Relocation (= move+destroy)
[official-gcc.git] / gcc / cfgloop.h
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1 /* Natural loop functions
2 Copyright (C) 1987-2018 Free Software Foundation, Inc.
4 This file is part of GCC.
6 GCC is free software; you can redistribute it and/or modify it under
7 the terms of the GNU General Public License as published by the Free
8 Software Foundation; either version 3, or (at your option) any later
9 version.
11 GCC is distributed in the hope that it will be useful, but WITHOUT ANY
12 WARRANTY; without even the implied warranty of MERCHANTABILITY or
13 FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
14 for more details.
16 You should have received a copy of the GNU General Public License
17 along with GCC; see the file COPYING3. If not see
18 <http://www.gnu.org/licenses/>. */
20 #ifndef GCC_CFGLOOP_H
21 #define GCC_CFGLOOP_H
23 #include "cfgloopmanip.h"
25 /* Structure to hold decision about unrolling/peeling. */
26 enum lpt_dec
28 LPT_NONE,
29 LPT_UNROLL_CONSTANT,
30 LPT_UNROLL_RUNTIME,
31 LPT_UNROLL_STUPID
34 struct GTY (()) lpt_decision {
35 enum lpt_dec decision;
36 unsigned times;
39 /* The type of extend applied to an IV. */
40 enum iv_extend_code
42 IV_SIGN_EXTEND,
43 IV_ZERO_EXTEND,
44 IV_UNKNOWN_EXTEND
47 /* The structure describing a bound on number of iterations of a loop. */
49 struct GTY ((chain_next ("%h.next"))) nb_iter_bound {
50 /* The statement STMT is executed at most ... */
51 gimple *stmt;
53 /* ... BOUND + 1 times (BOUND must be an unsigned constant).
54 The + 1 is added for the following reasons:
56 a) 0 would otherwise be unused, while we would need to care more about
57 overflows (as MAX + 1 is sometimes produced as the estimate on number
58 of executions of STMT).
59 b) it is consistent with the result of number_of_iterations_exit. */
60 widest_int bound;
62 /* True if the statement will cause the loop to be leaved the (at most)
63 BOUND + 1-st time it is executed, that is, all the statements after it
64 are executed at most BOUND times. */
65 bool is_exit;
67 /* The next bound in the list. */
68 struct nb_iter_bound *next;
71 /* Description of the loop exit. */
73 struct GTY ((for_user)) loop_exit {
74 /* The exit edge. */
75 edge e;
77 /* Previous and next exit in the list of the exits of the loop. */
78 struct loop_exit *prev;
79 struct loop_exit *next;
81 /* Next element in the list of loops from that E exits. */
82 struct loop_exit *next_e;
85 struct loop_exit_hasher : ggc_ptr_hash<loop_exit>
87 typedef edge compare_type;
89 static hashval_t hash (loop_exit *);
90 static bool equal (loop_exit *, edge);
91 static void remove (loop_exit *);
94 typedef struct loop *loop_p;
96 /* An integer estimation of the number of iterations. Estimate_state
97 describes what is the state of the estimation. */
98 enum loop_estimation
100 /* Estimate was not computed yet. */
101 EST_NOT_COMPUTED,
102 /* Estimate is ready. */
103 EST_AVAILABLE,
104 EST_LAST
107 /* The structure describing non-overflow control induction variable for
108 loop's exit edge. */
109 struct GTY ((chain_next ("%h.next"))) control_iv {
110 tree base;
111 tree step;
112 struct control_iv *next;
115 /* Structure to hold information for each natural loop. */
116 struct GTY ((chain_next ("%h.next"))) loop {
117 /* Index into loops array. Note indices will never be reused after loop
118 is destroyed. */
119 int num;
121 /* Number of loop insns. */
122 unsigned ninsns;
124 /* Basic block of loop header. */
125 basic_block header;
127 /* Basic block of loop latch. */
128 basic_block latch;
130 /* For loop unrolling/peeling decision. */
131 struct lpt_decision lpt_decision;
133 /* Average number of executed insns per iteration. */
134 unsigned av_ninsns;
136 /* Number of blocks contained within the loop. */
137 unsigned num_nodes;
139 /* Superloops of the loop, starting with the outermost loop. */
140 vec<loop_p, va_gc> *superloops;
142 /* The first inner (child) loop or NULL if innermost loop. */
143 struct loop *inner;
145 /* Link to the next (sibling) loop. */
146 struct loop *next;
148 /* Auxiliary info specific to a pass. */
149 PTR GTY ((skip (""))) aux;
151 /* The number of times the latch of the loop is executed. This can be an
152 INTEGER_CST, or a symbolic expression representing the number of
153 iterations like "N - 1", or a COND_EXPR containing the runtime
154 conditions under which the number of iterations is non zero.
