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1 /* Rename SSA copies.
2 Copyright (C) 2004-2015 Free Software Foundation, Inc.
3 Contributed by Andrew MacLeod <amacleod@redhat.com>
5 This file is part of GCC.
7 GCC is free software; you can redistribute it and/or modify
8 it under the terms of the GNU General Public License as published by
9 the Free Software Foundation; either version 3, or (at your option)
10 any later version.
12 GCC is distributed in the hope that it will be useful,
13 but WITHOUT ANY WARRANTY; without even the implied warranty of
14 MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
15 GNU General Public License for more details.
17 You should have received a copy of the GNU General Public License
18 along with GCC; see the file COPYING3. If not see
19 <http://www.gnu.org/licenses/>. */
74 static struct
75 {
76 /* Number of copies coalesced. */
80 /* The following routines implement the SSA copy renaming phase.
82 This optimization looks for copies between 2 SSA_NAMES, either through a
83 direct copy, or an implicit one via a PHI node result and its arguments.
85 Each copy is examined to determine if it is possible to rename the base
86 variable of one of the operands to the same variable as the other operand.
87 i.e.
88 T.3_5 = <blah>
89 a_1 = T.3_5
91 If this copy couldn't be copy propagated, it could possibly remain in the
92 program throughout the optimization phases. After SSA->normal, it would
93 become:
95 T.3 = <blah>
96 a = T.3
98 Since T.3_5 is distinct from all other SSA versions of T.3, there is no
99 fundamental reason why the base variable needs to be T.3, subject to
100 certain restrictions. This optimization attempts to determine if we can
101 change the base variable on copies like this, and result in code such as:
103 a_5 = <blah>
104 a_1 = a_5
106 This gives the SSA->normal pass a shot at coalescing a_1 and a_5. If it is
107 possible, the copy goes away completely. If it isn't possible, a new temp
108 will be created for a_5, and you will end up with the exact same code:
110 a.8 = <blah>
111 a = a.8
113 The other benefit of performing this optimization relates to what variables
114 are chosen in copies. Gimplification of the program uses temporaries for
115 a lot of things. expressions like
117 a_1 = <blah>
118 <blah2> = a_1
120 get turned into
122 T.3_5 = <blah>
123 a_1 = T.3_5
124 <blah2> = a_1
126 Copy propagation is done in a forward direction, and if we can propagate
127 through the copy, we end up with:
129 T.3_5 = <blah>
130 <blah2> = T.3_5
132 The copy is gone, but so is all reference to the user variable 'a'. By
133 performing this optimization, we would see the sequence:
135 a_5 = <blah>
136 a_1 = a_5
137 <blah2> = a_1
139 which copy propagation would then turn into:
141 a_5 = <blah>
142 <blah2> = a_5
144 and so we still retain the user variable whenever possible. */
147 /* Coalesce the partitions in MAP representing VAR1 and VAR2 if it is valid.
148 Choose a representative for the partition, and send debug info to DEBUG. */
150 static void
152 {
168 {
174 }
180 {
184 }
193 /* Don't coalesce if one of the variables occurs in an abnormal PHI. */
197 {
201 }
203 /* Partitions already have the same root, simply merge them. */
205 {
210 }
212 /* Never attempt to coalesce 2 different parameters. */
215 {
219 }
223 {
227 }
232 /* Refrain from coalescing user variables, if requested. */
234 {
240 {
244 }
245 else
247 }
249 /* If both values have default defs, we can't coalesce. If only one has a
250 tag, make sure that variable is the new root partition. */
252 {
254 {
258 }
259 else
260 {
263 }
264 }
266 {
269 }
271 /* Do not coalesce if we cannot assign a symbol to the partition. */
274 {
278 }
280 /* Don't coalesce if the new chosen root variable would be read-only.
281 If both ign1 && ign2, then the root var of the larger partition
282 wins, so reject in that case if any of the root vars is TREE_READONLY.
283 Otherwise reject only if the root var, on which replace_ssa_name_symbol
284 will be called below, is readonly. */
287 {
291 }
293 /* Don't coalesce if the two variables aren't type compatible . */
295 /* There is a disconnect between the middle-end type-system and
296 VRP, avoid coalescing enum types with different bounds. */
300 {
304 }
306 /* Merge the two partitions. */
309 /* Set the root variable of the partition to the better choice, if there is
310 one. */
315 else
319 {
322 TDF_SLIM);
324 }
325 }
331 {
341 };
344 {
348 {}
350 /* opt_pass methods: */
357 /* This function will make a pass through the IL, and attempt to coalesce any
358 SSA versions which occur in PHI's or copies. Coalescing is accomplished by
359 changing the underlying root variable of all coalesced version. This will
360 then cause the SSA->normal pass to attempt to coalesce them all to the same
361 variable. */
363 unsigned int
365 {
366 var_map map;
367 basic_block bb;
369 gimple stmt;
377 else
383 {
384 /* Scan for real copies. */
387 {
390 {
395 }
396 }
397 }
400 {
401 /* Treat PHI nodes as copies between the result and each argument. */
404 {
406 tree res;
410 /* Do not process virtual SSA_NAMES. */
414 /* Make sure to only use the same partition for an argument
415 as the result but never the other way around. */
419 {
423 debug);
424 }
425 /* Else if all arguments are in the same partition try to merge
426 it with the result. */
427 else
428 {
432 {
435 {
438 }
440 {
444 }
448 {
451 }
452 }
456 debug);
457 }
458 }
459 }
464 /* Now one more pass to make all elements of a partition share the same
465 root variable. */
468 {
476 {
482 }
485 }
491 }
495 gimple_opt_pass *
497 {
499 }