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[/] [openrisc/] [trunk/] [gnu-src/] [gcc-4.5.1/] [gcc/] [graphite-interchange.c] - Blame information for rev 461

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1 280 jeremybenn
/* Interchange heuristics and transform for loop interchange on
2
   polyhedral representation.
3
 
4
   Copyright (C) 2009 Free Software Foundation, Inc.
5
   Contributed by Sebastian Pop <sebastian.pop@amd.com> and
6
   Harsha Jagasia <harsha.jagasia@amd.com>.
7
 
8
This file is part of GCC.
9
 
10
GCC is free software; you can redistribute it and/or modify
11
it under the terms of the GNU General Public License as published by
12
the Free Software Foundation; either version 3, or (at your option)
13
any later version.
14
 
15
GCC is distributed in the hope that it will be useful,
16
but WITHOUT ANY WARRANTY; without even the implied warranty of
17
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
18
GNU General Public License for more details.
19
 
20
You should have received a copy of the GNU General Public License
21
along with GCC; see the file COPYING3.  If not see
22
<http://www.gnu.org/licenses/>.  */
23
#include "config.h"
24
#include "system.h"
25
#include "coretypes.h"
26
#include "tm.h"
27
#include "ggc.h"
28
#include "tree.h"
29
#include "rtl.h"
30
#include "output.h"
31
#include "basic-block.h"
32
#include "diagnostic.h"
33
#include "tree-flow.h"
34
#include "toplev.h"
35
#include "tree-dump.h"
36
#include "timevar.h"
37
#include "cfgloop.h"
38
#include "tree-chrec.h"
39
#include "tree-data-ref.h"
40
#include "tree-scalar-evolution.h"
41
#include "tree-pass.h"
42
#include "domwalk.h"
43
#include "value-prof.h"
44
#include "pointer-set.h"
45
#include "gimple.h"
46
#include "params.h"
47
 
48
#ifdef HAVE_cloog
49
#include "cloog/cloog.h"
50
#include "ppl_c.h"
51
#include "sese.h"
52
#include "graphite-ppl.h"
53
#include "graphite.h"
54
#include "graphite-poly.h"
55
 
56
/* Builds a linear expression, of dimension DIM, representing PDR's
57
   memory access:
58
 
59
   L = r_{n}*r_{n-1}*...*r_{1}*s_{0} + ... + r_{n}*s_{n-1} + s_{n}.
60
 
61
   For an array A[10][20] with two subscript locations s0 and s1, the
62
   linear memory access is 20 * s0 + s1: a stride of 1 in subscript s0
63
   corresponds to a memory stride of 20.
64
 
65
   OFFSET is a number of dimensions to prepend before the
66
   subscript dimensions: s_0, s_1, ..., s_n.
67
 
68
   Thus, the final linear expression has the following format:
69
 
70
   where the expression itself is:
71
   c_0 * s_0 + c_1 * s_1 + ... c_n * s_n.  */
72
 
73
static ppl_Linear_Expression_t
74
build_linearized_memory_access (ppl_dimension_type offset, poly_dr_p pdr)
75
{
76
  ppl_Linear_Expression_t res;
77
  ppl_Linear_Expression_t le;
78
  ppl_dimension_type i;
79
  ppl_dimension_type first = pdr_subscript_dim (pdr, 0);
80
  ppl_dimension_type last = pdr_subscript_dim (pdr, PDR_NB_SUBSCRIPTS (pdr));
81
  Value size, sub_size;
82
  graphite_dim_t dim = offset + pdr_dim (pdr);
83
 
84
  ppl_new_Linear_Expression_with_dimension (&res, dim);
85
 
86
  value_init (size);
87
  value_set_si (size, 1);
88
  value_init (sub_size);
89
  value_set_si (sub_size, 1);
90
 
91
  for (i = last - 1; i >= first; i--)
92
    {
93
      ppl_set_coef_gmp (res, i + offset, size);
94
 