156 Don't access this field directly: number_of_latch_executions
157 computes and caches the computed information in this field. */
158 tree nb_iterations;
160 /* An integer guaranteed to be greater or equal to nb_iterations. Only
161 valid if any_upper_bound is true. */
162 widest_int nb_iterations_upper_bound;
164 widest_int nb_iterations_likely_upper_bound;
166 /* An integer giving an estimate on nb_iterations. Unlike
167 nb_iterations_upper_bound, there is no guarantee that it is at least
168 nb_iterations. */
169 widest_int nb_iterations_estimate;
171 /* If > 0, an integer, where the user asserted that for any
172 I in [ 0, nb_iterations ) and for any J in
173 [ I, min ( I + safelen, nb_iterations ) ), the Ith and Jth iterations
174 of the loop can be safely evaluated concurrently. */
175 int safelen;
177 /* Constraints are generally set by consumers and affect certain
178 semantics of niter analyzer APIs. Currently the APIs affected are
179 number_of_iterations_exit* functions and their callers. One typical
180 use case of constraints is to vectorize possibly infinite loop:
182 1) Compute niter->assumptions by calling niter analyzer API and
183 record it as possible condition for loop versioning.
184 2) Clear buffered result of niter/scev analyzer.
185 3) Set constraint LOOP_C_FINITE assuming the loop is finite.
186 4) Analyze data references. Since data reference analysis depends
187 on niter/scev analyzer, the point is that niter/scev analysis
188 is done under circumstance of LOOP_C_FINITE constraint.
189 5) Version the loop with niter->assumptions computed in step 1).
190 6) Vectorize the versioned loop in which niter->assumptions is
191 checked to be true.
192 7) Update constraints in versioned loops so that niter analyzer
193 in following passes can use it.
195 Note consumers are usually the loop optimizers and it is consumers'
196 responsibility to set/clear constraints correctly. Failing to do
197 that might result in hard to track down bugs in niter/scev consumers. */
198 unsigned constraints;
200 /* An integer estimation of the number of iterations. Estimate_state
201 describes what is the state of the estimation. */
202 ENUM_BITFIELD(loop_estimation) estimate_state : 8;
204 unsigned any_upper_bound : 1;
205 unsigned any_estimate : 1;
206 unsigned any_likely_upper_bound : 1;
208 /* True if the loop can be parallel. */
209 unsigned can_be_parallel : 1;
211 /* True if -Waggressive-loop-optimizations warned about this loop
212 already. */
213 unsigned warned_aggressive_loop_optimizations : 1;
215 /* True if this loop should never be vectorized. */
216 unsigned dont_vectorize : 1;
218 /* True if we should try harder to vectorize this loop. */
219 unsigned force_vectorize : 1;
221 /* True if the loop is part of an oacc kernels region. */
222 unsigned in_oacc_kernels_region : 1;
224 /* The number of times to unroll the loop. 0 means no information given,
225 just do what we always do. A value of 1 means do not unroll the loop.
226 A value of USHRT_MAX means unroll with no specific unrolling factor.
227 Other values means unroll with the given unrolling factor. */
228 unsigned short unroll;
230 /* For SIMD loops, this is a unique identifier of the loop, referenced
231 by IFN_GOMP_SIMD_VF, IFN_GOMP_SIMD_LANE and IFN_GOMP_SIMD_LAST_LANE
232 builtins. */
233 tree simduid;
235 /* In loop optimization, it's common to generate loops from the original
236 loop. This field records the index of the original loop which can be
237 used to track the original loop from newly generated loops. This can
238 be done by calling function get_loop (cfun, orig_loop_num). Note the
239 original loop could be destroyed for various reasons thus no longer
240 exists, as a result, function call to get_loop returns NULL pointer.
