1 /* Graph coloring register allocator
2 Copyright (C) 2001, 2002, 2003, 2004 Free Software Foundation, Inc.
3 Contributed by Michael Matz <matz@suse.de>
4 and Daniel Berlin <dan@cgsoftware.com>
6 This file is part of GCC.
8 GCC is free software; you can redistribute it and/or modify it under the
9 terms of the GNU General Public License as published by the Free Software
10 Foundation; either version 2, or (at your option) any later version.
12 GCC is distributed in the hope that it will be useful, but WITHOUT ANY
13 WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS
14 FOR A PARTICULAR PURPOSE. See the GNU General Public License for more
17 You should have received a copy of the GNU General Public License along
18 with GCC; see the file COPYING. If not, write to the Free Software
19 Foundation, 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA. */
23 #include "coretypes.h"
27 #include "insn-config.h"
32 #include "hard-reg-set.h"
33 #include "basic-block.h"
39 /* This file is part of the graph coloring register allocator.
40 It deals with building the interference graph. When rebuilding
41 the graph for a function after spilling, we rebuild only those
42 parts needed, i.e. it works incrementally.
44 The first part (the functions called from build_web_parts_and_conflicts()
45 ) constructs a web_part for each pseudo register reference in the insn
46 stream, then goes backward from each use, until it reaches defs for that
47 pseudo. While going back it remember seen defs for other registers as
48 conflicts. By connecting the uses and defs, which reach each other, webs
49 (or live ranges) are built conceptually.
51 The second part (make_webs() and children) deals with converting that
52 structure to the nodes and edges, on which our interference graph is
53 built. For each root web part constructed above, an instance of struct
54 web is created. For all subregs of pseudos, which matter for allocation,
55 a subweb of the corresponding super web is built. Finally all the
56 conflicts noted in the first part (as bitmaps) are transformed into real
59 As part of that process the webs are also classified (their spill cost
60 is calculated, and if they are spillable at all, and if not, for what
61 reason; or if they are rematerializable), and move insns are collected,
62 which are potentially coalescable.
64 The top-level entry of this file (build_i_graph) puts it all together,
65 and leaves us with a complete interference graph, which just has to
71 static unsigned HOST_WIDE_INT
rtx_to_undefined (rtx
);
72 static bitmap
find_sub_conflicts (struct web_part
*, unsigned int);
73 static bitmap
get_sub_conflicts (struct web_part
*, unsigned int);
74 static unsigned int undef_to_size_word (rtx
, unsigned HOST_WIDE_INT
*);
75 static bitmap
undef_to_bitmap (struct web_part
*,
76 unsigned HOST_WIDE_INT
*);
77 static struct web_part
* find_web_part_1 (struct web_part
*);
78 static struct web_part
* union_web_part_roots
79 (struct web_part
*, struct web_part
*);
80 static int defuse_overlap_p_1 (rtx
, struct curr_use
*);
81 static int live_out_1 (struct df
*, struct curr_use
*, rtx
);
82 static int live_out (struct df
*, struct curr_use
*, rtx
);
83 static rtx
live_in_edge ( struct df
*, struct curr_use
*, edge
);
84 static void live_in (struct df
*, struct curr_use
*, rtx
);
85 static int copy_insn_p (rtx
, rtx
*, rtx
*);
86 static void remember_move (rtx
);
87 static void handle_asm_insn (struct df
*, rtx
);
88 static void prune_hardregs_for_mode (HARD_REG_SET
*, enum machine_mode
);
89 static void init_one_web_common (struct web
*, rtx
);
90 static void init_one_web (struct web
*, rtx
);
91 static void reinit_one_web (struct web
*, rtx
);
92 static struct web
* add_subweb (struct web
*, rtx
);
93 static struct web
* add_subweb_2 (struct web
*, unsigned int);
94 static void init_web_parts (struct df
*);
95 static void copy_conflict_list (struct web
*);
96 static void add_conflict_edge (struct web
*, struct web
*);
97 static void build_inverse_webs (struct web
*);
98 static void copy_web (struct web
*, struct web_link
**);
99 static void compare_and_free_webs (struct web_link
**);
100 static void init_webs_defs_uses (void);
101 static unsigned int parts_to_webs_1 (struct df
*, struct web_link
**,
103 static void parts_to_webs (struct df
*);
104 static void reset_conflicts (void);
106 static void check_conflict_numbers (void)
108 static void conflicts_between_webs (struct df
*);
109 static void remember_web_was_spilled (struct web
*);
110 static void detect_spill_temps (void);
111 static int contains_pseudo (rtx
);
112 static int want_to_remat (rtx x
);
113 static void detect_remat_webs (void);
114 static void determine_web_costs (void);
115 static void detect_webs_set_in_cond_jump (void);
116 static void make_webs (struct df
*);
117 static void moves_to_webs (struct df
*);
118 static void connect_rmw_web_parts (struct df
*);
119 static void update_regnos_mentioned (void);
120 static void livethrough_conflicts_bb (basic_block
);
121 static void init_bb_info (void);
122 static void free_bb_info (void);
123 static void build_web_parts_and_conflicts (struct df
*);
126 /* A sbitmap of DF_REF_IDs of uses, which are live over an abnormal
128 static sbitmap live_over_abnormal
;
130 /* To cache if we already saw a certain edge while analyzing one
131 use, we use a tick count incremented per use. */
132 static unsigned int visited_pass
;
134 /* A sbitmap of UIDs of move insns, which we already analyzed. */
135 static sbitmap move_handled
;
137 /* One such structed is allocated per insn, and traces for the currently
138 analyzed use, which web part belongs to it, and how many bytes of
139 it were still undefined when that insn was reached. */
143 unsigned HOST_WIDE_INT undefined
;
145 /* Indexed by UID. */
146 static struct visit_trace
*visit_trace
;
148 /* Per basic block we have one such structure, used to speed up
149 the backtracing of uses. */
152 /* The value of visited_pass, as the first insn of this BB was reached
153 the last time. If this equals the current visited_pass, then
154 undefined is valid. Otherwise not. */
156 /* The still undefined bytes at that time. The use to which this is
157 relative is the current use. */
158 unsigned HOST_WIDE_INT undefined
;
159 /* Bit regno is set, if that regno is mentioned in this BB as a def, or
160 the source of a copy insn. In these cases we can not skip the whole
161 block if we reach it from the end. */
162 bitmap regnos_mentioned
;
163 /* If a use reaches the end of a BB, and that BB doesn't mention its
164 regno, we skip the block, and remember the ID of that use
165 as living throughout the whole block. */
166 bitmap live_throughout
;
167 /* The content of the aux field before placing a pointer to this
172 /* We need a fast way to describe a certain part of a register.
173 Therefore we put together the size and offset (in bytes) in one
175 #define BL_TO_WORD(b, l) ((((b) & 0xFFFF) << 16) | ((l) & 0xFFFF))
176 #define BYTE_BEGIN(i) (((unsigned int)(i) >> 16) & 0xFFFF)
177 #define BYTE_LENGTH(i) ((unsigned int)(i) & 0xFFFF)
179 /* For a REG or SUBREG expression X return the size/offset pair
185 unsigned int len
, beg
;
186 len
= GET_MODE_SIZE (GET_MODE (x
));
187 beg
= (GET_CODE (x
) == SUBREG
) ? SUBREG_BYTE (x
) : 0;
188 return BL_TO_WORD (beg
, len
);
191 /* X is a REG or SUBREG rtx. Return the bytes it touches as a bitmask. */
193 static unsigned HOST_WIDE_INT
194 rtx_to_undefined (rtx x
)
196 unsigned int len
, beg
;
197 unsigned HOST_WIDE_INT ret
;
198 len
= GET_MODE_SIZE (GET_MODE (x
));
199 beg
= (GET_CODE (x
) == SUBREG
) ? SUBREG_BYTE (x
) : 0;
200 ret
= ~ ((unsigned HOST_WIDE_INT
) 0);
201 ret
= (~(ret
<< len
)) << beg
;
205 /* We remember if we've analyzed an insn for being a move insn, and if yes
206 between which operands. */
214 /* On demand cache, for if insns are copy insns, and if yes, what
215 source/target they have. */
216 static struct copy_p_cache
* copy_cache
;
220 /* For INSN, return nonzero, if it's a move insn, we consider to coalesce
221 later, and place the operands in *SOURCE and *TARGET, if they are
225 copy_insn_p (rtx insn
, rtx
*source
, rtx
*target
)
228 unsigned int d_regno
, s_regno
;
229 int uid
= INSN_UID (insn
);
234 /* First look, if we already saw this insn. */
235 if (copy_cache
[uid
].seen
)
237 /* And if we saw it, if it's actually a copy insn. */
238 if (copy_cache
[uid
].seen
== 1)
241 *source
= copy_cache
[uid
].source
;
243 *target
= copy_cache
[uid
].target
;
249 /* Mark it as seen, but not being a copy insn. */
250 copy_cache
[uid
].seen
= 2;
251 insn
= single_set (insn
);
257 /* We recognize moves between subreg's as copy insns. This is used to avoid
258 conflicts of those subwebs. But they are currently _not_ used for
259 coalescing (the check for this is in remember_move() below). */
260 while (GET_CODE (d
) == STRICT_LOW_PART
)
263 && (GET_CODE (d
) != SUBREG
|| !REG_P (SUBREG_REG (d
))))
265 while (GET_CODE (s
) == STRICT_LOW_PART
)
268 && (GET_CODE (s
) != SUBREG
|| !REG_P (SUBREG_REG (s
))))
271 s_regno
= (unsigned) REGNO (GET_CODE (s
) == SUBREG
? SUBREG_REG (s
) : s
);
272 d_regno
= (unsigned) REGNO (GET_CODE (d
) == SUBREG
? SUBREG_REG (d
) : d
);
274 /* Copies between hardregs are useless for us, as not coalesable anyway. */
275 if ((s_regno
< FIRST_PSEUDO_REGISTER
276 && d_regno
< FIRST_PSEUDO_REGISTER
)
277 || s_regno
>= max_normal_pseudo
278 || d_regno
>= max_normal_pseudo
)
286 /* Still mark it as seen, but as a copy insn this time. */
287 copy_cache
[uid
].seen
= 1;
288 copy_cache
[uid
].source
= s
;
289 copy_cache
[uid
].target
= d
;
293 /* We build webs, as we process the conflicts. For each use we go upward
294 the insn stream, noting any defs as potentially conflicting with the
295 current use. We stop at defs of the current regno. The conflicts are only
296 potentially, because we may never reach a def, so this is an undefined use,
297 which conflicts with nothing. */
300 /* Given a web part WP, and the location of a reg part SIZE_WORD
301 return the conflict bitmap for that reg part, or NULL if it doesn't
305 find_sub_conflicts (struct web_part
*wp
, unsigned int size_word
)
307 struct tagged_conflict
*cl
;
308 cl
= wp
->sub_conflicts
;
309 for (; cl
; cl
= cl
->next
)
310 if (cl
->size_word
== size_word
)
311 return cl
->conflicts
;
315 /* Similar to find_sub_conflicts(), but creates that bitmap, if it
316 doesn't exist. I.e. this never returns NULL. */
319 get_sub_conflicts (struct web_part
*wp
, unsigned int size_word
)
321 bitmap b
= find_sub_conflicts (wp
, size_word
);
324 struct tagged_conflict
*cl
= ra_alloc (sizeof *cl
);
325 cl
->conflicts
= BITMAP_XMALLOC ();
326 cl
->size_word
= size_word
;
327 cl
->next
= wp
->sub_conflicts
;
328 wp
->sub_conflicts
= cl
;
334 /* Helper table for undef_to_size_word() below for small values
335 of UNDEFINED. Offsets and lengths are byte based. */
336 static struct undef_table_s
{
337 unsigned int new_undef
;
338 /* size | (byte << 16) */
339 unsigned int size_word
;
340 } const undef_table
[] = {
341 { 0, BL_TO_WORD (0, 0)}, /* 0 */
342 { 0, BL_TO_WORD (0, 1)},
343 { 0, BL_TO_WORD (1, 1)},
344 { 0, BL_TO_WORD (0, 2)},
345 { 0, BL_TO_WORD (2, 1)}, /* 4 */
346 { 1, BL_TO_WORD (2, 1)},
347 { 2, BL_TO_WORD (2, 1)},
348 { 3, BL_TO_WORD (2, 1)},
349 { 0, BL_TO_WORD (3, 1)}, /* 8 */
350 { 1, BL_TO_WORD (3, 1)},
351 { 2, BL_TO_WORD (3, 1)},
352 { 3, BL_TO_WORD (3, 1)},
353 { 0, BL_TO_WORD (2, 2)}, /* 12 */
354 { 1, BL_TO_WORD (2, 2)},
355 { 2, BL_TO_WORD (2, 2)},
356 { 0, BL_TO_WORD (0, 4)}};
358 /* Interpret *UNDEFINED as bitmask where each bit corresponds to a byte.
359 A set bit means an undefined byte. Factor all undefined bytes into
360 groups, and return a size/ofs pair of consecutive undefined bytes,
361 but according to certain borders. Clear out those bits corresponding
362 to bytes overlaid by that size/ofs pair. REG is only used for
363 the mode, to detect if it's a floating mode or not.