95
      ppl_new_Linear_Expression_with_dimension (&le, dim - offset);
96
      ppl_set_coef (le, i, 1);
97
      ppl_max_for_le_pointset (PDR_ACCESSES (pdr), le, sub_size);
98
      value_multiply (size, size, sub_size);
99
      ppl_delete_Linear_Expression (le);
100
    }
101
 
102
  value_clear (sub_size);
103
  value_clear (size);
104
  return res;
105
}
106
 
107
/* Builds a partial difference equations and inserts them
108
   into pointset powerset polyhedron P.  Polyhedron is assumed
109
   to have the format: T|I|T'|I'|G|S|S'|l1|l2.
110
 
111
   TIME_DEPTH is the time dimension w.r.t. which we are
112
   differentiating.
113
   OFFSET represents the number of dimensions between
114
   columns t_{time_depth} and t'_{time_depth}.
115
   DIM_SCTR is the number of scattering dimensions.  It is
116
   essentially the dimensionality of the T vector.
117
 
118
   The following equations are inserted into the polyhedron P:
119
    | t_1 = t_1'
120
    | ...
121
    | t_{time_depth-1} = t'_{time_depth-1}
122
    | t_{time_depth} = t'_{time_depth} + 1
123
    | t_{time_depth+1} = t'_{time_depth + 1}
124
    | ...
125
    | t_{dim_sctr} = t'_{dim_sctr}.  */
126
 
127
static void
128
build_partial_difference (ppl_Pointset_Powerset_C_Polyhedron_t *p,
129
                          ppl_dimension_type time_depth,
130
                          ppl_dimension_type offset,
131
                          ppl_dimension_type dim_sctr)
132
{
133
  ppl_Constraint_t new_cstr;
134
  ppl_Linear_Expression_t le;
135
  ppl_dimension_type i;
136
  ppl_dimension_type dim;
137
  ppl_Pointset_Powerset_C_Polyhedron_t temp;
138
 
139
  /* Add the equality: t_{time_depth} = t'_{time_depth} + 1.
140
     This is the core part of this alogrithm, since this
141
     constraint asks for the memory access stride (difference)
142
     between two consecutive points in time dimensions.  */
143
 
144
  ppl_Pointset_Powerset_C_Polyhedron_space_dimension (*p, &dim);
145
  ppl_new_Linear_Expression_with_dimension (&le, dim);
146
  ppl_set_coef (le, time_depth, 1);
147
  ppl_set_coef (le, time_depth + offset, -1);
148
  ppl_set_inhomogeneous (le, 1);
149
  ppl_new_Constraint (&new_cstr, le, PPL_CONSTRAINT_TYPE_EQUAL);
150
  ppl_Pointset_Powerset_C_Polyhedron_add_constraint (*p, new_cstr);
151
  ppl_delete_Linear_Expression (le);
152
  ppl_delete_Constraint (new_cstr);
153
 
154
  /* Add equalities:
155
     | t1 = t1'
156
     | ...
157
     | t_{time_depth-1} = t'_{time_depth-1}
158
     | t_{time_depth+1} = t'_{time_depth+1}
159
     | ...
160
     | t_{dim_sctr} = t'_{dim_sctr}
161
 
162
     This means that all the time dimensions are equal except for
163
     time_depth, where the constraint is t_{depth} = t'_{depth} + 1
164
     step.  More to this: we should be carefull not to add equalities
165
     to the 'coupled' dimensions, which happens when the one dimension
166
     is stripmined dimension, and the other dimension corresponds
167
     to the point loop inside stripmined dimension.  */
168
 
169
  ppl_new_Pointset_Powerset_C_Polyhedron_from_Pointset_Powerset_C_Polyhedron (&temp, *p);
170
 
171
  for (i = 0; i < dim_sctr; i++)
172
    if (i != time_depth)
173
      {
174
        ppl_new_Linear_Expression_with_dimension (&le, dim);
175
        ppl_set_coef (le, i, 1);
176
        ppl_set_coef (le, i + offset, -1);
177
        ppl_new_Constraint (&new_cstr, le, PPL_CONSTRAINT_TYPE_EQUAL);
178
        ppl_Pointset_Powerset_C_Polyhedron_add_constraint (temp, new_cstr);
179
 
