* config/alpha/alpha.c (emit_insxl): Force the first operand of
[official-gcc.git] / gcc / df.h
blob689e058afb11a126d6250025e970e9a8f8752ca4
1 /* Form lists of pseudo register references for autoinc optimization
2 for GNU compiler. This is part of flow optimization.
3 Copyright (C) 1999, 2000, 2001, 2003, 2004, 2005, 2006
4 Free Software Foundation, Inc.
5 Originally contributed by Michael P. Hayes
6 (m.hayes@elec.canterbury.ac.nz, mhayes@redhat.com)
7 Major rewrite contributed by Danny Berlin (dberlin@dberlin.org)
8 and Kenneth Zadeck (zadeck@naturalbridge.com).
10 This file is part of GCC.
12 GCC is free software; you can redistribute it and/or modify it under
13 the terms of the GNU General Public License as published by the Free
14 Software Foundation; either version 2, or (at your option) any later
15 version.
17 GCC is distributed in the hope that it will be useful, but WITHOUT ANY
18 WARRANTY; without even the implied warranty of MERCHANTABILITY or
19 FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
20 for more details.
22 You should have received a copy of the GNU General Public License
23 along with GCC; see the file COPYING. If not, write to the Free
24 Software Foundation, 51 Franklin Street, Fifth Floor, Boston, MA
25 02110-1301, USA. */
27 #ifndef GCC_DF_H
28 #define GCC_DF_H
30 #include "bitmap.h"
31 #include "basic-block.h"
32 #include "alloc-pool.h"
34 struct dataflow;
35 struct df;
36 struct df_problem;
37 struct df_link;
39 /* Data flow problems. All problems must have a unique here. */
40 /* Scanning is not really a dataflow problem, but it is useful to have
41 the basic block functions in the vector so that things get done in
42 a uniform manner. */
43 #define DF_SCAN 0
44 #define DF_RU 1 /* Reaching Uses. */
45 #define DF_RD 2 /* Reaching Defs. */
46 #define DF_LR 3 /* Live Registers. */
47 #define DF_UR 4 /* Uninitialized Registers. */
48 #define DF_UREC 5 /* Uninitialized Registers with Early Clobber. */
49 #define DF_CHAIN 6 /* Def-Use and/or Use-Def Chains. */
50 #define DF_RI 7 /* Register Info. */
51 #define DF_LAST_PROBLEM_PLUS1 (DF_RI + 1)
54 /* Dataflow direction. */
55 enum df_flow_dir
57 DF_NONE,
58 DF_FORWARD,
59 DF_BACKWARD
63 /* The first of these is a set of a register. The remaining three are
64 all uses of a register (the mem_load and mem_store relate to how
65 the register as an addressing operand). */
66 enum df_ref_type {DF_REF_REG_DEF, DF_REF_REG_USE, DF_REF_REG_MEM_LOAD,
67 DF_REF_REG_MEM_STORE};
69 #define DF_REF_TYPE_NAMES {"def", "use", "mem load", "mem store"}
71 enum df_ref_flags
73 /* Read-modify-write refs generate both a use and a def and
74 these are marked with this flag to show that they are not
75 independent. */
76 DF_REF_READ_WRITE = 1,
78 /* This flag is set, if we stripped the subreg from the reference.
79 In this case we must make conservative guesses, at what the
80 outer mode was. */
81 DF_REF_STRIPPED = 2,
83 /* If this flag is set, this is not a real definition/use, but an
84 artificial one created to model always live registers, eh uses, etc. */
85 DF_REF_ARTIFICIAL = 4,
88 /* If this flag is set for an artificial use or def, that ref
89 logically happens at the top of the block. If it is not set
90 for an artificial use or def, that ref logically happens at the
91 bottom of the block. This is never set for regular refs. */
92 DF_REF_AT_TOP = 8,
94 /* This flag is set if the use is inside a REG_EQUAL note. */
95 DF_REF_IN_NOTE = 16,
97 /* This flag is set if this ref, generally a def, may clobber the
98 referenced register. This is generally only set for hard
99 registers that cross a call site. With better information
100 about calls, some of these could be changed in the future to
101 DF_REF_MUST_CLOBBER. */
102 DF_REF_MAY_CLOBBER = 32,
104 /* This flag is set if this ref, generally a def, is a real
105 clobber. This is not currently set for registers live across a
106 call because that clobbering may or may not happen.
