      tree parm = unmodified_parm (stmt, use);
1733
      if (parm && ipa_get_param_decl_index (info, parm) >= 0)
1734
        p = add_condition (summary,
1735
                           ipa_get_param_decl_index (info, parm),
1736
                           CHANGED, NULL);
1737
      else
1738
        p = *VEC_index (predicate_t, nonconstant_names,
1739
                        SSA_NAME_VERSION (use));
1740
      op_non_const = or_predicates (summary->conds, &p, &op_non_const);
1741
    }
1742
  if (gimple_code (stmt) == GIMPLE_ASSIGN
1743
      && TREE_CODE (gimple_assign_lhs (stmt)) == SSA_NAME)
1744
    VEC_replace (predicate_t, nonconstant_names,
1745
                 SSA_NAME_VERSION (gimple_assign_lhs (stmt)), &op_non_const);
1746
  return op_non_const;
1747
}
1748
 
1749
struct record_modified_bb_info
1750
{
1751
  bitmap bb_set;
1752
  gimple stmt;
1753
};
1754
 
1755
/* Callback of walk_aliased_vdefs.  Records basic blocks where the value may be
1756
   set except for info->stmt.  */
1757
 
1758
static bool
1759
record_modified (ao_ref *ao ATTRIBUTE_UNUSED, tree vdef,
1760
                 void *data)
1761
{
1762
  struct record_modified_bb_info *info = (struct record_modified_bb_info *) data;
1763
  if (SSA_NAME_DEF_STMT (vdef) == info->stmt)
1764
    return false;
1765
  bitmap_set_bit (info->bb_set,
1766
                  SSA_NAME_IS_DEFAULT_DEF (vdef)
1767
                  ? ENTRY_BLOCK_PTR->index : gimple_bb (SSA_NAME_DEF_STMT (vdef))->index);
1768
  return false;
1769
}
1770
 
1771
/* Return probability (based on REG_BR_PROB_BASE) that I-th parameter of STMT
1772
   will change since last invocation of STMT.
1773
 
1774
   Value 0 is reserved for compile time invariants.
1775
   For common parameters it is REG_BR_PROB_BASE.  For loop invariants it
1776
   ought to be REG_BR_PROB_BASE / estimated_iters.  */
1777
 
1778
static int
1779
param_change_prob (gimple stmt, int i)
1780
{
1781
  tree op = gimple_call_arg (stmt, i);
1782
  basic_block bb = gimple_bb (stmt);
1783
  tree base;
1784
 
1785
  if (is_gimple_min_invariant (op))
1786
    return 0;
1787
  /* We would have to do non-trivial analysis to really work out what
1788
     is the probability of value to change (i.e. when init statement
1789
     is in a sibling loop of the call).
1790
 
1791
     We do an conservative estimate: when call is executed N times more often
1792
     than the statement defining value, we take the frequency 1/N.  */
1793
  if (TREE_CODE (op) == SSA_NAME)
1794
    {
1795
      int init_freq;
1796
 
1797
      if (!bb->frequency)
1798
        return REG_BR_PROB_BASE;
1799
 
1800
      if (SSA_NAME_IS_DEFAULT_DEF (op))
1801
        init_freq = ENTRY_BLOCK_PTR->frequency;
1802
      else
1803
        init_freq = gimple_bb (SSA_NAME_DEF_STMT (op))->frequency;
1804
 
1805
      if (!init_freq)
1806
        init_freq = 1;
1807
      if (init_freq < bb->frequency)
1808
        return MAX ((init_freq * REG_BR_PROB_BASE +
1809
                    bb->frequency / 2) / bb->frequency, 1);
1810
      else
1811
        return REG_BR_PROB_BASE;
1812
    }
1813
 
1814
  base = get_base_address (op);
1815
  if (base)
1816
    {
1817
      ao_ref refd;
1818
      int max;
1819
      struct record_modified_bb_info info;
1820
      bitmap_iterator bi;
1821
      unsigned index;
1822
 
1823
      if (const_value_known_p (base))
1824
        return 0;
1825
      if (!bb->frequency)
1826
        return REG_BR_PROB_BASE;
1827
      ao_ref_init (&refd, op);
1828
      info.stmt = stmt;
1829
      info.bb_set = BITMAP_ALLOC (NULL);
1830
      walk_aliased_vdefs (&refd, gimple_vuse (stmt), record_modified, &info,
1831
                          NULL);
1832
      if (bitmap_bit_p (info.bb_set, bb->index))
1833
        {
1834
          BITMAP_FREE (info.bb_set);
1835
          return REG_BR_PROB_BASE;
1836
        }
1837
 
1838
      /* Assume that every memory is initialized at entry.
1839
         TODO: Can we easilly determine if value is always defined
1840
         and thus we may skip entry block?  */
1841
      if (ENTRY_BLOCK_PTR->frequency)
1842
        max = ENTRY_BLOCK_PTR->frequency;
1843
      else
1844
        max = 1;
1845
 
1846
      EXECUTE_IF_SET_IN_BITMAP (info.bb_set, 0, index, bi)
1847
        max = MIN (max, BASIC_BLOCK (index)->frequency);
1848
 
1849
      BITMAP_FREE (info.bb_set);
1850
      if (max < bb->frequency)
1851
        return MAX ((max * REG_BR_PROB_BASE +
1852
                     bb->frequency / 2) / bb->frequency, 1);
1853
      else
1854
        return REG_BR_PROB_BASE;
1855
    }
1856
  return REG_BR_PROB_BASE;
1857
}
1858
 
1859
 
1860
/* Compute function body size parameters for NODE.
1861
   When EARLY is true, we compute only simple summaries without
1862
   non-trivial predicates to drive the early inliner.  */
1863
 
1864
static void
1865
estimate_function_body_sizes (struct cgraph_node *node, bool early)
1866
{
1867
  gcov_type time = 0;
1868
  /* Estimate static overhead for function prologue/epilogue and alignment. */
1869
  int size = 2;
1870
  /* Benefits are scaled by probability of elimination that is in range
1871
     <0,2>.  */
1872
  basic_block bb;
1873
  gimple_stmt_iterator bsi;
1874
  struct function *my_function = DECL_STRUCT_FUNCTION (node->decl);
1875
  int freq;
1876
  struct inline_summary *info = inline_summary (node);
1877
  struct predicate bb_predicate;
1878
  struct ipa_node_params *parms_info = NULL;
1879
  VEC (predicate_t, heap) *nonconstant_names = NULL;
1880
 
1881
  if (ipa_node_params_vector && !early && optimize)
1882
    {
1883
      parms_info = IPA_NODE_REF (node);
1884
      VEC_safe_grow_cleared (predicate_t, heap, nonconstant_names,
1885
                             VEC_length (tree, SSANAMES (my_function)));
1886
    }
1887
 
1888
  info->conds = 0;
1889
  info->entry = 0;
1890
 
1891
 
1892
  if (dump_file)
1893
    fprintf (dump_file, "\nAnalyzing function body size: %s\n",
1894
             cgraph_node_name (node));
1895
 
1896
  /* When we run into maximal number of entries, we assign everything to the
1897
     constant truth case.  Be sure to have it in list. */
1898
  bb_predicate = true_predicate ();
1899
  account_size_time (info, 0, 0, &bb_predicate);
1900
 
1901
  bb_predicate = not_inlined_predicate ();
1902
  account_size_time (info, 2 * INLINE_SIZE_SCALE, 0, &bb_predicate);
1903
 
1904
  gcc_assert (my_function && my_function->cfg);
1905
  if (parms_info)
1906
    compute_bb_predicates (node, parms_info, info);
1907
  FOR_EACH_BB_FN (bb, my_function)
1908
    {
1909
      freq = compute_call_stmt_bb_frequency (node->decl, bb);
1910
 
1911
      /* TODO: Obviously predicates can be propagated down across CFG.  */
1912
      if (parms_info)
1913
        {
1914
          if (bb->aux)
1915
            bb_predicate = *(struct predicate *)bb->aux;
1916
          else
1917
            bb_predicate = false_predicate ();
1918
        }
1919
      else
1920
        bb_predicate = true_predicate ();
1921
 