180
        if (ppl_Pointset_Powerset_C_Polyhedron_is_empty (temp))
181
          {
182
            ppl_delete_Pointset_Powerset_C_Polyhedron (temp);
183
            ppl_new_Pointset_Powerset_C_Polyhedron_from_Pointset_Powerset_C_Polyhedron (&temp, *p);
184
          }
185
        else
186
          ppl_Pointset_Powerset_C_Polyhedron_add_constraint (*p, new_cstr);
187
        ppl_delete_Linear_Expression (le);
188
        ppl_delete_Constraint (new_cstr);
189
      }
190
 
191
  ppl_delete_Pointset_Powerset_C_Polyhedron (temp);
192
}
193
 
194
 
195
/* Set STRIDE to the stride of PDR in memory by advancing by one in
196
   the loop at DEPTH.  */
197
 
198
static void
199
pdr_stride_in_loop (Value stride, graphite_dim_t depth, poly_dr_p pdr)
200
{
201
  ppl_dimension_type time_depth;
202
  ppl_Linear_Expression_t le, lma;
203
  ppl_Constraint_t new_cstr;
204
  ppl_dimension_type i, *map;
205
  ppl_Pointset_Powerset_C_Polyhedron_t p1, p2, sctr;
206
  graphite_dim_t nb_subscripts = PDR_NB_SUBSCRIPTS (pdr) + 1;
207
  poly_bb_p pbb = PDR_PBB (pdr);
208
  ppl_dimension_type offset = pbb_nb_scattering_transform (pbb)
209
                              + pbb_nb_local_vars (pbb)
210
                              + pbb_dim_iter_domain (pbb);
211
  ppl_dimension_type offsetg = offset + pbb_nb_params (pbb);
212
  ppl_dimension_type dim_sctr = pbb_nb_scattering_transform (pbb)
213
                                + pbb_nb_local_vars (pbb);
214
  ppl_dimension_type dim_L1 = offset + offsetg + 2 * nb_subscripts;
215
  ppl_dimension_type dim_L2 = offset + offsetg + 2 * nb_subscripts + 1;
216
  ppl_dimension_type new_dim = offset + offsetg + 2 * nb_subscripts + 2;
217
 
218
  /* The resulting polyhedron should have the following format:
219
     T|I|T'|I'|G|S|S'|l1|l2
220
     where:
221
     | T = t_1..t_{dim_sctr}
222
     | I = i_1..i_{dim_iter_domain}
223
     | T'= t'_1..t'_{dim_sctr}
224
     | I'= i'_1..i'_{dim_iter_domain}
225
     | G = g_1..g_{nb_params}
226
     | S = s_1..s_{nb_subscripts}
227
     | S'= s'_1..s'_{nb_subscripts}
228
     | l1 and l2 are scalars.
229
 
230
     Some invariants:
231
     offset = dim_sctr + dim_iter_domain + nb_local_vars
232
     offsetg = dim_sctr + dim_iter_domain + nb_local_vars + nb_params.  */
233
 
234
  /* Construct the T|I|0|0|G|0|0|0|0 part.  */
235
  {
236
    ppl_new_Pointset_Powerset_C_Polyhedron_from_C_Polyhedron
237
      (&sctr, PBB_TRANSFORMED_SCATTERING (pbb));
238
    ppl_Pointset_Powerset_C_Polyhedron_add_space_dimensions_and_embed
239
      (sctr, 2 * nb_subscripts + 2);
240
    ppl_insert_dimensions_pointset (sctr, offset, offset);
241
  }
242
 
243
  /* Construct the 0|I|0|0|G|S|0|0|0 part.  */
244
  {
245
    ppl_new_Pointset_Powerset_C_Polyhedron_from_Pointset_Powerset_C_Polyhedron
246
      (&p1, PDR_ACCESSES (pdr));
247
    ppl_Pointset_Powerset_C_Polyhedron_add_space_dimensions_and_embed
248
      (p1, nb_subscripts + 2);
249
    ppl_insert_dimensions_pointset (p1, 0, dim_sctr);
250
    ppl_insert_dimensions_pointset (p1, offset, offset);
251
  }
252
 