108 Most of the uses of this are with sets that have a
109 GET_CODE(..)==CLOBBER. Note that this is set even if the
110 clobber is to a subreg. So in order to tell if the clobber
111 wipes out the entire register, it is necessary to also check
112 the DF_REF_PARTIAL flag. */
113 DF_REF_MUST_CLOBBER = 64,
115 /* This bit is true if this ref is part of a multiword hardreg. */
116 DF_REF_MW_HARDREG = 128,
118 /* This flag is set if this ref is a partial use or def of the
119 associated register. */
120 DF_REF_PARTIAL = 256
124 /* Function prototypes added to df_problem instance. */
126 /* Allocate the problem specific data. */
127 typedef void (*df_alloc_function) (struct dataflow *, bitmap, bitmap);
129 /* This function is called if the problem has global data that needs
130 to be cleared when ever the set of blocks changes. The bitmap
131 contains the set of blocks that may require special attention.
132 This call is only made if some of the blocks are going to change.
133 If everything is to be deleted, the wholesale deletion mechanisms
134 apply. */
135 typedef void (*df_reset_function) (struct dataflow *, bitmap);
137 /* Free the basic block info. Called from the block reordering code
138 to get rid of the blocks that have been squished down. */
139 typedef void (*df_free_bb_function) (struct dataflow *, basic_block, void *);
141 /* Local compute function. */
142 typedef void (*df_local_compute_function) (struct dataflow *, bitmap, bitmap);
144 /* Init the solution specific data. */
145 typedef void (*df_init_function) (struct dataflow *, bitmap);
147 /* Iterative dataflow function. */
148 typedef void (*df_dataflow_function) (struct dataflow *, bitmap, bitmap,
149 int *, int, bool);
151 /* Confluence operator for blocks with 0 out (or in) edges. */
152 typedef void (*df_confluence_function_0) (struct dataflow *, basic_block);
154 /* Confluence operator for blocks with 1 or more out (or in) edges. */
155 typedef void (*df_confluence_function_n) (struct dataflow *, edge);
157 /* Transfer function for blocks. */
158 typedef bool (*df_transfer_function) (struct dataflow *, int);
160 /* Function to massage the information after the problem solving. */
161 typedef void (*df_finalizer_function) (struct dataflow*, bitmap);
163 /* Function to free all of the problem specific datastructures. */
164 typedef void (*df_free_function) (struct dataflow *);
166 /* Function to dump results to FILE. */
167 typedef void (*df_dump_problem_function) (struct dataflow *, FILE *);
169 /* Function to add problem a dataflow problem that must be solved
170 before this problem can be solved. */
171 typedef struct dataflow * (*df_dependent_problem_function) (struct df *, int);
173 /* The static description of a dataflow problem to solve. See above
174 typedefs for doc for the function fields. */
176 struct df_problem {
177 /* The unique id of the problem. This is used it index into
178 df->defined_problems to make accessing the problem data easy. */
179 unsigned int id;
180 enum df_flow_dir dir; /* Dataflow direction. */
181 df_alloc_function alloc_fun;
182 df_reset_function reset_fun;
183 df_free_bb_function free_bb_fun;
184 df_local_compute_function local_compute_fun;
185 df_init_function init_fun;
186 df_dataflow_function dataflow_fun;
187 df_confluence_function_0 con_fun_0;
188 df_confluence_function_n con_fun_n;
189 df_transfer_function trans_fun;
190 df_finalizer_function finalize_fun;
191 df_free_function free_fun;
192 df_dump_problem_function dump_fun;
193 df_dependent_problem_function dependent_problem_fun;
195 /* Flags can be changed after analysis starts. */
196 int changeable_flags;
200 /* The specific instance of the problem to solve. */
201 struct dataflow
203 struct df *df; /* Instance of df we are working in. */
204 struct df_problem *problem; /* The problem to be solved. */
