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/* Allocation for dataflow support routines.
2
   Copyright (C) 1999, 2000, 2001, 2002, 2003, 2004, 2005, 2006, 2007
3
   Free Software Foundation, Inc.
4
   Originally contributed by Michael P. Hayes
5
             (m.hayes@elec.canterbury.ac.nz, mhayes@redhat.com)
6
   Major rewrite contributed by Danny Berlin (dberlin@dberlin.org)
7
             and Kenneth Zadeck (zadeck@naturalbridge.com).
8
 
9
This file is part of GCC.
10
 
11
GCC is free software; you can redistribute it and/or modify it under
12
the terms of the GNU General Public License as published by the Free
13
Software Foundation; either version 3, or (at your option) any later
14
version.
15
 
16
GCC is distributed in the hope that it will be useful, but WITHOUT ANY
17
WARRANTY; without even the implied warranty of MERCHANTABILITY or
18
FITNESS FOR A PARTICULAR PURPOSE.  See the GNU General Public License
19
for more details.
20
 
21
You should have received a copy of the GNU General Public License
22
along with GCC; see the file COPYING3.  If not see
23
<http://www.gnu.org/licenses/>.  */
24
 
25
/*
26
OVERVIEW:
27
 
28
The files in this collection (df*.c,df.h) provide a general framework
29
for solving dataflow problems.  The global dataflow is performed using
30
a good implementation of iterative dataflow analysis.
31
 
32
The file df-problems.c provides problem instance for the most common
33
dataflow problems: reaching defs, upward exposed uses, live variables,
34
uninitialized variables, def-use chains, and use-def chains.  However,
35
the interface allows other dataflow problems to be defined as well.
36
 
37
 
38
USAGE:
39
 
40
Here is an example of using the dataflow routines.
41
 
42
      struct df *df;
43
 
44
      df = df_init (init_flags);
45
 
46
      df_add_problem (df, problem, flags);
47
 
48
      df_set_blocks (df, blocks);
49
 
50
      df_rescan_blocks (df, blocks);
51
 
52
      df_analyze (df);
53
 
54
      df_dump (df, stderr);
55
 
56
      df_finish (df);
57
 
58
 
59
 
60
DF_INIT simply creates a poor man's object (df) that needs to be
61
passed to all the dataflow routines.  df_finish destroys this object
62
and frees up any allocated memory.
63
 
64
There are three flags that can be passed to df_init, each of these
65
flags controls the scanning of the rtl:
66
 
67
DF_HARD_REGS means that the scanning is to build information about
68
both pseudo registers and hardware registers.  Without this
69
information, the problems will be solved only on pseudo registers.
70
DF_EQUIV_NOTES marks the uses present in EQUIV/EQUAL notes.
71
DF_SUBREGS return subregs rather than the inner reg.
72
 
73
 
74
DF_ADD_PROBLEM adds a problem, defined by an instance to struct
75
df_problem, to the set of problems solved in this instance of df.  All
76
calls to add a problem for a given instance of df must occur before
77
the first call to DF_RESCAN_BLOCKS, DF_SET_BLOCKS or DF_ANALYZE.
78
 
79
For all of the problems defined in df-problems.c, there are
80
convenience functions named DF_*_ADD_PROBLEM.
81
 
82
 
83
Problems can be dependent on other problems.  For instance, solving
84
def-use or use-def chains is dependent on solving reaching
85
definitions. As long as these dependencies are listed in the problem
86
definition, the order of adding the problems is not material.
87
Otherwise, the problems will be solved in the order of calls to
88
df_add_problem.  Note that it is not necessary to have a problem.  In
89
that case, df will just be used to do the scanning.
90
 
91
 
92
 
93
DF_SET_BLOCKS is an optional call used to define a region of the
94
function on which the analysis will be performed.  The normal case is
95
to analyze the entire function and no call to df_set_blocks is made.
96
 
97
When a subset is given, the analysis behaves as if the function only
98
contains those blocks and any edges that occur directly between the
99
blocks in the set.  Care should be taken to call df_set_blocks right
100
before the call to analyze in order to eliminate the possibility that
101
optimizations that reorder blocks invalidate the bitvector.
102
 
103
 
104
 
105
DF_RESCAN_BLOCKS is an optional call that causes the scanner to be
106
 (re)run over the set of blocks passed in.  If blocks is NULL, the entire
107
function (or all of the blocks defined in df_set_blocks) is rescanned.
108
If blocks contains blocks that were not defined in the call to
109
df_set_blocks, these blocks are added to the set of blocks.
110
 
111
 
112
DF_ANALYZE causes all of the defined problems to be (re)solved.  It
113
does not cause blocks to be (re)scanned at the rtl level unless no
114
prior call is made to df_rescan_blocks.  When DF_ANALYZE is completes,
115
the IN and OUT sets for each basic block contain the computer
116
information.  The DF_*_BB_INFO macros can be used to access these
117
bitvectors.
118
 
119
 
120
DF_DUMP can then be called to dump the information produce to some
121
file.
122
 
123
 
124
 
125
DF_FINISH causes all of the datastructures to be cleaned up and freed.
126
The df_instance is also freed and its pointer should be NULLed.
127
 
128
 
129
 
130
 
131
Scanning produces a `struct df_ref' data structure (ref) is allocated
132
for every register reference (def or use) and this records the insn
133
and bb the ref is found within.  The refs are linked together in
134
chains of uses and defs for each insn and for each register.  Each ref
135
also has a chain field that links all the use refs for a def or all
136
the def refs for a use.  This is used to create use-def or def-use
137
chains.
138
 
139
Different optimizations have different needs.  Ultimately, only
140
register allocation and schedulers should be using the bitmaps
141
produced for the live register and uninitialized register problems.
142
The rest of the backend should be upgraded to using and maintaining
143
the linked information such as def use or use def chains.
144
 
145
 
146
 
147
PHILOSOPHY:
148
 
149
While incremental bitmaps are not worthwhile to maintain, incremental
150
chains may be perfectly reasonable.  The fastest way to build chains
151
from scratch or after significant modifications is to build reaching
152
definitions (RD) and build the chains from this.
153
 
