1 /* Analyze RTL for GNU compiler.
2 Copyright (C) 1987-2020 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
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
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/>. */
23 #include "coretypes.h"
32 #include "insn-config.h"
34 #include "emit-rtl.h" /* FIXME: Can go away once crtl is moved to rtl.h. */
36 #include "addresses.h"
38 #include "hard-reg-set.h"
39 #include "function-abi.h"
41 /* Forward declarations */
42 static void set_of_1 (rtx
, const_rtx
, void *);
43 static bool covers_regno_p (const_rtx
, unsigned int);
44 static bool covers_regno_no_parallel_p (const_rtx
, unsigned int);
45 static int computed_jump_p_1 (const_rtx
);
46 static void parms_set (rtx
, const_rtx
, void *);
48 static unsigned HOST_WIDE_INT
cached_nonzero_bits (const_rtx
, scalar_int_mode
,
49 const_rtx
, machine_mode
,
50 unsigned HOST_WIDE_INT
);
51 static unsigned HOST_WIDE_INT
nonzero_bits1 (const_rtx
, scalar_int_mode
,
52 const_rtx
, machine_mode
,
53 unsigned HOST_WIDE_INT
);
54 static unsigned int cached_num_sign_bit_copies (const_rtx
, scalar_int_mode
,
55 const_rtx
, machine_mode
,
57 static unsigned int num_sign_bit_copies1 (const_rtx
, scalar_int_mode
,
58 const_rtx
, machine_mode
,
61 rtx_subrtx_bound_info rtx_all_subrtx_bounds
[NUM_RTX_CODE
];
62 rtx_subrtx_bound_info rtx_nonconst_subrtx_bounds
[NUM_RTX_CODE
];
64 /* Truncation narrows the mode from SOURCE mode to DESTINATION mode.
65 If TARGET_MODE_REP_EXTENDED (DESTINATION, DESTINATION_REP) is
66 SIGN_EXTEND then while narrowing we also have to enforce the
67 representation and sign-extend the value to mode DESTINATION_REP.
69 If the value is already sign-extended to DESTINATION_REP mode we
70 can just switch to DESTINATION mode on it. For each pair of
71 integral modes SOURCE and DESTINATION, when truncating from SOURCE
72 to DESTINATION, NUM_SIGN_BIT_COPIES_IN_REP[SOURCE][DESTINATION]
73 contains the number of high-order bits in SOURCE that have to be
74 copies of the sign-bit so that we can do this mode-switch to
78 num_sign_bit_copies_in_rep
[MAX_MODE_INT
+ 1][MAX_MODE_INT
+ 1];
80 /* Store X into index I of ARRAY. ARRAY is known to have at least I
81 elements. Return the new base of ARRAY. */
84 typename
T::value_type
*
85 generic_subrtx_iterator
<T
>::add_single_to_queue (array_type
&array
,
87 size_t i
, value_type x
)
89 if (base
== array
.stack
)
96 gcc_checking_assert (i
== LOCAL_ELEMS
);
97 /* A previous iteration might also have moved from the stack to the
98 heap, in which case the heap array will already be big enough. */
99 if (vec_safe_length (array
.heap
) <= i
)
100 vec_safe_grow (array
.heap
, i
+ 1, true);
101 base
= array
.heap
->address ();
102 memcpy (base
, array
.stack
, sizeof (array
.stack
));
103 base
[LOCAL_ELEMS
] = x
;
106 unsigned int length
= array
.heap
->length ();
109 gcc_checking_assert (base
== array
.heap
->address ());
115 gcc_checking_assert (i
== length
);
116 vec_safe_push (array
.heap
, x
);
117 return array
.heap
->address ();
121 /* Add the subrtxes of X to worklist ARRAY, starting at END. Return the
122 number of elements added to the worklist. */
124 template <typename T
>
126 generic_subrtx_iterator
<T
>::add_subrtxes_to_queue (array_type
&array
,
128 size_t end
, rtx_type x
)
130 enum rtx_code code
= GET_CODE (x
);
131 const char *format
= GET_RTX_FORMAT (code
);
132 size_t orig_end
= end
;
133 if (__builtin_expect (INSN_P (x
), false))
135 /* Put the pattern at the top of the queue, since that's what
136 we're likely to want most. It also allows for the SEQUENCE
138 for (int i
= GET_RTX_LENGTH (GET_CODE (x
)) - 1; i
>= 0; --i
)
139 if (format
[i
] == 'e')
141 value_type subx
= T::get_value (x
->u
.fld
[i
].rt_rtx
);
142 if (__builtin_expect (end
< LOCAL_ELEMS
, true))
145 base
= add_single_to_queue (array
, base
, end
++, subx
);
149 for (int i
= 0; format
[i
]; ++i
)
150 if (format
[i
] == 'e')
152 value_type subx
= T::get_value (x
->u
.fld
[i
].rt_rtx
);
153 if (__builtin_expect (end
< LOCAL_ELEMS
, true))
156 base
= add_single_to_queue (array
, base
, end
++, subx
);
158 else if (format
[i
] == 'E')
160 unsigned int length
= GET_NUM_ELEM (x
->u
.fld
[i
].rt_rtvec
);
161 rtx
*vec
= x
->u
.fld
[i
].rt_rtvec
->elem
;
162 if (__builtin_expect (end
+ length
<= LOCAL_ELEMS
, true))
163 for (unsigned int j
= 0; j
< length
; j
++)
164 base
[end
++] = T::get_value (vec
[j
]);
166 for (unsigned int j
= 0; j
< length
; j
++)
167 base
= add_single_to_queue (array
, base
, end
++,
168 T::get_value (vec
[j
]));
169 if (code
== SEQUENCE
&& end
== length
)
170 /* If the subrtxes of the sequence fill the entire array then
171 we know that no other parts of a containing insn are queued.
172 The caller is therefore iterating over the sequence as a
173 PATTERN (...), so we also want the patterns of the
175 for (unsigned int j
= 0; j
< length
; j
++)
177 typename
T::rtx_type x
= T::get_rtx (base
[j
]);
179 base
[j
] = T::get_value (PATTERN (x
));
182 return end
- orig_end
;
185 template <typename T
>
187 generic_subrtx_iterator
<T
>::free_array (array_type
&array
)
189 vec_free (array
.heap
);
192 template <typename T
>
193 const size_t generic_subrtx_iterator
<T
>::LOCAL_ELEMS
;
195 template class generic_subrtx_iterator
<const_rtx_accessor
>;
196 template class generic_subrtx_iterator
<rtx_var_accessor
>;
197 template class generic_subrtx_iterator
<rtx_ptr_accessor
>;
199 /* Return 1 if the value of X is unstable
200 (would be different at a different point in the program).
201 The frame pointer, arg pointer, etc. are considered stable
202 (within one function) and so is anything marked `unchanging'. */
205 rtx_unstable_p (const_rtx x
)
207 const RTX_CODE code
= GET_CODE (x
);
214 return !MEM_READONLY_P (x
) || rtx_unstable_p (XEXP (x
, 0));
223 /* As in rtx_varies_p, we have to use the actual rtx, not reg number. */
224 if (x
== frame_pointer_rtx
|| x
== hard_frame_pointer_rtx
225 /* The arg pointer varies if it is not a fixed register. */
226 || (x
== arg_pointer_rtx
&& fixed_regs
[ARG_POINTER_REGNUM
]))
228 /* ??? When call-clobbered, the value is stable modulo the restore
229 that must happen after a call. This currently screws up local-alloc
230 into believing that the restore is not needed. */
231 if (!PIC_OFFSET_TABLE_REG_CALL_CLOBBERED
&& x
== pic_offset_table_rtx
)
236 if (MEM_VOLATILE_P (x
))
245 fmt
= GET_RTX_FORMAT (code
);
246 for (i
= GET_RTX_LENGTH (code
) - 1; i
>= 0; i
--)
249 if (rtx_unstable_p (XEXP (x
, i
)))
252 else if (fmt
[i
] == 'E')
255 for (j
= 0; j
< XVECLEN (x
, i
); j
++)
256 if (rtx_unstable_p (XVECEXP (x
, i
, j
)))
263 /* Return 1 if X has a value that can vary even between two
264 executions of the program. 0 means X can be compared reliably
265 against certain constants or near-constants.
266 FOR_ALIAS is nonzero if we are called from alias analysis; if it is
267 zero, we are slightly more conservative.
268 The frame pointer and the arg pointer are considered constant. */
271 rtx_varies_p (const_rtx x
, bool for_alias
)
284 return !MEM_READONLY_P (x
) || rtx_varies_p (XEXP (x
, 0), for_alias
);
293 /* Note that we have to test for the actual rtx used for the frame
294 and arg pointers and not just the register number in case we have
295 eliminated the frame and/or arg pointer and are using it
297 if (x
== frame_pointer_rtx
|| x
== hard_frame_pointer_rtx
298 /* The arg pointer varies if it is not a fixed register. */
299 || (x
== arg_pointer_rtx
&& fixed_regs
[ARG_POINTER_REGNUM
]))
301 if (x
== pic_offset_table_rtx
302 /* ??? When call-clobbered, the value is stable modulo the restore
303 that must happen after a call. This currently screws up
304 local-alloc into believing that the restore is not needed, so we
305 must return 0 only if we are called from alias analysis. */
306 && (!PIC_OFFSET_TABLE_REG_CALL_CLOBBERED
|| for_alias
))
311 /* The operand 0 of a LO_SUM is considered constant
312 (in fact it is related specifically to operand 1)
313 during alias analysis. */
314 return (! for_alias
&& rtx_varies_p (XEXP (x
, 0), for_alias
))
315 || rtx_varies_p (XEXP (x
, 1), for_alias
);
318 if (MEM_VOLATILE_P (x
))
327 fmt
= GET_RTX_FORMAT (code
);
328 for (i
= GET_RTX_LENGTH (code
) - 1; i
>= 0; i
--)
331 if (rtx_varies_p (XEXP (x
, i
), for_alias
))
334 else if (fmt
[i
] == 'E')
337 for (j
= 0; j
< XVECLEN (x
, i
); j
++)
338 if (rtx_varies_p (XVECEXP (x
, i
, j
), for_alias
))
345 /* Compute an approximation for the offset between the register
346 FROM and TO for the current function, as it was at the start
350 get_initial_register_offset (int from
, int to
)
352 static const struct elim_table_t
356 } table
[] = ELIMINABLE_REGS
;
357 poly_int64 offset1
, offset2
;
363 /* It is not safe to call INITIAL_ELIMINATION_OFFSET before the epilogue
364 is completed, but we need to give at least an estimate for the stack
365 pointer based on the frame size. */
366 if (!epilogue_completed
)
368 offset1
= crtl
->outgoing_args_size
+ get_frame_size ();
369 #if !STACK_GROWS_DOWNWARD
372 if (to
== STACK_POINTER_REGNUM
)
374 else if (from
== STACK_POINTER_REGNUM
)
380 for (i
= 0; i
< ARRAY_SIZE (table
); i
++)
381 if (table
[i
].from
== from
)
383 if (table
[i
].to
== to
)
385 INITIAL_ELIMINATION_OFFSET (table
[i
].from
, table
[i
].to
,
389 for (j
= 0; j
< ARRAY_SIZE (table
); j
++)
391 if (table
[j
].to
== to
392 && table
[j
].from
== table
[i
].to
)
394 INITIAL_ELIMINATION_OFFSET (table
[i
].from
, table
[i
].to
,
396 INITIAL_ELIMINATION_OFFSET (table
[j
].from
, table
[j
].to
,
398 return offset1
+ offset2
;
400 if (table
[j
].from
== to
401 && table
[j
].to
== table
[i
].to
)
403 INITIAL_ELIMINATION_OFFSET (table
[i
].from
, table
[i
].to
,
405 INITIAL_ELIMINATION_OFFSET (table
[j
].from
, table
[j
].to
,
407 return offset1
- offset2
;
411 else if (table
[i
].to
== from
)
413 if (table
[i
].from
== to
)
415 INITIAL_ELIMINATION_OFFSET (table
[i
].from
, table
[i
].to
,
419 for (j
= 0; j
< ARRAY_SIZE (table
); j
++)
421 if (table
[j
].to
== to
422 && table
[j
].from
== table
[i
].from
)
424 INITIAL_ELIMINATION_OFFSET (table
[i
].from
, table
[i
].to
,
426 INITIAL_ELIMINATION_OFFSET (table
[j
].from
, table
[j
].to
,
428 return - offset1
+ offset2
;
430 if (table
[j
].from
== to
431 && table
[j
].to
== table
[i
].from
)
433 INITIAL_ELIMINATION_OFFSET (table
[i
].from
, table
[i
].to
,
435 INITIAL_ELIMINATION_OFFSET (table
[j
].from
, table
[j
].to
,
437 return - offset1
- offset2
;
442 /* If the requested register combination was not found,
443 try a different more simple combination. */
444 if (from
== ARG_POINTER_REGNUM
)
445 return get_initial_register_offset (HARD_FRAME_POINTER_REGNUM
, to
);
446 else if (to
== ARG_POINTER_REGNUM
)
447 return get_initial_register_offset (from
, HARD_FRAME_POINTER_REGNUM
);
448 else if (from
== HARD_FRAME_POINTER_REGNUM
)
449 return get_initial_register_offset (FRAME_POINTER_REGNUM
, to
);
450 else if (to
== HARD_FRAME_POINTER_REGNUM
)
451 return get_initial_register_offset (from
, FRAME_POINTER_REGNUM
);
456 /* Return nonzero if the use of X+OFFSET as an address in a MEM with SIZE
457 bytes can cause a trap. MODE is the mode of the MEM (not that of X) and
458 UNALIGNED_MEMS controls whether nonzero is returned for unaligned memory
459 references on strict alignment machines. */
462 rtx_addr_can_trap_p_1 (const_rtx x
, poly_int64 offset
, poly_int64 size
,
463 machine_mode mode
, bool unaligned_mems
)
465 enum rtx_code code
= GET_CODE (x
);
466 gcc_checking_assert (mode
== BLKmode
|| known_size_p (size
));
469 /* The offset must be a multiple of the mode size if we are considering
470 unaligned memory references on strict alignment machines. */
471 if (STRICT_ALIGNMENT
&& unaligned_mems
&& mode
!= BLKmode
)
473 poly_int64 actual_offset
= offset
;
475 #ifdef SPARC_STACK_BOUNDARY_HACK
476 /* ??? The SPARC port may claim a STACK_BOUNDARY higher than
477 the real alignment of %sp. However, when it does this, the
478 alignment of %sp+STACK_POINTER_OFFSET is STACK_BOUNDARY. */
479 if (SPARC_STACK_BOUNDARY_HACK
480 && (x
== stack_pointer_rtx
|| x
== hard_frame_pointer_rtx
))
481 actual_offset
-= STACK_POINTER_OFFSET
;
484 if (!multiple_p (actual_offset
, GET_MODE_SIZE (mode
)))
491 if (SYMBOL_REF_WEAK (x
))
493 if (!CONSTANT_POOL_ADDRESS_P (x
) && !SYMBOL_REF_FUNCTION_P (x
))
496 poly_int64 decl_size
;
498 if (maybe_lt (offset
, 0))
500 if (!known_size_p (size
))
501 return maybe_ne (offset
, 0);
503 /* If the size of the access or of the symbol is unknown,
505 decl
= SYMBOL_REF_DECL (x
);
507 /* Else check that the access is in bounds. TODO: restructure
508 expr_size/tree_expr_size/int_expr_size and just use the latter. */
511 else if (DECL_P (decl
) && DECL_SIZE_UNIT (decl
))
513 if (!poly_int_tree_p (DECL_SIZE_UNIT (decl
), &decl_size
))
516 else if (TREE_CODE (decl
) == STRING_CST
)
517 decl_size
= TREE_STRING_LENGTH (decl
);
518 else if (TYPE_SIZE_UNIT (TREE_TYPE (decl
)))
519 decl_size
= int_size_in_bytes (TREE_TYPE (decl
));
523 return (!known_size_p (decl_size
) || known_eq (decl_size
, 0)
524 ? maybe_ne (offset
, 0)
525 : !known_subrange_p (offset
, size
, 0, decl_size
));
534 /* Stack references are assumed not to trap, but we need to deal with
535 nonsensical offsets. */
536 if (x
== frame_pointer_rtx
|| x
== hard_frame_pointer_rtx
537 || x
== stack_pointer_rtx
538 /* The arg pointer varies if it is not a fixed register. */
539 || (x
== arg_pointer_rtx
&& fixed_regs
[ARG_POINTER_REGNUM
]))
542 poly_int64 red_zone_size
= RED_ZONE_SIZE
;
544 poly_int64 red_zone_size
= 0;
546 poly_int64 stack_boundary
= PREFERRED_STACK_BOUNDARY
/ BITS_PER_UNIT
;
547 poly_int64 low_bound
, high_bound
;
549 if (!known_size_p (size
))
552 if (x
== frame_pointer_rtx
)
554 if (FRAME_GROWS_DOWNWARD
)
556 high_bound
= targetm
.starting_frame_offset ();
557 low_bound
= high_bound
- get_frame_size ();
561 low_bound
= targetm
.starting_frame_offset ();
562 high_bound
= low_bound
+ get_frame_size ();
565 else if (x
== hard_frame_pointer_rtx
)
568 = get_initial_register_offset (STACK_POINTER_REGNUM
,
569 HARD_FRAME_POINTER_REGNUM
);
571 = get_initial_register_offset (ARG_POINTER_REGNUM
,
572 HARD_FRAME_POINTER_REGNUM
);
574 #if STACK_GROWS_DOWNWARD
575 low_bound
= sp_offset
- red_zone_size
- stack_boundary
;
576 high_bound
= ap_offset
577 + FIRST_PARM_OFFSET (current_function_decl
)
578 #if !ARGS_GROW_DOWNWARD
583 high_bound
= sp_offset
+ red_zone_size
+ stack_boundary
;
584 low_bound
= ap_offset
585 + FIRST_PARM_OFFSET (current_function_decl
)
586 #if ARGS_GROW_DOWNWARD
592 else if (x
== stack_pointer_rtx
)
595 = get_initial_register_offset (ARG_POINTER_REGNUM
,
596 STACK_POINTER_REGNUM
);
598 #if STACK_GROWS_DOWNWARD
599 low_bound
= - red_zone_size
- stack_boundary
;
600 high_bound
= ap_offset
601 + FIRST_PARM_OFFSET (current_function_decl
)
602 #if !ARGS_GROW_DOWNWARD
607 high_bound
= red_zone_size
+ stack_boundary
;
608 low_bound
= ap_offset
609 + FIRST_PARM_OFFSET (current_function_decl
)
610 #if ARGS_GROW_DOWNWARD
618 /* We assume that accesses are safe to at least the
620 Examples are varargs and __builtin_return_address. */
621 #if ARGS_GROW_DOWNWARD
622 high_bound
= FIRST_PARM_OFFSET (current_function_decl
)
624 low_bound
= FIRST_PARM_OFFSET (current_function_decl
)
625 - crtl
->args
.size
- stack_boundary
;
627 low_bound
= FIRST_PARM_OFFSET (current_function_decl
)
629 high_bound
= FIRST_PARM_OFFSET (current_function_decl
)
630 + crtl
->args
.size
+ stack_boundary
;
634 if (known_ge (offset
, low_bound
)
635 && known_le (offset
, high_bound
- size
))
639 /* All of the virtual frame registers are stack references. */
640 if (REGNO (x
) >= FIRST_VIRTUAL_REGISTER
641 && REGNO (x
) <= LAST_VIRTUAL_REGISTER
)
646 return rtx_addr_can_trap_p_1 (XEXP (x
, 0), offset
, size
,
647 mode
, unaligned_mems
);
650 /* An address is assumed not to trap if:
651 - it is the pic register plus a const unspec without offset. */
652 if (XEXP (x
, 0) == pic_offset_table_rtx
653 && GET_CODE (XEXP (x
, 1)) == CONST
654 && GET_CODE (XEXP (XEXP (x
, 1), 0)) == UNSPEC
655 && known_eq (offset
, 0))
658 /* - or it is an address that can't trap plus a constant integer. */
659 if (poly_int_rtx_p (XEXP (x
, 1), &const_x1
)
660 && !rtx_addr_can_trap_p_1 (XEXP (x
, 0), offset
+ const_x1
,
661 size
, mode
, unaligned_mems
))
668 return rtx_addr_can_trap_p_1 (XEXP (x
, 1), offset
, size
,
669 mode
, unaligned_mems
);
676 return rtx_addr_can_trap_p_1 (XEXP (x
, 0), offset
, size
,
677 mode
, unaligned_mems
);
683 /* If it isn't one of the case above, it can cause a trap. */
687 /* Return nonzero if the use of X as an address in a MEM can cause a trap. */
690 rtx_addr_can_trap_p (const_rtx x
)
692 return rtx_addr_can_trap_p_1 (x
, 0, -1, BLKmode
, false);
695 /* Return true if X contains a MEM subrtx. */
698 contains_mem_rtx_p (rtx x
)
700 subrtx_iterator::array_type array
;
701 FOR_EACH_SUBRTX (iter
, array
, x
, ALL
)
708 /* Return true if X is an address that is known to not be zero. */
711 nonzero_address_p (const_rtx x
)
713 const enum rtx_code code
= GET_CODE (x
);
718 return flag_delete_null_pointer_checks
&& !SYMBOL_REF_WEAK (x
);
724 /* As in rtx_varies_p, we have to use the actual rtx, not reg number. */
725 if (x
== frame_pointer_rtx
|| x
== hard_frame_pointer_rtx
726 || x
== stack_pointer_rtx
727 || (x
== arg_pointer_rtx
&& fixed_regs
[ARG_POINTER_REGNUM
]))
729 /* All of the virtual frame registers are stack references. */
730 if (REGNO (x
) >= FIRST_VIRTUAL_REGISTER
731 && REGNO (x
) <= LAST_VIRTUAL_REGISTER
)
736 return nonzero_address_p (XEXP (x
, 0));
739 /* Handle PIC references. */
740 if (XEXP (x
, 0) == pic_offset_table_rtx
741 && CONSTANT_P (XEXP (x
, 1)))
746 /* Similar to the above; allow positive offsets. Further, since
747 auto-inc is only allowed in memories, the register must be a
749 if (CONST_INT_P (XEXP (x
, 1))
750 && INTVAL (XEXP (x
, 1)) > 0)
752 return nonzero_address_p (XEXP (x
, 0));
755 /* Similarly. Further, the offset is always positive. */
762 return nonzero_address_p (XEXP (x
, 0));
765 return nonzero_address_p (XEXP (x
, 1));
771 /* If it isn't one of the case above, might be zero. */
775 /* Return 1 if X refers to a memory location whose address
776 cannot be compared reliably with constant addresses,
777 or if X refers to a BLKmode memory object.