365 For example: *UNDEFINED size+ofs new *UNDEFINED
375 undef_to_size_word (rtx reg
, unsigned HOST_WIDE_INT
*undefined
)
377 /* When only the lower four bits are possibly set, we use
378 a fast lookup table. */
379 if (*undefined
<= 15)
381 struct undef_table_s u
;
382 u
= undef_table
[*undefined
];
383 *undefined
= u
.new_undef
;
387 /* Otherwise we handle certain cases directly. */
388 if (*undefined
<= 0xffff)
389 switch ((int) *undefined
)
391 case 0x00f0 : *undefined
= 0; return BL_TO_WORD (4, 4);
392 case 0x00ff : *undefined
= 0; return BL_TO_WORD (0, 8);
393 case 0x0f00 : *undefined
= 0; return BL_TO_WORD (8, 4);
394 case 0x0ff0 : *undefined
= 0xf0; return BL_TO_WORD (8, 4);
396 if (INTEGRAL_MODE_P (GET_MODE (reg
)))
397 { *undefined
= 0xff; return BL_TO_WORD (8, 4); }
399 { *undefined
= 0; return BL_TO_WORD (0, 12); /* XFmode */ }
400 case 0xf000 : *undefined
= 0; return BL_TO_WORD (12, 4);
401 case 0xff00 : *undefined
= 0; return BL_TO_WORD (8, 8);
402 case 0xfff0 : *undefined
= 0xf0; return BL_TO_WORD (8, 8);
403 case 0xffff : *undefined
= 0; return BL_TO_WORD (0, 16);
406 /* And if nothing matched fall back to the general solution. For
407 now unknown undefined bytes are converted to sequences of maximal
408 length 4 bytes. We could make this larger if necessary. */
410 unsigned HOST_WIDE_INT u
= *undefined
;
412 struct undef_table_s tab
;
413 for (word
= 0; (u
& 15) == 0; word
+= 4)
416 tab
= undef_table
[u
];
418 u
= (*undefined
& ~((unsigned HOST_WIDE_INT
)15 << word
)) | (u
<< word
);
420 /* Size remains the same, only the begin is moved up move bytes. */
421 return tab
.size_word
+ BL_TO_WORD (word
, 0);
425 /* Put the above three functions together. For a set of undefined bytes
426 as bitmap *UNDEFINED, look for (create if necessary) and return the
427 corresponding conflict bitmap. Change *UNDEFINED to remove the bytes
428 covered by the part for that bitmap. */
431 undef_to_bitmap (struct web_part
*wp
, unsigned HOST_WIDE_INT
*undefined
)
433 unsigned int size_word
= undef_to_size_word (DF_REF_REAL_REG (wp
->ref
),
435 return get_sub_conflicts (wp
, size_word
);
438 /* Returns the root of the web part P is a member of. Additionally
439 it compresses the path. P may not be NULL. */
441 static struct web_part
*
442 find_web_part_1 (struct web_part
*p
)
444 struct web_part
*r
= p
;
445 struct web_part
*p_next
;
448 for (; p
!= r
; p
= p_next
)
456 /* Fast macro for the common case (WP either being the root itself, or
457 the end of an already compressed path. */
459 #define find_web_part(wp) ((! (wp)->uplink) ? (wp) \
460 : (! (wp)->uplink->uplink) ? (wp)->uplink : find_web_part_1 (wp))
462 /* Unions together the parts R1 resp. R2 is a root of.
463 All dynamic information associated with the parts (number of spanned insns
464 and so on) is also merged.
465 The root of the resulting (possibly larger) web part is returned. */
467 static struct web_part
*
468 union_web_part_roots (struct web_part
*r1
, struct web_part
*r2
)
472 /* The new root is the smaller (pointerwise) of both. This is crucial
473 to make the construction of webs from web parts work (so, when
474 scanning all parts, we see the roots before all its children).
475 Additionally this ensures, that if the web has a def at all, than
476 the root is a def (because all def parts are before use parts in the
477 web_parts[] array), or put another way, as soon, as the root of a
478 web part is not a def, this is an uninitialized web part. The
479 way we construct the I-graph ensures, that if a web is initialized,
480 then the first part we find (besides trivial 1 item parts) has a
484 struct web_part
*h
= r1
;
491 /* Now we merge the dynamic information of R1 and R2. */
492 r1
->spanned_deaths
+= r2
->spanned_deaths
;
494 if (!r1
->sub_conflicts
)
495 r1
->sub_conflicts
= r2
->sub_conflicts
;
496 else if (r2
->sub_conflicts
)
497 /* We need to merge the conflict bitmaps from R2 into R1. */
499 struct tagged_conflict
*cl1
, *cl2
;
500 /* First those from R2, which are also contained in R1.
501 We union the bitmaps, and free those from R2, resetting them
503 for (cl1
= r1
->sub_conflicts
; cl1
; cl1
= cl1
->next
)
504 for (cl2
= r2
->sub_conflicts
; cl2
; cl2
= cl2
->next
)
505 if (cl1
->size_word
== cl2
->size_word
)
507 bitmap_operation (cl1
->conflicts
, cl1
->conflicts
,
508 cl2
->conflicts
, BITMAP_IOR
);
509 BITMAP_XFREE (cl2
->conflicts
);
510 cl2
->conflicts
= NULL
;
512 /* Now the conflict lists from R2 which weren't in R1.
513 We simply copy the entries from R2 into R1' list. */
514 for (cl2
= r2
->sub_conflicts
; cl2
;)
516 struct tagged_conflict
*cl_next
= cl2
->next
;
519 cl2
->next
= r1
->sub_conflicts
;
520 r1
->sub_conflicts
= cl2
;
525 r2
->sub_conflicts
= NULL
;
526 r1
->crosses_call
|= r2
->crosses_call
;
531 /* Convenience macro, that is capable of unioning also non-roots. */
532 #define union_web_parts(p1, p2) \
533 ((p1 == p2) ? find_web_part (p1) \
534 : union_web_part_roots (find_web_part (p1), find_web_part (p2)))
536 /* Remember that we've handled a given move, so we don't reprocess it. */
539 remember_move (rtx insn
)
541 if (!TEST_BIT (move_handled
, INSN_UID (insn
)))
544 SET_BIT (move_handled
, INSN_UID (insn
));
545 if (copy_insn_p (insn
, &s
, &d
))
547 /* Some sanity test for the copy insn. */
548 struct df_link
*slink
= DF_INSN_USES (df
, insn
);
549 struct df_link
*link
= DF_INSN_DEFS (df
, insn
);
550 if (!link
|| !link
->ref
|| !slink
|| !slink
->ref
)
552 /* The following (link->next != 0) happens when a hardreg
553 is used in wider mode (REG:DI %eax). Then df.* creates
554 a def/use for each hardreg contained therein. We only
555 allow hardregs here. */
557 && DF_REF_REGNO (link
->next
->ref
) >= FIRST_PSEUDO_REGISTER
)
562 /* XXX for now we don't remember move insns involving any subregs.
563 Those would be difficult to coalesce (we would need to implement
564 handling of all the subwebs in the allocator, including that such
565 subwebs could be source and target of coalescing). */
566 if (REG_P (s
) && REG_P (d
))
568 struct move
*m
= ra_calloc (sizeof (struct move
));
569 struct move_list
*ml
;
571 ml
= ra_alloc (sizeof (struct move_list
));
579 /* This describes the USE currently looked at in the main-loop in
580 build_web_parts_and_conflicts(). */
583 /* This has a 1-bit for each byte in the USE, which is still undefined. */
584 unsigned HOST_WIDE_INT undefined
;
585 /* For easy access. */
588 /* If some bits of this USE are live over an abnormal edge. */
589 unsigned int live_over_abnormal
;
592 /* Returns nonzero iff rtx DEF and USE have bits in common (but see below).
593 It is only called with DEF and USE being (reg:M a) or (subreg:M1 (reg:M2 a)
594 x) rtx's. Furthermore if it's a subreg rtx M1 is at least one word wide,
595 and a is a multi-word pseudo. If DEF or USE are hardregs, they are in
596 word_mode, so we don't need to check for further hardregs which would result
597 from wider references. We are never called with paradoxical subregs.
600 0 for no common bits,
601 1 if DEF and USE exactly cover the same bytes,
602 2 if the DEF only covers a part of the bits of USE
603 3 if the DEF covers more than the bits of the USE, and
604 4 if both are SUBREG's of different size, but have bytes in common.
605 -1 is a special case, for when DEF and USE refer to the same regno, but
606 have for other reasons no bits in common (can only happen with
607 subregs referring to different words, or to words which already were
608 defined for this USE).
609 Furthermore it modifies use->undefined to clear the bits which get defined
610 by DEF (only for cases with partial overlap).
611 I.e. if bit 1 is set for the result != -1, the USE was completely covered,
612 otherwise a test is needed to track the already defined bytes. */
615 defuse_overlap_p_1 (rtx def
, struct curr_use
*use
)
622 if (GET_CODE (def
) == SUBREG
)
624 if (REGNO (SUBREG_REG (def
)) != use
->regno
)
628 else if (REGNO (def
) != use
->regno
)
630 if (GET_CODE (use
->x
) == SUBREG
)
634 case 0: /* REG, REG */
636 case 1: /* SUBREG, REG */
638 unsigned HOST_WIDE_INT old_u
= use
->undefined
;
639 use
->undefined
&= ~ rtx_to_undefined (def
);
640 return (old_u
!= use
->undefined
) ? 2 : -1;
642 case 2: /* REG, SUBREG */
644 case 3: /* SUBREG, SUBREG */
645 if (GET_MODE_SIZE (GET_MODE (def
)) == GET_MODE_SIZE (GET_MODE (use
->x
)))
646 /* If the size of both things is the same, the subreg's overlap
647 if they refer to the same word. */
648 if (SUBREG_BYTE (def
) == SUBREG_BYTE (use
->x
))
650 /* Now the more difficult part: the same regno is referred, but the
651 sizes of the references or the words differ. E.g.
652 (subreg:SI (reg:CDI a) 0) and (subreg:DI (reg:CDI a) 2) do not
653 overlap, whereas the latter overlaps with (subreg:SI (reg:CDI a) 3).
656 unsigned HOST_WIDE_INT old_u
;
658 unsigned int bl1
, bl2
;
659 bl1
= rtx_to_bits (def
);
660 bl2
= rtx_to_bits (use
->x
);
661 b1
= BYTE_BEGIN (bl1
);
662 b2
= BYTE_BEGIN (bl2
);
663 e1
= b1
+ BYTE_LENGTH (bl1
) - 1;
664 e2
= b2
+ BYTE_LENGTH (bl2
) - 1;
665 if (b1
> e2
|| b2
> e1
)
667 old_u
= use
->undefined
;
668 use
->undefined
&= ~ rtx_to_undefined (def
);
669 return (old_u
!= use
->undefined
) ? 4 : -1;
676 /* Macro for the common case of either def and use having the same rtx,
677 or based on different regnos. */
678 #define defuse_overlap_p(def, use) \
679 ((def) == (use)->x ? 1 : \
680 (REGNO (GET_CODE (def) == SUBREG \
681 ? SUBREG_REG (def) : def) != use->regno \
682 ? 0 : defuse_overlap_p_1 (def, use)))
685 /* The use USE flows into INSN (backwards). Determine INSNs effect on it,
686 and return nonzero, if (parts of) that USE are also live before it.
687 This also notes conflicts between the USE and all DEFS in that insn,
688 and modifies the undefined bits of USE in case parts of it were set in
692 live_out_1 (struct df
*df ATTRIBUTE_UNUSED
, struct curr_use
*use
, rtx insn
)
695 int uid
= INSN_UID (insn
);
696 struct web_part
*wp
= use
->wp
;
698 /* Mark, that this insn needs this webpart live. */
699 visit_trace
[uid
].wp
= wp
;
700 visit_trace
[uid
].undefined
= use
->undefined
;
704 unsigned int source_regno
= ~0;
705 unsigned int regno
= use
->regno
;
706 unsigned HOST_WIDE_INT orig_undef
= use
->undefined
;
707 unsigned HOST_WIDE_INT final_undef
= use
->undefined
;
709 unsigned int n
, num_defs
= insn_df
[uid
].num_defs
;
710 struct ref
**defs
= insn_df
[uid
].defs
;
712 /* We want to access the root webpart. */
713 wp
= find_web_part (wp
);
714 if (GET_CODE (insn
) == CALL_INSN
)
715 wp
->crosses_call
= 1;
716 else if (copy_insn_p (insn
, &s
, NULL
))
717 source_regno
= REGNO (GET_CODE (s
) == SUBREG
? SUBREG_REG (s
) : s
);
719 /* Look at all DEFS in this insn. */
720 for (n
= 0; n
< num_defs
; n
++)
722 struct ref
*ref
= defs
[n
];
725 /* Reset the undefined bits for each iteration, in case this
726 insn has more than one set, and one of them sets this regno.
727 But still the original undefined part conflicts with the other
729 use
->undefined
= orig_undef
;
730 if ((lap
= defuse_overlap_p (DF_REF_REG (ref
), use
)) != 0)
733 /* Same regnos but non-overlapping or already defined bits,
734 so ignore this DEF, or better said make the yet undefined
735 part and this DEF conflicting. */
737 unsigned HOST_WIDE_INT undef
;
738 undef
= use
->undefined
;
740 bitmap_set_bit (undef_to_bitmap (wp
, &undef
),
745 /* The current DEF completely covers the USE, so we can
746 stop traversing the code looking for further DEFs. */
749 /* We have a partial overlap. */
751 final_undef
&= use
->undefined
;
752 if (final_undef
== 0)
753 /* Now the USE is completely defined, which means, that
754 we can stop looking for former DEFs. */
756 /* If this is a partial overlap, which left some bits
757 in USE undefined, we normally would need to create
758 conflicts between that undefined part and the part of
759 this DEF which overlapped with some of the formerly
760 undefined bits. We don't need to do this, because both
761 parts of this DEF (that which overlaps, and that which
762 doesn't) are written together in this one DEF, and can
763 not be colored in a way which would conflict with
764 the USE. This is only true for partial overlap,
765 because only then the DEF and USE have bits in common,
766 which makes the DEF move, if the USE moves, making them
768 If they have no bits in common (lap == -1), they are
769 really independent. Therefore we there made a
772 /* This is at least a partial overlap, so we need to union
774 wp
= union_web_parts (wp
, &web_parts
[DF_REF_ID (ref
)]);
778 /* The DEF and the USE don't overlap at all, different
779 regnos. I.e. make conflicts between the undefined bits,
781 unsigned HOST_WIDE_INT undef
= use
->undefined
;
783 if (regno
== source_regno
)
784 /* This triggers only, when this was a copy insn and the
785 source is at least a part of the USE currently looked at.