154
However, general algorithms for maintaining use-def or def-use chains
155
are not practical.  The amount of work to recompute the chain any
156
chain after an arbitrary change is large.  However, with a modest
157
amount of work it is generally possible to have the application that
158
uses the chains keep them up to date.  The high level knowledge of
159
what is really happening is essential to crafting efficient
160
incremental algorithms.
161
 
162
As for the bit vector problems, there is no interface to give a set of
163
blocks over with to resolve the iteration.  In general, restarting a
164
dataflow iteration is difficult and expensive.  Again, the best way to
165
keep the dataflow information up to data (if this is really what is
166
needed) it to formulate a problem specific solution.
167
 
168
There are fine grained calls for creating and deleting references from
169
instructions in df-scan.c.  However, these are not currently connected
170
to the engine that resolves the dataflow equations.
171
 
172
 
173
DATA STRUCTURES:
174
 
175
The basic object is a DF_REF (reference) and this may either be a
176
DEF (definition) or a USE of a register.
177
 
178
These are linked into a variety of lists; namely reg-def, reg-use,
179
insn-def, insn-use, def-use, and use-def lists.  For example, the
180
reg-def lists contain all the locations that define a given register
181
while the insn-use lists contain all the locations that use a
182
register.
183
 
184
Note that the reg-def and reg-use chains are generally short for
185
pseudos and long for the hard registers.
186
 
187
ACCESSING REFS:
188
 
189
There are 4 ways to obtain access to refs:
190
 
191
1) References are divided into two categories, REAL and ARTIFICIAL.
192
 
193
   REAL refs are associated with instructions.  They are linked into
194
   either in the insn's defs list (accessed by the DF_INSN_DEFS or
195
   DF_INSN_UID_DEFS macros) or the insn's uses list (accessed by the
196
   DF_INSN_USES or DF_INSN_UID_USES macros).  These macros produce a
197
   ref (or NULL), the rest of the list can be obtained by traversal of
198
   the NEXT_REF field (accessed by the DF_REF_NEXT_REF macro.)  There
199
   is no significance to the ordering of the uses or refs in an
200
   instruction.
201
 
202
   ARTIFICIAL refs are associated with basic blocks.  The heads of
203
   these lists can be accessed by calling get_artificial_defs or
204
   get_artificial_uses for the particular basic block.  Artificial
205
   defs and uses are only there if DF_HARD_REGS was specified when the
206
   df instance was created.
207
 
208
   Artificial defs and uses occur both at the beginning and ends of blocks.
209
 
210
     For blocks that area at the destination of eh edges, the
211
     artificial uses and defs occur at the beginning.  The defs relate
212
     to the registers specified in EH_RETURN_DATA_REGNO and the uses
213
     relate to the registers specified in ED_USES.  Logically these
214
     defs and uses should really occur along the eh edge, but there is
215
     no convenient way to do this.  Artificial edges that occur at the
216
     beginning of the block have the DF_REF_AT_TOP flag set.
217
 
218
     Artificial uses occur at the end of all blocks.  These arise from
219
     the hard registers that are always live, such as the stack
220
     register and are put there to keep the code from forgetting about
221
     them.
222
 
223
     Artificial defs occur at the end of the entry block.  These arise
224
     from registers that are live at entry to the function.
225
 
226
2) All of the uses and defs associated with each pseudo or hard
227
   register are linked in a bidirectional chain.  These are called
228
   reg-use or reg_def chains.
229
 
230
   The first use (or def) for a register can be obtained using the
231
   DF_REG_USE_GET macro (or DF_REG_DEF_GET macro).  Subsequent uses
232
   for the same regno can be obtained by following the next_reg field
233
   of the ref.
234
 
235
   In previous versions of this code, these chains were ordered.  It
236
   has not been practical to continue this practice.
237
 
238
3) If def-use or use-def chains are built, these can be traversed to
239
   get to other refs.
240
 
241
4) An array of all of the uses (and an array of all of the defs) can
242
   be built.  These arrays are indexed by the value in the id
243
   structure.  These arrays are only lazily kept up to date, and that
244
   process can be expensive.  To have these arrays built, call
245
   df_reorganize_refs.   Note that the values in the id field of a ref
246
   may change across calls to df_analyze or df_reorganize refs.
247
 
248
   If the only use of this array is to find all of the refs, it is
249
   better to traverse all of the registers and then traverse all of
250
   reg-use or reg-def chains.
251
 
252
 
253
 
254
NOTES:
255
 
256
Embedded addressing side-effects, such as POST_INC or PRE_INC, generate
257
both a use and a def.  These are both marked read/write to show that they
258
are dependent. For example, (set (reg 40) (mem (post_inc (reg 42))))
259
will generate a use of reg 42 followed by a def of reg 42 (both marked
260
read/write).  Similarly, (set (reg 40) (mem (pre_dec (reg 41))))
261
generates a use of reg 41 then a def of reg 41 (both marked read/write),
262
even though reg 41 is decremented before it is used for the memory
263
address in this second example.
264
 
265
A set to a REG inside a ZERO_EXTRACT, or a set to a non-paradoxical SUBREG
266
for which the number of word_mode units covered by the outer mode is
267
smaller than that covered by the inner mode, invokes a read-modify-write.
268
operation.  We generate both a use and a def and again mark them
269
read/write.
270
 
271
Paradoxical subreg writes do not leave a trace of the old content, so they
272
are write-only operations.
273
*/
274
 
275
 
276
#include "config.h"
277
#include "system.h"
278
#include "coretypes.h"
279
#include "tm.h"
280
#include "rtl.h"
281
#include "tm_p.h"
282
#include "insn-config.h"
283
#include "recog.h"
284
#include "function.h"
285
#include "regs.h"
286
#include "output.h"
287
#include "alloc-pool.h"
288
#include "flags.h"
289
#include "hard-reg-set.h"
290
#include "basic-block.h"
291
#include "sbitmap.h"
292
#include "bitmap.h"
293
#include "timevar.h"
294
#include "df.h"
295
#include "tree-pass.h"
296
 
297
static struct df *ddf = NULL;
298
struct df *shared_df = NULL;
299
 
300
static void *df_get_bb_info (struct dataflow *, unsigned int);
301
static void df_set_bb_info (struct dataflow *, unsigned int, void *);
302
/*----------------------------------------------------------------------------
303
  Functions to create, destroy and manipulate an instance of df.
304
----------------------------------------------------------------------------*/
305
 