241 In this case, this field should not be used and needs to be cleared
242 whenever possible. */
243 int orig_loop_num;
245 /* Upper bound on number of iterations of a loop. */
246 struct nb_iter_bound *bounds;
248 /* Non-overflow control ivs of a loop. */
249 struct control_iv *control_ivs;
251 /* Head of the cyclic list of the exits of the loop. */
252 struct loop_exit *exits;
254 /* Number of iteration analysis data for RTL. */
255 struct niter_desc *simple_loop_desc;
257 /* For sanity checking during loop fixup we record here the former
258 loop header for loops marked for removal. Note that this prevents
259 the basic-block from being collected but its index can still be
260 reused. */
261 basic_block former_header;
264 /* Set if the loop is known to be infinite. */
265 #define LOOP_C_INFINITE (1 << 0)
266 /* Set if the loop is known to be finite without any assumptions. */
267 #define LOOP_C_FINITE (1 << 1)
269 /* Set C to the LOOP constraint. */
270 static inline void
271 loop_constraint_set (struct loop *loop, unsigned c)
273 loop->constraints |= c;
276 /* Clear C from the LOOP constraint. */
277 static inline void
278 loop_constraint_clear (struct loop *loop, unsigned c)
280 loop->constraints &= ~c;
283 /* Check if C is set in the LOOP constraint. */
284 static inline bool
285 loop_constraint_set_p (struct loop *loop, unsigned c)
287 return (loop->constraints & c) == c;
290 /* Flags for state of loop structure. */
291 enum
293 LOOPS_HAVE_PREHEADERS = 1,
294 LOOPS_HAVE_SIMPLE_LATCHES = 2,
295 LOOPS_HAVE_MARKED_IRREDUCIBLE_REGIONS = 4,
296 LOOPS_HAVE_RECORDED_EXITS = 8,
297 LOOPS_MAY_HAVE_MULTIPLE_LATCHES = 16,
298 LOOP_CLOSED_SSA = 32,
299 LOOPS_NEED_FIXUP = 64,
300 LOOPS_HAVE_FALLTHRU_PREHEADERS = 128
303 #define LOOPS_NORMAL (LOOPS_HAVE_PREHEADERS | LOOPS_HAVE_SIMPLE_LATCHES \
304 | LOOPS_HAVE_MARKED_IRREDUCIBLE_REGIONS)
305 #define AVOID_CFG_MODIFICATIONS (LOOPS_MAY_HAVE_MULTIPLE_LATCHES)
307 /* Structure to hold CFG information about natural loops within a function. */
308 struct GTY (()) loops {
309 /* State of loops. */
310 int state;
312 /* Array of the loops. */
313 vec<loop_p, va_gc> *larray;
315 /* Maps edges to the list of their descriptions as loop exits. Edges
316 whose sources or destinations have loop_father == NULL (which may
317 happen during the cfg manipulations) should not appear in EXITS. */
318 hash_table<loop_exit_hasher> *GTY(()) exits;
320 /* Pointer to root of loop hierarchy tree. */
321 struct loop *tree_root;
324 /* Loop recognition. */
325 bool bb_loop_header_p (basic_block);
326 void init_loops_structure (struct function *, struct loops *, unsigned);
327 extern struct loops *flow_loops_find (struct loops *);
328 extern void disambiguate_loops_with_multiple_latches (void);
329 extern void flow_loops_free (struct loops *);
330 extern void flow_loops_dump (FILE *,
331 void (*)(const struct loop *, FILE *, int), int);
332 extern void flow_loop_dump (const struct loop *, FILE *,
333 void (*)(const struct loop *, FILE *, int), int);
334 struct loop *alloc_loop (void);
335 extern void flow_loop_free (struct loop *);
336 int flow_loop_nodes_find (basic_block, struct loop *);
337 unsigned fix_loop_structure (bitmap changed_bbs);
338 bool mark_irreducible_loops (void);