1922
      if (dump_file && (dump_flags & TDF_DETAILS))
1923
        {
1924
          fprintf (dump_file, "\n BB %i predicate:", bb->index);
1925
          dump_predicate (dump_file, info->conds, &bb_predicate);
1926
        }
1927
 
1928
      for (bsi = gsi_start_bb (bb); !gsi_end_p (bsi); gsi_next (&bsi))
1929
        {
1930
          gimple stmt = gsi_stmt (bsi);
1931
          int this_size = estimate_num_insns (stmt, &eni_size_weights);
1932
          int this_time = estimate_num_insns (stmt, &eni_time_weights);
1933
          int prob;
1934
          struct predicate will_be_nonconstant;
1935
 
1936
          if (dump_file && (dump_flags & TDF_DETAILS))
1937
            {
1938
              fprintf (dump_file, "  ");
1939
              print_gimple_stmt (dump_file, stmt, 0, 0);
1940
              fprintf (dump_file, "\t\tfreq:%3.2f size:%3i time:%3i\n",
1941
                       ((double)freq)/CGRAPH_FREQ_BASE, this_size, this_time);
1942
            }
1943
 
1944
          if (is_gimple_call (stmt))
1945
            {
1946
              struct cgraph_edge *edge = cgraph_edge (node, stmt);
1947
              struct inline_edge_summary *es = inline_edge_summary (edge);
1948
 
1949
              /* Special case: results of BUILT_IN_CONSTANT_P will be always
1950
                 resolved as constant.  We however don't want to optimize
1951
                 out the cgraph edges.  */
1952
              if (nonconstant_names
1953
                  && gimple_call_builtin_p (stmt, BUILT_IN_CONSTANT_P)
1954
                  && gimple_call_lhs (stmt)
1955
                  && TREE_CODE (gimple_call_lhs (stmt)) == SSA_NAME)
1956
                {
1957
                  struct predicate false_p = false_predicate ();
1958
                  VEC_replace (predicate_t, nonconstant_names,
1959
                               SSA_NAME_VERSION (gimple_call_lhs (stmt)),
1960
                               &false_p);
1961
                }
1962
              if (ipa_node_params_vector)
1963
                {
1964
                  int count = gimple_call_num_args (stmt);
1965
                  int i;
1966
 
1967
                  if (count)
1968
                    VEC_safe_grow_cleared (inline_param_summary_t, heap,
1969
                                           es->param, count);
1970
                  for (i = 0; i < count; i++)
1971
                    {
1972
                      int prob = param_change_prob (stmt, i);
1973
                      gcc_assert (prob >= 0 && prob <= REG_BR_PROB_BASE);
1974
                      VEC_index (inline_param_summary_t,
1975
                                 es->param, i)->change_prob = prob;
1976
                    }
1977
                }
1978
 
1979
              es->call_stmt_size = this_size;
1980
              es->call_stmt_time = this_time;
1981
              es->loop_depth = bb->loop_depth;
1982
              edge_set_predicate (edge, &bb_predicate);
1983
            }
1984
 
1985
          /* TODO: When conditional jump or swithc is known to be constant, but
1986
             we did not translate it into the predicates, we really can account
1987
             just maximum of the possible paths.  */
1988
          if (parms_info)
1989
            will_be_nonconstant
1990
               = will_be_nonconstant_predicate (parms_info, info,
1991
                                                stmt, nonconstant_names);
1992
          if (this_time || this_size)
1993
            {
1994
              struct predicate p;
1995
 
1996
              this_time *= freq;
1997
              time += this_time;
1998
              size += this_size;
1999
 
2000
              prob = eliminated_by_inlining_prob (stmt);
2001
              if (prob == 1 && dump_file && (dump_flags & TDF_DETAILS))
2002
                fprintf (dump_file, "\t\t50%% will be eliminated by inlining\n");
2003
              if (prob == 2 && dump_file && (dump_flags & TDF_DETAILS))
2004
                fprintf (dump_file, "\t\tWill be eliminated by inlining\n");
2005
 
2006
              if (parms_info)
2007
                p = and_predicates (info->conds, &bb_predicate,
2008
                                    &will_be_nonconstant);
2009
              else
2010
                p = true_predicate ();
2011
 
2012
              /* We account everything but the calls.  Calls have their own
2013
                 size/time info attached to cgraph edges.  This is neccesary
2014
                 in order to make the cost disappear after inlining.  */
2015
              if (!is_gimple_call (stmt))
2016
                {
2017
                  if (prob)
2018
                    {
2019
                      struct predicate ip = not_inlined_predicate ();
2020
                      ip = and_predicates (info->conds, &ip, &p);
2021
                      account_size_time (info, this_size * prob,
2022
                                         this_time * prob, &ip);
2023
                    }
2024
                  if (prob != 2)
2025
                    account_size_time (info, this_size * (2 - prob),
2026
                                       this_time * (2 - prob), &p);
2027
                }
2028
 
2029
              gcc_assert (time >= 0);
2030
              gcc_assert (size >= 0);
2031
            }
2032
        }
2033
    }
2034
  FOR_ALL_BB_FN (bb, my_function)
2035
    {
2036
      edge e;
2037
      edge_iterator ei;
2038
 
2039
      if (bb->aux)
2040
        pool_free (edge_predicate_pool, bb->aux);
2041
      bb->aux = NULL;
2042
      FOR_EACH_EDGE (e, ei, bb->succs)
2043
        {
2044
          if (e->aux)
2045
            pool_free (edge_predicate_pool, e->aux);
2046
          e->aux = NULL;
2047
        }
2048
    }
2049
  time = (time + CGRAPH_FREQ_BASE / 2) / CGRAPH_FREQ_BASE;
2050
  if (time > MAX_TIME)
2051
    time = MAX_TIME;
2052
  inline_summary (node)->self_time = time;
2053
  inline_summary (node)->self_size = size;
2054
  VEC_free (predicate_t, heap, nonconstant_names);
2055
  if (dump_file)
2056
    {
2057
      fprintf (dump_file, "\n");
2058
      dump_inline_summary (dump_file, node);
2059
    }
2060
}
2061
 
2062
 
2063
/* Compute parameters of functions used by inliner.
2064
   EARLY is true when we compute parameters for the early inliner  */
2065
 
2066
void
2067
compute_inline_parameters (struct cgraph_node *node, bool early)
2068
{
2069
  HOST_WIDE_INT self_stack_size;
2070
  struct cgraph_edge *e;
2071
  struct inline_summary *info;
2072
  tree old_decl = current_function_decl;
2073
 
2074
  gcc_assert (!node->global.inlined_to);
2075
 
2076
  inline_summary_alloc ();
2077
 
2078
  info = inline_summary (node);
2079
  reset_inline_summary (node);
2080
 
2081
  /* FIXME: Thunks are inlinable, but tree-inline don't know how to do that.
2082
     Once this happen, we will need to more curefully predict call
2083
     statement size.  */
2084
  if (node->thunk.thunk_p)
2085
    {
2086
      struct inline_edge_summary *es = inline_edge_summary (node->callees);
2087
      struct predicate t = true_predicate ();
2088
 
2089
      info->inlinable = 0;
2090
      node->callees->call_stmt_cannot_inline_p = true;
2091
      node->local.can_change_signature = false;
2092
      es->call_stmt_time = 1;
2093
      es->call_stmt_size = 1;
2094
      account_size_time (info, 0, 0, &t);
2095
      return;
2096
    }
2097
 
2098
  /* Even is_gimple_min_invariant rely on current_function_decl.  */
2099
  current_function_decl = node->decl;
2100
  push_cfun (DECL_STRUCT_FUNCTION (node->decl));
2101
 
2102
  /* Estimate the stack size for the function if we're optimizing.  */
2103
  self_stack_size = optimize ? estimated_stack_frame_size (node) : 0;
2104
  info->estimated_self_stack_size = self_stack_size;
2105
  info->estimated_stack_size = self_stack_size;
2106
  info->stack_frame_offset = 0;
2107
 
2108
  /* Can this function be inlined at all?  */
2109
  info->inlinable = tree_inlinable_function_p (node->decl);
2110
 