253
  /* Construct the 0|0|0|0|0|S|0|l1|0 part.  */
254
  {
255
    lma = build_linearized_memory_access (offset + dim_sctr, pdr);
256
    ppl_set_coef (lma, dim_L1, -1);
257
    ppl_new_Constraint (&new_cstr, lma, PPL_CONSTRAINT_TYPE_EQUAL);
258
    ppl_Pointset_Powerset_C_Polyhedron_add_constraint (p1, new_cstr);
259
    ppl_delete_Linear_Expression (lma);
260
    ppl_delete_Constraint (new_cstr);
261
  }
262
 
263
  /* Now intersect all the parts to get the polyhedron P1:
264
     T|I|0|0|G|0|0|0 |0
265
     0|I|0|0|G|S|0|0 |0
266
     0|0|0|0|0|S|0|l1|0
267
     ------------------
268
     T|I|0|0|G|S|0|l1|0.  */
269
 
270
  ppl_Pointset_Powerset_C_Polyhedron_intersection_assign (p1, sctr);
271
  ppl_delete_Pointset_Powerset_C_Polyhedron (sctr);
272
 
273
  /* Build P2, which would have the following form:
274
     0|0|T'|I'|G|0|S'|0|l2
275
 
276
     P2 is built, by remapping the P1 polyhedron:
277
     T|I|0|0|G|S|0|l1|0
278
 
279
     using the following mapping:
280
     T->T'
281
     I->I'
282
     S->S'
283
     l1->l2.  */
284
  {
285
    ppl_new_Pointset_Powerset_C_Polyhedron_from_Pointset_Powerset_C_Polyhedron
286
      (&p2, p1);
287
 
288
    map = ppl_new_id_map (new_dim);
289
 
290
    /* TI -> T'I'.  */
291
    for (i = 0; i < offset; i++)
292
      ppl_interchange (map, i, i + offset);
293
 
294
    /* l1 -> l2.  */
295
    ppl_interchange (map, dim_L1, dim_L2);
296
 
297
    /* S -> S'.  */
298
    for (i = 0; i < nb_subscripts; i++)
299
      ppl_interchange (map, offset + offsetg + i,
300
                       offset + offsetg + nb_subscripts + i);
301
 
302
    ppl_Pointset_Powerset_C_Polyhedron_map_space_dimensions (p2, map, new_dim);
303
    free (map);
304
  }
305
 
306
  time_depth = psct_dynamic_dim (pbb, depth);
307
 
308
  /* P1 = P1 inter P2.  */
309
  ppl_Pointset_Powerset_C_Polyhedron_intersection_assign (p1, p2);
310
  build_partial_difference (&p1, time_depth, offset, dim_sctr);
311
 
312
  /* Maximise the expression L2 - L1.  */
313
  {
314
    ppl_new_Linear_Expression_with_dimension (&le, new_dim);
315
    ppl_set_coef (le, dim_L2, 1);
316
    ppl_set_coef (le, dim_L1, -1);
317
    ppl_max_for_le_pointset (p1, le, stride);
318
  }
319
 
320
  if (dump_file && (dump_flags & TDF_DETAILS))
321
    {
322
      fprintf (dump_file, "\nStride in BB_%d, DR_%d, depth %d:",
323
               pbb_index (pbb), PDR_ID (pdr), (int) depth);
324
      value_print (dump_file, "  %s ", stride);
325
    }
326
 
327
  ppl_delete_Pointset_Powerset_C_Polyhedron (p1);
328
  ppl_delete_Pointset_Powerset_C_Polyhedron (p2);
329
  ppl_delete_Linear_Expression (le);
330
}
331
 
332
 
333
/* Sets STRIDES to the sum of all the strides of the data references
334
   accessed in LOOP at DEPTH.  */
335
 