206 /* Communication between iterative_dataflow and hybrid_search. */
207 sbitmap visited, pending, considered;
209 /* Array indexed by bb->index, that contains basic block problem and
210 solution specific information. */
211 void **block_info;
212 unsigned int block_info_size;
214 /* The pool to allocate the block_info from. */
215 alloc_pool block_pool;
217 /* Problem specific control information. */
219 /* Scanning flags. */
220 #define DF_HARD_REGS 1 /* Mark hard registers. */
221 #define DF_EQUIV_NOTES 2 /* Mark uses present in EQUIV/EQUAL notes. */
222 #define DF_SUBREGS 4 /* Return subregs rather than the inner reg. */
223 /* Flags that control the building of chains. */
224 #define DF_DU_CHAIN 1 /* Build DU chains. */
225 #define DF_UD_CHAIN 2 /* Build UD chains. */
226 /* Flag to control the building of register info. */
227 #define DF_RI_LIFE 1 /* Build register info. */
229 int flags;
231 /* Other problem specific data that is not on a per basic block
232 basis. The structure is generally defined privately for the
233 problem. The exception being the scanning problem where it is
234 fully public. */
235 void *problem_data;
239 /* The set of multiword hardregs used as operands to this
240 instruction. These are factored into individual uses and defs but
241 the aggregate is still needed to service the REG_DEAD and
242 REG_UNUSED notes. */
243 struct df_mw_hardreg
245 rtx mw_reg; /* The multiword hardreg. */
246 enum df_ref_type type; /* Used to see if the ref is read or write. */
247 enum df_ref_flags flags; /* Various flags. */
248 struct df_link *regs; /* The individual regs that make up
249 this hardreg. */
250 struct df_mw_hardreg *next; /* The next mw_hardreg in this insn. */
254 /* One of these structures is allocated for every insn. */
255 struct df_insn_info
257 struct df_ref *defs; /* Head of insn-def chain. */
258 struct df_ref *uses; /* Head of insn-use chain. */
259 struct df_mw_hardreg *mw_hardregs;
260 /* ???? The following luid field should be considered private so that
261 we can change it on the fly to accommodate new insns? */
262 int luid; /* Logical UID. */
263 bool contains_asm; /* Contains an asm instruction. */
267 /* Two of these structures are allocated for every pseudo reg, one for
268 the uses and one for the defs. */
269 struct df_reg_info
271 struct df_ref *reg_chain; /* Head of reg-use or def chain. */
272 unsigned int begin; /* First def_index for this pseudo. */
273 unsigned int n_refs; /* Number of refs or defs for this pseudo. */
276 /* Define a register reference structure. One of these is allocated
277 for every register reference (use or def). Note some register
278 references (e.g., post_inc, subreg) generate both a def and a use. */
279 struct df_ref
281 rtx reg; /* The register referenced. */
282 unsigned int regno; /* The register number referenced. */
283 basic_block bb; /* Basic block containing the instruction. */
285 /* Insn containing ref. This will be null if this is an artificial
286 reference. */
287 rtx insn;
288 rtx *loc; /* The location of the reg. */
289 struct df_link *chain; /* Head of def-use, use-def. */
290 unsigned int id; /* Location in table. */
291 enum df_ref_type type; /* Type of ref. */
292 enum df_ref_flags flags; /* Various flags. */
294 /* For each regno, there are two chains of refs, one for the uses
295 and one for the defs. These chains go thru the refs themselves
296 rather than using an external structure. */
297 struct df_ref *next_reg; /* Next ref with same regno and type. */
298 struct df_ref *prev_reg; /* Prev ref with same regno and type. */
300 /* Each insn has two lists, one for the uses and one for the
301 defs. This is the next field in either of these chains. */
302 struct df_ref *next_ref;
303 void *data; /* The data assigned to it by user. */
306 /* These links are used for two purposes:
307 1) def-use or use-def chains.
