| blob | 79e8a1ca5b92a72c1e0a3ad4ecb353e9d767afd3 |
1 /* Register Transfer Language (RTL) definitions for GCC
2 Copyright (C) 1987, 1991, 1992, 1993, 1994, 1995, 1996, 1997, 1998, 1999,
3 2000, 2001, 2002, 2003, 2004, 2005, 2006 Free Software Foundation, Inc.
5 This file is part of GCC.
7 GCC is free software; you can redistribute it and/or modify it under
8 the terms of the GNU General Public License as published by the Free
9 Software Foundation; either version 3, or (at your option) any later
10 version.
12 GCC is distributed in the hope that it will be useful, but WITHOUT ANY
13 WARRANTY; without even the implied warranty of MERCHANTABILITY or
14 FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
15 for more details.
17 You should have received a copy of the GNU General Public License
18 along with GCC; see the file COPYING3. If not see
19 <http://www.gnu.org/licenses/>. */
21 #ifndef GCC_RTL_H
22 #define GCC_RTL_H
35 /* Value used by some passes to "recognize" noop moves as valid
36 instructions. */
37 #define NOOP_MOVE_INSN_CODE INT_MAX
39 /* Register Transfer Language EXPRESSIONS CODES */
41 #define RTX_CODE enum rtx_code
44 #define DEF_RTL_EXPR(ENUM, NAME, FORMAT, CLASS) ENUM ,
46 #undef DEF_RTL_EXPR
49 NUM_RTX_CODE.
50 Assumes default enum value assignment. */
52 #define NUM_RTX_CODE ((int) LAST_AND_UNUSED_RTX_CODE)
53 /* The cast here, saves many elsewhere. */
55 /* Register Transfer Language EXPRESSIONS CODE CLASSES */
58 /* We check bit 0-1 of some rtx class codes in the predicates below. */
60 /* Bit 0 = comparison if 0, arithmetic is 1
61 Bit 1 = 1 if commutative. */
63 RTX_COMM_COMPARE,
64 RTX_BIN_ARITH,
65 RTX_COMM_ARITH,
67 /* Must follow the four preceding values. */
70 RTX_EXTRA,
71 RTX_MATCH,
72 RTX_INSN,
74 /* Bit 0 = 1 if constant. */
76 RTX_CONST_OBJ,
78 RTX_TERNARY,
79 RTX_BITFIELD_OPS,
80 RTX_AUTOINC
81 };
83 #define RTX_OBJ_MASK (~1)
84 #define RTX_OBJ_RESULT (RTX_OBJ & RTX_OBJ_MASK)
85 #define RTX_COMPARE_MASK (~1)
86 #define RTX_COMPARE_RESULT (RTX_COMPARE & RTX_COMPARE_MASK)
87 #define RTX_ARITHMETIC_MASK (~1)
88 #define RTX_ARITHMETIC_RESULT (RTX_COMM_ARITH & RTX_ARITHMETIC_MASK)
89 #define RTX_BINARY_MASK (~3)
90 #define RTX_BINARY_RESULT (RTX_COMPARE & RTX_BINARY_MASK)
91 #define RTX_COMMUTATIVE_MASK (~2)
92 #define RTX_COMMUTATIVE_RESULT (RTX_COMM_COMPARE & RTX_COMMUTATIVE_MASK)
93 #define RTX_NON_COMMUTATIVE_RESULT (RTX_COMPARE & RTX_COMMUTATIVE_MASK)
96 #define GET_RTX_LENGTH(CODE) (rtx_length[(int) (CODE)])
99 #define GET_RTX_NAME(CODE) (rtx_name[(int) (CODE)])
102 #define GET_RTX_FORMAT(CODE) (rtx_format[(int) (CODE)])
105 #define GET_RTX_CLASS(CODE) (rtx_class[(int) (CODE)])
109 \f
110 /* The flags and bitfields of an ADDR_DIFF_VEC. BASE is the base label
111 relative to which the offsets are calculated, as explained in rtl.def. */
113 {
114 /* Set at the start of shorten_branches - ONLY WHEN OPTIMIZING - : */
116 /* Flags: */
119 after the ADDR_DIFF_VEC. */
121 after the ADDR_DIFF_VEC. */
123 after BASE. */
125 after BASE. */
126 /* Set by the actual branch shortening process - ONLY WHEN OPTIMIZING - : */
132 /* Structure used to describe the attributes of a MEM. These are hashed
133 so MEMs that the same attributes share a data structure. This means
134 they cannot be modified in place. If any element is nonzero, it means
135 the value of the corresponding attribute is unknown. */
136 /* ALIGN and SIZE are the alignment and size of the MEM itself,
137 while EXPR can describe a larger underlying object, which might have a
138 stricter alignment; OFFSET is the offset of the MEM within that object. */
140 {
148 /* Structure used to describe the attributes of a REG in similar way as
149 mem_attrs does for MEM above. */
152 {
157 /* Common union for an element of an rtx. */
159 union rtunion_def
160 {
164 rtx rt_rtx;
165 rtvec rt_rtvec;
167 addr_diff_vec_flags rt_addr_diff_vec_flags;
170 tree rt_tree;
175 };
178 /* This structure remembers the position of a SYMBOL_REF within an
179 object_block structure. A SYMBOL_REF only provides this information
180 if SYMBOL_REF_HAS_BLOCK_INFO_P is true. */
182 /* The usual SYMBOL_REF fields. */
185 /* The block that contains this object. */
188 /* The offset of this object from the start of its block. It is negative
189 if the symbol has not yet been assigned an offset. */
190 HOST_WIDE_INT offset;
191 };
197 /* Describes a group of objects that are to be placed together in such
198 a way that their relative positions are known. */
200 {
201 /* The section in which these objects should be placed. */
204 /* The alignment of the first object, measured in bits. */
207 /* The total size of the objects, measured in bytes. */
208 HOST_WIDE_INT size;
210 /* The SYMBOL_REFs for each object. The vector is sorted in
211 order of increasing offset and the following conditions will
212 hold for each element X:
214 SYMBOL_REF_HAS_BLOCK_INFO_P (X)
215 !SYMBOL_REF_ANCHOR_P (X)
216 SYMBOL_REF_BLOCK (X) == [address of this structure]
217 SYMBOL_REF_BLOCK_OFFSET (X) >= 0. */
220 /* All the anchor SYMBOL_REFs used to address these objects, sorted
221 in order of increasing offset, and then increasing TLS model.
222 The following conditions will hold for each element X in this vector:
224 SYMBOL_REF_HAS_BLOCK_INFO_P (X)
225 SYMBOL_REF_ANCHOR_P (X)
226 SYMBOL_REF_BLOCK (X) == [address of this structure]
227 SYMBOL_REF_BLOCK_OFFSET (X) >= 0. */
229 };
231 /* RTL expression ("rtx"). */
235 {
236 /* The kind of expression this is. */
239 /* The kind of value the expression has. */
242 /* 1 in a MEM if we should keep the alias set for this mem unchanged
243 when we access a component.
244 1 in a CALL_INSN if it is a sibling call.
245 1 in a SET that is for a return.
246 In a CODE_LABEL, part of the two-bit alternate entry field. */
248 /* In a CODE_LABEL, part of the two-bit alternate entry field.
249 1 in a MEM if it cannot trap. */
251 /* 1 in a REG, MEM, or CONCAT if the value is set at most once, anywhere.
252 1 in a SUBREG if it references an unsigned object whose mode has been
253 from a promoted to a wider mode.
254 1 in a SYMBOL_REF if it addresses something in the per-function
255 constants pool.
256 1 in a CALL_INSN, NOTE, or EXPR_LIST for a const or pure call.
257 1 in a JUMP_INSN, CALL_INSN, or INSN of an annulling branch. */
259 /* 1 in a MEM or ASM_OPERANDS expression if the memory reference is volatile.
260 1 in an INSN, CALL_INSN, JUMP_INSN, CODE_LABEL, BARRIER, or NOTE
261 if it has been deleted.
262 1 in a REG expression if corresponds to a variable declared by the user,
263 0 for an internally generated temporary.
264 1 in a SUBREG with a negative value.
265 1 in a LABEL_REF or in a REG_LABEL note for a non-local label.
266 In a SYMBOL_REF, this flag is used for machine-specific purposes. */
268 /* 1 in a MEM referring to a field of an aggregate.
269 0 if the MEM was a variable or the result of a * operator in C;
270 1 if it was the result of a . or -> operator (on a struct) in C.
271 1 in a REG if the register is used only in exit code a loop.
272 1 in a SUBREG expression if was generated from a variable with a
273 promoted mode.
274 1 in a CODE_LABEL if the label is used for nonlocal gotos
275 and must not be deleted even if its count is zero.
276 1 in an INSN, JUMP_INSN or CALL_INSN if this insn must be scheduled
277 together with the preceding insn. Valid only within sched.
278 1 in an INSN, JUMP_INSN, or CALL_INSN if insn is in a delay slot and
279 from the target of a branch. Valid from reorg until end of compilation;
280 cleared before used. */
282 /* At the end of RTL generation, 1 if this rtx is used. This is used for
283 copying shared structure. See `unshare_all_rtl'.
284 In a REG, this is not needed for that purpose, and used instead
285 in `leaf_renumber_regs_insn'.
286 1 in a SYMBOL_REF, means that emit_library_call
287 has used it as the function. */
289 /* 1 in an INSN or a SET if this rtx is related to the call frame,
290 either changing how we compute the frame address or saving and
291 restoring registers in the prologue and epilogue.
292 1 in a REG or MEM if it is a pointer.
293 1 in a SYMBOL_REF if it addresses something in the per-function
294 constant string pool. */
296 /* 1 in a REG or PARALLEL that is the current function's return value.
297 1 in a MEM if it refers to a scalar.
298 1 in a SYMBOL_REF for a weak symbol. */
301 /* The first element of the operands of this rtx.