778 FOR_ALIAS is nonzero if we are called from alias analysis; if it is
779 zero, we are slightly more conservative. */
782 rtx_addr_varies_p (const_rtx x
, bool for_alias
)
793 return GET_MODE (x
) == BLKmode
|| rtx_varies_p (XEXP (x
, 0), for_alias
);
795 fmt
= GET_RTX_FORMAT (code
);
796 for (i
= GET_RTX_LENGTH (code
) - 1; i
>= 0; i
--)
799 if (rtx_addr_varies_p (XEXP (x
, i
), for_alias
))
802 else if (fmt
[i
] == 'E')
805 for (j
= 0; j
< XVECLEN (x
, i
); j
++)
806 if (rtx_addr_varies_p (XVECEXP (x
, i
, j
), for_alias
))
812 /* Return the CALL in X if there is one. */
815 get_call_rtx_from (const rtx_insn
*insn
)
817 rtx x
= PATTERN (insn
);
818 if (GET_CODE (x
) == PARALLEL
)
819 x
= XVECEXP (x
, 0, 0);
820 if (GET_CODE (x
) == SET
)
822 if (GET_CODE (x
) == CALL
&& MEM_P (XEXP (x
, 0)))
827 /* Get the declaration of the function called by INSN. */
830 get_call_fndecl (const rtx_insn
*insn
)
834 note
= find_reg_note (insn
, REG_CALL_DECL
, NULL_RTX
);
835 if (note
== NULL_RTX
)
838 datum
= XEXP (note
, 0);
839 if (datum
!= NULL_RTX
)
840 return SYMBOL_REF_DECL (datum
);
845 /* Return the value of the integer term in X, if one is apparent;
847 Only obvious integer terms are detected.
848 This is used in cse.c with the `related_value' field. */
851 get_integer_term (const_rtx x
)
853 if (GET_CODE (x
) == CONST
)
856 if (GET_CODE (x
) == MINUS
857 && CONST_INT_P (XEXP (x
, 1)))
858 return - INTVAL (XEXP (x
, 1));
859 if (GET_CODE (x
) == PLUS
860 && CONST_INT_P (XEXP (x
, 1)))
861 return INTVAL (XEXP (x
, 1));
865 /* If X is a constant, return the value sans apparent integer term;
867 Only obvious integer terms are detected. */
870 get_related_value (const_rtx x
)
872 if (GET_CODE (x
) != CONST
)
875 if (GET_CODE (x
) == PLUS
876 && CONST_INT_P (XEXP (x
, 1)))
878 else if (GET_CODE (x
) == MINUS
879 && CONST_INT_P (XEXP (x
, 1)))
884 /* Return true if SYMBOL is a SYMBOL_REF and OFFSET + SYMBOL points
885 to somewhere in the same object or object_block as SYMBOL. */
888 offset_within_block_p (const_rtx symbol
, HOST_WIDE_INT offset
)
892 if (GET_CODE (symbol
) != SYMBOL_REF
)
900 if (CONSTANT_POOL_ADDRESS_P (symbol
)
901 && offset
< (int) GET_MODE_SIZE (get_pool_mode (symbol
)))
904 decl
= SYMBOL_REF_DECL (symbol
);
905 if (decl
&& offset
< int_size_in_bytes (TREE_TYPE (decl
)))
909 if (SYMBOL_REF_HAS_BLOCK_INFO_P (symbol
)
910 && SYMBOL_REF_BLOCK (symbol
)
911 && SYMBOL_REF_BLOCK_OFFSET (symbol
) >= 0
912 && ((unsigned HOST_WIDE_INT
) offset
+ SYMBOL_REF_BLOCK_OFFSET (symbol
)
913 < (unsigned HOST_WIDE_INT
) SYMBOL_REF_BLOCK (symbol
)->size
))
919 /* Split X into a base and a constant offset, storing them in *BASE_OUT
920 and *OFFSET_OUT respectively. */
923 split_const (rtx x
, rtx
*base_out
, rtx
*offset_out
)
925 if (GET_CODE (x
) == CONST
)
928 if (GET_CODE (x
) == PLUS
&& CONST_INT_P (XEXP (x
, 1)))
930 *base_out
= XEXP (x
, 0);
931 *offset_out
= XEXP (x
, 1);
936 *offset_out
= const0_rtx
;
939 /* Express integer value X as some value Y plus a polynomial offset,
940 where Y is either const0_rtx, X or something within X (as opposed
941 to a new rtx). Return the Y and store the offset in *OFFSET_OUT. */
944 strip_offset (rtx x
, poly_int64_pod
*offset_out
)
946 rtx base
= const0_rtx
;
948 if (GET_CODE (test
) == CONST
)
949 test
= XEXP (test
, 0);
950 if (GET_CODE (test
) == PLUS
)
952 base
= XEXP (test
, 0);
953 test
= XEXP (test
, 1);
955 if (poly_int_rtx_p (test
, offset_out
))
961 /* Return the argument size in REG_ARGS_SIZE note X. */
964 get_args_size (const_rtx x
)
966 gcc_checking_assert (REG_NOTE_KIND (x
) == REG_ARGS_SIZE
);
967 return rtx_to_poly_int64 (XEXP (x
, 0));
970 /* Return the number of places FIND appears within X. If COUNT_DEST is
971 zero, we do not count occurrences inside the destination of a SET. */
974 count_occurrences (const_rtx x
, const_rtx find
, int count_dest
)
978 const char *format_ptr
;
997 count
= count_occurrences (XEXP (x
, 0), find
, count_dest
);
999 count
+= count_occurrences (XEXP (x
, 1), find
, count_dest
);
1003 if (MEM_P (find
) && rtx_equal_p (x
, find
))
1008 if (SET_DEST (x
) == find
&& ! count_dest
)
1009 return count_occurrences (SET_SRC (x
), find
, count_dest
);
1016 format_ptr
= GET_RTX_FORMAT (code
);
1019 for (i
= 0; i
< GET_RTX_LENGTH (code
); i
++)
1021 switch (*format_ptr
++)
1024 count
+= count_occurrences (XEXP (x
, i
), find
, count_dest
);
1028 for (j
= 0; j
< XVECLEN (x
, i
); j
++)
1029 count
+= count_occurrences (XVECEXP (x
, i
, j
), find
, count_dest
);
1037 /* Return TRUE if OP is a register or subreg of a register that
1038 holds an unsigned quantity. Otherwise, return FALSE. */
1041 unsigned_reg_p (rtx op
)
1045 && TYPE_UNSIGNED (TREE_TYPE (REG_EXPR (op
))))
1048 if (GET_CODE (op
) == SUBREG
1049 && SUBREG_PROMOTED_SIGN (op
))
1056 /* Nonzero if register REG appears somewhere within IN.
1057 Also works if REG is not a register; in this case it checks
1058 for a subexpression of IN that is Lisp "equal" to REG. */
1061 reg_mentioned_p (const_rtx reg
, const_rtx in
)
1073 if (GET_CODE (in
) == LABEL_REF
)
1074 return reg
== label_ref_label (in
);
1076 code
= GET_CODE (in
);
1080 /* Compare registers by number. */
1082 return REG_P (reg
) && REGNO (in
) == REGNO (reg
);
1084 /* These codes have no constituent expressions
1092 /* These are kept unique for a given value. */
1099 if (GET_CODE (reg
) == code
&& rtx_equal_p (reg
, in
))
1102 fmt
= GET_RTX_FORMAT (code
);
1104 for (i
= GET_RTX_LENGTH (code
) - 1; i
>= 0; i
--)
1109 for (j
= XVECLEN (in
, i
) - 1; j
>= 0; j
--)
1110 if (reg_mentioned_p (reg
, XVECEXP (in
, i
, j
)))
1113 else if (fmt
[i
] == 'e'
1114 && reg_mentioned_p (reg
, XEXP (in
, i
)))
1120 /* Return 1 if in between BEG and END, exclusive of BEG and END, there is
1121 no CODE_LABEL insn. */
1124 no_labels_between_p (const rtx_insn
*beg
, const rtx_insn
*end
)
1129 for (p
= NEXT_INSN (beg
); p
!= end
; p
= NEXT_INSN (p
))
1135 /* Nonzero if register REG is used in an insn between
1136 FROM_INSN and TO_INSN (exclusive of those two). */
1139 reg_used_between_p (const_rtx reg
, const rtx_insn
*from_insn
,
1140 const rtx_insn
*to_insn
)
1144 if (from_insn
== to_insn
)
1147 for (insn
= NEXT_INSN (from_insn
); insn
!= to_insn
; insn
= NEXT_INSN (insn
))
1148 if (NONDEBUG_INSN_P (insn
)
1149 && (reg_overlap_mentioned_p (reg
, PATTERN (insn
))
1150 || (CALL_P (insn
) && find_reg_fusage (insn
, USE
, reg
))))
1155 /* Nonzero if the old value of X, a register, is referenced in BODY. If X
1156 is entirely replaced by a new value and the only use is as a SET_DEST,
1157 we do not consider it a reference. */
1160 reg_referenced_p (const_rtx x
, const_rtx body
)
1164 switch (GET_CODE (body
))
1167 if (reg_overlap_mentioned_p (x
, SET_SRC (body
)))
1170 /* If the destination is anything other than CC0, PC, a REG or a SUBREG
1171 of a REG that occupies all of the REG, the insn references X if
1172 it is mentioned in the destination. */
1173 if (GET_CODE (SET_DEST (body
)) != CC0
1174 && GET_CODE (SET_DEST (body
)) != PC
1175 && !REG_P (SET_DEST (body
))
1176 && ! (GET_CODE (SET_DEST (body
)) == SUBREG
1177 && REG_P (SUBREG_REG (SET_DEST (body
)))
1178 && !read_modify_subreg_p (SET_DEST (body
)))
1179 && reg_overlap_mentioned_p (x
, SET_DEST (body
)))
1184 for (i
= ASM_OPERANDS_INPUT_LENGTH (body
) - 1; i
>= 0; i
--)
1185 if (reg_overlap_mentioned_p (x
, ASM_OPERANDS_INPUT (body
, i
)))
1192 return reg_overlap_mentioned_p (x
, body
);
1195 return reg_overlap_mentioned_p (x
, TRAP_CONDITION (body
));
1198 return reg_overlap_mentioned_p (x
, XEXP (body
, 0));
1201 case UNSPEC_VOLATILE
:
1202 for (i
= XVECLEN (body
, 0) - 1; i
>= 0; i
--)
1203 if (reg_overlap_mentioned_p (x
, XVECEXP (body
, 0, i
)))
1208 for (i
= XVECLEN (body
, 0) - 1; i
>= 0; i
--)
1209 if (reg_referenced_p (x
, XVECEXP (body
, 0, i
)))
1214 if (MEM_P (XEXP (body
, 0)))
1215 if (reg_overlap_mentioned_p (x
, XEXP (XEXP (body
, 0), 0)))
1220 if (reg_overlap_mentioned_p (x
, COND_EXEC_TEST (body
)))
1222 return reg_referenced_p (x
, COND_EXEC_CODE (body
));
1229 /* Nonzero if register REG is set or clobbered in an insn between
1230 FROM_INSN and TO_INSN (exclusive of those two). */
1233 reg_set_between_p (const_rtx reg
, const rtx_insn
*from_insn
,
1234 const rtx_insn
*to_insn
)
1236 const rtx_insn
*insn
;
1238 if (from_insn
== to_insn
)
1241 for (insn
= NEXT_INSN (from_insn
); insn
!= to_insn
; insn
= NEXT_INSN (insn
))
1242 if (INSN_P (insn
) && reg_set_p (reg
, insn
))
1247 /* Return true if REG is set or clobbered inside INSN. */
1250 reg_set_p (const_rtx reg
, const_rtx insn
)
1252 /* After delay slot handling, call and branch insns might be in a
1253 sequence. Check all the elements there. */
1254 if (INSN_P (insn
) && GET_CODE (PATTERN (insn
)) == SEQUENCE
)
1256 for (int i
= 0; i
< XVECLEN (PATTERN (insn
), 0); ++i
)
1257 if (reg_set_p (reg
, XVECEXP (PATTERN (insn
), 0, i
)))
1263 /* We can be passed an insn or part of one. If we are passed an insn,
1264 check if a side-effect of the insn clobbers REG. */
1266 && (FIND_REG_INC_NOTE (insn
, reg
)
1269 && REGNO (reg
) < FIRST_PSEUDO_REGISTER
1270 && (insn_callee_abi (as_a
<const rtx_insn
*> (insn
))
1271 .clobbers_reg_p (GET_MODE (reg
), REGNO (reg
))))
1273 || find_reg_fusage (insn
, CLOBBER
, reg
)))))
1276 /* There are no REG_INC notes for SP autoinc. */
1277 if (reg
== stack_pointer_rtx
&& INSN_P (insn
))
1279 subrtx_var_iterator::array_type array
;
1280 FOR_EACH_SUBRTX_VAR (iter
, array
, PATTERN (insn
), NONCONST
)
1285 && GET_RTX_CLASS (GET_CODE (XEXP (mem
, 0))) == RTX_AUTOINC
)
1287 if (XEXP (XEXP (mem
, 0), 0) == stack_pointer_rtx
)
1289 iter
.skip_subrtxes ();
1294 return set_of (reg
, insn
) != NULL_RTX
;
1297 /* Similar to reg_set_between_p, but check all registers in X. Return 0
1298 only if none of them are modified between START and END. Return 1 if
1299 X contains a MEM; this routine does use memory aliasing. */
1302 modified_between_p (const_rtx x
, const rtx_insn
*start
, const rtx_insn
*end
)
1304 const enum rtx_code code
= GET_CODE (x
);
1325 if (modified_between_p (XEXP (x
, 0), start
, end
))
1327 if (MEM_READONLY_P (x
))
1329 for (insn
= NEXT_INSN (start
); insn
!= end
; insn
= NEXT_INSN (insn
))
1330 if (memory_modified_in_insn_p (x
, insn
))
1335 return reg_set_between_p (x
, start
, end
);
1341 fmt
= GET_RTX_FORMAT (code
);
1342 for (i
= GET_RTX_LENGTH (code
) - 1; i
>= 0; i
--)
1344 if (fmt
[i
] == 'e' && modified_between_p (XEXP (x
, i
), start
, end
))
1347 else if (fmt
[i
] == 'E')
1348 for (j
= XVECLEN (x
, i
) - 1; j
>= 0; j
--)
1349 if (modified_between_p (XVECEXP (x
, i
, j
), start
, end
))
1356 /* Similar to reg_set_p, but check all registers in X. Return 0 only if none
1357 of them are modified in INSN. Return 1 if X contains a MEM; this routine
1358 does use memory aliasing. */
1361 modified_in_p (const_rtx x
, const_rtx insn
)
1363 const enum rtx_code code
= GET_CODE (x
);
1380 if (modified_in_p (XEXP (x
, 0), insn
))
1382 if (MEM_READONLY_P (x
))
1384 if (memory_modified_in_insn_p (x
, insn
))
1389 return reg_set_p (x
, insn
);
1395 fmt
= GET_RTX_FORMAT (code
);
1396 for (i
= GET_RTX_LENGTH (code
) - 1; i
>= 0; i
--)
1398 if (fmt
[i
] == 'e' && modified_in_p (XEXP (x
, i
), insn
))
1401 else if (fmt
[i
] == 'E')
1402 for (j
= XVECLEN (x
, i
) - 1; j
>= 0; j
--)
1403 if (modified_in_p (XVECEXP (x
, i
, j
), insn
))
1410 /* Return true if X is a SUBREG and if storing a value to X would
1411 preserve some of its SUBREG_REG. For example, on a normal 32-bit
1412 target, using a SUBREG to store to one half of a DImode REG would
1413 preserve the other half. */
1416 read_modify_subreg_p (const_rtx x
)
1418 if (GET_CODE (x
) != SUBREG
)
1420 poly_uint64 isize
= GET_MODE_SIZE (GET_MODE (SUBREG_REG (x
)));
1421 poly_uint64 osize
= GET_MODE_SIZE (GET_MODE (x
));
1422 poly_uint64 regsize
= REGMODE_NATURAL_SIZE (GET_MODE (SUBREG_REG (x
)));
1423 /* The inner and outer modes of a subreg must be ordered, so that we
1424 can tell whether they're paradoxical or partial. */
1425 gcc_checking_assert (ordered_p (isize
, osize
));
1426 return (maybe_gt (isize
, osize
) && maybe_gt (isize
, regsize
));
1429 /* Helper function for set_of. */
1437 set_of_1 (rtx x
, const_rtx pat
, void *data1
)
1439 struct set_of_data
*const data
= (struct set_of_data
*) (data1
);
1440 if (rtx_equal_p (x
, data
->pat
)
1441 || (!MEM_P (x
) && reg_overlap_mentioned_p (data
->pat
, x
)))
1445 /* Give an INSN, return a SET or CLOBBER expression that does modify PAT
1446 (either directly or via STRICT_LOW_PART and similar modifiers). */
1448 set_of (const_rtx pat
, const_rtx insn
)
1450 struct set_of_data data
;
1451 data
.found
= NULL_RTX
;
1453 note_pattern_stores (INSN_P (insn
) ? PATTERN (insn
) : insn
, set_of_1
, &data
);
1457 /* Add all hard register in X to *PSET. */
1459 find_all_hard_regs (const_rtx x
, HARD_REG_SET
*pset
)
1461 subrtx_iterator::array_type array
;
1462 FOR_EACH_SUBRTX (iter
, array
, x
, NONCONST
)
1464 const_rtx x
= *iter
;
1465 if (REG_P (x
) && REGNO (x
) < FIRST_PSEUDO_REGISTER
)
1466 add_to_hard_reg_set (pset
, GET_MODE (x
), REGNO (x
));
1470 /* This function, called through note_stores, collects sets and
1471 clobbers of hard registers in a HARD_REG_SET, which is pointed to
1474 record_hard_reg_sets (rtx x
, const_rtx pat ATTRIBUTE_UNUSED
, void *data
)
1476 HARD_REG_SET
*pset
= (HARD_REG_SET
*)data
;
1477 if (REG_P (x
) && HARD_REGISTER_P (x
))
1478 add_to_hard_reg_set (pset
, GET_MODE (x
), REGNO (x
));
1481 /* Examine INSN, and compute the set of hard registers written by it.
1482 Store it in *PSET. Should only be called after reload.
1484 IMPLICIT is true if we should include registers that are fully-clobbered
1485 by calls. This should be used with caution, since it doesn't include
1486 partially-clobbered registers. */
1488 find_all_hard_reg_sets (const rtx_insn
*insn
, HARD_REG_SET
*pset
, bool implicit
)
1492 CLEAR_HARD_REG_SET (*pset
);
1493 note_stores (insn
, record_hard_reg_sets
, pset
);
1494 if (CALL_P (insn
) && implicit
)
1495 *pset
|= insn_callee_abi (insn
).full_reg_clobbers ();
1496 for (link
= REG_NOTES (insn
); link
; link
= XEXP (link
, 1))
1497 if (REG_NOTE_KIND (link
) == REG_INC
)
1498 record_hard_reg_sets (XEXP (link
, 0), NULL
, pset
);
1501 /* Like record_hard_reg_sets, but called through note_uses. */
1503 record_hard_reg_uses (rtx
*px
, void *data
)
1505 find_all_hard_regs (*px
, (HARD_REG_SET
*) data
);
1508 /* Given an INSN, return a SET expression if this insn has only a single SET.
1509 It may also have CLOBBERs, USEs, or SET whose output
1510 will not be used, which we ignore. */
1513 single_set_2 (const rtx_insn
*insn
, const_rtx pat
)
1516 int set_verified
= 1;
1519 if (GET_CODE (pat
) == PARALLEL
)
1521 for (i
= 0; i
< XVECLEN (pat
, 0); i
++)
1523 rtx sub
= XVECEXP (pat
, 0, i
);
1524 switch (GET_CODE (sub
))
1531 /* We can consider insns having multiple sets, where all
1532 but one are dead as single set insns. In common case
1533 only single set is present in the pattern so we want
1534 to avoid checking for REG_UNUSED notes unless necessary.
1536 When we reach set first time, we just expect this is
1537 the single set we are looking for and only when more
1538 sets are found in the insn, we check them. */
1541 if (find_reg_note (insn
, REG_UNUSED
, SET_DEST (set
))
1542 && !side_effects_p (set
))
1548 set
= sub
, set_verified
= 0;
1549 else if (!find_reg_note (insn
, REG_UNUSED
, SET_DEST (sub
))
1550 || side_effects_p (sub
))
1562 /* Given an INSN, return nonzero if it has more than one SET, else return
1566 multiple_sets (const_rtx insn
)
1571 /* INSN must be an insn. */
1572 if (! INSN_P (insn
))
1575 /* Only a PARALLEL can have multiple SETs. */
1576 if (GET_CODE (PATTERN (insn
)) == PARALLEL
)
1578 for (i
= 0, found
= 0; i
< XVECLEN (PATTERN (insn
), 0); i
++)
1579 if (GET_CODE (XVECEXP (PATTERN (insn
), 0, i
)) == SET
)
1581 /* If we have already found a SET, then return now. */
1589 /* Either zero or one SET. */
1593 /* Return nonzero if the destination of SET equals the source
1594 and there are no side effects. */
1597 set_noop_p (const_rtx set
)
1599 rtx src
= SET_SRC (set
);
1600 rtx dst
= SET_DEST (set
);
1602 if (dst
== pc_rtx
&& src
== pc_rtx
)
1605 if (MEM_P (dst
) && MEM_P (src
))
1606 return rtx_equal_p (dst
, src
) && !side_effects_p (dst
);
1608 if (GET_CODE (dst
) == ZERO_EXTRACT
)
1609 return rtx_equal_p (XEXP (dst
, 0), src
)
1610 && !BITS_BIG_ENDIAN
&& XEXP (dst
, 2) == const0_rtx
1611 && !side_effects_p (src
);
1613 if (GET_CODE (dst
) == STRICT_LOW_PART
)
1614 dst
= XEXP (dst
, 0);
1616 if (GET_CODE (src
) == SUBREG
&& GET_CODE (dst
) == SUBREG
)
1618 if (maybe_ne (SUBREG_BYTE (src
), SUBREG_BYTE (dst
)))
1620 src
= SUBREG_REG (src
);
1621 dst
= SUBREG_REG (dst
);
1624 /* It is a NOOP if destination overlaps with selected src vector
1626 if (GET_CODE (src
) == VEC_SELECT
1627 && REG_P (XEXP (src
, 0)) && REG_P (dst
)
1628 && HARD_REGISTER_P (XEXP (src
, 0))
1629 && HARD_REGISTER_P (dst
))
1632 rtx par
= XEXP (src
, 1);
1633 rtx src0
= XEXP (src
, 0);
1635 if (!poly_int_rtx_p (XVECEXP (par
, 0, 0), &c0
))
1637 poly_int64 offset
= GET_MODE_UNIT_SIZE (GET_MODE (src0
)) * c0
;
1639 for (i
= 1; i
< XVECLEN (par
, 0); i
++)
1642 if (!poly_int_rtx_p (XVECEXP (par
, 0, i
), &c0i
)
1643 || maybe_ne (c0i
, c0
+ i
))
1647 REG_CAN_CHANGE_MODE_P (REGNO (dst
), GET_MODE (src0
), GET_MODE (dst
))
1648 && simplify_subreg_regno (REGNO (src0
), GET_MODE (src0
),
1649 offset
, GET_MODE (dst
)) == (int) REGNO (dst
);
1652 return (REG_P (src
) && REG_P (dst
)
1653 && REGNO (src
) == REGNO (dst
));
1656 /* Return nonzero if an insn consists only of SETs, each of which only sets a
1660 noop_move_p (const rtx_insn
*insn
)
1662 rtx pat
= PATTERN (insn
);
1664 if (INSN_CODE (insn
) == NOOP_MOVE_INSN_CODE
)
1667 /* Insns carrying these notes are useful later on. */
1668 if (find_reg_note (insn
, REG_EQUAL
, NULL_RTX
))
1671 /* Check the code to be executed for COND_EXEC. */
1672 if (GET_CODE (pat
) == COND_EXEC
)
1673 pat
= COND_EXEC_CODE (pat
);
1675 if (GET_CODE (pat
) == SET
&& set_noop_p (pat
))
1678 if (GET_CODE (pat
) == PARALLEL
)
1681 /* If nothing but SETs of registers to themselves,
1682 this insn can also be deleted. */
1683 for (i
= 0; i
< XVECLEN (pat
, 0); i
++)
1685 rtx tem
= XVECEXP (pat
, 0, i
);
1687 if (GET_CODE (tem
) == USE
|| GET_CODE (tem
) == CLOBBER
)
1690 if (GET_CODE (tem
) != SET
|| ! set_noop_p (tem
))
1700 /* Return nonzero if register in range [REGNO, ENDREGNO)
1701 appears either explicitly or implicitly in X
1702 other than being stored into.
1704 References contained within the substructure at LOC do not count.
1705 LOC may be zero, meaning don't ignore anything. */
1708 refers_to_regno_p (unsigned int regno
, unsigned int endregno
, const_rtx x
,
1712 unsigned int x_regno
;
1717 /* The contents of a REG_NONNEG note is always zero, so we must come here
1718 upon repeat in case the last REG_NOTE is a REG_NONNEG note. */
1722 code
= GET_CODE (x
);
1727 x_regno
= REGNO (x
);
1729 /* If we modifying the stack, frame, or argument pointer, it will
1730 clobber a virtual register. In fact, we could be more precise,
1731 but it isn't worth it. */
1732 if ((x_regno
== STACK_POINTER_REGNUM
1733 || (FRAME_POINTER_REGNUM
!= ARG_POINTER_REGNUM
1734 && x_regno
== ARG_POINTER_REGNUM
)
1735 || x_regno
== FRAME_POINTER_REGNUM
)
1736 && regno
>= FIRST_VIRTUAL_REGISTER
&& regno
<= LAST_VIRTUAL_REGISTER
)
1739 return endregno
> x_regno
&& regno
< END_REGNO (x
);
1742 /* If this is a SUBREG of a hard reg, we can see exactly which
1743 registers are being modified. Otherwise, handle normally. */
1744 if (REG_P (SUBREG_REG (x
))
1745 && REGNO (SUBREG_REG (x
)) < FIRST_PSEUDO_REGISTER
)
1747 unsigned int inner_regno
= subreg_regno (x
);
1748 unsigned int inner_endregno
1749 = inner_regno
+ (inner_regno
< FIRST_PSEUDO_REGISTER
1750 ? subreg_nregs (x
) : 1);
1752 return endregno
> inner_regno
&& regno
< inner_endregno
;
1758 if (&SET_DEST (x
) != loc
1759 /* Note setting a SUBREG counts as referring to the REG it is in for
1760 a pseudo but not for hard registers since we can
1761 treat each word individually. */
1762 && ((GET_CODE (SET_DEST (x
)) == SUBREG
1763 && loc
!= &SUBREG_REG (SET_DEST (x
))
1764 && REG_P (SUBREG_REG (SET_DEST (x
)))
1765 && REGNO (SUBREG_REG (SET_DEST (x
))) >= FIRST_PSEUDO_REGISTER
1766 && refers_to_regno_p (regno
, endregno
,
1767 SUBREG_REG (SET_DEST (x
)), loc
))
1768 || (!REG_P (SET_DEST (x
))
1769 && refers_to_regno_p (regno
, endregno
, SET_DEST (x
), loc
))))
1772 if (code
== CLOBBER
|| loc
== &SET_SRC (x
))
1781 /* X does not match, so try its subexpressions. */
1783 fmt
= GET_RTX_FORMAT (code
);
1784 for (i
= GET_RTX_LENGTH (code
) - 1; i
>= 0; i
--)
1786 if (fmt
[i
] == 'e' && loc
!= &XEXP (x
, i
))
1794 if (refers_to_regno_p (regno
, endregno
, XEXP (x
, i
), loc
))
1797 else if (fmt
[i
] == 'E')
1800 for (j
= XVECLEN (x
, i
) - 1; j
>= 0; j
--)
1801 if (loc
!= &XVECEXP (x
, i
, j
)
1802 && refers_to_regno_p (regno
, endregno
, XVECEXP (x
, i
, j
), loc
))
1809 /* Nonzero if modifying X will affect IN. If X is a register or a SUBREG,
1810 we check if any register number in X conflicts with the relevant register
1811 numbers. If X is a constant, return 0. If X is a MEM, return 1 iff IN
1812 contains a MEM (we don't bother checking for memory addresses that can't
1813 conflict because we expect this to be a rare case. */
1816 reg_overlap_mentioned_p (const_rtx x
, const_rtx in
)
1818 unsigned int regno
, endregno
;
1820 /* If either argument is a constant, then modifying X cannot
1821 affect IN. Here we look at IN, we can profitably combine
1822 CONSTANT_P (x) with the switch statement below. */
1823 if (CONSTANT_P (in
))
1827 switch (GET_CODE (x
))
1830 case STRICT_LOW_PART
:
1833 /* Overly conservative. */
1838 regno
= REGNO (SUBREG_REG (x
));
1839 if (regno
< FIRST_PSEUDO_REGISTER
)
1840 regno
= subreg_regno (x
);
1841 endregno
= regno
+ (regno
< FIRST_PSEUDO_REGISTER
1842 ? subreg_nregs (x
) : 1);
1847 endregno
= END_REGNO (x
);
1849 return refers_to_regno_p (regno
, endregno
, in
, (rtx
*) 0);
1859 fmt
= GET_RTX_FORMAT (GET_CODE (in
));
1860 for (i
= GET_RTX_LENGTH (GET_CODE (in
)) - 1; i
>= 0; i
--)
1863 if (reg_overlap_mentioned_p (x
, XEXP (in
, i
)))
1866 else if (fmt
[i
] == 'E')
1869 for (j
= XVECLEN (in
, i
) - 1; j
>= 0; --j
)
1870 if (reg_overlap_mentioned_p (x
, XVECEXP (in
, i
, j
)))
1880 return reg_mentioned_p (x
, in
);
1886 /* If any register in here refers to it we return true. */
1887 for (i
= XVECLEN (x
, 0) - 1; i
>= 0; i
--)
1888 if (XEXP (XVECEXP (x
, 0, i
), 0) != 0
1889 && reg_overlap_mentioned_p (XEXP (XVECEXP (x
, 0, i
), 0), in
))
1895 gcc_assert (CONSTANT_P (x
));
1900 /* Call FUN on each register or MEM that is stored into or clobbered by X.