306
 
307
/* Initialize dataflow analysis and allocate and initialize dataflow
308
   memory.  */
309
 
310
struct df *
311
df_init (int flags)
312
{
313
  struct df *df = XCNEW (struct df);
314
 
315
  /* This is executed once per compilation to initialize platform
316
     specific data structures. */
317
  df_hard_reg_init ();
318
 
319
  /* All df instance must define the scanning problem.  */
320
  df_scan_add_problem (df, flags);
321
  ddf = df;
322
  return df;
323
}
324
 
325
/* Add PROBLEM to the DF instance.  */
326
 
327
struct dataflow *
328
df_add_problem (struct df *df, struct df_problem *problem, int flags)
329
{
330
  struct dataflow *dflow;
331
 
332
  /* First try to add the dependent problem. */
333
  if (problem->dependent_problem_fun)
334
    (problem->dependent_problem_fun) (df, 0);
335
 
336
  /* Check to see if this problem has already been defined.  If it
337
     has, just return that instance, if not, add it to the end of the
338
     vector.  */
339
  dflow = df->problems_by_index[problem->id];
340
  if (dflow)
341
    return dflow;
342
 
343
  /* Make a new one and add it to the end.  */
344
  dflow = XCNEW (struct dataflow);
345
  dflow->flags = flags;
346
  dflow->df = df;
347
  dflow->problem = problem;
348
  df->problems_in_order[df->num_problems_defined++] = dflow;
349
  df->problems_by_index[dflow->problem->id] = dflow;
350
 
351
  return dflow;
352
}
353
 
354
 
355
/* Set the MASK flags in the DFLOW problem.  The old flags are
356
   returned.  If a flag is not allowed to be changed this will fail if
357
   checking is enabled.  */
358
int
359
df_set_flags (struct dataflow *dflow, int mask)
360
{
361
  int old_flags = dflow->flags;
362
 
363
  gcc_assert (!(mask & (~dflow->problem->changeable_flags)));
364
 
365
  dflow->flags |= mask;
366
 
367
  return old_flags;
368
}
369
 
370
/* Clear the MASK flags in the DFLOW problem.  The old flags are
371
   returned.  If a flag is not allowed to be changed this will fail if
372
   checking is enabled.  */
373
int
374
df_clear_flags (struct dataflow *dflow, int mask)
375
{
376
  int old_flags = dflow->flags;
377
 
378
  gcc_assert (!(mask & (~dflow->problem->changeable_flags)));
379
 
380
  dflow->flags &= !mask;
381
 
382
  return old_flags;
383
}
384
 
385
/* Set the blocks that are to be considered for analysis.  If this is
386
   not called or is called with null, the entire function in
387
   analyzed.  */
388
 
389
void
390
df_set_blocks (struct df *df, bitmap blocks)
391
{
392
  if (blocks)
393
    {
394
      if (df->blocks_to_analyze)
395
        {
396
          int p;
397
          bitmap diff = BITMAP_ALLOC (NULL);
398
          bitmap_and_compl (diff, df->blocks_to_analyze, blocks);
399
          for (p = df->num_problems_defined - 1; p >= 0 ;p--)
400
            {
401
              struct dataflow *dflow = df->problems_in_order[p];
402
              if (dflow->problem->reset_fun)
403
                dflow->problem->reset_fun (dflow, df->blocks_to_analyze);
404
              else if (dflow->problem->free_bb_fun)
405
                {
406
                  bitmap_iterator bi;
407
                  unsigned int bb_index;
408
 
409
                  EXECUTE_IF_SET_IN_BITMAP (diff, 0, bb_index, bi)
410
                    {
411
                      basic_block bb = BASIC_BLOCK (bb_index);
412
                      if (bb)
413
                        {
414
                          dflow->problem->free_bb_fun
415
                            (dflow, bb, df_get_bb_info (dflow, bb_index));
416
                          df_set_bb_info (dflow, bb_index, NULL);
417
                        }
418
                    }
419
                }
420
            }
421
 
422
          BITMAP_FREE (diff);
423
        }
424
      else
425
        {
426
          /* If we have not actually run scanning before, do not try
427
             to clear anything.  */
428
          struct dataflow *scan_dflow = df->problems_by_index [DF_SCAN];
429
          if (scan_dflow->problem_data)
430
            {
431
              bitmap blocks_to_reset = NULL;
432
              int p;
433
              for (p = df->num_problems_defined - 1; p >= 0 ;p--)
434
                {
435
                  struct dataflow *dflow = df->problems_in_order[p];
436
                  if (dflow->problem->reset_fun)
437
                    {
438
                      if (!blocks_to_reset)
439
                        {
440
                          basic_block bb;
441
                          blocks_to_reset = BITMAP_ALLOC (NULL);
442
                          FOR_ALL_BB(bb)
443
                            {
444
                              bitmap_set_bit (blocks_to_reset, bb->index);
445
                            }
446
                        }
447
                      dflow->problem->reset_fun (dflow, blocks_to_reset);
448
                    }
449
                }
450
              if (blocks_to_reset)
451
                BITMAP_FREE (blocks_to_reset);
452
            }
453
          df->blocks_to_analyze = BITMAP_ALLOC (NULL);
454
        }
455
      bitmap_copy (df->blocks_to_analyze, blocks);
456
    }
457
  else
458
    {
459
      if (df->blocks_to_analyze)
460
        {
461
          BITMAP_FREE (df->blocks_to_analyze);
462
          df->blocks_to_analyze = NULL;
463
        }
464
    }
465
}
466
 
467
 
468
/* Free all of the per basic block dataflow from all of the problems.
469
   This is typically called before a basic block is deleted and the
470
   problem will be reanalyzed.  */
471
 
472
void
473
df_delete_basic_block (struct df *df, int bb_index)
474
{
475
  basic_block bb = BASIC_BLOCK (bb_index);
476
  int i;
477
 
478
  for (i = 0; i < df->num_problems_defined; i++)
479
    {
480
      struct dataflow *dflow = df->problems_in_order[i];
481
      if (dflow->problem->free_bb_fun)
482
        dflow->problem->free_bb_fun
483
          (dflow, bb, df_get_bb_info (dflow, bb_index));
484
    }
485
}
486
 