302 The number of operands and their types are controlled
303 by the `code' field, according to rtl.def. */
310 };
312 /* The size in bytes of an rtx header (code, mode and flags). */
313 #define RTX_HDR_SIZE offsetof (struct rtx_def, u)
315 /* The size in bytes of an rtx with code CODE. */
316 #define RTX_CODE_SIZE(CODE) rtx_code_size[CODE]
318 #define NULL_RTX (rtx) 0
320 /* The "next" and "previous" RTX, relative to this one. */
322 #define RTX_NEXT(X) (rtx_next[GET_CODE (X)] == 0 ? NULL \
323 : *(rtx *)(((char *)X) + rtx_next[GET_CODE (X)]))
325 /* FIXME: the "NEXT_INSN (PREV_INSN (X)) == X" condition shouldn't be needed.
326 */
327 #define RTX_PREV(X) ((INSN_P (X) \
328 || NOTE_P (X) \
329 || BARRIER_P (X) \
330 || LABEL_P (X)) \
331 && PREV_INSN (X) != NULL \
332 && NEXT_INSN (PREV_INSN (X)) == X \
333 ? PREV_INSN (X) : NULL)
335 /* Define macros to access the `code' field of the rtx. */
337 #define GET_CODE(RTX) ((enum rtx_code) (RTX)->code)
338 #define PUT_CODE(RTX, CODE) ((RTX)->code = (CODE))
340 #define GET_MODE(RTX) ((enum machine_mode) (RTX)->mode)
341 #define PUT_MODE(RTX, MODE) ((RTX)->mode = (MODE))
343 /* RTL vector. These appear inside RTX's when there is a need
344 for a variable number of things. The principle use is inside
345 PARALLEL expressions. */
350 };
352 #define NULL_RTVEC (rtvec) 0
354 #define GET_NUM_ELEM(RTVEC) ((RTVEC)->num_elem)
355 #define PUT_NUM_ELEM(RTVEC, NUM) ((RTVEC)->num_elem = (NUM))
357 /* Predicate yielding nonzero iff X is an rtx for a register. */
358 #define REG_P(X) (GET_CODE (X) == REG)
360 /* Predicate yielding nonzero iff X is an rtx for a memory location. */
361 #define MEM_P(X) (GET_CODE (X) == MEM)
363 /* Predicate yielding nonzero iff X is an rtx for a constant integer. */
364 #define CONST_INT_P(X) (GET_CODE (X) == CONST_INT)
366 /* Predicate yielding nonzero iff X is a label insn. */
367 #define LABEL_P(X) (GET_CODE (X) == CODE_LABEL)
369 /* Predicate yielding nonzero iff X is a jump insn. */
370 #define JUMP_P(X) (GET_CODE (X) == JUMP_INSN)
372 /* Predicate yielding nonzero iff X is a call insn. */
373 #define CALL_P(X) (GET_CODE (X) == CALL_INSN)
375 /* Predicate yielding nonzero iff X is an insn that cannot jump. */
376 #define NONJUMP_INSN_P(X) (GET_CODE (X) == INSN)
378 /* Predicate yielding nonzero iff X is a real insn. */
379 #define INSN_P(X) \
380 (NONJUMP_INSN_P (X) || JUMP_P (X) || CALL_P (X))
382 /* Predicate yielding nonzero iff X is a note insn. */
383 #define NOTE_P(X) (GET_CODE (X) == NOTE)
385 /* Predicate yielding nonzero iff X is a barrier insn. */
386 #define BARRIER_P(X) (GET_CODE (X) == BARRIER)
388 /* Predicate yielding nonzero iff X is a data for a jump table. */
389 #define JUMP_TABLE_DATA_P(INSN) \
390 (JUMP_P (INSN) && (GET_CODE (PATTERN (INSN)) == ADDR_VEC || \
391 GET_CODE (PATTERN (INSN)) == ADDR_DIFF_VEC))
393 /* 1 if X is a unary operator. */
395 #define UNARY_P(X) \
396 (GET_RTX_CLASS (GET_CODE (X)) == RTX_UNARY)
398 /* 1 if X is a binary operator. */
400 #define BINARY_P(X) \
401 ((GET_RTX_CLASS (GET_CODE (X)) & RTX_BINARY_MASK) == RTX_BINARY_RESULT)
403 /* 1 if X is an arithmetic operator. */
405 #define ARITHMETIC_P(X) \
406 ((GET_RTX_CLASS (GET_CODE (X)) & RTX_ARITHMETIC_MASK) \
407 == RTX_ARITHMETIC_RESULT)
409 /* 1 if X is an arithmetic operator. */
411 #define COMMUTATIVE_ARITH_P(X) \
412 (GET_RTX_CLASS (GET_CODE (X)) == RTX_COMM_ARITH)
414 /* 1 if X is a commutative arithmetic operator or a comparison operator.
415 These two are sometimes selected together because it is possible to
416 swap the two operands. */
418 #define SWAPPABLE_OPERANDS_P(X) \
419 ((1 << GET_RTX_CLASS (GET_CODE (X))) \
420 & ((1 << RTX_COMM_ARITH) | (1 << RTX_COMM_COMPARE) \
421 | (1 << RTX_COMPARE)))
423 /* 1 if X is a non-commutative operator. */
425 #define NON_COMMUTATIVE_P(X) \
426 ((GET_RTX_CLASS (GET_CODE (X)) & RTX_COMMUTATIVE_MASK) \
427 == RTX_NON_COMMUTATIVE_RESULT)
429 /* 1 if X is a commutative operator on integers. */
431 #define COMMUTATIVE_P(X) \
432 ((GET_RTX_CLASS (GET_CODE (X)) & RTX_COMMUTATIVE_MASK) \
433 == RTX_COMMUTATIVE_RESULT)
435 /* 1 if X is a relational operator. */
437 #define COMPARISON_P(X) \
438 ((GET_RTX_CLASS (GET_CODE (X)) & RTX_COMPARE_MASK) == RTX_COMPARE_RESULT)
440 /* 1 if X is a constant value that is an integer. */
442 #define CONSTANT_P(X) \
443 (GET_RTX_CLASS (GET_CODE (X)) == RTX_CONST_OBJ)
445 /* 1 if X can be used to represent an object. */
446 #define OBJECT_P(X) \
447 ((GET_RTX_CLASS (GET_CODE (X)) & RTX_OBJ_MASK) == RTX_OBJ_RESULT)
449 /* General accessor macros for accessing the fields of an rtx. */
451 #if defined ENABLE_RTL_CHECKING && (GCC_VERSION >= 2007)
452 /* The bit with a star outside the statement expr and an & inside is
453 so that N can be evaluated only once. */
454 #define RTL_CHECK1(RTX, N, C1) __extension__ \
455 (*({ rtx const _rtx = (RTX); const int _n = (N); \
456 const enum rtx_code _code = GET_CODE (_rtx); \
457 if (_n < 0 || _n >= GET_RTX_LENGTH (_code)) \
458 rtl_check_failed_bounds (_rtx, _n, __FILE__, __LINE__, \
459 __FUNCTION__); \
460 if (GET_RTX_FORMAT(_code)[_n] != C1) \
461 rtl_check_failed_type1 (_rtx, _n, C1, __FILE__, __LINE__, \
462 __FUNCTION__); \
463 &_rtx->u.fld[_n]; }))
465 #define RTL_CHECK2(RTX, N, C1, C2) __extension__ \
466 (*({ rtx const _rtx = (RTX); const int _n = (N); \
467 const enum rtx_code _code = GET_CODE (_rtx); \
468 if (_n < 0 || _n >= GET_RTX_LENGTH (_code)) \
469 rtl_check_failed_bounds (_rtx, _n, __FILE__, __LINE__, \
470 __FUNCTION__); \
471 if (GET_RTX_FORMAT(_code)[_n] != C1 \
472 && GET_RTX_FORMAT(_code)[_n] != C2) \
473 rtl_check_failed_type2 (_rtx, _n, C1, C2, __FILE__, __LINE__, \
474 __FUNCTION__); \
475 &_rtx->u.fld[_n]; }))
477 #define RTL_CHECKC1(RTX, N, C) __extension__ \
478 (*({ rtx const _rtx = (RTX); const int _n = (N); \
479 if (GET_CODE (_rtx) != (C)) \
480 rtl_check_failed_code1 (_rtx, (C), __FILE__, __LINE__, \
481 __FUNCTION__); \
482 &_rtx->u.fld[_n]; }))
484 #define RTL_CHECKC2(RTX, N, C1, C2) __extension__ \
485 (*({ rtx const _rtx = (RTX); const int _n = (N); \
486 const enum rtx_code _code = GET_CODE (_rtx); \
487 if (_code != (C1) && _code != (C2)) \
488 rtl_check_failed_code2 (_rtx, (C1), (C2), __FILE__, __LINE__, \
489 __FUNCTION__); \
490 &_rtx->u.fld[_n]; }))
492 #define RTVEC_ELT(RTVEC, I) __extension__ \
493 (*({ rtvec const _rtvec = (RTVEC); const int _i = (I); \
494 if (_i < 0 || _i >= GET_NUM_ELEM (_rtvec)) \
495 rtvec_check_failed_bounds (_rtvec, _i, __FILE__, __LINE__, \
496 __FUNCTION__); \
497 &_rtvec->elem[_i]; }))
499 #define XWINT(RTX, N) __extension__ \
500 (*({ rtx const _rtx = (RTX); const int _n = (N); \
501 const enum rtx_code _code = GET_CODE (_rtx); \
502 if (_n < 0 || _n >= GET_RTX_LENGTH (_code)) \