1901 (X would be the pattern of an insn). DATA is an arbitrary pointer,
1902 ignored by note_stores, but passed to FUN.
1904 FUN receives three arguments:
1905 1. the REG, MEM, CC0 or PC being stored in or clobbered,
1906 2. the SET or CLOBBER rtx that does the store,
1907 3. the pointer DATA provided to note_stores.
1909 If the item being stored in or clobbered is a SUBREG of a hard register,
1910 the SUBREG will be passed. */
1913 note_pattern_stores (const_rtx x
,
1914 void (*fun
) (rtx
, const_rtx
, void *), void *data
)
1918 if (GET_CODE (x
) == COND_EXEC
)
1919 x
= COND_EXEC_CODE (x
);
1921 if (GET_CODE (x
) == SET
|| GET_CODE (x
) == CLOBBER
)
1923 rtx dest
= SET_DEST (x
);
1925 while ((GET_CODE (dest
) == SUBREG
1926 && (!REG_P (SUBREG_REG (dest
))
1927 || REGNO (SUBREG_REG (dest
)) >= FIRST_PSEUDO_REGISTER
))
1928 || GET_CODE (dest
) == ZERO_EXTRACT
1929 || GET_CODE (dest
) == STRICT_LOW_PART
)
1930 dest
= XEXP (dest
, 0);
1932 /* If we have a PARALLEL, SET_DEST is a list of EXPR_LIST expressions,
1933 each of whose first operand is a register. */
1934 if (GET_CODE (dest
) == PARALLEL
)
1936 for (i
= XVECLEN (dest
, 0) - 1; i
>= 0; i
--)
1937 if (XEXP (XVECEXP (dest
, 0, i
), 0) != 0)
1938 (*fun
) (XEXP (XVECEXP (dest
, 0, i
), 0), x
, data
);
1941 (*fun
) (dest
, x
, data
);
1944 else if (GET_CODE (x
) == PARALLEL
)
1945 for (i
= XVECLEN (x
, 0) - 1; i
>= 0; i
--)
1946 note_pattern_stores (XVECEXP (x
, 0, i
), fun
, data
);
1949 /* Same, but for an instruction. If the instruction is a call, include
1950 any CLOBBERs in its CALL_INSN_FUNCTION_USAGE. */
1953 note_stores (const rtx_insn
*insn
,
1954 void (*fun
) (rtx
, const_rtx
, void *), void *data
)
1957 for (rtx link
= CALL_INSN_FUNCTION_USAGE (insn
);
1958 link
; link
= XEXP (link
, 1))
1959 if (GET_CODE (XEXP (link
, 0)) == CLOBBER
)
1960 note_pattern_stores (XEXP (link
, 0), fun
, data
);
1961 note_pattern_stores (PATTERN (insn
), fun
, data
);
1964 /* Like notes_stores, but call FUN for each expression that is being
1965 referenced in PBODY, a pointer to the PATTERN of an insn. We only call
1966 FUN for each expression, not any interior subexpressions. FUN receives a
1967 pointer to the expression and the DATA passed to this function.
1969 Note that this is not quite the same test as that done in reg_referenced_p
1970 since that considers something as being referenced if it is being
1971 partially set, while we do not. */
1974 note_uses (rtx
*pbody
, void (*fun
) (rtx
*, void *), void *data
)
1979 switch (GET_CODE (body
))
1982 (*fun
) (&COND_EXEC_TEST (body
), data
);
1983 note_uses (&COND_EXEC_CODE (body
), fun
, data
);
1987 for (i
= XVECLEN (body
, 0) - 1; i
>= 0; i
--)
1988 note_uses (&XVECEXP (body
, 0, i
), fun
, data
);
1992 for (i
= XVECLEN (body
, 0) - 1; i
>= 0; i
--)
1993 note_uses (&PATTERN (XVECEXP (body
, 0, i
)), fun
, data
);
1997 (*fun
) (&XEXP (body
, 0), data
);
2001 for (i
= ASM_OPERANDS_INPUT_LENGTH (body
) - 1; i
>= 0; i
--)
2002 (*fun
) (&ASM_OPERANDS_INPUT (body
, i
), data
);
2006 (*fun
) (&TRAP_CONDITION (body
), data
);
2010 (*fun
) (&XEXP (body
, 0), data
);
2014 case UNSPEC_VOLATILE
:
2015 for (i
= XVECLEN (body
, 0) - 1; i
>= 0; i
--)
2016 (*fun
) (&XVECEXP (body
, 0, i
), data
);
2020 if (MEM_P (XEXP (body
, 0)))
2021 (*fun
) (&XEXP (XEXP (body
, 0), 0), data
);
2026 rtx dest
= SET_DEST (body
);
2028 /* For sets we replace everything in source plus registers in memory
2029 expression in store and operands of a ZERO_EXTRACT. */
2030 (*fun
) (&SET_SRC (body
), data
);
2032 if (GET_CODE (dest
) == ZERO_EXTRACT
)
2034 (*fun
) (&XEXP (dest
, 1), data
);
2035 (*fun
) (&XEXP (dest
, 2), data
);
2038 while (GET_CODE (dest
) == SUBREG
|| GET_CODE (dest
) == STRICT_LOW_PART
)
2039 dest
= XEXP (dest
, 0);
2042 (*fun
) (&XEXP (dest
, 0), data
);
2047 /* All the other possibilities never store. */
2048 (*fun
) (pbody
, data
);
2053 /* Return nonzero if X's old contents don't survive after INSN.
2054 This will be true if X is (cc0) or if X is a register and
2055 X dies in INSN or because INSN entirely sets X.
2057 "Entirely set" means set directly and not through a SUBREG, or
2058 ZERO_EXTRACT, so no trace of the old contents remains.
2059 Likewise, REG_INC does not count.
2061 REG may be a hard or pseudo reg. Renumbering is not taken into account,
2062 but for this use that makes no difference, since regs don't overlap
2063 during their lifetimes. Therefore, this function may be used
2064 at any time after deaths have been computed.
2066 If REG is a hard reg that occupies multiple machine registers, this
2067 function will only return 1 if each of those registers will be replaced
2071 dead_or_set_p (const rtx_insn
*insn
, const_rtx x
)
2073 unsigned int regno
, end_regno
;
2076 /* Can't use cc0_rtx below since this file is used by genattrtab.c. */
2077 if (GET_CODE (x
) == CC0
)
2080 gcc_assert (REG_P (x
));
2083 end_regno
= END_REGNO (x
);
2084 for (i
= regno
; i
< end_regno
; i
++)
2085 if (! dead_or_set_regno_p (insn
, i
))
2091 /* Return TRUE iff DEST is a register or subreg of a register, is a
2092 complete rather than read-modify-write destination, and contains
2093 register TEST_REGNO. */
2096 covers_regno_no_parallel_p (const_rtx dest
, unsigned int test_regno
)
2098 unsigned int regno
, endregno
;
2100 if (GET_CODE (dest
) == SUBREG
&& !read_modify_subreg_p (dest
))
2101 dest
= SUBREG_REG (dest
);
2106 regno
= REGNO (dest
);
2107 endregno
= END_REGNO (dest
);
2108 return (test_regno
>= regno
&& test_regno
< endregno
);
2111 /* Like covers_regno_no_parallel_p, but also handles PARALLELs where
2112 any member matches the covers_regno_no_parallel_p criteria. */
2115 covers_regno_p (const_rtx dest
, unsigned int test_regno
)
2117 if (GET_CODE (dest
) == PARALLEL
)
2119 /* Some targets place small structures in registers for return
2120 values of functions, and those registers are wrapped in
2121 PARALLELs that we may see as the destination of a SET. */
2124 for (i
= XVECLEN (dest
, 0) - 1; i
>= 0; i
--)
2126 rtx inner
= XEXP (XVECEXP (dest
, 0, i
), 0);
2127 if (inner
!= NULL_RTX
2128 && covers_regno_no_parallel_p (inner
, test_regno
))
2135 return covers_regno_no_parallel_p (dest
, test_regno
);
2138 /* Utility function for dead_or_set_p to check an individual register. */
2141 dead_or_set_regno_p (const rtx_insn
*insn
, unsigned int test_regno
)
2145 /* See if there is a death note for something that includes TEST_REGNO. */
2146 if (find_regno_note (insn
, REG_DEAD
, test_regno
))
2150 && find_regno_fusage (insn
, CLOBBER
, test_regno
))
2153 pattern
= PATTERN (insn
);
2155 /* If a COND_EXEC is not executed, the value survives. */
2156 if (GET_CODE (pattern
) == COND_EXEC
)
2159 if (GET_CODE (pattern
) == SET
|| GET_CODE (pattern
) == CLOBBER
)
2160 return covers_regno_p (SET_DEST (pattern
), test_regno
);
2161 else if (GET_CODE (pattern
) == PARALLEL
)
2165 for (i
= XVECLEN (pattern
, 0) - 1; i
>= 0; i
--)
2167 rtx body
= XVECEXP (pattern
, 0, i
);
2169 if (GET_CODE (body
) == COND_EXEC
)
2170 body
= COND_EXEC_CODE (body
);
2172 if ((GET_CODE (body
) == SET
|| GET_CODE (body
) == CLOBBER
)
2173 && covers_regno_p (SET_DEST (body
), test_regno
))
2181 /* Return the reg-note of kind KIND in insn INSN, if there is one.
2182 If DATUM is nonzero, look for one whose datum is DATUM. */
2185 find_reg_note (const_rtx insn
, enum reg_note kind
, const_rtx datum
)
2189 gcc_checking_assert (insn
);
2191 /* Ignore anything that is not an INSN, JUMP_INSN or CALL_INSN. */
2192 if (! INSN_P (insn
))
2196 for (link
= REG_NOTES (insn
); link
; link
= XEXP (link
, 1))
2197 if (REG_NOTE_KIND (link
) == kind
)
2202 for (link
= REG_NOTES (insn
); link
; link
= XEXP (link
, 1))
2203 if (REG_NOTE_KIND (link
) == kind
&& datum
== XEXP (link
, 0))
2208 /* Return the reg-note of kind KIND in insn INSN which applies to register
2209 number REGNO, if any. Return 0 if there is no such reg-note. Note that
2210 the REGNO of this NOTE need not be REGNO if REGNO is a hard register;
2211 it might be the case that the note overlaps REGNO. */
2214 find_regno_note (const_rtx insn
, enum reg_note kind
, unsigned int regno
)
2218 /* Ignore anything that is not an INSN, JUMP_INSN or CALL_INSN. */
2219 if (! INSN_P (insn
))
2222 for (link
= REG_NOTES (insn
); link
; link
= XEXP (link
, 1))
2223 if (REG_NOTE_KIND (link
) == kind
2224 /* Verify that it is a register, so that scratch and MEM won't cause a
2226 && REG_P (XEXP (link
, 0))
2227 && REGNO (XEXP (link
, 0)) <= regno
2228 && END_REGNO (XEXP (link
, 0)) > regno
)
2233 /* Return a REG_EQUIV or REG_EQUAL note if insn has only a single set and
2237 find_reg_equal_equiv_note (const_rtx insn
)
2244 for (link
= REG_NOTES (insn
); link
; link
= XEXP (link
, 1))
2245 if (REG_NOTE_KIND (link
) == REG_EQUAL
2246 || REG_NOTE_KIND (link
) == REG_EQUIV
)
2248 /* FIXME: We should never have REG_EQUAL/REG_EQUIV notes on
2249 insns that have multiple sets. Checking single_set to
2250 make sure of this is not the proper check, as explained
2251 in the comment in set_unique_reg_note.
2253 This should be changed into an assert. */
2254 if (GET_CODE (PATTERN (insn
)) == PARALLEL
&& multiple_sets (insn
))
2261 /* Check whether INSN is a single_set whose source is known to be
2262 equivalent to a constant. Return that constant if so, otherwise
2266 find_constant_src (const rtx_insn
*insn
)
2270 set
= single_set (insn
);
2273 x
= avoid_constant_pool_reference (SET_SRC (set
));
2278 note
= find_reg_equal_equiv_note (insn
);
2279 if (note
&& CONSTANT_P (XEXP (note
, 0)))
2280 return XEXP (note
, 0);
2285 /* Return true if DATUM, or any overlap of DATUM, of kind CODE is found
2286 in the CALL_INSN_FUNCTION_USAGE information of INSN. */
2289 find_reg_fusage (const_rtx insn
, enum rtx_code code
, const_rtx datum
)
2291 /* If it's not a CALL_INSN, it can't possibly have a
2292 CALL_INSN_FUNCTION_USAGE field, so don't bother checking. */
2302 for (link
= CALL_INSN_FUNCTION_USAGE (insn
);
2304 link
= XEXP (link
, 1))
2305 if (GET_CODE (XEXP (link
, 0)) == code
2306 && rtx_equal_p (datum
, XEXP (XEXP (link
, 0), 0)))
2311 unsigned int regno
= REGNO (datum
);
2313 /* CALL_INSN_FUNCTION_USAGE information cannot contain references
2314 to pseudo registers, so don't bother checking. */
2316 if (regno
< FIRST_PSEUDO_REGISTER
)
2318 unsigned int end_regno
= END_REGNO (datum
);
2321 for (i
= regno
; i
< end_regno
; i
++)
2322 if (find_regno_fusage (insn
, code
, i
))
2330 /* Return true if REGNO, or any overlap of REGNO, of kind CODE is found
2331 in the CALL_INSN_FUNCTION_USAGE information of INSN. */
2334 find_regno_fusage (const_rtx insn
, enum rtx_code code
, unsigned int regno
)
2338 /* CALL_INSN_FUNCTION_USAGE information cannot contain references
2339 to pseudo registers, so don't bother checking. */
2341 if (regno
>= FIRST_PSEUDO_REGISTER
2345 for (link
= CALL_INSN_FUNCTION_USAGE (insn
); link
; link
= XEXP (link
, 1))
2349 if (GET_CODE (op
= XEXP (link
, 0)) == code
2350 && REG_P (reg
= XEXP (op
, 0))
2351 && REGNO (reg
) <= regno
2352 && END_REGNO (reg
) > regno
)
2360 /* Return true if KIND is an integer REG_NOTE. */
2363 int_reg_note_p (enum reg_note kind
)
2365 return kind
== REG_BR_PROB
;
2368 /* Allocate a register note with kind KIND and datum DATUM. LIST is
2369 stored as the pointer to the next register note. */
2372 alloc_reg_note (enum reg_note kind
, rtx datum
, rtx list
)
2376 gcc_checking_assert (!int_reg_note_p (kind
));
2381 case REG_LABEL_TARGET
:
2382 case REG_LABEL_OPERAND
:
2384 /* These types of register notes use an INSN_LIST rather than an
2385 EXPR_LIST, so that copying is done right and dumps look
2387 note
= alloc_INSN_LIST (datum
, list
);
2388 PUT_REG_NOTE_KIND (note
, kind
);
2392 note
= alloc_EXPR_LIST (kind
, datum
, list
);
2399 /* Add register note with kind KIND and datum DATUM to INSN. */
2402 add_reg_note (rtx insn
, enum reg_note kind
, rtx datum
)
2404 REG_NOTES (insn
) = alloc_reg_note (kind
, datum
, REG_NOTES (insn
));
2407 /* Add an integer register note with kind KIND and datum DATUM to INSN. */
2410 add_int_reg_note (rtx_insn
*insn
, enum reg_note kind
, int datum
)
2412 gcc_checking_assert (int_reg_note_p (kind
));
2413 REG_NOTES (insn
) = gen_rtx_INT_LIST ((machine_mode
) kind
,
2414 datum
, REG_NOTES (insn
));
2417 /* Add a REG_ARGS_SIZE note to INSN with value VALUE. */
2420 add_args_size_note (rtx_insn
*insn
, poly_int64 value
)
2422 gcc_checking_assert (!find_reg_note (insn
, REG_ARGS_SIZE
, NULL_RTX
));
2423 add_reg_note (insn
, REG_ARGS_SIZE
, gen_int_mode (value
, Pmode
));
2426 /* Add a register note like NOTE to INSN. */
2429 add_shallow_copy_of_reg_note (rtx_insn
*insn
, rtx note
)
2431 if (GET_CODE (note
) == INT_LIST
)
2432 add_int_reg_note (insn
, REG_NOTE_KIND (note
), XINT (note
, 0));
2434 add_reg_note (insn
, REG_NOTE_KIND (note
), XEXP (note
, 0));
2437 /* Duplicate NOTE and return the copy. */
2439 duplicate_reg_note (rtx note
)
2441 reg_note kind
= REG_NOTE_KIND (note
);
2443 if (GET_CODE (note
) == INT_LIST
)
2444 return gen_rtx_INT_LIST ((machine_mode
) kind
, XINT (note
, 0), NULL_RTX
);
2445 else if (GET_CODE (note
) == EXPR_LIST
)
2446 return alloc_reg_note (kind
, copy_insn_1 (XEXP (note
, 0)), NULL_RTX
);
2448 return alloc_reg_note (kind
, XEXP (note
, 0), NULL_RTX
);
2451 /* Remove register note NOTE from the REG_NOTES of INSN. */
2454 remove_note (rtx_insn
*insn
, const_rtx note
)
2458 if (note
== NULL_RTX
)
2461 if (REG_NOTES (insn
) == note
)
2462 REG_NOTES (insn
) = XEXP (note
, 1);
2464 for (link
= REG_NOTES (insn
); link
; link
= XEXP (link
, 1))
2465 if (XEXP (link
, 1) == note
)
2467 XEXP (link
, 1) = XEXP (note
, 1);
2471 switch (REG_NOTE_KIND (note
))
2475 df_notes_rescan (insn
);
2482 /* Remove REG_EQUAL and/or REG_EQUIV notes if INSN has such notes.
2483 If NO_RESCAN is false and any notes were removed, call
2484 df_notes_rescan. Return true if any note has been removed. */
2487 remove_reg_equal_equiv_notes (rtx_insn
*insn
, bool no_rescan
)
2492 loc
= ®_NOTES (insn
);
2495 enum reg_note kind
= REG_NOTE_KIND (*loc
);
2496 if (kind
== REG_EQUAL
|| kind
== REG_EQUIV
)
2498 *loc
= XEXP (*loc
, 1);
2502 loc
= &XEXP (*loc
, 1);
2504 if (ret
&& !no_rescan
)
2505 df_notes_rescan (insn
);
2509 /* Remove all REG_EQUAL and REG_EQUIV notes referring to REGNO. */
2512 remove_reg_equal_equiv_notes_for_regno (unsigned int regno
)
2519 /* This loop is a little tricky. We cannot just go down the chain because
2520 it is being modified by some actions in the loop. So we just iterate
2521 over the head. We plan to drain the list anyway. */
2522 while ((eq_use
= DF_REG_EQ_USE_CHAIN (regno
)) != NULL
)
2524 rtx_insn
*insn
= DF_REF_INSN (eq_use
);
2525 rtx note
= find_reg_equal_equiv_note (insn
);
2527 /* This assert is generally triggered when someone deletes a REG_EQUAL
2528 or REG_EQUIV note by hacking the list manually rather than calling
2532 remove_note (insn
, note
);
2536 /* Search LISTP (an EXPR_LIST) for an entry whose first operand is NODE and
2537 return 1 if it is found. A simple equality test is used to determine if
2541 in_insn_list_p (const rtx_insn_list
*listp
, const rtx_insn
*node
)
2545 for (x
= listp
; x
; x
= XEXP (x
, 1))
2546 if (node
== XEXP (x
, 0))
2552 /* Search LISTP (an EXPR_LIST) for an entry whose first operand is NODE and
2553 remove that entry from the list if it is found.
2555 A simple equality test is used to determine if NODE matches. */
2558 remove_node_from_expr_list (const_rtx node
, rtx_expr_list
**listp
)
2560 rtx_expr_list
*temp
= *listp
;
2561 rtx_expr_list
*prev
= NULL
;
2565 if (node
== temp
->element ())
2567 /* Splice the node out of the list. */
2569 XEXP (prev
, 1) = temp
->next ();
2571 *listp
= temp
->next ();
2577 temp
= temp
->next ();
2581 /* Search LISTP (an INSN_LIST) for an entry whose first operand is NODE and
2582 remove that entry from the list if it is found.
2584 A simple equality test is used to determine if NODE matches. */
2587 remove_node_from_insn_list (const rtx_insn
*node
, rtx_insn_list
**listp
)
2589 rtx_insn_list
*temp
= *listp
;
2590 rtx_insn_list
*prev
= NULL
;
2594 if (node
== temp
->insn ())
2596 /* Splice the node out of the list. */
2598 XEXP (prev
, 1) = temp
->next ();
2600 *listp
= temp
->next ();
2606 temp
= temp
->next ();
2610 /* Nonzero if X contains any volatile instructions. These are instructions
2611 which may cause unpredictable machine state instructions, and thus no
2612 instructions or register uses should be moved or combined across them.
2613 This includes only volatile asms and UNSPEC_VOLATILE instructions. */
2616 volatile_insn_p (const_rtx x
)
2618 const RTX_CODE code
= GET_CODE (x
);
2636 case UNSPEC_VOLATILE
:
2641 if (MEM_VOLATILE_P (x
))
2648 /* Recursively scan the operands of this expression. */
2651 const char *const fmt
= GET_RTX_FORMAT (code
);
2654 for (i
= GET_RTX_LENGTH (code
) - 1; i
>= 0; i
--)
2658 if (volatile_insn_p (XEXP (x
, i
)))
2661 else if (fmt
[i
] == 'E')
2664 for (j
= 0; j
< XVECLEN (x
, i
); j
++)
2665 if (volatile_insn_p (XVECEXP (x
, i
, j
)))
2673 /* Nonzero if X contains any volatile memory references
2674 UNSPEC_VOLATILE operations or volatile ASM_OPERANDS expressions. */
2677 volatile_refs_p (const_rtx x
)
2679 const RTX_CODE code
= GET_CODE (x
);
2695 case UNSPEC_VOLATILE
:
2701 if (MEM_VOLATILE_P (x
))
2708 /* Recursively scan the operands of this expression. */
2711 const char *const fmt
= GET_RTX_FORMAT (code
);
2714 for (i
= GET_RTX_LENGTH (code
) - 1; i
>= 0; i
--)
2718 if (volatile_refs_p (XEXP (x
, i
)))
2721 else if (fmt
[i
] == 'E')
2724 for (j
= 0; j
< XVECLEN (x
, i
); j
++)
2725 if (volatile_refs_p (XVECEXP (x
, i
, j
)))
2733 /* Similar to above, except that it also rejects register pre- and post-
2737 side_effects_p (const_rtx x
)
2739 const RTX_CODE code
= GET_CODE (x
);
2756 /* Reject CLOBBER with a non-VOID mode. These are made by combine.c
2757 when some combination can't be done. If we see one, don't think
2758 that we can simplify the expression. */
2759 return (GET_MODE (x
) != VOIDmode
);
2768 case UNSPEC_VOLATILE
:
2774 if (MEM_VOLATILE_P (x
))
2781 /* Recursively scan the operands of this expression. */
2784 const char *fmt
= GET_RTX_FORMAT (code
);
2787 for (i
= GET_RTX_LENGTH (code
) - 1; i
>= 0; i
--)
2791 if (side_effects_p (XEXP (x
, i
)))
2794 else if (fmt
[i
] == 'E')
2797 for (j
= 0; j
< XVECLEN (x
, i
); j
++)
2798 if (side_effects_p (XVECEXP (x
, i
, j
)))
2806 /* Return nonzero if evaluating rtx X might cause a trap.