339 void release_recorded_exits (function *);
340 void record_loop_exits (void);
341 void rescan_loop_exit (edge, bool, bool);
342 void sort_sibling_loops (function *);
344 /* Loop data structure manipulation/querying. */
345 extern void flow_loop_tree_node_add (struct loop *, struct loop *,
346 struct loop * = NULL);
347 extern void flow_loop_tree_node_remove (struct loop *);
348 extern bool flow_loop_nested_p (const struct loop *, const struct loop *);
349 extern bool flow_bb_inside_loop_p (const struct loop *, const_basic_block);
350 extern struct loop * find_common_loop (struct loop *, struct loop *);
351 struct loop *superloop_at_depth (struct loop *, unsigned);
352 struct eni_weights;
353 extern int num_loop_insns (const struct loop *);
354 extern int average_num_loop_insns (const struct loop *);
355 extern unsigned get_loop_level (const struct loop *);
356 extern bool loop_exit_edge_p (const struct loop *, const_edge);
357 extern bool loop_exits_to_bb_p (struct loop *, basic_block);
358 extern bool loop_exits_from_bb_p (struct loop *, basic_block);
359 extern void mark_loop_exit_edges (void);
360 extern dump_user_location_t get_loop_location (struct loop *loop);
362 /* Loops & cfg manipulation. */
363 extern basic_block *get_loop_body (const struct loop *);
364 extern unsigned get_loop_body_with_size (const struct loop *, basic_block *,
365 unsigned);
366 extern basic_block *get_loop_body_in_dom_order (const struct loop *);
367 extern basic_block *get_loop_body_in_bfs_order (const struct loop *);
368 extern basic_block *get_loop_body_in_custom_order (const struct loop *,
369 int (*) (const void *, const void *));
371 extern vec<edge> get_loop_exit_edges (const struct loop *);
372 extern edge single_exit (const struct loop *);
373 extern edge single_likely_exit (struct loop *loop);
374 extern unsigned num_loop_branches (const struct loop *);
376 extern edge loop_preheader_edge (const struct loop *);
377 extern edge loop_latch_edge (const struct loop *);
379 extern void add_bb_to_loop (basic_block, struct loop *);
380 extern void remove_bb_from_loops (basic_block);
382 extern void cancel_loop_tree (struct loop *);
383 extern void delete_loop (struct loop *);
386 extern void verify_loop_structure (void);
388 /* Loop analysis. */
389 extern bool just_once_each_iteration_p (const struct loop *, const_basic_block);
390 gcov_type expected_loop_iterations_unbounded (const struct loop *,
391 bool *read_profile_p = NULL, bool by_profile_only = false);
392 extern unsigned expected_loop_iterations (struct loop *);
393 extern rtx doloop_condition_get (rtx_insn *);
395 void mark_loop_for_removal (loop_p);
397 /* Induction variable analysis. */
399 /* The description of induction variable. The things are a bit complicated
400 due to need to handle subregs and extends. The value of the object described
401 by it can be obtained as follows (all computations are done in extend_mode):
403 Value in i-th iteration is
404 delta + mult * extend_{extend_mode} (subreg_{mode} (base + i * step)).
406 If first_special is true, the value in the first iteration is
407 delta + mult * base
409 If extend = UNKNOWN, first_special must be false, delta 0, mult 1 and value is
410 subreg_{mode} (base + i * step)