503 rtl_check_failed_bounds (_rtx, _n, __FILE__, __LINE__, \
504 __FUNCTION__); \
507 __FUNCTION__); \
508 &_rtx->u.hwint[_n]; }))
510 #define XCWINT(RTX, N, C) __extension__ \
511 (*({ rtx const _rtx = (RTX); \
512 if (GET_CODE (_rtx) != (C)) \
513 rtl_check_failed_code1 (_rtx, (C), __FILE__, __LINE__, \
514 __FUNCTION__); \
515 &_rtx->u.hwint[N]; }))
517 #define XCMWINT(RTX, N, C, M) __extension__ \
518 (*({ rtx const _rtx = (RTX); \
519 if (GET_CODE (_rtx) != (C) || GET_MODE (_rtx) != (M)) \
520 rtl_check_failed_code_mode (_rtx, (C), (M), false, __FILE__, \
521 __LINE__, __FUNCTION__); \
522 &_rtx->u.hwint[N]; }))
524 #define XCNMPRV(RTX, C, M) __extension__ \
525 ({ rtx const _rtx = (RTX); \
526 if (GET_CODE (_rtx) != (C) || GET_MODE (_rtx) == (M)) \
527 rtl_check_failed_code_mode (_rtx, (C), (M), true, __FILE__, \
528 __LINE__, __FUNCTION__); \
529 &_rtx->u.rv; })
531 #define BLOCK_SYMBOL_CHECK(RTX) __extension__ \
532 ({ rtx const _symbol = (RTX); \
533 unsigned int flags = RTL_CHECKC1 (_symbol, 1, SYMBOL_REF).rt_int; \
534 if ((flags & SYMBOL_FLAG_HAS_BLOCK_INFO) == 0) \
535 rtl_check_failed_block_symbol (__FILE__, __LINE__, \
536 __FUNCTION__); \
537 &_symbol->u.block_sym; })
541 ATTRIBUTE_NORETURN;
544 ATTRIBUTE_NORETURN;
547 ATTRIBUTE_NORETURN;
550 ATTRIBUTE_NORETURN;
553 ATTRIBUTE_NORETURN;
556 ATTRIBUTE_NORETURN;
558 ATTRIBUTE_NORETURN;
561 ATTRIBUTE_NORETURN;
565 #define RTL_CHECK1(RTX, N, C1) ((RTX)->u.fld[N])
566 #define RTL_CHECK2(RTX, N, C1, C2) ((RTX)->u.fld[N])
567 #define RTL_CHECKC1(RTX, N, C) ((RTX)->u.fld[N])
568 #define RTL_CHECKC2(RTX, N, C1, C2) ((RTX)->u.fld[N])
569 #define RTVEC_ELT(RTVEC, I) ((RTVEC)->elem[I])
570 #define XWINT(RTX, N) ((RTX)->u.hwint[N])
571 #define XCWINT(RTX, N, C) ((RTX)->u.hwint[N])
572 #define XCMWINT(RTX, N, C, M) ((RTX)->u.hwint[N])
573 #define XCNMWINT(RTX, N, C, M) ((RTX)->u.hwint[N])
574 #define XCNMPRV(RTX, C, M) (&(RTX)->u.rv)
575 #define BLOCK_SYMBOL_CHECK(RTX) (&(RTX)->u.block_sym)
577 #endif
579 /* General accessor macros for accessing the flags of an rtx. */
581 /* Access an individual rtx flag, with no checking of any kind. */
582 #define RTX_FLAG(RTX, FLAG) ((RTX)->FLAG)
584 #if defined ENABLE_RTL_FLAG_CHECKING && (GCC_VERSION >= 2007)
585 #define RTL_FLAG_CHECK1(NAME, RTX, C1) __extension__ \
586 ({ rtx const _rtx = (RTX); \
587 if (GET_CODE(_rtx) != C1) \
588 rtl_check_failed_flag (NAME, _rtx, __FILE__, __LINE__, \
589 __FUNCTION__); \
590 _rtx; })
592 #define RTL_FLAG_CHECK2(NAME, RTX, C1, C2) __extension__ \
593 ({ rtx const _rtx = (RTX); \
594 if (GET_CODE(_rtx) != C1 && GET_CODE(_rtx) != C2) \
595 rtl_check_failed_flag (NAME,_rtx, __FILE__, __LINE__, \
596 __FUNCTION__); \
597 _rtx; })
599 #define RTL_FLAG_CHECK3(NAME, RTX, C1, C2, C3) __extension__ \
600 ({ rtx const _rtx = (RTX); \
601 if (GET_CODE(_rtx) != C1 && GET_CODE(_rtx) != C2 \
602 && GET_CODE(_rtx) != C3) \
603 rtl_check_failed_flag (NAME, _rtx, __FILE__, __LINE__, \
604 __FUNCTION__); \
605 _rtx; })
607 #define RTL_FLAG_CHECK4(NAME, RTX, C1, C2, C3, C4) __extension__ \
608 ({ rtx const _rtx = (RTX); \
609 if (GET_CODE(_rtx) != C1 && GET_CODE(_rtx) != C2 \
610 && GET_CODE(_rtx) != C3 && GET_CODE(_rtx) != C4) \
611 rtl_check_failed_flag (NAME, _rtx, __FILE__, __LINE__, \
612 __FUNCTION__); \
613 _rtx; })
615 #define RTL_FLAG_CHECK5(NAME, RTX, C1, C2, C3, C4, C5) __extension__ \
616 ({ rtx const _rtx = (RTX); \
617 if (GET_CODE(_rtx) != C1 && GET_CODE(_rtx) != C2 \
618 && GET_CODE(_rtx) != C3 && GET_CODE(_rtx) != C4 \
619 && GET_CODE(_rtx) != C5) \
620 rtl_check_failed_flag (NAME, _rtx, __FILE__, __LINE__, \
621 __FUNCTION__); \
622 _rtx; })
624 #define RTL_FLAG_CHECK6(NAME, RTX, C1, C2, C3, C4, C5, C6) \
625 __extension__ \
626 ({ rtx const _rtx = (RTX); \
627 if (GET_CODE(_rtx) != C1 && GET_CODE(_rtx) != C2 \
628 && GET_CODE(_rtx) != C3 && GET_CODE(_rtx) != C4 \
629 && GET_CODE(_rtx) != C5 && GET_CODE(_rtx) != C6) \
630 rtl_check_failed_flag (NAME,_rtx, __FILE__, __LINE__, \
631 __FUNCTION__); \
632 _rtx; })
634 #define RTL_FLAG_CHECK7(NAME, RTX, C1, C2, C3, C4, C5, C6, C7) \
635 __extension__ \
636 ({ rtx const _rtx = (RTX); \
637 if (GET_CODE(_rtx) != C1 && GET_CODE(_rtx) != C2 \
638 && GET_CODE(_rtx) != C3 && GET_CODE(_rtx) != C4 \
639 && GET_CODE(_rtx) != C5 && GET_CODE(_rtx) != C6 \
640 && GET_CODE(_rtx) != C7) \
641 rtl_check_failed_flag (NAME, _rtx, __FILE__, __LINE__, \
642 __FUNCTION__); \
643 _rtx; })
645 #define RTL_FLAG_CHECK8(NAME, RTX, C1, C2, C3, C4, C5, C6, C7, C8) \
646 __extension__ \
647 ({ rtx const _rtx = (RTX); \
648 if (GET_CODE(_rtx) != C1 && GET_CODE(_rtx) != C2 \
649 && GET_CODE(_rtx) != C3 && GET_CODE(_rtx) != C4 \
650 && GET_CODE(_rtx) != C5 && GET_CODE(_rtx) != C6 \
651 && GET_CODE(_rtx) != C7 && GET_CODE(_rtx) != C8) \
652 rtl_check_failed_flag (NAME, _rtx, __FILE__, __LINE__, \
653 __FUNCTION__); \
654 _rtx; })
658 ATTRIBUTE_NORETURN
659 ;
663 #define RTL_FLAG_CHECK1(NAME, RTX, C1) (RTX)
664 #define RTL_FLAG_CHECK2(NAME, RTX, C1, C2) (RTX)
665 #define RTL_FLAG_CHECK3(NAME, RTX, C1, C2, C3) (RTX)
666 #define RTL_FLAG_CHECK4(NAME, RTX, C1, C2, C3, C4) (RTX)
667 #define RTL_FLAG_CHECK5(NAME, RTX, C1, C2, C3, C4, C5) (RTX)
668 #define RTL_FLAG_CHECK6(NAME, RTX, C1, C2, C3, C4, C5, C6) (RTX)
669 #define RTL_FLAG_CHECK7(NAME, RTX, C1, C2, C3, C4, C5, C6, C7) (RTX)
670 #define RTL_FLAG_CHECK8(NAME, RTX, C1, C2, C3, C4, C5, C6, C7, C8) (RTX)
671 #endif
683 #define XVECEXP(RTX, N, M) RTVEC_ELT (XVEC (RTX, N), M)
684 #define XVECLEN(RTX, N) GET_NUM_ELEM (XVEC (RTX, N))
686 /* These are like XINT, etc. except that they expect a '0' field instead
687 of the normal type code. */
700 #define X0MEMATTR(RTX, N) (RTL_CHECKC1 (RTX, N, MEM).rt_mem)
701 #define X0REGATTR(RTX, N) (RTL_CHECKC1 (RTX, N, REG).rt_reg)
704 /* Access a '0' field with any type. */
707 #define XCINT(RTX, N, C) (RTL_CHECKC1 (RTX, N, C).rt_int)
708 #define XCUINT(RTX, N, C) (RTL_CHECKC1 (RTX, N, C).rt_uint)
709 #define XCSTR(RTX, N, C) (RTL_CHECKC1 (RTX, N, C).rt_str)
710 #define XCEXP(RTX, N, C) (RTL_CHECKC1 (RTX, N, C).rt_rtx)
711 #define XCVEC(RTX, N, C) (RTL_CHECKC1 (RTX, N, C).rt_rtvec)
712 #define XCMODE(RTX, N, C) (RTL_CHECKC1 (RTX, N, C).rt_type)
713 #define XCBITMAP(RTX, N, C) (RTL_CHECKC1 (RTX, N, C).rt_bit)
714 #define XCTREE(RTX, N, C) (RTL_CHECKC1 (RTX, N, C).rt_tree)
715 #define XCBBDEF(RTX, N, C) (RTL_CHECKC1 (RTX, N, C).rt_bb)
716 #define XCCSELIB(RTX, N, C) (RTL_CHECKC1 (RTX, N, C).rt_cselib)
718 #define XCVECEXP(RTX, N, M, C) RTVEC_ELT (XCVEC (RTX, N, C), M)
719 #define XCVECLEN(RTX, N, C) GET_NUM_ELEM (XCVEC (RTX, N, C))
721 #define XC2EXP(RTX, N, C1, C2) (RTL_CHECKC2 (RTX, N, C1, C2).rt_rtx)
722 \f
723 /* ACCESS MACROS for particular fields of insns. */
725 /* Holds a unique number for each insn.