487
 
488
/* Free all the dataflow info and the DF structure.  This should be
489
   called from the df_finish macro which also NULLs the parm.  */
490
 
491
void
492
df_finish1 (struct df *df)
493
{
494
  int i;
495
 
496
  for (i = 0; i < df->num_problems_defined; i++)
497
    df->problems_in_order[i]->problem->free_fun (df->problems_in_order[i]);
498
 
499
  free (df);
500
}
501
 
502
 
503
/*----------------------------------------------------------------------------
504
   The general data flow analysis engine.
505
----------------------------------------------------------------------------*/
506
 
507
 
508
/* Hybrid search algorithm from "Implementation Techniques for
509
   Efficient Data-Flow Analysis of Large Programs".  */
510
 
511
static void
512
df_hybrid_search_forward (basic_block bb,
513
                          struct dataflow *dataflow,
514
                          bool single_pass)
515
{
516
  int result_changed;
517
  int i = bb->index;
518
  edge e;
519
  edge_iterator ei;
520
 
521
  SET_BIT (dataflow->visited, bb->index);
522
  gcc_assert (TEST_BIT (dataflow->pending, bb->index));
523
  RESET_BIT (dataflow->pending, i);
524
 
525
  /*  Calculate <conf_op> of predecessor_outs.  */
526
  if (EDGE_COUNT (bb->preds) > 0)
527
    FOR_EACH_EDGE (e, ei, bb->preds)
528
      {
529
        if (!TEST_BIT (dataflow->considered, e->src->index))
530
          continue;
531
 
532
        dataflow->problem->con_fun_n (dataflow, e);
533
      }
534
  else if (dataflow->problem->con_fun_0)
535
    dataflow->problem->con_fun_0 (dataflow, bb);
536
 
537
  result_changed = dataflow->problem->trans_fun (dataflow, i);
538
 
539
  if (!result_changed || single_pass)
540
    return;
541
 
542
  FOR_EACH_EDGE (e, ei, bb->succs)
543
    {
544
      if (e->dest->index == i)
545
        continue;
546
      if (!TEST_BIT (dataflow->considered, e->dest->index))
547
        continue;
548
      SET_BIT (dataflow->pending, e->dest->index);
549
    }
550
 
551
  FOR_EACH_EDGE (e, ei, bb->succs)
552
    {
553
      if (e->dest->index == i)
554
        continue;
555
 
556
      if (!TEST_BIT (dataflow->considered, e->dest->index))
557
        continue;
558
      if (!TEST_BIT (dataflow->visited, e->dest->index))
559
        df_hybrid_search_forward (e->dest, dataflow, single_pass);
560
    }
561
}
562
 
563
static void
564
df_hybrid_search_backward (basic_block bb,
565
                           struct dataflow *dataflow,
566
                           bool single_pass)
567
{
568
  int result_changed;
569
  int i = bb->index;
570
  edge e;
571
  edge_iterator ei;
572
 
573
  SET_BIT (dataflow->visited, bb->index);
574
  gcc_assert (TEST_BIT (dataflow->pending, bb->index));
575
  RESET_BIT (dataflow->pending, i);
576
 
577
  /*  Calculate <conf_op> of predecessor_outs.  */
578
  if (EDGE_COUNT (bb->succs) > 0)
579
    FOR_EACH_EDGE (e, ei, bb->succs)
580
      {
581
        if (!TEST_BIT (dataflow->considered, e->dest->index))
582
          continue;
583
 
584
        dataflow->problem->con_fun_n (dataflow, e);
585
      }
586
  else if (dataflow->problem->con_fun_0)
587
    dataflow->problem->con_fun_0 (dataflow, bb);
588
 
589
  result_changed = dataflow->problem->trans_fun (dataflow, i);
590
 
591
  if (!result_changed || single_pass)
592
    return;
593
 
594
  FOR_EACH_EDGE (e, ei, bb->preds)
595
    {
596
      if (e->src->index == i)
597
        continue;
598
 
599
      if (!TEST_BIT (dataflow->considered, e->src->index))
600
        continue;
601
 
602
      SET_BIT (dataflow->pending, e->src->index);
603
    }
604
 
605
  FOR_EACH_EDGE (e, ei, bb->preds)
606
    {
607
      if (e->src->index == i)
608
        continue;
609
 
610
      if (!TEST_BIT (dataflow->considered, e->src->index))
611
        continue;
612
 
613
      if (!TEST_BIT (dataflow->visited, e->src->index))
614
        df_hybrid_search_backward (e->src, dataflow, single_pass);
615
    }
616
}
617
 
618
 
619
/* This function will perform iterative bitvector dataflow described
620
   by DATAFLOW, producing the in and out sets.  Only the part of the
621
   cfg induced by blocks in DATAFLOW->order is taken into account.
622
 
623
   SINGLE_PASS is true if you just want to make one pass over the
624
   blocks.  */
625
 
626
void
627
df_iterative_dataflow (struct dataflow *dataflow,
628
                       bitmap blocks_to_consider, bitmap blocks_to_init,
629
                       int *blocks_in_postorder, int n_blocks,
630
                       bool single_pass)
631
{
632
  unsigned int idx;
633
  int i;
634
  sbitmap visited = sbitmap_alloc (last_basic_block);
635
  sbitmap pending = sbitmap_alloc (last_basic_block);
636
  sbitmap considered = sbitmap_alloc (last_basic_block);
637
  bitmap_iterator bi;
638
 
639
  dataflow->visited = visited;
640
  dataflow->pending = pending;
641
  dataflow->considered = considered;
642
 
643
  sbitmap_zero (visited);
644
  sbitmap_zero (pending);
645
  sbitmap_zero (considered);
646
 
647
  gcc_assert (dataflow->problem->dir);
648
 
649
  EXECUTE_IF_SET_IN_BITMAP (blocks_to_consider, 0, idx, bi)
650
    {
651
      SET_BIT (considered, idx);
652
    }
653
 
654
  for (i = 0; i < n_blocks; i++)
655
    {
656
      idx = blocks_in_postorder[i];
657
      SET_BIT (pending, idx);
658
    };
659
 