308 2) Multiword hard registers that underly a single hardware register. */
309 struct df_link
311 struct df_ref *ref;
312 struct df_link *next;
315 /* Two of these structures are allocated, one for the uses and one for
316 the defs. */
317 struct df_ref_info
319 struct df_reg_info **regs; /* Array indexed by pseudo regno. */
320 unsigned int regs_size; /* Size of currently allocated regs table. */
321 unsigned int regs_inited; /* Number of regs with reg_infos allocated. */
322 struct df_ref **refs; /* Ref table, indexed by id. */
323 unsigned int refs_size; /* Size of currently allocated refs table. */
324 unsigned int bitmap_size; /* Number of refs seen. */
326 /* True if refs table is organized so that every reference for a
327 pseudo is contiguous. */
328 bool refs_organized;
329 /* True if the next refs should be added immediately or false to
330 defer to later to reorganize the table. */
331 bool add_refs_inline;
335 /*----------------------------------------------------------------------------
336 Problem data for the scanning dataflow problem. Unlike the other
337 dataflow problems, the problem data for scanning is fully exposed and
338 used by owners of the problem.
339 ----------------------------------------------------------------------------*/
341 struct df
344 /* The set of problems to be solved is stored in two arrays. In
345 PROBLEMS_IN_ORDER, the problems are stored in the order that they
346 are solved. This is an internally dense array that may have
347 nulls at the end of it. In PROBLEMS_BY_INDEX, the problem is
348 stored by the value in df_problem.id. These are used to access
349 the problem local data without having to search the first
350 array. */
352 struct dataflow *problems_in_order [DF_LAST_PROBLEM_PLUS1];
353 struct dataflow *problems_by_index [DF_LAST_PROBLEM_PLUS1];
354 int num_problems_defined;
356 /* Set after calls to df_scan_blocks, this contains all of the
357 blocks that higher level problems must rescan before solving the
358 dataflow equations. If this is NULL, the blocks_to_analyze is
359 used. */
360 bitmap blocks_to_scan;
362 /* If not NULL, the subset of blocks of the program to be considered
363 for analysis. */
364 bitmap blocks_to_analyze;
366 /* The following information is really the problem data for the
367 scanning instance but it is used too often by the other problems
368 to keep getting it from there. */
369 struct df_ref_info def_info; /* Def info. */
370 struct df_ref_info use_info; /* Use info. */
371 struct df_insn_info **insns; /* Insn table, indexed by insn UID. */
372 unsigned int insns_size; /* Size of insn table. */
373 bitmap hardware_regs_used; /* The set of hardware registers used. */
374 bitmap entry_block_defs; /* The set of hardware registers live on entry to the function. */
375 bitmap exit_block_uses; /* The set of hardware registers used in exit block. */