412 The get_iv_value function can be used to obtain these expressions.
414 ??? Add a third mode field that would specify the mode in that inner
415 computation is done, which would enable it to be different from the
416 outer one? */
418 struct rtx_iv
420 /* Its base and step (mode of base and step is supposed to be extend_mode,
421 see the description above). */
422 rtx base, step;
424 /* The type of extend applied to it (IV_SIGN_EXTEND, IV_ZERO_EXTEND,
425 or IV_UNKNOWN_EXTEND). */
426 enum iv_extend_code extend;
428 /* Operations applied in the extended mode. */
429 rtx delta, mult;
431 /* The mode it is extended to. */
432 scalar_int_mode extend_mode;
434 /* The mode the variable iterates in. */
435 scalar_int_mode mode;
437 /* Whether the first iteration needs to be handled specially. */
438 unsigned first_special : 1;
441 /* The description of an exit from the loop and of the number of iterations
442 till we take the exit. */
444 struct GTY(()) niter_desc
446 /* The edge out of the loop. */
447 edge out_edge;
449 /* The other edge leading from the condition. */
450 edge in_edge;
452 /* True if we are able to say anything about number of iterations of the
453 loop. */
454 bool simple_p;
456 /* True if the loop iterates the constant number of times. */
457 bool const_iter;
459 /* Number of iterations if constant. */
460 uint64_t niter;
462 /* Assumptions under that the rest of the information is valid. */
463 rtx assumptions;
465 /* Assumptions under that the loop ends before reaching the latch,
466 even if value of niter_expr says otherwise. */
467 rtx noloop_assumptions;
469 /* Condition under that the loop is infinite. */
470 rtx infinite;
472 /* Whether the comparison is signed. */
473 bool signed_p;
475 /* The mode in that niter_expr should be computed. */
476 scalar_int_mode mode;
478 /* The number of iterations of the loop. */
479 rtx niter_expr;
482 extern void iv_analysis_loop_init (struct loop *);
483 extern bool iv_analyze (rtx_insn *, scalar_int_mode, rtx, struct rtx_iv *);
484 extern bool iv_analyze_result (rtx_insn *, rtx, struct rtx_iv *);
485 extern bool iv_analyze_expr (rtx_insn *, scalar_int_mode, rtx,
486 struct rtx_iv *);
487 extern rtx get_iv_value (struct rtx_iv *, rtx);
488 extern bool biv_p (rtx_insn *, scalar_int_mode, rtx);
489 extern void find_simple_exit (struct loop *, struct niter_desc *);
490 extern void iv_analysis_done (void);
492 extern struct niter_desc *get_simple_loop_desc (struct loop *loop);
493 extern void free_simple_loop_desc (struct loop *loop);
495 static inline struct niter_desc *
496 simple_loop_desc (struct loop *loop)
498 return loop->simple_loop_desc;
501 /* Accessors for the loop structures. */
503 /* Returns the loop with index NUM from FNs loop tree. */
505 static inline struct loop *
506 get_loop (struct function *fn, unsigned num)
508 return (*loops_for_fn (fn)->larray)[num];
511 /* Returns the number of superloops of LOOP. */
513 static inline unsigned
514 loop_depth (const struct loop *loop)
516 return vec_safe_length (loop->superloops);
519 /* Returns the immediate superloop of LOOP, or NULL if LOOP is the outermost
520 loop. */
522 static inline struct loop *
523 loop_outer (const struct loop *loop)
525 unsigned n = vec_safe_length (loop->superloops);
527 if (n == 0)
528 return NULL;
530 return (*loop->superloops)[n - 1];
533 /* Returns true if LOOP has at least one exit edge. */
535 static inline bool
536 loop_has_exit_edges (const struct loop *loop)
538 return loop->exits->next->e != NULL;
541 /* Returns the list of loops in FN. */
543 inline vec<loop_p, va_gc> *
544 get_loops (struct function *fn)
546 struct loops *loops = loops_for_fn (fn);
547 if (!loops)
548 return NULL;
550 return loops->larray;
553 /* Returns the number of loops in FN (including the removed
554 ones and the fake loop that forms the root of the loop tree). */
556 static inline unsigned
557 number_of_loops (struct function *fn)
559 struct loops *loops = loops_for_fn (fn);
560 if (!loops)
561 return 0;
563 return vec_safe_length (loops->larray);
566 /* Returns true if state of the loops satisfies all properties
567 described by FLAGS. */
569 static inline bool
570 loops_state_satisfies_p (function *fn, unsigned flags)
572 return (loops_for_fn (fn)->state & flags) == flags;
575 static inline bool
576 loops_state_satisfies_p (unsigned flags)
578 return loops_state_satisfies_p (cfun, flags);
581 /* Sets FLAGS to the loops state. */
583 static inline void
584 loops_state_set (function *fn, unsigned flags)
586 loops_for_fn (fn)->state |= flags;
589 static inline void
590 loops_state_set (unsigned flags)
592 loops_state_set (cfun, flags);
595 /* Clears FLAGS from the loops state. */
597 static inline void
598 loops_state_clear (function *fn, unsigned flags)
600 loops_for_fn (fn)->state &= ~flags;
603 static inline void
604 loops_state_clear (unsigned flags)
606 if (!current_loops)
607 return;
608 loops_state_clear (cfun, flags);
611 /* Check loop structure invariants, if internal consistency checks are
612 enabled. */
614 static inline void
615 checking_verify_loop_structure (void)
617 /* VERIFY_LOOP_STRUCTURE essentially asserts that no loops need fixups.
619 The loop optimizers should never make changes to the CFG which
620 require loop fixups. But the low level CFG manipulation code may
621 set the flag conservatively.
623 Go ahead and clear the flag here. That avoids the assert inside
624 VERIFY_LOOP_STRUCTURE, and if there is an inconsistency in the loop
625 structures VERIFY_LOOP_STRUCTURE will detect it.
627 This also avoid the compile time cost of excessive fixups. */
628 loops_state_clear (LOOPS_NEED_FIXUP);
629 if (flag_checking)
630 verify_loop_structure ();
633 /* Loop iterators. */
635 /* Flags for loop iteration. */
637 enum li_flags
639 LI_INCLUDE_ROOT = 1, /* Include the fake root of the loop tree. */
640 LI_FROM_INNERMOST = 2, /* Iterate over the loops in the reverse order,
641 starting from innermost ones. */
642 LI_ONLY_INNERMOST = 4 /* Iterate only over innermost loops. */
645 /* The iterator for loops. */
647 struct loop_iterator
649 loop_iterator (function *fn, loop_p *loop, unsigned flags);
650 ~loop_iterator ();
652 inline loop_p next ();
654 /* The function we are visiting. */
655 function *fn;
657 /* The list of loops to visit. */
658 vec<int> to_visit;
660 /* The index of the actual loop. */
661 unsigned idx;
664 inline loop_p
665 loop_iterator::next ()
667 int anum;
669 while (this->to_visit.iterate (this->idx, &anum))
671 this->idx++;
672 loop_p loop = get_loop (fn, anum);
673 if (loop)
674 return loop;
677 return NULL;
680 inline
681 loop_iterator::loop_iterator (function *fn, loop_p *loop, unsigned flags)
683 struct loop *aloop;
684 unsigned i;
685 int mn;
687 this->idx = 0;
688 this->fn = fn;
689 if (!loops_for_fn (fn))
691 this->to_visit.create (0);
692 *loop = NULL;
693 return;
696 this->to_visit.create (number_of_loops (fn));
697 mn = (flags & LI_INCLUDE_ROOT) ? 0 : 1;
699 if (flags & LI_ONLY_INNERMOST)
701 for (i = 0; vec_safe_iterate (loops_for_fn (fn)->larray, i, &aloop); i++)
702 if (aloop != NULL
703 && aloop->inner == NULL
704 && aloop->num >= mn)
705 this->to_visit.quick_push (aloop->num);
707 else if (flags & LI_FROM_INNERMOST)
709 /* Push the loops to LI->TO_VISIT in postorder. */
710 for (aloop = loops_for_fn (fn)->tree_root;
711 aloop->inner != NULL;
712 aloop = aloop->inner)
713 continue;
715 while (1)
717 if (aloop->num >= mn)
718 this->to_visit.quick_push (aloop->num);
720 if (aloop->next)
722 for (aloop = aloop->next;
723 aloop->inner != NULL;
724 aloop = aloop->inner)
725 continue;
727 else if (!loop_outer (aloop))
728 break;
729 else
730 aloop = loop_outer (aloop);
733 else
735 /* Push the loops to LI->TO_VISIT in preorder. */
736 aloop = loops_for_fn (fn)->tree_root;
737 while (1)
739 if (aloop->num >= mn)
740 this->to_visit.quick_push (aloop->num);
742 if (aloop->inner != NULL)
743 aloop = aloop->inner;
744 else
746 while (aloop != NULL && aloop->next == NULL)
747 aloop = loop_outer (aloop);
748 if (aloop == NULL)
749 break;
750 aloop = aloop->next;
755 *loop = this->next ();
758 inline
759 loop_iterator::~loop_iterator ()
761 this->to_visit.release ();
764 #define FOR_EACH_LOOP(LOOP, FLAGS) \
765 for (loop_iterator li(cfun, &(LOOP), FLAGS); \
766 (LOOP); \
767 (LOOP) = li.next ())
769 #define FOR_EACH_LOOP_FN(FN, LOOP, FLAGS) \
770 for (loop_iterator li(FN, &(LOOP), FLAGS); \
771 (LOOP); \
772 (LOOP) = li.next ())
774 /* The properties of the target. */