660
  dataflow->problem->init_fun (dataflow, blocks_to_init);
661
 
662
  while (1)
663
    {
664
 
665
      /* For forward problems, you want to pass in reverse postorder
666
         and for backward problems you want postorder.  This has been
667
         shown to be as good as you can do by several people, the
668
         first being Mathew Hecht in his phd dissertation.
669
 
670
         The nodes are passed into this function in postorder.  */
671
 
672
      if (dataflow->problem->dir == DF_FORWARD)
673
        {
674
          for (i = n_blocks - 1 ; i >= 0 ; i--)
675
            {
676
              idx = blocks_in_postorder[i];
677
 
678
              if (TEST_BIT (pending, idx) && !TEST_BIT (visited, idx))
679
                df_hybrid_search_forward (BASIC_BLOCK (idx), dataflow, single_pass);
680
            }
681
        }
682
      else
683
        {
684
          for (i = 0; i < n_blocks; i++)
685
            {
686
              idx = blocks_in_postorder[i];
687
 
688
              if (TEST_BIT (pending, idx) && !TEST_BIT (visited, idx))
689
                df_hybrid_search_backward (BASIC_BLOCK (idx), dataflow, single_pass);
690
            }
691
        }
692
 
693
      if (sbitmap_first_set_bit (pending) == -1)
694
        break;
695
 
696
      sbitmap_zero (visited);
697
    }
698
 
699
  sbitmap_free (pending);
700
  sbitmap_free (visited);
701
  sbitmap_free (considered);
702
}
703
 
704
 
705
/* Remove the entries not in BLOCKS from the LIST of length LEN, preserving
706
   the order of the remaining entries.  Returns the length of the resulting
707
   list.  */
708
 
709
static unsigned
710
df_prune_to_subcfg (int list[], unsigned len, bitmap blocks)
711
{
712
  unsigned act, last;
713
 
714
  for (act = 0, last = 0; act < len; act++)
715
    if (bitmap_bit_p (blocks, list[act]))
716
      list[last++] = list[act];
717
 
718
  return last;
719
}
720
 
721
 
722
/* Execute dataflow analysis on a single dataflow problem.
723
 
724
   There are three sets of blocks passed in:
725
 
726
   BLOCKS_TO_CONSIDER are the blocks whose solution can either be
727
   examined or will be computed.  For calls from DF_ANALYZE, this is
728
   the set of blocks that has been passed to DF_SET_BLOCKS.  For calls
729
   from DF_ANALYZE_SIMPLE_CHANGE_SOME_BLOCKS, this is the set of
730
   blocks in the fringe (the set of blocks passed in plus the set of
731
   immed preds and succs of those blocks).
732
 
733
   BLOCKS_TO_INIT are the blocks whose solution will be changed by
734
   this iteration.  For calls from DF_ANALYZE, this is the set of
735
   blocks that has been passed to DF_SET_BLOCKS.  For calls from
736
   DF_ANALYZE_SIMPLE_CHANGE_SOME_BLOCKS, this is the set of blocks
737
   passed in.
738
 
739
   BLOCKS_TO_SCAN are the set of blocks that need to be rescanned.
740
   For calls from DF_ANALYZE, this is the accumulated set of blocks
741
   that has been passed to DF_RESCAN_BLOCKS since the last call to
742
   DF_ANALYZE.  For calls from DF_ANALYZE_SIMPLE_CHANGE_SOME_BLOCKS,
743
   this is the set of blocks passed in.
744
 
745
                   blocks_to_consider    blocks_to_init    blocks_to_scan
746
   full redo       all                   all               all
747
   partial redo    all                   all               sub
748
   small fixup     fringe                sub               sub
749
*/
750
 
751
void
752
df_analyze_problem (struct dataflow *dflow,
753
                    bitmap blocks_to_consider,
754
                    bitmap blocks_to_init,
755
                    bitmap blocks_to_scan,
756
                    int *postorder, int n_blocks, bool single_pass)
757
{
758
  /* (Re)Allocate the datastructures necessary to solve the problem.  */
759
  if (dflow->problem->alloc_fun)
760
    dflow->problem->alloc_fun (dflow, blocks_to_scan, blocks_to_init);
761
 
762
  /* Set up the problem and compute the local information.  This
763
     function is passed both the blocks_to_consider and the
764
     blocks_to_scan because the RD and RU problems require the entire
765
     function to be rescanned if they are going to be updated.  */
766
  if (dflow->problem->local_compute_fun)
767
    dflow->problem->local_compute_fun (dflow, blocks_to_consider, blocks_to_scan);
768
 
769
  /* Solve the equations.  */
770
  if (dflow->problem->dataflow_fun)
771
    dflow->problem->dataflow_fun (dflow, blocks_to_consider, blocks_to_init,
772
                                  postorder, n_blocks, single_pass);
773
 
774
  /* Massage the solution.  */
775
  if (dflow->problem->finalize_fun)
776
    dflow->problem->finalize_fun (dflow, blocks_to_consider);
777
}
778
 
779
 
780
/* Analyze dataflow info for the basic blocks specified by the bitmap
781
   BLOCKS, or for the whole CFG if BLOCKS is zero.  */
782
 
783
void
784
df_analyze (struct df *df)
785
{
786
  int *postorder = XNEWVEC (int, last_basic_block);
787
  bitmap current_all_blocks = BITMAP_ALLOC (NULL);
788
  int n_blocks;
789
  int i;
790
  bool everything;
791
 
792
  n_blocks = post_order_compute (postorder, true);
793
 
794
  if (n_blocks != n_basic_blocks)
795
    delete_unreachable_blocks ();
796
 
797
  for (i = 0; i < n_blocks; i++)
798
    bitmap_set_bit (current_all_blocks, postorder[i]);
799
 
800
  /* No one called df_rescan_blocks, so do it.  */
801
  if (!df->blocks_to_scan)
802
    df_rescan_blocks (df, NULL);
803
 
804
  /* Make sure that we have pruned any unreachable blocks from these
805
     sets.  */
806
  bitmap_and_into (df->blocks_to_scan, current_all_blocks);
807
 