378 #define DF_SCAN_BB_INFO(DF, BB) (df_scan_get_bb_info((DF)->problems_by_index[DF_SCAN],(BB)->index))
379 #define DF_RU_BB_INFO(DF, BB) (df_ru_get_bb_info((DF)->problems_by_index[DF_RU],(BB)->index))
380 #define DF_RD_BB_INFO(DF, BB) (df_rd_get_bb_info((DF)->problems_by_index[DF_RD],(BB)->index))
381 #define DF_LR_BB_INFO(DF, BB) (df_lr_get_bb_info((DF)->problems_by_index[DF_LR],(BB)->index))
382 #define DF_UR_BB_INFO(DF, BB) (df_ur_get_bb_info((DF)->problems_by_index[DF_UR],(BB)->index))
383 #define DF_UREC_BB_INFO(DF, BB) (df_urec_get_bb_info((DF)->problems_by_index[DF_UREC],(BB)->index))
385 /* Most transformations that wish to use live register analysis will
386 use these macros. The DF_UPWARD_LIVE* macros are only half of the
387 solution. */
388 #define DF_LIVE_IN(DF, BB) (DF_UR_BB_INFO(DF, BB)->in)
389 #define DF_LIVE_OUT(DF, BB) (DF_UR_BB_INFO(DF, BB)->out)
392 /* Live in for register allocation also takes into account several other factors. */
393 #define DF_RA_LIVE_IN(DF, BB) (DF_UREC_BB_INFO(DF, BB)->in)
394 #define DF_RA_LIVE_OUT(DF, BB) (DF_UREC_BB_INFO(DF, BB)->out)
396 /* These macros are currently used by only reg-stack since it is not
397 tolerant of uninitialized variables. This intolerance should be
398 fixed because it causes other problems. */
399 #define DF_UPWARD_LIVE_IN(DF, BB) (DF_LR_BB_INFO(DF, BB)->in)
400 #define DF_UPWARD_LIVE_OUT(DF, BB) (DF_LR_BB_INFO(DF, BB)->out)
403 /* Macros to access the elements within the ref structure. */
406 #define DF_REF_REAL_REG(REF) (GET_CODE ((REF)->reg) == SUBREG \
407 ? SUBREG_REG ((REF)->reg) : ((REF)->reg))
408 #define DF_REF_REGNO(REF) ((REF)->regno)
409 #define DF_REF_REAL_LOC(REF) (GET_CODE ((REF)->reg) == SUBREG \
410 ? &SUBREG_REG ((REF)->reg) : ((REF)->loc))
411 #define DF_REF_REG(REF) ((REF)->reg)
412 #define DF_REF_LOC(REF) ((REF)->loc)
413 #define DF_REF_BB(REF) ((REF)->bb)
414 #define DF_REF_BBNO(REF) (DF_REF_BB (REF)->index)
415 #define DF_REF_INSN(REF) ((REF)->insn)
416 #define DF_REF_INSN_UID(REF) (INSN_UID ((REF)->insn))
417 #define DF_REF_TYPE(REF) ((REF)->type)
418 #define DF_REF_CHAIN(REF) ((REF)->chain)
419 #define DF_REF_ID(REF) ((REF)->id)
420 #define DF_REF_FLAGS(REF) ((REF)->flags)
421 #define DF_REF_NEXT_REG(REF) ((REF)->next_reg)
422 #define DF_REF_PREV_REG(REF) ((REF)->prev_reg)
423 #define DF_REF_NEXT_REF(REF) ((REF)->next_ref)
424 #define DF_REF_DATA(REF) ((REF)->data)
426 /* Macros to determine the reference type. */
428 #define DF_REF_REG_DEF_P(REF) (DF_REF_TYPE (REF) == DF_REF_REG_DEF)
429 #define DF_REF_REG_USE_P(REF) ((REF) && !DF_REF_REG_DEF_P (REF))
430 #define DF_REF_REG_MEM_STORE_P(REF) (DF_REF_TYPE (REF) == DF_REF_REG_MEM_STORE)
431 #define DF_REF_REG_MEM_LOAD_P(REF) (DF_REF_TYPE (REF) == DF_REF_REG_MEM_LOAD)
432 #define DF_REF_REG_MEM_P(REF) (DF_REF_REG_MEM_STORE_P (REF) \
433 || DF_REF_REG_MEM_LOAD_P (REF))
435 /* Macros to get the refs out of def_info or use_info refs table. */