775 struct target_cfgloop {
776 /* Number of available registers. */
777 unsigned x_target_avail_regs;
779 /* Number of available registers that are call-clobbered. */
780 unsigned x_target_clobbered_regs;
782 /* Number of registers reserved for temporary expressions. */
783 unsigned x_target_res_regs;
785 /* The cost for register when there still is some reserve, but we are
786 approaching the number of available registers. */
787 unsigned x_target_reg_cost[2];
789 /* The cost for register when we need to spill. */
790 unsigned x_target_spill_cost[2];
793 extern struct target_cfgloop default_target_cfgloop;
794 #if SWITCHABLE_TARGET
795 extern struct target_cfgloop *this_target_cfgloop;
796 #else
797 #define this_target_cfgloop (&default_target_cfgloop)
798 #endif
800 #define target_avail_regs \
801 (this_target_cfgloop->x_target_avail_regs)
802 #define target_clobbered_regs \
803 (this_target_cfgloop->x_target_clobbered_regs)
804 #define target_res_regs \
805 (this_target_cfgloop->x_target_res_regs)
806 #define target_reg_cost \
807 (this_target_cfgloop->x_target_reg_cost)
808 #define target_spill_cost \
809 (this_target_cfgloop->x_target_spill_cost)
811 /* Register pressure estimation for induction variable optimizations & loop
812 invariant motion. */
813 extern unsigned estimate_reg_pressure_cost (unsigned, unsigned, bool, bool);
814 extern void init_set_costs (void);
816 /* Loop optimizer initialization. */
817 extern void loop_optimizer_init (unsigned);
818 extern void loop_optimizer_finalize (function *);
819 inline void
820 loop_optimizer_finalize ()
822 loop_optimizer_finalize (cfun);
825 /* Optimization passes. */
826 enum
828 UAP_UNROLL = 1, /* Enables unrolling of loops if it seems profitable. */
829 UAP_UNROLL_ALL = 2 /* Enables unrolling of all loops. */
832 extern void doloop_optimize_loops (void);
833 extern void move_loop_invariants (void);
834 extern vec<basic_block> get_loop_hot_path (const struct loop *loop);
836 /* Returns the outermost loop of the loop nest that contains LOOP.*/
837 static inline struct loop *
838 loop_outermost (struct loop *loop)
840 unsigned n = vec_safe_length (loop->superloops);
842 if (n <= 1)
843 return loop;
845 return (*loop->superloops)[1];
848 extern void record_niter_bound (struct loop *, const widest_int &, bool, bool);
849 extern HOST_WIDE_INT get_estimated_loop_iterations_int (struct loop *);
850 extern HOST_WIDE_INT get_max_loop_iterations_int (const struct loop *);
851 extern HOST_WIDE_INT get_likely_max_loop_iterations_int (struct loop *);
852 extern bool get_estimated_loop_iterations (struct loop *loop, widest_int *nit);
853 extern bool get_max_loop_iterations (const struct loop *loop, widest_int *nit);
854 extern bool get_likely_max_loop_iterations (struct loop *loop, widest_int *nit);
855 extern int bb_loop_depth (const_basic_block);
857 /* Converts VAL to widest_int. */
859 static inline widest_int
860 gcov_type_to_wide_int (gcov_type val)
862 HOST_WIDE_INT a[2];
864 a[0] = (unsigned HOST_WIDE_INT) val;
865 /* If HOST_BITS_PER_WIDE_INT == HOST_BITS_PER_WIDEST_INT, avoid shifting by
866 the size of type. */
867 val >>= HOST_BITS_PER_WIDE_INT - 1;
868 val >>= 1;
869 a[1] = (unsigned HOST_WIDE_INT) val;
871 return widest_int::from_array (a, 2);
873 #endif /* GCC_CFGLOOP_H */