2111
  /* Type attributes can use parameter indices to describe them.  */
2112
  if (TYPE_ATTRIBUTES (TREE_TYPE (node->decl)))
2113
    node->local.can_change_signature = false;
2114
  else
2115
    {
2116
      /* Otherwise, inlinable functions always can change signature.  */
2117
      if (info->inlinable)
2118
        node->local.can_change_signature = true;
2119
      else
2120
        {
2121
          /* Functions calling builtin_apply can not change signature.  */
2122
          for (e = node->callees; e; e = e->next_callee)
2123
            {
2124
              tree cdecl = e->callee->decl;
2125
              if (DECL_BUILT_IN (cdecl)
2126
                  && DECL_BUILT_IN_CLASS (cdecl) == BUILT_IN_NORMAL
2127
                  && (DECL_FUNCTION_CODE (cdecl) == BUILT_IN_APPLY_ARGS
2128
                      || DECL_FUNCTION_CODE (cdecl) == BUILT_IN_VA_START))
2129
                break;
2130
            }
2131
          node->local.can_change_signature = !e;
2132
        }
2133
    }
2134
  estimate_function_body_sizes (node, early);
2135
 
2136
  /* Inlining characteristics are maintained by the cgraph_mark_inline.  */
2137
  info->time = info->self_time;
2138
  info->size = info->self_size;
2139
  info->stack_frame_offset = 0;
2140
  info->estimated_stack_size = info->estimated_self_stack_size;
2141
  current_function_decl = old_decl;
2142
  pop_cfun ();
2143
}
2144
 
2145
 
2146
/* Compute parameters of functions used by inliner using
2147
   current_function_decl.  */
2148
 
2149
static unsigned int
2150
compute_inline_parameters_for_current (void)
2151
{
2152
  compute_inline_parameters (cgraph_get_node (current_function_decl), true);
2153
  return 0;
2154
}
2155
 
2156
struct gimple_opt_pass pass_inline_parameters =
2157
{
2158
 {
2159
  GIMPLE_PASS,
2160
  "inline_param",                       /* name */
2161
  NULL,                                 /* gate */
2162
  compute_inline_parameters_for_current,/* execute */
2163
  NULL,                                 /* sub */
2164
  NULL,                                 /* next */
2165
  0,                                     /* static_pass_number */
2166
  TV_INLINE_HEURISTICS,                 /* tv_id */
2167
  0,                                     /* properties_required */
2168
  0,                                     /* properties_provided */
2169
  0,                                     /* properties_destroyed */
2170
  0,                                     /* todo_flags_start */
2171
 
2172
 }
2173
};
2174
 
2175
 
2176
/* Increase SIZE and TIME for size and time needed to handle edge E.  */
2177
 
2178
static void
2179
estimate_edge_size_and_time (struct cgraph_edge *e, int *size, int *time,
2180
                             int prob)
2181
{
2182
  struct inline_edge_summary *es = inline_edge_summary (e);
2183
  *size += es->call_stmt_size * INLINE_SIZE_SCALE;
2184
  *time += (es->call_stmt_time * prob / REG_BR_PROB_BASE
2185
            * e->frequency * (INLINE_TIME_SCALE / CGRAPH_FREQ_BASE));
2186
  if (*time > MAX_TIME * INLINE_TIME_SCALE)
2187
    *time = MAX_TIME * INLINE_TIME_SCALE;
2188
}
2189
 
2190
 
2191
/* Estimate benefit devirtualizing indirect edge IE, provided KNOWN_VALS and
2192
   KNOWN_BINFOS.  */
2193
 
2194
static void
2195
estimate_edge_devirt_benefit (struct cgraph_edge *ie,
2196
                              int *size, int *time, int prob,
2197
                              VEC (tree, heap) *known_vals,
2198
                              VEC (tree, heap) *known_binfos)
2199
{
2200
  tree target;
2201
  int time_diff, size_diff;
2202
 
2203
  if (!known_vals && !known_binfos)
2204
    return;
2205
 
2206
  target = ipa_get_indirect_edge_target (ie, known_vals, known_binfos);
2207
  if (!target)
2208
    return;
2209
 
2210
  /* Account for difference in cost between indirect and direct calls.  */
2211
  size_diff = ((eni_size_weights.indirect_call_cost - eni_size_weights.call_cost)
2212
                * INLINE_SIZE_SCALE);
2213
  *size -= size_diff;
2214
  time_diff = ((eni_time_weights.indirect_call_cost - eni_time_weights.call_cost)
2215
               * INLINE_TIME_SCALE * prob / REG_BR_PROB_BASE);
2216
  *time -= time_diff;
2217
 
2218
  /* TODO: This code is trying to benefit indirect calls that will be inlined later.
2219
     The logic however do not belong into local size/time estimates and can not be
2220
     done here, or the accounting of changes will get wrong and we result with
2221
     negative function body sizes.  We need to introduce infrastructure for independent
2222
     benefits to the inliner.  */
2223
#if 0
2224
  struct cgraph_node *callee;
2225
  struct inline_summary *isummary;
2226
  int edge_size, edge_time, time_diff, size_diff;
2227
 
2228
  callee = cgraph_get_node (target);
2229
  if (!callee || !callee->analyzed)
2230
    return;
2231
  isummary = inline_summary (callee);
2232
  if (!isummary->inlinable)
2233
    return;
2234
 
2235
  estimate_edge_size_and_time (ie, &edge_size, &edge_time, prob);
2236
 
2237
  /* Count benefit only from functions that definitely will be inlined
2238
     if additional context from NODE's caller were available.
2239
 
2240
     We just account overall size change by inlining.  TODO:
2241
     we really need to add sort of benefit metrics for these kind of
2242
     cases. */
2243
  if (edge_size - size_diff >= isummary->size * INLINE_SIZE_SCALE)
2244
    {
2245
      /* Subtract size and time that we added for edge IE.  */
2246
      *size -= edge_size - size_diff;
2247
 
2248
      /* Account inlined call.  */
2249
      *size += isummary->size * INLINE_SIZE_SCALE;
2250
    }
2251
#endif
2252
}
2253
 
2254
 
2255
/* Increase SIZE and TIME for size and time needed to handle all calls in NODE.
2256
   POSSIBLE_TRUTHS, KNOWN_VALS and KNOWN_BINFOS describe context of the call
2257
   site.  */
2258
 
2259
static void
2260
estimate_calls_size_and_time (struct cgraph_node *node, int *size, int *time,
2261
                              clause_t possible_truths,
2262
                              VEC (tree, heap) *known_vals,
2263
                              VEC (tree, heap) *known_binfos)
2264
{
2265
  struct cgraph_edge *e;
2266
  for (e = node->callees; e; e = e->next_callee)
2267
    {
2268
      struct inline_edge_summary *es = inline_edge_summary (e);
2269
      if (!es->predicate || evaluate_predicate (es->predicate, possible_truths))
2270
        {
2271
          if (e->inline_failed)
2272
            {
2273
              /* Predicates of calls shall not use NOT_CHANGED codes,
2274
                 sowe do not need to compute probabilities.  */
2275
              estimate_edge_size_and_time (e, size, time, REG_BR_PROB_BASE);
2276
            }
2277
          else
2278
            estimate_calls_size_and_time (e->callee, size, time,
2279
                                          possible_truths,
2280
                                          known_vals, known_binfos);
2281
        }
2282
    }
2283
  for (e = node->indirect_calls; e; e = e->next_callee)
2284
    {
2285
      struct inline_edge_summary *es = inline_edge_summary (e);
2286
      if (!es->predicate || evaluate_predicate (es->predicate, possible_truths))
2287
        {
2288
          estimate_edge_size_and_time (e, size, time, REG_BR_PROB_BASE);
2289
          estimate_edge_devirt_benefit (e, size, time, REG_BR_PROB_BASE,
2290
                                        known_vals, known_binfos);
2291
        }
2292
    }
2293
}
2294
 
2295
 
2296
/* Estimate size and time needed to execute NODE assuming
2297
   POSSIBLE_TRUTHS clause, and KNOWN_VALS and KNOWN_BINFOS information
2298
   about NODE's arguments. */
2299
 