808
  if (df->blocks_to_analyze)
809
    {
810
      everything = false;
811
      bitmap_and_into (df->blocks_to_analyze, current_all_blocks);
812
      n_blocks = df_prune_to_subcfg (postorder, n_blocks, df->blocks_to_analyze);
813
      BITMAP_FREE (current_all_blocks);
814
    }
815
  else
816
    {
817
      everything = true;
818
      df->blocks_to_analyze = current_all_blocks;
819
      current_all_blocks = NULL;
820
    }
821
 
822
  /* Skip over the DF_SCAN problem. */
823
  for (i = 1; i < df->num_problems_defined; i++)
824
    df_analyze_problem (df->problems_in_order[i],
825
                        df->blocks_to_analyze, df->blocks_to_analyze,
826
                        df->blocks_to_scan,
827
                        postorder, n_blocks, false);
828
 
829
  if (everything)
830
    {
831
      BITMAP_FREE (df->blocks_to_analyze);
832
      df->blocks_to_analyze = NULL;
833
    }
834
 
835
  BITMAP_FREE (df->blocks_to_scan);
836
  df->blocks_to_scan = NULL;
837
  free (postorder);
838
}
839
 
840
 
841
 
842
/*----------------------------------------------------------------------------
843
   Functions to support limited incremental change.
844
----------------------------------------------------------------------------*/
845
 
846
 
847
/* Get basic block info.  */
848
 
849
static void *
850
df_get_bb_info (struct dataflow *dflow, unsigned int index)
851
{
852
  return (struct df_scan_bb_info *) dflow->block_info[index];
853
}
854
 
855
 
856
/* Set basic block info.  */
857
 
858
static void
859
df_set_bb_info (struct dataflow *dflow, unsigned int index,
860
                void *bb_info)
861
{
862
  dflow->block_info[index] = bb_info;
863
}
864
 
865
 
866
/* Called from the rtl_compact_blocks to reorganize the problems basic
867
   block info.  */
868
 
869
void
870
df_compact_blocks (struct df *df)
871
{
872
  int i, p;
873
  basic_block bb;
874
  void **problem_temps;
875
  int size = last_basic_block *sizeof (void *);
876
  problem_temps = xmalloc (size);
877
 
878
  for (p = 0; p < df->num_problems_defined; p++)
879
    {
880
      struct dataflow *dflow = df->problems_in_order[p];
881
      if (dflow->problem->free_bb_fun)
882
        {
883
          df_grow_bb_info (dflow);
884
          memcpy (problem_temps, dflow->block_info, size);
885
 
886
          /* Copy the bb info from the problem tmps to the proper
887
             place in the block_info vector.  Null out the copied
888
             item.  */
889
          i = NUM_FIXED_BLOCKS;
890
          FOR_EACH_BB (bb)
891
            {
892
              df_set_bb_info (dflow, i, problem_temps[bb->index]);
893
              problem_temps[bb->index] = NULL;
894
              i++;
895
            }
896
          memset (dflow->block_info + i, 0,
897
                  (last_basic_block - i) *sizeof (void *));
898
 
899
          /* Free any block infos that were not copied (and NULLed).
900
             These are from orphaned blocks.  */
901
          for (i = NUM_FIXED_BLOCKS; i < last_basic_block; i++)
902
            {
903
              basic_block bb = BASIC_BLOCK (i);
904
              if (problem_temps[i] && bb)
905
                dflow->problem->free_bb_fun
906
                  (dflow, bb, problem_temps[i]);
907
            }
908
        }
909
    }
910
 
911
  free (problem_temps);
912
 
913
  i = NUM_FIXED_BLOCKS;
914
  FOR_EACH_BB (bb)
915
    {
916
      SET_BASIC_BLOCK (i, bb);
917
      bb->index = i;
918
      i++;
919
    }
920
 
921
  gcc_assert (i == n_basic_blocks);
922
 
923
  for (; i < last_basic_block; i++)
924
    SET_BASIC_BLOCK (i, NULL);
925
}
926
 
927
 
928
/* Shove NEW_BLOCK in at OLD_INDEX.  Called from if-cvt to hack a
929
   block.  There is no excuse for people to do this kind of thing.  */
930
 
931
void
932
df_bb_replace (struct df *df, int old_index, basic_block new_block)
933
{
934
  int p;
935
 
936
  for (p = 0; p < df->num_problems_defined; p++)
937
    {
938
      struct dataflow *dflow = df->problems_in_order[p];
939
      if (dflow->block_info)
940
        {
941
          void *temp;
942
 
943
          df_grow_bb_info (dflow);
944
 
945
          /* The old switcheroo.  */
946
 
947
          temp = df_get_bb_info (dflow, old_index);
948
          df_set_bb_info (dflow, old_index,
949
                          df_get_bb_info (dflow, new_block->index));
950
          df_set_bb_info (dflow, new_block->index, temp);
951
        }
952
    }
953
 
954
  SET_BASIC_BLOCK (old_index, new_block);
955
  new_block->index = old_index;
956
}
957
 
958
/*----------------------------------------------------------------------------
959
   PUBLIC INTERFACES TO QUERY INFORMATION.
960
----------------------------------------------------------------------------*/
961
 
962
 
963
/* Return last use of REGNO within BB.  */
964
 
965
struct df_ref *
966
df_bb_regno_last_use_find (struct df *df, basic_block bb, unsigned int regno)
967
{
968
  rtx insn;
969
  struct df_ref *use;
970
  unsigned int uid;
971
 
972
  FOR_BB_INSNS_REVERSE (bb, insn)
973
    {
974
      if (!INSN_P (insn))
975
        continue;
976
 
977
      uid = INSN_UID (insn);
978
      for (use = DF_INSN_UID_GET (df, uid)->uses; use; use = use->next_ref)
979
        if (DF_REF_REGNO (use) == regno)
980
          return use;
981
    }
982
  return NULL;
983
}
984
 
985
 
986
/* Return first def of REGNO within BB.  */
987
 
988
struct df_ref *
989
df_bb_regno_first_def_find (struct df *df, basic_block bb, unsigned int regno)
990
{
991
  rtx insn;
992
  struct df_ref *def;
993
  unsigned int uid;
994
 