726 These are not necessarily sequentially increasing. */
727 #define INSN_UID(INSN) XINT (INSN, 0)
729 /* Chain insns together in sequence. */
730 #define PREV_INSN(INSN) XEXP (INSN, 1)
731 #define NEXT_INSN(INSN) XEXP (INSN, 2)
733 #define BLOCK_FOR_INSN(INSN) XBBDEF (INSN, 3)
734 #define INSN_LOCATOR(INSN) XINT (INSN, 4)
735 /* The body of an insn. */
736 #define PATTERN(INSN) XEXP (INSN, 5)
738 /* Code number of instruction, from when it was recognized.
739 -1 means this instruction has not been recognized yet. */
740 #define INSN_CODE(INSN) XINT (INSN, 6)
742 /* Set up in flow.c; empty before then.
743 Holds a chain of INSN_LIST rtx's whose first operands point at
744 previous insns with direct data-flow connections to this one.
745 That means that those insns set variables whose next use is in this insn.
746 They are always in the same basic block as this insn. */
747 #define LOG_LINKS(INSN) XEXP(INSN, 7)
749 #define RTX_FRAME_RELATED_P(RTX) \
751 JUMP_INSN, BARRIER, SET)->frame_related)
753 /* 1 if RTX is an insn that has been deleted. */
754 #define INSN_DELETED_P(RTX) \
756 CODE_LABEL, BARRIER, NOTE)->volatil)
758 /* 1 if RTX is a call to a const or pure function. */
759 #define CONST_OR_PURE_CALL_P(RTX) \
761 EXPR_LIST)->unchanging)
763 /* 1 if RTX is a call_insn for a sibling call. */
764 #define SIBLING_CALL_P(RTX) \
767 /* 1 if RTX is a jump_insn, call_insn, or insn that is an annulling branch. */
768 #define INSN_ANNULLED_BRANCH_P(RTX) \
771 /* 1 if RTX is an insn in a delay slot and is from the target of the branch.
772 If the branch insn has INSN_ANNULLED_BRANCH_P set, this insn should only be
773 executed if the branch is taken. For annulled branches with this bit
774 clear, the insn should be executed only if the branch is not taken. */
775 #define INSN_FROM_TARGET_P(RTX) \
778 /* In an ADDR_DIFF_VEC, the flags for RTX for use by branch shortening.
779 See the comments for ADDR_DIFF_VEC in rtl.def. */
780 #define ADDR_DIFF_VEC_FLAGS(RTX) X0ADVFLAGS(RTX, 4)
782 /* In a VALUE, the value cselib has assigned to RTX.
783 This is a "struct cselib_val_struct", see cselib.h. */
784 #define CSELIB_VAL_PTR(RTX) X0CSELIB(RTX, 0)
786 /* Holds a list of notes on what this insn does to various REGs.
787 It is a chain of EXPR_LIST rtx's, where the second operand is the
788 chain pointer and the first operand is the REG being described.
789 The mode field of the EXPR_LIST contains not a real machine mode
790 but a value from enum reg_note. */
791 #define REG_NOTES(INSN) XEXP(INSN, 8)
793 enum reg_note
794 {
795 #define DEF_REG_NOTE(NAME) NAME,
797 #undef DEF_REG_NOTE
798 REG_NOTE_MAX
799 };
801 /* Define macros to extract and insert the reg-note kind in an EXPR_LIST. */
802 #define REG_NOTE_KIND(LINK) ((enum reg_note) GET_MODE (LINK))
803 #define PUT_REG_NOTE_KIND(LINK, KIND) \
804 PUT_MODE (LINK, (enum machine_mode) (KIND))
806 /* Names for REG_NOTE's in EXPR_LIST insn's. */
809 #define GET_REG_NOTE_NAME(MODE) (reg_note_name[(int) (MODE)])
811 /* This field is only present on CALL_INSNs. It holds a chain of EXPR_LIST of
812 USE and CLOBBER expressions.
813 USE expressions list the registers filled with arguments that
814 are passed to the function.
815 CLOBBER expressions document the registers explicitly clobbered
816 by this CALL_INSN.
817 Pseudo registers can not be mentioned in this list. */
818 #define CALL_INSN_FUNCTION_USAGE(INSN) XEXP(INSN, 9)
820 /* The label-number of a code-label. The assembler label
821 is made from `L' and the label-number printed in decimal.
822 Label numbers are unique in a compilation. */
823 #define CODE_LABEL_NUMBER(INSN) XINT (INSN, 6)
825 /* In a NOTE that is a line number, this is a string for the file name that the
826 line is in. We use the same field to record block numbers temporarily in
827 NOTE_INSN_BLOCK_BEG and NOTE_INSN_BLOCK_END notes. (We avoid lots of casts
828 between ints and pointers if we use a different macro for the block number.)
829 */
831 /* Opaque data. */
832 #define NOTE_DATA(INSN) RTL_CHECKC1 (INSN, 4, NOTE)
833 #define NOTE_DELETED_LABEL_NAME(INSN) XCSTR (INSN, 4, NOTE)
834 #ifdef USE_MAPPED_LOCATION
835 #define NOTE_SOURCE_LOCATION(INSN) XCUINT (INSN, 5, NOTE)
836 #define NOTE_EXPANDED_LOCATION(XLOC, INSN) \
837 (XLOC) = expand_location (NOTE_SOURCE_LOCATION (INSN))
838 #define SET_INSN_DELETED(INSN) \
839 (PUT_CODE (INSN, NOTE), NOTE_LINE_NUMBER (INSN) = NOTE_INSN_DELETED)
840 #else
841 #define NOTE_EXPANDED_LOCATION(XLOC, INSN) \
842 ((XLOC).file = NOTE_SOURCE_FILE (INSN), \
843 (XLOC).line = NOTE_LINE_NUMBER (INSN))
844 #define NOTE_SOURCE_FILE(INSN) XCSTR (INSN, 4, NOTE)
845 #define SET_INSN_DELETED(INSN) \
846 (PUT_CODE (INSN, NOTE), NOTE_SOURCE_FILE (INSN) = 0, \
847 NOTE_LINE_NUMBER (INSN) = NOTE_INSN_DELETED)
848 #endif
849 #define NOTE_BLOCK(INSN) XCTREE (INSN, 4, NOTE)
850 #define NOTE_EH_HANDLER(INSN) XCINT (INSN, 4, NOTE)
851 #define NOTE_BASIC_BLOCK(INSN) XCBBDEF (INSN, 4, NOTE)
852 #define NOTE_EXPECTED_VALUE(INSN) XCEXP (INSN, 4, NOTE)
853 #define NOTE_VAR_LOCATION(INSN) XCEXP (INSN, 4, NOTE)
855 /* In a NOTE that is a line number, this is the line number.
856 Other kinds of NOTEs are identified by negative numbers here. */
857 #define NOTE_LINE_NUMBER(INSN) XCINT (INSN, 5, NOTE)
859 /* Nonzero if INSN is a note marking the beginning of a basic block. */
860 #define NOTE_INSN_BASIC_BLOCK_P(INSN) \
861 (GET_CODE (INSN) == NOTE \
862 && NOTE_LINE_NUMBER (INSN) == NOTE_INSN_BASIC_BLOCK)
864 /* Variable declaration and the location of a variable. */
865 #define NOTE_VAR_LOCATION_DECL(INSN) (XCTREE (XCEXP (INSN, 4, NOTE), \
866 0, VAR_LOCATION))
867 #define NOTE_VAR_LOCATION_LOC(INSN) (XCEXP (XCEXP (INSN, 4, NOTE), \
868 1, VAR_LOCATION))
870 /* Codes that appear in the NOTE_LINE_NUMBER field for kinds of notes
871 that are not line numbers. These codes are all negative.