2300
static void
2301
estimate_node_size_and_time (struct cgraph_node *node,
2302
                             clause_t possible_truths,
2303
                             VEC (tree, heap) *known_vals,
2304
                             VEC (tree, heap) *known_binfos,
2305
                             int *ret_size, int *ret_time,
2306
                             VEC (inline_param_summary_t, heap)
2307
                               *inline_param_summary)
2308
{
2309
  struct inline_summary *info = inline_summary (node);
2310
  size_time_entry *e;
2311
  int size = 0, time = 0;
2312
  int i;
2313
 
2314
  if (dump_file
2315
      && (dump_flags & TDF_DETAILS))
2316
    {
2317
      bool found = false;
2318
      fprintf (dump_file, "   Estimating body: %s/%i\n"
2319
                          "   Known to be false: ",
2320
               cgraph_node_name (node),
2321
               node->uid);
2322
 
2323
      for (i = predicate_not_inlined_condition;
2324
           i < (predicate_first_dynamic_condition
2325
                + (int)VEC_length (condition, info->conds)); i++)
2326
        if (!(possible_truths & (1 << i)))
2327
          {
2328
            if (found)
2329
              fprintf (dump_file, ", ");
2330
            found = true;
2331
            dump_condition (dump_file, info->conds, i);
2332
          }
2333
    }
2334
 
2335
  for (i = 0; VEC_iterate (size_time_entry, info->entry, i, e); i++)
2336
    if (evaluate_predicate (&e->predicate, possible_truths))
2337
      {
2338
        size += e->size;
2339
        if (!inline_param_summary)
2340
          time += e->time;
2341
        else
2342
          {
2343
            int prob = predicate_probability (info->conds,
2344
                                              &e->predicate,
2345
                                              possible_truths,
2346
                                              inline_param_summary);
2347
            time += e->time * prob / REG_BR_PROB_BASE;
2348
          }
2349
 
2350
      }
2351
 
2352
  if (time > MAX_TIME * INLINE_TIME_SCALE)
2353
    time = MAX_TIME * INLINE_TIME_SCALE;
2354
 
2355
  estimate_calls_size_and_time (node, &size, &time, possible_truths,
2356
                                known_vals, known_binfos);
2357
  time = (time + INLINE_TIME_SCALE / 2) / INLINE_TIME_SCALE;
2358
  size = (size + INLINE_SIZE_SCALE / 2) / INLINE_SIZE_SCALE;
2359
 
2360
 
2361
  if (dump_file
2362
      && (dump_flags & TDF_DETAILS))
2363
    fprintf (dump_file, "\n   size:%i time:%i\n", size, time);
2364
  if (ret_time)
2365
    *ret_time = time;
2366
  if (ret_size)
2367
    *ret_size = size;
2368
  return;
2369
}
2370
 
2371
 
2372
/* Estimate size and time needed to execute callee of EDGE assuming that
2373
   parameters known to be constant at caller of EDGE are propagated.
2374
   KNOWN_VALS and KNOWN_BINFOS are vectors of assumed known constant values
2375
   and types for parameters.  */
2376
 
2377
void
2378
estimate_ipcp_clone_size_and_time (struct cgraph_node *node,
2379
                                   VEC (tree, heap) *known_vals,
2380
                                   VEC (tree, heap) *known_binfos,
2381
                                   int *ret_size, int *ret_time)
2382
{
2383
  clause_t clause;
2384
 
2385
  clause = evaluate_conditions_for_known_args (node, false, known_vals);
2386
  estimate_node_size_and_time (node, clause, known_vals, known_binfos,
2387
                               ret_size, ret_time,
2388
                               NULL);
2389
}
2390
 
2391
 
2392
/* Translate all conditions from callee representation into caller
2393
   representation and symbolically evaluate predicate P into new predicate.
2394
 
2395
   INFO is inline_summary of function we are adding predicate into,
2396
   CALLEE_INFO is summary of function predicate P is from. OPERAND_MAP is
2397
   array giving callee formal IDs the caller formal IDs. POSSSIBLE_TRUTHS is
2398
   clausule of all callee conditions that may be true in caller context.
2399
   TOPLEV_PREDICATE is predicate under which callee is executed.  */
2400
 
2401
static struct predicate
2402
remap_predicate (struct inline_summary *info,
2403
                 struct inline_summary *callee_info,
2404
                 struct predicate *p,
2405
                 VEC (int, heap) *operand_map,
2406
                 clause_t possible_truths,
2407
                 struct predicate *toplev_predicate)
2408
{
2409
  int i;
2410
  struct predicate out = true_predicate ();
2411
 
2412
  /* True predicate is easy.  */
2413
  if (true_predicate_p (p))
2414
    return *toplev_predicate;
2415
  for (i = 0; p->clause[i]; i++)
2416
    {
2417
      clause_t clause = p->clause[i];
2418
      int cond;
2419
      struct predicate clause_predicate = false_predicate ();
2420
 
2421
      gcc_assert (i < MAX_CLAUSES);
2422
 
2423
      for (cond = 0; cond < NUM_CONDITIONS; cond ++)
2424
        /* Do we have condition we can't disprove?   */
2425
        if (clause & possible_truths & (1 << cond))
2426
          {
2427
            struct predicate cond_predicate;
2428
            /* Work out if the condition can translate to predicate in the
2429
               inlined function.  */
2430
            if (cond >= predicate_first_dynamic_condition)
2431
              {
2432
                 struct condition *c;
2433
 
2434
                 c = VEC_index (condition, callee_info->conds,
2435
                                cond - predicate_first_dynamic_condition);
2436
                 /* See if we can remap condition operand to caller's operand.
2437
                    Otherwise give up.  */
2438
                 if (!operand_map
2439
                     || (int)VEC_length (int, operand_map) <= c->operand_num
2440
                     || VEC_index (int, operand_map, c->operand_num) == -1)
2441
                   cond_predicate = true_predicate ();
2442
                 else
2443
                   cond_predicate = add_condition (info,
2444
                                                   VEC_index (int, operand_map,
2445
                                                              c->operand_num),
2446
                                                   c->code, c->val);
2447
              }
2448
            /* Fixed conditions remains same, construct single
2449
               condition predicate.  */
2450
            else
2451
              {
2452
                cond_predicate.clause[0] = 1 << cond;
2453
                cond_predicate.clause[1] = 0;
2454
              }
2455
            clause_predicate = or_predicates (info->conds, &clause_predicate,
2456
                                              &cond_predicate);
2457
          }
2458
      out = and_predicates (info->conds, &out, &clause_predicate);
2459
    }
2460
  return and_predicates (info->conds, &out, toplev_predicate);
2461
}
2462
 
2463
 
2464
/* Update summary information of inline clones after inlining.
2465
   Compute peak stack usage.  */
2466
 
2467
static void
2468
inline_update_callee_summaries (struct cgraph_node *node,
2469
                                int depth)
2470
{
2471
  struct cgraph_edge *e;
2472
  struct inline_summary *callee_info = inline_summary (node);
2473
  struct inline_summary *caller_info = inline_summary (node->callers->caller);
2474
  HOST_WIDE_INT peak;
2475
 
2476
  callee_info->stack_frame_offset
2477
    = caller_info->stack_frame_offset
2478
      + caller_info->estimated_self_stack_size;
2479
  peak = callee_info->stack_frame_offset
2480
      + callee_info->estimated_self_stack_size;
2481
  if (inline_summary (node->global.inlined_to)->estimated_stack_size
2482
      < peak)
2483
    inline_summary (node->global.inlined_to)->estimated_stack_size = peak;
2484
  cgraph_propagate_frequency (node);
2485
  for (e = node->callees; e; e = e->next_callee)
2486
    {
2487
      if (!e->inline_failed)
2488
        inline_update_callee_summaries (e->callee, depth);
2489
      inline_edge_summary (e)->loop_depth += depth;
2490
    }
2491
  for (e = node->indirect_calls; e; e = e->next_callee)
2492
    inline_edge_summary (e)->loop_depth += depth;
2493
}
2494
 