436 #define DF_DEFS_SIZE(DF) ((DF)->def_info.bitmap_size)
437 #define DF_DEFS_GET(DF,ID) ((DF)->def_info.refs[(ID)])
438 #define DF_DEFS_SET(DF,ID,VAL) ((DF)->def_info.refs[(ID)]=(VAL))
439 #define DF_USES_SIZE(DF) ((DF)->use_info.bitmap_size)
440 #define DF_USES_GET(DF,ID) ((DF)->use_info.refs[(ID)])
441 #define DF_USES_SET(DF,ID,VAL) ((DF)->use_info.refs[(ID)]=(VAL))
443 /* Macros to access the register information from scan dataflow record. */
445 #define DF_REG_SIZE(DF) ((DF)->def_info.regs_inited)
446 #define DF_REG_DEF_GET(DF, REG) ((DF)->def_info.regs[(REG)])
447 #define DF_REG_DEF_SET(DF, REG, VAL) ((DF)->def_info.regs[(REG)]=(VAL))
448 #define DF_REG_DEF_COUNT(DF, REG) ((DF)->def_info.regs[(REG)]->n_refs)
449 #define DF_REG_USE_GET(DF, REG) ((DF)->use_info.regs[(REG)])
450 #define DF_REG_USE_SET(DF, REG, VAL) ((DF)->use_info.regs[(REG)]=(VAL))
451 #define DF_REG_USE_COUNT(DF, REG) ((DF)->use_info.regs[(REG)]->n_refs)
453 /* Macros to access the elements within the reg_info structure table. */
455 #define DF_REGNO_FIRST_DEF(DF, REGNUM) \
456 (DF_REG_DEF_GET(DF, REGNUM) ? DF_REG_DEF_GET(DF, REGNUM) : 0)
457 #define DF_REGNO_LAST_USE(DF, REGNUM) \
458 (DF_REG_USE_GET(DF, REGNUM) ? DF_REG_USE_GET(DF, REGNUM) : 0)
460 /* Macros to access the elements within the insn_info structure table. */
462 #define DF_INSN_SIZE(DF) ((DF)->insns_size)
463 #define DF_INSN_GET(DF,INSN) ((DF)->insns[(INSN_UID(INSN))])
464 #define DF_INSN_SET(DF,INSN,VAL) ((DF)->insns[(INSN_UID (INSN))]=(VAL))
465 #define DF_INSN_CONTAINS_ASM(DF, INSN) (DF_INSN_GET(DF,INSN)->contains_asm)
466 #define DF_INSN_LUID(DF, INSN) (DF_INSN_GET(DF,INSN)->luid)
467 #define DF_INSN_DEFS(DF, INSN) (DF_INSN_GET(DF,INSN)->defs)
468 #define DF_INSN_USES(DF, INSN) (DF_INSN_GET(DF,INSN)->uses)
470 #define DF_INSN_UID_GET(DF,UID) ((DF)->insns[(UID)])
471 #define DF_INSN_UID_LUID(DF, INSN) (DF_INSN_UID_GET(DF,INSN)->luid)
472 #define DF_INSN_UID_DEFS(DF, INSN) (DF_INSN_UID_GET(DF,INSN)->defs)
473 #define DF_INSN_UID_USES(DF, INSN) (DF_INSN_UID_GET(DF,INSN)->uses)
474 #define DF_INSN_UID_MWS(DF, INSN) (DF_INSN_UID_GET(DF,INSN)->mw_hardregs)
476 /* This is a bitmap copy of regs_invalidated_by_call so that we can
477 easily add it into bitmaps, etc. */
479 extern bitmap df_invalidated_by_call;
482 /* One of these structures is allocated for every basic block. */
483 struct df_scan_bb_info
485 /* Defs at the start of a basic block that is the target of an
486 exception edge. */
487 struct df_ref *artificial_defs;
489 /* Uses of hard registers that are live at every block. */
490 struct df_ref *artificial_uses;
494 /* Reaching uses. All bitmaps are indexed by the id field of the ref
495 except sparse_kill (see below). */
496 struct df_ru_bb_info
498 /* Local sets to describe the basic blocks. */
499 /* The kill set is the set of uses that are killed in this block.