873 Notice that we do not try to use zero here for any of
874 the special note codes because sometimes the source line
875 actually can be zero! This happens (for example) when we
876 are generating code for the per-translation-unit constructor
877 and destructor routines for some C++ translation unit. */
879 enum insn_note
880 {
881 /* Keep all of these numbers negative. Adjust as needed. */
884 #define DEF_INSN_NOTE(NAME) NAME,
886 #undef DEF_INSN_NOTE
888 NOTE_INSN_MAX
889 };
891 /* Names for NOTE insn's other than line numbers. */
894 #define GET_NOTE_INSN_NAME(NOTE_CODE) \
895 (note_insn_name[(NOTE_CODE) - (int) NOTE_INSN_BIAS])
897 /* The name of a label, in case it corresponds to an explicit label
898 in the input source code. */
899 #define LABEL_NAME(RTX) XCSTR (RTX, 7, CODE_LABEL)
901 /* In jump.c, each label contains a count of the number
902 of LABEL_REFs that point at it, so unused labels can be deleted. */
903 #define LABEL_NUSES(RTX) XCINT (RTX, 4, CODE_LABEL)
905 /* Labels carry a two-bit field composed of the ->jump and ->call
906 bits. This field indicates whether the label is an alternate
907 entry point, and if so, what kind. */
908 enum label_kind
909 {
913 LABEL_WEAK_ENTRY /* alternate entry point, exported as weak symbol */
914 };
916 #if defined ENABLE_RTL_FLAG_CHECKING && (GCC_VERSION > 2007)
918 /* Retrieve the kind of LABEL. */
919 #define LABEL_KIND(LABEL) __extension__ \
920 ({ rtx const _label = (LABEL); \
921 if (GET_CODE (_label) != CODE_LABEL) \
923 __FUNCTION__); \
924 (enum label_kind) ((_label->jump << 1) | _label->call); })
926 /* Set the kind of LABEL. */
927 #define SET_LABEL_KIND(LABEL, KIND) do { \
928 rtx _label = (LABEL); \
929 unsigned int _kind = (KIND); \
930 if (GET_CODE (_label) != CODE_LABEL) \
932 __FUNCTION__); \
933 _label->jump = ((_kind >> 1) & 1); \
934 _label->call = (_kind & 1); \
935 } while (0)
937 #else
939 /* Retrieve the kind of LABEL. */
940 #define LABEL_KIND(LABEL) \
941 ((enum label_kind) (((LABEL)->jump << 1) | (LABEL)->call))
943 /* Set the kind of LABEL. */
944 #define SET_LABEL_KIND(LABEL, KIND) do { \
945 rtx _label = (LABEL); \
946 unsigned int _kind = (KIND); \
947 _label->jump = ((_kind >> 1) & 1); \
948 _label->call = (_kind & 1); \
949 } while (0)
953 #define LABEL_ALT_ENTRY_P(LABEL) (LABEL_KIND (LABEL) != LABEL_NORMAL)
955 /* In jump.c, each JUMP_INSN can point to a label that it can jump to,
956 so that if the JUMP_INSN is deleted, the label's LABEL_NUSES can
957 be decremented and possibly the label can be deleted. */
958 #define JUMP_LABEL(INSN) XCEXP (INSN, 9, JUMP_INSN)
960 /* Once basic blocks are found in flow.c,
961 each CODE_LABEL starts a chain that goes through
962 all the LABEL_REFs that jump to that label.
963 The chain eventually winds up at the CODE_LABEL: it is circular. */
964 #define LABEL_REFS(LABEL) XCEXP (LABEL, 5, CODE_LABEL)
965 \f
966 /* For a REG rtx, REGNO extracts the register number. ORIGINAL_REGNO holds
967 the number the register originally had; for a pseudo register turned into
968 a hard reg this will hold the old pseudo register number. */
970 #define REGNO(RTX) XCUINT (RTX, 0, REG)
971 #define ORIGINAL_REGNO(RTX) X0UINT (RTX, 1)
973 /* 1 if RTX is a reg or parallel that is the current function's return
974 value. */
975 #define REG_FUNCTION_VALUE_P(RTX) \
978 /* 1 if RTX is a reg that corresponds to a variable declared by the user. */
979 #define REG_USERVAR_P(RTX) \
982 /* 1 if RTX is a reg that holds a pointer value. */
983 #define REG_POINTER(RTX) \
986 /* 1 if RTX is a mem that holds a pointer value. */
987 #define MEM_POINTER(RTX) \
990 /* 1 if the given register REG corresponds to a hard register. */
991 #define HARD_REGISTER_P(REG) (HARD_REGISTER_NUM_P (REGNO (REG)))
993 /* 1 if the given register number REG_NO corresponds to a hard register. */
994 #define HARD_REGISTER_NUM_P(REG_NO) ((REG_NO) < FIRST_PSEUDO_REGISTER)
996 /* For a CONST_INT rtx, INTVAL extracts the integer. */
997 #define INTVAL(RTX) XCWINT(RTX, 0, CONST_INT)
998 #define UINTVAL(RTX) ((unsigned HOST_WIDE_INT) INTVAL (RTX))
1000 /* For a CONST_DOUBLE:
1001 For a VOIDmode, there are two integers CONST_DOUBLE_LOW is the
1002 low-order word and ..._HIGH the high-order.
1003 For a float, there is a REAL_VALUE_TYPE structure, and
1004 CONST_DOUBLE_REAL_VALUE(r) is a pointer to it. */
1005 #define CONST_DOUBLE_LOW(r) XCMWINT (r, 0, CONST_DOUBLE, VOIDmode)
1006 #define CONST_DOUBLE_HIGH(r) XCMWINT (r, 1, CONST_DOUBLE, VOIDmode)
1007 #define CONST_DOUBLE_REAL_VALUE(r) \
1008 ((const struct real_value *) XCNMPRV (r, CONST_DOUBLE, VOIDmode))
1010 /* For a CONST_VECTOR, return element #n. */
1011 #define CONST_VECTOR_ELT(RTX, N) XCVECEXP (RTX, 0, N, CONST_VECTOR)
1013 /* For a CONST_VECTOR, return the number of elements in a vector. */
1014 #define CONST_VECTOR_NUNITS(RTX) XCVECLEN (RTX, 0, CONST_VECTOR)
1016 /* For a SUBREG rtx, SUBREG_REG extracts the value we want a subreg of.
1017 SUBREG_BYTE extracts the byte-number. */
1019 #define SUBREG_REG(RTX) XCEXP (RTX, 0, SUBREG)
1020 #define SUBREG_BYTE(RTX) XCUINT (RTX, 1, SUBREG)
1022 /* in rtlanal.c */
1023 /* Return the right cost to give to an operation
1024 to make the cost of the corresponding register-to-register instruction
1025 N times that of a fast register-to-register instruction. */
1026 #define COSTS_N_INSNS(N) ((N) * 4)
1028 /* Maximum cost of an rtl expression. This value has the special meaning
1029 not to use an rtx with this cost under any circumstances. */
1030 #define MAX_COST INT_MAX
1049 /* 1 if RTX is a subreg containing a reg that is already known to be
1050 sign- or zero-extended from the mode of the subreg to the mode of
1051 the reg. SUBREG_PROMOTED_UNSIGNED_P gives the signedness of the
1052 extension.
1054 When used as a LHS, is means that this extension must be done
1055 when assigning to SUBREG_REG. */
1057 #define SUBREG_PROMOTED_VAR_P(RTX) \
1060 #define SUBREG_PROMOTED_UNSIGNED_SET(RTX, VAL) \
1061 do { \
1063 if ((VAL) < 0) \
1064 _rtx->volatil = 1; \
1065 else { \
1066 _rtx->volatil = 0; \
1067 _rtx->unchanging = (VAL); \
1068 } \
1069 } while (0)
1070 #define SUBREG_PROMOTED_UNSIGNED_P(RTX) \
1072 ? -1 : (RTX)->unchanging)
1074 /* Access various components of an ASM_OPERANDS rtx. */
1076 #define ASM_OPERANDS_TEMPLATE(RTX) XCSTR (RTX, 0, ASM_OPERANDS)
1077 #define ASM_OPERANDS_OUTPUT_CONSTRAINT(RTX) XCSTR (RTX, 1, ASM_OPERANDS)
1078 #define ASM_OPERANDS_OUTPUT_IDX(RTX) XCINT (RTX, 2, ASM_OPERANDS)
1079 #define ASM_OPERANDS_INPUT_VEC(RTX) XCVEC (RTX, 3, ASM_OPERANDS)
1080 #define ASM_OPERANDS_INPUT_CONSTRAINT_VEC(RTX) XCVEC (RTX, 4, ASM_OPERANDS)
1081 #define ASM_OPERANDS_INPUT(RTX, N) XCVECEXP (RTX, 3, N, ASM_OPERANDS)
1082 #define ASM_OPERANDS_INPUT_LENGTH(RTX) XCVECLEN (RTX, 3, ASM_OPERANDS)
1083 #define ASM_OPERANDS_INPUT_CONSTRAINT_EXP(RTX, N) \
1084 XCVECEXP (RTX, 4, N, ASM_OPERANDS)
1085 #define ASM_OPERANDS_INPUT_CONSTRAINT(RTX, N) \
1086 XSTR (XCVECEXP (RTX, 4, N, ASM_OPERANDS), 0)
1087 #define ASM_OPERANDS_INPUT_MODE(RTX, N) \
1088 GET_MODE (XCVECEXP (RTX, 4, N, ASM_OPERANDS))
1089 #ifdef USE_MAPPED_LOCATION
1090 #define ASM_OPERANDS_SOURCE_LOCATION(RTX) XCUINT (RTX, 5, ASM_OPERANDS)
1091 #else
1092 #define ASM_OPERANDS_SOURCE_FILE(RTX) XCSTR (RTX, 5, ASM_OPERANDS)