336
static void
337
memory_strides_in_loop_1 (lst_p loop, graphite_dim_t depth, Value strides)
338
{
339
  int i, j;
340
  lst_p l;
341
  poly_dr_p pdr;
342
  Value s, n;
343
 
344
  value_init (s);
345
  value_init (n);
346
 
347
  for (j = 0; VEC_iterate (lst_p, LST_SEQ (loop), j, l); j++)
348
    if (LST_LOOP_P (l))
349
      memory_strides_in_loop_1 (l, depth, strides);
350
    else
351
      for (i = 0; VEC_iterate (poly_dr_p, PBB_DRS (LST_PBB (l)), i, pdr); i++)
352
        {
353
          pdr_stride_in_loop (s, depth, pdr);
354
          value_set_si (n, PDR_NB_REFS (pdr));
355
          value_multiply (s, s, n);
356
          value_addto (strides, strides, s);
357
        }
358
 
359
  value_clear (s);
360
  value_clear (n);
361
}
362
 
363
/* Sets STRIDES to the sum of all the strides of the data references
364
   accessed in LOOP at DEPTH.  */
365
 
366
static void
367
memory_strides_in_loop (lst_p loop, graphite_dim_t depth, Value strides)
368
{
369
  if (value_mone_p (loop->memory_strides))
370
    {
371
      value_set_si (strides, 0);
372
      memory_strides_in_loop_1 (loop, depth, strides);
373
    }
374
  else
375
    value_assign (strides, loop->memory_strides);
376
}
377
 
378
/* Return true when the interchange of loops LOOP1 and LOOP2 is
379
   profitable.
380
 
381
   Example:
382
 
383
   | int a[100][100];
384
   |
385
   | int
386
   | foo (int N)
387
   | {
388
   |   int j;
389
   |   int i;
390
   |
391
   |   for (i = 0; i < N; i++)
392
   |     for (j = 0; j < N; j++)
393
   |       a[j][2 * i] += 1;
394
   |
395
   |   return a[N][12];
396
   | }
397
 
398
   The data access A[j][i] is described like this:
399
 
400
   | i   j   N   a  s0  s1   1
401
   | 0   0   0   1   0   0  -5    = 0
402
   | 0  -1   0   0   1   0   0    = 0
403
   |-2   0   0   0   0   1   0    = 0
404
   | 0   0   0   0   1   0   0   >= 0
405
   | 0   0   0   0   0   1   0   >= 0
406
   | 0   0   0   0  -1   0 100   >= 0
407
   | 0   0   0   0   0  -1 100   >= 0
408
 
409
   The linearized memory access L to A[100][100] is:
410
 
411
   | i   j   N   a  s0  s1   1
412
   | 0   0   0   0 100   1   0
413
 
414
   TODO: the shown format is not valid as it does not show the fact
415
   that the iteration domain "i j" is transformed using the scattering.
416
 
417
   Next, to measure the impact of iterating once in loop "i", we build
418
   a maximization problem: first, we add to DR accesses the dimensions
419
   k, s2, s3, L1 = 100 * s0 + s1, L2, and D1: this is the polyhedron P1.
420
   L1 and L2 are the linearized memory access functions.
421
 
422
   | i   j   N   a  s0  s1   k  s2  s3  L1  L2  D1   1
423
   | 0   0   0   1   0   0   0   0   0   0   0   0  -5    = 0  alias = 5
424
   | 0  -1   0   0   1   0   0   0   0   0   0   0   0    = 0  s0 = j
425
   |-2   0   0   0   0   1   0   0   0   0   0   0   0    = 0  s1 = 2 * i
426
   | 0   0   0   0   1   0   0   0   0   0   0   0   0   >= 0
427
   | 0   0   0   0   0   1   0   0   0   0   0   0   0   >= 0
428
   | 0   0   0   0  -1   0   0   0   0   0   0   0 100   >= 0
429
   | 0   0   0   0   0  -1   0   0   0   0   0   0 100   >= 0
430
   | 0   0   0   0 100   1   0   0   0  -1   0   0   0    = 0  L1 = 100 * s0 + s1
431
 