995
  FOR_BB_INSNS (bb, insn)
996
    {
997
      if (!INSN_P (insn))
998
        continue;
999
 
1000
      uid = INSN_UID (insn);
1001
      for (def = DF_INSN_UID_GET (df, uid)->defs; def; def = def->next_ref)
1002
        if (DF_REF_REGNO (def) == regno)
1003
          return def;
1004
    }
1005
  return NULL;
1006
}
1007
 
1008
 
1009
/* Return last def of REGNO within BB.  */
1010
 
1011
struct df_ref *
1012
df_bb_regno_last_def_find (struct df *df, basic_block bb, unsigned int regno)
1013
{
1014
  rtx insn;
1015
  struct df_ref *def;
1016
  unsigned int uid;
1017
 
1018
  FOR_BB_INSNS_REVERSE (bb, insn)
1019
    {
1020
      if (!INSN_P (insn))
1021
        continue;
1022
 
1023
      uid = INSN_UID (insn);
1024
      for (def = DF_INSN_UID_GET (df, uid)->defs; def; def = def->next_ref)
1025
        if (DF_REF_REGNO (def) == regno)
1026
          return def;
1027
    }
1028
 
1029
  return NULL;
1030
}
1031
 
1032
/* Return true if INSN defines REGNO.  */
1033
 
1034
bool
1035
df_insn_regno_def_p (struct df *df, rtx insn, unsigned int regno)
1036
{
1037
  unsigned int uid;
1038
  struct df_ref *def;
1039
 
1040
  uid = INSN_UID (insn);
1041
  for (def = DF_INSN_UID_GET (df, uid)->defs; def; def = def->next_ref)
1042
    if (DF_REF_REGNO (def) == regno)
1043
      return true;
1044
 
1045
  return false;
1046
}
1047
 
1048
 
1049
/* Finds the reference corresponding to the definition of REG in INSN.
1050
   DF is the dataflow object.  */
1051
 
1052
struct df_ref *
1053
df_find_def (struct df *df, rtx insn, rtx reg)
1054
{
1055
  unsigned int uid;
1056
  struct df_ref *def;
1057
 
1058
  if (GET_CODE (reg) == SUBREG)
1059
    reg = SUBREG_REG (reg);
1060
  gcc_assert (REG_P (reg));
1061
 
1062
  uid = INSN_UID (insn);
1063
  for (def = DF_INSN_UID_GET (df, uid)->defs; def; def = def->next_ref)
1064
    if (rtx_equal_p (DF_REF_REAL_REG (def), reg))
1065
      return def;
1066
 
1067
  return NULL;
1068
}
1069
 
1070
 
1071
/* Return true if REG is defined in INSN, zero otherwise.  */
1072
 
1073
bool
1074
df_reg_defined (struct df *df, rtx insn, rtx reg)
1075
{
1076
  return df_find_def (df, insn, reg) != NULL;
1077
}
1078
 
1079
 
1080
/* Finds the reference corresponding to the use of REG in INSN.
1081
   DF is the dataflow object.  */
1082
 
1083
struct df_ref *
1084
df_find_use (struct df *df, rtx insn, rtx reg)
1085
{
1086
  unsigned int uid;
1087
  struct df_ref *use;
1088
 
1089
  if (GET_CODE (reg) == SUBREG)
1090
    reg = SUBREG_REG (reg);
1091
  gcc_assert (REG_P (reg));
1092
 
1093
  uid = INSN_UID (insn);
1094
  for (use = DF_INSN_UID_GET (df, uid)->uses; use; use = use->next_ref)
1095
    if (rtx_equal_p (DF_REF_REAL_REG (use), reg))
1096
      return use;
1097
 
1098
  return NULL;
1099
}
1100
 
1101
 
1102
/* Return true if REG is referenced in INSN, zero otherwise.  */
1103
 
1104
bool
1105
df_reg_used (struct df *df, rtx insn, rtx reg)
1106
{
1107
  return df_find_use (df, insn, reg) != NULL;
1108
}
1109
 
1110
 
1111
/*----------------------------------------------------------------------------
1112
   Debugging and printing functions.
1113
----------------------------------------------------------------------------*/
1114
 
1115
/* Dump dataflow info.  */
1116
void
1117
df_dump (struct df *df, FILE *file)
1118
{
1119
  int i;
1120
 
1121
  if (!df || !file)
1122
    return;
1123
 
1124
  fprintf (file, "\n\n%s\n", current_function_name ());
1125
  fprintf (file, "\nDataflow summary:\n");
1126
  fprintf (file, "def_info->bitmap_size = %d, use_info->bitmap_size = %d\n",
1127
           df->def_info.bitmap_size, df->use_info.bitmap_size);
1128
 
1129
  for (i = 0; i < df->num_problems_defined; i++)
1130
    df->problems_in_order[i]->problem->dump_fun (df->problems_in_order[i], file);
1131
 
1132
  fprintf (file, "\n");
1133
}
1134
 
1135
 
1136
void
1137
df_refs_chain_dump (struct df_ref *ref, bool follow_chain, FILE *file)
1138
{
1139
  fprintf (file, "{ ");
1140
  while (ref)
1141
    {
1142
      fprintf (file, "%c%d(%d) ",
1143
               DF_REF_REG_DEF_P (ref) ? 'd' : 'u',
1144
               DF_REF_ID (ref),
1145
               DF_REF_REGNO (ref));
1146
      if (follow_chain)
1147
        df_chain_dump (DF_REF_CHAIN (ref), file);
1148
      ref = ref->next_ref;
1149
    }
1150
  fprintf (file, "}");
1151
}
1152
 
1153
 
1154
/* Dump either a ref-def or reg-use chain.  */
1155
 
1156
void
1157
df_regs_chain_dump (struct df *df ATTRIBUTE_UNUSED, struct df_ref *ref,  FILE *file)
1158
{
1159
  fprintf (file, "{ ");
1160
  while (ref)
1161
    {
1162
      fprintf (file, "%c%d(%d) ",
1163
               DF_REF_REG_DEF_P (ref) ? 'd' : 'u',
1164
               DF_REF_ID (ref),
1165
               DF_REF_REGNO (ref));
1166
      ref = ref->next_reg;
1167
    }
1168
  fprintf (file, "}");
1169
}
1170
 