1093 #define ASM_OPERANDS_SOURCE_LINE(RTX) XCINT (RTX, 6, ASM_OPERANDS)
1094 #endif
1096 /* 1 if RTX is a mem that is statically allocated in read-only memory. */
1097 #define MEM_READONLY_P(RTX) \
1100 /* 1 if RTX is a mem and we should keep the alias set for this mem
1101 unchanged when we access a component. Set to 1, or example, when we
1102 are already in a non-addressable component of an aggregate. */
1103 #define MEM_KEEP_ALIAS_SET_P(RTX) \
1106 /* 1 if RTX is a mem or asm_operand for a volatile reference. */
1107 #define MEM_VOLATILE_P(RTX) \
1109 ASM_INPUT)->volatil)
1111 /* 1 if RTX is a mem that refers to an aggregate, either to the
1112 aggregate itself or to a field of the aggregate. If zero, RTX may
1113 or may not be such a reference. */
1114 #define MEM_IN_STRUCT_P(RTX) \
1117 /* 1 if RTX is a MEM that refers to a scalar. If zero, RTX may or may
1118 not refer to a scalar. */
1119 #define MEM_SCALAR_P(RTX) \
1122 /* 1 if RTX is a mem that cannot trap. */
1123 #define MEM_NOTRAP_P(RTX) \
1126 /* If VAL is nonzero, set MEM_IN_STRUCT_P and clear MEM_SCALAR_P in
1127 RTX. Otherwise, vice versa. Use this macro only when you are
1128 *sure* that you know that the MEM is in a structure, or is a
1129 scalar. VAL is evaluated only once. */
1130 #define MEM_SET_IN_STRUCT_P(RTX, VAL) \
1131 do { \
1132 if (VAL) \
1133 { \
1134 MEM_IN_STRUCT_P (RTX) = 1; \
1135 MEM_SCALAR_P (RTX) = 0; \
1136 } \
1137 else \
1138 { \
1139 MEM_IN_STRUCT_P (RTX) = 0; \
1140 MEM_SCALAR_P (RTX) = 1; \
1141 } \
1142 } while (0)
1144 /* The memory attribute block. We provide access macros for each value
1145 in the block and provide defaults if none specified. */
1146 #define MEM_ATTRS(RTX) X0MEMATTR (RTX, 1)
1148 /* The register attribute block. We provide access macros for each value
1149 in the block and provide defaults if none specified. */
1150 #define REG_ATTRS(RTX) X0REGATTR (RTX, 2)
1152 /* For a MEM rtx, the alias set. If 0, this MEM is not in any alias
1153 set, and may alias anything. Otherwise, the MEM can only alias
1154 MEMs in a conflicting alias set. This value is set in a
1155 language-dependent manner in the front-end, and should not be
1156 altered in the back-end. These set numbers are tested with
1157 alias_sets_conflict_p. */
1158 #define MEM_ALIAS_SET(RTX) (MEM_ATTRS (RTX) == 0 ? 0 : MEM_ATTRS (RTX)->alias)
1160 /* For a MEM rtx, the decl it is known to refer to, if it is known to
1161 refer to part of a DECL. It may also be a COMPONENT_REF. */
1162 #define MEM_EXPR(RTX) (MEM_ATTRS (RTX) == 0 ? 0 : MEM_ATTRS (RTX)->expr)
1164 /* For a MEM rtx, the offset from the start of MEM_EXPR, if known, as a
1165 RTX that is always a CONST_INT. */
1166 #define MEM_OFFSET(RTX) (MEM_ATTRS (RTX) == 0 ? 0 : MEM_ATTRS (RTX)->offset)
1168 /* For a MEM rtx, the size in bytes of the MEM, if known, as an RTX that
1169 is always a CONST_INT. */
1170 #define MEM_SIZE(RTX) \
1171 (MEM_ATTRS (RTX) != 0 ? MEM_ATTRS (RTX)->size \
1172 : GET_MODE (RTX) != BLKmode ? GEN_INT (GET_MODE_SIZE (GET_MODE (RTX))) \
1173 : 0)
1175 /* For a MEM rtx, the alignment in bits. We can use the alignment of the
1176 mode as a default when STRICT_ALIGNMENT, but not if not. */
1177 #define MEM_ALIGN(RTX) \
1178 (MEM_ATTRS (RTX) != 0 ? MEM_ATTRS (RTX)->align \
1179 : (STRICT_ALIGNMENT && GET_MODE (RTX) != BLKmode \
1180 ? GET_MODE_ALIGNMENT (GET_MODE (RTX)) : BITS_PER_UNIT))
1182 /* For a REG rtx, the decl it is known to refer to, if it is known to
1183 refer to part of a DECL. */
1184 #define REG_EXPR(RTX) (REG_ATTRS (RTX) == 0 ? 0 : REG_ATTRS (RTX)->decl)
1186 /* For a MEM rtx, the offset from the start of MEM_DECL, if known, as a
1187 RTX that is always a CONST_INT. */
1188 #define REG_OFFSET(RTX) (REG_ATTRS (RTX) == 0 ? 0 : REG_ATTRS (RTX)->offset)
1190 /* Copy the attributes that apply to memory locations from RHS to LHS. */
1191 #define MEM_COPY_ATTRIBUTES(LHS, RHS) \
1192 (MEM_VOLATILE_P (LHS) = MEM_VOLATILE_P (RHS), \
1193 MEM_IN_STRUCT_P (LHS) = MEM_IN_STRUCT_P (RHS), \
1194 MEM_SCALAR_P (LHS) = MEM_SCALAR_P (RHS), \
1195 MEM_NOTRAP_P (LHS) = MEM_NOTRAP_P (RHS), \
1196 MEM_READONLY_P (LHS) = MEM_READONLY_P (RHS), \
1197 MEM_KEEP_ALIAS_SET_P (LHS) = MEM_KEEP_ALIAS_SET_P (RHS), \
1198 MEM_ATTRS (LHS) = MEM_ATTRS (RHS))
1200 /* 1 if RTX is a label_ref for a nonlocal label. */
1201 /* Likewise in an expr_list for a reg_label note. */
1202 #define LABEL_REF_NONLOCAL_P(RTX) \
1204 REG_LABEL)->volatil)
1206 /* 1 if RTX is a code_label that should always be considered to be needed. */
1207 #define LABEL_PRESERVE_P(RTX) \
1210 /* During sched, 1 if RTX is an insn that must be scheduled together
1211 with the preceding insn. */
1212 #define SCHED_GROUP_P(RTX) \
1214 )->in_struct)
1216 /* For a SET rtx, SET_DEST is the place that is set
1217 and SET_SRC is the value it is set to. */
1218 #define SET_DEST(RTX) XC2EXP(RTX, 0, SET, CLOBBER)
1219 #define SET_SRC(RTX) XCEXP(RTX, 1, SET)
1220 #define SET_IS_RETURN_P(RTX) \
1223 /* For a TRAP_IF rtx, TRAP_CONDITION is an expression. */
1224 #define TRAP_CONDITION(RTX) XCEXP (RTX, 0, TRAP_IF)
1225 #define TRAP_CODE(RTX) XCEXP (RTX, 1, TRAP_IF)
1227 /* For a COND_EXEC rtx, COND_EXEC_TEST is the condition to base
1228 conditionally executing the code on, COND_EXEC_CODE is the code
1229 to execute if the condition is true. */
1230 #define COND_EXEC_TEST(RTX) XCEXP (RTX, 0, COND_EXEC)
1231 #define COND_EXEC_CODE(RTX) XCEXP (RTX, 1, COND_EXEC)
1233 /* 1 if RTX is a symbol_ref that addresses this function's rtl
1234 constants pool. */
1235 #define CONSTANT_POOL_ADDRESS_P(RTX) \
1238 /* 1 if RTX is a symbol_ref that addresses a value in the file's
1239 tree constant pool. This information is private to varasm.c. */
1240 #define TREE_CONSTANT_POOL_ADDRESS_P(RTX) \
1242 (RTX), SYMBOL_REF)->frame_related)
1244 /* Used if RTX is a symbol_ref, for machine-specific purposes. */
1245 #define SYMBOL_REF_FLAG(RTX) \
1248 /* 1 if RTX is a symbol_ref that has been the library function in
1249 emit_library_call. */
1250 #define SYMBOL_REF_USED(RTX) \
1253 /* 1 if RTX is a symbol_ref for a weak symbol. */
1254 #define SYMBOL_REF_WEAK(RTX) \
1257 /* A pointer attached to the SYMBOL_REF; either SYMBOL_REF_DECL or
1258 SYMBOL_REF_CONSTANT. */
1259 #define SYMBOL_REF_DATA(RTX) X0ANY ((RTX), 2)
1261 /* Set RTX's SYMBOL_REF_DECL to DECL. RTX must not be a constant
1262 pool symbol. */
1263 #define SET_SYMBOL_REF_DECL(RTX, DECL) \
1264 (gcc_assert (!CONSTANT_POOL_ADDRESS_P (RTX)), X0TREE ((RTX), 2) = (DECL))
1266 /* The tree (decl or constant) associated with the symbol, or null. */
1267 #define SYMBOL_REF_DECL(RTX) \
1268 (CONSTANT_POOL_ADDRESS_P (RTX) ? NULL : X0TREE ((RTX), 2))
1270 /* Set RTX's SYMBOL_REF_CONSTANT to C. RTX must be a constant pool symbol. */
1271 #define SET_SYMBOL_REF_CONSTANT(RTX, C) \
1272 (gcc_assert (CONSTANT_POOL_ADDRESS_P (RTX)), X0CONSTANT ((RTX), 2) = (C))
1274 /* The rtx constant pool entry for a symbol, or null. */
1275 #define SYMBOL_REF_CONSTANT(RTX) \
1276 (CONSTANT_POOL_ADDRESS_P (RTX) ? X0CONSTANT ((RTX), 2) : NULL)
1278 /* A set of flags on a symbol_ref that are, in some respects, redundant with
1279 information derivable from the tree decl associated with this symbol.
1280 Except that we build a *lot* of SYMBOL_REFs that aren't associated with a
1281 decl. In some cases this is a bug. But beyond that, it's nice to cache
1282 this information to avoid recomputing it. Finally, this allows space for
1283 the target to store more than one bit of information, as with
1284 SYMBOL_REF_FLAG. */
1285 #define SYMBOL_REF_FLAGS(RTX) X0INT ((RTX), 1)
1287 /* These flags are common enough to be defined for all targets. They
1288 are computed by the default version of targetm.encode_section_info. */
1290 /* Set if this symbol is a function. */
1291 #define SYMBOL_FLAG_FUNCTION (1 << 0)
1292 #define SYMBOL_REF_FUNCTION_P(RTX) \
1293 ((SYMBOL_REF_FLAGS (RTX) & SYMBOL_FLAG_FUNCTION) != 0)
1294 /* Set if targetm.binds_local_p is true. */
1295 #define SYMBOL_FLAG_LOCAL (1 << 1)
1296 #define SYMBOL_REF_LOCAL_P(RTX) \
1297 ((SYMBOL_REF_FLAGS (RTX) & SYMBOL_FLAG_LOCAL) != 0)
1298 /* Set if targetm.in_small_data_p is true. */
1299 #define SYMBOL_FLAG_SMALL (1 << 2)
1300 #define SYMBOL_REF_SMALL_P(RTX) \
1301 ((SYMBOL_REF_FLAGS (RTX) & SYMBOL_FLAG_SMALL) != 0)
1302 /* The three-bit field at [5:3] is true for TLS variables; use
1303 SYMBOL_REF_TLS_MODEL to extract the field as an enum tls_model. */
1304 #define SYMBOL_FLAG_TLS_SHIFT 3
1305 #define SYMBOL_REF_TLS_MODEL(RTX) \
1306 ((enum tls_model) ((SYMBOL_REF_FLAGS (RTX) >> SYMBOL_FLAG_TLS_SHIFT) & 7))
1307 /* Set if this symbol is not defined in this translation unit. */
1308 #define SYMBOL_FLAG_EXTERNAL (1 << 6)
1309 #define SYMBOL_REF_EXTERNAL_P(RTX) \
1310 ((SYMBOL_REF_FLAGS (RTX) & SYMBOL_FLAG_EXTERNAL) != 0)
1311 /* Set if this symbol has a block_symbol structure associated with it. */
1312 #define SYMBOL_FLAG_HAS_BLOCK_INFO (1 << 7)
1313 #define SYMBOL_REF_HAS_BLOCK_INFO_P(RTX) \
1314 ((SYMBOL_REF_FLAGS (RTX) & SYMBOL_FLAG_HAS_BLOCK_INFO) != 0)
1315 /* Set if this symbol is a section anchor. SYMBOL_REF_ANCHOR_P implies
1316 SYMBOL_REF_HAS_BLOCK_INFO_P. */
1317 #define SYMBOL_FLAG_ANCHOR (1 << 8)
1318 #define SYMBOL_REF_ANCHOR_P(RTX) \
1319 ((SYMBOL_REF_FLAGS (RTX) & SYMBOL_FLAG_ANCHOR) != 0)
1321 /* Subsequent bits are available for the target to use. */
1322 #define SYMBOL_FLAG_MACH_DEP_SHIFT 9
1323 #define SYMBOL_FLAG_MACH_DEP (1 << SYMBOL_FLAG_MACH_DEP_SHIFT)
1325 /* If SYMBOL_REF_HAS_BLOCK_INFO_P (RTX), this is the object_block
1326 structure to which the symbol belongs, or NULL if it has not been
1327 assigned a block. */
1328 #define SYMBOL_REF_BLOCK(RTX) (BLOCK_SYMBOL_CHECK (RTX)->block)
1330 /* If SYMBOL_REF_HAS_BLOCK_INFO_P (RTX), this is the offset of RTX from
1331 the first object in SYMBOL_REF_BLOCK (RTX). The value is negative if
1332 RTX has not yet been assigned to a block, or it has not been given an
1333 offset within that block. */
1334 #define SYMBOL_REF_BLOCK_OFFSET(RTX) (BLOCK_SYMBOL_CHECK (RTX)->offset)
1336 /* Define a macro to look for REG_INC notes,
1337 but save time on machines where they never exist. */
1339 #if (defined (HAVE_PRE_INCREMENT) || defined (HAVE_PRE_DECREMENT) || defined (HAVE_POST_INCREMENT) || defined (HAVE_POST_DECREMENT))
1340 #define FIND_REG_INC_NOTE(INSN, REG) \
1341 ((REG) != NULL_RTX && REG_P ((REG)) \
1342 ? find_regno_note ((INSN), REG_INC, REGNO (REG)) \
1343 : find_reg_note ((INSN), REG_INC, (REG)))
1344 #else
1345 #define FIND_REG_INC_NOTE(INSN, REG) 0
1346 #endif
1348 /* Indicate whether the machine has any sort of auto increment addressing.
1349 If not, we can avoid checking for REG_INC notes. */
1351 #if (defined (HAVE_PRE_INCREMENT) || defined (HAVE_PRE_DECREMENT) || defined (HAVE_POST_INCREMENT) || defined (HAVE_POST_DECREMENT))
1352 #define AUTO_INC_DEC
1353 #endif
1355 #ifndef HAVE_PRE_INCREMENT
1356 #define HAVE_PRE_INCREMENT 0
1357 #endif
1359 #ifndef HAVE_PRE_DECREMENT
1360 #define HAVE_PRE_DECREMENT 0
1361 #endif
1363 #ifndef HAVE_POST_INCREMENT
1364 #define HAVE_POST_INCREMENT 0
1365 #endif
1367 #ifndef HAVE_POST_DECREMENT
1368 #define HAVE_POST_DECREMENT 0
1369 #endif
1371 #ifndef HAVE_POST_MODIFY_DISP
1372 #define HAVE_POST_MODIFY_DISP 0
1373 #endif
1375 #ifndef HAVE_POST_MODIFY_REG
1376 #define HAVE_POST_MODIFY_REG 0
1377 #endif
1379 #ifndef HAVE_PRE_MODIFY_DISP
1380 #define HAVE_PRE_MODIFY_DISP 0
1381 #endif
1383 #ifndef HAVE_PRE_MODIFY_REG
1384 #define HAVE_PRE_MODIFY_REG 0
1385 #endif
1388 /* Some architectures do not have complete pre/post increment/decrement
1389 instruction sets, or only move some modes efficiently. These macros
1390 allow us to tune autoincrement generation. */
1392 #ifndef USE_LOAD_POST_INCREMENT
1393 #define USE_LOAD_POST_INCREMENT(MODE) HAVE_POST_INCREMENT
1394 #endif
1396 #ifndef USE_LOAD_POST_DECREMENT
1397 #define USE_LOAD_POST_DECREMENT(MODE) HAVE_POST_DECREMENT
1398 #endif
1400 #ifndef USE_LOAD_PRE_INCREMENT
1401 #define USE_LOAD_PRE_INCREMENT(MODE) HAVE_PRE_INCREMENT
1402 #endif
1404 #ifndef USE_LOAD_PRE_DECREMENT
1405 #define USE_LOAD_PRE_DECREMENT(MODE) HAVE_PRE_DECREMENT
1406 #endif
1408 #ifndef USE_STORE_POST_INCREMENT
1409 #define USE_STORE_POST_INCREMENT(MODE) HAVE_POST_INCREMENT
1410 #endif
1412 #ifndef USE_STORE_POST_DECREMENT
1413 #define USE_STORE_POST_DECREMENT(MODE) HAVE_POST_DECREMENT
1414 #endif
1416 #ifndef USE_STORE_PRE_INCREMENT
1417 #define USE_STORE_PRE_INCREMENT(MODE) HAVE_PRE_INCREMENT
1418 #endif
1420 #ifndef USE_STORE_PRE_DECREMENT
1421 #define USE_STORE_PRE_DECREMENT(MODE) HAVE_PRE_DECREMENT
1422 #endif
1423 \f
1424 /* Nonzero when we are generating CONCATs. */
1427 /* Nonzero when we are expanding trees to RTL. */
1430 /* Generally useful functions. */
1432 /* In expmed.c */
1435 /* In builtins.c */
1438 /* In explow.c */
1443 /* In emit-rtl.c */
1454 /* In rtl.c */
1456 #define rtx_alloc(c) rtx_alloc_stat (c MEM_STAT_INFO)
1462 /* In emit-rtl.c */
1465 /* In rtl.c */
1468 #define shallow_copy_rtx(a) shallow_copy_rtx_stat (a MEM_STAT_INFO)
1471 /* In emit-rtl.c */
1478 /* In cse.c */
1481 /* In emit-rtl.c */
1486 /* In emit-rtl.c */
1507 /* In loop-iv.c */
1511 /* In varasm.c */
1514 /* In varasm.c */
1522 /* In function.c */
1529 /* In emit-rtl.c */
1582 /* In cfglayout.c */
1589 /* In jump.c */
1598 /* In jump.c */
1606 /* In recog.c */
1609 /* In emit-rtl.c */
1613 /* In unknown file */
1616 /* In simplify-rtx.c */
1624 rtx);
1648 /* In regclass.c */
1652 /* In emit-rtl.c */
1655 /* Functions in rtlanal.c */
1657 /* Single set is implemented as macro for performance reasons. */
1658 #define single_set(I) (INSN_P (I) \
1659 ? (GET_CODE (PATTERN (I)) == SET \
1660 ? PATTERN (I) : single_set_1 (I)) \
1661 : NULL_RTX)
1662 #define single_set_1(I) single_set_2 (I, PATTERN (I))
1664 /* Structure used for passing data to REPLACE_LABEL. */
1666 {
1667 rtx r1;
1668 rtx r2;
1733 /* Given an insn and condition, return a canonical description of
1734 the test being made. */
1737 /* Given a JUMP_INSN, return a canonical description of the test
1738 being made. */
1742 /* flow.c */
1746 /* lists.c */
1761 /* regclass.c */
1763 /* Maximum number of parallel sets and clobbers in any insn in this fn.