786 In this case only the bits of the USE conflict with the
787 DEF, which are not covered by the source of this copy
788 insn, and which are still undefined. I.e. in the best
789 case (the whole reg being the source), _no_ conflicts
790 between that USE and this DEF (the target of the move)
791 are created by this insn (though they might be by
792 others). This is a super case of the normal copy insn
793 only between full regs. */
795 undef
&= ~ rtx_to_undefined (s
);
799 /*struct web_part *cwp;
800 cwp = find_web_part (&web_parts[DF_REF_ID
803 /* TODO: somehow instead of noting the ID of the LINK
804 use an ID nearer to the root webpart of that LINK.
805 We can't use the root itself, because we later use the
806 ID to look at the form (reg or subreg, and if yes,
807 which subreg) of this conflict. This means, that we
808 need to remember in the root an ID for each form, and
809 maintaining this, when merging web parts. This makes
810 the bitmaps smaller. */
812 bitmap_set_bit (undef_to_bitmap (wp
, &undef
),
822 /* If this insn doesn't completely define the USE, increment also
823 it's spanned deaths count (if this insn contains a death). */
824 if (uid
>= death_insns_max_uid
)
826 if (TEST_BIT (insns_with_deaths
, uid
))
827 wp
->spanned_deaths
++;
828 use
->undefined
= final_undef
;
835 /* Same as live_out_1() (actually calls it), but caches some information.
836 E.g. if we reached this INSN with the current regno already, and the
837 current undefined bits are a subset of those as we came here, we
838 simply connect the web parts of the USE, and the one cached for this
839 INSN, and additionally return zero, indicating we don't need to traverse
840 this path any longer (all effect were already seen, as we first reached
844 live_out (struct df
*df
, struct curr_use
*use
, rtx insn
)
846 unsigned int uid
= INSN_UID (insn
);
847 if (visit_trace
[uid
].wp
848 && DF_REF_REGNO (visit_trace
[uid
].wp
->ref
) == use
->regno
849 && (use
->undefined
& ~visit_trace
[uid
].undefined
) == 0)
851 union_web_parts (visit_trace
[uid
].wp
, use
->wp
);
852 /* Don't search any further, as we already were here with this regno. */
856 return live_out_1 (df
, use
, insn
);
859 /* The current USE reached a basic block head. The edge E is one
860 of the predecessors edges. This evaluates the effect of the predecessor
861 block onto the USE, and returns the next insn, which should be looked at.
862 This either is the last insn of that pred. block, or the first one.
863 The latter happens, when the pred. block has no possible effect on the
864 USE, except for conflicts. In that case, it's remembered, that the USE
865 is live over that whole block, and it's skipped. Otherwise we simply
866 continue with the last insn of the block.
868 This also determines the effects of abnormal edges, and remembers
869 which uses are live at the end of that basic block. */
872 live_in_edge (struct df
*df
, struct curr_use
*use
, edge e
)
874 struct ra_bb_info
*info_pred
;
876 /* Call used hard regs die over an exception edge, ergo
877 they don't reach the predecessor block, so ignore such
878 uses. And also don't set the live_over_abnormal flag
880 if ((e
->flags
& EDGE_EH
) && use
->regno
< FIRST_PSEUDO_REGISTER
881 && call_used_regs
[use
->regno
])
883 if (e
->flags
& EDGE_ABNORMAL
)
884 use
->live_over_abnormal
= 1;
885 bitmap_set_bit (live_at_end
[e
->src
->index
], DF_REF_ID (use
->wp
->ref
));
886 info_pred
= (struct ra_bb_info
*) e
->src
->aux
;
887 next_insn
= BB_END (e
->src
);
889 /* If the last insn of the pred. block doesn't completely define the
890 current use, we need to check the block. */
891 if (live_out (df
, use
, next_insn
))
893 /* If the current regno isn't mentioned anywhere in the whole block,
894 and the complete use is still undefined... */
895 if (!bitmap_bit_p (info_pred
->regnos_mentioned
, use
->regno
)
896 && (rtx_to_undefined (use
->x
) & ~use
->undefined
) == 0)
898 /* ...we can hop over the whole block and defer conflict
899 creation to later. */
900 bitmap_set_bit (info_pred
->live_throughout
,
901 DF_REF_ID (use
->wp
->ref
));
902 next_insn
= BB_HEAD (e
->src
);
910 /* USE flows into the end of the insns preceding INSN. Determine
911 their effects (in live_out()) and possibly loop over the preceding INSN,
912 or call itself recursively on a basic block border. When a topleve
913 call of this function returns the USE is completely analyzed. I.e.
914 its def-use chain (at least) is built, possibly connected with other
915 def-use chains, and all defs during that chain are noted. */
918 live_in (struct df
*df
, struct curr_use
*use
, rtx insn
)
920 unsigned int loc_vpass
= visited_pass
;
922 /* Note, that, even _if_ we are called with use->wp a root-part, this might
923 become non-root in the for() loop below (due to live_out() unioning
924 it). So beware, not to change use->wp in a way, for which only root-webs
928 int uid
= INSN_UID (insn
);
929 basic_block bb
= BLOCK_FOR_INSN (insn
);
932 /* We want to be as fast as possible, so explicitly write
934 for (insn
= PREV_INSN (insn
); insn
&& !INSN_P (insn
);
935 insn
= PREV_INSN (insn
))
939 if (bb
!= BLOCK_FOR_INSN (insn
))
942 unsigned HOST_WIDE_INT undef
= use
->undefined
;
943 struct ra_bb_info
*info
= (struct ra_bb_info
*) bb
->aux
;
944 if ((e
= bb
->pred
) == NULL
)
946 /* We now check, if we already traversed the predecessors of this
947 block for the current pass and the current set of undefined
948 bits. If yes, we don't need to check the predecessors again.
949 So, conceptually this information is tagged to the first
950 insn of a basic block. */
951 if (info
->pass
== loc_vpass
&& (undef
& ~info
->undefined
) == 0)
953 info
->pass
= loc_vpass
;
954 info
->undefined
= undef
;
955 /* All but the last predecessor are handled recursively. */
956 for (; e
->pred_next
; e
= e
->pred_next
)
958 insn
= live_in_edge (df
, use
, e
);
960 live_in (df
, use
, insn
);
961 use
->undefined
= undef
;
963 insn
= live_in_edge (df
, use
, e
);
967 else if (!live_out (df
, use
, insn
))
972 /* Determine all regnos which are mentioned in a basic block, in an
973 interesting way. Interesting here means either in a def, or as the
974 source of a move insn. We only look at insns added since the last
978 update_regnos_mentioned (void)
980 int last_uid
= last_max_uid
;
983 for (insn
= get_insns (); insn
; insn
= NEXT_INSN (insn
))
986 /* Don't look at old insns. */
987 if (INSN_UID (insn
) < last_uid
)
989 /* XXX We should also remember moves over iterations (we already
990 save the cache, but not the movelist). */
991 if (copy_insn_p (insn
, NULL
, NULL
))
992 remember_move (insn
);
994 else if ((bb
= BLOCK_FOR_INSN (insn
)) != NULL
)
997 struct ra_bb_info
*info
= (struct ra_bb_info
*) bb
->aux
;
998 bitmap mentioned
= info
->regnos_mentioned
;
999 struct df_link
*link
;
1000 if (copy_insn_p (insn
, &source
, NULL
))
1002 remember_move (insn
);
1003 bitmap_set_bit (mentioned
,
1004 REGNO (GET_CODE (source
) == SUBREG
1005 ? SUBREG_REG (source
) : source
));
1007 for (link
= DF_INSN_DEFS (df
, insn
); link
; link
= link
->next
)
1009 bitmap_set_bit (mentioned
, DF_REF_REGNO (link
->ref
));
1014 /* Handle the uses which reach a block end, but were deferred due
1015 to it's regno not being mentioned in that block. This adds the
1016 remaining conflicts and updates also the crosses_call and
1017 spanned_deaths members. */
1020 livethrough_conflicts_bb (basic_block bb
)
1022 struct ra_bb_info
*info
= (struct ra_bb_info
*) bb
->aux
;
1026 unsigned int deaths
= 0;
1027 unsigned int contains_call
= 0;
1029 /* If there are no deferred uses, just return. */
1030 if ((first
= bitmap_first_set_bit (info
->live_throughout
)) < 0)
1033 /* First collect the IDs of all defs, count the number of death
1034 containing insns, and if there's some call_insn here. */
1035 all_defs
= BITMAP_XMALLOC ();
1036 for (insn
= BB_HEAD (bb
); insn
; insn
= NEXT_INSN (insn
))
1041 struct ra_insn_info info
;
1043 info
= insn_df
[INSN_UID (insn
)];
1044 for (n
= 0; n
< info
.num_defs
; n
++)
1045 bitmap_set_bit (all_defs
, DF_REF_ID (info
.defs
[n
]));
1046 if (TEST_BIT (insns_with_deaths
, INSN_UID (insn
)))
1048 if (GET_CODE (insn
) == CALL_INSN
)
1051 if (insn
== BB_END (bb
))
1055 /* And now, if we have found anything, make all live_through
1056 uses conflict with all defs, and update their other members. */
1059 || bitmap_first_set_bit (all_defs
) >= 0)
1060 EXECUTE_IF_SET_IN_BITMAP (info
->live_throughout
, first
, use_id
,
1062 struct web_part
*wp
= &web_parts
[df
->def_id
+ use_id
];
1063 unsigned int bl
= rtx_to_bits (DF_REF_REG (wp
->ref
));
1065 wp
= find_web_part (wp
);
1066 wp
->spanned_deaths
+= deaths
;
1067 wp
->crosses_call
|= contains_call
;
1068 conflicts
= get_sub_conflicts (wp
, bl
);
1069 bitmap_operation (conflicts
, conflicts
, all_defs
, BITMAP_IOR
);
1072 BITMAP_XFREE (all_defs
);
1075 /* Allocate the per basic block info for traversing the insn stream for
1076 building live ranges. */
1084 struct ra_bb_info
*info
= xcalloc (1, sizeof *info
);
1085 info
->regnos_mentioned
= BITMAP_XMALLOC ();
1086 info
->live_throughout
= BITMAP_XMALLOC ();
1087 info
->old_aux
= bb
->aux
;
1088 bb
->aux
= (void *) info
;
1092 /* Free that per basic block info. */
1100 struct ra_bb_info
*info
= (struct ra_bb_info
*) bb
->aux
;
1101 BITMAP_XFREE (info
->regnos_mentioned
);
1102 BITMAP_XFREE (info
->live_throughout
);
1103 bb
->aux
= info
->old_aux
;
1108 /* Toplevel function for the first part of this file.
1109 Connect web parts, thereby implicitly building webs, and remember
1113 build_web_parts_and_conflicts (struct df
*df
)
1115 struct df_link
*link
;
1116 struct curr_use use
;
1119 number_seen
= xcalloc (get_max_uid (), sizeof (int));
1120 visit_trace
= xcalloc (get_max_uid (), sizeof (visit_trace
[0]));
1121 update_regnos_mentioned ();
1123 /* Here's the main loop.
1124 It goes through all insn's, connects web parts along the way, notes
1125 conflicts between webparts, and remembers move instructions. */
1127 for (use
.regno
= 0; use
.regno
< (unsigned int)max_regno
; use
.regno
++)
1128 if (use
.regno
>= FIRST_PSEUDO_REGISTER
|| !fixed_regs
[use
.regno
])
1129 for (link
= df
->regs
[use
.regno
].uses
; link
; link
= link
->next
)
1132 struct ref
*ref
= link
->ref
;
1133 rtx insn
= DF_REF_INSN (ref
);
1134 /* Only recheck marked or new uses, or uses from hardregs. */
1135 if (use
.regno
>= FIRST_PSEUDO_REGISTER
1136 && DF_REF_ID (ref
) < last_use_id
1137 && !TEST_BIT (last_check_uses
, DF_REF_ID (ref
)))
1139 use
.wp
= &web_parts
[df
->def_id
+ DF_REF_ID (ref
)];
1140 use
.x
= DF_REF_REG (ref
);
1141 use
.live_over_abnormal
= 0;
1142 use
.undefined
= rtx_to_undefined (use
.x
);
1144 live_in (df
, &use
, insn
);
1145 if (use
.live_over_abnormal
)
1146 SET_BIT (live_over_abnormal
, DF_REF_ID (ref
));
1149 dump_number_seen ();
1152 struct ra_bb_info
*info
= (struct ra_bb_info
*) bb
->aux
;
1153 livethrough_conflicts_bb (bb
);
1154 bitmap_zero (info
->live_throughout
);
1161 /* Here we look per insn, for DF references being in uses _and_ defs.
1162 This means, in the RTL a (REG xx) expression was seen as a
1163 read/modify/write, as happens for (set (subreg:SI (reg:DI xx)) (...))
1164 e.g. Our code has created two webs for this, as it should. Unfortunately,
1165 as the REG reference is only one time in the RTL we can't color
1166 both webs different (arguably this also would be wrong for a real
1167 read-mod-write instruction), so we must reconnect such webs. */
1170 connect_rmw_web_parts (struct df
*df
)
1174 for (i
= 0; i
< df
->use_id
; i
++)
1176 struct web_part
*wp1
= &web_parts
[df
->def_id
+ i
];
1178 struct df_link
*link
;
1181 /* If it's an uninitialized web, we don't want to connect it to others,
1182 as the read cycle in read-mod-write had probably no effect. */
1183 if (find_web_part (wp1
) >= &web_parts
[df
->def_id
])
1185 reg
= DF_REF_REAL_REG (wp1
->ref
);
1186 link
= DF_INSN_DEFS (df
, DF_REF_INSN (wp1
->ref
));
1187 for (; link
; link
= link
->next
)
1188 if (reg
== DF_REF_REAL_REG (link
->ref
))
1190 struct web_part
*wp2
= &web_parts
[DF_REF_ID (link
->ref
)];
1191 union_web_parts (wp1
, wp2
);
1196 /* Deletes all hardregs from *S which are not allowed for MODE. */
1199 prune_hardregs_for_mode (HARD_REG_SET
*s
, enum machine_mode mode
)
1201 AND_HARD_REG_SET (*s
, hardregs_for_mode
[(int) mode
]);
1204 /* Initialize the members of a web, which are deducible from REG. */
1207 init_one_web_common (struct web
*web
, rtx reg
)
1211 /* web->id isn't initialized here. */
1212 web
->regno
= REGNO (reg
);
1216 web
->dlink
= ra_calloc (sizeof (struct dlist
));
1217 DLIST_WEB (web
->dlink
) = web
;
1220 the former (superunion) doesn't constrain the graph enough. E.g.