500 However, if the number of uses for this register is greater than
501 DF_SPARSE_THRESHOLD, the sparse_kill is used instead. In
502 sparse_kill, each register gets a slot and a 1 in this bitvector
503 means that all of the uses of that register are killed. This is
504 a very useful efficiency hack in that it keeps from having push
505 around big groups of 1s. This is implemented by the
506 bitmap_clear_range call. */
508 bitmap kill;
509 bitmap sparse_kill;
510 bitmap gen; /* The set of uses generated in this block. */
512 /* The results of the dataflow problem. */
513 bitmap in; /* At the top of the block. */
514 bitmap out; /* At the bottom of the block. */
518 /* Reaching definitions. All bitmaps are indexed by the id field of
519 the ref except sparse_kill (see above). */
520 struct df_rd_bb_info
522 /* Local sets to describe the basic blocks. See the note in the RU
523 datastructures for kill and sparse_kill. */
524 bitmap kill;
525 bitmap sparse_kill;
526 bitmap gen; /* The set of defs generated in this block. */
528 /* The results of the dataflow problem. */
529 bitmap in; /* At the top of the block. */
530 bitmap out; /* At the bottom of the block. */
534 /* Live registers. All bitmaps are referenced by the register number. */
535 struct df_lr_bb_info
537 /* Local sets to describe the basic blocks. */
538 bitmap def; /* The set of registers set in this block. */
539 bitmap use; /* The set of registers used in this block. */
541 /* The results of the dataflow problem. */
542 bitmap in; /* At the top of the block. */
543 bitmap out; /* At the bottom of the block. */
547 /* Uninitialized registers. All bitmaps are referenced by the register number. */
548 struct df_ur_bb_info
550 /* Local sets to describe the basic blocks. */
551 bitmap kill; /* The set of registers unset in this block. Calls,
552 for instance, unset registers. */
553 bitmap gen; /* The set of registers set in this block. */
555 /* The results of the dataflow problem. */
556 bitmap in; /* At the top of the block. */
557 bitmap out; /* At the bottom of the block. */
560 /* Uninitialized registers. All bitmaps are referenced by the register number. */
561 struct df_urec_bb_info
563 /* Local sets to describe the basic blocks. */
564 bitmap earlyclobber; /* The set of registers that are referenced
565 with an an early clobber mode. */
566 /* Kill and gen are defined as in the UR problem. */
567 bitmap kill;
568 bitmap gen;
570 /* The results of the dataflow problem. */
571 bitmap in; /* At the top of the block. */
572 bitmap out; /* At the bottom of the block. */
576 #define df_finish(df) {df_finish1(df); df=NULL;}
578 /* Functions defined in df-core.c. */
580 extern struct df *df_init (int);
581 extern struct dataflow *df_add_problem (struct df *, struct df_problem *, int);
582 extern int df_set_flags (struct dataflow *, int);
583 extern int df_clear_flags (struct dataflow *, int);
584 extern void df_set_blocks (struct df*, bitmap);
585 extern void df_delete_basic_block (struct df *, int);
586 extern void df_finish1 (struct df *);
587 extern void df_analyze_problem (struct dataflow *, bitmap, bitmap, bitmap, int *, int, bool);
588 extern void df_analyze (struct df *);
589 extern void df_compact_blocks (struct df *);
590 extern void df_bb_replace (struct df *, int, basic_block);
591 extern struct df_ref *df_bb_regno_last_use_find (struct df *, basic_block, unsigned int);
592 extern struct df_ref *df_bb_regno_first_def_find (struct df *, basic_block, unsigned int);
593 extern struct df_ref *df_bb_regno_last_def_find (struct df *, basic_block, unsigned int);
594 extern bool df_insn_regno_def_p (struct df *, rtx, unsigned int);
595 extern struct df_ref *df_find_def (struct df *, rtx, rtx);
596 extern bool df_reg_defined (struct df *, rtx, rtx);
597 extern struct df_ref *df_find_use (struct df *, rtx, rtx);
598 extern bool df_reg_used (struct df *, rtx, rtx);
599 extern void df_iterative_dataflow (struct dataflow *, bitmap, bitmap, int *, int, bool);
600 extern void df_dump (struct df *, FILE *);
601 extern void df_refs_chain_dump (struct df_ref *, bool, FILE *);
602 extern void df_regs_chain_dump (struct df *, struct df_ref *, FILE *);
603 extern void df_insn_debug (struct df *, rtx, bool, FILE *);
604 extern void df_insn_debug_regno (struct df *, rtx, FILE *);
605 extern void df_regno_debug (struct df *, unsigned int, FILE *);
606 extern void df_ref_debug (struct df_ref *, FILE *);
607 extern void debug_df_insn (rtx);
608 extern void debug_df_regno (unsigned int);
609 extern void debug_df_reg (rtx);
610 extern void debug_df_defno (unsigned int);
611 extern void debug_df_useno (unsigned int);
612 extern void debug_df_ref (struct df_ref *);
613 extern void debug_df_chain (struct df_link *);
614 /* An instance of df that can be shared between passes. */
615 extern struct df *shared_df;
618 /* Functions defined in df-problems.c. */
620 extern struct df_link *df_chain_create (struct dataflow *, struct df_ref *, struct df_ref *);
621 extern void df_chain_unlink (struct dataflow *, struct df_ref *, struct df_link *);
622 extern void df_chain_copy (struct dataflow *, struct df_ref *, struct df_link *);
623 extern bitmap df_get_live_in (struct df *, basic_block);
624 extern bitmap df_get_live_out (struct df *, basic_block);
625 extern void df_grow_bb_info (struct dataflow *);
626 extern void df_chain_dump (struct df_link *, FILE *);
627 extern void df_print_bb_index (basic_block bb, FILE *file);
628 extern struct dataflow *df_ru_add_problem (struct df *, int);
629 extern struct df_ru_bb_info *df_ru_get_bb_info (struct dataflow *, unsigned int);
630 extern struct dataflow *df_rd_add_problem (struct df *, int);
631 extern struct df_rd_bb_info *df_rd_get_bb_info (struct dataflow *, unsigned int);
632 extern struct dataflow *df_lr_add_problem (struct df *, int);
633 extern struct df_lr_bb_info *df_lr_get_bb_info (struct dataflow *, unsigned int);
634 extern struct dataflow *df_ur_add_problem (struct df *, int);
635 extern struct df_ur_bb_info *df_ur_get_bb_info (struct dataflow *, unsigned int);
636 extern struct dataflow *df_urec_add_problem (struct df *, int);
637 extern struct df_urec_bb_info *df_urec_get_bb_info (struct dataflow *, unsigned int);
638 extern struct dataflow *df_chain_add_problem (struct df *, int);
639 extern struct dataflow *df_ri_add_problem (struct df *, int);
642 /* Functions defined in df-scan.c. */
644 extern struct df_scan_bb_info *df_scan_get_bb_info (struct dataflow *, unsigned int);
645 extern struct dataflow *df_scan_add_problem (struct df *, int);
646 extern void df_rescan_blocks (struct df *, bitmap);
647 extern struct df_ref *df_ref_create (struct df *, rtx, rtx *, rtx,basic_block,enum df_ref_type, enum df_ref_flags);
648 extern struct df_ref *df_get_artificial_defs (struct df *, unsigned int);
649 extern struct df_ref *df_get_artificial_uses (struct df *, unsigned int);
650 extern void df_reg_chain_create (struct df_reg_info *, struct df_ref *);
651 extern struct df_ref *df_reg_chain_unlink (struct dataflow *, struct df_ref *);
652 extern void df_ref_remove (struct df *, struct df_ref *);
653 extern void df_insn_refs_delete (struct dataflow *, rtx);
654 extern void df_bb_refs_delete (struct dataflow *, int);
655 extern void df_refs_delete (struct dataflow *, bitmap);
656 extern void df_reorganize_refs (struct df_ref_info *);
657 extern void df_hard_reg_init (void);
658 extern bool df_read_modify_subreg_p (rtx);
661 /* web */
663 /* This entry is allocated for each reference in the insn stream. */
664 struct web_entry
666 /* Pointer to the parent in the union/find tree. */
667 struct web_entry *pred;
668 /* Newly assigned register to the entry. Set only for roots. */
669 rtx reg;
670 void* extra_info;
673 extern struct web_entry *unionfind_root (struct web_entry *);
674 extern bool unionfind_union (struct web_entry *, struct web_entry *);
675 extern void union_defs (struct df *, struct df_ref *,
676 struct web_entry *, struct web_entry *,
677 bool (*fun) (struct web_entry *, struct web_entry *));
680 #endif /* GCC_DF_H */