1764 Always at least 3, since the combiner could put that many together
1765 and we want this to remain correct for all the remaining passes. */
1769 /* Free up register info memory. */
1772 /* recog.c */
1783 #define MAX_SAVED_CONST_INT 64
1786 #define const0_rtx (const_int_rtx[MAX_SAVED_CONST_INT])
1787 #define const1_rtx (const_int_rtx[MAX_SAVED_CONST_INT+1])
1788 #define const2_rtx (const_int_rtx[MAX_SAVED_CONST_INT+2])
1789 #define constm1_rtx (const_int_rtx[MAX_SAVED_CONST_INT-1])
1794 /* Returns a constant 0 rtx in mode MODE. Integer modes are treated the
1795 same as VOIDmode. */
1797 #define CONST0_RTX(MODE) (const_tiny_rtx[0][(int) (MODE)])
1799 /* Likewise, for the constants 1 and 2. */
1801 #define CONST1_RTX(MODE) (const_tiny_rtx[1][(int) (MODE)])
1802 #define CONST2_RTX(MODE) (const_tiny_rtx[2][(int) (MODE)])
1804 /* If HARD_FRAME_POINTER_REGNUM is defined, then a special dummy reg
1805 is used to represent the frame pointer. This is because the
1806 hard frame pointer and the automatic variables are separated by an amount
1807 that cannot be determined until after register allocation. We can assume
1808 that in this case ELIMINABLE_REGS will be defined, one action of which
1809 will be to eliminate FRAME_POINTER_REGNUM into HARD_FRAME_POINTER_REGNUM. */
1810 #ifndef HARD_FRAME_POINTER_REGNUM
1811 #define HARD_FRAME_POINTER_REGNUM FRAME_POINTER_REGNUM
1812 #endif
1814 /* Index labels for global_rtl. */
1815 enum global_rtl_index
1816 {
1817 GR_PC,
1818 GR_CC0,
1819 GR_STACK_POINTER,
1820 GR_FRAME_POINTER,
1821 /* For register elimination to work properly these hard_frame_pointer_rtx,
1822 frame_pointer_rtx, and arg_pointer_rtx must be the same if they refer to
1823 the same register. */
1824 #if FRAME_POINTER_REGNUM == ARG_POINTER_REGNUM
1826 #endif
1827 #if HARD_FRAME_POINTER_REGNUM == FRAME_POINTER_REGNUM
1829 #else
1830 GR_HARD_FRAME_POINTER,
1831 #endif
1832 #if FRAME_POINTER_REGNUM != ARG_POINTER_REGNUM
1833 #if HARD_FRAME_POINTER_REGNUM == ARG_POINTER_REGNUM
1835 #else
1836 GR_ARG_POINTER,
1837 #endif
1838 #endif
1839 GR_VIRTUAL_INCOMING_ARGS,
1840 GR_VIRTUAL_STACK_ARGS,
1841 GR_VIRTUAL_STACK_DYNAMIC,
1842 GR_VIRTUAL_OUTGOING_ARGS,
1843 GR_VIRTUAL_CFA,
1845 GR_MAX
1846 };
1848 /* Pointers to standard pieces of rtx are stored here. */
1851 /* Standard pieces of rtx, to be substituted directly into things. */
1852 #define pc_rtx (global_rtl[GR_PC])
1853 #define cc0_rtx (global_rtl[GR_CC0])
1855 /* All references to certain hard regs, except those created
1856 by allocating pseudo regs into them (when that's possible),
1857 go through these unique rtx objects. */
1858 #define stack_pointer_rtx (global_rtl[GR_STACK_POINTER])
1859 #define frame_pointer_rtx (global_rtl[GR_FRAME_POINTER])
1860 #define hard_frame_pointer_rtx (global_rtl[GR_HARD_FRAME_POINTER])
1861 #define arg_pointer_rtx (global_rtl[GR_ARG_POINTER])
1868 /* Include the RTL generation functions. */
1870 #ifndef GENERATOR_FILE
1872 #ifndef USE_MAPPED_LOCATION
1873 #undef gen_rtx_ASM_OPERANDS
1874 #define gen_rtx_ASM_OPERANDS(MODE, ARG0, ARG1, ARG2, ARG3, ARG4, LOC) \
1875 gen_rtx_fmt_ssiEEsi (ASM_OPERANDS, (MODE), (ARG0), (ARG1), (ARG2), (ARG3), (ARG4), (LOC).file, (LOC).line)
1876 #endif
1877 #endif
1879 /* There are some RTL codes that require special attention; the
1880 generation functions included above do the raw handling. If you
1881 add to this list, modify special_rtx in gengenrtl.c as well. */
1890 #define GEN_INT(N) gen_rtx_CONST_INT (VOIDmode, (N))
1892 /* Virtual registers are used during RTL generation to refer to locations into
1893 the stack frame when the actual location isn't known until RTL generation
1894 is complete. The routine instantiate_virtual_regs replaces these with
1895 the proper value, which is normally {frame,arg,stack}_pointer_rtx plus
1896 a constant. */
1898 #define FIRST_VIRTUAL_REGISTER (FIRST_PSEUDO_REGISTER)
1900 /* This points to the first word of the incoming arguments passed on the stack,
1901 either by the caller or by the callee when pretending it was passed by the
1902 caller. */
1904 #define virtual_incoming_args_rtx (global_rtl[GR_VIRTUAL_INCOMING_ARGS])
1906 #define VIRTUAL_INCOMING_ARGS_REGNUM (FIRST_VIRTUAL_REGISTER)
1908 /* If FRAME_GROWS_DOWNWARD, this points to immediately above the first
1909 variable on the stack. Otherwise, it points to the first variable on
1910 the stack. */
1912 #define virtual_stack_vars_rtx (global_rtl[GR_VIRTUAL_STACK_ARGS])
1914 #define VIRTUAL_STACK_VARS_REGNUM ((FIRST_VIRTUAL_REGISTER) + 1)
1916 /* This points to the location of dynamically-allocated memory on the stack
1917 immediately after the stack pointer has been adjusted by the amount
1918 desired. */
1920 #define virtual_stack_dynamic_rtx (global_rtl[GR_VIRTUAL_STACK_DYNAMIC])
1922 #define VIRTUAL_STACK_DYNAMIC_REGNUM ((FIRST_VIRTUAL_REGISTER) + 2)
1924 /* This points to the location in the stack at which outgoing arguments should
1925 be written when the stack is pre-pushed (arguments pushed using push
1926 insns always use sp). */
1928 #define virtual_outgoing_args_rtx (global_rtl[GR_VIRTUAL_OUTGOING_ARGS])
1930 #define VIRTUAL_OUTGOING_ARGS_REGNUM ((FIRST_VIRTUAL_REGISTER) + 3)
1932 /* This points to the Canonical Frame Address of the function. This
1933 should correspond to the CFA produced by INCOMING_FRAME_SP_OFFSET,
1934 but is calculated relative to the arg pointer for simplicity; the
1935 frame pointer nor stack pointer are necessarily fixed relative to
1936 the CFA until after reload. */
1938 #define virtual_cfa_rtx (global_rtl[GR_VIRTUAL_CFA])
1940 #define VIRTUAL_CFA_REGNUM ((FIRST_VIRTUAL_REGISTER) + 4)
1942 #define LAST_VIRTUAL_REGISTER ((FIRST_VIRTUAL_REGISTER) + 4)
1944 /* Nonzero if REGNUM is a pointer into the stack frame. */
1945 #define REGNO_PTR_FRAME_P(REGNUM) \
1946 ((REGNUM) == STACK_POINTER_REGNUM \
1947 || (REGNUM) == FRAME_POINTER_REGNUM \
1948 || (REGNUM) == HARD_FRAME_POINTER_REGNUM \
1949 || (REGNUM) == ARG_POINTER_REGNUM \
1950 || ((REGNUM) >= FIRST_VIRTUAL_REGISTER \
1951 && (REGNUM) <= LAST_VIRTUAL_REGISTER))
1953 /* REGNUM never really appearing in the INSN stream. */
1954 #define INVALID_REGNUM (~(unsigned int) 0)
1959 /* Nonzero after the second flow pass has completed.
1960 Set to 1 or 0 by toplev.c */
1963 /* Nonzero after end of reload pass.
1964 Set to 1 or 0 by reload1.c. */
1968 /* Nonzero after thread_prologue_and_epilogue_insns has run. */
1971 /* Set to 1 while reload_as_needed is operating.
1972 Required by some machines to handle any generated moves differently. */
1976 #ifdef STACK_REGS
1977 /* Nonzero after end of regstack pass.
1978 Set to 1 or 0 by reg-stack.c. */
1980 #endif
1982 /* If this is nonzero, we do not bother generating VOLATILE
1983 around volatile memory references, and we are willing to
1984 output indirect addresses. If cse is to follow, we reject
1985 indirect addresses so a useful potential cse is generated;
1986 if it is used only once, instruction combination will produce
1987 the same indirect address eventually. */
1990 /* Set to nonzero before life analysis to indicate that it is unsafe to
1991 generate any new pseudo registers. */
1994 /* Translates rtx code to tree code, for those codes needed by
1995 REAL_ARITHMETIC. The function returns an int because the caller may not
1996 know what `enum tree_code' means. */
2000 /* In cse.c */
2006 /* In jump.c */
2035 /* In emit-rtl.c. */
2083 /* In combine.c */
2089 /* In sched-vis.c. */
2094 /* In sched-rgn.c. */
2097 /* In sched-ebb.c. */
2100 /* In haifa-sched.c. */
2103 /* In print-rtl.c */
2115 /* In bt-load.c */
2118 /* In function.c */
2126 /* In stmt.c */
2131 /* In expr.c */
2135 /* In flow.c */
2140 /* In expmed.c */
2145 /* In gcse.c */
2149 /* In global.c */
2152 #ifdef HARD_CONST
2153 /* Yes, this ifdef is silly, but HARD_REG_SET is not always defined. */
2155 #endif
2158 /* In regclass.c */
2172 #ifdef HARD_CONST
2175 #endif
2179 /* In reorg.c */
2182 /* In local-alloc.c */
2185 /* In reload1.c */
2188 /* In calls.c */
2189 enum libcall_type
2190 {
2199 };
2202 ...);
2206 /* In varasm.c */
2210 /* In rtl.c */
2214 /* In read-rtl.c */
2224 /* In alias.c */
2243 #ifdef STACK_REGS
2245 #endif
2247 /* In toplev.c */
2250 /* In predict.c */
2253 /* In tracer.c */
2256 /* In var-tracking.c */
2259 /* In stor-layout.c. */
2263 /* In loop-unswitch.c */
2267 /* In loop-iv.c */
2270 \f
2271 struct rtl_hooks
2272 {
2281 /* Whenever you add entries here, make sure you adjust rtlhooks-def.h. */
2282 };
2284 /* Each pass can provide its own. */
2287 /* ... but then it has to restore these. */
2290 /* Keep this for the nonce. */
2291 #define gen_lowpart rtl_hooks.gen_lowpart