1221 on x86 QImode _requires_ QI_REGS, but as alternate class usually
1222 GENERAL_REGS is given. So the graph is not constrained enough,
1223 thinking it has more freedom then it really has, which leads
1224 to repeated spill tryings. OTOH the latter (only using preferred
1225 class) is too constrained, as normally (e.g. with all SImode
1226 pseudos), they can be allocated also in the alternate class.
1227 What we really want, are the _exact_ hard regs allowed, not
1228 just a class. Later. */
1229 /*web->regclass = reg_class_superunion
1230 [reg_preferred_class (web->regno)]
1231 [reg_alternate_class (web->regno)];*/
1232 /*web->regclass = reg_preferred_class (web->regno);*/
1233 web
->regclass
= reg_class_subunion
1234 [reg_preferred_class (web
->regno
)] [reg_alternate_class (web
->regno
)];
1235 web
->regclass
= reg_preferred_class (web
->regno
);
1236 if (web
->regno
< FIRST_PSEUDO_REGISTER
)
1238 web
->color
= web
->regno
;
1239 put_web (web
, PRECOLORED
);
1240 web
->num_conflicts
= UINT_MAX
;
1241 web
->add_hardregs
= 0;
1242 CLEAR_HARD_REG_SET (web
->usable_regs
);
1243 SET_HARD_REG_BIT (web
->usable_regs
, web
->regno
);
1244 web
->num_freedom
= 1;
1248 HARD_REG_SET alternate
;
1250 put_web (web
, INITIAL
);
1251 /* add_hardregs is wrong in multi-length classes, e.g.
1252 using a DFmode pseudo on x86 can result in class FLOAT_INT_REGS,
1253 where, if it finally is allocated to GENERAL_REGS it needs two,
1254 if allocated to FLOAT_REGS only one hardreg. XXX */
1256 CLASS_MAX_NREGS (web
->regclass
, PSEUDO_REGNO_MODE (web
->regno
)) - 1;
1257 web
->num_conflicts
= 0 * web
->add_hardregs
;
1258 COPY_HARD_REG_SET (web
->usable_regs
,
1259 reg_class_contents
[reg_preferred_class (web
->regno
)]);
1260 COPY_HARD_REG_SET (alternate
,
1261 reg_class_contents
[reg_alternate_class (web
->regno
)]);
1262 IOR_HARD_REG_SET (web
->usable_regs
, alternate
);
1263 /*IOR_HARD_REG_SET (web->usable_regs,
1264 reg_class_contents[reg_alternate_class
1266 AND_COMPL_HARD_REG_SET (web
->usable_regs
, never_use_colors
);
1267 prune_hardregs_for_mode (&web
->usable_regs
,
1268 PSEUDO_REGNO_MODE (web
->regno
));
1269 #ifdef CANNOT_CHANGE_MODE_CLASS
1270 if (web
->mode_changed
)
1271 AND_COMPL_HARD_REG_SET (web
->usable_regs
, invalid_mode_change_regs
);
1273 web
->num_freedom
= hard_regs_count (web
->usable_regs
);
1274 web
->num_freedom
-= web
->add_hardregs
;
1275 if (!web
->num_freedom
)
1278 COPY_HARD_REG_SET (web
->orig_usable_regs
, web
->usable_regs
);
1281 /* Initializes WEBs members from REG or zero them. */
1284 init_one_web (struct web
*web
, rtx reg
)
1286 memset (web
, 0, sizeof (struct web
));
1287 init_one_web_common (web
, reg
);
1288 web
->useless_conflicts
= BITMAP_XMALLOC ();
1291 /* WEB is an old web, meaning it came from the last pass, and got a
1292 color. We want to remember some of it's info, so zero only some
1296 reinit_one_web (struct web
*web
, rtx reg
)
1298 web
->old_color
= web
->color
+ 1;
1299 init_one_web_common (web
, reg
);
1300 web
->span_deaths
= 0;
1301 web
->spill_temp
= 0;
1302 web
->orig_spill_temp
= 0;
1303 web
->use_my_regs
= 0;
1304 web
->spill_cost
= 0;
1305 web
->was_spilled
= 0;
1306 web
->is_coalesced
= 0;
1307 web
->artificial
= 0;
1308 web
->live_over_abnormal
= 0;
1309 web
->mode_changed
= 0;
1310 web
->subreg_stripped
= 0;
1311 web
->move_related
= 0;
1313 web
->target_of_spilled_move
= 0;
1314 web
->num_aliased
= 0;
1315 if (web
->type
== PRECOLORED
)
1319 web
->orig_spill_cost
= 0;
1321 CLEAR_HARD_REG_SET (web
->bias_colors
);
1322 CLEAR_HARD_REG_SET (web
->prefer_colors
);
1323 web
->reg_rtx
= NULL
;
1324 web
->stack_slot
= NULL
;
1325 web
->pattern
= NULL
;
1329 if (!web
->useless_conflicts
)
1333 /* Insert and returns a subweb corresponding to REG into WEB (which
1334 becomes its super web). It must not exist already. */
1337 add_subweb (struct web
*web
, rtx reg
)
1340 if (GET_CODE (reg
) != SUBREG
)
1342 w
= xmalloc (sizeof (struct web
));
1343 /* Copy most content from parent-web. */
1345 /* And initialize the private stuff. */
1347 w
->add_hardregs
= CLASS_MAX_NREGS (web
->regclass
, GET_MODE (reg
)) - 1;
1348 w
->num_conflicts
= 0 * w
->add_hardregs
;
1352 w
->parent_web
= web
;
1353 w
->subreg_next
= web
->subreg_next
;
1354 web
->subreg_next
= w
;
1358 /* Similar to add_subweb(), but instead of relying on a given SUBREG,
1359 we have just a size and an offset of the subpart of the REG rtx.
1360 In difference to add_subweb() this marks the new subweb as artificial. */
1363 add_subweb_2 (struct web
*web
, unsigned int size_word
)
1365 /* To get a correct mode for the to be produced subreg, we don't want to
1366 simply do a mode_for_size() for the mode_class of the whole web.
1367 Suppose we deal with a CDImode web, but search for a 8 byte part.
1368 Now mode_for_size() would only search in the class MODE_COMPLEX_INT
1369 and would find CSImode which probably is not what we want. Instead
1370 we want DImode, which is in a completely other class. For this to work
1371 we instead first search the already existing subwebs, and take
1372 _their_ modeclasses as base for a search for ourself. */
1373 rtx ref_rtx
= (web
->subreg_next
? web
->subreg_next
: web
)->orig_x
;
1374 unsigned int size
= BYTE_LENGTH (size_word
) * BITS_PER_UNIT
;
1375 enum machine_mode mode
;
1376 mode
= mode_for_size (size
, GET_MODE_CLASS (GET_MODE (ref_rtx
)), 0);
1377 if (mode
== BLKmode
)
1378 mode
= mode_for_size (size
, MODE_INT
, 0);
1379 if (mode
== BLKmode
)
1381 web
= add_subweb (web
, gen_rtx_SUBREG (mode
, web
->orig_x
,
1382 BYTE_BEGIN (size_word
)));
1383 web
->artificial
= 1;
1387 /* Initialize all the web parts we are going to need. */
1390 init_web_parts (struct df
*df
)
1395 for (no
= 0; no
< df
->def_id
; no
++)
1399 if (no
< last_def_id
&& web_parts
[no
].ref
!= df
->defs
[no
])
1401 web_parts
[no
].ref
= df
->defs
[no
];
1402 /* Uplink might be set from the last iteration. */
1403 if (!web_parts
[no
].uplink
)
1407 /* The last iteration might have left .ref set, while df_analyze()
1408 removed that ref (due to a removed copy insn) from the df->defs[]
1409 array. As we don't check for that in realloc_web_parts()
1411 web_parts
[no
].ref
= NULL
;
1413 for (no
= 0; no
< df
->use_id
; no
++)
1417 if (no
< last_use_id
1418 && web_parts
[no
+ df
->def_id
].ref
!= df
->uses
[no
])
1420 web_parts
[no
+ df
->def_id
].ref
= df
->uses
[no
];
1421 if (!web_parts
[no
+ df
->def_id
].uplink
)
1425 web_parts
[no
+ df
->def_id
].ref
= NULL
;
1428 /* We want to have only one web for each precolored register. */
1429 for (regno
= 0; regno
< FIRST_PSEUDO_REGISTER
; regno
++)
1431 struct web_part
*r1
= NULL
;
1432 struct df_link
*link
;
1433 /* Here once was a test, if there is any DEF at all, and only then to
1434 merge all the parts. This was incorrect, we really also want to have
1435 only one web-part for hardregs, even if there is no explicit DEF. */
1436 /* Link together all defs... */
1437 for (link
= df
->regs
[regno
].defs
; link
; link
= link
->next
)
1440 struct web_part
*r2
= &web_parts
[DF_REF_ID (link
->ref
)];
1444 r1
= union_web_parts (r1
, r2
);
1446 /* ... and all uses. */
1447 for (link
= df
->regs
[regno
].uses
; link
; link
= link
->next
)
1450 struct web_part
*r2
= &web_parts
[df
->def_id
1451 + DF_REF_ID (link
->ref
)];
1455 r1
= union_web_parts (r1
, r2
);
1460 /* In case we want to remember the conflict list of a WEB, before adding
1461 new conflicts, we copy it here to orig_conflict_list. */
1464 copy_conflict_list (struct web
*web
)
1466 struct conflict_link
*cl
;
1467 if (web
->orig_conflict_list
|| web
->have_orig_conflicts
)
1469 web
->have_orig_conflicts
= 1;
1470 for (cl
= web
->conflict_list
; cl
; cl
= cl
->next
)
1472 struct conflict_link
*ncl
;
1473 ncl
= ra_alloc (sizeof *ncl
);
1476 ncl
->next
= web
->orig_conflict_list
;
1477 web
->orig_conflict_list
= ncl
;
1480 struct sub_conflict
*sl
, *nsl
;
1481 for (sl
= cl
->sub
; sl
; sl
= sl
->next
)
1483 nsl
= ra_alloc (sizeof *nsl
);
1486 nsl
->next
= ncl
->sub
;
1493 /* Possibly add an edge from web FROM to TO marking a conflict between
1494 those two. This is one half of marking a complete conflict, which notes
1495 in FROM, that TO is a conflict. Adding TO to FROM's conflicts might
1496 make other conflicts superfluous, because the current TO overlaps some web
1497 already being in conflict with FROM. In this case the smaller webs are
1498 deleted from the conflict list. Likewise if TO is overlapped by a web
1499 already in the list, it isn't added at all. Note, that this can only
1500 happen, if SUBREG webs are involved. */
1503 add_conflict_edge (struct web
*from
, struct web
*to
)
1505 if (from
->type
!= PRECOLORED
)
1507 struct web
*pfrom
= find_web_for_subweb (from
);
1508 struct web
*pto
= find_web_for_subweb (to
);
1509 struct sub_conflict
*sl
;
1510 struct conflict_link
*cl
= pfrom
->conflict_list
;
1513 /* This can happen when subwebs of one web conflict with each
1514 other. In live_out_1() we created such conflicts between yet
1515 undefined webparts and defs of parts which didn't overlap with the
1516 undefined bits. Then later they nevertheless could have merged into
1517 one web, and then we land here. */
1520 if (remember_conflicts
&& !pfrom
->have_orig_conflicts
)
1521 copy_conflict_list (pfrom
);
1522 if (!TEST_BIT (sup_igraph
, (pfrom
->id
* num_webs
+ pto
->id
)))
1524 cl
= ra_alloc (sizeof (*cl
));
1527 cl
->next
= pfrom
->conflict_list
;
1528 pfrom
->conflict_list
= cl
;
1529 if (pto
->type
!= SELECT
&& pto
->type
!= COALESCED
)
1530 pfrom
->num_conflicts
+= 1 + pto
->add_hardregs
;
1531 SET_BIT (sup_igraph
, (pfrom
->id
* num_webs
+ pto
->id
));
1535 /* We don't need to test for cl==NULL, because at this point
1536 a cl with cl->t==pto is guaranteed to exist. */
1537 while (cl
->t
!= pto
)
1539 if (pfrom
!= from
|| pto
!= to
)
1541 /* This is a subconflict which should be added.
1542 If we inserted cl in this invocation, we really need to add this
1543 subconflict. If we did _not_ add it here, we only add the
1544 subconflict, if cl already had subconflicts, because otherwise
1545 this indicated, that the whole webs already conflict, which
1546 means we are not interested in this subconflict. */
1547 if (!may_delete
|| cl
->sub
!= NULL
)
1549 sl
= ra_alloc (sizeof (*sl
));
1557 /* pfrom == from && pto == to means, that we are not interested
1558 anymore in the subconflict list for this pair, because anyway
1559 the whole webs conflict. */
1564 /* Record a conflict between two webs, if we haven't recorded it
1568 record_conflict (struct web
*web1
, struct web
*web2
)
1570 unsigned int id1
= web1
->id
, id2
= web2
->id
;
1571 unsigned int index
= igraph_index (id1
, id2
);
1572 /* Trivial non-conflict or already recorded conflict. */
1573 if (web1
== web2
|| TEST_BIT (igraph
, index
))
1577 /* As fixed_regs are no targets for allocation, conflicts with them
1579 if ((web1
->regno
< FIRST_PSEUDO_REGISTER
&& fixed_regs
[web1
->regno
])
1580 || (web2
->regno
< FIRST_PSEUDO_REGISTER
&& fixed_regs
[web2
->regno
]))
1582 /* Conflicts with hardregs, which are not even a candidate
1583 for this pseudo are also pointless. */
1584 if ((web1
->type
== PRECOLORED
1585 && ! TEST_HARD_REG_BIT (web2
->usable_regs
, web1
->regno
))
1586 || (web2
->type
== PRECOLORED
1587 && ! TEST_HARD_REG_BIT (web1
->usable_regs
, web2
->regno
)))
1589 /* Similar if the set of possible hardregs don't intersect. This iteration
1590 those conflicts are useless (and would make num_conflicts wrong, because
1591 num_freedom is calculated from the set of possible hardregs).