2495
/* Update change_prob of EDGE after INLINED_EDGE has been inlined.
2496
   When functoin A is inlined in B and A calls C with parameter that
2497
   changes with probability PROB1 and C is known to be passthroug
2498
   of argument if B that change with probability PROB2, the probability
2499
   of change is now PROB1*PROB2.  */
2500
 
2501
static void
2502
remap_edge_change_prob (struct cgraph_edge *inlined_edge,
2503
                        struct cgraph_edge *edge)
2504
{
2505
  if (ipa_node_params_vector)
2506
    {
2507
      int i;
2508
      struct ipa_edge_args *args = IPA_EDGE_REF (edge);
2509
      struct inline_edge_summary *es = inline_edge_summary (edge);
2510
      struct inline_edge_summary *inlined_es
2511
                                    = inline_edge_summary (inlined_edge);
2512
 
2513
      for (i = 0; i < ipa_get_cs_argument_count (args); i++)
2514
        {
2515
          struct ipa_jump_func *jfunc = ipa_get_ith_jump_func (args, i);
2516
          if (jfunc->type == IPA_JF_PASS_THROUGH
2517
              && (jfunc->value.pass_through.formal_id
2518
                  < (int) VEC_length (inline_param_summary_t,
2519
                                      inlined_es->param)))
2520
            {
2521
              int prob1 = VEC_index (inline_param_summary_t,
2522
                                     es->param, i)->change_prob;
2523
              int prob2 = VEC_index
2524
                             (inline_param_summary_t,
2525
                             inlined_es->param,
2526
                             jfunc->value.pass_through.formal_id)->change_prob;
2527
              int prob = ((prob1 * prob2 + REG_BR_PROB_BASE / 2)
2528
                          / REG_BR_PROB_BASE);
2529
 
2530
              if (prob1 && prob2 && !prob)
2531
                prob = 1;
2532
 
2533
              VEC_index (inline_param_summary_t,
2534
                         es->param, i)->change_prob = prob;
2535
            }
2536
        }
2537
  }
2538
}
2539
 
2540
/* Update edge summaries of NODE after INLINED_EDGE has been inlined.
2541
 
2542
   Remap predicates of callees of NODE.  Rest of arguments match
2543
   remap_predicate.
2544
 
2545
   Also update change probabilities.  */
2546
 
2547
static void
2548
remap_edge_summaries  (struct cgraph_edge *inlined_edge,
2549
                       struct cgraph_node *node,
2550
                       struct inline_summary *info,
2551
                       struct inline_summary *callee_info,
2552
                       VEC (int, heap) *operand_map,
2553
                       clause_t possible_truths,
2554
                       struct predicate *toplev_predicate)
2555
{
2556
  struct cgraph_edge *e;
2557
  for (e = node->callees; e; e = e->next_callee)
2558
    {
2559
      struct inline_edge_summary *es = inline_edge_summary (e);
2560
      struct predicate p;
2561
 
2562
      if (e->inline_failed)
2563
        {
2564
          remap_edge_change_prob (inlined_edge, e);
2565
 
2566
          if (es->predicate)
2567
            {
2568
              p = remap_predicate (info, callee_info,
2569
                                   es->predicate, operand_map, possible_truths,
2570
                                   toplev_predicate);
2571
              edge_set_predicate (e, &p);
2572
              /* TODO: We should remove the edge for code that will be
2573
                 optimized out, but we need to keep verifiers and tree-inline
2574
                 happy.  Make it cold for now.  */
2575
              if (false_predicate_p (&p))
2576
                {
2577
                  e->count = 0;
2578
                  e->frequency = 0;
2579
                }
2580
            }
2581
          else
2582
            edge_set_predicate (e, toplev_predicate);
2583
        }
2584
      else
2585
        remap_edge_summaries (inlined_edge, e->callee, info, callee_info,
2586
                              operand_map, possible_truths, toplev_predicate);
2587
    }
2588
  for (e = node->indirect_calls; e; e = e->next_callee)
2589
    {
2590
      struct inline_edge_summary *es = inline_edge_summary (e);
2591
      struct predicate p;
2592
 
2593
      remap_edge_change_prob (inlined_edge, e);
2594
      if (es->predicate)
2595
        {
2596
          p = remap_predicate (info, callee_info,
2597
                               es->predicate, operand_map, possible_truths,
2598
                               toplev_predicate);
2599
          edge_set_predicate (e, &p);
2600
          /* TODO: We should remove the edge for code that will be optimized
2601
             out, but we need to keep verifiers and tree-inline happy.
2602
             Make it cold for now.  */
2603
          if (false_predicate_p (&p))
2604
            {
2605
              e->count = 0;
2606
              e->frequency = 0;
2607
            }
2608
        }
2609
      else
2610
        edge_set_predicate (e, toplev_predicate);
2611
    }
2612
}
2613
 
2614
 
2615
/* We inlined EDGE.  Update summary of the function we inlined into.  */
2616
 
2617
void
2618
inline_merge_summary (struct cgraph_edge *edge)
2619
{
2620
  struct inline_summary *callee_info = inline_summary (edge->callee);
2621
  struct cgraph_node *to = (edge->caller->global.inlined_to
2622
                            ? edge->caller->global.inlined_to : edge->caller);
2623
  struct inline_summary *info = inline_summary (to);
2624
  clause_t clause = 0;           /* not_inline is known to be false.  */
2625
  size_time_entry *e;
2626
  VEC (int, heap) *operand_map = NULL;
2627
  int i;
2628
  struct predicate toplev_predicate;
2629
  struct predicate true_p = true_predicate ();
2630
  struct inline_edge_summary *es = inline_edge_summary (edge);
2631
 
2632
  if (es->predicate)
2633
    toplev_predicate = *es->predicate;
2634
  else
2635
    toplev_predicate = true_predicate ();
2636
 
2637
  if (ipa_node_params_vector && callee_info->conds)
2638
    {
2639
      struct ipa_edge_args *args = IPA_EDGE_REF (edge);
2640
      int count = ipa_get_cs_argument_count (args);
2641
      int i;
2642
 
2643
      evaluate_properties_for_edge (edge, true, &clause, NULL, NULL);
2644
      if (count)
2645
        VEC_safe_grow_cleared (int, heap, operand_map, count);
2646
      for (i = 0; i < count; i++)
2647
        {
2648
          struct ipa_jump_func *jfunc = ipa_get_ith_jump_func (args, i);
2649
          int map = -1;
2650
          /* TODO: handle non-NOPs when merging.  */
2651
          if (jfunc->type == IPA_JF_PASS_THROUGH
2652
              && jfunc->value.pass_through.operation == NOP_EXPR)
2653
            map = jfunc->value.pass_through.formal_id;
2654
          VEC_replace (int, operand_map, i, map);
2655
          gcc_assert (map < ipa_get_param_count (IPA_NODE_REF (to)));
2656
        }
2657
    }
2658
  for (i = 0; VEC_iterate (size_time_entry, callee_info->entry, i, e); i++)
2659
    {
2660
      struct predicate p = remap_predicate (info, callee_info,
2661
                                            &e->predicate, operand_map, clause,
2662
                                            &toplev_predicate);
2663
      if (!false_predicate_p (&p))
2664
        {
2665
          gcov_type add_time = ((gcov_type)e->time * edge->frequency
2666
                                + CGRAPH_FREQ_BASE / 2) / CGRAPH_FREQ_BASE;
2667
          int prob = predicate_probability (callee_info->conds,
2668
                                            &e->predicate,
2669
                                            clause, es->param);
2670
          add_time = add_time * prob / REG_BR_PROB_BASE;
2671
          if (add_time > MAX_TIME * INLINE_TIME_SCALE)
2672
            add_time = MAX_TIME * INLINE_TIME_SCALE;
2673
          if (prob != REG_BR_PROB_BASE
2674
              && dump_file && (dump_flags & TDF_DETAILS))
2675
            {
2676
              fprintf (dump_file, "\t\tScaling time by probability:%f\n",
2677
                       (double)prob / REG_BR_PROB_BASE);
2678
            }
2679
          account_size_time (info, e->size, add_time, &p);
2680
        }
2681
    }
2682
  remap_edge_summaries (edge, edge->callee, info, callee_info, operand_map,
2683
                        clause, &toplev_predicate);
2684
  info->size = 0;
2685
  info->time = 0;
2686
  for (i = 0; VEC_iterate (size_time_entry, info->entry, i, e); i++)
2687
    info->size += e->size, info->time += e->time;
2688
  estimate_calls_size_and_time (to, &info->size, &info->time,
2689
                                ~(clause_t)(1 << predicate_false_condition),
2690
                                NULL, NULL);
2691
 