1171
 
1172
static void
1173
df_mws_dump (struct df_mw_hardreg *mws, FILE *file)
1174
{
1175
  while (mws)
1176
    {
1177
      struct df_link *regs = mws->regs;
1178
      fprintf (file, "%c%d(",
1179
               (mws->type == DF_REF_REG_DEF) ? 'd' : 'u',
1180
               DF_REF_REGNO (regs->ref));
1181
      while (regs)
1182
        {
1183
          fprintf (file, "%d ", DF_REF_REGNO (regs->ref));
1184
          regs = regs->next;
1185
        }
1186
 
1187
      fprintf (file, ") ");
1188
      mws = mws->next;
1189
    }
1190
}
1191
 
1192
 
1193
static void
1194
df_insn_uid_debug (struct df *df, unsigned int uid,
1195
                   bool follow_chain, FILE *file)
1196
{
1197
  int bbi;
1198
 
1199
  if (DF_INSN_UID_DEFS (df, uid))
1200
    bbi = DF_REF_BBNO (DF_INSN_UID_DEFS (df, uid));
1201
  else if (DF_INSN_UID_USES(df, uid))
1202
    bbi = DF_REF_BBNO (DF_INSN_UID_USES (df, uid));
1203
  else
1204
    bbi = -1;
1205
 
1206
  fprintf (file, "insn %d bb %d luid %d",
1207
           uid, bbi, DF_INSN_UID_LUID (df, uid));
1208
 
1209
  if (DF_INSN_UID_DEFS (df, uid))
1210
    {
1211
      fprintf (file, " defs ");
1212
      df_refs_chain_dump (DF_INSN_UID_DEFS (df, uid), follow_chain, file);
1213
    }
1214
 
1215
  if (DF_INSN_UID_USES (df, uid))
1216
    {
1217
      fprintf (file, " uses ");
1218
      df_refs_chain_dump (DF_INSN_UID_USES (df, uid), follow_chain, file);
1219
    }
1220
 
1221
  if (DF_INSN_UID_MWS (df, uid))
1222
    {
1223
      fprintf (file, " mws ");
1224
      df_mws_dump (DF_INSN_UID_MWS (df, uid), file);
1225
    }
1226
  fprintf (file, "\n");
1227
}
1228
 
1229
 
1230
void
1231
df_insn_debug (struct df *df, rtx insn, bool follow_chain, FILE *file)
1232
{
1233
  df_insn_uid_debug (df, INSN_UID (insn), follow_chain, file);
1234
}
1235
 
1236
void
1237
df_insn_debug_regno (struct df *df, rtx insn, FILE *file)
1238
{
1239
  unsigned int uid;
1240
  int bbi;
1241
 
1242
  uid = INSN_UID (insn);
1243
  if (DF_INSN_UID_DEFS (df, uid))
1244
    bbi = DF_REF_BBNO (DF_INSN_UID_DEFS (df, uid));
1245
  else if (DF_INSN_UID_USES(df, uid))
1246
    bbi = DF_REF_BBNO (DF_INSN_UID_USES (df, uid));
1247
  else
1248
    bbi = -1;
1249
 
1250
  fprintf (file, "insn %d bb %d luid %d defs ",
1251
           uid, bbi, DF_INSN_LUID (df, insn));
1252
  df_regs_chain_dump (df, DF_INSN_UID_DEFS (df, uid), file);
1253
 
1254
  fprintf (file, " uses ");
1255
  df_regs_chain_dump (df, DF_INSN_UID_USES (df, uid), file);
1256
  fprintf (file, "\n");
1257
}
1258
 
1259
void
1260
df_regno_debug (struct df *df, unsigned int regno, FILE *file)
1261
{
1262
  fprintf (file, "reg %d defs ", regno);
1263
  df_regs_chain_dump (df, DF_REG_DEF_GET (df, regno)->reg_chain, file);
1264
  fprintf (file, " uses ");
1265
  df_regs_chain_dump (df, DF_REG_USE_GET (df, regno)->reg_chain, file);
1266
  fprintf (file, "\n");
1267
}
1268
 
1269
 
1270
void
1271
df_ref_debug (struct df_ref *ref, FILE *file)
1272
{
1273
  fprintf (file, "%c%d ",
1274
           DF_REF_REG_DEF_P (ref) ? 'd' : 'u',
1275
           DF_REF_ID (ref));
1276
  fprintf (file, "reg %d bb %d insn %d flag %x chain ",
1277
           DF_REF_REGNO (ref),
1278
           DF_REF_BBNO (ref),
1279
           DF_REF_INSN (ref) ? INSN_UID (DF_REF_INSN (ref)) : -1,
1280
           DF_REF_FLAGS (ref));
1281
  df_chain_dump (DF_REF_CHAIN (ref), file);
1282
  fprintf (file, "\n");
1283
}
1284
 
1285
/* Functions for debugging from GDB.  */
1286
 
1287
void
1288
debug_df_insn (rtx insn)
1289
{
1290
  df_insn_debug (ddf, insn, true, stderr);
1291
  debug_rtx (insn);
1292
}
1293
 
1294
 
1295
void
1296
debug_df_reg (rtx reg)
1297
{
1298
  df_regno_debug (ddf, REGNO (reg), stderr);
1299
}
1300
 
1301
 
1302
void
1303
debug_df_regno (unsigned int regno)
1304
{
1305
  df_regno_debug (ddf, regno, stderr);
1306
}
1307
 
1308
 
1309
void
1310
debug_df_ref (struct df_ref *ref)
1311
{
1312
  df_ref_debug (ref, stderr);
1313
}
1314
 
1315
 
1316
void
1317
debug_df_defno (unsigned int defno)
1318
{
1319
  df_ref_debug (DF_DEFS_GET (ddf, defno), stderr);
1320
}
1321
 
1322
 
1323
void
1324
debug_df_useno (unsigned int defno)
1325
{
1326
  df_ref_debug (DF_USES_GET (ddf, defno), stderr);
1327
}
1328
 
1329
 
1330
void
1331
debug_df_chain (struct df_link *link)
1332
{
1333
  df_chain_dump (link, stderr);
1334
  fputc ('\n', stderr);
1335
}

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