1592 But in presence of spilling and incremental building of the graph we
1593 need to note all uses of webs conflicting with the spilled ones.
1594 Because the set of possible hardregs can change in the next round for
1595 spilled webs, we possibly have then conflicts with webs which would
1596 be excluded now (because then hardregs intersect). But we actually
1597 need to check those uses, and to get hold of them, we need to remember
1598 also webs conflicting with this one, although not conflicting in this
1599 round because of non-intersecting hardregs. */
1600 if (web1
->type
!= PRECOLORED
&& web2
->type
!= PRECOLORED
1601 && ! hard_regs_intersect_p (&web1
->usable_regs
, &web2
->usable_regs
))
1603 struct web
*p1
= find_web_for_subweb (web1
);
1604 struct web
*p2
= find_web_for_subweb (web2
);
1605 /* We expect these to be rare enough to justify bitmaps. And because
1606 we have only a special use for it, we note only the superwebs. */
1607 bitmap_set_bit (p1
->useless_conflicts
, p2
->id
);
1608 bitmap_set_bit (p2
->useless_conflicts
, p1
->id
);
1611 SET_BIT (igraph
, index
);
1612 add_conflict_edge (web1
, web2
);
1613 add_conflict_edge (web2
, web1
);
1616 /* For each web W this produces the missing subwebs Wx, such that it's
1617 possible to exactly specify (W-Wy) for all already existing subwebs Wy. */
1620 build_inverse_webs (struct web
*web
)
1622 struct web
*sweb
= web
->subreg_next
;
1623 unsigned HOST_WIDE_INT undef
;
1625 undef
= rtx_to_undefined (web
->orig_x
);
1626 for (; sweb
; sweb
= sweb
->subreg_next
)
1627 /* Only create inverses of non-artificial webs. */
1628 if (!sweb
->artificial
)
1630 unsigned HOST_WIDE_INT bits
;
1631 bits
= undef
& ~ rtx_to_undefined (sweb
->orig_x
);
1634 unsigned int size_word
= undef_to_size_word (web
->orig_x
, &bits
);
1635 if (!find_subweb_2 (web
, size_word
))
1636 add_subweb_2 (web
, size_word
);
1641 /* Copies the content of WEB to a new one, and link it into WL.
1642 Used for consistency checking. */
1645 copy_web (struct web
*web
, struct web_link
**wl
)
1647 struct web
*cweb
= xmalloc (sizeof *cweb
);
1648 struct web_link
*link
= ra_alloc (sizeof *link
);
1655 /* Given a list of webs LINK, compare the content of the webs therein
1656 with the global webs of the same ID. For consistency checking. */
1659 compare_and_free_webs (struct web_link
**link
)
1661 struct web_link
*wl
;
1662 for (wl
= *link
; wl
; wl
= wl
->next
)
1664 struct web
*web1
= wl
->web
;
1665 struct web
*web2
= ID2WEB (web1
->id
);
1666 if (web1
->regno
!= web2
->regno
1667 || web1
->mode_changed
!= web2
->mode_changed
1668 || !rtx_equal_p (web1
->orig_x
, web2
->orig_x
)
1669 || web1
->type
!= web2
->type
1670 /* Only compare num_defs/num_uses with non-hardreg webs.
1671 E.g. the number of uses of the framepointer changes due to
1672 inserting spill code. */
1673 || (web1
->type
!= PRECOLORED
1674 && (web1
->num_uses
!= web2
->num_uses
1675 || web1
->num_defs
!= web2
->num_defs
))
1676 /* Similarly, if the framepointer was unreferenced originally
1677 but we added spills, these fields may not match. */
1678 || (web1
->type
!= PRECOLORED
1679 && web1
->crosses_call
!= web2
->crosses_call
)
1680 || (web1
->type
!= PRECOLORED
1681 && web1
->live_over_abnormal
!= web2
->live_over_abnormal
))
1683 if (web1
->type
!= PRECOLORED
)
1686 for (i
= 0; i
< web1
->num_defs
; i
++)
1687 if (web1
->defs
[i
] != web2
->defs
[i
])
1689 for (i
= 0; i
< web1
->num_uses
; i
++)
1690 if (web1
->uses
[i
] != web2
->uses
[i
])
1693 if (web1
->type
== PRECOLORED
)
1705 /* Setup and fill uses[] and defs[] arrays of the webs. */
1708 init_webs_defs_uses (void)
1711 for (d
= WEBS(INITIAL
); d
; d
= d
->next
)
1713 struct web
*web
= DLIST_WEB (d
);
1714 unsigned int def_i
, use_i
;
1715 struct df_link
*link
;
1718 if (web
->type
== PRECOLORED
)
1720 web
->num_defs
= web
->num_uses
= 0;
1724 web
->defs
= xmalloc (web
->num_defs
* sizeof (web
->defs
[0]));
1726 web
->uses
= xmalloc (web
->num_uses
* sizeof (web
->uses
[0]));
1728 for (link
= web
->temp_refs
; link
; link
= link
->next
)
1730 if (DF_REF_REG_DEF_P (link
->ref
))
1731 web
->defs
[def_i
++] = link
->ref
;
1733 web
->uses
[use_i
++] = link
->ref
;
1735 web
->temp_refs
= NULL
;
1736 if (def_i
!= web
->num_defs
|| use_i
!= web
->num_uses
)
1741 /* Called by parts_to_webs(). This creates (or recreates) the webs (and
1742 subwebs) from web parts, gives them IDs (only to super webs), and sets
1743 up use2web and def2web arrays. */
1746 parts_to_webs_1 (struct df
*df
, struct web_link
**copy_webs
,
1747 struct df_link
*all_refs
)
1750 unsigned int webnum
;
1751 unsigned int def_id
= df
->def_id
;
1752 unsigned int use_id
= df
->use_id
;
1753 struct web_part
*wp_first_use
= &web_parts
[def_id
];
1755 /* For each root web part: create and initialize a new web,
1756 setup def2web[] and use2web[] for all defs and uses, and
1757 id2web for all new webs. */
1760 for (i
= 0; i
< def_id
+ use_id
; i
++)
1762 struct web
*subweb
, *web
= 0; /* Initialize web to silence warnings. */
1763 struct web_part
*wp
= &web_parts
[i
];
1764 struct ref
*ref
= wp
->ref
;
1765 unsigned int ref_id
;
1772 all_refs
[i
].ref
= ref
;
1773 reg
= DF_REF_REG (ref
);
1776 /* If we have a web part root, create a new web. */
1777 unsigned int newid
= ~(unsigned)0;
1778 unsigned int old_web
= 0;
1780 /* In the first pass, there are no old webs, so unconditionally
1781 allocate a new one. */
1784 web
= xmalloc (sizeof (struct web
));
1785 newid
= last_num_webs
++;
1786 init_one_web (web
, GET_CODE (reg
) == SUBREG
1787 ? SUBREG_REG (reg
) : reg
);
1789 /* Otherwise, we look for an old web. */
1792 /* Remember, that use2web == def2web + def_id.
1793 Ergo is def2web[i] == use2web[i - def_id] for i >= def_id.
1794 So we only need to look into def2web[] array.
1795 Try to look at the web, which formerly belonged to this
1798 /* Or which belonged to this hardreg. */
1799 if (!web
&& DF_REF_REGNO (ref
) < FIRST_PSEUDO_REGISTER
)
1800 web
= hardreg2web
[DF_REF_REGNO (ref
)];
1803 /* If we found one, reuse it. */
1804 web
= find_web_for_subweb (web
);
1805 remove_list (web
->dlink
, &WEBS(INITIAL
));
1807 copy_web (web
, copy_webs
);
1811 /* Otherwise use a new one. First from the free list. */
1813 web
= DLIST_WEB (pop_list (&WEBS(FREE
)));
1816 /* Else allocate a new one. */
1817 web
= xmalloc (sizeof (struct web
));
1818 newid
= last_num_webs
++;
1821 /* The id is zeroed in init_one_web(). */
1822 if (newid
== ~(unsigned)0)
1825 reinit_one_web (web
, GET_CODE (reg
) == SUBREG
1826 ? SUBREG_REG (reg
) : reg
);
1828 init_one_web (web
, GET_CODE (reg
) == SUBREG
1829 ? SUBREG_REG (reg
) : reg
);
1830 web
->old_web
= (old_web
&& web
->type
!= PRECOLORED
) ? 1 : 0;
1832 web
->span_deaths
= wp
->spanned_deaths
;
1833 web
->crosses_call
= wp
->crosses_call
;
1835 web
->temp_refs
= NULL
;
1837 if (web
->regno
< FIRST_PSEUDO_REGISTER
&& !hardreg2web
[web
->regno
])
1838 hardreg2web
[web
->regno
] = web
;
1839 else if (web
->regno
< FIRST_PSEUDO_REGISTER
1840 && hardreg2web
[web
->regno
] != web
)
1844 /* If this reference already had a web assigned, we are done.
1845 This test better is equivalent to the web being an old web.
1846 Otherwise something is screwed. (This is tested) */
1847 if (def2web
[i
] != NULL
)
1850 web
= find_web_for_subweb (web
);
1851 /* But if this ref includes a mode change, or was a use live
1852 over an abnormal call, set appropriate flags in the web. */
1853 if ((DF_REF_FLAGS (ref
) & DF_REF_MODE_CHANGE
) != 0
1854 && web
->regno
>= FIRST_PSEUDO_REGISTER
)
1855 web
->mode_changed
= 1;
1856 if ((DF_REF_FLAGS (ref
) & DF_REF_STRIPPED
) != 0
1857 && web
->regno
>= FIRST_PSEUDO_REGISTER
)
1858 web
->subreg_stripped
= 1;
1860 && TEST_BIT (live_over_abnormal
, ref_id
))
1861 web
->live_over_abnormal
= 1;
1862 /* And check, that it's not a newly allocated web. This would be
1863 an inconsistency. */
1864 if (!web
->old_web
|| web
->type
== PRECOLORED
)
1868 /* In case this was no web part root, we need to initialize WEB
1869 from the ref2web array belonging to the root. */
1872 struct web_part
*rwp
= find_web_part (wp
);
1873 unsigned int j
= DF_REF_ID (rwp
->ref
);
1874 if (rwp
< wp_first_use
)
1878 web
= find_web_for_subweb (web
);
1881 /* Remember all references for a web in a single linked list. */
1882 all_refs
[i
].next
= web
->temp_refs
;
1883 web
->temp_refs
= &all_refs
[i
];
1885 /* And the test, that if def2web[i] was NULL above, that we are _not_
1887 if (web
->old_web
&& web
->type
!= PRECOLORED
)
1890 /* Possible create a subweb, if this ref was a subreg. */
1891 if (GET_CODE (reg
) == SUBREG
)
1893 subweb
= find_subweb (web
, reg
);
1896 subweb
= add_subweb (web
, reg
);
1904 /* And look, if the ref involves an invalid mode change. */
1905 if ((DF_REF_FLAGS (ref
) & DF_REF_MODE_CHANGE
) != 0
1906 && web
->regno
>= FIRST_PSEUDO_REGISTER
)
1907 web
->mode_changed
= 1;
1908 if ((DF_REF_FLAGS (ref
) & DF_REF_STRIPPED
) != 0
1909 && web
->regno
>= FIRST_PSEUDO_REGISTER
)
1910 web
->subreg_stripped
= 1;
1912 /* Setup def2web, or use2web, and increment num_defs or num_uses. */
1915 /* Some sanity checks. */
1918 struct web
*compare
= def2web
[i
];
1919 if (i
< last_def_id
)
1921 if (web
->old_web
&& compare
!= subweb
)
1924 if (!web
->old_web
&& compare
)
1926 if (compare
&& compare
!= subweb
)
1929 def2web
[i
] = subweb
;
1936 struct web
*compare
= use2web
[ref_id
];
1937 if (ref_id
< last_use_id
)
1939 if (web
->old_web
&& compare
!= subweb
)
1942 if (!web
->old_web
&& compare
)
1944 if (compare
&& compare
!= subweb
)
1947 use2web
[ref_id
] = subweb
;
1949 if (TEST_BIT (live_over_abnormal
, ref_id
))
1950 web
->live_over_abnormal
= 1;
1954 /* We better now have exactly as many webs as we had web part roots. */
1955 if (webnum
!= num_webs
)
1961 /* This builds full webs out of web parts, without relating them to each
1962 other (i.e. without creating the conflict edges). */
1965 parts_to_webs (struct df
*df
)
1968 unsigned int webnum
;
1969 struct web_link
*copy_webs
= NULL
;
1971 struct df_link
*all_refs
;
1974 /* First build webs and ordinary subwebs. */
1975 all_refs
= xcalloc (df
->def_id
+ df
->use_id
, sizeof (all_refs
[0]));
1976 webnum
= parts_to_webs_1 (df
, ©_webs
, all_refs
);
1978 /* Setup the webs for hardregs which are still missing (weren't
1979 mentioned in the code). */
1980 for (i
= 0; i
< FIRST_PSEUDO_REGISTER
; i
++)
1981 if (!hardreg2web
[i
])
1983 struct web
*web
= xmalloc (sizeof (struct web
));
1984 init_one_web (web
, gen_rtx_REG (reg_raw_mode
[i
], i
));
1985 web
->id
= last_num_webs
++;
1986 hardreg2web
[web
->regno
] = web
;
1988 num_webs
= last_num_webs
;
1990 /* Now create all artificial subwebs, i.e. those, which do
1991 not correspond to a real subreg in the current function's RTL, but
1992 which nevertheless is a target of a conflict.