2807 FLAGS controls how to consider MEMs. A nonzero means the context
2808 of the access may have changed from the original, such that the
2809 address may have become invalid. */
2812 may_trap_p_1 (const_rtx x
, unsigned flags
)
2818 /* We make no distinction currently, but this function is part of
2819 the internal target-hooks ABI so we keep the parameter as
2820 "unsigned flags". */
2821 bool code_changed
= flags
!= 0;
2825 code
= GET_CODE (x
);
2828 /* Handle these cases quickly. */
2840 return targetm
.unspec_may_trap_p (x
, flags
);
2842 case UNSPEC_VOLATILE
:
2848 return MEM_VOLATILE_P (x
);
2850 /* Memory ref can trap unless it's a static var or a stack slot. */
2852 /* Recognize specific pattern of stack checking probes. */
2853 if (flag_stack_check
2854 && MEM_VOLATILE_P (x
)
2855 && XEXP (x
, 0) == stack_pointer_rtx
)
2857 if (/* MEM_NOTRAP_P only relates to the actual position of the memory
2858 reference; moving it out of context such as when moving code
2859 when optimizing, might cause its address to become invalid. */
2861 || !MEM_NOTRAP_P (x
))
2863 poly_int64 size
= MEM_SIZE_KNOWN_P (x
) ? MEM_SIZE (x
) : -1;
2864 return rtx_addr_can_trap_p_1 (XEXP (x
, 0), 0, size
,
2865 GET_MODE (x
), code_changed
);
2870 /* Division by a non-constant might trap. */
2875 if (HONOR_SNANS (x
))
2877 if (FLOAT_MODE_P (GET_MODE (x
)))
2878 return flag_trapping_math
;
2879 if (!CONSTANT_P (XEXP (x
, 1)) || (XEXP (x
, 1) == const0_rtx
))
2881 if (GET_CODE (XEXP (x
, 1)) == CONST_VECTOR
)
2883 /* For CONST_VECTOR, return 1 if any element is or might be zero. */
2884 unsigned int n_elts
;
2885 rtx op
= XEXP (x
, 1);
2886 if (!GET_MODE_NUNITS (GET_MODE (op
)).is_constant (&n_elts
))
2888 if (!CONST_VECTOR_DUPLICATE_P (op
))
2890 for (unsigned i
= 0; i
< (unsigned int) XVECLEN (op
, 0); i
++)
2891 if (CONST_VECTOR_ENCODED_ELT (op
, i
) == const0_rtx
)
2895 for (unsigned i
= 0; i
< n_elts
; i
++)
2896 if (CONST_VECTOR_ELT (op
, i
) == const0_rtx
)
2902 /* An EXPR_LIST is used to represent a function call. This
2903 certainly may trap. */
2912 /* Some floating point comparisons may trap. */
2913 if (!flag_trapping_math
)
2915 /* ??? There is no machine independent way to check for tests that trap
2916 when COMPARE is used, though many targets do make this distinction.
2917 For instance, sparc uses CCFPE for compares which generate exceptions
2918 and CCFP for compares which do not generate exceptions. */
2921 /* But often the compare has some CC mode, so check operand
2923 if (HONOR_NANS (XEXP (x
, 0))
2924 || HONOR_NANS (XEXP (x
, 1)))
2930 if (HONOR_SNANS (x
))
2932 /* Often comparison is CC mode, so check operand modes. */
2933 if (HONOR_SNANS (XEXP (x
, 0))
2934 || HONOR_SNANS (XEXP (x
, 1)))
2939 /* Conversion of floating point might trap. */
2940 if (flag_trapping_math
&& HONOR_NANS (XEXP (x
, 0)))
2951 /* These operations don't trap even with floating point. */
2955 /* Any floating arithmetic may trap. */
2956 if (FLOAT_MODE_P (GET_MODE (x
)) && flag_trapping_math
)
2960 fmt
= GET_RTX_FORMAT (code
);
2961 for (i
= GET_RTX_LENGTH (code
) - 1; i
>= 0; i
--)
2965 if (may_trap_p_1 (XEXP (x
, i
), flags
))
2968 else if (fmt
[i
] == 'E')
2971 for (j
= 0; j
< XVECLEN (x
, i
); j
++)
2972 if (may_trap_p_1 (XVECEXP (x
, i
, j
), flags
))
2979 /* Return nonzero if evaluating rtx X might cause a trap. */
2982 may_trap_p (const_rtx x
)
2984 return may_trap_p_1 (x
, 0);
2987 /* Same as above, but additionally return nonzero if evaluating rtx X might
2988 cause a fault. We define a fault for the purpose of this function as a
2989 erroneous execution condition that cannot be encountered during the normal
2990 execution of a valid program; the typical example is an unaligned memory
2991 access on a strict alignment machine. The compiler guarantees that it
2992 doesn't generate code that will fault from a valid program, but this
2993 guarantee doesn't mean anything for individual instructions. Consider
2994 the following example:
2996 struct S { int d; union { char *cp; int *ip; }; };
2998 int foo(struct S *s)
3006 on a strict alignment machine. In a valid program, foo will never be
3007 invoked on a structure for which d is equal to 1 and the underlying
3008 unique field of the union not aligned on a 4-byte boundary, but the
3009 expression *s->ip might cause a fault if considered individually.
3011 At the RTL level, potentially problematic expressions will almost always
3012 verify may_trap_p; for example, the above dereference can be emitted as
3013 (mem:SI (reg:P)) and this expression is may_trap_p for a generic register.
3014 However, suppose that foo is inlined in a caller that causes s->cp to
3015 point to a local character variable and guarantees that s->d is not set
3016 to 1; foo may have been effectively translated into pseudo-RTL as:
3019 (set (reg:SI) (mem:SI (%fp - 7)))
3021 (set (reg:QI) (mem:QI (%fp - 7)))
3023 Now (mem:SI (%fp - 7)) is considered as not may_trap_p since it is a
3024 memory reference to a stack slot, but it will certainly cause a fault
3025 on a strict alignment machine. */
3028 may_trap_or_fault_p (const_rtx x
)
3030 return may_trap_p_1 (x
, 1);
3033 /* Replace any occurrence of FROM in X with TO. The function does
3034 not enter into CONST_DOUBLE for the replace.
3036 Note that copying is not done so X must not be shared unless all copies
3039 ALL_REGS is true if we want to replace all REGs equal to FROM, not just
3040 those pointer-equal ones. */
3043 replace_rtx (rtx x
, rtx from
, rtx to
, bool all_regs
)
3051 /* Allow this function to make replacements in EXPR_LISTs. */
3058 && REGNO (x
) == REGNO (from
))
3060 gcc_assert (GET_MODE (x
) == GET_MODE (from
));
3063 else if (GET_CODE (x
) == SUBREG
)
3065 rtx new_rtx
= replace_rtx (SUBREG_REG (x
), from
, to
, all_regs
);
3067 if (CONST_INT_P (new_rtx
))
3069 x
= simplify_subreg (GET_MODE (x
), new_rtx
,
3070 GET_MODE (SUBREG_REG (x
)),
3075 SUBREG_REG (x
) = new_rtx
;
3079 else if (GET_CODE (x
) == ZERO_EXTEND
)
3081 rtx new_rtx
= replace_rtx (XEXP (x
, 0), from
, to
, all_regs
);
3083 if (CONST_INT_P (new_rtx
))
3085 x
= simplify_unary_operation (ZERO_EXTEND
, GET_MODE (x
),
3086 new_rtx
, GET_MODE (XEXP (x
, 0)));
3090 XEXP (x
, 0) = new_rtx
;
3095 fmt
= GET_RTX_FORMAT (GET_CODE (x
));
3096 for (i
= GET_RTX_LENGTH (GET_CODE (x
)) - 1; i
>= 0; i
--)
3099 XEXP (x
, i
) = replace_rtx (XEXP (x
, i
), from
, to
, all_regs
);
3100 else if (fmt
[i
] == 'E')
3101 for (j
= XVECLEN (x
, i
) - 1; j
>= 0; j
--)
3102 XVECEXP (x
, i
, j
) = replace_rtx (XVECEXP (x
, i
, j
),
3103 from
, to
, all_regs
);
3109 /* Replace occurrences of the OLD_LABEL in *LOC with NEW_LABEL. Also track
3110 the change in LABEL_NUSES if UPDATE_LABEL_NUSES. */
3113 replace_label (rtx
*loc
, rtx old_label
, rtx new_label
, bool update_label_nuses
)
3115 /* Handle jump tables specially, since ADDR_{DIFF_,}VECs can be long. */
3117 if (JUMP_TABLE_DATA_P (x
))
3120 rtvec vec
= XVEC (x
, GET_CODE (x
) == ADDR_DIFF_VEC
);
3121 int len
= GET_NUM_ELEM (vec
);
3122 for (int i
= 0; i
< len
; ++i
)
3124 rtx ref
= RTVEC_ELT (vec
, i
);
3125 if (XEXP (ref
, 0) == old_label
)
3127 XEXP (ref
, 0) = new_label
;
3128 if (update_label_nuses
)
3130 ++LABEL_NUSES (new_label
);
3131 --LABEL_NUSES (old_label
);
3138 /* If this is a JUMP_INSN, then we also need to fix the JUMP_LABEL
3139 field. This is not handled by the iterator because it doesn't
3140 handle unprinted ('0') fields. */
3141 if (JUMP_P (x
) && JUMP_LABEL (x
) == old_label
)
3142 JUMP_LABEL (x
) = new_label
;
3144 subrtx_ptr_iterator::array_type array
;
3145 FOR_EACH_SUBRTX_PTR (iter
, array
, loc
, ALL
)
3150 if (GET_CODE (x
) == SYMBOL_REF
3151 && CONSTANT_POOL_ADDRESS_P (x
))
3153 rtx c
= get_pool_constant (x
);
3154 if (rtx_referenced_p (old_label
, c
))
3156 /* Create a copy of constant C; replace the label inside
3157 but do not update LABEL_NUSES because uses in constant pool
3159 rtx new_c
= copy_rtx (c
);
3160 replace_label (&new_c
, old_label
, new_label
, false);
3162 /* Add the new constant NEW_C to constant pool and replace
3163 the old reference to constant by new reference. */
3164 rtx new_mem
= force_const_mem (get_pool_mode (x
), new_c
);
3165 *loc
= replace_rtx (x
, x
, XEXP (new_mem
, 0));
3169 if ((GET_CODE (x
) == LABEL_REF
3170 || GET_CODE (x
) == INSN_LIST
)
3171 && XEXP (x
, 0) == old_label
)
3173 XEXP (x
, 0) = new_label
;
3174 if (update_label_nuses
)
3176 ++LABEL_NUSES (new_label
);
3177 --LABEL_NUSES (old_label
);
3185 replace_label_in_insn (rtx_insn
*insn
, rtx_insn
*old_label
,
3186 rtx_insn
*new_label
, bool update_label_nuses
)
3188 rtx insn_as_rtx
= insn
;
3189 replace_label (&insn_as_rtx
, old_label
, new_label
, update_label_nuses
);
3190 gcc_checking_assert (insn_as_rtx
== insn
);
3193 /* Return true if X is referenced in BODY. */
3196 rtx_referenced_p (const_rtx x
, const_rtx body
)
3198 subrtx_iterator::array_type array
;
3199 FOR_EACH_SUBRTX (iter
, array
, body
, ALL
)
3200 if (const_rtx y
= *iter
)
3202 /* Check if a label_ref Y refers to label X. */
3203 if (GET_CODE (y
) == LABEL_REF
3205 && label_ref_label (y
) == x
)
3208 if (rtx_equal_p (x
, y
))
3211 /* If Y is a reference to pool constant traverse the constant. */
3212 if (GET_CODE (y
) == SYMBOL_REF
3213 && CONSTANT_POOL_ADDRESS_P (y
))
3214 iter
.substitute (get_pool_constant (y
));
3219 /* If INSN is a tablejump return true and store the label (before jump table) to
3220 *LABELP and the jump table to *TABLEP. LABELP and TABLEP may be NULL. */
3223 tablejump_p (const rtx_insn
*insn
, rtx_insn
**labelp
,
3224 rtx_jump_table_data
**tablep
)
3229 rtx target
= JUMP_LABEL (insn
);
3230 if (target
== NULL_RTX
|| ANY_RETURN_P (target
))
3233 rtx_insn
*label
= as_a
<rtx_insn
*> (target
);
3234 rtx_insn
*table
= next_insn (label
);
3235 if (table
== NULL_RTX
|| !JUMP_TABLE_DATA_P (table
))
3241 *tablep
= as_a
<rtx_jump_table_data
*> (table
);
3245 /* For INSN known to satisfy tablejump_p, determine if it actually is a
3246 CASESI. Return the insn pattern if so, NULL_RTX otherwise. */
3249 tablejump_casesi_pattern (const rtx_insn
*insn
)
3253 if ((tmp
= single_set (insn
)) != NULL
3254 && SET_DEST (tmp
) == pc_rtx
3255 && GET_CODE (SET_SRC (tmp
)) == IF_THEN_ELSE
3256 && GET_CODE (XEXP (SET_SRC (tmp
), 2)) == LABEL_REF
)
3262 /* A subroutine of computed_jump_p, return 1 if X contains a REG or MEM or
3263 constant that is not in the constant pool and not in the condition
3264 of an IF_THEN_ELSE. */
3267 computed_jump_p_1 (const_rtx x
)
3269 const enum rtx_code code
= GET_CODE (x
);
3286 return ! (GET_CODE (XEXP (x
, 0)) == SYMBOL_REF
3287 && CONSTANT_POOL_ADDRESS_P (XEXP (x
, 0)));
3290 return (computed_jump_p_1 (XEXP (x
, 1))
3291 || computed_jump_p_1 (XEXP (x
, 2)));
3297 fmt
= GET_RTX_FORMAT (code
);
3298 for (i
= GET_RTX_LENGTH (code
) - 1; i
>= 0; i
--)
3301 && computed_jump_p_1 (XEXP (x
, i
)))
3304 else if (fmt
[i
] == 'E')
3305 for (j
= 0; j
< XVECLEN (x
, i
); j
++)
3306 if (computed_jump_p_1 (XVECEXP (x
, i
, j
)))
3313 /* Return nonzero if INSN is an indirect jump (aka computed jump).
3315 Tablejumps and casesi insns are not considered indirect jumps;
3316 we can recognize them by a (use (label_ref)). */
3319 computed_jump_p (const rtx_insn
*insn
)
3324 rtx pat
= PATTERN (insn
);
3326 /* If we have a JUMP_LABEL set, we're not a computed jump. */
3327 if (JUMP_LABEL (insn
) != NULL
)
3330 if (GET_CODE (pat
) == PARALLEL
)
3332 int len
= XVECLEN (pat
, 0);
3333 int has_use_labelref
= 0;
3335 for (i
= len
- 1; i
>= 0; i
--)
3336 if (GET_CODE (XVECEXP (pat
, 0, i
)) == USE
3337 && (GET_CODE (XEXP (XVECEXP (pat
, 0, i
), 0))
3340 has_use_labelref
= 1;
3344 if (! has_use_labelref
)
3345 for (i
= len
- 1; i
>= 0; i
--)
3346 if (GET_CODE (XVECEXP (pat
, 0, i
)) == SET
3347 && SET_DEST (XVECEXP (pat
, 0, i
)) == pc_rtx
3348 && computed_jump_p_1 (SET_SRC (XVECEXP (pat
, 0, i
))))
3351 else if (GET_CODE (pat
) == SET
3352 && SET_DEST (pat
) == pc_rtx
3353 && computed_jump_p_1 (SET_SRC (pat
)))
3361 /* MEM has a PRE/POST-INC/DEC/MODIFY address X. Extract the operands of
3362 the equivalent add insn and pass the result to FN, using DATA as the
3366 for_each_inc_dec_find_inc_dec (rtx mem
, for_each_inc_dec_fn fn
, void *data
)
3368 rtx x
= XEXP (mem
, 0);
3369 switch (GET_CODE (x
))
3374 poly_int64 size
= GET_MODE_SIZE (GET_MODE (mem
));
3375 rtx r1
= XEXP (x
, 0);
3376 rtx c
= gen_int_mode (size
, GET_MODE (r1
));
3377 return fn (mem
, x
, r1
, r1
, c
, data
);
3383 poly_int64 size
= GET_MODE_SIZE (GET_MODE (mem
));
3384 rtx r1
= XEXP (x
, 0);
3385 rtx c
= gen_int_mode (-size
, GET_MODE (r1
));
3386 return fn (mem
, x
, r1
, r1
, c
, data
);
3392 rtx r1
= XEXP (x
, 0);
3393 rtx add
= XEXP (x
, 1);
3394 return fn (mem
, x
, r1
, add
, NULL
, data
);
3402 /* Traverse *LOC looking for MEMs that have autoinc addresses.
3403 For each such autoinc operation found, call FN, passing it
3404 the innermost enclosing MEM, the operation itself, the RTX modified
3405 by the operation, two RTXs (the second may be NULL) that, once
3406 added, represent the value to be held by the modified RTX
3407 afterwards, and DATA. FN is to return 0 to continue the
3408 traversal or any other value to have it returned to the caller of
3409 for_each_inc_dec. */
3412 for_each_inc_dec (rtx x
,
3413 for_each_inc_dec_fn fn
,
3416 subrtx_var_iterator::array_type array
;
3417 FOR_EACH_SUBRTX_VAR (iter
, array
, x
, NONCONST
)
3422 && GET_RTX_CLASS (GET_CODE (XEXP (mem
, 0))) == RTX_AUTOINC
)
3424 int res
= for_each_inc_dec_find_inc_dec (mem
, fn
, data
);
3427 iter
.skip_subrtxes ();
3434 /* Searches X for any reference to REGNO, returning the rtx of the
3435 reference found if any. Otherwise, returns NULL_RTX. */
3438 regno_use_in (unsigned int regno
, rtx x
)
3444 if (REG_P (x
) && REGNO (x
) == regno
)
3447 fmt
= GET_RTX_FORMAT (GET_CODE (x
));
3448 for (i
= GET_RTX_LENGTH (GET_CODE (x
)) - 1; i
>= 0; i
--)
3452 if ((tem
= regno_use_in (regno
, XEXP (x
, i
))))
3455 else if (fmt
[i
] == 'E')
3456 for (j
= XVECLEN (x
, i
) - 1; j
>= 0; j
--)
3457 if ((tem
= regno_use_in (regno
, XVECEXP (x
, i
, j
))))
3464 /* Return a value indicating whether OP, an operand of a commutative
3465 operation, is preferred as the first or second operand. The more
3466 positive the value, the stronger the preference for being the first
3470 commutative_operand_precedence (rtx op
)
3472 enum rtx_code code
= GET_CODE (op
);
3474 /* Constants always become the second operand. Prefer "nice" constants. */
3475 if (code
== CONST_INT
)
3477 if (code
== CONST_WIDE_INT
)
3479 if (code
== CONST_POLY_INT
)
3481 if (code
== CONST_DOUBLE
)
3483 if (code
== CONST_FIXED
)
3485 op
= avoid_constant_pool_reference (op
);
3486 code
= GET_CODE (op
);
3488 switch (GET_RTX_CLASS (code
))
3491 if (code
== CONST_INT
)
3493 if (code
== CONST_WIDE_INT
)
3495 if (code
== CONST_POLY_INT
)
3497 if (code
== CONST_DOUBLE
)
3499 if (code
== CONST_FIXED
)
3504 /* SUBREGs of objects should come second. */
3505 if (code
== SUBREG
&& OBJECT_P (SUBREG_REG (op
)))
3510 /* Complex expressions should be the first, so decrease priority
3511 of objects. Prefer pointer objects over non pointer objects. */
3512 if ((REG_P (op
) && REG_POINTER (op
))
3513 || (MEM_P (op
) && MEM_POINTER (op
)))
3517 case RTX_COMM_ARITH
:
3518 /* Prefer operands that are themselves commutative to be first.
3519 This helps to make things linear. In particular,
3520 (and (and (reg) (reg)) (not (reg))) is canonical. */
3524 /* If only one operand is a binary expression, it will be the first
3525 operand. In particular, (plus (minus (reg) (reg)) (neg (reg)))
3526 is canonical, although it will usually be further simplified. */
3530 /* Then prefer NEG and NOT. */
3531 if (code
== NEG
|| code
== NOT
)
3540 /* Return 1 iff it is necessary to swap operands of commutative operation
3541 in order to canonicalize expression. */
3544 swap_commutative_operands_p (rtx x
, rtx y
)
3546 return (commutative_operand_precedence (x
)
3547 < commutative_operand_precedence (y
));
3550 /* Return 1 if X is an autoincrement side effect and the register is
3551 not the stack pointer. */
3553 auto_inc_p (const_rtx x
)
3555 switch (GET_CODE (x
))
3563 /* There are no REG_INC notes for SP. */
3564 if (XEXP (x
, 0) != stack_pointer_rtx
)
3572 /* Return nonzero if IN contains a piece of rtl that has the address LOC. */
3574 loc_mentioned_in_p (rtx
*loc
, const_rtx in
)
3583 code
= GET_CODE (in
);
3584 fmt
= GET_RTX_FORMAT (code
);
3585 for (i
= GET_RTX_LENGTH (code
) - 1; i
>= 0; i
--)
3589 if (loc
== &XEXP (in
, i
) || loc_mentioned_in_p (loc
, XEXP (in
, i
)))
3592 else if (fmt
[i
] == 'E')
3593 for (j
= XVECLEN (in
, i
) - 1; j
>= 0; j
--)
3594 if (loc
== &XVECEXP (in
, i
, j
)
3595 || loc_mentioned_in_p (loc
, XVECEXP (in
, i
, j
)))
3601 /* Reinterpret a subreg as a bit extraction from an integer and return
3602 the position of the least significant bit of the extracted value.
3603 In other words, if the extraction were performed as a shift right
3604 and mask, return the number of bits to shift right.
3606 The outer value of the subreg has OUTER_BYTES bytes and starts at
3607 byte offset SUBREG_BYTE within an inner value of INNER_BYTES bytes. */
3610 subreg_size_lsb (poly_uint64 outer_bytes
,
3611 poly_uint64 inner_bytes
,
3612 poly_uint64 subreg_byte
)
3614 poly_uint64 subreg_end
, trailing_bytes
, byte_pos
;
3616 /* A paradoxical subreg begins at bit position 0. */
3617 gcc_checking_assert (ordered_p (outer_bytes
, inner_bytes
));
3618 if (maybe_gt (outer_bytes
, inner_bytes
))
3620 gcc_checking_assert (known_eq (subreg_byte
, 0U));
3624 subreg_end
= subreg_byte
+ outer_bytes
;
3625 trailing_bytes
= inner_bytes
- subreg_end
;
3626 if (WORDS_BIG_ENDIAN
&& BYTES_BIG_ENDIAN
)
3627 byte_pos
= trailing_bytes
;
3628 else if (!WORDS_BIG_ENDIAN
&& !BYTES_BIG_ENDIAN
)
3629 byte_pos
= subreg_byte
;
3632 /* When bytes and words have opposite endianness, we must be able
3633 to split offsets into words and bytes at compile time. */
3634 poly_uint64 leading_word_part
3635 = force_align_down (subreg_byte
, UNITS_PER_WORD
);
3636 poly_uint64 trailing_word_part
3637 = force_align_down (trailing_bytes
, UNITS_PER_WORD
);
3638 /* If the subreg crosses a word boundary ensure that
3639 it also begins and ends on a word boundary. */
3640 gcc_assert (known_le (subreg_end
- leading_word_part
,
3641 (unsigned int) UNITS_PER_WORD
)
3642 || (known_eq (leading_word_part
, subreg_byte
)
3643 && known_eq (trailing_word_part
, trailing_bytes
)));
3644 if (WORDS_BIG_ENDIAN
)
3645 byte_pos
= trailing_word_part
+ (subreg_byte
- leading_word_part
);
3647 byte_pos
= leading_word_part
+ (trailing_bytes
- trailing_word_part
);
3650 return byte_pos
* BITS_PER_UNIT
;
3653 /* Given a subreg X, return the bit offset where the subreg begins
3654 (counting from the least significant bit of the reg). */
3657 subreg_lsb (const_rtx x
)
3659 return subreg_lsb_1 (GET_MODE (x
), GET_MODE (SUBREG_REG (x
)),
3663 /* Return the subreg byte offset for a subreg whose outer value has
3664 OUTER_BYTES bytes, whose inner value has INNER_BYTES bytes, and where
3665 there are LSB_SHIFT *bits* between the lsb of the outer value and the
3666 lsb of the inner value. This is the inverse of the calculation
3667 performed by subreg_lsb_1 (which converts byte offsets to bit shifts). */
3670 subreg_size_offset_from_lsb (poly_uint64 outer_bytes
, poly_uint64 inner_bytes
,
3671 poly_uint64 lsb_shift
)
3673 /* A paradoxical subreg begins at bit position 0. */
3674 gcc_checking_assert (ordered_p (outer_bytes
, inner_bytes
));
3675 if (maybe_gt (outer_bytes
, inner_bytes
))
3677 gcc_checking_assert (known_eq (lsb_shift
, 0U));
3681 poly_uint64 lower_bytes
= exact_div (lsb_shift
, BITS_PER_UNIT
);
3682 poly_uint64 upper_bytes
= inner_bytes
- (lower_bytes
+ outer_bytes
);
3683 if (WORDS_BIG_ENDIAN
&& BYTES_BIG_ENDIAN
)
3685 else if (!WORDS_BIG_ENDIAN
&& !BYTES_BIG_ENDIAN
)
3689 /* When bytes and words have opposite endianness, we must be able
3690 to split offsets into words and bytes at compile time. */
3691 poly_uint64 lower_word_part
= force_align_down (lower_bytes
,
3693 poly_uint64 upper_word_part
= force_align_down (upper_bytes
,
3695 if (WORDS_BIG_ENDIAN
)
3696 return upper_word_part
+ (lower_bytes
- lower_word_part
);
3698 return lower_word_part
+ (upper_bytes
- upper_word_part
);
3702 /* Fill in information about a subreg of a hard register.
3703 xregno - A regno of an inner hard subreg_reg (or what will become one).
3704 xmode - The mode of xregno.
3705 offset - The byte offset.
3706 ymode - The mode of a top level SUBREG (or what may become one).
3707 info - Pointer to structure to fill in.
3709 Rather than considering one particular inner register (and thus one
3710 particular "outer" register) in isolation, this function really uses
3711 XREGNO as a model for a sequence of isomorphic hard registers. Thus the
3712 function does not check whether adding INFO->offset to XREGNO gives
3713 a valid hard register; even if INFO->offset + XREGNO is out of range,
3714 there might be another register of the same type that is in range.
3715 Likewise it doesn't check whether targetm.hard_regno_mode_ok accepts
3716 the new register, since that can depend on things like whether the final
3717 register number is even or odd. Callers that want to check whether
3718 this particular subreg can be replaced by a simple (reg ...) should
3719 use simplify_subreg_regno. */
3722 subreg_get_info (unsigned int xregno
, machine_mode xmode
,
3723 poly_uint64 offset
, machine_mode ymode
,
3724 struct subreg_info
*info
)
3726 unsigned int nregs_xmode
, nregs_ymode
;
3728 gcc_assert (xregno
< FIRST_PSEUDO_REGISTER
);
3730 poly_uint64 xsize
= GET_MODE_SIZE (xmode
);
3731 poly_uint64 ysize
= GET_MODE_SIZE (ymode
);
3733 bool rknown
= false;
3735 /* If the register representation of a non-scalar mode has holes in it,
3736 we expect the scalar units to be concatenated together, with the holes
3737 distributed evenly among the scalar units. Each scalar unit must occupy
3738 at least one register. */
3739 if (HARD_REGNO_NREGS_HAS_PADDING (xregno
, xmode
))
3741 /* As a consequence, we must be dealing with a constant number of
3742 scalars, and thus a constant offset and number of units. */
3743 HOST_WIDE_INT coffset
= offset
.to_constant ();
3744 HOST_WIDE_INT cysize
= ysize
.to_constant ();
3745 nregs_xmode
= HARD_REGNO_NREGS_WITH_PADDING (xregno
, xmode
);
3746 unsigned int nunits
= GET_MODE_NUNITS (xmode
).to_constant ();
3747 scalar_mode xmode_unit
= GET_MODE_INNER (xmode
);
3748 gcc_assert (HARD_REGNO_NREGS_HAS_PADDING (xregno
, xmode_unit
));
3749 gcc_assert (nregs_xmode
3751 * HARD_REGNO_NREGS_WITH_PADDING (xregno
, xmode_unit
)));
3752 gcc_assert (hard_regno_nregs (xregno
, xmode
)
3753 == hard_regno_nregs (xregno
, xmode_unit
) * nunits
);
3755 /* You can only ask for a SUBREG of a value with holes in the middle
3756 if you don't cross the holes. (Such a SUBREG should be done by
3757 picking a different register class, or doing it in memory if
3758 necessary.) An example of a value with holes is XCmode on 32-bit
3759 x86 with -m128bit-long-double; it's represented in 6 32-bit registers,
3760 3 for each part, but in memory it's two 128-bit parts.
3761 Padding is assumed to be at the end (not necessarily the 'high part')
3763 if ((coffset
/ GET_MODE_SIZE (xmode_unit
) + 1 < nunits
)
3764 && (coffset
/ GET_MODE_SIZE (xmode_unit
)
3765 != ((coffset
+ cysize
- 1) / GET_MODE_SIZE (xmode_unit
))))
3767 info
->representable_p
= false;
3772 nregs_xmode
= hard_regno_nregs (xregno
, xmode
);
3774 nregs_ymode
= hard_regno_nregs (xregno
, ymode
);
3776 /* Subreg sizes must be ordered, so that we can tell whether they are
3777 partial, paradoxical or complete. */
3778 gcc_checking_assert (ordered_p (xsize
, ysize
));
3780 /* Paradoxical subregs are otherwise valid. */
3781 if (!rknown
&& known_eq (offset
, 0U) && maybe_gt (ysize
, xsize
))
3783 info
->representable_p
= true;
3784 /* If this is a big endian paradoxical subreg, which uses more
3785 actual hard registers than the original register, we must
3786 return a negative offset so that we find the proper highpart
3789 We assume that the ordering of registers within a multi-register
3790 value has a consistent endianness: if bytes and register words
3791 have different endianness, the hard registers that make up a
3792 multi-register value must be at least word-sized. */
3793 if (REG_WORDS_BIG_ENDIAN
)
3794 info
->offset
= (int) nregs_xmode
- (int) nregs_ymode
;
3797 info
->nregs
= nregs_ymode
;
3801 /* If registers store different numbers of bits in the different
3802 modes, we cannot generally form this subreg. */
3803 poly_uint64 regsize_xmode
, regsize_ymode
;
3804 if (!HARD_REGNO_NREGS_HAS_PADDING (xregno
, xmode
)
3805 && !HARD_REGNO_NREGS_HAS_PADDING (xregno
, ymode
)
3806 && multiple_p (xsize
, nregs_xmode
, ®size_xmode
)
3807 && multiple_p (ysize
, nregs_ymode
, ®size_ymode
))
3810 && ((nregs_ymode
> 1 && maybe_gt (regsize_xmode
, regsize_ymode
))
3811 || (nregs_xmode
> 1 && maybe_gt (regsize_ymode
, regsize_xmode
))))
3813 info
->representable_p
= false;
3814 if (!can_div_away_from_zero_p (ysize
, regsize_xmode
, &info
->nregs
)
3815 || !can_div_trunc_p (offset
, regsize_xmode
, &info
->offset
))
3816 /* Checked by validate_subreg. We must know at compile time
3817 which inner registers are being accessed. */
3821 /* It's not valid to extract a subreg of mode YMODE at OFFSET that
3822 would go outside of XMODE. */
3823 if (!rknown
&& maybe_gt (ysize
+ offset
, xsize
))
3825 info
->representable_p
= false;
3826 info
->nregs
= nregs_ymode
;
3827 if (!can_div_trunc_p (offset
, regsize_xmode
, &info
->offset
))
3828 /* Checked by validate_subreg. We must know at compile time
3829 which inner registers are being accessed. */
3833 /* Quick exit for the simple and common case of extracting whole
3834 subregisters from a multiregister value. */
3835 /* ??? It would be better to integrate this into the code below,
3836 if we can generalize the concept enough and figure out how
3837 odd-sized modes can coexist with the other weird cases we support. */
3838 HOST_WIDE_INT count
;
3840 && WORDS_BIG_ENDIAN
== REG_WORDS_BIG_ENDIAN
3841 && known_eq (regsize_xmode
, regsize_ymode
)
3842 && constant_multiple_p (offset
, regsize_ymode
, &count
))
3844 info
->representable_p
= true;
3845 info
->nregs
= nregs_ymode
;
3846 info
->offset
= count
;
3847 gcc_assert (info
->offset
+ info
->nregs
<= (int) nregs_xmode
);
3852 /* Lowpart subregs are otherwise valid. */
3853 if (!rknown
&& known_eq (offset
, subreg_lowpart_offset (ymode
, xmode
)))
3855 info
->representable_p
= true;
3858 if (known_eq (offset
, 0U) || nregs_xmode
== nregs_ymode
)
3861 info
->nregs
= nregs_ymode
;
3866 /* Set NUM_BLOCKS to the number of independently-representable YMODE
3867 values there are in (reg:XMODE XREGNO). We can view the register
3868 as consisting of this number of independent "blocks", where each
3869 block occupies NREGS_YMODE registers and contains exactly one
3870 representable YMODE value. */
3871 gcc_assert ((nregs_xmode
% nregs_ymode
) == 0);
3872 unsigned int num_blocks
= nregs_xmode
/ nregs_ymode
;
3874 /* Calculate the number of bytes in each block. This must always
3875 be exact, otherwise we don't know how to verify the constraint.
3876 These conditions may be relaxed but subreg_regno_offset would
3877 need to be redesigned. */
3878 poly_uint64 bytes_per_block
= exact_div (xsize
, num_blocks
);
3880 /* Get the number of the first block that contains the subreg and the byte
3881 offset of the subreg from the start of that block. */
3882 unsigned int block_number
;
3883 poly_uint64 subblock_offset
;
3884 if (!can_div_trunc_p (offset
, bytes_per_block
, &block_number
,
3886 /* Checked by validate_subreg. We must know at compile time which
3887 inner registers are being accessed. */
3892 /* Only the lowpart of each block is representable. */
3893 info
->representable_p
3894 = known_eq (subblock_offset
,
3895 subreg_size_lowpart_offset (ysize
, bytes_per_block
));
3899 /* We assume that the ordering of registers within a multi-register
3900 value has a consistent endianness: if bytes and register words
3901 have different endianness, the hard registers that make up a
3902 multi-register value must be at least word-sized. */
3903 if (WORDS_BIG_ENDIAN
!= REG_WORDS_BIG_ENDIAN
)
3904 /* The block number we calculated above followed memory endianness.
3905 Convert it to register endianness by counting back from the end.
3906 (Note that, because of the assumption above, each block must be
3907 at least word-sized.) */
3908 info
->offset
= (num_blocks
- block_number
- 1) * nregs_ymode
;
3910 info
->offset
= block_number
* nregs_ymode
;
3911 info
->nregs
= nregs_ymode
;
3914 /* This function returns the regno offset of a subreg expression.
3915 xregno - A regno of an inner hard subreg_reg (or what will become one).
3916 xmode - The mode of xregno.
3917 offset - The byte offset.
3918 ymode - The mode of a top level SUBREG (or what may become one).
3919 RETURN - The regno offset which would be used. */
3921 subreg_regno_offset (unsigned int xregno
, machine_mode xmode
,
3922 poly_uint64 offset
, machine_mode ymode
)
3924 struct subreg_info info
;
3925 subreg_get_info (xregno
, xmode
, offset
, ymode
, &info
);
3929 /* This function returns true when the offset is representable via
3930 subreg_offset in the given regno.
3931 xregno - A regno of an inner hard subreg_reg (or what will become one).
3932 xmode - The mode of xregno.
3933 offset - The byte offset.
3934 ymode - The mode of a top level SUBREG (or what may become one).
3935 RETURN - Whether the offset is representable. */
3937 subreg_offset_representable_p (unsigned int xregno
, machine_mode xmode
,
3938 poly_uint64 offset
, machine_mode ymode
)
3940 struct subreg_info info
;
3941 subreg_get_info (xregno
, xmode
, offset
, ymode
, &info
);
3942 return info
.representable_p
;
3945 /* Return the number of a YMODE register to which
3947 (subreg:YMODE (reg:XMODE XREGNO) OFFSET)
3949 can be simplified. Return -1 if the subreg can't be simplified.
3951 XREGNO is a hard register number. */
3954 simplify_subreg_regno (unsigned int xregno
, machine_mode xmode
,
3955 poly_uint64 offset
, machine_mode ymode
)
3957 struct subreg_info info
;
3958 unsigned int yregno
;
3960 /* Give the backend a chance to disallow the mode change. */
3961 if (GET_MODE_CLASS (xmode
) != MODE_COMPLEX_INT
3962 && GET_MODE_CLASS (xmode
) != MODE_COMPLEX_FLOAT
3963 && !REG_CAN_CHANGE_MODE_P (xregno
, xmode
, ymode
))
3966 /* We shouldn't simplify stack-related registers. */
3967 if ((!reload_completed
|| frame_pointer_needed
)
3968 && xregno
== FRAME_POINTER_REGNUM
)
3971 if (FRAME_POINTER_REGNUM
!= ARG_POINTER_REGNUM
3972 && xregno
== ARG_POINTER_REGNUM
)
3975 if (xregno
== STACK_POINTER_REGNUM
3976 /* We should convert hard stack register in LRA if it is
3978 && ! lra_in_progress
)
3981 /* Try to get the register offset. */
3982 subreg_get_info (xregno
, xmode
, offset
, ymode
, &info
);
3983 if (!info
.representable_p
)
3986 /* Make sure that the offsetted register value is in range. */
3987 yregno
= xregno
+ info
.offset
;
3988 if (!HARD_REGISTER_NUM_P (yregno
))
3991 /* See whether (reg:YMODE YREGNO) is valid.
3993 ??? We allow invalid registers if (reg:XMODE XREGNO) is also invalid.
3994 This is a kludge to work around how complex FP arguments are passed
3995 on IA-64 and should be fixed. See PR target/49226. */
3996 if (!targetm
.hard_regno_mode_ok (yregno
, ymode
)
3997 && targetm
.hard_regno_mode_ok (xregno
, xmode
))
4000 return (int) yregno
;
4003 /* Return the final regno that a subreg expression refers to. */
4005 subreg_regno (const_rtx x
)
4008 rtx subreg
= SUBREG_REG (x
);
4009 int regno
= REGNO (subreg
);
4011 ret
= regno
+ subreg_regno_offset (regno
,
4019 /* Return the number of registers that a subreg expression refers
4022 subreg_nregs (const_rtx x
)
4024 return subreg_nregs_with_regno (REGNO (SUBREG_REG (x
)), x
);
4027 /* Return the number of registers that a subreg REG with REGNO
4028 expression refers to. This is a copy of the rtlanal.c:subreg_nregs
4029 changed so that the regno can be passed in. */
4032 subreg_nregs_with_regno (unsigned int regno
, const_rtx x
)
4034 struct subreg_info info
;
4035 rtx subreg
= SUBREG_REG (x
);
4037 subreg_get_info (regno
, GET_MODE (subreg
), SUBREG_BYTE (x
), GET_MODE (x
),
4042 struct parms_set_data
4048 /* Helper function for noticing stores to parameter registers. */
4050 parms_set (rtx x
, const_rtx pat ATTRIBUTE_UNUSED
, void *data
)
4052 struct parms_set_data
*const d
= (struct parms_set_data
*) data
;
4053 if (REG_P (x
) && REGNO (x
) < FIRST_PSEUDO_REGISTER
4054 && TEST_HARD_REG_BIT (d
->regs
, REGNO (x
)))
4056 CLEAR_HARD_REG_BIT (d
->regs
, REGNO (x
));
4061 /* Look backward for first parameter to be loaded.
4062 Note that loads of all parameters will not necessarily be
4063 found if CSE has eliminated some of them (e.g., an argument
4064 to the outer function is passed down as a parameter).
4065 Do not skip BOUNDARY. */
4067 find_first_parameter_load (rtx_insn
*call_insn
, rtx_insn
*boundary
)
4069 struct parms_set_data parm
;
4071 rtx_insn
*before
, *first_set
;
4073 /* Since different machines initialize their parameter registers
4074 in different orders, assume nothing. Collect the set of all
4075 parameter registers. */
4076 CLEAR_HARD_REG_SET (parm
.regs
);
4078 for (p
= CALL_INSN_FUNCTION_USAGE (call_insn
); p
; p
= XEXP (p
, 1))
4079 if (GET_CODE (XEXP (p
, 0)) == USE
4080 && REG_P (XEXP (XEXP (p
, 0), 0))
4081 && !STATIC_CHAIN_REG_P (XEXP (XEXP (p
, 0), 0)))
4083 gcc_assert (REGNO (XEXP (XEXP (p
, 0), 0)) < FIRST_PSEUDO_REGISTER
);
4085 /* We only care about registers which can hold function
4087 if (!FUNCTION_ARG_REGNO_P (REGNO (XEXP (XEXP (p
, 0), 0))))
4090 SET_HARD_REG_BIT (parm
.regs
, REGNO (XEXP (XEXP (p
, 0), 0)));
4094 first_set
= call_insn
;
4096 /* Search backward for the first set of a register in this set. */
4097 while (parm
.nregs
&& before
!= boundary
)
4099 before
= PREV_INSN (before
);
4101 /* It is possible that some loads got CSEed from one call to
4102 another. Stop in that case. */
4103 if (CALL_P (before
))
4106 /* Our caller needs either ensure that we will find all sets
4107 (in case code has not been optimized yet), or take care
4108 for possible labels in a way by setting boundary to preceding
4110 if (LABEL_P (before
))
4112 gcc_assert (before
== boundary
);
4116 if (INSN_P (before
))
4118 int nregs_old
= parm
.nregs
;
4119 note_stores (before
, parms_set
, &parm
);
4120 /* If we found something that did not set a parameter reg,
4121 we're done. Do not keep going, as that might result
4122 in hoisting an insn before the setting of a pseudo
4123 that is used by the hoisted insn. */
4124 if (nregs_old
!= parm
.nregs
)
4133 /* Return true if we should avoid inserting code between INSN and preceding
4134 call instruction. */
4137 keep_with_call_p (const rtx_insn
*insn
)
4141 if (INSN_P (insn
) && (set
= single_set (insn
)) != NULL
)
4143 if (REG_P (SET_DEST (set
))
4144 && REGNO (SET_DEST (set
)) < FIRST_PSEUDO_REGISTER
4145 && fixed_regs
[REGNO (SET_DEST (set
))]
4146 && general_operand (SET_SRC (set
), VOIDmode
))
4148 if (REG_P (SET_SRC (set
))
4149 && targetm
.calls
.function_value_regno_p (REGNO (SET_SRC (set
)))
4150 && REG_P (SET_DEST (set
))
4151 && REGNO (SET_DEST (set
)) >= FIRST_PSEUDO_REGISTER
)
4153 /* There may be a stack pop just after the call and before the store
4154 of the return register. Search for the actual store when deciding
4155 if we can break or not. */
4156 if (SET_DEST (set
) == stack_pointer_rtx
)
4158 /* This CONST_CAST is okay because next_nonnote_insn just
4159 returns its argument and we assign it to a const_rtx
4162 = next_nonnote_insn (const_cast<rtx_insn
*> (insn
));
4163 if (i2
&& keep_with_call_p (i2
))
4170 /* Return true if LABEL is a target of JUMP_INSN. This applies only
4171 to non-complex jumps. That is, direct unconditional, conditional,
4172 and tablejumps, but not computed jumps or returns. It also does
4173 not apply to the fallthru case of a conditional jump. */
4176 label_is_jump_target_p (const_rtx label
, const rtx_insn
*jump_insn
)
4178 rtx tmp
= JUMP_LABEL (jump_insn
);
4179 rtx_jump_table_data
*table
;
4184 if (tablejump_p (jump_insn
, NULL
, &table
))
4186 rtvec vec
= table
->get_labels ();
4187 int i
, veclen
= GET_NUM_ELEM (vec
);
4189 for (i
= 0; i
< veclen
; ++i
)
4190 if (XEXP (RTVEC_ELT (vec
, i
), 0) == label
)
4194 if (find_reg_note (jump_insn
, REG_LABEL_TARGET
, label
))
4201 /* Return an estimate of the cost of computing rtx X.
4202 One use is in cse, to decide which expression to keep in the hash table.
4203 Another is in rtl generation, to pick the cheapest way to multiply.
4204 Other uses like the latter are expected in the future.
4206 X appears as operand OPNO in an expression with code OUTER_CODE.
4207 SPEED specifies whether costs optimized for speed or size should
4211 rtx_cost (rtx x
, machine_mode mode
, enum rtx_code outer_code
,
4212 int opno
, bool speed
)
4224 if (GET_CODE (x
) == SET
)
4225 /* A SET doesn't have a mode, so let's look at the SET_DEST to get
4226 the mode for the factor. */
4227 mode
= GET_MODE (SET_DEST (x
));
4228 else if (GET_MODE (x
) != VOIDmode
)
4229 mode
= GET_MODE (x
);
4231 mode_size
= estimated_poly_value (GET_MODE_SIZE (mode
));
4233 /* A size N times larger than UNITS_PER_WORD likely needs N times as
4234 many insns, taking N times as long. */
4235 factor
= mode_size
> UNITS_PER_WORD
? mode_size
/ UNITS_PER_WORD
: 1;
4237 /* Compute the default costs of certain things.
4238 Note that targetm.rtx_costs can override the defaults. */
4240 code
= GET_CODE (x
);
4244 /* Multiplication has time-complexity O(N*N), where N is the
4245 number of units (translated from digits) when using
4246 schoolbook long multiplication. */
4247 total
= factor
* factor
* COSTS_N_INSNS (5);
4253 /* Similarly, complexity for schoolbook long division. */
4254 total
= factor
* factor
* COSTS_N_INSNS (7);
4257 /* Used in combine.c as a marker. */
4261 total
= factor
* COSTS_N_INSNS (1);
4271 /* If we can't tie these modes, make this expensive. The larger
4272 the mode, the more expensive it is. */
4273 if (!targetm
.modes_tieable_p (mode
, GET_MODE (SUBREG_REG (x
))))
4274 return COSTS_N_INSNS (2 + factor
);
4278 if (targetm
.modes_tieable_p (mode
, GET_MODE (XEXP (x
, 0))))
4285 if (targetm
.rtx_costs (x
, mode
, outer_code
, opno
, &total
, speed
))
4290 /* Sum the costs of the sub-rtx's, plus cost of this operation,
4291 which is already in total. */
4293 fmt
= GET_RTX_FORMAT (code
);
4294 for (i
= GET_RTX_LENGTH (code
) - 1; i
>= 0; i
--)
4296 total
+= rtx_cost (XEXP (x
, i
), mode
, code
, i
, speed
);
4297 else if (fmt
[i
] == 'E')
4298 for (j
= 0; j
< XVECLEN (x
, i
); j
++)
4299 total
+= rtx_cost (XVECEXP (x
, i
, j
), mode
, code
, i
, speed
);
4304 /* Fill in the structure C with information about both speed and size rtx
4305 costs for X, which is operand OPNO in an expression with code OUTER. */
4308 get_full_rtx_cost (rtx x
, machine_mode mode
, enum rtx_code outer
, int opno
,
4309 struct full_rtx_costs
*c
)
4311 c
->speed
= rtx_cost (x
, mode
, outer
, opno
, true);
4312 c
->size
= rtx_cost (x
, mode
, outer
, opno
, false);
4316 /* Return cost of address expression X.
4317 Expect that X is properly formed address reference.
4319 SPEED parameter specify whether costs optimized for speed or size should
4323 address_cost (rtx x
, machine_mode mode
, addr_space_t as
, bool speed
)
4325 /* We may be asked for cost of various unusual addresses, such as operands
4326 of push instruction. It is not worthwhile to complicate writing
4327 of the target hook by such cases. */
4329 if (!memory_address_addr_space_p (mode
, x
, as
))
4332 return targetm
.address_cost (x
, mode
, as
, speed
);
4335 /* If the target doesn't override, compute the cost as with arithmetic. */
4338 default_address_cost (rtx x
, machine_mode
, addr_space_t
, bool speed
)
4340 return rtx_cost (x
, Pmode
, MEM
, 0, speed
);
4344 unsigned HOST_WIDE_INT
4345 nonzero_bits (const_rtx x
, machine_mode mode
)
4347 if (mode
== VOIDmode
)
4348 mode
= GET_MODE (x
);
4349 scalar_int_mode int_mode
;
4350 if (!is_a
<scalar_int_mode
> (mode
, &int_mode
))
4351 return GET_MODE_MASK (mode
);
4352 return cached_nonzero_bits (x
, int_mode
, NULL_RTX
, VOIDmode
, 0);
4356 num_sign_bit_copies (const_rtx x
, machine_mode mode
)
4358 if (mode
== VOIDmode
)
4359 mode
= GET_MODE (x
);
4360 scalar_int_mode int_mode
;
4361 if (!is_a
<scalar_int_mode
> (mode
, &int_mode
))
4363 return cached_num_sign_bit_copies (x
, int_mode
, NULL_RTX
, VOIDmode
, 0);
4366 /* Return true if nonzero_bits1 might recurse into both operands
4370 nonzero_bits_binary_arith_p (const_rtx x
)
4372 if (!ARITHMETIC_P (x
))
4374 switch (GET_CODE (x
))
4396 /* The function cached_nonzero_bits is a wrapper around nonzero_bits1.
4397 It avoids exponential behavior in nonzero_bits1 when X has
4398 identical subexpressions on the first or the second level. */
4400 static unsigned HOST_WIDE_INT
4401 cached_nonzero_bits (const_rtx x
, scalar_int_mode mode
, const_rtx known_x
,
4402 machine_mode known_mode
,
4403 unsigned HOST_WIDE_INT known_ret
)
4405 if (x
== known_x
&& mode
== known_mode
)
4408 /* Try to find identical subexpressions. If found call
4409 nonzero_bits1 on X with the subexpressions as KNOWN_X and the
4410 precomputed value for the subexpression as KNOWN_RET. */
4412 if (nonzero_bits_binary_arith_p (x
))
4414 rtx x0
= XEXP (x
, 0);
4415 rtx x1
= XEXP (x
, 1);
4417 /* Check the first level. */
4419 return nonzero_bits1 (x
, mode
, x0
, mode
,
4420 cached_nonzero_bits (x0
, mode
, known_x
,
4421 known_mode
, known_ret
));
4423 /* Check the second level. */
4424 if (nonzero_bits_binary_arith_p (x0
)
4425 && (x1
== XEXP (x0
, 0) || x1
== XEXP (x0
, 1)))
4426 return nonzero_bits1 (x
, mode
, x1
, mode
,
4427 cached_nonzero_bits (x1
, mode
, known_x
,
4428 known_mode
, known_ret
));
4430 if (nonzero_bits_binary_arith_p (x1
)
4431 && (x0
== XEXP (x1
, 0) || x0
== XEXP (x1
, 1)))
4432 return nonzero_bits1 (x
, mode
, x0
, mode
,
4433 cached_nonzero_bits (x0
, mode
, known_x
,
4434 known_mode
, known_ret
));
4437 return nonzero_bits1 (x
, mode
, known_x
, known_mode
, known_ret
);
4440 /* We let num_sign_bit_copies recur into nonzero_bits as that is useful.
4441 We don't let nonzero_bits recur into num_sign_bit_copies, because that
4442 is less useful. We can't allow both, because that results in exponential
4443 run time recursion. There is a nullstone testcase that triggered
4444 this. This macro avoids accidental uses of num_sign_bit_copies. */
4445 #define cached_num_sign_bit_copies sorry_i_am_preventing_exponential_behavior
4447 /* Given an expression, X, compute which bits in X can be nonzero.
4448 We don't care about bits outside of those defined in MODE.
4450 For most X this is simply GET_MODE_MASK (GET_MODE (X)), but if X is
4451 an arithmetic operation, we can do better. */
4453 static unsigned HOST_WIDE_INT
4454 nonzero_bits1 (const_rtx x
, scalar_int_mode mode
, const_rtx known_x
,
4455 machine_mode known_mode
,
4456 unsigned HOST_WIDE_INT known_ret
)
4458 unsigned HOST_WIDE_INT nonzero
= GET_MODE_MASK (mode
);
4459 unsigned HOST_WIDE_INT inner_nz
;
4460 enum rtx_code code
= GET_CODE (x
);
4461 machine_mode inner_mode
;
4462 unsigned int inner_width
;
4463 scalar_int_mode xmode
;
4465 unsigned int mode_width
= GET_MODE_PRECISION (mode
);
4467 if (CONST_INT_P (x
))
4469 if (SHORT_IMMEDIATES_SIGN_EXTEND
4471 && mode_width
< BITS_PER_WORD
4472 && (UINTVAL (x
) & (HOST_WIDE_INT_1U
<< (mode_width
- 1))) != 0)
4473 return UINTVAL (x
) | (HOST_WIDE_INT_M1U
<< mode_width
);
4478 if (!is_a
<scalar_int_mode
> (GET_MODE (x
), &xmode
))
4480 unsigned int xmode_width
= GET_MODE_PRECISION (xmode
);
4482 /* If X is wider than MODE, use its mode instead. */
4483 if (xmode_width
> mode_width
)
4486 nonzero
= GET_MODE_MASK (mode
);
4487 mode_width
= xmode_width
;
4490 if (mode_width
> HOST_BITS_PER_WIDE_INT
)
4491 /* Our only callers in this case look for single bit values. So
4492 just return the mode mask. Those tests will then be false. */
4495 /* If MODE is wider than X, but both are a single word for both the host
4496 and target machines, we can compute this from which bits of the object
4497 might be nonzero in its own mode, taking into account the fact that, on
4498 CISC machines, accessing an object in a wider mode generally causes the
4499 high-order bits to become undefined, so they are not known to be zero.
4500 We extend this reasoning to RISC machines for operations that might not
4501 operate on the full registers. */
4502 if (mode_width
> xmode_width
4503 && xmode_width
<= BITS_PER_WORD
4504 && xmode_width
<= HOST_BITS_PER_WIDE_INT
4505 && !(WORD_REGISTER_OPERATIONS
&& word_register_operation_p (x
)))
4507 nonzero
&= cached_nonzero_bits (x
, xmode
,
4508 known_x
, known_mode
, known_ret
);
4509 nonzero
|= GET_MODE_MASK (mode
) & ~GET_MODE_MASK (xmode
);
4513 /* Please keep nonzero_bits_binary_arith_p above in sync with
4514 the code in the switch below. */
4518 #if defined(POINTERS_EXTEND_UNSIGNED)
4519 /* If pointers extend unsigned and this is a pointer in Pmode, say that
4520 all the bits above ptr_mode are known to be zero. */
4521 /* As we do not know which address space the pointer is referring to,
4522 we can do this only if the target does not support different pointer
4523 or address modes depending on the address space. */
4524 if (target_default_pointer_address_modes_p ()
4525 && POINTERS_EXTEND_UNSIGNED
4528 && !targetm
.have_ptr_extend ())
4529 nonzero
&= GET_MODE_MASK (ptr_mode
);
4532 /* Include declared information about alignment of pointers. */
4533 /* ??? We don't properly preserve REG_POINTER changes across
4534 pointer-to-integer casts, so we can't trust it except for
4535 things that we know must be pointers. See execute/960116-1.c. */
4536 if ((x
== stack_pointer_rtx
4537 || x
== frame_pointer_rtx
4538 || x
== arg_pointer_rtx
)
4539 && REGNO_POINTER_ALIGN (REGNO (x
)))
4541 unsigned HOST_WIDE_INT alignment
4542 = REGNO_POINTER_ALIGN (REGNO (x
)) / BITS_PER_UNIT
;
4544 #ifdef PUSH_ROUNDING
4545 /* If PUSH_ROUNDING is defined, it is possible for the
4546 stack to be momentarily aligned only to that amount,
4547 so we pick the least alignment. */
4548 if (x
== stack_pointer_rtx
&& PUSH_ARGS
)
4550 poly_uint64 rounded_1
= PUSH_ROUNDING (poly_int64 (1));
4551 alignment
= MIN (known_alignment (rounded_1
), alignment
);
4555 nonzero
&= ~(alignment
- 1);
4559 unsigned HOST_WIDE_INT nonzero_for_hook
= nonzero
;
4560 rtx new_rtx
= rtl_hooks
.reg_nonzero_bits (x
, xmode
, mode
,
4564 nonzero_for_hook
&= cached_nonzero_bits (new_rtx
, mode
, known_x
,
4565 known_mode
, known_ret
);
4567 return nonzero_for_hook
;
4571 /* In many, if not most, RISC machines, reading a byte from memory
4572 zeros the rest of the register. Noticing that fact saves a lot
4573 of extra zero-extends. */
4574 if (load_extend_op (xmode
) == ZERO_EXTEND
)
4575 nonzero
&= GET_MODE_MASK (xmode
);
4579 case UNEQ
: case LTGT
:
4580 case GT
: case GTU
: case UNGT
:
4581 case LT
: case LTU
: case UNLT
:
4582 case GE
: case GEU
: case UNGE
:
4583 case LE
: case LEU
: case UNLE
:
4584 case UNORDERED
: case ORDERED
:
4585 /* If this produces an integer result, we know which bits are set.
4586 Code here used to clear bits outside the mode of X, but that is
4588 /* Mind that MODE is the mode the caller wants to look at this
4589 operation in, and not the actual operation mode. We can wind
4590 up with (subreg:DI (gt:V4HI x y)), and we don't have anything
4591 that describes the results of a vector compare. */
4592 if (GET_MODE_CLASS (xmode
) == MODE_INT
4593 && mode_width
<= HOST_BITS_PER_WIDE_INT
)
4594 nonzero
= STORE_FLAG_VALUE
;
4599 /* Disabled to avoid exponential mutual recursion between nonzero_bits
4600 and num_sign_bit_copies. */
4601 if (num_sign_bit_copies (XEXP (x
, 0), xmode
) == xmode_width
)
4605 if (xmode_width
< mode_width
)
4606 nonzero
|= (GET_MODE_MASK (mode
) & ~GET_MODE_MASK (xmode
));
4611 /* Disabled to avoid exponential mutual recursion between nonzero_bits
4612 and num_sign_bit_copies. */
4613 if (num_sign_bit_copies (XEXP (x
, 0), xmode
) == xmode_width
)
4619 nonzero
&= (cached_nonzero_bits (XEXP (x
, 0), mode
,
4620 known_x
, known_mode
, known_ret
)
4621 & GET_MODE_MASK (mode
));
4625 nonzero
&= cached_nonzero_bits (XEXP (x
, 0), mode
,
4626 known_x
, known_mode
, known_ret
);
4627 if (GET_MODE (XEXP (x
, 0)) != VOIDmode
)
4628 nonzero
&= GET_MODE_MASK (GET_MODE (XEXP (x
, 0)));
4632 /* If the sign bit is known clear, this is the same as ZERO_EXTEND.
4633 Otherwise, show all the bits in the outer mode but not the inner
4635 inner_nz
= cached_nonzero_bits (XEXP (x
, 0), mode
,
4636 known_x
, known_mode
, known_ret
);
4637 if (GET_MODE (XEXP (x
, 0)) != VOIDmode
)
4639 inner_nz
&= GET_MODE_MASK (GET_MODE (XEXP (x
, 0)));
4640 if (val_signbit_known_set_p (GET_MODE (XEXP (x
, 0)), inner_nz
))
4641 inner_nz
|= (GET_MODE_MASK (mode
)
4642 & ~GET_MODE_MASK (GET_MODE (XEXP (x
, 0))));
4645 nonzero
&= inner_nz
;
4649 nonzero
&= cached_nonzero_bits (XEXP (x
, 0), mode
,
4650 known_x
, known_mode
, known_ret
)
4651 & cached_nonzero_bits (XEXP (x
, 1), mode
,
4652 known_x
, known_mode
, known_ret
);
4656 case UMIN
: case UMAX
: case SMIN
: case SMAX
:
4658 unsigned HOST_WIDE_INT nonzero0
4659 = cached_nonzero_bits (XEXP (x
, 0), mode
,
4660 known_x
, known_mode
, known_ret
);
4662 /* Don't call nonzero_bits for the second time if it cannot change
4664 if ((nonzero
& nonzero0
) != nonzero
)
4666 | cached_nonzero_bits (XEXP (x
, 1), mode
,
4667 known_x
, known_mode
, known_ret
);
4671 case PLUS
: case MINUS
:
4673 case DIV
: case UDIV
:
4674 case MOD
: case UMOD
:
4675 /* We can apply the rules of arithmetic to compute the number of
4676 high- and low-order zero bits of these operations. We start by
4677 computing the width (position of the highest-order nonzero bit)
4678 and the number of low-order zero bits for each value. */
4680 unsigned HOST_WIDE_INT nz0
4681 = cached_nonzero_bits (XEXP (x
, 0), mode
,
4682 known_x
, known_mode
, known_ret
);
4683 unsigned HOST_WIDE_INT nz1
4684 = cached_nonzero_bits (XEXP (x
, 1), mode
,
4685 known_x
, known_mode
, known_ret
);
4686 int sign_index
= xmode_width
- 1;
4687 int width0
= floor_log2 (nz0
) + 1;
4688 int width1
= floor_log2 (nz1
) + 1;
4689 int low0
= ctz_or_zero (nz0
);
4690 int low1
= ctz_or_zero (nz1
);
4691 unsigned HOST_WIDE_INT op0_maybe_minusp
4692 = nz0
& (HOST_WIDE_INT_1U
<< sign_index
);
4693 unsigned HOST_WIDE_INT op1_maybe_minusp
4694 = nz1
& (HOST_WIDE_INT_1U
<< sign_index
);
4695 unsigned int result_width
= mode_width
;
4701 result_width
= MAX (width0
, width1
) + 1;
4702 result_low
= MIN (low0
, low1
);
4705 result_low
= MIN (low0
, low1
);
4708 result_width
= width0
+ width1
;
4709 result_low
= low0
+ low1
;
4714 if (!op0_maybe_minusp
&& !op1_maybe_minusp
)
4715 result_width
= width0
;
4720 result_width
= width0
;
4725 if (!op0_maybe_minusp
&& !op1_maybe_minusp
)
4726 result_width
= MIN (width0
, width1
);
4727 result_low
= MIN (low0
, low1
);
4732 result_width
= MIN (width0
, width1
);
4733 result_low
= MIN (low0
, low1
);
4739 if (result_width
< mode_width
)
4740 nonzero
&= (HOST_WIDE_INT_1U
<< result_width
) - 1;
4743 nonzero
&= ~((HOST_WIDE_INT_1U
<< result_low
) - 1);
4748 if (CONST_INT_P (XEXP (x
, 1))
4749 && INTVAL (XEXP (x
, 1)) < HOST_BITS_PER_WIDE_INT
)
4750 nonzero
&= (HOST_WIDE_INT_1U
<< INTVAL (XEXP (x
, 1))) - 1;
4754 /* If this is a SUBREG formed for a promoted variable that has
4755 been zero-extended, we know that at least the high-order bits
4756 are zero, though others might be too. */
4757 if (SUBREG_PROMOTED_VAR_P (x
) && SUBREG_PROMOTED_UNSIGNED_P (x
))
4758 nonzero
= GET_MODE_MASK (xmode
)
4759 & cached_nonzero_bits (SUBREG_REG (x
), xmode
,
4760 known_x
, known_mode
, known_ret
);
4762 /* If the inner mode is a single word for both the host and target
4763 machines, we can compute this from which bits of the inner
4764 object might be nonzero. */
4765 inner_mode
= GET_MODE (SUBREG_REG (x
));
4766 if (GET_MODE_PRECISION (inner_mode
).is_constant (&inner_width
)
4767 && inner_width
<= BITS_PER_WORD
4768 && inner_width
<= HOST_BITS_PER_WIDE_INT
)
4770 nonzero
&= cached_nonzero_bits (SUBREG_REG (x
), mode
,
4771 known_x
, known_mode
, known_ret
);
4773 /* On a typical CISC machine, accessing an object in a wider mode
4774 causes the high-order bits to become undefined. So they are
4775 not known to be zero.
4777 On a typical RISC machine, we only have to worry about the way
4778 loads are extended. Otherwise, if we get a reload for the inner
4779 part, it may be loaded from the stack, and then we may lose all
4780 the zero bits that existed before the store to the stack. */
4782 if ((!WORD_REGISTER_OPERATIONS
4783 || ((extend_op
= load_extend_op (inner_mode
)) == SIGN_EXTEND
4784 ? val_signbit_known_set_p (inner_mode
, nonzero
)
4785 : extend_op
!= ZERO_EXTEND
)
4786 || !MEM_P (SUBREG_REG (x
)))
4787 && xmode_width
> inner_width
)
4789 |= (GET_MODE_MASK (GET_MODE (x
)) & ~GET_MODE_MASK (inner_mode
));
4798 /* The nonzero bits are in two classes: any bits within MODE
4799 that aren't in xmode are always significant. The rest of the
4800 nonzero bits are those that are significant in the operand of
4801 the shift when shifted the appropriate number of bits. This
4802 shows that high-order bits are cleared by the right shift and
4803 low-order bits by left shifts. */
4804 if (CONST_INT_P (XEXP (x
, 1))
4805 && INTVAL (XEXP (x
, 1)) >= 0
4806 && INTVAL (XEXP (x
, 1)) < HOST_BITS_PER_WIDE_INT
4807 && INTVAL (XEXP (x
, 1)) < xmode_width
)
4809 int count
= INTVAL (XEXP (x
, 1));
4810 unsigned HOST_WIDE_INT mode_mask
= GET_MODE_MASK (xmode
);
4811 unsigned HOST_WIDE_INT op_nonzero
4812 = cached_nonzero_bits (XEXP (x
, 0), mode
,
4813 known_x
, known_mode
, known_ret
);
4814 unsigned HOST_WIDE_INT inner
= op_nonzero
& mode_mask
;
4815 unsigned HOST_WIDE_INT outer
= 0;
4817 if (mode_width
> xmode_width
)
4818 outer
= (op_nonzero
& nonzero
& ~mode_mask
);
4833 /* If the sign bit may have been nonzero before the shift, we
4834 need to mark all the places it could have been copied to
4835 by the shift as possibly nonzero. */
4836 if (inner
& (HOST_WIDE_INT_1U
<< (xmode_width
- 1 - count
)))
4837 inner
|= (((HOST_WIDE_INT_1U
<< count
) - 1)
4838 << (xmode_width
- count
));
4842 inner
= (inner
<< (count
% xmode_width
)
4843 | (inner
>> (xmode_width
- (count
% xmode_width
))))
4848 inner
= (inner
>> (count
% xmode_width
)
4849 | (inner
<< (xmode_width
- (count
% xmode_width
))))
4857 nonzero
&= (outer
| inner
);
4863 /* This is at most the number of bits in the mode. */
4864 nonzero
= ((unsigned HOST_WIDE_INT
) 2 << (floor_log2 (mode_width
))) - 1;
4868 /* If CLZ has a known value at zero, then the nonzero bits are
4869 that value, plus the number of bits in the mode minus one. */
4870 if (CLZ_DEFINED_VALUE_AT_ZERO (mode
, nonzero
))
4872 |= (HOST_WIDE_INT_1U
<< (floor_log2 (mode_width
))) - 1;
4878 /* If CTZ has a known value at zero, then the nonzero bits are
4879 that value, plus the number of bits in the mode minus one. */
4880 if (CTZ_DEFINED_VALUE_AT_ZERO (mode
, nonzero
))
4882 |= (HOST_WIDE_INT_1U
<< (floor_log2 (mode_width
))) - 1;
4888 /* This is at most the number of bits in the mode minus 1. */
4889 nonzero
= (HOST_WIDE_INT_1U
<< (floor_log2 (mode_width
))) - 1;
4898 unsigned HOST_WIDE_INT nonzero_true
4899 = cached_nonzero_bits (XEXP (x
, 1), mode
,
4900 known_x
, known_mode
, known_ret
);
4902 /* Don't call nonzero_bits for the second time if it cannot change
4904 if ((nonzero
& nonzero_true
) != nonzero
)
4905 nonzero
&= nonzero_true
4906 | cached_nonzero_bits (XEXP (x
, 2), mode
,
4907 known_x
, known_mode
, known_ret
);
4918 /* See the macro definition above. */
4919 #undef cached_num_sign_bit_copies
4922 /* Return true if num_sign_bit_copies1 might recurse into both operands
4926 num_sign_bit_copies_binary_arith_p (const_rtx x
)
4928 if (!ARITHMETIC_P (x
))
4930 switch (GET_CODE (x
))
4948 /* The function cached_num_sign_bit_copies is a wrapper around
4949 num_sign_bit_copies1. It avoids exponential behavior in
4950 num_sign_bit_copies1 when X has identical subexpressions on the
4951 first or the second level. */
4954 cached_num_sign_bit_copies (const_rtx x
, scalar_int_mode mode
,
4955 const_rtx known_x
, machine_mode known_mode
,
4956 unsigned int known_ret
)
4958 if (x
== known_x
&& mode
== known_mode
)
4961 /* Try to find identical subexpressions. If found call
4962 num_sign_bit_copies1 on X with the subexpressions as KNOWN_X and
4963 the precomputed value for the subexpression as KNOWN_RET. */
4965 if (num_sign_bit_copies_binary_arith_p (x
))
4967 rtx x0
= XEXP (x
, 0);
4968 rtx x1
= XEXP (x
, 1);
4970 /* Check the first level. */
4973 num_sign_bit_copies1 (x
, mode
, x0
, mode
,
4974 cached_num_sign_bit_copies (x0
, mode
, known_x
,
4978 /* Check the second level. */
4979 if (num_sign_bit_copies_binary_arith_p (x0
)
4980 && (x1
== XEXP (x0
, 0) || x1
== XEXP (x0
, 1)))
4982 num_sign_bit_copies1 (x
, mode
, x1
, mode
,
4983 cached_num_sign_bit_copies (x1
, mode
, known_x
,
4987 if (num_sign_bit_copies_binary_arith_p (x1
)
4988 && (x0
== XEXP (x1
, 0) || x0
== XEXP (x1
, 1)))
4990 num_sign_bit_copies1 (x
, mode
, x0
, mode
,
4991 cached_num_sign_bit_copies (x0
, mode
, known_x
,
4996 return num_sign_bit_copies1 (x
, mode
, known_x
, known_mode
, known_ret
);
4999 /* Return the number of bits at the high-order end of X that are known to
5000 be equal to the sign bit. X will be used in mode MODE. The returned
5001 value will always be between 1 and the number of bits in MODE. */
5004 num_sign_bit_copies1 (const_rtx x
, scalar_int_mode mode
, const_rtx known_x
,
5005 machine_mode known_mode
,
5006 unsigned int known_ret
)
5008 enum rtx_code code
= GET_CODE (x
);
5009 unsigned int bitwidth
= GET_MODE_PRECISION (mode
);
5010 int num0
, num1
, result
;
5011 unsigned HOST_WIDE_INT nonzero
;
5013 if (CONST_INT_P (x
))
5015 /* If the constant is negative, take its 1's complement and remask.
5016 Then see how many zero bits we have. */
5017 nonzero
= UINTVAL (x
) & GET_MODE_MASK (mode
);
5018 if (bitwidth
<= HOST_BITS_PER_WIDE_INT
5019 && (nonzero
& (HOST_WIDE_INT_1U
<< (bitwidth
- 1))) != 0)
5020 nonzero
= (~nonzero
) & GET_MODE_MASK (mode
);
5022 return (nonzero
== 0 ? bitwidth
: bitwidth
- floor_log2 (nonzero
) - 1);
5025 scalar_int_mode xmode
, inner_mode
;
5026 if (!is_a
<scalar_int_mode
> (GET_MODE (x
), &xmode
))
5029 unsigned int xmode_width
= GET_MODE_PRECISION (xmode
);
5031 /* For a smaller mode, just ignore the high bits. */
5032 if (bitwidth
< xmode_width
)
5034 num0
= cached_num_sign_bit_copies (x
, xmode
,
5035 known_x
, known_mode
, known_ret
);
5036 return MAX (1, num0
- (int) (xmode_width
- bitwidth
));
5039 if (bitwidth
> xmode_width
)
5041 /* If this machine does not do all register operations on the entire
5042 register and MODE is wider than the mode of X, we can say nothing
5043 at all about the high-order bits. We extend this reasoning to RISC
5044 machines for operations that might not operate on full registers. */
5045 if (!(WORD_REGISTER_OPERATIONS
&& word_register_operation_p (x
)))
5048 /* Likewise on machines that do, if the mode of the object is smaller
5049 than a word and loads of that size don't sign extend, we can say
5050 nothing about the high order bits. */
5051 if (xmode_width
< BITS_PER_WORD
5052 && load_extend_op (xmode
) != SIGN_EXTEND
)
5056 /* Please keep num_sign_bit_copies_binary_arith_p above in sync with
5057 the code in the switch below. */
5062 #if defined(POINTERS_EXTEND_UNSIGNED)
5063 /* If pointers extend signed and this is a pointer in Pmode, say that
5064 all the bits above ptr_mode are known to be sign bit copies. */
5065 /* As we do not know which address space the pointer is referring to,
5066 we can do this only if the target does not support different pointer
5067 or address modes depending on the address space. */
5068 if (target_default_pointer_address_modes_p ()
5069 && ! POINTERS_EXTEND_UNSIGNED
&& xmode
== Pmode
5070 && mode
== Pmode
&& REG_POINTER (x
)
5071 && !targetm
.have_ptr_extend ())
5072 return GET_MODE_PRECISION (Pmode
) - GET_MODE_PRECISION (ptr_mode
) + 1;
5076 unsigned int copies_for_hook
= 1, copies
= 1;
5077 rtx new_rtx
= rtl_hooks
.reg_num_sign_bit_copies (x
, xmode
, mode
,
5081 copies
= cached_num_sign_bit_copies (new_rtx
, mode
, known_x
,
5082 known_mode
, known_ret
);
5084 if (copies
> 1 || copies_for_hook
> 1)
5085 return MAX (copies
, copies_for_hook
);
5087 /* Else, use nonzero_bits to guess num_sign_bit_copies (see below). */
5092 /* Some RISC machines sign-extend all loads of smaller than a word. */
5093 if (load_extend_op (xmode
) == SIGN_EXTEND
)
5094 return MAX (1, ((int) bitwidth
- (int) xmode_width
+ 1));
5098 /* If this is a SUBREG for a promoted object that is sign-extended
5099 and we are looking at it in a wider mode, we know that at least the
5100 high-order bits are known to be sign bit copies. */
5102 if (SUBREG_PROMOTED_VAR_P (x
) && SUBREG_PROMOTED_SIGNED_P (x
))
5104 num0
= cached_num_sign_bit_copies (SUBREG_REG (x
), mode
,
5105 known_x
, known_mode
, known_ret
);
5106 return MAX ((int) bitwidth
- (int) xmode_width
+ 1, num0
);
5109 if (is_a
<scalar_int_mode
> (GET_MODE (SUBREG_REG (x
)), &inner_mode
))
5111 /* For a smaller object, just ignore the high bits. */
5112 if (bitwidth
<= GET_MODE_PRECISION (inner_mode
))
5114 num0
= cached_num_sign_bit_copies (SUBREG_REG (x
), inner_mode
,
5115 known_x
, known_mode
,
5117 return MAX (1, num0
- (int) (GET_MODE_PRECISION (inner_mode
)
5121 /* For paradoxical SUBREGs on machines where all register operations
5122 affect the entire register, just look inside. Note that we are
5123 passing MODE to the recursive call, so the number of sign bit
5124 copies will remain relative to that mode, not the inner mode.
5126 This works only if loads sign extend. Otherwise, if we get a
5127 reload for the inner part, it may be loaded from the stack, and
5128 then we lose all sign bit copies that existed before the store
5130 if (WORD_REGISTER_OPERATIONS
5131 && load_extend_op (inner_mode
) == SIGN_EXTEND
5132 && paradoxical_subreg_p (x
)
5133 && MEM_P (SUBREG_REG (x
)))
5134 return cached_num_sign_bit_copies (SUBREG_REG (x
), mode
,
5135 known_x
, known_mode
, known_ret
);
5140 if (CONST_INT_P (XEXP (x
, 1)))
5141 return MAX (1, (int) bitwidth
- INTVAL (XEXP (x
, 1)));
5145 if (is_a
<scalar_int_mode
> (GET_MODE (XEXP (x
, 0)), &inner_mode
))
5146 return (bitwidth
- GET_MODE_PRECISION (inner_mode
)
5147 + cached_num_sign_bit_copies (XEXP (x
, 0), inner_mode
,
5148 known_x
, known_mode
, known_ret
));
5152 /* For a smaller object, just ignore the high bits. */
5153 inner_mode
= as_a
<scalar_int_mode
> (GET_MODE (XEXP (x
, 0)));
5154 num0
= cached_num_sign_bit_copies (XEXP (x
, 0), inner_mode
,
5155 known_x
, known_mode
, known_ret
);
5156 return MAX (1, (num0
- (int) (GET_MODE_PRECISION (inner_mode
)
5160 return cached_num_sign_bit_copies (XEXP (x
, 0), mode
,
5161 known_x
, known_mode
, known_ret
);
5163 case ROTATE
: case ROTATERT
:
5164 /* If we are rotating left by a number of bits less than the number
5165 of sign bit copies, we can just subtract that amount from the
5167 if (CONST_INT_P (XEXP (x
, 1))
5168 && INTVAL (XEXP (x
, 1)) >= 0
5169 && INTVAL (XEXP (x
, 1)) < (int) bitwidth
)
5171 num0
= cached_num_sign_bit_copies (XEXP (x
, 0), mode
,
5172 known_x
, known_mode
, known_ret
);
5173 return MAX (1, num0
- (code
== ROTATE
? INTVAL (XEXP (x
, 1))
5174 : (int) bitwidth
- INTVAL (XEXP (x
, 1))));
5179 /* In general, this subtracts one sign bit copy. But if the value
5180 is known to be positive, the number of sign bit copies is the
5181 same as that of the input. Finally, if the input has just one bit
5182 that might be nonzero, all the bits are copies of the sign bit. */
5183 num0
= cached_num_sign_bit_copies (XEXP (x
, 0), mode
,
5184 known_x
, known_mode
, known_ret
);
5185 if (bitwidth
> HOST_BITS_PER_WIDE_INT
)
5186 return num0
> 1 ? num0
- 1 : 1;
5188 nonzero
= nonzero_bits (XEXP (x
, 0), mode
);
5193 && ((HOST_WIDE_INT_1U
<< (bitwidth
- 1)) & nonzero
))
5198 case IOR
: case AND
: case XOR
:
5199 case SMIN
: case SMAX
: case UMIN
: case UMAX
:
5200 /* Logical operations will preserve the number of sign-bit copies.
5201 MIN and MAX operations always return one of the operands. */
5202 num0
= cached_num_sign_bit_copies (XEXP (x
, 0), mode
,
5203 known_x
, known_mode
, known_ret
);
5204 num1
= cached_num_sign_bit_copies (XEXP (x
, 1), mode
,
5205 known_x
, known_mode
, known_ret
);
5207 /* If num1 is clearing some of the top bits then regardless of
5208 the other term, we are guaranteed to have at least that many
5209 high-order zero bits. */
5212 && bitwidth
<= HOST_BITS_PER_WIDE_INT
5213 && CONST_INT_P (XEXP (x
, 1))
5214 && (UINTVAL (XEXP (x
, 1))
5215 & (HOST_WIDE_INT_1U
<< (bitwidth
- 1))) == 0)
5218 /* Similarly for IOR when setting high-order bits. */
5221 && bitwidth
<= HOST_BITS_PER_WIDE_INT
5222 && CONST_INT_P (XEXP (x
, 1))
5223 && (UINTVAL (XEXP (x
, 1))
5224 & (HOST_WIDE_INT_1U
<< (bitwidth
- 1))) != 0)
5227 return MIN (num0
, num1
);
5229 case PLUS
: case MINUS
:
5230 /* For addition and subtraction, we can have a 1-bit carry. However,
5231 if we are subtracting 1 from a positive number, there will not
5232 be such a carry. Furthermore, if the positive number is known to
5233 be 0 or 1, we know the result is either -1 or 0. */
5235 if (code
== PLUS
&& XEXP (x
, 1) == constm1_rtx
5236 && bitwidth
<= HOST_BITS_PER_WIDE_INT
)
5238 nonzero
= nonzero_bits (XEXP (x
, 0), mode
);
5239 if (((HOST_WIDE_INT_1U
<< (bitwidth
- 1)) & nonzero
) == 0)
5240 return (nonzero
== 1 || nonzero
== 0 ? bitwidth
5241 : bitwidth
- floor_log2 (nonzero
) - 1);
5244 num0
= cached_num_sign_bit_copies (XEXP (x
, 0), mode
,
5245 known_x
, known_mode
, known_ret
);
5246 num1
= cached_num_sign_bit_copies (XEXP (x
, 1), mode
,
5247 known_x
, known_mode
, known_ret
);
5248 result
= MAX (1, MIN (num0
, num1
) - 1);
5253 /* The number of bits of the product is the sum of the number of
5254 bits of both terms. However, unless one of the terms if known
5255 to be positive, we must allow for an additional bit since negating
5256 a negative number can remove one sign bit copy. */
5258 num0
= cached_num_sign_bit_copies (XEXP (x
, 0), mode
,
5259 known_x
, known_mode
, known_ret
);
5260 num1
= cached_num_sign_bit_copies (XEXP (x
, 1), mode
,
5261 known_x
, known_mode
, known_ret
);
5263 result
= bitwidth
- (bitwidth
- num0
) - (bitwidth
- num1
);
5265 && (bitwidth
> HOST_BITS_PER_WIDE_INT
5266 || (((nonzero_bits (XEXP (x
, 0), mode
)
5267 & (HOST_WIDE_INT_1U
<< (bitwidth
- 1))) != 0)
5268 && ((nonzero_bits (XEXP (x
, 1), mode
)
5269 & (HOST_WIDE_INT_1U
<< (bitwidth
- 1)))
5273 return MAX (1, result
);
5276 /* The result must be <= the first operand. If the first operand
5277 has the high bit set, we know nothing about the number of sign
5279 if (bitwidth
> HOST_BITS_PER_WIDE_INT
)
5281 else if ((nonzero_bits (XEXP (x
, 0), mode
)
5282 & (HOST_WIDE_INT_1U
<< (bitwidth
- 1))) != 0)
5285 return cached_num_sign_bit_copies (XEXP (x
, 0), mode
,
5286 known_x
, known_mode
, known_ret
);
5289 /* The result must be <= the second operand. If the second operand
5290 has (or just might have) the high bit set, we know nothing about
5291 the number of sign bit copies. */
5292 if (bitwidth
> HOST_BITS_PER_WIDE_INT
)
5294 else if ((nonzero_bits (XEXP (x
, 1), mode
)
5295 & (HOST_WIDE_INT_1U
<< (bitwidth
- 1))) != 0)
5298 return cached_num_sign_bit_copies (XEXP (x
, 1), mode
,
5299 known_x
, known_mode
, known_ret
);
5302 /* Similar to unsigned division, except that we have to worry about
5303 the case where the divisor is negative, in which case we have
5305 result
= cached_num_sign_bit_copies (XEXP (x
, 0), mode
,
5306 known_x
, known_mode
, known_ret
);
5308 && (bitwidth
> HOST_BITS_PER_WIDE_INT
5309 || (nonzero_bits (XEXP (x
, 1), mode
)
5310 & (HOST_WIDE_INT_1U
<< (bitwidth
- 1))) != 0))
5316 result
= cached_num_sign_bit_copies (XEXP (x
, 1), mode
,
5317 known_x
, known_mode
, known_ret
);
5319 && (bitwidth
> HOST_BITS_PER_WIDE_INT
5320 || (nonzero_bits (XEXP (x
, 1), mode
)
5321 & (HOST_WIDE_INT_1U
<< (bitwidth
- 1))) != 0))
5327 /* Shifts by a constant add to the number of bits equal to the
5329 num0
= cached_num_sign_bit_copies (XEXP (x
, 0), mode
,
5330 known_x
, known_mode
, known_ret
);
5331 if (CONST_INT_P (XEXP (x
, 1))
5332 && INTVAL (XEXP (x
, 1)) > 0
5333 && INTVAL (XEXP (x
, 1)) < xmode_width
)
5334 num0
= MIN ((int) bitwidth
, num0
+ INTVAL (XEXP (x
, 1)));
5339 /* Left shifts destroy copies. */
5340 if (!CONST_INT_P (XEXP (x
, 1))
5341 || INTVAL (XEXP (x
, 1)) < 0
5342 || INTVAL (XEXP (x
, 1)) >= (int) bitwidth
5343 || INTVAL (XEXP (x
, 1)) >= xmode_width
)
5346 num0
= cached_num_sign_bit_copies (XEXP (x
, 0), mode
,
5347 known_x
, known_mode
, known_ret
);
5348 return MAX (1, num0
- INTVAL (XEXP (x
, 1)));
5351 num0
= cached_num_sign_bit_copies (XEXP (x
, 1), mode
,
5352 known_x
, known_mode
, known_ret
);
5353 num1
= cached_num_sign_bit_copies (XEXP (x
, 2), mode
,
5354 known_x
, known_mode
, known_ret
);
5355 return MIN (num0
, num1
);
5357 case EQ
: case NE
: case GE
: case GT
: case LE
: case LT
:
5358 case UNEQ
: case LTGT
: case UNGE
: case UNGT
: case UNLE
: case UNLT
:
5359 case GEU
: case GTU
: case LEU
: case LTU
:
5360 case UNORDERED
: case ORDERED
:
5361 /* If the constant is negative, take its 1's complement and remask.
5362 Then see how many zero bits we have. */
5363 nonzero
= STORE_FLAG_VALUE
;
5364 if (bitwidth
<= HOST_BITS_PER_WIDE_INT
5365 && (nonzero
& (HOST_WIDE_INT_1U
<< (bitwidth
- 1))) != 0)
5366 nonzero
= (~nonzero
) & GET_MODE_MASK (mode
);
5368 return (nonzero
== 0 ? bitwidth
: bitwidth
- floor_log2 (nonzero
) - 1);
5374 /* If we haven't been able to figure it out by one of the above rules,
5375 see if some of the high-order bits are known to be zero. If so,
5376 count those bits and return one less than that amount. If we can't
5377 safely compute the mask for this mode, always return BITWIDTH. */
5379 bitwidth
= GET_MODE_PRECISION (mode
);
5380 if (bitwidth
> HOST_BITS_PER_WIDE_INT
)
5383 nonzero
= nonzero_bits (x
, mode
);
5384 return nonzero
& (HOST_WIDE_INT_1U
<< (bitwidth
- 1))
5385 ? 1 : bitwidth
- floor_log2 (nonzero
) - 1;
5388 /* Calculate the rtx_cost of a single instruction pattern. A return value of
5389 zero indicates an instruction pattern without a known cost. */
5392 pattern_cost (rtx pat
, bool speed
)
5397 /* Extract the single set rtx from the instruction pattern. We
5398 can't use single_set since we only have the pattern. We also
5399 consider PARALLELs of a normal set and a single comparison. In
5400 that case we use the cost of the non-comparison SET operation,
5401 which is most-likely to be the real cost of this operation. */
5402 if (GET_CODE (pat
) == SET
)
5404 else if (GET_CODE (pat
) == PARALLEL
)
5407 rtx comparison
= NULL_RTX
;
5409 for (i
= 0; i
< XVECLEN (pat
, 0); i
++)
5411 rtx x
= XVECEXP (pat
, 0, i
);
5412 if (GET_CODE (x
) == SET
)
5414 if (GET_CODE (SET_SRC (x
)) == COMPARE
)
5429 if (!set
&& comparison
)
5438 cost
= set_src_cost (SET_SRC (set
), GET_MODE (SET_DEST (set
)), speed
);
5439 return cost
> 0 ? cost
: COSTS_N_INSNS (1);
5442 /* Calculate the cost of a single instruction. A return value of zero
5443 indicates an instruction pattern without a known cost. */
5446 insn_cost (rtx_insn
*insn
, bool speed
)
5448 if (targetm
.insn_cost
)
5449 return targetm
.insn_cost (insn
, speed
);
5451 return pattern_cost (PATTERN (insn
), speed
);
5454 /* Returns estimate on cost of computing SEQ. */
5457 seq_cost (const rtx_insn
*seq
, bool speed
)
5462 for (; seq
; seq
= NEXT_INSN (seq
))
5464 set
= single_set (seq
);
5466 cost
+= set_rtx_cost (set
, speed
);
5467 else if (NONDEBUG_INSN_P (seq
))
5469 int this_cost
= insn_cost (CONST_CAST_RTX_INSN (seq
), speed
);
5480 /* Given an insn INSN and condition COND, return the condition in a
5481 canonical form to simplify testing by callers. Specifically:
5483 (1) The code will always be a comparison operation (EQ, NE, GT, etc.).
5484 (2) Both operands will be machine operands; (cc0) will have been replaced.
5485 (3) If an operand is a constant, it will be the second operand.
5486 (4) (LE x const) will be replaced with (LT x <const+1>) and similarly
5487 for GE, GEU, and LEU.
5489 If the condition cannot be understood, or is an inequality floating-point
5490 comparison which needs to be reversed, 0 will be returned.
5492 If REVERSE is nonzero, then reverse the condition prior to canonizing it.
5494 If EARLIEST is nonzero, it is a pointer to a place where the earliest
5495 insn used in locating the condition was found. If a replacement test
5496 of the condition is desired, it should be placed in front of that
5497 insn and we will be sure that the inputs are still valid.
5499 If WANT_REG is nonzero, we wish the condition to be relative to that
5500 register, if possible. Therefore, do not canonicalize the condition
5501 further. If ALLOW_CC_MODE is nonzero, allow the condition returned
5502 to be a compare to a CC mode register.
5504 If VALID_AT_INSN_P, the condition must be valid at both *EARLIEST
5508 canonicalize_condition (rtx_insn
*insn
, rtx cond
, int reverse
,
5509 rtx_insn
**earliest
,
5510 rtx want_reg
, int allow_cc_mode
, int valid_at_insn_p
)
5513 rtx_insn
*prev
= insn
;
5517 int reverse_code
= 0;
5519 basic_block bb
= BLOCK_FOR_INSN (insn
);
5521 code
= GET_CODE (cond
);
5522 mode
= GET_MODE (cond
);
5523 op0
= XEXP (cond
, 0);
5524 op1
= XEXP (cond
, 1);
5527 code
= reversed_comparison_code (cond
, insn
);
5528 if (code
== UNKNOWN
)
5534 /* If we are comparing a register with zero, see if the register is set
5535 in the previous insn to a COMPARE or a comparison operation. Perform
5536 the same tests as a function of STORE_FLAG_VALUE as find_comparison_args
5539 while ((GET_RTX_CLASS (code
) == RTX_COMPARE
5540 || GET_RTX_CLASS (code
) == RTX_COMM_COMPARE
)
5541 && op1
== CONST0_RTX (GET_MODE (op0
))
5544 /* Set nonzero when we find something of interest. */
5547 /* If comparison with cc0, import actual comparison from compare
5551 if ((prev
= prev_nonnote_insn (prev
)) == 0
5552 || !NONJUMP_INSN_P (prev
)
5553 || (set
= single_set (prev
)) == 0
5554 || SET_DEST (set
) != cc0_rtx
)
5557 op0
= SET_SRC (set
);
5558 op1
= CONST0_RTX (GET_MODE (op0
));
5563 /* If this is a COMPARE, pick up the two things being compared. */
5564 if (GET_CODE (op0
) == COMPARE
)
5566 op1
= XEXP (op0
, 1);
5567 op0
= XEXP (op0
, 0);
5570 else if (!REG_P (op0
))
5573 /* Go back to the previous insn. Stop if it is not an INSN. We also
5574 stop if it isn't a single set or if it has a REG_INC note because
5575 we don't want to bother dealing with it. */
5577 prev
= prev_nonnote_nondebug_insn (prev
);
5580 || !NONJUMP_INSN_P (prev
)
5581 || FIND_REG_INC_NOTE (prev
, NULL_RTX
)
5582 /* In cfglayout mode, there do not have to be labels at the
5583 beginning of a block, or jumps at the end, so the previous
5584 conditions would not stop us when we reach bb boundary. */
5585 || BLOCK_FOR_INSN (prev
) != bb
)
5588 set
= set_of (op0
, prev
);
5591 && (GET_CODE (set
) != SET
5592 || !rtx_equal_p (SET_DEST (set
), op0
)))
5595 /* If this is setting OP0, get what it sets it to if it looks
5599 machine_mode inner_mode
= GET_MODE (SET_DEST (set
));
5600 #ifdef FLOAT_STORE_FLAG_VALUE
5601 REAL_VALUE_TYPE fsfv
;
5604 /* ??? We may not combine comparisons done in a CCmode with
5605 comparisons not done in a CCmode. This is to aid targets
5606 like Alpha that have an IEEE compliant EQ instruction, and
5607 a non-IEEE compliant BEQ instruction. The use of CCmode is
5608 actually artificial, simply to prevent the combination, but
5609 should not affect other platforms.
5611 However, we must allow VOIDmode comparisons to match either
5612 CCmode or non-CCmode comparison, because some ports have
5613 modeless comparisons inside branch patterns.
5615 ??? This mode check should perhaps look more like the mode check
5616 in simplify_comparison in combine. */
5617 if (((GET_MODE_CLASS (mode
) == MODE_CC
)
5618 != (GET_MODE_CLASS (inner_mode
) == MODE_CC
))
5620 && inner_mode
!= VOIDmode
)
5622 if (GET_CODE (SET_SRC (set
)) == COMPARE
5625 && val_signbit_known_set_p (inner_mode
,
5627 #ifdef FLOAT_STORE_FLAG_VALUE
5629 && SCALAR_FLOAT_MODE_P (inner_mode
)
5630 && (fsfv
= FLOAT_STORE_FLAG_VALUE (inner_mode
),
5631 REAL_VALUE_NEGATIVE (fsfv
)))
5634 && COMPARISON_P (SET_SRC (set
))))
5636 else if (((code
== EQ
5638 && val_signbit_known_set_p (inner_mode
,
5640 #ifdef FLOAT_STORE_FLAG_VALUE
5642 && SCALAR_FLOAT_MODE_P (inner_mode
)
5643 && (fsfv
= FLOAT_STORE_FLAG_VALUE (inner_mode
),
5644 REAL_VALUE_NEGATIVE (fsfv
)))
5647 && COMPARISON_P (SET_SRC (set
)))
5652 else if ((code
== EQ
|| code
== NE
)
5653 && GET_CODE (SET_SRC (set
)) == XOR
)
5654 /* Handle sequences like:
5657 ...(eq|ne op0 (const_int 0))...
5661 (eq op0 (const_int 0)) reduces to (eq X Y)
5662 (ne op0 (const_int 0)) reduces to (ne X Y)
5664 This is the form used by MIPS16, for example. */
5670 else if (reg_set_p (op0
, prev
))
5671 /* If this sets OP0, but not directly, we have to give up. */
5676 /* If the caller is expecting the condition to be valid at INSN,
5677 make sure X doesn't change before INSN. */
5678 if (valid_at_insn_p
)
5679 if (modified_in_p (x
, prev
) || modified_between_p (x
, prev
, insn
))
5681 if (COMPARISON_P (x
))
5682 code
= GET_CODE (x
);
5685 code
= reversed_comparison_code (x
, prev
);
5686 if (code
== UNKNOWN
)
5691 op0
= XEXP (x
, 0), op1
= XEXP (x
, 1);
5697 /* If constant is first, put it last. */
5698 if (CONSTANT_P (op0
))
5699 code
= swap_condition (code
), tem
= op0
, op0
= op1
, op1
= tem
;
5701 /* If OP0 is the result of a comparison, we weren't able to find what
5702 was really being compared, so fail. */
5704 && GET_MODE_CLASS (GET_MODE (op0
)) == MODE_CC
)
5707 /* Canonicalize any ordered comparison with integers involving equality
5708 if we can do computations in the relevant mode and we do not
5711 scalar_int_mode op0_mode
;
5712 if (CONST_INT_P (op1
)
5713 && is_a
<scalar_int_mode
> (GET_MODE (op0
), &op0_mode
)
5714 && GET_MODE_PRECISION (op0_mode
) <= HOST_BITS_PER_WIDE_INT
)
5716 HOST_WIDE_INT const_val
= INTVAL (op1
);
5717 unsigned HOST_WIDE_INT uconst_val
= const_val
;
5718 unsigned HOST_WIDE_INT max_val
5719 = (unsigned HOST_WIDE_INT
) GET_MODE_MASK (op0_mode
);
5724 if ((unsigned HOST_WIDE_INT
) const_val
!= max_val
>> 1)
5725 code
= LT
, op1
= gen_int_mode (const_val
+ 1, op0_mode
);
5728 /* When cross-compiling, const_val might be sign-extended from
5729 BITS_PER_WORD to HOST_BITS_PER_WIDE_INT */
5731 if ((const_val
& max_val
)
5732 != (HOST_WIDE_INT_1U
<< (GET_MODE_PRECISION (op0_mode
) - 1)))
5733 code
= GT
, op1
= gen_int_mode (const_val
- 1, op0_mode
);
5737 if (uconst_val
< max_val
)
5738 code
= LTU
, op1
= gen_int_mode (uconst_val
+ 1, op0_mode
);
5742 if (uconst_val
!= 0)
5743 code
= GTU
, op1
= gen_int_mode (uconst_val
- 1, op0_mode
);
5751 /* Never return CC0; return zero instead. */
5755 /* We promised to return a comparison. */
5756 rtx ret
= gen_rtx_fmt_ee (code
, VOIDmode
, op0
, op1
);
5757 if (COMPARISON_P (ret
))
5762 /* Given a jump insn JUMP, return the condition that will cause it to branch
5763 to its JUMP_LABEL. If the condition cannot be understood, or is an
5764 inequality floating-point comparison which needs to be reversed, 0 will
5767 If EARLIEST is nonzero, it is a pointer to a place where the earliest
5768 insn used in locating the condition was found. If a replacement test
5769 of the condition is desired, it should be placed in front of that
5770 insn and we will be sure that the inputs are still valid. If EARLIEST
5771 is null, the returned condition will be valid at INSN.
5773 If ALLOW_CC_MODE is nonzero, allow the condition returned to be a
5774 compare CC mode register.