2692
  inline_update_callee_summaries (edge->callee,
2693
                                  inline_edge_summary (edge)->loop_depth);
2694
 
2695
  /* We do not maintain predicates of inlined edges, free it.  */
2696
  edge_set_predicate (edge, &true_p);
2697
  /* Similarly remove param summaries.  */
2698
  VEC_free (inline_param_summary_t, heap, es->param);
2699
 
2700
  info->time = (info->time + INLINE_TIME_SCALE / 2) / INLINE_TIME_SCALE;
2701
  info->size = (info->size + INLINE_SIZE_SCALE / 2) / INLINE_SIZE_SCALE;
2702
}
2703
 
2704
 
2705
/* Estimate the time cost for the caller when inlining EDGE.
2706
   Only to be called via estimate_edge_time, that handles the
2707
   caching mechanism.
2708
 
2709
   When caching, also update the cache entry.  Compute both time and
2710
   size, since we always need both metrics eventually.  */
2711
 
2712
int
2713
do_estimate_edge_time (struct cgraph_edge *edge)
2714
{
2715
  int time;
2716
  int size;
2717
  gcov_type ret;
2718
  struct cgraph_node *callee;
2719
  clause_t clause;
2720
  VEC (tree, heap) *known_vals;
2721
  VEC (tree, heap) *known_binfos;
2722
  struct inline_edge_summary *es = inline_edge_summary (edge);
2723
 
2724
  callee = cgraph_function_or_thunk_node (edge->callee, NULL);
2725
 
2726
  gcc_checking_assert (edge->inline_failed);
2727
  evaluate_properties_for_edge (edge, true,
2728
                                &clause, &known_vals, &known_binfos);
2729
  estimate_node_size_and_time (callee, clause, known_vals, known_binfos,
2730
                               &size, &time, es->param);
2731
  VEC_free (tree, heap, known_vals);
2732
  VEC_free (tree, heap, known_binfos);
2733
 
2734
  ret = (((gcov_type)time
2735
           - es->call_stmt_time) * edge->frequency
2736
         + CGRAPH_FREQ_BASE / 2) / CGRAPH_FREQ_BASE;
2737
 
2738
  /* When caching, update the cache entry.  */
2739
  if (edge_growth_cache)
2740
    {
2741
      int ret_size;
2742
      if ((int)VEC_length (edge_growth_cache_entry, edge_growth_cache)
2743
          <= edge->uid)
2744
        VEC_safe_grow_cleared (edge_growth_cache_entry, heap, edge_growth_cache,
2745
                               cgraph_edge_max_uid);
2746
      VEC_index (edge_growth_cache_entry, edge_growth_cache, edge->uid)->time
2747
        = ret + (ret >= 0);
2748
 
2749
      ret_size = size - es->call_stmt_size;
2750
      gcc_checking_assert (es->call_stmt_size);
2751
      VEC_index (edge_growth_cache_entry, edge_growth_cache, edge->uid)->size
2752
        = ret_size + (ret_size >= 0);
2753
    }
2754
  return ret;
2755
}
2756
 
2757
 
2758
/* Estimate the growth of the caller when inlining EDGE.
2759
   Only to be called via estimate_edge_size.  */
2760
 
2761
int
2762
do_estimate_edge_growth (struct cgraph_edge *edge)
2763
{
2764
  int size;
2765
  struct cgraph_node *callee;
2766
  clause_t clause;
2767
  VEC (tree, heap) *known_vals;
2768
  VEC (tree, heap) *known_binfos;
2769
 
2770
  /* When we do caching, use do_estimate_edge_time to populate the entry.  */
2771
 
2772
  if (edge_growth_cache)
2773
    {
2774
      do_estimate_edge_time (edge);
2775
      size = VEC_index (edge_growth_cache_entry,
2776
                        edge_growth_cache,
2777
                        edge->uid)->size;
2778
      gcc_checking_assert (size);
2779
      return size - (size > 0);
2780
    }
2781
 
2782
  callee = cgraph_function_or_thunk_node (edge->callee, NULL);
2783
 
2784
  /* Early inliner runs without caching, go ahead and do the dirty work.  */
2785
  gcc_checking_assert (edge->inline_failed);
2786
  evaluate_properties_for_edge (edge, true,
2787
                                &clause, &known_vals, &known_binfos);
2788
  estimate_node_size_and_time (callee, clause, known_vals, known_binfos,
2789
                               &size, NULL, NULL);
2790
  VEC_free (tree, heap, known_vals);
2791
  VEC_free (tree, heap, known_binfos);
2792
  gcc_checking_assert (inline_edge_summary (edge)->call_stmt_size);
2793
  return size - inline_edge_summary (edge)->call_stmt_size;
2794
}
2795
 
2796
 
2797
/* Estimate self time of the function NODE after inlining EDGE.  */
2798
 
2799
int
2800
estimate_time_after_inlining (struct cgraph_node *node,
2801
                              struct cgraph_edge *edge)
2802
{
2803
  struct inline_edge_summary *es = inline_edge_summary (edge);
2804
  if (!es->predicate || !false_predicate_p (es->predicate))
2805
    {
2806
      gcov_type time = inline_summary (node)->time + estimate_edge_time (edge);
2807
      if (time < 0)
2808
        time = 0;
2809
      if (time > MAX_TIME)
2810
        time = MAX_TIME;
2811
      return time;
2812
    }
2813
  return inline_summary (node)->time;
2814
}
2815
 
2816
 
2817
/* Estimate the size of NODE after inlining EDGE which should be an
2818
   edge to either NODE or a call inlined into NODE.  */
2819
 
2820
int
2821
estimate_size_after_inlining (struct cgraph_node *node,
2822
                              struct cgraph_edge *edge)
2823
{
2824
  struct inline_edge_summary *es = inline_edge_summary (edge);
2825
  if (!es->predicate || !false_predicate_p (es->predicate))
2826
    {
2827
      int size = inline_summary (node)->size + estimate_edge_growth (edge);
2828
      gcc_assert (size >= 0);
2829
      return size;
2830
    }
2831
  return inline_summary (node)->size;
2832
}
2833
 
2834
 
2835
struct growth_data
2836
{
2837
  bool self_recursive;
2838
  int growth;
2839
};
2840
 
2841
 
2842
/* Worker for do_estimate_growth.  Collect growth for all callers.  */
2843
 
2844
static bool
2845
do_estimate_growth_1 (struct cgraph_node *node, void *data)
2846
{
2847
  struct cgraph_edge *e;
2848
  struct growth_data *d = (struct growth_data *) data;
2849
 
2850
  for (e = node->callers; e; e = e->next_caller)
2851
    {
2852
      gcc_checking_assert (e->inline_failed);
2853
 
2854
      if (e->caller == node
2855
          || (e->caller->global.inlined_to
2856
              && e->caller->global.inlined_to == node))
2857
        d->self_recursive = true;
2858
      d->growth += estimate_edge_growth (e);
2859
    }
2860
  return false;
2861
}
2862
 
2863
 
2864
/* Estimate the growth caused by inlining NODE into all callees.  */
2865
 
2866
int
2867
do_estimate_growth (struct cgraph_node *node)
2868
{
2869
  struct growth_data d = {0, false};
2870
  struct inline_summary *info = inline_summary (node);
2871
 
2872
  cgraph_for_node_and_aliases (node, do_estimate_growth_1, &d, true);
2873
 
2874
  /* For self recursive functions the growth estimation really should be
2875
     infinity.  We don't want to return very large values because the growth
2876
     plays various roles in badness computation fractions.  Be sure to not
2877
     return zero or negative growths. */
2878
  if (d.self_recursive)
2879
    d.growth = d.growth < info->size ? info->size : d.growth;
2880
  else
2881
    {
2882
      if (!DECL_EXTERNAL (node->decl)
2883
          && cgraph_will_be_removed_from_program_if_no_direct_calls (node))
2884
        d.growth -= info->size;
2885
      /* COMDAT functions are very often not shared across multiple units
2886
         since they come from various template instantiations.
2887
         Take this into account.  */
2888
      else  if (DECL_COMDAT (node->decl)
2889
                && cgraph_can_remove_if_no_direct_calls_p (node))
2890
        d.growth -= (info->size
2891
                     * (100 - PARAM_VALUE (PARAM_COMDAT_SHARING_PROBABILITY))
2892
                     + 50) / 100;
2893
    }
2894
 
2895
  if (node_growth_cache)
2896
    {
2897
      if ((int)VEC_length (int, node_growth_cache) <= node->uid)
2898
        VEC_safe_grow_cleared (int, heap, node_growth_cache, cgraph_max_uid);
2899
      VEC_replace (int, node_growth_cache, node->uid,
2900
                   d.growth + (d.growth >= 0));
2901
    }
2902
  return d.growth;
2903
}
2904
 
2905
 
2906
/* This function performs intraprocedural analysis in NODE that is required to
2907
   inline indirect calls.  */
2908
 
2909
static void
2910
inline_indirect_intraprocedural_analysis (struct cgraph_node *node)
2911
{
2912
  ipa_analyze_node (node);
2913
  if (dump_file && (dump_flags & TDF_DETAILS))
2914
    {
2915
      ipa_print_node_params (dump_file, node);
2916
      ipa_print_node_jump_functions (dump_file, node);
2917
    }
2918
}
2919
 
2920
 
2921
/* Note function body size.  */
2922
 
2923
static void
2924
inline_analyze_function (struct cgraph_node *node)
2925
{
2926
  push_cfun (DECL_STRUCT_FUNCTION (node->decl));
2927
  current_function_decl = node->decl;
2928
 
2929
  if (dump_file)
2930
    fprintf (dump_file, "\nAnalyzing function: %s/%u\n",
2931
             cgraph_node_name (node), node->uid);
2932
  if (optimize && !node->thunk.thunk_p)
2933
    inline_indirect_intraprocedural_analysis (node);
2934
  compute_inline_parameters (node, false);
2935
 
2936
  current_function_decl = NULL;
2937
  pop_cfun ();
2938
}
2939
 
2940
 
2941
/* Called when new function is inserted to callgraph late.  */
2942
 
2943
static void
2944
add_new_function (struct cgraph_node *node, void *data ATTRIBUTE_UNUSED)
2945
{
2946
  inline_analyze_function (node);
2947
}
2948
 
2949
 
2950
/* Note function body size.  */
2951
 
2952
void
2953
inline_generate_summary (void)
2954
{
2955
  struct cgraph_node *node;
2956
 
2957
  function_insertion_hook_holder =
2958
      cgraph_add_function_insertion_hook (&add_new_function, NULL);
2959
 
2960
  ipa_register_cgraph_hooks ();
2961
  inline_free_summary ();
2962
 
2963
  FOR_EACH_DEFINED_FUNCTION (node)
2964
    if (!node->alias)
2965
      inline_analyze_function (node);
2966
}
2967
 
2968
 
2969
/* Read predicate from IB.  */
2970
 
2971
static struct predicate
2972
read_predicate (struct lto_input_block *ib)
2973
{
2974
  struct predicate out;
2975
  clause_t clause;
2976
  int k = 0;
2977
 
2978
  do
2979
    {
2980
      gcc_assert (k <= MAX_CLAUSES);
2981
      clause = out.clause[k++] = streamer_read_uhwi (ib);
2982
    }
2983
  while (clause);
2984
 
2985
  /* Zero-initialize the remaining clauses in OUT.  */
2986
  while (k <= MAX_CLAUSES)
2987
    out.clause[k++] = 0;
2988
 
2989
  return out;
2990
}
2991
 
2992
 
2993
/* Write inline summary for edge E to OB.  */
2994
 
2995
static void
2996
read_inline_edge_summary (struct lto_input_block *ib, struct cgraph_edge *e)
2997
{
2998
  struct inline_edge_summary *es = inline_edge_summary (e);
2999
  struct predicate p;
3000
  int length, i;
3001
 
3002
  es->call_stmt_size = streamer_read_uhwi (ib);
3003
  es->call_stmt_time = streamer_read_uhwi (ib);
3004
  es->loop_depth = streamer_read_uhwi (ib);
3005
  p = read_predicate (ib);
3006
  edge_set_predicate (e, &p);
3007
  length = streamer_read_uhwi (ib);
3008
  if (length)
3009
    {
3010
      VEC_safe_grow_cleared (inline_param_summary_t, heap, es->param, length);
3011
      for (i = 0; i < length; i++)
3012
        VEC_index (inline_param_summary_t, es->param, i)->change_prob
3013
          = streamer_read_uhwi (ib);
3014
    }
3015
}
3016
 
3017
 
3018
/* Stream in inline summaries from the section.  */
3019
 
3020
static void
3021
inline_read_section (struct lto_file_decl_data *file_data, const char *data,
3022
                     size_t len)
3023
{
3024
  const struct lto_function_header *header =
3025
    (const struct lto_function_header *) data;
3026
  const int cfg_offset = sizeof (struct lto_function_header);
3027
  const int main_offset = cfg_offset + header->cfg_size;
3028
  const int string_offset = main_offset + header->main_size;
3029
  struct data_in *data_in;
3030
  struct lto_input_block ib;
3031
  unsigned int i, count2, j;
3032
  unsigned int f_count;
3033
 
3034
  LTO_INIT_INPUT_BLOCK (ib, (const char *) data + main_offset, 0,
3035
                        header->main_size);
3036
 
3037
  data_in =
3038
    lto_data_in_create (file_data, (const char *) data + string_offset,
3039
                        header->string_size, NULL);
3040
  f_count = streamer_read_uhwi (&ib);
3041
  for (i = 0; i < f_count; i++)
3042
    {
3043
      unsigned int index;
3044
      struct cgraph_node *node;
3045
      struct inline_summary *info;
3046
      lto_cgraph_encoder_t encoder;
3047
      struct bitpack_d bp;
3048
      struct cgraph_edge *e;
3049
 
3050
      index = streamer_read_uhwi (&ib);
3051
      encoder = file_data->cgraph_node_encoder;
3052
      node = lto_cgraph_encoder_deref (encoder, index);
3053
      info = inline_summary (node);
3054
 
3055
      info->estimated_stack_size
3056
        = info->estimated_self_stack_size = streamer_read_uhwi (&ib);
3057
      info->size = info->self_size = streamer_read_uhwi (&ib);
3058
      info->time = info->self_time = streamer_read_uhwi (&ib);
3059
 
3060
      bp = streamer_read_bitpack (&ib);
3061
      info->inlinable = bp_unpack_value (&bp, 1);
3062
 
3063
      count2 = streamer_read_uhwi (&ib);
3064
      gcc_assert (!info->conds);
3065
      for (j = 0; j < count2; j++)
3066
        {
3067
          struct condition c;
3068
          c.operand_num = streamer_read_uhwi (&ib);
3069
          c.code = (enum tree_code) streamer_read_uhwi (&ib);
3070
          c.val = stream_read_tree (&ib, data_in);
3071
          VEC_safe_push (condition, gc, info->conds, &c);
3072
        }
3073
      count2 = streamer_read_uhwi (&ib);
3074
      gcc_assert (!info->entry);
3075
      for (j = 0; j < count2; j++)
3076
        {
3077
          struct size_time_entry e;
3078
 
3079
          e.size = streamer_read_uhwi (&ib);
3080
          e.time = streamer_read_uhwi (&ib);
3081
          e.predicate = read_predicate (&ib);
3082
 