1993 XXX we need to merge this loop with the one above, which means, we need
1994 a way to later override the artificiality. Beware: currently
1995 add_subweb_2() relies on the existence of normal subwebs for deducing
1996 a sane mode to use for the artificial subwebs. */
1997 for (i
= 0; i
< df
->def_id
+ df
->use_id
; i
++)
1999 struct web_part
*wp
= &web_parts
[i
];
2000 struct tagged_conflict
*cl
;
2002 if (wp
->uplink
|| !wp
->ref
)
2004 if (wp
->sub_conflicts
)
2009 web
= find_web_for_subweb (web
);
2010 for (cl
= wp
->sub_conflicts
; cl
; cl
= cl
->next
)
2011 if (!find_subweb_2 (web
, cl
->size_word
))
2012 add_subweb_2 (web
, cl
->size_word
);
2015 /* And now create artificial subwebs needed for representing the inverse
2016 of some subwebs. This also gives IDs to all subwebs. */
2017 webnum
= last_num_webs
;
2018 for (d
= WEBS(INITIAL
); d
; d
= d
->next
)
2020 struct web
*web
= DLIST_WEB (d
);
2021 if (web
->subreg_next
)
2024 build_inverse_webs (web
);
2025 for (sweb
= web
->subreg_next
; sweb
; sweb
= sweb
->subreg_next
)
2026 sweb
->id
= webnum
++;
2030 /* Now that everyone has an ID, we can setup the id2web array. */
2031 id2web
= xcalloc (webnum
, sizeof (id2web
[0]));
2032 for (d
= WEBS(INITIAL
); d
; d
= d
->next
)
2034 struct web
*web
= DLIST_WEB (d
);
2035 ID2WEB (web
->id
) = web
;
2036 for (web
= web
->subreg_next
; web
; web
= web
->subreg_next
)
2037 ID2WEB (web
->id
) = web
;
2039 num_subwebs
= webnum
- last_num_webs
;
2040 num_allwebs
= num_webs
+ num_subwebs
;
2041 num_webs
+= num_subwebs
;
2043 /* Allocate and clear the conflict graph bitmaps. */
2044 igraph
= sbitmap_alloc (num_webs
* num_webs
/ 2);
2045 sup_igraph
= sbitmap_alloc (num_webs
* num_webs
);
2046 sbitmap_zero (igraph
);
2047 sbitmap_zero (sup_igraph
);
2049 /* Distribute the references to their webs. */
2050 init_webs_defs_uses ();
2051 /* And do some sanity checks if old webs, and those recreated from the
2052 really are the same. */
2053 compare_and_free_webs (©_webs
);
2057 /* This deletes all conflicts to and from webs which need to be renewed
2058 in this pass of the allocator, i.e. those which were spilled in the
2059 last pass. Furthermore it also rebuilds the bitmaps for the remaining
2063 reset_conflicts (void)
2066 bitmap newwebs
= BITMAP_XMALLOC ();
2067 for (i
= 0; i
< num_webs
- num_subwebs
; i
++)
2069 struct web
*web
= ID2WEB (i
);
2070 /* Hardreg webs and non-old webs are new webs (which
2071 need rebuilding). */
2072 if (web
->type
== PRECOLORED
|| !web
->old_web
)
2073 bitmap_set_bit (newwebs
, web
->id
);
2076 for (i
= 0; i
< num_webs
- num_subwebs
; i
++)
2078 struct web
*web
= ID2WEB (i
);
2079 struct conflict_link
*cl
;
2080 struct conflict_link
**pcl
;
2081 pcl
= &(web
->conflict_list
);
2083 /* First restore the conflict list to be like it was before
2085 if (web
->have_orig_conflicts
)
2087 web
->conflict_list
= web
->orig_conflict_list
;
2088 web
->orig_conflict_list
= NULL
;
2090 if (web
->orig_conflict_list
)
2093 /* New non-precolored webs, have no conflict list. */
2094 if (web
->type
!= PRECOLORED
&& !web
->old_web
)
2097 /* Useless conflicts will be rebuilt completely. But check
2098 for cleanliness, as the web might have come from the
2100 if (bitmap_first_set_bit (web
->useless_conflicts
) >= 0)
2105 /* Useless conflicts with new webs will be rebuilt if they
2107 bitmap_operation (web
->useless_conflicts
, web
->useless_conflicts
,
2108 newwebs
, BITMAP_AND_COMPL
);
2109 /* Go through all conflicts, and retain those to old webs. */
2110 for (cl
= web
->conflict_list
; cl
; cl
= cl
->next
)
2112 if (cl
->t
->old_web
|| cl
->t
->type
== PRECOLORED
)
2117 /* Also restore the entries in the igraph bitmaps. */
2118 web
->num_conflicts
+= 1 + cl
->t
->add_hardregs
;
2119 SET_BIT (sup_igraph
, (web
->id
* num_webs
+ cl
->t
->id
));
2120 /* No subconflicts mean full webs conflict. */
2122 SET_BIT (igraph
, igraph_index (web
->id
, cl
->t
->id
));
2124 /* Else only the parts in cl->sub must be in the
2127 struct sub_conflict
*sl
;
2128 for (sl
= cl
->sub
; sl
; sl
= sl
->next
)
2129 SET_BIT (igraph
, igraph_index (sl
->s
->id
, sl
->t
->id
));
2135 web
->have_orig_conflicts
= 0;
2137 BITMAP_XFREE (newwebs
);
2140 /* For each web check it's num_conflicts member against that
2141 number, as calculated from scratch from all neighbors. */
2145 check_conflict_numbers (void)
2148 for (i
= 0; i
< num_webs
; i
++)
2150 struct web
*web
= ID2WEB (i
);
2151 int new_conf
= 0 * web
->add_hardregs
;
2152 struct conflict_link
*cl
;
2153 for (cl
= web
->conflict_list
; cl
; cl
= cl
->next
)
2154 if (cl
->t
->type
!= SELECT
&& cl
->t
->type
!= COALESCED
)
2155 new_conf
+= 1 + cl
->t
->add_hardregs
;
2156 if (web
->type
!= PRECOLORED
&& new_conf
!= web
->num_conflicts
)
2162 /* Convert the conflicts between web parts to conflicts between full webs.
2164 This can't be done in parts_to_webs(), because for recording conflicts
2165 between webs we need to know their final usable_regs set, which is used
2166 to discard non-conflicts (between webs having no hard reg in common).
2167 But this is set for spill temporaries only after the webs itself are
2168 built. Until then the usable_regs set is based on the pseudo regno used
2169 in this web, which may contain far less registers than later determined.
2170 This would result in us loosing conflicts (due to record_conflict()
2171 thinking that a web can only be allocated to the current usable_regs,
2172 whereas later this is extended) leading to colorings, where some regs which
2173 in reality conflict get the same color. */
2176 conflicts_between_webs (struct df
*df
)
2182 bitmap ignore_defs
= BITMAP_XMALLOC ();
2183 unsigned int have_ignored
;
2184 unsigned int *pass_cache
= xcalloc (num_webs
, sizeof (int));
2185 unsigned int pass
= 0;
2190 /* It is possible, that in the conflict bitmaps still some defs I are noted,
2191 which have web_parts[I].ref being NULL. This can happen, when from the
2192 last iteration the conflict bitmap for this part wasn't deleted, but a
2193 conflicting move insn was removed. It's DEF is still in the conflict
2194 bitmap, but it doesn't exist anymore in df->defs. To not have to check
2195 it in the tight loop below, we instead remember the ID's of them in a
2196 bitmap, and loop only over IDs which are not in it. */
2197 for (i
= 0; i
< df
->def_id
; i
++)
2198 if (web_parts
[i
].ref
== NULL
)
2199 bitmap_set_bit (ignore_defs
, i
);
2200 have_ignored
= (bitmap_first_set_bit (ignore_defs
) >= 0);
2202 /* Now record all conflicts between webs. Note that we only check
2203 the conflict bitmaps of all defs. Conflict bitmaps are only in
2204 webpart roots. If they are in uses, those uses are roots, which
2205 means, that this is an uninitialized web, whose conflicts
2206 don't matter. Nevertheless for hardregs we also need to check uses.
2207 E.g. hardregs used for argument passing have no DEF in the RTL,
2208 but if they have uses, they indeed conflict with all DEFs they
2210 for (i
= 0; i
< df
->def_id
+ df
->use_id
; i
++)
2212 struct tagged_conflict
*cl
= web_parts
[i
].sub_conflicts
;
2213 struct web
*supweb1
;
2216 && DF_REF_REGNO (web_parts
[i
].ref
) >= FIRST_PSEUDO_REGISTER
))
2218 supweb1
= def2web
[i
];
2219 supweb1
= find_web_for_subweb (supweb1
);
2220 for (; cl
; cl
= cl
->next
)
2224 struct web
*web1
= find_subweb_2 (supweb1
, cl
->size_word
);
2226 bitmap_operation (cl
->conflicts
, cl
->conflicts
, ignore_defs
,
2228 /* We reduce the number of calls to record_conflict() with this
2229 pass thing. record_conflict() itself also has some early-out
2230 optimizations, but here we can use the special properties of
2231 the loop (constant web1) to reduce that even more.
2232 We once used an sbitmap of already handled web indices,
2233 but sbitmaps are slow to clear and bitmaps are slow to
2234 set/test. The current approach needs more memory, but
2235 locality is large. */
2238 /* Note, that there are only defs in the conflicts bitset. */
2239 EXECUTE_IF_SET_IN_BITMAP (
2240 cl
->conflicts
, 0, j
,
2242 struct web
*web2
= def2web
[j
];
2243 unsigned int id2
= web2
->id
;
2244 if (pass_cache
[id2
] != pass
)
2246 pass_cache
[id2
] = pass
;
2247 record_conflict (web1
, web2
);
2254 BITMAP_XFREE (ignore_defs
);
2257 /* Pseudos can't go in stack regs if they are live at the beginning of
2258 a block that is reached by an abnormal edge. */
2259 for (d
= WEBS(INITIAL
); d
; d
= d
->next
)
2261 struct web
*web
= DLIST_WEB (d
);
2263 if (web
->live_over_abnormal
)
2264 for (j
= FIRST_STACK_REG
; j
<= LAST_STACK_REG
; j
++)
2265 record_conflict (web
, hardreg2web
[j
]);
2270 /* Remember that a web was spilled, and change some characteristics
2274 remember_web_was_spilled (struct web
*web
)
2277 unsigned int found_size
= 0;
2279 web
->spill_temp
= 1;
2281 /* From now on don't use reg_pref/alt_class (regno) anymore for
2282 this web, but instead usable_regs. We can't use spill_temp for
2283 this, as it might get reset later, when we are coalesced to a
2284 non-spill-temp. In that case we still want to use usable_regs. */
2285 web
->use_my_regs
= 1;
2287 /* We don't constrain spill temporaries in any way for now.
2288 It's wrong sometimes to have the same constraints or
2289 preferences as the original pseudo, esp. if they were very narrow.
2290 (E.g. there once was a reg wanting class AREG (only one register)
2291 without alternative class. As long, as also the spill-temps for
2292 this pseudo had the same constraints it was spilled over and over.