5776 VALID_AT_INSN_P is the same as for canonicalize_condition. */
5779 get_condition (rtx_insn
*jump
, rtx_insn
**earliest
, int allow_cc_mode
,
5780 int valid_at_insn_p
)
5786 /* If this is not a standard conditional jump, we can't parse it. */
5788 || ! any_condjump_p (jump
))
5790 set
= pc_set (jump
);
5792 cond
= XEXP (SET_SRC (set
), 0);
5794 /* If this branches to JUMP_LABEL when the condition is false, reverse
5797 = GET_CODE (XEXP (SET_SRC (set
), 2)) == LABEL_REF
5798 && label_ref_label (XEXP (SET_SRC (set
), 2)) == JUMP_LABEL (jump
);
5800 return canonicalize_condition (jump
, cond
, reverse
, earliest
, NULL_RTX
,
5801 allow_cc_mode
, valid_at_insn_p
);
5804 /* Initialize the table NUM_SIGN_BIT_COPIES_IN_REP based on
5805 TARGET_MODE_REP_EXTENDED.
5807 Note that we assume that the property of
5808 TARGET_MODE_REP_EXTENDED(B, C) is sticky to the integral modes
5809 narrower than mode B. I.e., if A is a mode narrower than B then in
5810 order to be able to operate on it in mode B, mode A needs to
5811 satisfy the requirements set by the representation of mode B. */
5814 init_num_sign_bit_copies_in_rep (void)
5816 opt_scalar_int_mode in_mode_iter
;
5817 scalar_int_mode mode
;
5819 FOR_EACH_MODE_IN_CLASS (in_mode_iter
, MODE_INT
)
5820 FOR_EACH_MODE_UNTIL (mode
, in_mode_iter
.require ())
5822 scalar_int_mode in_mode
= in_mode_iter
.require ();
5825 /* Currently, it is assumed that TARGET_MODE_REP_EXTENDED
5826 extends to the next widest mode. */
5827 gcc_assert (targetm
.mode_rep_extended (mode
, in_mode
) == UNKNOWN
5828 || GET_MODE_WIDER_MODE (mode
).require () == in_mode
);
5830 /* We are in in_mode. Count how many bits outside of mode
5831 have to be copies of the sign-bit. */
5832 FOR_EACH_MODE (i
, mode
, in_mode
)
5834 /* This must always exist (for the last iteration it will be
5836 scalar_int_mode wider
= GET_MODE_WIDER_MODE (i
).require ();
5838 if (targetm
.mode_rep_extended (i
, wider
) == SIGN_EXTEND
5839 /* We can only check sign-bit copies starting from the
5840 top-bit. In order to be able to check the bits we
5841 have already seen we pretend that subsequent bits
5842 have to be sign-bit copies too. */
5843 || num_sign_bit_copies_in_rep
[in_mode
][mode
])
5844 num_sign_bit_copies_in_rep
[in_mode
][mode
]
5845 += GET_MODE_PRECISION (wider
) - GET_MODE_PRECISION (i
);
5850 /* Suppose that truncation from the machine mode of X to MODE is not a
5851 no-op. See if there is anything special about X so that we can
5852 assume it already contains a truncated value of MODE. */
5855 truncated_to_mode (machine_mode mode
, const_rtx x
)
5857 /* This register has already been used in MODE without explicit
5859 if (REG_P (x
) && rtl_hooks
.reg_truncated_to_mode (mode
, x
))
5862 /* See if we already satisfy the requirements of MODE. If yes we
5863 can just switch to MODE. */
5864 if (num_sign_bit_copies_in_rep
[GET_MODE (x
)][mode
]
5865 && (num_sign_bit_copies (x
, GET_MODE (x
))
5866 >= num_sign_bit_copies_in_rep
[GET_MODE (x
)][mode
] + 1))
5872 /* Return true if RTX code CODE has a single sequence of zero or more
5873 "e" operands and no rtvec operands. Initialize its rtx_all_subrtx_bounds
5874 entry in that case. */
5877 setup_reg_subrtx_bounds (unsigned int code
)
5879 const char *format
= GET_RTX_FORMAT ((enum rtx_code
) code
);
5881 for (; format
[i
] != 'e'; ++i
)
5884 /* No subrtxes. Leave start and count as 0. */
5886 if (format
[i
] == 'E' || format
[i
] == 'V')
5890 /* Record the sequence of 'e's. */
5891 rtx_all_subrtx_bounds
[code
].start
= i
;
5894 while (format
[i
] == 'e');
5895 rtx_all_subrtx_bounds
[code
].count
= i
- rtx_all_subrtx_bounds
[code
].start
;
5896 /* rtl-iter.h relies on this. */
5897 gcc_checking_assert (rtx_all_subrtx_bounds
[code
].count
<= 3);
5899 for (; format
[i
]; ++i
)
5900 if (format
[i
] == 'E' || format
[i
] == 'V' || format
[i
] == 'e')
5906 /* Initialize rtx_all_subrtx_bounds. */
5911 for (i
= 0; i
< NUM_RTX_CODE
; i
++)
5913 if (!setup_reg_subrtx_bounds (i
))
5914 rtx_all_subrtx_bounds
[i
].count
= UCHAR_MAX
;
5915 if (GET_RTX_CLASS (i
) != RTX_CONST_OBJ
)
5916 rtx_nonconst_subrtx_bounds
[i
] = rtx_all_subrtx_bounds
[i
];
5919 init_num_sign_bit_copies_in_rep ();
5922 /* Check whether this is a constant pool constant. */
5924 constant_pool_constant_p (rtx x
)
5926 x
= avoid_constant_pool_reference (x
);
5927 return CONST_DOUBLE_P (x
);
5930 /* If M is a bitmask that selects a field of low-order bits within an item but
5931 not the entire word, return the length of the field. Return -1 otherwise.
5932 M is used in machine mode MODE. */
5935 low_bitmask_len (machine_mode mode
, unsigned HOST_WIDE_INT m
)
5937 if (mode
!= VOIDmode
)
5939 if (!HWI_COMPUTABLE_MODE_P (mode
))
5941 m
&= GET_MODE_MASK (mode
);
5944 return exact_log2 (m
+ 1);
5947 /* Return the mode of MEM's address. */
5950 get_address_mode (rtx mem
)
5954 gcc_assert (MEM_P (mem
));
5955 mode
= GET_MODE (XEXP (mem
, 0));
5956 if (mode
!= VOIDmode
)
5957 return as_a
<scalar_int_mode
> (mode
);
5958 return targetm
.addr_space
.address_mode (MEM_ADDR_SPACE (mem
));
5961 /* Split up a CONST_DOUBLE or integer constant rtx
5962 into two rtx's for single words,
5963 storing in *FIRST the word that comes first in memory in the target
5964 and in *SECOND the other.
5966 TODO: This function needs to be rewritten to work on any size
5970 split_double (rtx value
, rtx
*first
, rtx
*second
)
5972 if (CONST_INT_P (value
))
5974 if (HOST_BITS_PER_WIDE_INT
>= (2 * BITS_PER_WORD
))
5976 /* In this case the CONST_INT holds both target words.
5977 Extract the bits from it into two word-sized pieces.
5978 Sign extend each half to HOST_WIDE_INT. */
5979 unsigned HOST_WIDE_INT low
, high
;
5980 unsigned HOST_WIDE_INT mask
, sign_bit
, sign_extend
;
5981 unsigned bits_per_word
= BITS_PER_WORD
;
5983 /* Set sign_bit to the most significant bit of a word. */
5985 sign_bit
<<= bits_per_word
- 1;
5987 /* Set mask so that all bits of the word are set. We could
5988 have used 1 << BITS_PER_WORD instead of basing the
5989 calculation on sign_bit. However, on machines where
5990 HOST_BITS_PER_WIDE_INT == BITS_PER_WORD, it could cause a
5991 compiler warning, even though the code would never be
5993 mask
= sign_bit
<< 1;
5996 /* Set sign_extend as any remaining bits. */
5997 sign_extend
= ~mask
;
5999 /* Pick the lower word and sign-extend it. */
6000 low
= INTVAL (value
);
6005 /* Pick the higher word, shifted to the least significant
6006 bits, and sign-extend it. */
6007 high
= INTVAL (value
);
6008 high
>>= bits_per_word
- 1;
6011 if (high
& sign_bit
)
6012 high
|= sign_extend
;
6014 /* Store the words in the target machine order. */
6015 if (WORDS_BIG_ENDIAN
)
6017 *first
= GEN_INT (high
);
6018 *second
= GEN_INT (low
);
6022 *first
= GEN_INT (low
);
6023 *second
= GEN_INT (high
);
6028 /* The rule for using CONST_INT for a wider mode
6029 is that we regard the value as signed.
6030 So sign-extend it. */
6031 rtx high
= (INTVAL (value
) < 0 ? constm1_rtx
: const0_rtx
);
6032 if (WORDS_BIG_ENDIAN
)
6044 else if (GET_CODE (value
) == CONST_WIDE_INT
)
6046 /* All of this is scary code and needs to be converted to
6047 properly work with any size integer. */
6048 gcc_assert (CONST_WIDE_INT_NUNITS (value
) == 2);
6049 if (WORDS_BIG_ENDIAN
)
6051 *first
= GEN_INT (CONST_WIDE_INT_ELT (value
, 1));
6052 *second
= GEN_INT (CONST_WIDE_INT_ELT (value
, 0));
6056 *first
= GEN_INT (CONST_WIDE_INT_ELT (value
, 0));
6057 *second
= GEN_INT (CONST_WIDE_INT_ELT (value
, 1));
6060 else if (!CONST_DOUBLE_P (value
))
6062 if (WORDS_BIG_ENDIAN
)
6064 *first
= const0_rtx
;
6070 *second
= const0_rtx
;
6073 else if (GET_MODE (value
) == VOIDmode
6074 /* This is the old way we did CONST_DOUBLE integers. */
6075 || GET_MODE_CLASS (GET_MODE (value
)) == MODE_INT
)
6077 /* In an integer, the words are defined as most and least significant.
6078 So order them by the target's convention. */
6079 if (WORDS_BIG_ENDIAN
)
6081 *first
= GEN_INT (CONST_DOUBLE_HIGH (value
));
6082 *second
= GEN_INT (CONST_DOUBLE_LOW (value
));
6086 *first
= GEN_INT (CONST_DOUBLE_LOW (value
));
6087 *second
= GEN_INT (CONST_DOUBLE_HIGH (value
));
6094 /* Note, this converts the REAL_VALUE_TYPE to the target's
6095 format, splits up the floating point double and outputs
6096 exactly 32 bits of it into each of l[0] and l[1] --
6097 not necessarily BITS_PER_WORD bits. */
6098 REAL_VALUE_TO_TARGET_DOUBLE (*CONST_DOUBLE_REAL_VALUE (value
), l
);
6100 /* If 32 bits is an entire word for the target, but not for the host,
6101 then sign-extend on the host so that the number will look the same
6102 way on the host that it would on the target. See for instance
6103 simplify_unary_operation. The #if is needed to avoid compiler
6106 #if HOST_BITS_PER_LONG > 32
6107 if (BITS_PER_WORD
< HOST_BITS_PER_LONG
&& BITS_PER_WORD
== 32)
6109 if (l
[0] & ((long) 1 << 31))
6110 l
[0] |= ((unsigned long) (-1) << 32);
6111 if (l
[1] & ((long) 1 << 31))
6112 l
[1] |= ((unsigned long) (-1) << 32);
6116 *first
= GEN_INT (l
[0]);
6117 *second
= GEN_INT (l
[1]);
6121 /* Return true if X is a sign_extract or zero_extract from the least
6125 lsb_bitfield_op_p (rtx x
)
6127 if (GET_RTX_CLASS (GET_CODE (x
)) == RTX_BITFIELD_OPS
)
6129 machine_mode mode
= GET_MODE (XEXP (x
, 0));
6130 HOST_WIDE_INT len
= INTVAL (XEXP (x
, 1));
6131 HOST_WIDE_INT pos
= INTVAL (XEXP (x
, 2));
6132 poly_int64 remaining_bits
= GET_MODE_PRECISION (mode
) - len
;
6134 return known_eq (pos
, BITS_BIG_ENDIAN
? remaining_bits
: 0);
6139 /* Strip outer address "mutations" from LOC and return a pointer to the
6140 inner value. If OUTER_CODE is nonnull, store the code of the innermost
6141 stripped expression there.
6143 "Mutations" either convert between modes or apply some kind of
6144 extension, truncation or alignment. */
6147 strip_address_mutations (rtx
*loc
, enum rtx_code
*outer_code
)
6151 enum rtx_code code
= GET_CODE (*loc
);
6152 if (GET_RTX_CLASS (code
) == RTX_UNARY
)
6153 /* Things like SIGN_EXTEND, ZERO_EXTEND and TRUNCATE can be
6154 used to convert between pointer sizes. */
6155 loc
= &XEXP (*loc
, 0);
6156 else if (lsb_bitfield_op_p (*loc
))
6157 /* A [SIGN|ZERO]_EXTRACT from the least significant bit effectively
6158 acts as a combined truncation and extension. */
6159 loc
= &XEXP (*loc
, 0);
6160 else if (code
== AND
&& CONST_INT_P (XEXP (*loc
, 1)))
6161 /* (and ... (const_int -X)) is used to align to X bytes. */
6162 loc
= &XEXP (*loc
, 0);
6163 else if (code
== SUBREG
6164 && !OBJECT_P (SUBREG_REG (*loc
))
6165 && subreg_lowpart_p (*loc
))
6166 /* (subreg (operator ...) ...) inside and is used for mode
6168 loc
= &SUBREG_REG (*loc
);
6176 /* Return true if CODE applies some kind of scale. The scaled value is
6177 is the first operand and the scale is the second. */
6180 binary_scale_code_p (enum rtx_code code
)
6182 return (code
== MULT
6184 /* Needed by ARM targets. */
6188 || code
== ROTATERT
);
6191 /* If *INNER can be interpreted as a base, return a pointer to the inner term
6192 (see address_info). Return null otherwise. */
6195 get_base_term (rtx
*inner
)
6197 if (GET_CODE (*inner
) == LO_SUM
)
6198 inner
= strip_address_mutations (&XEXP (*inner
, 0));
6201 || GET_CODE (*inner
) == SUBREG
6202 || GET_CODE (*inner
) == SCRATCH
)
6207 /* If *INNER can be interpreted as an index, return a pointer to the inner term
6208 (see address_info). Return null otherwise. */
6211 get_index_term (rtx
*inner
)
6213 /* At present, only constant scales are allowed. */
6214 if (binary_scale_code_p (GET_CODE (*inner
)) && CONSTANT_P (XEXP (*inner
, 1)))
6215 inner
= strip_address_mutations (&XEXP (*inner
, 0));
6218 || GET_CODE (*inner
) == SUBREG
6219 || GET_CODE (*inner
) == SCRATCH
)
6224 /* Set the segment part of address INFO to LOC, given that INNER is the
6228 set_address_segment (struct address_info
*info
, rtx
*loc
, rtx
*inner
)
6230 gcc_assert (!info
->segment
);
6231 info
->segment
= loc
;
6232 info
->segment_term
= inner
;
6235 /* Set the base part of address INFO to LOC, given that INNER is the
6239 set_address_base (struct address_info
*info
, rtx
*loc
, rtx
*inner
)
6241 gcc_assert (!info
->base
);
6243 info
->base_term
= inner
;
6246 /* Set the index part of address INFO to LOC, given that INNER is the
6250 set_address_index (struct address_info
*info
, rtx
*loc
, rtx
*inner
)
6252 gcc_assert (!info
->index
);
6254 info
->index_term
= inner
;
6257 /* Set the displacement part of address INFO to LOC, given that INNER
6258 is the constant term. */
6261 set_address_disp (struct address_info
*info
, rtx
*loc
, rtx
*inner
)
6263 gcc_assert (!info
->disp
);
6265 info
->disp_term
= inner
;
6268 /* INFO->INNER describes a {PRE,POST}_{INC,DEC} address. Set up the
6269 rest of INFO accordingly. */
6272 decompose_incdec_address (struct address_info
*info
)
6274 info
->autoinc_p
= true;
6276 rtx
*base
= &XEXP (*info
->inner
, 0);
6277 set_address_base (info
, base
, base
);
6278 gcc_checking_assert (info
->base
== info
->base_term
);
6280 /* These addresses are only valid when the size of the addressed
6282 gcc_checking_assert (info
->mode
!= VOIDmode
);
6285 /* INFO->INNER describes a {PRE,POST}_MODIFY address. Set up the rest
6286 of INFO accordingly. */
6289 decompose_automod_address (struct address_info
*info
)
6291 info
->autoinc_p
= true;
6293 rtx
*base
= &XEXP (*info
->inner
, 0);
6294 set_address_base (info
, base
, base
);
6295 gcc_checking_assert (info
->base
== info
->base_term
);
6297 rtx plus
= XEXP (*info
->inner
, 1);
6298 gcc_assert (GET_CODE (plus
) == PLUS
);
6300 info
->base_term2
= &XEXP (plus
, 0);
6301 gcc_checking_assert (rtx_equal_p (*info
->base_term
, *info
->base_term2
));
6303 rtx
*step
= &XEXP (plus
, 1);
6304 rtx
*inner_step
= strip_address_mutations (step
);
6305 if (CONSTANT_P (*inner_step
))
6306 set_address_disp (info
, step
, inner_step
);
6308 set_address_index (info
, step
, inner_step
);
6311 /* Treat *LOC as a tree of PLUS operands and store pointers to the summed
6312 values in [PTR, END). Return a pointer to the end of the used array. */
6315 extract_plus_operands (rtx
*loc
, rtx
**ptr
, rtx
**end
)
6318 if (GET_CODE (x
) == PLUS
)
6320 ptr
= extract_plus_operands (&XEXP (x
, 0), ptr
, end
);
6321 ptr
= extract_plus_operands (&XEXP (x
, 1), ptr
, end
);
6325 gcc_assert (ptr
!= end
);
6331 /* Evaluate the likelihood of X being a base or index value, returning
6332 positive if it is likely to be a base, negative if it is likely to be
6333 an index, and 0 if we can't tell. Make the magnitude of the return
6334 value reflect the amount of confidence we have in the answer.
6336 MODE, AS, OUTER_CODE and INDEX_CODE are as for ok_for_base_p_1. */
6339 baseness (rtx x
, machine_mode mode
, addr_space_t as
,
6340 enum rtx_code outer_code
, enum rtx_code index_code
)
6342 /* Believe *_POINTER unless the address shape requires otherwise. */
6343 if (REG_P (x
) && REG_POINTER (x
))
6345 if (MEM_P (x
) && MEM_POINTER (x
))
6348 if (REG_P (x
) && HARD_REGISTER_P (x
))
6350 /* X is a hard register. If it only fits one of the base
6351 or index classes, choose that interpretation. */
6352 int regno
= REGNO (x
);
6353 bool base_p
= ok_for_base_p_1 (regno
, mode
, as
, outer_code
, index_code
);
6354 bool index_p
= REGNO_OK_FOR_INDEX_P (regno
);
6355 if (base_p
!= index_p
)
6356 return base_p
? 1 : -1;
6361 /* INFO->INNER describes a normal, non-automodified address.
6362 Fill in the rest of INFO accordingly. */
6365 decompose_normal_address (struct address_info
*info
)
6367 /* Treat the address as the sum of up to four values. */
6369 size_t n_ops
= extract_plus_operands (info
->inner
, ops
,
6370 ops
+ ARRAY_SIZE (ops
)) - ops
;
6372 /* If there is more than one component, any base component is in a PLUS. */
6374 info
->base_outer_code
= PLUS
;
6376 /* Try to classify each sum operand now. Leave those that could be
6377 either a base or an index in OPS. */
6380 for (size_t in
= 0; in
< n_ops
; ++in
)
6383 rtx
*inner
= strip_address_mutations (loc
);
6384 if (CONSTANT_P (*inner
))
6385 set_address_disp (info
, loc
, inner
);
6386 else if (GET_CODE (*inner
) == UNSPEC
)
6387 set_address_segment (info
, loc
, inner
);
6390 /* The only other possibilities are a base or an index. */
6391 rtx
*base_term
= get_base_term (inner
);
6392 rtx
*index_term
= get_index_term (inner
);
6393 gcc_assert (base_term
|| index_term
);
6395 set_address_index (info
, loc
, index_term
);
6396 else if (!index_term
)
6397 set_address_base (info
, loc
, base_term
);
6400 gcc_assert (base_term
== index_term
);
6402 inner_ops
[out
] = base_term
;
6408 /* Classify the remaining OPS members as bases and indexes. */
6411 /* If we haven't seen a base or an index yet, assume that this is
6412 the base. If we were confident that another term was the base
6413 or index, treat the remaining operand as the other kind. */
6415 set_address_base (info
, ops
[0], inner_ops
[0]);
6417 set_address_index (info
, ops
[0], inner_ops
[0]);
6421 /* In the event of a tie, assume the base comes first. */
6422 if (baseness (*inner_ops
[0], info
->mode
, info
->as
, PLUS
,
6424 >= baseness (*inner_ops
[1], info
->mode
, info
->as
, PLUS
,
6425 GET_CODE (*ops
[0])))
6427 set_address_base (info
, ops
[0], inner_ops
[0]);
6428 set_address_index (info
, ops
[1], inner_ops
[1]);
6432 set_address_base (info
, ops
[1], inner_ops
[1]);
6433 set_address_index (info
, ops
[0], inner_ops
[0]);
6437 gcc_assert (out
== 0);
6440 /* Describe address *LOC in *INFO. MODE is the mode of the addressed value,
6441 or VOIDmode if not known. AS is the address space associated with LOC.
6442 OUTER_CODE is MEM if *LOC is a MEM address and ADDRESS otherwise. */
6445 decompose_address (struct address_info
*info
, rtx
*loc
, machine_mode mode
,
6446 addr_space_t as
, enum rtx_code outer_code
)
6448 memset (info
, 0, sizeof (*info
));
6451 info
->addr_outer_code
= outer_code
;
6453 info
->inner
= strip_address_mutations (loc
, &outer_code
);
6454 info
->base_outer_code
= outer_code
;
6455 switch (GET_CODE (*info
->inner
))
6461 decompose_incdec_address (info
);
6466 decompose_automod_address (info
);
6470 decompose_normal_address (info
);
6475 /* Describe address operand LOC in INFO. */
6478 decompose_lea_address (struct address_info
*info
, rtx
*loc
)
6480 decompose_address (info
, loc
, VOIDmode
, ADDR_SPACE_GENERIC
, ADDRESS
);
6483 /* Describe the address of MEM X in INFO. */
6486 decompose_mem_address (struct address_info
*info
, rtx x
)
6488 gcc_assert (MEM_P (x
));
6489 decompose_address (info
, &XEXP (x
, 0), GET_MODE (x
),
6490 MEM_ADDR_SPACE (x
), MEM
);
6493 /* Update INFO after a change to the address it describes. */
6496 update_address (struct address_info
*info
)
6498 decompose_address (info
, info
->outer
, info
->mode
, info
->as
,
6499 info
->addr_outer_code
);
6502 /* Return the scale applied to *INFO->INDEX_TERM, or 0 if the index is
6503 more complicated than that. */
6506 get_index_scale (const struct address_info
*info
)
6508 rtx index
= *info
->index
;
6509 if (GET_CODE (index
) == MULT
6510 && CONST_INT_P (XEXP (index
, 1))
6511 && info
->index_term
== &XEXP (index
, 0))
6512 return INTVAL (XEXP (index
, 1));
6514 if (GET_CODE (index
) == ASHIFT
6515 && CONST_INT_P (XEXP (index
, 1))
6516 && info
->index_term
== &XEXP (index
, 0))
6517 return HOST_WIDE_INT_1
<< INTVAL (XEXP (index
, 1));
6519 if (info
->index
== info
->index_term
)
6525 /* Return the "index code" of INFO, in the form required by
6529 get_index_code (const struct address_info
*info
)
6532 return GET_CODE (*info
->index
);
6535 return GET_CODE (*info
->disp
);
6540 /* Return true if RTL X contains a SYMBOL_REF. */
6543 contains_symbol_ref_p (const_rtx x
)
6545 subrtx_iterator::array_type array
;
6546 FOR_EACH_SUBRTX (iter
, array
, x
, ALL
)
6547 if (SYMBOL_REF_P (*iter
))
6553 /* Return true if RTL X contains a SYMBOL_REF or LABEL_REF. */
6556 contains_symbolic_reference_p (const_rtx x
)
6558 subrtx_iterator::array_type array
;
6559 FOR_EACH_SUBRTX (iter
, array
, x
, ALL
)
6560 if (SYMBOL_REF_P (*iter
) || GET_CODE (*iter
) == LABEL_REF
)
6566 /* Return true if RTL X contains a constant pool address. */
6569 contains_constant_pool_address_p (const_rtx x
)
6571 subrtx_iterator::array_type array
;
6572 FOR_EACH_SUBRTX (iter
, array
, x
, ALL
)
6573 if (SYMBOL_REF_P (*iter
) && CONSTANT_POOL_ADDRESS_P (*iter
))
6580 /* Return true if X contains a thread-local symbol. */
6583 tls_referenced_p (const_rtx x
)
6585 if (!targetm
.have_tls
)
6588 subrtx_iterator::array_type array
;
6589 FOR_EACH_SUBRTX (iter
, array
, x
, ALL
)
6590 if (GET_CODE (*iter
) == SYMBOL_REF
&& SYMBOL_REF_TLS_MODEL (*iter
) != 0)
6595 /* Process recursively X of INSN and add REG_INC notes if necessary. */
6597 add_auto_inc_notes (rtx_insn
*insn
, rtx x
)
6599 enum rtx_code code
= GET_CODE (x
);
6603 if (code
== MEM
&& auto_inc_p (XEXP (x
, 0)))
6605 add_reg_note (insn
, REG_INC
, XEXP (XEXP (x
, 0), 0));
6609 /* Scan all X sub-expressions. */
6610 fmt
= GET_RTX_FORMAT (code
);
6611 for (i
= GET_RTX_LENGTH (code
) - 1; i
>= 0; i
--)
6614 add_auto_inc_notes (insn
, XEXP (x
, i
));
6615 else if (fmt
[i
] == 'E')
6616 for (j
= XVECLEN (x
, i
) - 1; j
>= 0; j
--)
6617 add_auto_inc_notes (insn
, XVECEXP (x
, i
, j
));