3083
          VEC_safe_push (size_time_entry, gc, info->entry, &e);
3084
        }
3085
      for (e = node->callees; e; e = e->next_callee)
3086
        read_inline_edge_summary (&ib, e);
3087
      for (e = node->indirect_calls; e; e = e->next_callee)
3088
        read_inline_edge_summary (&ib, e);
3089
    }
3090
 
3091
  lto_free_section_data (file_data, LTO_section_inline_summary, NULL, data,
3092
                         len);
3093
  lto_data_in_delete (data_in);
3094
}
3095
 
3096
 
3097
/* Read inline summary.  Jump functions are shared among ipa-cp
3098
   and inliner, so when ipa-cp is active, we don't need to write them
3099
   twice.  */
3100
 
3101
void
3102
inline_read_summary (void)
3103
{
3104
  struct lto_file_decl_data **file_data_vec = lto_get_file_decl_data ();
3105
  struct lto_file_decl_data *file_data;
3106
  unsigned int j = 0;
3107
 
3108
  inline_summary_alloc ();
3109
 
3110
  while ((file_data = file_data_vec[j++]))
3111
    {
3112
      size_t len;
3113
      const char *data = lto_get_section_data (file_data,
3114
                                               LTO_section_inline_summary,
3115
                                               NULL, &len);
3116
      if (data)
3117
        inline_read_section (file_data, data, len);
3118
      else
3119
        /* Fatal error here.  We do not want to support compiling ltrans units
3120
           with different version of compiler or different flags than the WPA
3121
           unit, so this should never happen.  */
3122
        fatal_error ("ipa inline summary is missing in input file");
3123
    }
3124
  if (optimize)
3125
    {
3126
      ipa_register_cgraph_hooks ();
3127
      if (!flag_ipa_cp)
3128
        ipa_prop_read_jump_functions ();
3129
    }
3130
  function_insertion_hook_holder =
3131
      cgraph_add_function_insertion_hook (&add_new_function, NULL);
3132
}
3133
 
3134
 
3135
/* Write predicate P to OB.  */
3136
 
3137
static void
3138
write_predicate (struct output_block *ob, struct predicate *p)
3139
{
3140
  int j;
3141
  if (p)
3142
    for (j = 0; p->clause[j]; j++)
3143
      {
3144
         gcc_assert (j < MAX_CLAUSES);
3145
         streamer_write_uhwi (ob, p->clause[j]);
3146
      }
3147
  streamer_write_uhwi (ob, 0);
3148
}
3149
 
3150
 
3151
/* Write inline summary for edge E to OB.  */
3152
 
3153
static void
3154
write_inline_edge_summary (struct output_block *ob, struct cgraph_edge *e)
3155
{
3156
  struct inline_edge_summary *es = inline_edge_summary (e);
3157
  int i;
3158
 
3159
  streamer_write_uhwi (ob, es->call_stmt_size);
3160
  streamer_write_uhwi (ob, es->call_stmt_time);
3161
  streamer_write_uhwi (ob, es->loop_depth);
3162
  write_predicate (ob, es->predicate);
3163
  streamer_write_uhwi (ob, VEC_length (inline_param_summary_t, es->param));
3164
  for (i = 0; i < (int)VEC_length (inline_param_summary_t, es->param); i++)
3165
    streamer_write_uhwi (ob, VEC_index (inline_param_summary_t,
3166
                                        es->param, i)->change_prob);
3167
}
3168
 
3169
 
3170
/* Write inline summary for node in SET.
3171
   Jump functions are shared among ipa-cp and inliner, so when ipa-cp is
3172
   active, we don't need to write them twice.  */
3173
 
3174
void
3175
inline_write_summary (cgraph_node_set set,
3176
                      varpool_node_set vset ATTRIBUTE_UNUSED)
3177
{
3178
  struct cgraph_node *node;
3179
  struct output_block *ob = create_output_block (LTO_section_inline_summary);
3180
  lto_cgraph_encoder_t encoder = ob->decl_state->cgraph_node_encoder;
3181
  unsigned int count = 0;
3182
  int i;
3183
 
3184
  for (i = 0; i < lto_cgraph_encoder_size (encoder); i++)
3185
    if (lto_cgraph_encoder_deref (encoder, i)->analyzed)
3186
      count++;
3187
  streamer_write_uhwi (ob, count);
3188
 
3189
  for (i = 0; i < lto_cgraph_encoder_size (encoder); i++)
3190
    {
3191
      node = lto_cgraph_encoder_deref (encoder, i);
3192
      if (node->analyzed)
3193
        {
3194
          struct inline_summary *info = inline_summary (node);
3195
          struct bitpack_d bp;
3196
          struct cgraph_edge *edge;
3197
          int i;
3198
          size_time_entry *e;
3199
          struct condition *c;
3200
 
3201
          streamer_write_uhwi (ob, lto_cgraph_encoder_encode (encoder, node));
3202
          streamer_write_hwi (ob, info->estimated_self_stack_size);
3203
          streamer_write_hwi (ob, info->self_size);
3204
          streamer_write_hwi (ob, info->self_time);
3205
          bp = bitpack_create (ob->main_stream);
3206
          bp_pack_value (&bp, info->inlinable, 1);
3207
          streamer_write_bitpack (&bp);
3208
          streamer_write_uhwi (ob, VEC_length (condition, info->conds));
3209
          for (i = 0; VEC_iterate (condition, info->conds, i, c); i++)
3210
            {
3211
              streamer_write_uhwi (ob, c->operand_num);
3212
              streamer_write_uhwi (ob, c->code);
3213
              stream_write_tree (ob, c->val, true);
3214
            }
3215
          streamer_write_uhwi (ob, VEC_length (size_time_entry, info->entry));
3216
          for (i = 0;
3217
               VEC_iterate (size_time_entry, info->entry, i, e);
3218
               i++)
3219
            {
3220
              streamer_write_uhwi (ob, e->size);
3221
              streamer_write_uhwi (ob, e->time);
3222
              write_predicate (ob, &e->predicate);
3223
            }
3224
          for (edge = node->callees; edge; edge = edge->next_callee)
3225
            write_inline_edge_summary (ob, edge);
3226
          for (edge = node->indirect_calls; edge; edge = edge->next_callee)
3227
            write_inline_edge_summary (ob, edge);
3228
        }
3229
    }
3230
  streamer_write_char_stream (ob->main_stream, 0);
3231
  produce_asm (ob, NULL);
3232
  destroy_output_block (ob);
3233
 
3234
  if (optimize && !flag_ipa_cp)
3235
    ipa_prop_write_jump_functions (set);
3236
}
3237
 
3238
 
3239
/* Release inline summary.  */
3240
 
3241
void
3242
inline_free_summary (void)
3243
{
3244
  struct cgraph_node *node;
3245
  FOR_EACH_DEFINED_FUNCTION (node)
3246
    reset_inline_summary (node);
3247
  if (function_insertion_hook_holder)
3248
    cgraph_remove_function_insertion_hook (function_insertion_hook_holder);
3249
  function_insertion_hook_holder = NULL;
3250
  if (node_removal_hook_holder)
3251
    cgraph_remove_node_removal_hook (node_removal_hook_holder);
3252
  node_removal_hook_holder = NULL;
3253
  if (edge_removal_hook_holder)
3254
    cgraph_remove_edge_removal_hook (edge_removal_hook_holder);
3255
  edge_removal_hook_holder = NULL;
3256
  if (node_duplication_hook_holder)
3257
    cgraph_remove_node_duplication_hook (node_duplication_hook_holder);
3258
  node_duplication_hook_holder = NULL;
3259
  if (edge_duplication_hook_holder)
3260
    cgraph_remove_edge_duplication_hook (edge_duplication_hook_holder);
3261
  edge_duplication_hook_holder = NULL;
3262
  VEC_free (inline_summary_t, gc, inline_summary_vec);
3263
  inline_summary_vec = NULL;
3264
  VEC_free (inline_edge_summary_t, heap, inline_edge_summary_vec);
3265
  inline_edge_summary_vec = NULL;
3266
  if (edge_predicate_pool)
3267
    free_alloc_pool (edge_predicate_pool);
3268
  edge_predicate_pool = 0;
3269
}

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