2293 Ideally we want some constraints also on spill-temps: Because they are
2294 not only loaded/stored, but also worked with, any constraints from insn
2295 alternatives needs applying. Currently this is dealt with by reload, as
2296 many other things, but at some time we want to integrate that
2297 functionality into the allocator. */
2298 if (web
->regno
>= max_normal_pseudo
)
2300 COPY_HARD_REG_SET (web
->usable_regs
,
2301 reg_class_contents
[reg_preferred_class (web
->regno
)]);
2302 IOR_HARD_REG_SET (web
->usable_regs
,
2303 reg_class_contents
[reg_alternate_class (web
->regno
)]);
2306 COPY_HARD_REG_SET (web
->usable_regs
,
2307 reg_class_contents
[(int) GENERAL_REGS
]);
2308 AND_COMPL_HARD_REG_SET (web
->usable_regs
, never_use_colors
);
2309 prune_hardregs_for_mode (&web
->usable_regs
, PSEUDO_REGNO_MODE (web
->regno
));
2310 #ifdef CANNOT_CHANGE_MODE_CLASS
2311 if (web
->mode_changed
)
2312 AND_COMPL_HARD_REG_SET (web
->usable_regs
, invalid_mode_change_regs
);
2314 web
->num_freedom
= hard_regs_count (web
->usable_regs
);
2315 if (!web
->num_freedom
)
2317 COPY_HARD_REG_SET (web
->orig_usable_regs
, web
->usable_regs
);
2318 /* Now look for a class, which is subset of our constraints, to
2319 setup add_hardregs, and regclass for debug output. */
2320 web
->regclass
= NO_REGS
;
2321 for (i
= (int) ALL_REGS
- 1; i
> 0; i
--)
2325 COPY_HARD_REG_SET (test
, reg_class_contents
[i
]);
2326 AND_COMPL_HARD_REG_SET (test
, never_use_colors
);
2327 GO_IF_HARD_REG_SUBSET (test
, web
->usable_regs
, found
);
2330 /* Measure the actual number of bits which really are overlapping
2331 the target regset, not just the reg_class_size. */
2332 size
= hard_regs_count (test
);
2333 if (found_size
< size
)
2335 web
->regclass
= (enum reg_class
) i
;
2340 adjust
= 0 * web
->add_hardregs
;
2342 CLASS_MAX_NREGS (web
->regclass
, PSEUDO_REGNO_MODE (web
->regno
)) - 1;
2343 web
->num_freedom
-= web
->add_hardregs
;
2344 if (!web
->num_freedom
)
2346 adjust
-= 0 * web
->add_hardregs
;
2347 web
->num_conflicts
-= adjust
;
2350 /* Look at each web, if it is used as spill web. Or better said,
2351 if it will be spillable in this pass. */
2354 detect_spill_temps (void)
2357 bitmap already
= BITMAP_XMALLOC ();
2359 /* Detect webs used for spill temporaries. */
2360 for (d
= WEBS(INITIAL
); d
; d
= d
->next
)
2362 struct web
*web
= DLIST_WEB (d
);
2364 /* Below only the detection of spill temporaries. We never spill
2365 precolored webs, so those can't be spill temporaries. The code above
2366 (remember_web_was_spilled) can't currently cope with hardregs
2368 if (web
->regno
< FIRST_PSEUDO_REGISTER
)
2370 /* Uninitialized webs can't be spill-temporaries. */
2371 if (web
->num_defs
== 0)
2374 /* A web with only defs and no uses can't be spilled. Nevertheless
2375 it must get a color, as it takes away a register from all webs
2376 live at these defs. So we make it a short web. */
2377 if (web
->num_uses
== 0)
2378 web
->spill_temp
= 3;
2379 /* A web which was spilled last time, but for which no insns were
2380 emitted (can happen with IR spilling ignoring sometimes
2382 else if (web
->changed
)
2383 web
->spill_temp
= 1;
2384 /* A spill temporary has one def, one or more uses, all uses
2385 are in one insn, and either the def or use insn was inserted
2386 by the allocator. */
2387 /* XXX not correct currently. There might also be spill temps
2388 involving more than one def. Usually that's an additional
2389 clobber in the using instruction. We might also constrain
2390 ourself to that, instead of like currently marking all
2391 webs involving any spill insns at all. */
2395 int spill_involved
= 0;
2396 for (i
= 0; i
< web
->num_uses
&& !spill_involved
; i
++)
2397 if (DF_REF_INSN_UID (web
->uses
[i
]) >= orig_max_uid
)
2399 for (i
= 0; i
< web
->num_defs
&& !spill_involved
; i
++)
2400 if (DF_REF_INSN_UID (web
->defs
[i
]) >= orig_max_uid
)
2403 if (spill_involved
/* && ra_pass > 2*/)
2405 int num_deaths
= web
->span_deaths
;
2406 /* Mark webs involving at least one spill insn as
2408 remember_web_was_spilled (web
);
2409 /* Search for insns which define and use the web in question
2410 at the same time, i.e. look for rmw insns. If these insns
2411 are also deaths of other webs they might have been counted
2412 as such into web->span_deaths. But because of the rmw nature
2413 of this insn it is no point where a load/reload could be
2414 placed successfully (it would still conflict with the
2415 dead web), so reduce the number of spanned deaths by those
2416 insns. Note that sometimes such deaths are _not_ counted,
2417 so negative values can result. */
2418 bitmap_zero (already
);
2419 for (i
= 0; i
< web
->num_defs
; i
++)
2421 rtx insn
= web
->defs
[i
]->insn
;
2422 if (TEST_BIT (insns_with_deaths
, INSN_UID (insn
))
2423 && !bitmap_bit_p (already
, INSN_UID (insn
)))
2426 bitmap_set_bit (already
, INSN_UID (insn
));
2427 /* Only decrement it once for each insn. */
2428 for (j
= 0; j
< web
->num_uses
; j
++)
2429 if (web
->uses
[j
]->insn
== insn
)
2436 /* But mark them specially if they could possibly be spilled,
2437 either because they cross some deaths (without the above
2438 mentioned ones) or calls. */
2439 if (web
->crosses_call
|| num_deaths
> 0)
2440 web
->spill_temp
= 1 * 2;
2442 /* A web spanning no deaths can't be spilled either. No loads
2443 would be created for it, ergo no defs. So the insns wouldn't
2444 change making the graph not easier to color. Make this also
2445 a short web. Don't do this if it crosses calls, as these are
2446 also points of reloads. */
2447 else if (web
->span_deaths
== 0 && !web
->crosses_call
)
2448 web
->spill_temp
= 3;
2450 web
->orig_spill_temp
= web
->spill_temp
;
2452 BITMAP_XFREE (already
);
2455 /* Returns nonzero if the rtx MEM refers somehow to a stack location. */
2458 memref_is_stack_slot (rtx mem
)
2460 rtx ad
= XEXP (mem
, 0);
2462 if (GET_CODE (ad
) != PLUS
|| GET_CODE (XEXP (ad
, 1)) != CONST_INT
)
2465 if (x
== frame_pointer_rtx
|| x
== hard_frame_pointer_rtx
2466 || (x
== arg_pointer_rtx
&& fixed_regs
[ARG_POINTER_REGNUM
])
2467 || x
== stack_pointer_rtx
)
2472 /* Returns nonzero, if rtx X somewhere contains any pseudo register. */
2475 contains_pseudo (rtx x
)
2479 if (GET_CODE (x
) == SUBREG
)
2483 if (REGNO (x
) >= FIRST_PSEUDO_REGISTER
)
2489 fmt
= GET_RTX_FORMAT (GET_CODE (x
));
2490 for (i
= GET_RTX_LENGTH (GET_CODE (x
)) - 1; i
>= 0; i
--)
2493 if (contains_pseudo (XEXP (x
, i
)))
2496 else if (fmt
[i
] == 'E')
2499 for (j
= 0; j
< XVECLEN (x
, i
); j
++)
2500 if (contains_pseudo (XVECEXP (x
, i
, j
)))
2506 /* Returns nonzero, if we are able to rematerialize something with
2507 value X. If it's not a general operand, we test if we can produce
2508 a valid insn which set a pseudo to that value, and that insn doesn't
2509 clobber anything. */
2511 static GTY(()) rtx remat_test_insn
;
2513 want_to_remat (rtx x
)
2515 int num_clobbers
= 0;
2518 /* If this is a valid operand, we are OK. If it's VOIDmode, we aren't. */
2519 if (general_operand (x
, GET_MODE (x
)))
2522 /* Otherwise, check if we can make a valid insn from it. First initialize
2523 our test insn if we haven't already. */
2524 if (remat_test_insn
== 0)
2527 = make_insn_raw (gen_rtx_SET (VOIDmode
,
2528 gen_rtx_REG (word_mode
,
2529 FIRST_PSEUDO_REGISTER
* 2),
2531 NEXT_INSN (remat_test_insn
) = PREV_INSN (remat_test_insn
) = 0;
2534 /* Now make an insn like the one we would make when rematerializing
2535 the value X and see if valid. */
2536 PUT_MODE (SET_DEST (PATTERN (remat_test_insn
)), GET_MODE (x
));
2537 SET_SRC (PATTERN (remat_test_insn
)) = x
;
2538 /* XXX For now we don't allow any clobbers to be added, not just no
2539 hardreg clobbers. */
2540 return ((icode
= recog (PATTERN (remat_test_insn
), remat_test_insn
,
2541 &num_clobbers
)) >= 0
2542 && (num_clobbers
== 0
2543 /*|| ! added_clobbers_hard_reg_p (icode)*/));
2546 /* Look at all webs, if they perhaps are rematerializable.
2547 They are, if all their defs are simple sets to the same value,
2548 and that value is simple enough, and want_to_remat() holds for it. */
2551 detect_remat_webs (void)
2554 for (d
= WEBS(INITIAL
); d
; d
= d
->next
)
2556 struct web
*web
= DLIST_WEB (d
);
2559 /* Hardregs and useless webs aren't spilled -> no remat necessary.
2560 Defless webs obviously also can't be rematerialized. */
2561 if (web
->regno
< FIRST_PSEUDO_REGISTER
|| !web
->num_defs
2564 for (i
= 0; i
< web
->num_defs
; i
++)
2567 rtx set
= single_set (insn
= DF_REF_INSN (web
->defs
[i
]));
2571 src
= SET_SRC (set
);
2572 /* When only subregs of the web are set it isn't easily
2573 rematerializable. */
2574 if (!rtx_equal_p (SET_DEST (set
), web
->orig_x
))
2576 /* If we already have a pattern it must be equal to the current. */
2577 if (pat
&& !rtx_equal_p (pat
, src
))
2579 /* Don't do the expensive checks multiple times. */
2582 /* For now we allow only constant sources. */
2583 if ((CONSTANT_P (src
)
2584 /* If the whole thing is stable already, it is a source for
2585 remat, no matter how complicated (probably all needed
2586 resources for it are live everywhere, and don't take
2587 additional register resources). */
2588 /* XXX Currently we can't use patterns which contain
2589 pseudos, _even_ if they are stable. The code simply isn't
2590 prepared for that. All those operands can't be spilled (or
2591 the dependent remat webs are not remat anymore), so they
2592 would be oldwebs in the next iteration. But currently
2593 oldwebs can't have their references changed. The
2594 incremental machinery barfs on that. */
2595 || (!rtx_unstable_p (src
) && !contains_pseudo (src
))
2596 /* Additionally also memrefs to stack-slots are useful, when
2597 we created them ourself. They might not have set their
2598 unchanging flag set, but nevertheless they are stable across
2599 the livetime in question. */
2600 || (GET_CODE (src
) == MEM
2601 && INSN_UID (insn
) >= orig_max_uid
2602 && memref_is_stack_slot (src
)))
2603 /* And we must be able to construct an insn without
2604 side-effects to actually load that value into a reg. */
2605 && want_to_remat (src
))
2610 if (pat
&& i
== web
->num_defs
)
2615 /* Determine the spill costs of all webs. */
2618 determine_web_costs (void)
2621 for (d
= WEBS(INITIAL
); d
; d
= d
->next
)
2623 unsigned int i
, num_loads
;
2624 int load_cost
, store_cost
;
2625 unsigned HOST_WIDE_INT w
;
2626 struct web
*web
= DLIST_WEB (d
);
2627 if (web
->type
== PRECOLORED
)
2629 /* Get costs for one load/store. Note that we offset them by 1,
2630 because some patterns have a zero rtx_cost(), but we of course
2631 still need the actual load/store insns. With zero all those
2632 webs would be the same, no matter how often and where
2636 /* This web is rematerializable. Beware, we set store_cost to
2637 zero optimistically assuming, that we indeed don't emit any
2638 stores in the spill-code addition. This might be wrong if
2639 at the point of the load not all needed resources are
2640 available, in which case we emit a stack-based load, for
2641 which we in turn need the according stores. */
2642 load_cost
= 1 + rtx_cost (web
->pattern
, 0);
2647 load_cost
= 1 + MEMORY_MOVE_COST (GET_MODE (web
->orig_x
),
2649 store_cost
= 1 + MEMORY_MOVE_COST (GET_MODE (web
->orig_x
),
2652 /* We create only loads at deaths, whose number is in span_deaths. */
2653 num_loads
= MIN (web
->span_deaths
, web
->num_uses
);
2654 for (w
= 0, i
= 0; i
< web
->num_uses
; i
++)
2655 w
+= DF_REF_BB (web
->uses
[i
])->frequency
+ 1;
2656 if (num_loads
< web
->num_uses
)
2657 w
= (w
* num_loads
+ web
->num_uses
- 1) / web
->num_uses
;
2658 web
->spill_cost
= w
* load_cost
;
2661 for (w
= 0, i
= 0; i
< web
->num_defs
; i
++)
2662 w
+= DF_REF_BB (web
->defs
[i
])->frequency
+ 1;
2663 web
->spill_cost
+= w
* store_cost
;
2665 web
->orig_spill_cost
= web
->spill_cost
;
2669 /* Detect webs which are set in a conditional jump insn (possibly a
2670 decrement-and-branch type of insn), and mark them not to be
2671 spillable. The stores for them would need to be placed on edges,
2672 which destroys the CFG. (Somewhen we want to deal with that XXX) */
2675 detect_webs_set_in_cond_jump (void)
2679 if (GET_CODE (BB_END (bb
)) == JUMP_INSN
)
2681 struct df_link
*link
;
2682 for (link
= DF_INSN_DEFS (df
, BB_END (bb
)); link
; link
= link
->next
)
2683 if (link
->ref
&& DF_REF_REGNO (link
->ref
) >= FIRST_PSEUDO_REGISTER
)
2685 struct web
*web
= def2web
[DF_REF_ID (link
->ref
)];
2686 web
->orig_spill_temp
= web
->spill_temp
= 3;
2691 /* Second top-level function of this file.
2692 Converts the connected web parts to full webs. This means, it allocates
2693 all webs, and initializes all fields, including detecting spill
2694 temporaries. It does not distribute moves to their corresponding webs,
2698 make_webs (struct df
*df
)
2700 /* First build all the webs itself. They are not related with
2703 /* Now detect spill temporaries to initialize their usable_regs set. */
2704 detect_spill_temps ();
2705 detect_webs_set_in_cond_jump ();
2706 /* And finally relate them to each other, meaning to record all possible
2707 conflicts between webs (see the comment there). */
2708 conflicts_between_webs (df
);
2709 detect_remat_webs ();
2710 determine_web_costs ();
2713 /* Distribute moves to the corresponding webs. */
2716 moves_to_webs (struct df
*df
)
2718 struct df_link
*link
;
2719 struct move_list
*ml
;
2721 /* Distribute all moves to their corresponding webs, making sure,
2722 each move is in a web maximally one time (happens on some strange
2724 for (ml
= wl_moves
; ml
; ml
= ml
->next
)
2726 struct move
*m
= ml
->move
;
2728 struct move_list
*newml
;
2733 /* Multiple defs/uses can happen in moves involving hard-regs in
2734 a wider mode. For those df.* creates use/def references for each
2735 real hard-reg involved. For coalescing we are interested in
2736 the smallest numbered hard-reg. */
2737 for (link
= DF_INSN_DEFS (df
, m
->insn
); link
; link
= link
->next
)
2740 web
= def2web
[DF_REF_ID (link
->ref
)];
2741 web
= find_web_for_subweb (web
);
2742 if (!m
->target_web
|| web
->regno
< m
->target_web
->regno
)
2743 m
->target_web
= web
;
2745 for (link
= DF_INSN_USES (df
, m
->insn
); link
; link
= link
->next
)
2748 web
= use2web
[DF_REF_ID (link
->ref
)];
2749 web
= find_web_for_subweb (web
);
2750 if (!m
->source_web
|| web
->regno
< m
->source_web
->regno
)
2751 m
->source_web
= web
;
2753 if (m
->source_web
&& m
->target_web
2754 /* If the usable_regs don't intersect we can't coalesce the two
2755 webs anyway, as this is no simple copy insn (it might even
2756 need an intermediate stack temp to execute this "copy" insn). */
2757 && hard_regs_intersect_p (&m
->source_web
->usable_regs
,
2758 &m
->target_web
->usable_regs
))
2760 if (!flag_ra_optimistic_coalescing
)
2762 struct move_list
*test
= m
->source_web
->moves
;
2763 for (; test
&& test
->move
!= m
; test
= test
->next
);
2766 newml
= ra_alloc (sizeof (struct move_list
));
2768 newml
->next
= m
->source_web
->moves
;
2769 m
->source_web
->moves
= newml
;
2771 test
= m
->target_web
->moves
;
2772 for (; test
&& test
->move
!= m
; test
= test
->next
);
2775 newml
= ra_alloc (sizeof (struct move_list
));
2777 newml
->next
= m
->target_web
->moves
;
2778 m
->target_web
->moves
= newml
;
2783 /* Delete this move. */
2788 /* Handle tricky asm insns.