432
   Then, we generate the polyhedron P2 by interchanging the dimensions
433
   (s0, s2), (s1, s3), (L1, L2), (k, i)
434
 
435
   | i   j   N   a  s0  s1   k  s2  s3  L1  L2  D1   1
436
   | 0   0   0   1   0   0   0   0   0   0   0   0  -5    = 0  alias = 5
437
   | 0  -1   0   0   0   0   0   1   0   0   0   0   0    = 0  s2 = j
438
   | 0   0   0   0   0   0  -2   0   1   0   0   0   0    = 0  s3 = 2 * k
439
   | 0   0   0   0   0   0   0   1   0   0   0   0   0   >= 0
440
   | 0   0   0   0   0   0   0   0   1   0   0   0   0   >= 0
441
   | 0   0   0   0   0   0   0  -1   0   0   0   0 100   >= 0
442
   | 0   0   0   0   0   0   0   0  -1   0   0   0 100   >= 0
443
   | 0   0   0   0   0   0   0 100   1   0  -1   0   0    = 0  L2 = 100 * s2 + s3
444
 
445
   then we add to P2 the equality k = i + 1:
446
 
447
   |-1   0   0   0   0   0   1   0   0   0   0   0  -1    = 0  k = i + 1
448
 
449
   and finally we maximize the expression "D1 = max (P1 inter P2, L2 - L1)".
450
 
451
   Similarly, to determine the impact of one iteration on loop "j", we
452
   interchange (k, j), we add "k = j + 1", and we compute D2 the
453
   maximal value of the difference.
454
 
455
   Finally, the profitability test is D1 < D2: if in the outer loop
456
   the strides are smaller than in the inner loop, then it is
457
   profitable to interchange the loops at DEPTH1 and DEPTH2.  */
458
 
459
static bool
460
lst_interchange_profitable_p (lst_p loop1, lst_p loop2)
461
{
462
  Value d1, d2;
463
  bool res;
464
 
465
  gcc_assert (loop1 && loop2
466
              && LST_LOOP_P (loop1) && LST_LOOP_P (loop2)
467
              && lst_depth (loop1) < lst_depth (loop2));
468
 
469
  value_init (d1);
470
  value_init (d2);
471
 
472
  memory_strides_in_loop (loop1, lst_depth (loop1), d1);
473
  memory_strides_in_loop (loop2, lst_depth (loop2), d2);
474
 
475
  res = value_lt (d1, d2);
476
 
477
  value_clear (d1);
478
  value_clear (d2);
479
 
480
  return res;
481
}
482
 
483
/* Interchanges the loops at DEPTH1 and DEPTH2 of the original
484
   scattering and assigns the resulting polyhedron to the transformed
485
   scattering.  */
486
 
487
static void
488
pbb_interchange_loop_depths (graphite_dim_t depth1, graphite_dim_t depth2,
489
                             poly_bb_p pbb)
490
{
491
  ppl_dimension_type i, dim;
492
  ppl_dimension_type *map;
493
  ppl_Polyhedron_t poly = PBB_TRANSFORMED_SCATTERING (pbb);
494
  ppl_dimension_type dim1 = psct_dynamic_dim (pbb, depth1);
495
  ppl_dimension_type dim2 = psct_dynamic_dim (pbb, depth2);
496
 
497
  ppl_Polyhedron_space_dimension (poly, &dim);
498
  map = (ppl_dimension_type *) XNEWVEC (ppl_dimension_type, dim);
499
 
500
  for (i = 0; i < dim; i++)
501
    map[i] = i;
502
 
503
  map[dim1] = dim2;
504
  map[dim2] = dim1;
505
 
506
  ppl_Polyhedron_map_space_dimensions (poly, map, dim);
507
  free (map);
508
}
509
 
510
/* Apply the interchange of loops at depths DEPTH1 and DEPTH2 to all
511
   the statements below LST.  */
512
 
513
static void
514
lst_apply_interchange (lst_p lst, int depth1, int depth2)
515
{
516
  if (!lst)
517
    return;
518
 
519
  if (LST_LOOP_P (lst))
520
    {
521
      int i;
522
      lst_p l;
523
 
524
      for (i = 0; VEC_iterate (lst_p, LST_SEQ (lst), i, l); i++)
525
        lst_apply_interchange (l, depth1, depth2);
526
    }
527
  else
528
    pbb_interchange_loop_depths (depth1, depth2, LST_PBB (lst));
529
}
530
 
531
/* Return true when the nest starting at LOOP1 and ending on LOOP2 is
532
   perfect: i.e. there are no sequence of statements.  */
533
 
534
static bool
535
lst_perfectly_nested_p (lst_p loop1, lst_p loop2)
536
{
537
  if (loop1 == loop2)
538
    return true;
539
 
540
  if (!LST_LOOP_P (loop1))
541
    return false;
542
 
543
  return VEC_length (lst_p, LST_SEQ (loop1)) == 1
544
    && lst_perfectly_nested_p (VEC_index (lst_p, LST_SEQ (loop1), 0), loop2);
545
}
546
 
547
/* Transform the loop nest between LOOP1 and LOOP2 into a perfect
548
   nest.  To continue the naming tradition, this function is called
549
   after perfect_nestify.  NEST is set to the perfectly nested loop
550
   that is created.  BEFORE/AFTER are set to the loops distributed
551
   before/after the loop NEST.  */
552
 
553
static void
554
lst_perfect_nestify (lst_p loop1, lst_p loop2, lst_p *before,
555
                     lst_p *nest, lst_p *after)
556
{
557
  poly_bb_p first, last;
558
 
559
  gcc_assert (loop1 && loop2
560
              && loop1 != loop2
561
              && LST_LOOP_P (loop1) && LST_LOOP_P (loop2));
562
 
563
  first = LST_PBB (lst_find_first_pbb (loop2));
564
  last = LST_PBB (lst_find_last_pbb (loop2));
565
 
566
  *before = copy_lst (loop1);
567
  *nest = copy_lst (loop1);
568
  *after = copy_lst (loop1);
569
 
570
  lst_remove_all_before_including_pbb (*before, first, false);
571
  lst_remove_all_before_including_pbb (*after, last, true);
572
 
573
  lst_remove_all_before_excluding_pbb (*nest, first, true);
574
  lst_remove_all_before_excluding_pbb (*nest, last, false);
575
 
576
  if (lst_empty_p (*before))
577
    {
578
      free_lst (*before);
579
      *before = NULL;
580
    }
581
  if (lst_empty_p (*after))
582
    {
583
      free_lst (*after);
584
      *after = NULL;
585
    }
586
  if (lst_empty_p (*nest))
587
    {
588
      free_lst (*nest);
589
      *nest = NULL;
590
    }
591
}
592
 
593
/* Try to interchange LOOP1 with LOOP2 for all the statements of the
594
   body of LOOP2.  LOOP1 contains LOOP2.  Return true if it did the
595
   interchange.  */
596
 
597
static bool
598
lst_try_interchange_loops (scop_p scop, lst_p loop1, lst_p loop2)
599
{
600
  int depth1 = lst_depth (loop1);
601
  int depth2 = lst_depth (loop2);
602
  lst_p transformed;
603
 
604
  lst_p before = NULL, nest = NULL, after = NULL;
605
 
606
  if (!lst_interchange_profitable_p (loop1, loop2))
607
    return false;
608
 
609
  if (!lst_perfectly_nested_p (loop1, loop2))
610
    lst_perfect_nestify (loop1, loop2, &before, &nest, &after);
611
 
612
  lst_apply_interchange (loop2, depth1, depth2);
613
 
614
  /* Sync the transformed LST information and the PBB scatterings
615
     before using the scatterings in the data dependence analysis.  */
616
  if (before || nest || after)
617
    {
618
      transformed = lst_substitute_3 (SCOP_TRANSFORMED_SCHEDULE (scop), loop1,
619
                                      before, nest, after);
620
      lst_update_scattering (transformed);
621
      free_lst (transformed);
622
    }
623
 
624
  if (graphite_legal_transform (scop))
625
    {
626
      if (dump_file && (dump_flags & TDF_DETAILS))
627
        fprintf (dump_file,
628
                 "Loops at depths %d and %d will be interchanged.\n",
629
                 depth1, depth2);
630
 
631
      /* Transform the SCOP_TRANSFORMED_SCHEDULE of the SCOP.  */
632
      lst_insert_in_sequence (before, loop1, true);
633
      lst_insert_in_sequence (after, loop1, false);
634
 
635
      if (nest)
636
        {
637
          lst_replace (loop1, nest);
638
          free_lst (loop1);
639
        }
640
 
641
      return true;
642
    }
643
 
644
  /* Undo the transform.  */
645
  free_lst (before);
646
  free_lst (nest);
647
  free_lst (after);
648
  lst_apply_interchange (loop2, depth2, depth1);
649
  return false;
650
}
651
 
652
/* Selects the inner loop in LST_SEQ (INNER_FATHER) to be interchanged
653
   with the loop OUTER in LST_SEQ (OUTER_FATHER).  */
654
 
655
static bool
656
lst_interchange_select_inner (scop_p scop, lst_p outer_father, int outer,
657
                              lst_p inner_father)
658
{
659
  int inner;
660
  lst_p loop1, loop2;
661
 
662
  gcc_assert (outer_father
663
              && LST_LOOP_P (outer_father)
664
              && LST_LOOP_P (VEC_index (lst_p, LST_SEQ (outer_father), outer))
665
              && inner_father
666
              && LST_LOOP_P (inner_father));
667
 
668
  loop1 = VEC_index (lst_p, LST_SEQ (outer_father), outer);
669
 
670
  for (inner = 0; VEC_iterate (lst_p, LST_SEQ (inner_father), inner, loop2); inner++)
671
    if (LST_LOOP_P (loop2)
672
        && (lst_try_interchange_loops (scop, loop1, loop2)
673
            || lst_interchange_select_inner (scop, outer_father, outer, loop2)))
674
      return true;
675
 
676
  return false;
677
}
678
 
679
/* Interchanges all the loops of LOOP and the loops of its body that
680
   are considered profitable to interchange.  Return true if it did
681
   interchanged some loops.  OUTER is the index in LST_SEQ (LOOP) that
682
   points to the next outer loop to be considered for interchange.  */
683
 
684
static bool
685
lst_interchange_select_outer (scop_p scop, lst_p loop, int outer)
686
{
687
  lst_p l;
688
  bool res = false;
689
  int i = 0;
690
  lst_p father;
691
 
692
  if (!loop || !LST_LOOP_P (loop))
693
    return false;
694
 
695
  father = LST_LOOP_FATHER (loop);
696
  if (father)
697
    {
698
      while (lst_interchange_select_inner (scop, father, outer, loop))
699
        {
700
          res = true;
701
          loop = VEC_index (lst_p, LST_SEQ (father), outer);
702
        }
703
    }
704
 
705
  if (LST_LOOP_P (loop))
706
    for (i = 0; VEC_iterate (lst_p, LST_SEQ (loop), i, l); i++)
707
      if (LST_LOOP_P (l))
708
        res |= lst_interchange_select_outer (scop, l, i);
709
 
710
  return res;
711
}
712
 
713
/* Interchanges all the loop depths that are considered profitable for SCOP.  */
714
 
715
bool
716
scop_do_interchange (scop_p scop)
717
{
718
  bool res = lst_interchange_select_outer
719
    (scop, SCOP_TRANSFORMED_SCHEDULE (scop), 0);
720
 
721
  lst_update_scattering (SCOP_TRANSFORMED_SCHEDULE (scop));
722
 
723
  return res;
724
}
725
 
726
 
727
#endif
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