2789 Supposed to create conflicts to hardregs which aren't allowed in
2790 the constraints. Doesn't actually do that, as it might confuse
2791 and constrain the allocator too much. */
2794 handle_asm_insn (struct df
*df
, rtx insn
)
2796 const char *constraints
[MAX_RECOG_OPERANDS
];
2797 enum machine_mode operand_mode
[MAX_RECOG_OPERANDS
];
2798 int i
, noperands
, in_output
;
2799 HARD_REG_SET clobbered
, allowed
, conflict
;
2802 || (noperands
= asm_noperands (PATTERN (insn
))) < 0)
2804 pat
= PATTERN (insn
);
2805 CLEAR_HARD_REG_SET (clobbered
);
2807 if (GET_CODE (pat
) == PARALLEL
)
2808 for (i
= 0; i
< XVECLEN (pat
, 0); i
++)
2810 rtx t
= XVECEXP (pat
, 0, i
);
2811 if (GET_CODE (t
) == CLOBBER
&& REG_P (XEXP (t
, 0))
2812 && REGNO (XEXP (t
, 0)) < FIRST_PSEUDO_REGISTER
)
2813 SET_HARD_REG_BIT (clobbered
, REGNO (XEXP (t
, 0)));
2816 decode_asm_operands (pat
, recog_data
.operand
, recog_data
.operand_loc
,
2817 constraints
, operand_mode
);
2819 for (i
= 0; i
< noperands
; i
++)
2821 const char *p
= constraints
[i
];
2822 int cls
= (int) NO_REGS
;
2823 struct df_link
*link
;
2826 int nothing_allowed
= 1;
2827 reg
= recog_data
.operand
[i
];
2829 /* Look, if the constraints apply to a pseudo reg, and not to
2831 while (GET_CODE (reg
) == SUBREG
2832 || GET_CODE (reg
) == ZERO_EXTRACT
2833 || GET_CODE (reg
) == SIGN_EXTRACT
2834 || GET_CODE (reg
) == STRICT_LOW_PART
)
2835 reg
= XEXP (reg
, 0);
2836 if (!REG_P (reg
) || REGNO (reg
) < FIRST_PSEUDO_REGISTER
)
2839 /* Search the web corresponding to this operand. We depend on
2840 that decode_asm_operands() places the output operands
2841 before the input operands. */
2845 link
= df
->insns
[INSN_UID (insn
)].defs
;
2847 link
= df
->insns
[INSN_UID (insn
)].uses
;
2848 while (link
&& link
->ref
&& DF_REF_REAL_REG (link
->ref
) != reg
)
2850 if (!link
|| !link
->ref
)
2861 web
= def2web
[DF_REF_ID (link
->ref
)];
2863 web
= use2web
[DF_REF_ID (link
->ref
)];
2864 reg
= DF_REF_REG (link
->ref
);
2866 /* Find the constraints, noting the allowed hardregs in allowed. */
2867 CLEAR_HARD_REG_SET (allowed
);
2872 if (c
== '\0' || c
== ',' || c
== '#')
2874 /* End of one alternative - mark the regs in the current
2875 class, and reset the class. */
2877 IOR_HARD_REG_SET (allowed
, reg_class_contents
[cls
]);
2879 nothing_allowed
= 0;
2884 } while (c
!= '\0' && c
!= ',');
2892 case '=': case '+': case '*': case '%': case '?': case '!':
2893 case '0': case '1': case '2': case '3': case '4': case 'm':
2894 case '<': case '>': case 'V': case 'o': case '&': case 'E':
2895 case 'F': case 's': case 'i': case 'n': case 'X': case 'I':
2896 case 'J': case 'K': case 'L': case 'M': case 'N': case 'O':
2901 cls
= (int) reg_class_subunion
[cls
][(int) BASE_REG_CLASS
];
2902 nothing_allowed
= 0;
2907 cls
= (int) reg_class_subunion
[cls
][(int) GENERAL_REGS
];
2908 nothing_allowed
= 0;
2913 (int) reg_class_subunion
[cls
][(int)
2914 REG_CLASS_FROM_CONSTRAINT (c
,
2917 p
+= CONSTRAINT_LEN (c
, p
);
2920 /* Now make conflicts between this web, and all hardregs, which
2921 are not allowed by the constraints. */
2922 if (nothing_allowed
)
2924 /* If we had no real constraints nothing was explicitly
2925 allowed, so we allow the whole class (i.e. we make no
2926 additional conflicts). */
2927 CLEAR_HARD_REG_SET (conflict
);
2931 COPY_HARD_REG_SET (conflict
, usable_regs
2932 [reg_preferred_class (web
->regno
)]);
2933 IOR_HARD_REG_SET (conflict
, usable_regs
2934 [reg_alternate_class (web
->regno
)]);
2935 AND_COMPL_HARD_REG_SET (conflict
, allowed
);
2936 /* We can't yet establish these conflicts. Reload must go first
2937 (or better said, we must implement some functionality of reload).
2938 E.g. if some operands must match, and they need the same color
2939 we don't see yet, that they do not conflict (because they match).
2940 For us it looks like two normal references with different DEFs,
2941 so they conflict, and as they both need the same color, the
2942 graph becomes uncolorable. */
2944 for (c
= 0; c
< FIRST_PSEUDO_REGISTER
; c
++)
2945 if (TEST_HARD_REG_BIT (conflict
, c
))
2946 record_conflict (web
, hardreg2web
[c
]);
2952 ra_debug_msg (DUMP_ASM
, " ASM constrain Web %d conflicts with:", web
->id
);
2953 for (c
= 0; c
< FIRST_PSEUDO_REGISTER
; c
++)
2954 if (TEST_HARD_REG_BIT (conflict
, c
))
2955 ra_debug_msg (DUMP_ASM
, " %d", c
);
2956 ra_debug_msg (DUMP_ASM
, "\n");
2961 /* The real toplevel function in this file.
2962 Build (or rebuilds) the complete interference graph with webs
2966 build_i_graph (struct df
*df
)
2970 init_web_parts (df
);
2972 sbitmap_zero (move_handled
);
2975 build_web_parts_and_conflicts (df
);
2977 /* For read-modify-write instructions we may have created two webs.
2978 Reconnect them here. (s.a.) */
2979 connect_rmw_web_parts (df
);
2981 /* The webs are conceptually complete now, but still scattered around as
2982 connected web parts. Collect all information and build the webs
2983 including all conflicts between webs (instead web parts). */
2987 /* Look for additional constraints given by asms. */
2988 for (insn
= get_insns (); insn
; insn
= NEXT_INSN (insn
))
2989 handle_asm_insn (df
, insn
);
2992 /* Allocates or reallocates most memory for the interference graph and
2993 associated structures. If it reallocates memory (meaning, this is not
2994 the first pass), this also changes some structures to reflect the
2995 additional entries in various array, and the higher number of
2999 ra_build_realloc (struct df
*df
)
3001 struct web_part
*last_web_parts
= web_parts
;
3002 struct web
**last_def2web
= def2web
;
3003 struct web
**last_use2web
= use2web
;
3004 sbitmap last_live_over_abnormal
= live_over_abnormal
;
3007 move_handled
= sbitmap_alloc (get_max_uid () );
3008 web_parts
= xcalloc (df
->def_id
+ df
->use_id
, sizeof web_parts
[0]);
3009 def2web
= xcalloc (df
->def_id
+ df
->use_id
, sizeof def2web
[0]);
3010 use2web
= &def2web
[df
->def_id
];
3011 live_over_abnormal
= sbitmap_alloc (df
->use_id
);
3012 sbitmap_zero (live_over_abnormal
);
3014 /* First go through all old defs and uses. */
3015 for (i
= 0; i
< last_def_id
+ last_use_id
; i
++)
3017 /* And relocate them to the new array. This is made ugly by the
3018 fact, that defs and uses are placed consecutive into one array. */
3019 struct web_part
*dest
= &web_parts
[i
< last_def_id
3020 ? i
: (df
->def_id
+ i
- last_def_id
)];
3021 struct web_part
*up
;
3022 *dest
= last_web_parts
[i
];
3024 dest
->uplink
= NULL
;
3026 /* Also relocate the uplink to point into the new array. */
3029 unsigned int id
= DF_REF_ID (up
->ref
);
3030 if (up
< &last_web_parts
[last_def_id
])
3033 dest
->uplink
= &web_parts
[DF_REF_ID (up
->ref
)];
3035 else if (df
->uses
[id
])
3036 dest
->uplink
= &web_parts
[df
->def_id
+ DF_REF_ID (up
->ref
)];
3040 /* Also set up the def2web and use2web arrays, from the last pass.i
3041 Remember also the state of live_over_abnormal. */
3042 for (i
= 0; i
< last_def_id
; i
++)
3044 struct web
*web
= last_def2web
[i
];
3047 web
= find_web_for_subweb (web
);
3048 if (web
->type
!= FREE
&& web
->type
!= PRECOLORED
)
3049 def2web
[i
] = last_def2web
[i
];
3052 for (i
= 0; i
< last_use_id
; i
++)
3054 struct web
*web
= last_use2web
[i
];
3057 web
= find_web_for_subweb (web
);
3058 if (web
->type
!= FREE
&& web
->type
!= PRECOLORED
)
3059 use2web
[i
] = last_use2web
[i
];
3061 if (TEST_BIT (last_live_over_abnormal
, i
))
3062 SET_BIT (live_over_abnormal
, i
);
3065 /* We don't have any subwebs for now. Somewhen we might want to
3066 remember them too, instead of recreating all of them every time.
3067 The problem is, that which subwebs we need, depends also on what
3068 other webs and subwebs exist, and which conflicts are there.
3069 OTOH it should be no problem, if we had some more subwebs than strictly
3071 for (d
= WEBS(FREE
); d
; d
= d
->next
)
3073 struct web
*web
= DLIST_WEB (d
);
3075 for (web
= web
->subreg_next
; web
; web
= wnext
)
3077 wnext
= web
->subreg_next
;
3080 DLIST_WEB (d
)->subreg_next
= NULL
;
3083 /* The uses we anyway are going to check, are not yet live over an abnormal
3084 edge. In fact, they might actually not anymore, due to added
3086 if (last_check_uses
)
3087 sbitmap_difference (live_over_abnormal
, live_over_abnormal
,
3090 if (last_def_id
|| last_use_id
)
3092 sbitmap_free (last_live_over_abnormal
);
3093 free (last_web_parts
);
3094 free (last_def2web
);
3098 /* Setup copy cache, for copy_insn_p (). */
3099 copy_cache
= xcalloc (get_max_uid (), sizeof (copy_cache
[0]));
3104 copy_cache
= xrealloc (copy_cache
, get_max_uid () * sizeof (copy_cache
[0]));
3105 memset (©_cache
[last_max_uid
], 0,
3106 (get_max_uid () - last_max_uid
) * sizeof (copy_cache
[0]));
3110 /* Free up/clear some memory, only needed for one pass. */
3113 ra_build_free (void)
3118 /* Clear the moves associated with a web (we also need to look into
3120 for (i
= 0; i
< num_webs
; i
++)
3122 struct web
*web
= ID2WEB (i
);
3125 if (i
>= num_webs
- num_subwebs
3126 && (web
->conflict_list
|| web
->orig_conflict_list
))
3130 /* All webs in the free list have no defs or uses anymore. */
3131 for (d
= WEBS(FREE
); d
; d
= d
->next
)
3133 struct web
*web
= DLIST_WEB (d
);
3140 /* We can't free the subwebs here, as they are referenced from
3141 def2web[], and possibly needed in the next ra_build_realloc().
3142 We free them there (or in free_all_mem()). */
3145 /* Free all conflict bitmaps from web parts. Note that we clear
3146 _all_ these conflicts, and don't rebuild them next time for uses
3147 which aren't rechecked. This mean, that those conflict bitmaps
3148 only contain the incremental information. The cumulative one
3149 is still contained in the edges of the I-graph, i.e. in
3150 conflict_list (or orig_conflict_list) of the webs. */
3151 for (i
= 0; i
< df
->def_id
+ df
->use_id
; i
++)
3153 struct tagged_conflict
*cl
;
3154 for (cl
= web_parts
[i
].sub_conflicts
; cl
; cl
= cl
->next
)
3157 BITMAP_XFREE (cl
->conflicts
);
3159 web_parts
[i
].sub_conflicts
= NULL
;
3165 free (move_handled
);
3166 sbitmap_free (sup_igraph
);
3167 sbitmap_free (igraph
);
3170 /* Free all memory for the interference graph structures. */
3173 ra_build_free_all (struct df
*df
)
3180 for (i
= 0; i
< df
->def_id
+ df
->use_id
; i
++)
3182 struct tagged_conflict
*cl
;
3183 for (cl
= web_parts
[i
].sub_conflicts
; cl
; cl
= cl
->next
)
3186 BITMAP_XFREE (cl
->conflicts
);
3188 web_parts
[i
].sub_conflicts
= NULL
;
3190 sbitmap_free (live_over_abnormal
);
3193 if (last_check_uses
)
3194 sbitmap_free (last_check_uses
);
3195 last_check_uses
= NULL
;
3201 #include "gt-ra-build.h"
3204 vim:cinoptions={.5s,g0,p5,t0,(0,^-0.5s,n-0.5s:tw=78:cindent:sw=4: