1 /* Subroutines used for MIPS code generation.
2 Copyright (C) 1989, 1990, 1991, 1993, 1994, 1995, 1996, 1997, 1998,
3 1999, 2000, 2001, 2002, 2003, 2004, 2005 Free Software Foundation, Inc.
4 Contributed by A. Lichnewsky, lich@inria.inria.fr.
5 Changes by Michael Meissner, meissner@osf.org.
6 64 bit r4000 support by Ian Lance Taylor, ian@cygnus.com, and
7 Brendan Eich, brendan@microunity.com.
9 This file is part of GCC.
11 GCC is free software; you can redistribute it and/or modify
12 it under the terms of the GNU General Public License as published by
13 the Free Software Foundation; either version 2, or (at your option)
16 GCC is distributed in the hope that it will be useful,
17 but WITHOUT ANY WARRANTY; without even the implied warranty of
18 MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
19 GNU General Public License for more details.
21 You should have received a copy of the GNU General Public License
22 along with GCC; see the file COPYING. If not, write to
23 the Free Software Foundation, 51 Franklin Street, Fifth Floor,
24 Boston, MA 02110-1301, USA. */
28 #include "coretypes.h"
33 #include "hard-reg-set.h"
35 #include "insn-config.h"
36 #include "conditions.h"
37 #include "insn-attr.h"
53 #include "target-def.h"
54 #include "integrate.h"
55 #include "langhooks.h"
56 #include "cfglayout.h"
57 #include "sched-int.h"
58 #include "tree-gimple.h"
61 /* True if X is an unspec wrapper around a SYMBOL_REF or LABEL_REF. */
62 #define UNSPEC_ADDRESS_P(X) \
63 (GET_CODE (X) == UNSPEC \
64 && XINT (X, 1) >= UNSPEC_ADDRESS_FIRST \
65 && XINT (X, 1) < UNSPEC_ADDRESS_FIRST + NUM_SYMBOL_TYPES)
67 /* Extract the symbol or label from UNSPEC wrapper X. */
68 #define UNSPEC_ADDRESS(X) \
71 /* Extract the symbol type from UNSPEC wrapper X. */
72 #define UNSPEC_ADDRESS_TYPE(X) \
73 ((enum mips_symbol_type) (XINT (X, 1) - UNSPEC_ADDRESS_FIRST))
75 /* The maximum distance between the top of the stack frame and the
76 value $sp has when we save & restore registers.
78 Use a maximum gap of 0x100 in the mips16 case. We can then use
79 unextended instructions to save and restore registers, and to
80 allocate and deallocate the top part of the frame.
82 The value in the !mips16 case must be a SMALL_OPERAND and must
83 preserve the maximum stack alignment. */
84 #define MIPS_MAX_FIRST_STACK_STEP (TARGET_MIPS16 ? 0x100 : 0x7ff0)
86 /* True if INSN is a mips.md pattern or asm statement. */
87 #define USEFUL_INSN_P(INSN) \
89 && GET_CODE (PATTERN (INSN)) != USE \
90 && GET_CODE (PATTERN (INSN)) != CLOBBER \
91 && GET_CODE (PATTERN (INSN)) != ADDR_VEC \
92 && GET_CODE (PATTERN (INSN)) != ADDR_DIFF_VEC)
94 /* If INSN is a delayed branch sequence, return the first instruction
95 in the sequence, otherwise return INSN itself. */
96 #define SEQ_BEGIN(INSN) \
97 (INSN_P (INSN) && GET_CODE (PATTERN (INSN)) == SEQUENCE \
98 ? XVECEXP (PATTERN (INSN), 0, 0) \
101 /* Likewise for the last instruction in a delayed branch sequence. */
102 #define SEQ_END(INSN) \
103 (INSN_P (INSN) && GET_CODE (PATTERN (INSN)) == SEQUENCE \
104 ? XVECEXP (PATTERN (INSN), 0, XVECLEN (PATTERN (INSN), 0) - 1) \
107 /* Execute the following loop body with SUBINSN set to each instruction
108 between SEQ_BEGIN (INSN) and SEQ_END (INSN) inclusive. */
109 #define FOR_EACH_SUBINSN(SUBINSN, INSN) \
110 for ((SUBINSN) = SEQ_BEGIN (INSN); \
111 (SUBINSN) != NEXT_INSN (SEQ_END (INSN)); \
112 (SUBINSN) = NEXT_INSN (SUBINSN))
114 /* Classifies an address.
117 A natural register + offset address. The register satisfies
118 mips_valid_base_register_p and the offset is a const_arith_operand.
121 A LO_SUM rtx. The first operand is a valid base register and
122 the second operand is a symbolic address.
125 A signed 16-bit constant address.
128 A constant symbolic address (equivalent to CONSTANT_SYMBOLIC). */
129 enum mips_address_type {
136 /* Classifies the prototype of a builtin function. */
137 enum mips_function_type
139 MIPS_V2SF_FTYPE_V2SF,
140 MIPS_V2SF_FTYPE_V2SF_V2SF,
141 MIPS_V2SF_FTYPE_V2SF_V2SF_INT,
142 MIPS_V2SF_FTYPE_V2SF_V2SF_V2SF_V2SF,
143 MIPS_V2SF_FTYPE_SF_SF,
144 MIPS_INT_FTYPE_V2SF_V2SF,
145 MIPS_INT_FTYPE_V2SF_V2SF_V2SF_V2SF,
146 MIPS_INT_FTYPE_SF_SF,
147 MIPS_INT_FTYPE_DF_DF,
154 /* For MIPS DSP ASE */
156 MIPS_DI_FTYPE_DI_SI_SI,
157 MIPS_DI_FTYPE_DI_V2HI_V2HI,
158 MIPS_DI_FTYPE_DI_V4QI_V4QI,
160 MIPS_SI_FTYPE_PTR_SI,
164 MIPS_SI_FTYPE_V2HI_V2HI,
166 MIPS_SI_FTYPE_V4QI_V4QI,
169 MIPS_V2HI_FTYPE_SI_SI,
170 MIPS_V2HI_FTYPE_V2HI,
171 MIPS_V2HI_FTYPE_V2HI_SI,
172 MIPS_V2HI_FTYPE_V2HI_V2HI,
173 MIPS_V2HI_FTYPE_V4QI,
174 MIPS_V2HI_FTYPE_V4QI_V2HI,
176 MIPS_V4QI_FTYPE_V2HI_V2HI,
177 MIPS_V4QI_FTYPE_V4QI_SI,
178 MIPS_V4QI_FTYPE_V4QI_V4QI,
179 MIPS_VOID_FTYPE_SI_SI,
180 MIPS_VOID_FTYPE_V2HI_V2HI,
181 MIPS_VOID_FTYPE_V4QI_V4QI,
187 /* Specifies how a builtin function should be converted into rtl. */
188 enum mips_builtin_type
190 /* The builtin corresponds directly to an .md pattern. The return
191 value is mapped to operand 0 and the arguments are mapped to
192 operands 1 and above. */
195 /* The builtin corresponds directly to an .md pattern. There is no return
196 value and the arguments are mapped to operands 0 and above. */
197 MIPS_BUILTIN_DIRECT_NO_TARGET,
199 /* The builtin corresponds to a comparison instruction followed by
200 a mips_cond_move_tf_ps pattern. The first two arguments are the
201 values to compare and the second two arguments are the vector
202 operands for the movt.ps or movf.ps instruction (in assembly order). */
206 /* The builtin corresponds to a V2SF comparison instruction. Operand 0
207 of this instruction is the result of the comparison, which has mode
208 CCV2 or CCV4. The function arguments are mapped to operands 1 and
209 above. The function's return value is an SImode boolean that is
210 true under the following conditions:
212 MIPS_BUILTIN_CMP_ANY: one of the registers is true
213 MIPS_BUILTIN_CMP_ALL: all of the registers are true
214 MIPS_BUILTIN_CMP_LOWER: the first register is true
215 MIPS_BUILTIN_CMP_UPPER: the second register is true. */
216 MIPS_BUILTIN_CMP_ANY,
217 MIPS_BUILTIN_CMP_ALL,
218 MIPS_BUILTIN_CMP_UPPER,
219 MIPS_BUILTIN_CMP_LOWER,
221 /* As above, but the instruction only sets a single $fcc register. */
222 MIPS_BUILTIN_CMP_SINGLE,
224 /* For generating bposge32 branch instructions in MIPS32 DSP ASE. */
225 MIPS_BUILTIN_BPOSGE32
228 /* Invokes MACRO (COND) for each c.cond.fmt condition. */
229 #define MIPS_FP_CONDITIONS(MACRO) \
247 /* Enumerates the codes above as MIPS_FP_COND_<X>. */
248 #define DECLARE_MIPS_COND(X) MIPS_FP_COND_ ## X
249 enum mips_fp_condition {
250 MIPS_FP_CONDITIONS (DECLARE_MIPS_COND)
253 /* Index X provides the string representation of MIPS_FP_COND_<X>. */
254 #define STRINGIFY(X) #X
255 static const char *const mips_fp_conditions[] = {
256 MIPS_FP_CONDITIONS (STRINGIFY)
259 /* A function to save or store a register. The first argument is the
260 register and the second is the stack slot. */
261 typedef void (*mips_save_restore_fn) (rtx, rtx);
263 struct mips16_constant;
264 struct mips_arg_info;
265 struct mips_address_info;
266 struct mips_integer_op;
269 static enum mips_symbol_type mips_classify_symbol (rtx);
270 static void mips_split_const (rtx, rtx *, HOST_WIDE_INT *);
271 static bool mips_offset_within_object_p (rtx, HOST_WIDE_INT);
272 static bool mips_valid_base_register_p (rtx, enum machine_mode, int);
273 static bool mips_symbolic_address_p (enum mips_symbol_type, enum machine_mode);
274 static bool mips_classify_address (struct mips_address_info *, rtx,
275 enum machine_mode, int);
276 static bool mips_cannot_force_const_mem (rtx);
277 static bool mips_use_blocks_for_constant_p (enum machine_mode, rtx);
278 static int mips_symbol_insns (enum mips_symbol_type);
279 static bool mips16_unextended_reference_p (enum machine_mode mode, rtx, rtx);
280 static rtx mips_force_temporary (rtx, rtx);
281 static rtx mips_unspec_offset_high (rtx, rtx, rtx, enum mips_symbol_type);
282 static rtx mips_add_offset (rtx, rtx, HOST_WIDE_INT);
283 static unsigned int mips_build_shift (struct mips_integer_op *, HOST_WIDE_INT);
284 static unsigned int mips_build_lower (struct mips_integer_op *,
285 unsigned HOST_WIDE_INT);
286 static unsigned int mips_build_integer (struct mips_integer_op *,
287 unsigned HOST_WIDE_INT);
288 static void mips_legitimize_const_move (enum machine_mode, rtx, rtx);
289 static int m16_check_op (rtx, int, int, int);
290 static bool mips_rtx_costs (rtx, int, int, int *);
291 static int mips_address_cost (rtx);
292 static void mips_emit_compare (enum rtx_code *, rtx *, rtx *, bool);
293 static void mips_load_call_address (rtx, rtx, int);
294 static bool mips_function_ok_for_sibcall (tree, tree);
295 static void mips_block_move_straight (rtx, rtx, HOST_WIDE_INT);
296 static void mips_adjust_block_mem (rtx, HOST_WIDE_INT, rtx *, rtx *);
297 static void mips_block_move_loop (rtx, rtx, HOST_WIDE_INT);
298 static void mips_arg_info (const CUMULATIVE_ARGS *, enum machine_mode,
299 tree, int, struct mips_arg_info *);
300 static bool mips_get_unaligned_mem (rtx *, unsigned int, int, rtx *, rtx *);
301 static void mips_set_architecture (const struct mips_cpu_info *);
302 static void mips_set_tune (const struct mips_cpu_info *);
303 static bool mips_handle_option (size_t, const char *, int);
304 static struct machine_function *mips_init_machine_status (void);
305 static void print_operand_reloc (FILE *, rtx, const char **);
307 static void irix_output_external_libcall (rtx);
309 static void mips_file_start (void);
310 static void mips_file_end (void);
311 static bool mips_rewrite_small_data_p (rtx);
312 static int mips_small_data_pattern_1 (rtx *, void *);
313 static int mips_rewrite_small_data_1 (rtx *, void *);
314 static bool mips_function_has_gp_insn (void);
315 static unsigned int mips_global_pointer (void);
316 static bool mips_save_reg_p (unsigned int);
317 static void mips_save_restore_reg (enum machine_mode, int, HOST_WIDE_INT,
318 mips_save_restore_fn);
319 static void mips_for_each_saved_reg (HOST_WIDE_INT, mips_save_restore_fn);
320 static void mips_output_cplocal (void);
321 static void mips_emit_loadgp (void);
322 static void mips_output_function_prologue (FILE *, HOST_WIDE_INT);
323 static void mips_set_frame_expr (rtx);
324 static rtx mips_frame_set (rtx, rtx);
325 static void mips_save_reg (rtx, rtx);
326 static void mips_output_function_epilogue (FILE *, HOST_WIDE_INT);
327 static void mips_restore_reg (rtx, rtx);
328 static void mips_output_mi_thunk (FILE *, tree, HOST_WIDE_INT,
329 HOST_WIDE_INT, tree);
330 static int symbolic_expression_p (rtx);
331 static section *mips_select_rtx_section (enum machine_mode, rtx,
332 unsigned HOST_WIDE_INT);
333 static section *mips_function_rodata_section (tree);
334 static bool mips_in_small_data_p (tree);
335 static bool mips_use_anchors_for_symbol_p (rtx);
336 static int mips_fpr_return_fields (tree, tree *);
337 static bool mips_return_in_msb (tree);
338 static rtx mips_return_fpr_pair (enum machine_mode mode,
339 enum machine_mode mode1, HOST_WIDE_INT,
340 enum machine_mode mode2, HOST_WIDE_INT);
341 static rtx mips16_gp_pseudo_reg (void);
342 static void mips16_fp_args (FILE *, int, int);
343 static void build_mips16_function_stub (FILE *);
344 static rtx dump_constants_1 (enum machine_mode, rtx, rtx);
345 static void dump_constants (struct mips16_constant *, rtx);
346 static int mips16_insn_length (rtx);
347 static int mips16_rewrite_pool_refs (rtx *, void *);
348 static void mips16_lay_out_constants (void);
349 static void mips_sim_reset (struct mips_sim *);
350 static void mips_sim_init (struct mips_sim *, state_t);
351 static void mips_sim_next_cycle (struct mips_sim *);
352 static void mips_sim_wait_reg (struct mips_sim *, rtx, rtx);
353 static int mips_sim_wait_regs_2 (rtx *, void *);
354 static void mips_sim_wait_regs_1 (rtx *, void *);
355 static void mips_sim_wait_regs (struct mips_sim *, rtx);
356 static void mips_sim_wait_units (struct mips_sim *, rtx);
357 static void mips_sim_wait_insn (struct mips_sim *, rtx);
358 static void mips_sim_record_set (rtx, rtx, void *);
359 static void mips_sim_issue_insn (struct mips_sim *, rtx);
360 static void mips_sim_issue_nop (struct mips_sim *);
361 static void mips_sim_finish_insn (struct mips_sim *, rtx);
362 static void vr4130_avoid_branch_rt_conflict (rtx);
363 static void vr4130_align_insns (void);
364 static void mips_avoid_hazard (rtx, rtx, int *, rtx *, rtx);
365 static void mips_avoid_hazards (void);
366 static void mips_reorg (void);
367 static bool mips_strict_matching_cpu_name_p (const char *, const char *);
368 static bool mips_matching_cpu_name_p (const char *, const char *);
369 static const struct mips_cpu_info *mips_parse_cpu (const char *);
370 static const struct mips_cpu_info *mips_cpu_info_from_isa (int);
371 static bool mips_return_in_memory (tree, tree);
372 static bool mips_strict_argument_naming (CUMULATIVE_ARGS *);
373 static void mips_macc_chains_record (rtx);
374 static void mips_macc_chains_reorder (rtx *, int);
375 static void vr4130_true_reg_dependence_p_1 (rtx, rtx, void *);
376 static bool vr4130_true_reg_dependence_p (rtx);
377 static bool vr4130_swap_insns_p (rtx, rtx);
378 static void vr4130_reorder (rtx *, int);
379 static void mips_promote_ready (rtx *, int, int);
380 static int mips_sched_reorder (FILE *, int, rtx *, int *, int);
381 static int mips_variable_issue (FILE *, int, rtx, int);
382 static int mips_adjust_cost (rtx, rtx, rtx, int);
383 static int mips_issue_rate (void);
384 static int mips_multipass_dfa_lookahead (void);
385 static void mips_init_libfuncs (void);
386 static void mips_setup_incoming_varargs (CUMULATIVE_ARGS *, enum machine_mode,
388 static tree mips_build_builtin_va_list (void);
389 static tree mips_gimplify_va_arg_expr (tree, tree, tree *, tree *);
390 static bool mips_pass_by_reference (CUMULATIVE_ARGS *, enum machine_mode mode,
392 static bool mips_callee_copies (CUMULATIVE_ARGS *, enum machine_mode mode,
394 static int mips_arg_partial_bytes (CUMULATIVE_ARGS *, enum machine_mode mode,
396 static bool mips_valid_pointer_mode (enum machine_mode);
397 static bool mips_vector_mode_supported_p (enum machine_mode);
398 static rtx mips_prepare_builtin_arg (enum insn_code, unsigned int, tree *);
399 static rtx mips_prepare_builtin_target (enum insn_code, unsigned int, rtx);
400 static rtx mips_expand_builtin (tree, rtx, rtx, enum machine_mode, int);
401 static void mips_init_builtins (void);
402 static rtx mips_expand_builtin_direct (enum insn_code, rtx, tree, bool);
403 static rtx mips_expand_builtin_movtf (enum mips_builtin_type,
404 enum insn_code, enum mips_fp_condition,
406 static rtx mips_expand_builtin_compare (enum mips_builtin_type,
407 enum insn_code, enum mips_fp_condition,
409 static rtx mips_expand_builtin_bposge (enum mips_builtin_type, rtx);
410 static void mips_encode_section_info (tree, rtx, int);
411 static void mips_extra_live_on_entry (bitmap);
412 static int mips_mode_rep_extended (enum machine_mode, enum machine_mode);
414 /* Structure to be filled in by compute_frame_size with register
415 save masks, and offsets for the current function. */
417 struct mips_frame_info GTY(())
419 HOST_WIDE_INT total_size; /* # bytes that the entire frame takes up */
420 HOST_WIDE_INT var_size; /* # bytes that variables take up */
421 HOST_WIDE_INT args_size; /* # bytes that outgoing arguments take up */
422 HOST_WIDE_INT cprestore_size; /* # bytes that the .cprestore slot takes up */
423 HOST_WIDE_INT gp_reg_size; /* # bytes needed to store gp regs */
424 HOST_WIDE_INT fp_reg_size; /* # bytes needed to store fp regs */
425 unsigned int mask; /* mask of saved gp registers */
426 unsigned int fmask; /* mask of saved fp registers */
427 HOST_WIDE_INT gp_save_offset; /* offset from vfp to store gp registers */
428 HOST_WIDE_INT fp_save_offset; /* offset from vfp to store fp registers */
429 HOST_WIDE_INT gp_sp_offset; /* offset from new sp to store gp registers */
430 HOST_WIDE_INT fp_sp_offset; /* offset from new sp to store fp registers */
431 bool initialized; /* true if frame size already calculated */
432 int num_gp; /* number of gp registers saved */
433 int num_fp; /* number of fp registers saved */
436 struct machine_function GTY(()) {
437 /* Pseudo-reg holding the value of $28 in a mips16 function which
438 refers to GP relative global variables. */
439 rtx mips16_gp_pseudo_rtx;
441 /* The number of extra stack bytes taken up by register varargs.
442 This area is allocated by the callee at the very top of the frame. */
445 /* Current frame information, calculated by compute_frame_size. */
446 struct mips_frame_info frame;
448 /* The register to use as the global pointer within this function. */
449 unsigned int global_pointer;
451 /* True if mips_adjust_insn_length should ignore an instruction's
453 bool ignore_hazard_length_p;
455 /* True if the whole function is suitable for .set noreorder and
457 bool all_noreorder_p;
459 /* True if the function is known to have an instruction that needs $gp. */
463 /* Information about a single argument. */
466 /* True if the argument is passed in a floating-point register, or
467 would have been if we hadn't run out of registers. */
470 /* The number of words passed in registers, rounded up. */
471 unsigned int reg_words;
473 /* For EABI, the offset of the first register from GP_ARG_FIRST or
474 FP_ARG_FIRST. For other ABIs, the offset of the first register from
475 the start of the ABI's argument structure (see the CUMULATIVE_ARGS
476 comment for details).
478 The value is MAX_ARGS_IN_REGISTERS if the argument is passed entirely
480 unsigned int reg_offset;
482 /* The number of words that must be passed on the stack, rounded up. */
483 unsigned int stack_words;
485 /* The offset from the start of the stack overflow area of the argument's
486 first stack word. Only meaningful when STACK_WORDS is nonzero. */
487 unsigned int stack_offset;
491 /* Information about an address described by mips_address_type.
497 REG is the base register and OFFSET is the constant offset.
500 REG is the register that contains the high part of the address,
501 OFFSET is the symbolic address being referenced and SYMBOL_TYPE
502 is the type of OFFSET's symbol.
505 SYMBOL_TYPE is the type of symbol being referenced. */
507 struct mips_address_info
509 enum mips_address_type type;
512 enum mips_symbol_type symbol_type;
516 /* One stage in a constant building sequence. These sequences have
520 A = A CODE[1] VALUE[1]
521 A = A CODE[2] VALUE[2]
524 where A is an accumulator, each CODE[i] is a binary rtl operation
525 and each VALUE[i] is a constant integer. */
526 struct mips_integer_op {
528 unsigned HOST_WIDE_INT value;
532 /* The largest number of operations needed to load an integer constant.
533 The worst accepted case for 64-bit constants is LUI,ORI,SLL,ORI,SLL,ORI.
534 When the lowest bit is clear, we can try, but reject a sequence with
535 an extra SLL at the end. */
536 #define MIPS_MAX_INTEGER_OPS 7
539 /* Global variables for machine-dependent things. */
541 /* Threshold for data being put into the small data/bss area, instead
542 of the normal data area. */
543 int mips_section_threshold = -1;
545 /* Count the number of .file directives, so that .loc is up to date. */
546 int num_source_filenames = 0;
548 /* Count the number of sdb related labels are generated (to find block
549 start and end boundaries). */
550 int sdb_label_count = 0;
552 /* Next label # for each statement for Silicon Graphics IRIS systems. */
555 /* Linked list of all externals that are to be emitted when optimizing
556 for the global pointer if they haven't been declared by the end of
557 the program with an appropriate .comm or initialization. */
559 struct extern_list GTY (())
561 struct extern_list *next; /* next external */
562 const char *name; /* name of the external */
563 int size; /* size in bytes */
566 static GTY (()) struct extern_list *extern_head = 0;
568 /* Name of the file containing the current function. */
569 const char *current_function_file = "";
571 /* Number of nested .set noreorder, noat, nomacro, and volatile requests. */
577 /* The next branch instruction is a branch likely, not branch normal. */
578 int mips_branch_likely;
580 /* The operands passed to the last cmpMM expander. */
583 /* The target cpu for code generation. */
584 enum processor_type mips_arch;
585 const struct mips_cpu_info *mips_arch_info;
587 /* The target cpu for optimization and scheduling. */
588 enum processor_type mips_tune;
589 const struct mips_cpu_info *mips_tune_info;
591 /* Which instruction set architecture to use. */
594 /* Which ABI to use. */
595 int mips_abi = MIPS_ABI_DEFAULT;
597 /* Cost information to use. */
598 const struct mips_rtx_cost_data *mips_cost;
600 /* Whether we are generating mips16 hard float code. In mips16 mode
601 we always set TARGET_SOFT_FLOAT; this variable is nonzero if
602 -msoft-float was not specified by the user, which means that we
603 should arrange to call mips32 hard floating point code. */
604 int mips16_hard_float;
606 /* The architecture selected by -mipsN. */
607 static const struct mips_cpu_info *mips_isa_info;
609 /* If TRUE, we split addresses into their high and low parts in the RTL. */
610 int mips_split_addresses;
612 /* Mode used for saving/restoring general purpose registers. */
613 static enum machine_mode gpr_mode;
615 /* Array giving truth value on whether or not a given hard register
616 can support a given mode. */
617 char mips_hard_regno_mode_ok[(int)MAX_MACHINE_MODE][FIRST_PSEUDO_REGISTER];
619 /* List of all MIPS punctuation characters used by print_operand. */
620 char mips_print_operand_punct[256];
622 /* Map GCC register number to debugger register number. */
623 int mips_dbx_regno[FIRST_PSEUDO_REGISTER];
625 /* A copy of the original flag_delayed_branch: see override_options. */
626 static int mips_flag_delayed_branch;
628 static GTY (()) int mips_output_filename_first_time = 1;
630 /* mips_split_p[X] is true if symbols of type X can be split by
631 mips_split_symbol(). */
632 bool mips_split_p[NUM_SYMBOL_TYPES];
634 /* mips_lo_relocs[X] is the relocation to use when a symbol of type X
635 appears in a LO_SUM. It can be null if such LO_SUMs aren't valid or
636 if they are matched by a special .md file pattern. */
637 static const char *mips_lo_relocs[NUM_SYMBOL_TYPES];
639 /* Likewise for HIGHs. */
640 static const char *mips_hi_relocs[NUM_SYMBOL_TYPES];
642 /* Map hard register number to register class */
643 const enum reg_class mips_regno_to_class[] =
645 LEA_REGS, LEA_REGS, M16_NA_REGS, V1_REG,
646 M16_REGS, M16_REGS, M16_REGS, M16_REGS,
647 LEA_REGS, LEA_REGS, LEA_REGS, LEA_REGS,
648 LEA_REGS, LEA_REGS, LEA_REGS, LEA_REGS,
649 M16_NA_REGS, M16_NA_REGS, LEA_REGS, LEA_REGS,
650 LEA_REGS, LEA_REGS, LEA_REGS, LEA_REGS,
651 T_REG, PIC_FN_ADDR_REG, LEA_REGS, LEA_REGS,
652 LEA_REGS, LEA_REGS, LEA_REGS, LEA_REGS,
653 FP_REGS, FP_REGS, FP_REGS, FP_REGS,
654 FP_REGS, FP_REGS, FP_REGS, FP_REGS,
655 FP_REGS, FP_REGS, FP_REGS, FP_REGS,
656 FP_REGS, FP_REGS, FP_REGS, FP_REGS,
657 FP_REGS, FP_REGS, FP_REGS, FP_REGS,
658 FP_REGS, FP_REGS, FP_REGS, FP_REGS,
659 FP_REGS, FP_REGS, FP_REGS, FP_REGS,
660 FP_REGS, FP_REGS, FP_REGS, FP_REGS,
661 HI_REG, LO_REG, NO_REGS, ST_REGS,
662 ST_REGS, ST_REGS, ST_REGS, ST_REGS,
663 ST_REGS, ST_REGS, ST_REGS, NO_REGS,
664 NO_REGS, ALL_REGS, ALL_REGS, NO_REGS,
665 COP0_REGS, COP0_REGS, COP0_REGS, COP0_REGS,
666 COP0_REGS, COP0_REGS, COP0_REGS, COP0_REGS,
667 COP0_REGS, COP0_REGS, COP0_REGS, COP0_REGS,
668 COP0_REGS, COP0_REGS, COP0_REGS, COP0_REGS,
669 COP0_REGS, COP0_REGS, COP0_REGS, COP0_REGS,
670 COP0_REGS, COP0_REGS, COP0_REGS, COP0_REGS,
671 COP0_REGS, COP0_REGS, COP0_REGS, COP0_REGS,
672 COP0_REGS, COP0_REGS, COP0_REGS, COP0_REGS,
673 COP2_REGS, COP2_REGS, COP2_REGS, COP2_REGS,
674 COP2_REGS, COP2_REGS, COP2_REGS, COP2_REGS,
675 COP2_REGS, COP2_REGS, COP2_REGS, COP2_REGS,
676 COP2_REGS, COP2_REGS, COP2_REGS, COP2_REGS,
677 COP2_REGS, COP2_REGS, COP2_REGS, COP2_REGS,
678 COP2_REGS, COP2_REGS, COP2_REGS, COP2_REGS,
679 COP2_REGS, COP2_REGS, COP2_REGS, COP2_REGS,
680 COP2_REGS, COP2_REGS, COP2_REGS, COP2_REGS,
681 COP3_REGS, COP3_REGS, COP3_REGS, COP3_REGS,
682 COP3_REGS, COP3_REGS, COP3_REGS, COP3_REGS,
683 COP3_REGS, COP3_REGS, COP3_REGS, COP3_REGS,
684 COP3_REGS, COP3_REGS, COP3_REGS, COP3_REGS,
685 COP3_REGS, COP3_REGS, COP3_REGS, COP3_REGS,
686 COP3_REGS, COP3_REGS, COP3_REGS, COP3_REGS,
687 COP3_REGS, COP3_REGS, COP3_REGS, COP3_REGS,
688 COP3_REGS, COP3_REGS, COP3_REGS, COP3_REGS,
689 DSP_ACC_REGS, DSP_ACC_REGS, DSP_ACC_REGS, DSP_ACC_REGS,
690 DSP_ACC_REGS, DSP_ACC_REGS, ALL_REGS, ALL_REGS,
691 ALL_REGS, ALL_REGS, ALL_REGS, ALL_REGS
694 /* Table of machine dependent attributes. */
695 const struct attribute_spec mips_attribute_table[] =
697 { "long_call", 0, 0, false, true, true, NULL },
698 { NULL, 0, 0, false, false, false, NULL }
701 /* A table describing all the processors gcc knows about. Names are
702 matched in the order listed. The first mention of an ISA level is
703 taken as the canonical name for that ISA.
705 To ease comparison, please keep this table in the same order as
706 gas's mips_cpu_info_table[]. */
707 const struct mips_cpu_info mips_cpu_info_table[] = {
708 /* Entries for generic ISAs */
709 { "mips1", PROCESSOR_R3000, 1 },
710 { "mips2", PROCESSOR_R6000, 2 },
711 { "mips3", PROCESSOR_R4000, 3 },
712 { "mips4", PROCESSOR_R8000, 4 },
713 { "mips32", PROCESSOR_4KC, 32 },
714 { "mips32r2", PROCESSOR_M4K, 33 },
715 { "mips64", PROCESSOR_5KC, 64 },
716 { "mips64r2", PROCESSOR_5KC, 65 },
719 { "r3000", PROCESSOR_R3000, 1 },
720 { "r2000", PROCESSOR_R3000, 1 }, /* = r3000 */
721 { "r3900", PROCESSOR_R3900, 1 },
724 { "r6000", PROCESSOR_R6000, 2 },
727 { "r4000", PROCESSOR_R4000, 3 },
728 { "vr4100", PROCESSOR_R4100, 3 },
729 { "vr4111", PROCESSOR_R4111, 3 },
730 { "vr4120", PROCESSOR_R4120, 3 },
731 { "vr4130", PROCESSOR_R4130, 3 },
732 { "vr4300", PROCESSOR_R4300, 3 },
733 { "r4400", PROCESSOR_R4000, 3 }, /* = r4000 */
734 { "r4600", PROCESSOR_R4600, 3 },
735 { "orion", PROCESSOR_R4600, 3 }, /* = r4600 */
736 { "r4650", PROCESSOR_R4650, 3 },
739 { "r8000", PROCESSOR_R8000, 4 },
740 { "vr5000", PROCESSOR_R5000, 4 },
741 { "vr5400", PROCESSOR_R5400, 4 },
742 { "vr5500", PROCESSOR_R5500, 4 },
743 { "rm7000", PROCESSOR_R7000, 4 },
744 { "rm9000", PROCESSOR_R9000, 4 },
747 { "4kc", PROCESSOR_4KC, 32 },
748 { "4km", PROCESSOR_4KC, 32 }, /* = 4kc */
749 { "4kp", PROCESSOR_4KP, 32 },
751 /* MIPS32 Release 2 */
752 { "m4k", PROCESSOR_M4K, 33 },
753 { "24k", PROCESSOR_24K, 33 },
754 { "24kc", PROCESSOR_24K, 33 }, /* 24K no FPU */
755 { "24kf", PROCESSOR_24K, 33 }, /* 24K 1:2 FPU */
756 { "24kx", PROCESSOR_24KX, 33 }, /* 24K 1:1 FPU */
759 { "5kc", PROCESSOR_5KC, 64 },
760 { "5kf", PROCESSOR_5KF, 64 },
761 { "20kc", PROCESSOR_20KC, 64 },
762 { "sb1", PROCESSOR_SB1, 64 },
763 { "sb1a", PROCESSOR_SB1A, 64 },
764 { "sr71000", PROCESSOR_SR71000, 64 },
767 { "octeon", PROCESSOR_OCTEON, 65 },
768 { "octeon+", PROCESSOR_OCTEON, 65 },
774 /* Default costs. If these are used for a processor we should look
775 up the actual costs. */
776 #define DEFAULT_COSTS COSTS_N_INSNS (6), /* fp_add */ \
777 COSTS_N_INSNS (7), /* fp_mult_sf */ \
778 COSTS_N_INSNS (8), /* fp_mult_df */ \
779 COSTS_N_INSNS (23), /* fp_div_sf */ \
780 COSTS_N_INSNS (36), /* fp_div_df */ \
781 COSTS_N_INSNS (10), /* int_mult_si */ \
782 COSTS_N_INSNS (10), /* int_mult_di */ \
783 COSTS_N_INSNS (69), /* int_div_si */ \
784 COSTS_N_INSNS (69), /* int_div_di */ \
785 2, /* branch_cost */ \
786 4 /* memory_latency */
788 /* Need to replace these with the costs of calling the appropriate
790 #define SOFT_FP_COSTS COSTS_N_INSNS (256), /* fp_add */ \
791 COSTS_N_INSNS (256), /* fp_mult_sf */ \
792 COSTS_N_INSNS (256), /* fp_mult_df */ \
793 COSTS_N_INSNS (256), /* fp_div_sf */ \
794 COSTS_N_INSNS (256) /* fp_div_df */
796 static struct mips_rtx_cost_data const mips_rtx_cost_data[PROCESSOR_MAX] =
799 COSTS_N_INSNS (2), /* fp_add */
800 COSTS_N_INSNS (4), /* fp_mult_sf */
801 COSTS_N_INSNS (5), /* fp_mult_df */
802 COSTS_N_INSNS (12), /* fp_div_sf */
803 COSTS_N_INSNS (19), /* fp_div_df */
804 COSTS_N_INSNS (12), /* int_mult_si */
805 COSTS_N_INSNS (12), /* int_mult_di */
806 COSTS_N_INSNS (35), /* int_div_si */
807 COSTS_N_INSNS (35), /* int_div_di */
809 4 /* memory_latency */
814 COSTS_N_INSNS (6), /* int_mult_si */
815 COSTS_N_INSNS (6), /* int_mult_di */
816 COSTS_N_INSNS (36), /* int_div_si */
817 COSTS_N_INSNS (36), /* int_div_di */
819 4 /* memory_latency */
823 COSTS_N_INSNS (36), /* int_mult_si */
824 COSTS_N_INSNS (36), /* int_mult_di */
825 COSTS_N_INSNS (37), /* int_div_si */
826 COSTS_N_INSNS (37), /* int_div_di */
828 4 /* memory_latency */
832 COSTS_N_INSNS (4), /* int_mult_si */
833 COSTS_N_INSNS (11), /* int_mult_di */
834 COSTS_N_INSNS (36), /* int_div_si */
835 COSTS_N_INSNS (68), /* int_div_di */
837 4 /* memory_latency */
840 COSTS_N_INSNS (4), /* fp_add */
841 COSTS_N_INSNS (4), /* fp_mult_sf */
842 COSTS_N_INSNS (5), /* fp_mult_df */
843 COSTS_N_INSNS (17), /* fp_div_sf */
844 COSTS_N_INSNS (32), /* fp_div_df */
845 COSTS_N_INSNS (4), /* int_mult_si */
846 COSTS_N_INSNS (11), /* int_mult_di */
847 COSTS_N_INSNS (36), /* int_div_si */
848 COSTS_N_INSNS (68), /* int_div_di */
850 4 /* memory_latency */
856 COSTS_N_INSNS (8), /* fp_add */
857 COSTS_N_INSNS (8), /* fp_mult_sf */
858 COSTS_N_INSNS (10), /* fp_mult_df */
859 COSTS_N_INSNS (34), /* fp_div_sf */
860 COSTS_N_INSNS (64), /* fp_div_df */
861 COSTS_N_INSNS (5), /* int_mult_si */
862 COSTS_N_INSNS (5), /* int_mult_di */
863 COSTS_N_INSNS (41), /* int_div_si */
864 COSTS_N_INSNS (41), /* int_div_di */
866 4 /* memory_latency */
869 COSTS_N_INSNS (4), /* fp_add */
870 COSTS_N_INSNS (4), /* fp_mult_sf */
871 COSTS_N_INSNS (5), /* fp_mult_df */
872 COSTS_N_INSNS (17), /* fp_div_sf */
873 COSTS_N_INSNS (32), /* fp_div_df */
874 COSTS_N_INSNS (5), /* int_mult_si */
875 COSTS_N_INSNS (5), /* int_mult_di */
876 COSTS_N_INSNS (41), /* int_div_si */
877 COSTS_N_INSNS (41), /* int_div_di */
879 4 /* memory_latency */
885 COSTS_N_INSNS (2), /* fp_add */
886 COSTS_N_INSNS (4), /* fp_mult_sf */
887 COSTS_N_INSNS (5), /* fp_mult_df */
888 COSTS_N_INSNS (12), /* fp_div_sf */
889 COSTS_N_INSNS (19), /* fp_div_df */
890 COSTS_N_INSNS (2), /* int_mult_si */
891 COSTS_N_INSNS (2), /* int_mult_di */
892 COSTS_N_INSNS (35), /* int_div_si */
893 COSTS_N_INSNS (35), /* int_div_di */
895 4 /* memory_latency */
898 COSTS_N_INSNS (3), /* fp_add */
899 COSTS_N_INSNS (5), /* fp_mult_sf */
900 COSTS_N_INSNS (6), /* fp_mult_df */
901 COSTS_N_INSNS (15), /* fp_div_sf */
902 COSTS_N_INSNS (16), /* fp_div_df */
903 COSTS_N_INSNS (17), /* int_mult_si */
904 COSTS_N_INSNS (17), /* int_mult_di */
905 COSTS_N_INSNS (38), /* int_div_si */
906 COSTS_N_INSNS (38), /* int_div_di */
908 6 /* memory_latency */
911 COSTS_N_INSNS (6), /* fp_add */
912 COSTS_N_INSNS (7), /* fp_mult_sf */
913 COSTS_N_INSNS (8), /* fp_mult_df */
914 COSTS_N_INSNS (23), /* fp_div_sf */
915 COSTS_N_INSNS (36), /* fp_div_df */
916 COSTS_N_INSNS (10), /* int_mult_si */
917 COSTS_N_INSNS (10), /* int_mult_di */
918 COSTS_N_INSNS (69), /* int_div_si */
919 COSTS_N_INSNS (69), /* int_div_di */
921 6 /* memory_latency */
933 /* The only costs that appear to be updated here are
934 integer multiplication. */
936 COSTS_N_INSNS (4), /* int_mult_si */
937 COSTS_N_INSNS (6), /* int_mult_di */
938 COSTS_N_INSNS (69), /* int_div_si */
939 COSTS_N_INSNS (69), /* int_div_di */
941 4 /* memory_latency */
953 COSTS_N_INSNS (6), /* fp_add */
954 COSTS_N_INSNS (4), /* fp_mult_sf */
955 COSTS_N_INSNS (5), /* fp_mult_df */
956 COSTS_N_INSNS (23), /* fp_div_sf */
957 COSTS_N_INSNS (36), /* fp_div_df */
958 COSTS_N_INSNS (5), /* int_mult_si */
959 COSTS_N_INSNS (5), /* int_mult_di */
960 COSTS_N_INSNS (36), /* int_div_si */
961 COSTS_N_INSNS (36), /* int_div_di */
963 4 /* memory_latency */
966 COSTS_N_INSNS (6), /* fp_add */
967 COSTS_N_INSNS (5), /* fp_mult_sf */
968 COSTS_N_INSNS (6), /* fp_mult_df */
969 COSTS_N_INSNS (30), /* fp_div_sf */
970 COSTS_N_INSNS (59), /* fp_div_df */
971 COSTS_N_INSNS (3), /* int_mult_si */
972 COSTS_N_INSNS (4), /* int_mult_di */
973 COSTS_N_INSNS (42), /* int_div_si */
974 COSTS_N_INSNS (74), /* int_div_di */
976 4 /* memory_latency */
979 COSTS_N_INSNS (6), /* fp_add */
980 COSTS_N_INSNS (5), /* fp_mult_sf */
981 COSTS_N_INSNS (6), /* fp_mult_df */
982 COSTS_N_INSNS (30), /* fp_div_sf */
983 COSTS_N_INSNS (59), /* fp_div_df */
984 COSTS_N_INSNS (5), /* int_mult_si */
985 COSTS_N_INSNS (9), /* int_mult_di */
986 COSTS_N_INSNS (42), /* int_div_si */
987 COSTS_N_INSNS (74), /* int_div_di */
989 4 /* memory_latency */
992 /* The only costs that are changed here are
993 integer multiplication. */
994 COSTS_N_INSNS (6), /* fp_add */
995 COSTS_N_INSNS (7), /* fp_mult_sf */
996 COSTS_N_INSNS (8), /* fp_mult_df */
997 COSTS_N_INSNS (23), /* fp_div_sf */
998 COSTS_N_INSNS (36), /* fp_div_df */
999 COSTS_N_INSNS (5), /* int_mult_si */
1000 COSTS_N_INSNS (9), /* int_mult_di */
1001 COSTS_N_INSNS (69), /* int_div_si */
1002 COSTS_N_INSNS (69), /* int_div_di */
1003 1, /* branch_cost */
1004 4 /* memory_latency */
1010 /* The only costs that are changed here are
1011 integer multiplication. */
1012 COSTS_N_INSNS (6), /* fp_add */
1013 COSTS_N_INSNS (7), /* fp_mult_sf */
1014 COSTS_N_INSNS (8), /* fp_mult_df */
1015 COSTS_N_INSNS (23), /* fp_div_sf */
1016 COSTS_N_INSNS (36), /* fp_div_df */
1017 COSTS_N_INSNS (3), /* int_mult_si */
1018 COSTS_N_INSNS (8), /* int_mult_di */
1019 COSTS_N_INSNS (69), /* int_div_si */
1020 COSTS_N_INSNS (69), /* int_div_di */
1021 1, /* branch_cost */
1022 4 /* memory_latency */
1025 /* These costs are the same as the SB-1A below. */
1026 COSTS_N_INSNS (4), /* fp_add */
1027 COSTS_N_INSNS (4), /* fp_mult_sf */
1028 COSTS_N_INSNS (4), /* fp_mult_df */
1029 COSTS_N_INSNS (24), /* fp_div_sf */
1030 COSTS_N_INSNS (32), /* fp_div_df */
1031 COSTS_N_INSNS (3), /* int_mult_si */
1032 COSTS_N_INSNS (4), /* int_mult_di */
1033 COSTS_N_INSNS (36), /* int_div_si */
1034 COSTS_N_INSNS (68), /* int_div_di */
1035 1, /* branch_cost */
1036 4 /* memory_latency */
1039 /* These costs are the same as the SB-1 above. */
1040 COSTS_N_INSNS (4), /* fp_add */
1041 COSTS_N_INSNS (4), /* fp_mult_sf */
1042 COSTS_N_INSNS (4), /* fp_mult_df */
1043 COSTS_N_INSNS (24), /* fp_div_sf */
1044 COSTS_N_INSNS (32), /* fp_div_df */
1045 COSTS_N_INSNS (3), /* int_mult_si */
1046 COSTS_N_INSNS (4), /* int_mult_di */
1047 COSTS_N_INSNS (36), /* int_div_si */
1048 COSTS_N_INSNS (68), /* int_div_di */
1049 1, /* branch_cost */
1050 4 /* memory_latency */
1058 /* Nonzero if -march should decide the default value of MASK_SOFT_FLOAT. */
1059 #ifndef MIPS_MARCH_CONTROLS_SOFT_FLOAT
1060 #define MIPS_MARCH_CONTROLS_SOFT_FLOAT 0
1063 /* Initialize the GCC target structure. */
1064 #undef TARGET_ASM_ALIGNED_HI_OP
1065 #define TARGET_ASM_ALIGNED_HI_OP "\t.half\t"
1066 #undef TARGET_ASM_ALIGNED_SI_OP
1067 #define TARGET_ASM_ALIGNED_SI_OP "\t.word\t"
1068 #undef TARGET_ASM_ALIGNED_DI_OP
1069 #define TARGET_ASM_ALIGNED_DI_OP "\t.dword\t"
1071 #undef TARGET_ASM_FUNCTION_PROLOGUE
1072 #define TARGET_ASM_FUNCTION_PROLOGUE mips_output_function_prologue
1073 #undef TARGET_ASM_FUNCTION_EPILOGUE
1074 #define TARGET_ASM_FUNCTION_EPILOGUE mips_output_function_epilogue
1075 #undef TARGET_ASM_SELECT_RTX_SECTION
1076 #define TARGET_ASM_SELECT_RTX_SECTION mips_select_rtx_section
1077 #undef TARGET_ASM_FUNCTION_RODATA_SECTION
1078 #define TARGET_ASM_FUNCTION_RODATA_SECTION mips_function_rodata_section
1080 #undef TARGET_SCHED_REORDER
1081 #define TARGET_SCHED_REORDER mips_sched_reorder
1082 #undef TARGET_SCHED_VARIABLE_ISSUE
1083 #define TARGET_SCHED_VARIABLE_ISSUE mips_variable_issue
1084 #undef TARGET_SCHED_ADJUST_COST
1085 #define TARGET_SCHED_ADJUST_COST mips_adjust_cost
1086 #undef TARGET_SCHED_ISSUE_RATE
1087 #define TARGET_SCHED_ISSUE_RATE mips_issue_rate
1088 #undef TARGET_SCHED_FIRST_CYCLE_MULTIPASS_DFA_LOOKAHEAD
1089 #define TARGET_SCHED_FIRST_CYCLE_MULTIPASS_DFA_LOOKAHEAD \
1090 mips_multipass_dfa_lookahead
1092 #undef TARGET_DEFAULT_TARGET_FLAGS
1093 #define TARGET_DEFAULT_TARGET_FLAGS \
1095 | TARGET_CPU_DEFAULT \
1096 | TARGET_ENDIAN_DEFAULT \
1097 | TARGET_FP_EXCEPTIONS_DEFAULT \
1098 | MASK_CHECK_ZERO_DIV \
1100 #undef TARGET_HANDLE_OPTION
1101 #define TARGET_HANDLE_OPTION mips_handle_option
1103 #undef TARGET_FUNCTION_OK_FOR_SIBCALL
1104 #define TARGET_FUNCTION_OK_FOR_SIBCALL mips_function_ok_for_sibcall
1106 #undef TARGET_VALID_POINTER_MODE
1107 #define TARGET_VALID_POINTER_MODE mips_valid_pointer_mode
1108 #undef TARGET_RTX_COSTS
1109 #define TARGET_RTX_COSTS mips_rtx_costs
1110 #undef TARGET_ADDRESS_COST
1111 #define TARGET_ADDRESS_COST mips_address_cost
1113 #undef TARGET_IN_SMALL_DATA_P
1114 #define TARGET_IN_SMALL_DATA_P mips_in_small_data_p
1116 #undef TARGET_MACHINE_DEPENDENT_REORG
1117 #define TARGET_MACHINE_DEPENDENT_REORG mips_reorg
1119 #undef TARGET_ASM_FILE_START
1120 #undef TARGET_ASM_FILE_END
1121 #define TARGET_ASM_FILE_START mips_file_start
1122 #define TARGET_ASM_FILE_END mips_file_end
1123 #undef TARGET_ASM_FILE_START_FILE_DIRECTIVE
1124 #define TARGET_ASM_FILE_START_FILE_DIRECTIVE true
1126 #undef TARGET_INIT_LIBFUNCS
1127 #define TARGET_INIT_LIBFUNCS mips_init_libfuncs
1129 #undef TARGET_BUILD_BUILTIN_VA_LIST
1130 #define TARGET_BUILD_BUILTIN_VA_LIST mips_build_builtin_va_list
1131 #undef TARGET_GIMPLIFY_VA_ARG_EXPR
1132 #define TARGET_GIMPLIFY_VA_ARG_EXPR mips_gimplify_va_arg_expr
1134 #undef TARGET_PROMOTE_FUNCTION_ARGS
1135 #define TARGET_PROMOTE_FUNCTION_ARGS hook_bool_tree_true
1136 #undef TARGET_PROMOTE_FUNCTION_RETURN
1137 #define TARGET_PROMOTE_FUNCTION_RETURN hook_bool_tree_true
1138 #undef TARGET_PROMOTE_PROTOTYPES
1139 #define TARGET_PROMOTE_PROTOTYPES hook_bool_tree_true
1141 #undef TARGET_RETURN_IN_MEMORY
1142 #define TARGET_RETURN_IN_MEMORY mips_return_in_memory
1143 #undef TARGET_RETURN_IN_MSB
1144 #define TARGET_RETURN_IN_MSB mips_return_in_msb
1146 #undef TARGET_ASM_OUTPUT_MI_THUNK
1147 #define TARGET_ASM_OUTPUT_MI_THUNK mips_output_mi_thunk
1148 #undef TARGET_ASM_CAN_OUTPUT_MI_THUNK
1149 #define TARGET_ASM_CAN_OUTPUT_MI_THUNK hook_bool_tree_hwi_hwi_tree_true
1151 #undef TARGET_SETUP_INCOMING_VARARGS
1152 #define TARGET_SETUP_INCOMING_VARARGS mips_setup_incoming_varargs
1153 #undef TARGET_STRICT_ARGUMENT_NAMING
1154 #define TARGET_STRICT_ARGUMENT_NAMING mips_strict_argument_naming
1155 #undef TARGET_MUST_PASS_IN_STACK
1156 #define TARGET_MUST_PASS_IN_STACK must_pass_in_stack_var_size
1157 #undef TARGET_PASS_BY_REFERENCE
1158 #define TARGET_PASS_BY_REFERENCE mips_pass_by_reference
1159 #undef TARGET_CALLEE_COPIES
1160 #define TARGET_CALLEE_COPIES mips_callee_copies
1161 #undef TARGET_ARG_PARTIAL_BYTES
1162 #define TARGET_ARG_PARTIAL_BYTES mips_arg_partial_bytes
1164 #undef TARGET_MODE_REP_EXTENDED
1165 #define TARGET_MODE_REP_EXTENDED mips_mode_rep_extended
1167 #undef TARGET_VECTOR_MODE_SUPPORTED_P
1168 #define TARGET_VECTOR_MODE_SUPPORTED_P mips_vector_mode_supported_p
1170 #undef TARGET_INIT_BUILTINS
1171 #define TARGET_INIT_BUILTINS mips_init_builtins
1172 #undef TARGET_EXPAND_BUILTIN
1173 #define TARGET_EXPAND_BUILTIN mips_expand_builtin
1175 #undef TARGET_HAVE_TLS
1176 #define TARGET_HAVE_TLS HAVE_AS_TLS
1178 #undef TARGET_CANNOT_FORCE_CONST_MEM
1179 #define TARGET_CANNOT_FORCE_CONST_MEM mips_cannot_force_const_mem
1181 #undef TARGET_ENCODE_SECTION_INFO
1182 #define TARGET_ENCODE_SECTION_INFO mips_encode_section_info
1184 #undef TARGET_ATTRIBUTE_TABLE
1185 #define TARGET_ATTRIBUTE_TABLE mips_attribute_table
1187 #undef TARGET_EXTRA_LIVE_ON_ENTRY
1188 #define TARGET_EXTRA_LIVE_ON_ENTRY mips_extra_live_on_entry
1190 #undef TARGET_MIN_ANCHOR_OFFSET
1191 #define TARGET_MIN_ANCHOR_OFFSET -32768
1192 #undef TARGET_MAX_ANCHOR_OFFSET
1193 #define TARGET_MAX_ANCHOR_OFFSET 32767
1194 #undef TARGET_USE_BLOCKS_FOR_CONSTANT_P
1195 #define TARGET_USE_BLOCKS_FOR_CONSTANT_P mips_use_blocks_for_constant_p
1196 #undef TARGET_USE_ANCHORS_FOR_SYMBOL_P
1197 #define TARGET_USE_ANCHORS_FOR_SYMBOL_P mips_use_anchors_for_symbol_p
1199 struct gcc_target targetm = TARGET_INITIALIZER;
1201 /* Classify symbol X, which must be a SYMBOL_REF or a LABEL_REF. */
1203 static enum mips_symbol_type
1204 mips_classify_symbol (rtx x)
1206 if (GET_CODE (x) == LABEL_REF)
1209 return SYMBOL_CONSTANT_POOL;
1210 if (TARGET_ABICALLS && !TARGET_ABSOLUTE_ABICALLS)
1211 return SYMBOL_GOT_LOCAL;
1212 return SYMBOL_GENERAL;
1215 gcc_assert (GET_CODE (x) == SYMBOL_REF);
1217 if (SYMBOL_REF_TLS_MODEL (x))
1220 if (CONSTANT_POOL_ADDRESS_P (x))
1223 return SYMBOL_CONSTANT_POOL;
1225 if (GET_MODE_SIZE (get_pool_mode (x)) <= mips_section_threshold)
1226 return SYMBOL_SMALL_DATA;
1229 /* Do not use small-data accesses for weak symbols; they may end up
1231 if (SYMBOL_REF_SMALL_P (x)
1232 && !SYMBOL_REF_WEAK (x))
1233 return SYMBOL_SMALL_DATA;
1235 if (TARGET_ABICALLS)
1237 if (SYMBOL_REF_DECL (x) == 0)
1239 if (!SYMBOL_REF_LOCAL_P (x))
1240 return SYMBOL_GOT_GLOBAL;
1244 /* Don't use GOT accesses for locally-binding symbols if
1245 TARGET_ABSOLUTE_ABICALLS. Otherwise, there are three
1248 - o32 PIC (either with or without explicit relocs)
1249 - n32/n64 PIC without explicit relocs
1250 - n32/n64 PIC with explicit relocs
1252 In the first case, both local and global accesses will use an
1253 R_MIPS_GOT16 relocation. We must correctly predict which of
1254 the two semantics (local or global) the assembler and linker
1255 will apply. The choice doesn't depend on the symbol's
1256 visibility, so we deliberately ignore decl_visibility and
1259 In the second case, the assembler will not use R_MIPS_GOT16
1260 relocations, but it chooses between local and global accesses
1261 in the same way as for o32 PIC.
1263 In the third case we have more freedom since both forms of
1264 access will work for any kind of symbol. However, there seems
1265 little point in doing things differently. */
1266 if (DECL_P (SYMBOL_REF_DECL (x))
1267 && TREE_PUBLIC (SYMBOL_REF_DECL (x))
1268 && !(TARGET_ABSOLUTE_ABICALLS
1269 && targetm.binds_local_p (SYMBOL_REF_DECL (x))))
1270 return SYMBOL_GOT_GLOBAL;
1273 if (!TARGET_ABSOLUTE_ABICALLS)
1274 return SYMBOL_GOT_LOCAL;
1277 return SYMBOL_GENERAL;
1281 /* Split X into a base and a constant offset, storing them in *BASE
1282 and *OFFSET respectively. */
1285 mips_split_const (rtx x, rtx *base, HOST_WIDE_INT *offset)
1289 if (GET_CODE (x) == CONST)
1292 if (GET_CODE (x) == PLUS && GET_CODE (XEXP (x, 1)) == CONST_INT)
1294 *offset += INTVAL (XEXP (x, 1));
1301 /* Classify symbolic expression X, given that it appears in context
1304 static enum mips_symbol_type
1305 mips_classify_symbolic_expression (rtx x)
1307 HOST_WIDE_INT offset;
1309 mips_split_const (x, &x, &offset);
1310 if (UNSPEC_ADDRESS_P (x))
1311 return UNSPEC_ADDRESS_TYPE (x);
1313 return mips_classify_symbol (x);
1316 /* Return true if SYMBOL is a SYMBOL_REF and OFFSET + SYMBOL points
1317 to the same object as SYMBOL, or to the same object_block. */
1320 mips_offset_within_object_p (rtx symbol, HOST_WIDE_INT offset)
1322 if (GET_CODE (symbol) != SYMBOL_REF)
1325 if (CONSTANT_POOL_ADDRESS_P (symbol)
1327 && offset < (int) GET_MODE_SIZE (get_pool_mode (symbol)))
1330 if (SYMBOL_REF_DECL (symbol) != 0
1332 && offset < int_size_in_bytes (TREE_TYPE (SYMBOL_REF_DECL (symbol))))
1335 if (SYMBOL_REF_HAS_BLOCK_INFO_P (symbol)
1336 && SYMBOL_REF_BLOCK (symbol)
1337 && SYMBOL_REF_BLOCK_OFFSET (symbol) >= 0
1338 && ((unsigned HOST_WIDE_INT) offset + SYMBOL_REF_BLOCK_OFFSET (symbol)
1339 < (unsigned HOST_WIDE_INT) SYMBOL_REF_BLOCK (symbol)->size))
1346 /* Return true if X is a symbolic constant that can be calculated in
1347 the same way as a bare symbol. If it is, store the type of the
1348 symbol in *SYMBOL_TYPE. */
1351 mips_symbolic_constant_p (rtx x, enum mips_symbol_type *symbol_type)
1353 HOST_WIDE_INT offset;
1355 mips_split_const (x, &x, &offset);
1356 if (UNSPEC_ADDRESS_P (x))
1357 *symbol_type = UNSPEC_ADDRESS_TYPE (x);
1358 else if (GET_CODE (x) == SYMBOL_REF || GET_CODE (x) == LABEL_REF)
1360 *symbol_type = mips_classify_symbol (x);
1361 if (*symbol_type == SYMBOL_TLS)
1370 /* Check whether a nonzero offset is valid for the underlying
1372 switch (*symbol_type)
1374 case SYMBOL_GENERAL:
1375 case SYMBOL_64_HIGH:
1378 /* If the target has 64-bit pointers and the object file only
1379 supports 32-bit symbols, the values of those symbols will be
1380 sign-extended. In this case we can't allow an arbitrary offset
1381 in case the 32-bit value X + OFFSET has a different sign from X. */
1382 if (Pmode == DImode && !ABI_HAS_64BIT_SYMBOLS)
1383 return mips_offset_within_object_p (x, offset);
1385 /* In other cases the relocations can handle any offset. */
1388 case SYMBOL_CONSTANT_POOL:
1389 /* Allow constant pool references to be converted to LABEL+CONSTANT.
1390 In this case, we no longer have access to the underlying constant,
1391 but the original symbol-based access was known to be valid. */
1392 if (GET_CODE (x) == LABEL_REF)
1397 case SYMBOL_SMALL_DATA:
1398 /* Make sure that the offset refers to something within the
1399 underlying object. This should guarantee that the final
1400 PC- or GP-relative offset is within the 16-bit limit. */
1401 return mips_offset_within_object_p (x, offset);
1403 case SYMBOL_GOT_LOCAL:
1404 case SYMBOL_GOTOFF_PAGE:
1405 /* The linker should provide enough local GOT entries for a
1406 16-bit offset. Larger offsets may lead to GOT overflow. */
1407 return SMALL_OPERAND (offset);
1409 case SYMBOL_GOT_GLOBAL:
1410 case SYMBOL_GOTOFF_GLOBAL:
1411 case SYMBOL_GOTOFF_CALL:
1412 case SYMBOL_GOTOFF_LOADGP:
1417 case SYMBOL_GOTTPREL:
1425 /* This function is used to implement REG_MODE_OK_FOR_BASE_P. */
1428 mips_regno_mode_ok_for_base_p (int regno, enum machine_mode mode, int strict)
1430 if (regno >= FIRST_PSEUDO_REGISTER)
1434 regno = reg_renumber[regno];
1437 /* These fake registers will be eliminated to either the stack or
1438 hard frame pointer, both of which are usually valid base registers.
1439 Reload deals with the cases where the eliminated form isn't valid. */
1440 if (regno == ARG_POINTER_REGNUM || regno == FRAME_POINTER_REGNUM)
1443 /* In mips16 mode, the stack pointer can only address word and doubleword
1444 values, nothing smaller. There are two problems here:
1446 (a) Instantiating virtual registers can introduce new uses of the
1447 stack pointer. If these virtual registers are valid addresses,
1448 the stack pointer should be too.
1450 (b) Most uses of the stack pointer are not made explicit until
1451 FRAME_POINTER_REGNUM and ARG_POINTER_REGNUM have been eliminated.
1452 We don't know until that stage whether we'll be eliminating to the
1453 stack pointer (which needs the restriction) or the hard frame
1454 pointer (which doesn't).
1456 All in all, it seems more consistent to only enforce this restriction
1457 during and after reload. */
1458 if (TARGET_MIPS16 && regno == STACK_POINTER_REGNUM)
1459 return !strict || GET_MODE_SIZE (mode) == 4 || GET_MODE_SIZE (mode) == 8;
1461 return TARGET_MIPS16 ? M16_REG_P (regno) : GP_REG_P (regno);
1465 /* Return true if X is a valid base register for the given mode.
1466 Allow only hard registers if STRICT. */
1469 mips_valid_base_register_p (rtx x, enum machine_mode mode, int strict)
1471 if (!strict && GET_CODE (x) == SUBREG)
1475 && mips_regno_mode_ok_for_base_p (REGNO (x), mode, strict));
1479 /* Return true if symbols of type SYMBOL_TYPE can directly address a value
1480 with mode MODE. This is used for both symbolic and LO_SUM addresses. */
1483 mips_symbolic_address_p (enum mips_symbol_type symbol_type,
1484 enum machine_mode mode)
1486 switch (symbol_type)
1488 case SYMBOL_GENERAL:
1489 return !TARGET_MIPS16;
1491 case SYMBOL_SMALL_DATA:
1494 case SYMBOL_CONSTANT_POOL:
1495 /* PC-relative addressing is only available for lw and ld. */
1496 return GET_MODE_SIZE (mode) == 4 || GET_MODE_SIZE (mode) == 8;
1498 case SYMBOL_GOT_LOCAL:
1501 case SYMBOL_GOT_GLOBAL:
1502 /* The address will have to be loaded from the GOT first. */
1505 case SYMBOL_GOTOFF_PAGE:
1506 case SYMBOL_GOTOFF_GLOBAL:
1507 case SYMBOL_GOTOFF_CALL:
1508 case SYMBOL_GOTOFF_LOADGP:
1513 case SYMBOL_GOTTPREL:
1515 case SYMBOL_64_HIGH:
1524 /* Return true if X is a valid address for machine mode MODE. If it is,
1525 fill in INFO appropriately. STRICT is true if we should only accept
1526 hard base registers. */
1529 mips_classify_address (struct mips_address_info *info, rtx x,
1530 enum machine_mode mode, int strict)
1532 switch (GET_CODE (x))
1536 info->type = ADDRESS_REG;
1538 info->offset = const0_rtx;
1539 return mips_valid_base_register_p (info->reg, mode, strict);
1542 info->type = ADDRESS_REG;
1543 info->reg = XEXP (x, 0);
1544 info->offset = XEXP (x, 1);
1545 return (mips_valid_base_register_p (info->reg, mode, strict)
1546 && const_arith_operand (info->offset, VOIDmode));
1549 info->type = ADDRESS_LO_SUM;
1550 info->reg = XEXP (x, 0);
1551 info->offset = XEXP (x, 1);
1552 /* We have to trust the creator of the LO_SUM to do something vaguely
1553 sane. Target-independent code that creates a LO_SUM should also
1554 create and verify the matching HIGH. Target-independent code that
1555 adds an offset to a LO_SUM must prove that the offset will not
1556 induce a carry. Failure to do either of these things would be
1557 a bug, and we are not required to check for it here. The MIPS
1558 backend itself should only create LO_SUMs for valid symbolic
1559 constants, with the high part being either a HIGH or a copy
1561 info->symbol_type = mips_classify_symbolic_expression (info->offset);
1562 return (mips_valid_base_register_p (info->reg, mode, strict)
1563 && mips_symbolic_address_p (info->symbol_type, mode)
1564 && mips_lo_relocs[info->symbol_type] != 0);
1567 /* Small-integer addresses don't occur very often, but they
1568 are legitimate if $0 is a valid base register. */
1569 info->type = ADDRESS_CONST_INT;
1570 return !TARGET_MIPS16 && SMALL_INT (x);
1575 info->type = ADDRESS_SYMBOLIC;
1576 return (mips_symbolic_constant_p (x, &info->symbol_type)
1577 && mips_symbolic_address_p (info->symbol_type, mode)
1578 && !mips_split_p[info->symbol_type]);
1585 /* Return true if X is a thread-local symbol. */
1588 mips_tls_operand_p (rtx x)
1590 return GET_CODE (x) == SYMBOL_REF && SYMBOL_REF_TLS_MODEL (x) != 0;
1593 /* Return true if X can not be forced into a constant pool. */
1596 mips_tls_symbol_ref_1 (rtx *x, void *data ATTRIBUTE_UNUSED)
1598 return mips_tls_operand_p (*x);
1601 /* Return true if X can not be forced into a constant pool. */
1604 mips_cannot_force_const_mem (rtx x)
1607 HOST_WIDE_INT offset;
1611 /* As an optimization, reject constants that mips_legitimize_move
1614 Suppose we have a multi-instruction sequence that loads constant C
1615 into register R. If R does not get allocated a hard register, and
1616 R is used in an operand that allows both registers and memory
1617 references, reload will consider forcing C into memory and using
1618 one of the instruction's memory alternatives. Returning false
1619 here will force it to use an input reload instead. */
1620 if (GET_CODE (x) == CONST_INT)
1623 mips_split_const (x, &base, &offset);
1624 if (symbolic_operand (base, VOIDmode) && SMALL_OPERAND (offset))
1628 if (TARGET_HAVE_TLS && for_each_rtx (&x, &mips_tls_symbol_ref_1, 0))
1634 /* Implement TARGET_USE_BLOCKS_FOR_CONSTANT_P. MIPS16 uses per-function
1635 constant pools, but normal-mode code doesn't need to. */
1638 mips_use_blocks_for_constant_p (enum machine_mode mode ATTRIBUTE_UNUSED,
1639 rtx x ATTRIBUTE_UNUSED)
1641 return !TARGET_MIPS16;
1644 /* Return the number of instructions needed to load a symbol of the
1645 given type into a register. If valid in an address, the same number
1646 of instructions are needed for loads and stores. Treat extended
1647 mips16 instructions as two instructions. */
1650 mips_symbol_insns (enum mips_symbol_type type)
1654 case SYMBOL_GENERAL:
1655 /* In mips16 code, general symbols must be fetched from the
1660 /* When using 64-bit symbols, we need 5 preparatory instructions,
1663 lui $at,%highest(symbol)
1664 daddiu $at,$at,%higher(symbol)
1666 daddiu $at,$at,%hi(symbol)
1669 The final address is then $at + %lo(symbol). With 32-bit
1670 symbols we just need a preparatory lui. */
1671 return (ABI_HAS_64BIT_SYMBOLS ? 6 : 2);
1673 case SYMBOL_SMALL_DATA:
1676 case SYMBOL_CONSTANT_POOL:
1677 /* This case is for mips16 only. Assume we'll need an
1678 extended instruction. */
1681 case SYMBOL_GOT_LOCAL:
1682 case SYMBOL_GOT_GLOBAL:
1683 /* Unless -funit-at-a-time is in effect, we can't be sure whether
1684 the local/global classification is accurate. See override_options
1687 The worst cases are:
1689 (1) For local symbols when generating o32 or o64 code. The assembler
1695 ...and the final address will be $at + %lo(symbol).
1697 (2) For global symbols when -mxgot. The assembler will use:
1699 lui $at,%got_hi(symbol)
1702 ...and the final address will be $at + %got_lo(symbol). */
1705 case SYMBOL_GOTOFF_PAGE:
1706 case SYMBOL_GOTOFF_GLOBAL:
1707 case SYMBOL_GOTOFF_CALL:
1708 case SYMBOL_GOTOFF_LOADGP:
1709 case SYMBOL_64_HIGH:
1715 case SYMBOL_GOTTPREL:
1717 /* Check whether the offset is a 16- or 32-bit value. */
1718 return mips_split_p[type] ? 2 : 1;
1721 /* We don't treat a bare TLS symbol as a constant. */
1727 /* Return true if X is a legitimate $sp-based address for mode MDOE. */
1730 mips_stack_address_p (rtx x, enum machine_mode mode)
1732 struct mips_address_info addr;
1734 return (mips_classify_address (&addr, x, mode, false)
1735 && addr.type == ADDRESS_REG
1736 && addr.reg == stack_pointer_rtx);
1739 /* Return true if a value at OFFSET bytes from BASE can be accessed
1740 using an unextended mips16 instruction. MODE is the mode of the
1743 Usually the offset in an unextended instruction is a 5-bit field.
1744 The offset is unsigned and shifted left once for HIs, twice
1745 for SIs, and so on. An exception is SImode accesses off the
1746 stack pointer, which have an 8-bit immediate field. */
1749 mips16_unextended_reference_p (enum machine_mode mode, rtx base, rtx offset)
1752 && GET_CODE (offset) == CONST_INT
1753 && INTVAL (offset) >= 0
1754 && (INTVAL (offset) & (GET_MODE_SIZE (mode) - 1)) == 0)
1756 if (GET_MODE_SIZE (mode) == 4 && base == stack_pointer_rtx)
1757 return INTVAL (offset) < 256 * GET_MODE_SIZE (mode);
1758 return INTVAL (offset) < 32 * GET_MODE_SIZE (mode);
1764 /* Return the number of instructions needed to load or store a value
1765 of mode MODE at X. Return 0 if X isn't valid for MODE.
1767 For mips16 code, count extended instructions as two instructions. */
1770 mips_address_insns (rtx x, enum machine_mode mode)
1772 struct mips_address_info addr;
1775 if (mode == BLKmode)
1776 /* BLKmode is used for single unaligned loads and stores. */
1779 /* Each word of a multi-word value will be accessed individually. */
1780 factor = (GET_MODE_SIZE (mode) + UNITS_PER_WORD - 1) / UNITS_PER_WORD;
1782 if (mips_classify_address (&addr, x, mode, false))
1787 && !mips16_unextended_reference_p (mode, addr.reg, addr.offset))
1791 case ADDRESS_LO_SUM:
1792 return (TARGET_MIPS16 ? factor * 2 : factor);
1794 case ADDRESS_CONST_INT:
1797 case ADDRESS_SYMBOLIC:
1798 return factor * mips_symbol_insns (addr.symbol_type);
1804 /* Likewise for constant X. */
1807 mips_const_insns (rtx x)
1809 struct mips_integer_op codes[MIPS_MAX_INTEGER_OPS];
1810 enum mips_symbol_type symbol_type;
1811 HOST_WIDE_INT offset;
1813 switch (GET_CODE (x))
1817 || !mips_symbolic_constant_p (XEXP (x, 0), &symbol_type)
1818 || !mips_split_p[symbol_type])
1825 /* Unsigned 8-bit constants can be loaded using an unextended
1826 LI instruction. Unsigned 16-bit constants can be loaded
1827 using an extended LI. Negative constants must be loaded
1828 using LI and then negated. */
1829 return (INTVAL (x) >= 0 && INTVAL (x) < 256 ? 1
1830 : SMALL_OPERAND_UNSIGNED (INTVAL (x)) ? 2
1831 : INTVAL (x) > -256 && INTVAL (x) < 0 ? 2
1832 : SMALL_OPERAND_UNSIGNED (-INTVAL (x)) ? 3
1835 return mips_build_integer (codes, INTVAL (x));
1839 return (!TARGET_MIPS16 && x == CONST0_RTX (GET_MODE (x)) ? 1 : 0);
1845 /* See if we can refer to X directly. */
1846 if (mips_symbolic_constant_p (x, &symbol_type))
1847 return mips_symbol_insns (symbol_type);
1849 /* Otherwise try splitting the constant into a base and offset.
1850 16-bit offsets can be added using an extra addiu. Larger offsets
1851 must be calculated separately and then added to the base. */
1852 mips_split_const (x, &x, &offset);
1855 int n = mips_const_insns (x);
1858 if (SMALL_OPERAND (offset))
1861 return n + 1 + mips_build_integer (codes, offset);
1868 return mips_symbol_insns (mips_classify_symbol (x));
1876 /* Return the number of instructions needed for memory reference X.
1877 Count extended mips16 instructions as two instructions. */
1880 mips_fetch_insns (rtx x)
1882 gcc_assert (MEM_P (x));
1883 return mips_address_insns (XEXP (x, 0), GET_MODE (x));
1887 /* Return the number of instructions needed for an integer division. */
1890 mips_idiv_insns (void)
1895 if (TARGET_CHECK_ZERO_DIV)
1897 if (GENERATE_DIVIDE_TRAPS)
1903 if (TARGET_FIX_R4000 || TARGET_FIX_R4400)
1908 /* This function is used to implement GO_IF_LEGITIMATE_ADDRESS. It
1909 returns a nonzero value if X is a legitimate address for a memory
1910 operand of the indicated MODE. STRICT is nonzero if this function
1911 is called during reload. */
1914 mips_legitimate_address_p (enum machine_mode mode, rtx x, int strict)
1916 struct mips_address_info addr;
1918 return mips_classify_address (&addr, x, mode, strict);
1922 /* Copy VALUE to a register and return that register. If new psuedos
1923 are allowed, copy it into a new register, otherwise use DEST. */
1926 mips_force_temporary (rtx dest, rtx value)
1928 if (!no_new_pseudos)
1929 return force_reg (Pmode, value);
1932 emit_move_insn (copy_rtx (dest), value);
1938 /* Return a LO_SUM expression for ADDR. TEMP is as for mips_force_temporary
1939 and is used to load the high part into a register. */
1942 mips_split_symbol (rtx temp, rtx addr)
1947 high = mips16_gp_pseudo_reg ();
1949 high = mips_force_temporary (temp, gen_rtx_HIGH (Pmode, copy_rtx (addr)));
1950 return gen_rtx_LO_SUM (Pmode, high, addr);
1954 /* Return an UNSPEC address with underlying address ADDRESS and symbol
1955 type SYMBOL_TYPE. */
1958 mips_unspec_address (rtx address, enum mips_symbol_type symbol_type)
1961 HOST_WIDE_INT offset;
1963 mips_split_const (address, &base, &offset);
1964 base = gen_rtx_UNSPEC (Pmode, gen_rtvec (1, base),
1965 UNSPEC_ADDRESS_FIRST + symbol_type);
1966 return plus_constant (gen_rtx_CONST (Pmode, base), offset);
1970 /* If mips_unspec_address (ADDR, SYMBOL_TYPE) is a 32-bit value, add the
1971 high part to BASE and return the result. Just return BASE otherwise.
1972 TEMP is available as a temporary register if needed.
1974 The returned expression can be used as the first operand to a LO_SUM. */
1977 mips_unspec_offset_high (rtx temp, rtx base, rtx addr,
1978 enum mips_symbol_type symbol_type)
1980 if (mips_split_p[symbol_type])
1982 addr = gen_rtx_HIGH (Pmode, mips_unspec_address (addr, symbol_type));
1983 addr = mips_force_temporary (temp, addr);
1984 return mips_force_temporary (temp, gen_rtx_PLUS (Pmode, addr, base));
1990 /* Return a legitimate address for REG + OFFSET. TEMP is as for
1991 mips_force_temporary; it is only needed when OFFSET is not a
1995 mips_add_offset (rtx temp, rtx reg, HOST_WIDE_INT offset)
1997 if (!SMALL_OPERAND (offset))
2002 /* Load the full offset into a register so that we can use
2003 an unextended instruction for the address itself. */
2004 high = GEN_INT (offset);
2009 /* Leave OFFSET as a 16-bit offset and put the excess in HIGH. */
2010 high = GEN_INT (CONST_HIGH_PART (offset));
2011 offset = CONST_LOW_PART (offset);
2013 high = mips_force_temporary (temp, high);
2014 reg = mips_force_temporary (temp, gen_rtx_PLUS (Pmode, high, reg));
2016 return plus_constant (reg, offset);
2019 /* Emit a call to __tls_get_addr. SYM is the TLS symbol we are
2020 referencing, and TYPE is the symbol type to use (either global
2021 dynamic or local dynamic). V0 is an RTX for the return value
2022 location. The entire insn sequence is returned. */
2024 static GTY(()) rtx mips_tls_symbol;
2027 mips_call_tls_get_addr (rtx sym, enum mips_symbol_type type, rtx v0)
2029 rtx insn, loc, tga, a0;
2031 a0 = gen_rtx_REG (Pmode, GP_ARG_FIRST);
2033 if (!mips_tls_symbol)
2034 mips_tls_symbol = init_one_libfunc ("__tls_get_addr");
2036 loc = mips_unspec_address (sym, type);
2040 emit_insn (gen_rtx_SET (Pmode, a0,
2041 gen_rtx_LO_SUM (Pmode, pic_offset_table_rtx, loc)));
2042 tga = gen_rtx_MEM (Pmode, mips_tls_symbol);
2043 insn = emit_call_insn (gen_call_value (v0, tga, const0_rtx, const0_rtx));
2044 CONST_OR_PURE_CALL_P (insn) = 1;
2045 use_reg (&CALL_INSN_FUNCTION_USAGE (insn), v0);
2046 use_reg (&CALL_INSN_FUNCTION_USAGE (insn), a0);
2047 insn = get_insns ();
2054 /* Generate the code to access LOC, a thread local SYMBOL_REF. The
2055 return value will be a valid address and move_operand (either a REG
2059 mips_legitimize_tls_address (rtx loc)
2061 rtx dest, insn, v0, v1, tmp1, tmp2, eqv;
2062 enum tls_model model;
2064 v0 = gen_rtx_REG (Pmode, GP_RETURN);
2065 v1 = gen_rtx_REG (Pmode, GP_RETURN + 1);
2067 model = SYMBOL_REF_TLS_MODEL (loc);
2068 /* Only TARGET_ABICALLS code can have more than one module; other
2069 code must be be static and should not use a GOT. All TLS models
2070 reduce to local exec in this situation. */
2071 if (!TARGET_ABICALLS)
2072 model = TLS_MODEL_LOCAL_EXEC;
2076 case TLS_MODEL_GLOBAL_DYNAMIC:
2077 insn = mips_call_tls_get_addr (loc, SYMBOL_TLSGD, v0);
2078 dest = gen_reg_rtx (Pmode);
2079 emit_libcall_block (insn, dest, v0, loc);
2082 case TLS_MODEL_LOCAL_DYNAMIC:
2083 insn = mips_call_tls_get_addr (loc, SYMBOL_TLSLDM, v0);
2084 tmp1 = gen_reg_rtx (Pmode);
2086 /* Attach a unique REG_EQUIV, to allow the RTL optimizers to
2087 share the LDM result with other LD model accesses. */
2088 eqv = gen_rtx_UNSPEC (Pmode, gen_rtvec (1, const0_rtx),
2090 emit_libcall_block (insn, tmp1, v0, eqv);
2092 tmp2 = mips_unspec_offset_high (NULL, tmp1, loc, SYMBOL_DTPREL);
2093 dest = gen_rtx_LO_SUM (Pmode, tmp2,
2094 mips_unspec_address (loc, SYMBOL_DTPREL));
2097 case TLS_MODEL_INITIAL_EXEC:
2098 tmp1 = gen_reg_rtx (Pmode);
2099 tmp2 = mips_unspec_address (loc, SYMBOL_GOTTPREL);
2100 if (Pmode == DImode)
2102 emit_insn (gen_tls_get_tp_di (v1));
2103 emit_insn (gen_load_gotdi (tmp1, pic_offset_table_rtx, tmp2));
2107 emit_insn (gen_tls_get_tp_si (v1));
2108 emit_insn (gen_load_gotsi (tmp1, pic_offset_table_rtx, tmp2));
2110 dest = gen_reg_rtx (Pmode);
2111 emit_insn (gen_add3_insn (dest, tmp1, v1));
2114 case TLS_MODEL_LOCAL_EXEC:
2115 if (Pmode == DImode)
2116 emit_insn (gen_tls_get_tp_di (v1));
2118 emit_insn (gen_tls_get_tp_si (v1));
2120 tmp1 = mips_unspec_offset_high (NULL, v1, loc, SYMBOL_TPREL);
2121 dest = gen_rtx_LO_SUM (Pmode, tmp1,
2122 mips_unspec_address (loc, SYMBOL_TPREL));
2132 /* This function is used to implement LEGITIMIZE_ADDRESS. If *XLOC can
2133 be legitimized in a way that the generic machinery might not expect,
2134 put the new address in *XLOC and return true. MODE is the mode of
2135 the memory being accessed. */
2138 mips_legitimize_address (rtx *xloc, enum machine_mode mode)
2140 enum mips_symbol_type symbol_type;
2142 if (mips_tls_operand_p (*xloc))
2144 *xloc = mips_legitimize_tls_address (*xloc);
2148 /* See if the address can split into a high part and a LO_SUM. */
2149 if (mips_symbolic_constant_p (*xloc, &symbol_type)
2150 && mips_symbolic_address_p (symbol_type, mode)
2151 && mips_split_p[symbol_type])
2153 *xloc = mips_split_symbol (0, *xloc);
2157 if (GET_CODE (*xloc) == PLUS && GET_CODE (XEXP (*xloc, 1)) == CONST_INT)
2159 /* Handle REG + CONSTANT using mips_add_offset. */
2162 reg = XEXP (*xloc, 0);
2163 if (!mips_valid_base_register_p (reg, mode, 0))
2164 reg = copy_to_mode_reg (Pmode, reg);
2165 *xloc = mips_add_offset (0, reg, INTVAL (XEXP (*xloc, 1)));
2173 /* Subroutine of mips_build_integer (with the same interface).
2174 Assume that the final action in the sequence should be a left shift. */
2177 mips_build_shift (struct mips_integer_op *codes, HOST_WIDE_INT value)
2179 unsigned int i, shift;
2181 /* Shift VALUE right until its lowest bit is set. Shift arithmetically
2182 since signed numbers are easier to load than unsigned ones. */
2184 while ((value & 1) == 0)
2185 value /= 2, shift++;
2187 i = mips_build_integer (codes, value);
2188 codes[i].code = ASHIFT;
2189 codes[i].value = shift;
2194 /* As for mips_build_shift, but assume that the final action will be
2195 an IOR or PLUS operation. */
2198 mips_build_lower (struct mips_integer_op *codes, unsigned HOST_WIDE_INT value)
2200 unsigned HOST_WIDE_INT high;
2203 high = value & ~(unsigned HOST_WIDE_INT) 0xffff;
2204 if (!LUI_OPERAND (high) && (value & 0x18000) == 0x18000)
2206 /* The constant is too complex to load with a simple lui/ori pair
2207 so our goal is to clear as many trailing zeros as possible.
2208 In this case, we know bit 16 is set and that the low 16 bits
2209 form a negative number. If we subtract that number from VALUE,
2210 we will clear at least the lowest 17 bits, maybe more. */
2211 i = mips_build_integer (codes, CONST_HIGH_PART (value));
2212 codes[i].code = PLUS;
2213 codes[i].value = CONST_LOW_PART (value);
2217 i = mips_build_integer (codes, high);
2218 codes[i].code = IOR;
2219 codes[i].value = value & 0xffff;
2225 /* Fill CODES with a sequence of rtl operations to load VALUE.
2226 Return the number of operations needed. */
2229 mips_build_integer (struct mips_integer_op *codes,
2230 unsigned HOST_WIDE_INT value)
2232 if (SMALL_OPERAND (value)
2233 || SMALL_OPERAND_UNSIGNED (value)
2234 || LUI_OPERAND (value))
2236 /* The value can be loaded with a single instruction. */
2237 codes[0].code = UNKNOWN;
2238 codes[0].value = value;
2241 else if ((value & 1) != 0 || LUI_OPERAND (CONST_HIGH_PART (value)))
2243 /* Either the constant is a simple LUI/ORI combination or its
2244 lowest bit is set. We don't want to shift in this case. */
2245 return mips_build_lower (codes, value);
2247 else if ((value & 0xffff) == 0)
2249 /* The constant will need at least three actions. The lowest
2250 16 bits are clear, so the final action will be a shift. */
2251 return mips_build_shift (codes, value);
2255 /* The final action could be a shift, add or inclusive OR.
2256 Rather than use a complex condition to select the best
2257 approach, try both mips_build_shift and mips_build_lower
2258 and pick the one that gives the shortest sequence.
2259 Note that this case is only used once per constant. */
2260 struct mips_integer_op alt_codes[MIPS_MAX_INTEGER_OPS];
2261 unsigned int cost, alt_cost;
2263 cost = mips_build_shift (codes, value);
2264 alt_cost = mips_build_lower (alt_codes, value);
2265 if (alt_cost < cost)
2267 memcpy (codes, alt_codes, alt_cost * sizeof (codes[0]));
2275 /* Load VALUE into DEST, using TEMP as a temporary register if need be. */
2278 mips_move_integer (rtx dest, rtx temp, unsigned HOST_WIDE_INT value)
2280 struct mips_integer_op codes[MIPS_MAX_INTEGER_OPS];
2281 enum machine_mode mode;
2282 unsigned int i, cost;
2285 mode = GET_MODE (dest);
2286 cost = mips_build_integer (codes, value);
2288 /* Apply each binary operation to X. Invariant: X is a legitimate
2289 source operand for a SET pattern. */
2290 x = GEN_INT (codes[0].value);
2291 for (i = 1; i < cost; i++)
2295 emit_insn (gen_rtx_SET (VOIDmode, temp, x));
2299 x = force_reg (mode, x);
2300 x = gen_rtx_fmt_ee (codes[i].code, mode, x, GEN_INT (codes[i].value));
2303 emit_insn (gen_rtx_SET (VOIDmode, dest, x));
2307 /* Subroutine of mips_legitimize_move. Move constant SRC into register
2308 DEST given that SRC satisfies immediate_operand but doesn't satisfy
2312 mips_legitimize_const_move (enum machine_mode mode, rtx dest, rtx src)
2315 HOST_WIDE_INT offset;
2317 /* Split moves of big integers into smaller pieces. */
2318 if (splittable_const_int_operand (src, mode))
2320 mips_move_integer (dest, dest, INTVAL (src));
2324 /* Split moves of symbolic constants into high/low pairs. */
2325 if (splittable_symbolic_operand (src, mode))
2327 emit_insn (gen_rtx_SET (VOIDmode, dest, mips_split_symbol (dest, src)));
2331 if (mips_tls_operand_p (src))
2333 emit_move_insn (dest, mips_legitimize_tls_address (src));
2337 /* If we have (const (plus symbol offset)), load the symbol first
2338 and then add in the offset. This is usually better than forcing
2339 the constant into memory, at least in non-mips16 code. */
2340 mips_split_const (src, &base, &offset);
2343 && (!no_new_pseudos || SMALL_OPERAND (offset)))
2345 base = mips_force_temporary (dest, base);
2346 emit_move_insn (dest, mips_add_offset (0, base, offset));
2350 src = force_const_mem (mode, src);
2352 /* When using explicit relocs, constant pool references are sometimes
2353 not legitimate addresses. */
2354 if (!memory_operand (src, VOIDmode))
2355 src = replace_equiv_address (src, mips_split_symbol (dest, XEXP (src, 0)));
2356 emit_move_insn (dest, src);
2360 /* If (set DEST SRC) is not a valid instruction, emit an equivalent
2361 sequence that is valid. */
2364 mips_legitimize_move (enum machine_mode mode, rtx dest, rtx src)
2366 if (!register_operand (dest, mode) && !reg_or_0_operand (src, mode))
2368 emit_move_insn (dest, force_reg (mode, src));
2372 /* Check for individual, fully-reloaded mflo and mfhi instructions. */
2373 if (GET_MODE_SIZE (mode) <= UNITS_PER_WORD
2374 && REG_P (src) && MD_REG_P (REGNO (src))
2375 && REG_P (dest) && GP_REG_P (REGNO (dest)))
2377 int other_regno = REGNO (src) == HI_REGNUM ? LO_REGNUM : HI_REGNUM;
2378 if (GET_MODE_SIZE (mode) <= 4)
2379 emit_insn (gen_mfhilo_si (gen_rtx_REG (SImode, REGNO (dest)),
2380 gen_rtx_REG (SImode, REGNO (src)),
2381 gen_rtx_REG (SImode, other_regno)));
2383 emit_insn (gen_mfhilo_di (gen_rtx_REG (DImode, REGNO (dest)),
2384 gen_rtx_REG (DImode, REGNO (src)),
2385 gen_rtx_REG (DImode, other_regno)));
2389 /* We need to deal with constants that would be legitimate
2390 immediate_operands but not legitimate move_operands. */
2391 if (CONSTANT_P (src) && !move_operand (src, mode))
2393 mips_legitimize_const_move (mode, dest, src);
2394 set_unique_reg_note (get_last_insn (), REG_EQUAL, copy_rtx (src));
2400 /* We need a lot of little routines to check constant values on the
2401 mips16. These are used to figure out how long the instruction will
2402 be. It would be much better to do this using constraints, but
2403 there aren't nearly enough letters available. */
2406 m16_check_op (rtx op, int low, int high, int mask)
2408 return (GET_CODE (op) == CONST_INT
2409 && INTVAL (op) >= low
2410 && INTVAL (op) <= high
2411 && (INTVAL (op) & mask) == 0);
2415 m16_uimm3_b (rtx op, enum machine_mode mode ATTRIBUTE_UNUSED)
2417 return m16_check_op (op, 0x1, 0x8, 0);
2421 m16_simm4_1 (rtx op, enum machine_mode mode ATTRIBUTE_UNUSED)
2423 return m16_check_op (op, - 0x8, 0x7, 0);
2427 m16_nsimm4_1 (rtx op, enum machine_mode mode ATTRIBUTE_UNUSED)
2429 return m16_check_op (op, - 0x7, 0x8, 0);
2433 m16_simm5_1 (rtx op, enum machine_mode mode ATTRIBUTE_UNUSED)
2435 return m16_check_op (op, - 0x10, 0xf, 0);
2439 m16_nsimm5_1 (rtx op, enum machine_mode mode ATTRIBUTE_UNUSED)
2441 return m16_check_op (op, - 0xf, 0x10, 0);
2445 m16_uimm5_4 (rtx op, enum machine_mode mode ATTRIBUTE_UNUSED)
2447 return m16_check_op (op, (- 0x10) << 2, 0xf << 2, 3);
2451 m16_nuimm5_4 (rtx op, enum machine_mode mode ATTRIBUTE_UNUSED)
2453 return m16_check_op (op, (- 0xf) << 2, 0x10 << 2, 3);
2457 m16_simm8_1 (rtx op, enum machine_mode mode ATTRIBUTE_UNUSED)
2459 return m16_check_op (op, - 0x80, 0x7f, 0);
2463 m16_nsimm8_1 (rtx op, enum machine_mode mode ATTRIBUTE_UNUSED)
2465 return m16_check_op (op, - 0x7f, 0x80, 0);
2469 m16_uimm8_1 (rtx op, enum machine_mode mode ATTRIBUTE_UNUSED)
2471 return m16_check_op (op, 0x0, 0xff, 0);
2475 m16_nuimm8_1 (rtx op, enum machine_mode mode ATTRIBUTE_UNUSED)
2477 return m16_check_op (op, - 0xff, 0x0, 0);
2481 m16_uimm8_m1_1 (rtx op, enum machine_mode mode ATTRIBUTE_UNUSED)
2483 return m16_check_op (op, - 0x1, 0xfe, 0);
2487 m16_uimm8_4 (rtx op, enum machine_mode mode ATTRIBUTE_UNUSED)
2489 return m16_check_op (op, 0x0, 0xff << 2, 3);
2493 m16_nuimm8_4 (rtx op, enum machine_mode mode ATTRIBUTE_UNUSED)
2495 return m16_check_op (op, (- 0xff) << 2, 0x0, 3);
2499 m16_simm8_8 (rtx op, enum machine_mode mode ATTRIBUTE_UNUSED)
2501 return m16_check_op (op, (- 0x80) << 3, 0x7f << 3, 7);
2505 m16_nsimm8_8 (rtx op, enum machine_mode mode ATTRIBUTE_UNUSED)
2507 return m16_check_op (op, (- 0x7f) << 3, 0x80 << 3, 7);
2511 mips_rtx_costs (rtx x, int code, int outer_code, int *total)
2513 enum machine_mode mode = GET_MODE (x);
2514 bool float_mode_p = FLOAT_MODE_P (mode);
2521 /* A number between 1 and 8 inclusive is efficient for a shift.
2522 Otherwise, we will need an extended instruction. */
2523 if ((outer_code) == ASHIFT || (outer_code) == ASHIFTRT
2524 || (outer_code) == LSHIFTRT)
2526 if (INTVAL (x) >= 1 && INTVAL (x) <= 8)
2529 *total = COSTS_N_INSNS (1);
2533 /* We can use cmpi for an xor with an unsigned 16 bit value. */
2534 if ((outer_code) == XOR
2535 && INTVAL (x) >= 0 && INTVAL (x) < 0x10000)
2541 /* We may be able to use slt or sltu for a comparison with a
2542 signed 16 bit value. (The boundary conditions aren't quite
2543 right, but this is just a heuristic anyhow.) */
2544 if (((outer_code) == LT || (outer_code) == LE
2545 || (outer_code) == GE || (outer_code) == GT
2546 || (outer_code) == LTU || (outer_code) == LEU
2547 || (outer_code) == GEU || (outer_code) == GTU)
2548 && INTVAL (x) >= -0x8000 && INTVAL (x) < 0x8000)
2554 /* Equality comparisons with 0 are cheap. */
2555 if (((outer_code) == EQ || (outer_code) == NE)
2562 /* Constants in the range 0...255 can be loaded with an unextended
2563 instruction. They are therefore as cheap as a register move.
2565 Given the choice between "li R1,0...255" and "move R1,R2"
2566 (where R2 is a known constant), it is usually better to use "li",
2567 since we do not want to unnecessarily extend the lifetime
2569 if (outer_code == SET
2571 && INTVAL (x) < 256)
2579 /* These can be used anywhere. */
2584 /* Otherwise fall through to the handling below because
2585 we'll need to construct the constant. */
2591 if (LEGITIMATE_CONSTANT_P (x))
2593 *total = COSTS_N_INSNS (1);
2598 /* The value will need to be fetched from the constant pool. */
2599 *total = CONSTANT_POOL_COST;
2605 /* If the address is legitimate, return the number of
2606 instructions it needs, otherwise use the default handling. */
2607 int n = mips_address_insns (XEXP (x, 0), GET_MODE (x));
2610 *total = COSTS_N_INSNS (n + 1);
2617 *total = COSTS_N_INSNS (6);
2621 *total = COSTS_N_INSNS ((mode == DImode && !TARGET_64BIT) ? 2 : 1);
2627 if (mode == DImode && !TARGET_64BIT)
2629 *total = COSTS_N_INSNS (2);
2637 if (mode == DImode && !TARGET_64BIT)
2639 *total = COSTS_N_INSNS ((GET_CODE (XEXP (x, 1)) == CONST_INT)
2647 *total = COSTS_N_INSNS (1);
2649 *total = COSTS_N_INSNS (4);
2653 *total = COSTS_N_INSNS (1);
2660 *total = mips_cost->fp_add;
2664 else if (mode == DImode && !TARGET_64BIT)
2666 *total = COSTS_N_INSNS (4);
2672 if (mode == DImode && !TARGET_64BIT)
2674 *total = COSTS_N_INSNS (4);
2681 *total = mips_cost->fp_mult_sf;
2683 else if (mode == DFmode)
2684 *total = mips_cost->fp_mult_df;
2686 else if (mode == SImode)
2687 *total = mips_cost->int_mult_si;
2690 *total = mips_cost->int_mult_di;
2699 *total = mips_cost->fp_div_sf;
2701 *total = mips_cost->fp_div_df;
2710 *total = mips_cost->int_div_di;
2712 *total = mips_cost->int_div_si;
2717 /* A sign extend from SImode to DImode in 64 bit mode is often
2718 zero instructions, because the result can often be used
2719 directly by another instruction; we'll call it one. */
2720 if (TARGET_64BIT && mode == DImode
2721 && GET_MODE (XEXP (x, 0)) == SImode)
2722 *total = COSTS_N_INSNS (1);
2724 *total = COSTS_N_INSNS (2);
2728 if (TARGET_64BIT && mode == DImode
2729 && GET_MODE (XEXP (x, 0)) == SImode)
2730 *total = COSTS_N_INSNS (2);
2732 *total = COSTS_N_INSNS (1);
2736 case UNSIGNED_FLOAT:
2739 case FLOAT_TRUNCATE:
2741 *total = mips_cost->fp_add;
2749 /* Provide the costs of an addressing mode that contains ADDR.
2750 If ADDR is not a valid address, its cost is irrelevant. */
2753 mips_address_cost (rtx addr)
2755 return mips_address_insns (addr, SImode);
2758 /* Return one word of double-word value OP, taking into account the fixed
2759 endianness of certain registers. HIGH_P is true to select the high part,
2760 false to select the low part. */
2763 mips_subword (rtx op, int high_p)
2766 enum machine_mode mode;
2768 mode = GET_MODE (op);
2769 if (mode == VOIDmode)
2772 if (TARGET_BIG_ENDIAN ? !high_p : high_p)
2773 byte = UNITS_PER_WORD;
2779 if (FP_REG_P (REGNO (op)))
2780 return gen_rtx_REG (word_mode, high_p ? REGNO (op) + 1 : REGNO (op));
2781 if (ACC_HI_REG_P (REGNO (op)))
2782 return gen_rtx_REG (word_mode, high_p ? REGNO (op) : REGNO (op) + 1);
2786 return mips_rewrite_small_data (adjust_address (op, word_mode, byte));
2788 return simplify_gen_subreg (word_mode, op, mode, byte);
2792 /* Return true if a 64-bit move from SRC to DEST should be split into two. */
2795 mips_split_64bit_move_p (rtx dest, rtx src)
2800 /* FP->FP moves can be done in a single instruction. */
2801 if (FP_REG_RTX_P (src) && FP_REG_RTX_P (dest))
2804 /* Check for floating-point loads and stores. They can be done using
2805 ldc1 and sdc1 on MIPS II and above. */
2808 if (FP_REG_RTX_P (dest) && MEM_P (src))
2810 if (FP_REG_RTX_P (src) && MEM_P (dest))
2817 /* Split a 64-bit move from SRC to DEST assuming that
2818 mips_split_64bit_move_p holds.
2820 Moves into and out of FPRs cause some difficulty here. Such moves
2821 will always be DFmode, since paired FPRs are not allowed to store
2822 DImode values. The most natural representation would be two separate
2823 32-bit moves, such as:
2825 (set (reg:SI $f0) (mem:SI ...))
2826 (set (reg:SI $f1) (mem:SI ...))
2828 However, the second insn is invalid because odd-numbered FPRs are
2829 not allowed to store independent values. Use the patterns load_df_low,
2830 load_df_high and store_df_high instead. */
2833 mips_split_64bit_move (rtx dest, rtx src)
2835 if (FP_REG_RTX_P (dest))
2837 /* Loading an FPR from memory or from GPRs. */
2838 emit_insn (gen_load_df_low (copy_rtx (dest), mips_subword (src, 0)));
2839 emit_insn (gen_load_df_high (dest, mips_subword (src, 1),
2842 else if (FP_REG_RTX_P (src))
2844 /* Storing an FPR into memory or GPRs. */
2845 emit_move_insn (mips_subword (dest, 0), mips_subword (src, 0));
2846 emit_insn (gen_store_df_high (mips_subword (dest, 1), src));
2850 /* The operation can be split into two normal moves. Decide in
2851 which order to do them. */
2854 low_dest = mips_subword (dest, 0);
2855 if (REG_P (low_dest)
2856 && reg_overlap_mentioned_p (low_dest, src))
2858 emit_move_insn (mips_subword (dest, 1), mips_subword (src, 1));
2859 emit_move_insn (low_dest, mips_subword (src, 0));
2863 emit_move_insn (low_dest, mips_subword (src, 0));
2864 emit_move_insn (mips_subword (dest, 1), mips_subword (src, 1));
2869 /* Return the appropriate instructions to move SRC into DEST. Assume
2870 that SRC is operand 1 and DEST is operand 0. */
2873 mips_output_move (rtx dest, rtx src)
2875 enum rtx_code dest_code, src_code;
2878 dest_code = GET_CODE (dest);
2879 src_code = GET_CODE (src);
2880 dbl_p = (GET_MODE_SIZE (GET_MODE (dest)) == 8);
2882 if (dbl_p && mips_split_64bit_move_p (dest, src))
2885 if ((src_code == REG && GP_REG_P (REGNO (src)))
2886 || (!TARGET_MIPS16 && src == CONST0_RTX (GET_MODE (dest))))
2888 if (dest_code == REG)
2890 if (GP_REG_P (REGNO (dest)))
2891 return "move\t%0,%z1";
2893 if (MD_REG_P (REGNO (dest)))
2896 if (DSP_ACC_REG_P (REGNO (dest)))
2898 static char retval[] = "mt__\t%z1,%q0";
2899 retval[2] = reg_names[REGNO (dest)][4];
2900 retval[3] = reg_names[REGNO (dest)][5];
2904 if (FP_REG_P (REGNO (dest)))
2905 return (dbl_p ? "dmtc1\t%z1,%0" : "mtc1\t%z1,%0");
2907 if (ALL_COP_REG_P (REGNO (dest)))
2909 static char retval[] = "dmtc_\t%z1,%0";
2911 retval[4] = COPNUM_AS_CHAR_FROM_REGNUM (REGNO (dest));
2912 return (dbl_p ? retval : retval + 1);
2915 if (dest_code == MEM)
2916 return (dbl_p ? "sd\t%z1,%0" : "sw\t%z1,%0");
2918 if (dest_code == REG && GP_REG_P (REGNO (dest)))
2920 if (src_code == REG)
2922 if (DSP_ACC_REG_P (REGNO (src)))
2924 static char retval[] = "mf__\t%0,%q1";
2925 retval[2] = reg_names[REGNO (src)][4];
2926 retval[3] = reg_names[REGNO (src)][5];
2930 if (ST_REG_P (REGNO (src)) && ISA_HAS_8CC)
2931 return "lui\t%0,0x3f80\n\tmovf\t%0,%.,%1";
2933 if (FP_REG_P (REGNO (src)))
2934 return (dbl_p ? "dmfc1\t%0,%1" : "mfc1\t%0,%1");
2936 if (ALL_COP_REG_P (REGNO (src)))
2938 static char retval[] = "dmfc_\t%0,%1";
2940 retval[4] = COPNUM_AS_CHAR_FROM_REGNUM (REGNO (src));
2941 return (dbl_p ? retval : retval + 1);
2945 if (src_code == MEM)
2946 return (dbl_p ? "ld\t%0,%1" : "lw\t%0,%1");
2948 if (src_code == CONST_INT)
2950 /* Don't use the X format, because that will give out of
2951 range numbers for 64 bit hosts and 32 bit targets. */
2953 return "li\t%0,%1\t\t\t# %X1";
2955 if (INTVAL (src) >= 0 && INTVAL (src) <= 0xffff)
2958 if (INTVAL (src) < 0 && INTVAL (src) >= -0xffff)
2962 if (src_code == HIGH)
2963 return "lui\t%0,%h1";
2965 if (CONST_GP_P (src))
2966 return "move\t%0,%1";
2968 if (symbolic_operand (src, VOIDmode))
2969 return (dbl_p ? "dla\t%0,%1" : "la\t%0,%1");
2971 if (src_code == REG && FP_REG_P (REGNO (src)))
2973 if (dest_code == REG && FP_REG_P (REGNO (dest)))
2975 if (GET_MODE (dest) == V2SFmode)
2976 return "mov.ps\t%0,%1";
2978 return (dbl_p ? "mov.d\t%0,%1" : "mov.s\t%0,%1");
2981 if (dest_code == MEM)
2982 return (dbl_p ? "sdc1\t%1,%0" : "swc1\t%1,%0");
2984 if (dest_code == REG && FP_REG_P (REGNO (dest)))
2986 if (src_code == MEM)
2987 return (dbl_p ? "ldc1\t%0,%1" : "lwc1\t%0,%1");
2989 if (dest_code == REG && ALL_COP_REG_P (REGNO (dest)) && src_code == MEM)
2991 static char retval[] = "l_c_\t%0,%1";
2993 retval[1] = (dbl_p ? 'd' : 'w');
2994 retval[3] = COPNUM_AS_CHAR_FROM_REGNUM (REGNO (dest));
2997 if (dest_code == MEM && src_code == REG && ALL_COP_REG_P (REGNO (src)))
2999 static char retval[] = "s_c_\t%1,%0";
3001 retval[1] = (dbl_p ? 'd' : 'w');
3002 retval[3] = COPNUM_AS_CHAR_FROM_REGNUM (REGNO (src));
3008 /* Restore $gp from its save slot. Valid only when using o32 or
3012 mips_restore_gp (void)
3016 gcc_assert (TARGET_ABICALLS && TARGET_OLDABI);
3018 address = mips_add_offset (pic_offset_table_rtx,
3019 frame_pointer_needed
3020 ? hard_frame_pointer_rtx
3021 : stack_pointer_rtx,
3022 current_function_outgoing_args_size);
3023 slot = gen_rtx_MEM (Pmode, address);
3025 emit_move_insn (pic_offset_table_rtx, slot);
3026 if (!TARGET_EXPLICIT_RELOCS)
3027 emit_insn (gen_blockage ());
3030 /* Emit an instruction of the form (set TARGET (CODE OP0 OP1)). */
3033 mips_emit_binary (enum rtx_code code, rtx target, rtx op0, rtx op1)
3035 emit_insn (gen_rtx_SET (VOIDmode, target,
3036 gen_rtx_fmt_ee (code, GET_MODE (target), op0, op1)));
3039 /* Return true if CMP1 is a suitable second operand for relational
3040 operator CODE. See also the *sCC patterns in mips.md. */
3043 mips_relational_operand_ok_p (enum rtx_code code, rtx cmp1)
3049 return reg_or_0_operand (cmp1, VOIDmode);
3053 return !TARGET_MIPS16 && cmp1 == const1_rtx;
3057 return arith_operand (cmp1, VOIDmode);
3060 return sle_operand (cmp1, VOIDmode);
3063 return sleu_operand (cmp1, VOIDmode);
3070 /* Canonicalize LE or LEU comparisons into LT comparisons when
3071 possible to avoid extra instructions or inverting the
3075 mips_canonicalize_comparison (enum rtx_code *code, rtx *cmp1,
3076 enum machine_mode mode)
3078 HOST_WIDE_INT original, plus_one;
3080 if (GET_CODE (*cmp1) != CONST_INT)
3083 original = INTVAL (*cmp1);
3084 plus_one = trunc_int_for_mode ((unsigned HOST_WIDE_INT) original + 1, mode);
3089 if (original < plus_one)
3092 *cmp1 = force_reg (mode, GEN_INT (plus_one));
3101 *cmp1 = force_reg (mode, GEN_INT (plus_one));
3114 /* Compare CMP0 and CMP1 using relational operator CODE and store the
3115 result in TARGET. CMP0 and TARGET are register_operands that have
3116 the same integer mode. If INVERT_PTR is nonnull, it's OK to set
3117 TARGET to the inverse of the result and flip *INVERT_PTR instead. */
3120 mips_emit_int_relational (enum rtx_code code, bool *invert_ptr,
3121 rtx target, rtx cmp0, rtx cmp1)
3123 /* First see if there is a MIPS instruction that can do this operation
3124 with CMP1 in its current form. If not, try to canonicalize the
3125 comparison to LT. If that fails, try doing the same for the
3126 inverse operation. If that also fails, force CMP1 into a register
3128 if (mips_relational_operand_ok_p (code, cmp1))
3129 mips_emit_binary (code, target, cmp0, cmp1);
3130 else if (mips_canonicalize_comparison (&code, &cmp1, GET_MODE (target)))
3131 mips_emit_binary (code, target, cmp0, cmp1);
3134 enum rtx_code inv_code = reverse_condition (code);
3135 if (!mips_relational_operand_ok_p (inv_code, cmp1))
3137 cmp1 = force_reg (GET_MODE (cmp0), cmp1);
3138 mips_emit_int_relational (code, invert_ptr, target, cmp0, cmp1);
3140 else if (invert_ptr == 0)
3142 rtx inv_target = gen_reg_rtx (GET_MODE (target));
3143 mips_emit_binary (inv_code, inv_target, cmp0, cmp1);
3144 mips_emit_binary (XOR, target, inv_target, const1_rtx);
3148 *invert_ptr = !*invert_ptr;
3149 mips_emit_binary (inv_code, target, cmp0, cmp1);
3154 /* Return a register that is zero iff CMP0 and CMP1 are equal.
3155 The register will have the same mode as CMP0. */
3158 mips_zero_if_equal (rtx cmp0, rtx cmp1)
3160 if (cmp1 == const0_rtx)
3163 if (uns_arith_operand (cmp1, VOIDmode))
3164 return expand_binop (GET_MODE (cmp0), xor_optab,
3165 cmp0, cmp1, 0, 0, OPTAB_DIRECT);
3167 return expand_binop (GET_MODE (cmp0), sub_optab,
3168 cmp0, cmp1, 0, 0, OPTAB_DIRECT);
3171 /* Convert *CODE into a code that can be used in a floating-point
3172 scc instruction (c.<cond>.<fmt>). Return true if the values of
3173 the condition code registers will be inverted, with 0 indicating
3174 that the condition holds. */
3177 mips_reverse_fp_cond_p (enum rtx_code *code)
3184 *code = reverse_condition_maybe_unordered (*code);
3192 /* Convert a comparison into something that can be used in a branch or
3193 conditional move. cmp_operands[0] and cmp_operands[1] are the values
3194 being compared and *CODE is the code used to compare them.
3196 Update *CODE, *OP0 and *OP1 so that they describe the final comparison.
3197 If NEED_EQ_NE_P, then only EQ/NE comparisons against zero are possible,
3198 otherwise any standard branch condition can be used. The standard branch
3201 - EQ/NE between two registers.
3202 - any comparison between a register and zero. */
3205 mips_emit_compare (enum rtx_code *code, rtx *op0, rtx *op1, bool need_eq_ne_p)
3207 if (GET_MODE_CLASS (GET_MODE (cmp_operands[0])) == MODE_INT)
3209 if (!need_eq_ne_p && cmp_operands[1] == const0_rtx)
3211 *op0 = cmp_operands[0];
3212 *op1 = cmp_operands[1];
3214 else if (*code == EQ || *code == NE)
3218 *op0 = mips_zero_if_equal (cmp_operands[0], cmp_operands[1]);
3223 *op0 = cmp_operands[0];
3224 *op1 = force_reg (GET_MODE (*op0), cmp_operands[1]);
3229 /* The comparison needs a separate scc instruction. Store the
3230 result of the scc in *OP0 and compare it against zero. */
3231 bool invert = false;
3232 *op0 = gen_reg_rtx (GET_MODE (cmp_operands[0]));
3234 mips_emit_int_relational (*code, &invert, *op0,
3235 cmp_operands[0], cmp_operands[1]);
3236 *code = (invert ? EQ : NE);
3241 enum rtx_code cmp_code;
3243 /* Floating-point tests use a separate c.cond.fmt comparison to
3244 set a condition code register. The branch or conditional move
3245 will then compare that register against zero.
3247 Set CMP_CODE to the code of the comparison instruction and
3248 *CODE to the code that the branch or move should use. */
3250 *code = mips_reverse_fp_cond_p (&cmp_code) ? EQ : NE;
3252 ? gen_reg_rtx (CCmode)
3253 : gen_rtx_REG (CCmode, FPSW_REGNUM));
3255 mips_emit_binary (cmp_code, *op0, cmp_operands[0], cmp_operands[1]);
3259 /* Try comparing cmp_operands[0] and cmp_operands[1] using rtl code CODE.
3260 Store the result in TARGET and return true if successful.
3262 On 64-bit targets, TARGET may be wider than cmp_operands[0]. */
3265 mips_emit_scc (enum rtx_code code, rtx target)
3267 if (GET_MODE_CLASS (GET_MODE (cmp_operands[0])) != MODE_INT)
3270 target = gen_lowpart (GET_MODE (cmp_operands[0]), target);
3271 if (code == EQ || code == NE)
3273 rtx zie = mips_zero_if_equal (cmp_operands[0], cmp_operands[1]);
3274 mips_emit_binary (code, target, zie, const0_rtx);
3277 mips_emit_int_relational (code, 0, target,
3278 cmp_operands[0], cmp_operands[1]);
3282 /* Emit the common code for doing conditional branches.
3283 operand[0] is the label to jump to.
3284 The comparison operands are saved away by cmp{si,di,sf,df}. */
3287 gen_conditional_branch (rtx *operands, enum rtx_code code)
3289 rtx op0, op1, condition;
3291 mips_emit_compare (&code, &op0, &op1, TARGET_MIPS16);
3292 condition = gen_rtx_fmt_ee (code, VOIDmode, op0, op1);
3293 emit_jump_insn (gen_condjump (condition, operands[0]));
3298 (set temp (COND:CCV2 CMP_OP0 CMP_OP1))
3299 (set DEST (unspec [TRUE_SRC FALSE_SRC temp] UNSPEC_MOVE_TF_PS)) */
3302 mips_expand_vcondv2sf (rtx dest, rtx true_src, rtx false_src,
3303 enum rtx_code cond, rtx cmp_op0, rtx cmp_op1)
3308 reversed_p = mips_reverse_fp_cond_p (&cond);
3309 cmp_result = gen_reg_rtx (CCV2mode);
3310 emit_insn (gen_scc_ps (cmp_result,
3311 gen_rtx_fmt_ee (cond, VOIDmode, cmp_op0, cmp_op1)));
3313 emit_insn (gen_mips_cond_move_tf_ps (dest, false_src, true_src,
3316 emit_insn (gen_mips_cond_move_tf_ps (dest, true_src, false_src,
3320 /* Emit the common code for conditional moves. OPERANDS is the array
3321 of operands passed to the conditional move define_expand. */
3324 gen_conditional_move (rtx *operands)
3329 code = GET_CODE (operands[1]);
3330 mips_emit_compare (&code, &op0, &op1, true);
3331 emit_insn (gen_rtx_SET (VOIDmode, operands[0],
3332 gen_rtx_IF_THEN_ELSE (GET_MODE (operands[0]),
3333 gen_rtx_fmt_ee (code,
3336 operands[2], operands[3])));
3339 /* Emit a conditional trap. OPERANDS is the array of operands passed to
3340 the conditional_trap expander. */
3343 mips_gen_conditional_trap (rtx *operands)
3346 enum rtx_code cmp_code = GET_CODE (operands[0]);
3347 enum machine_mode mode = GET_MODE (cmp_operands[0]);
3349 /* MIPS conditional trap machine instructions don't have GT or LE
3350 flavors, so we must invert the comparison and convert to LT and
3351 GE, respectively. */
3354 case GT: cmp_code = LT; break;
3355 case LE: cmp_code = GE; break;
3356 case GTU: cmp_code = LTU; break;
3357 case LEU: cmp_code = GEU; break;
3360 if (cmp_code == GET_CODE (operands[0]))
3362 op0 = cmp_operands[0];
3363 op1 = cmp_operands[1];
3367 op0 = cmp_operands[1];
3368 op1 = cmp_operands[0];
3370 op0 = force_reg (mode, op0);
3371 if (!arith_operand (op1, mode))
3372 op1 = force_reg (mode, op1);
3374 emit_insn (gen_rtx_TRAP_IF (VOIDmode,
3375 gen_rtx_fmt_ee (cmp_code, mode, op0, op1),
3379 /* Load function address ADDR into register DEST. SIBCALL_P is true
3380 if the address is needed for a sibling call. */
3383 mips_load_call_address (rtx dest, rtx addr, int sibcall_p)
3385 /* If we're generating PIC, and this call is to a global function,
3386 try to allow its address to be resolved lazily. This isn't
3387 possible for NewABI sibcalls since the value of $gp on entry
3388 to the stub would be our caller's gp, not ours. */
3389 if (TARGET_EXPLICIT_RELOCS
3390 && !(sibcall_p && TARGET_NEWABI)
3391 && global_got_operand (addr, VOIDmode))
3393 rtx high, lo_sum_symbol;
3395 high = mips_unspec_offset_high (dest, pic_offset_table_rtx,
3396 addr, SYMBOL_GOTOFF_CALL);
3397 lo_sum_symbol = mips_unspec_address (addr, SYMBOL_GOTOFF_CALL);
3398 if (Pmode == SImode)
3399 emit_insn (gen_load_callsi (dest, high, lo_sum_symbol));
3401 emit_insn (gen_load_calldi (dest, high, lo_sum_symbol));
3404 emit_move_insn (dest, addr);
3408 /* Expand a call or call_value instruction. RESULT is where the
3409 result will go (null for calls), ADDR is the address of the
3410 function, ARGS_SIZE is the size of the arguments and AUX is
3411 the value passed to us by mips_function_arg. SIBCALL_P is true
3412 if we are expanding a sibling call, false if we're expanding
3416 mips_expand_call (rtx result, rtx addr, rtx args_size, rtx aux, int sibcall_p)
3418 rtx orig_addr, pattern, insn;
3421 if (!call_insn_operand (addr, VOIDmode))
3423 addr = gen_reg_rtx (Pmode);
3424 mips_load_call_address (addr, orig_addr, sibcall_p);
3428 && mips16_hard_float
3429 && build_mips16_call_stub (result, addr, args_size,
3430 aux == 0 ? 0 : (int) GET_MODE (aux)))
3434 pattern = (sibcall_p
3435 ? gen_sibcall_internal (addr, args_size)
3436 : gen_call_internal (addr, args_size));
3437 else if (GET_CODE (result) == PARALLEL && XVECLEN (result, 0) == 2)
3441 reg1 = XEXP (XVECEXP (result, 0, 0), 0);
3442 reg2 = XEXP (XVECEXP (result, 0, 1), 0);
3445 ? gen_sibcall_value_multiple_internal (reg1, addr, args_size, reg2)
3446 : gen_call_value_multiple_internal (reg1, addr, args_size, reg2));
3449 pattern = (sibcall_p
3450 ? gen_sibcall_value_internal (result, addr, args_size)
3451 : gen_call_value_internal (result, addr, args_size));
3453 insn = emit_call_insn (pattern);
3455 /* Lazy-binding stubs require $gp to be valid on entry. */
3456 if (global_got_operand (orig_addr, VOIDmode))
3457 use_reg (&CALL_INSN_FUNCTION_USAGE (insn), pic_offset_table_rtx);
3461 /* We can handle any sibcall when TARGET_SIBCALLS is true. */
3464 mips_function_ok_for_sibcall (tree decl ATTRIBUTE_UNUSED,
3465 tree exp ATTRIBUTE_UNUSED)
3467 return TARGET_SIBCALLS;
3470 /* Emit code to move general operand SRC into condition-code
3471 register DEST. SCRATCH is a scratch TFmode float register.
3478 where FP1 and FP2 are single-precision float registers
3479 taken from SCRATCH. */
3482 mips_emit_fcc_reload (rtx dest, rtx src, rtx scratch)
3486 /* Change the source to SFmode. */
3488 src = adjust_address (src, SFmode, 0);
3489 else if (REG_P (src) || GET_CODE (src) == SUBREG)
3490 src = gen_rtx_REG (SFmode, true_regnum (src));
3492 fp1 = gen_rtx_REG (SFmode, REGNO (scratch));
3493 fp2 = gen_rtx_REG (SFmode, REGNO (scratch) + FP_INC);
3495 emit_move_insn (copy_rtx (fp1), src);
3496 emit_move_insn (copy_rtx (fp2), CONST0_RTX (SFmode));
3497 emit_insn (gen_slt_sf (dest, fp2, fp1));
3500 /* Emit code to change the current function's return address to
3501 ADDRESS. SCRATCH is available as a scratch register, if needed.
3502 ADDRESS and SCRATCH are both word-mode GPRs. */
3505 mips_set_return_address (rtx address, rtx scratch)
3509 compute_frame_size (get_frame_size ());
3510 gcc_assert ((cfun->machine->frame.mask >> 31) & 1);
3511 slot_address = mips_add_offset (scratch, stack_pointer_rtx,
3512 cfun->machine->frame.gp_sp_offset);
3514 emit_move_insn (gen_rtx_MEM (GET_MODE (address), slot_address), address);
3517 /* Emit straight-line code to move LENGTH bytes from SRC to DEST.
3518 Assume that the areas do not overlap. */
3521 mips_block_move_straight (rtx dest, rtx src, HOST_WIDE_INT length)
3523 HOST_WIDE_INT offset, delta;
3524 unsigned HOST_WIDE_INT bits;
3526 enum machine_mode mode;
3529 /* Work out how many bits to move at a time. If both operands have
3530 half-word alignment, it is usually better to move in half words.
3531 For instance, lh/lh/sh/sh is usually better than lwl/lwr/swl/swr
3532 and lw/lw/sw/sw is usually better than ldl/ldr/sdl/sdr.
3533 Otherwise move word-sized chunks. */
3534 if (MEM_ALIGN (src) == BITS_PER_WORD / 2
3535 && MEM_ALIGN (dest) == BITS_PER_WORD / 2)
3536 bits = BITS_PER_WORD / 2;
3538 bits = BITS_PER_WORD;
3540 mode = mode_for_size (bits, MODE_INT, 0);
3541 delta = bits / BITS_PER_UNIT;
3543 /* Allocate a buffer for the temporary registers. */
3544 regs = alloca (sizeof (rtx) * length / delta);
3546 /* Load as many BITS-sized chunks as possible. Use a normal load if
3547 the source has enough alignment, otherwise use left/right pairs. */
3548 for (offset = 0, i = 0; offset + delta <= length; offset += delta, i++)
3550 regs[i] = gen_reg_rtx (mode);
3551 if (MEM_ALIGN (src) >= bits)
3552 emit_move_insn (regs[i], adjust_address (src, mode, offset));
3555 rtx part = adjust_address (src, BLKmode, offset);
3556 if (!mips_expand_unaligned_load (regs[i], part, bits, 0))
3561 /* Copy the chunks to the destination. */
3562 for (offset = 0, i = 0; offset + delta <= length; offset += delta, i++)
3563 if (MEM_ALIGN (dest) >= bits)
3564 emit_move_insn (adjust_address (dest, mode, offset), regs[i]);
3567 rtx part = adjust_address (dest, BLKmode, offset);
3568 if (!mips_expand_unaligned_store (part, regs[i], bits, 0))
3572 /* Mop up any left-over bytes. */
3573 if (offset < length)
3575 src = adjust_address (src, BLKmode, offset);
3576 dest = adjust_address (dest, BLKmode, offset);
3577 move_by_pieces (dest, src, length - offset,
3578 MIN (MEM_ALIGN (src), MEM_ALIGN (dest)), 0);
3582 #define MAX_MOVE_REGS 4
3583 #define MAX_MOVE_BYTES (MAX_MOVE_REGS * UNITS_PER_WORD)
3586 /* Helper function for doing a loop-based block operation on memory
3587 reference MEM. Each iteration of the loop will operate on LENGTH
3590 Create a new base register for use within the loop and point it to
3591 the start of MEM. Create a new memory reference that uses this
3592 register. Store them in *LOOP_REG and *LOOP_MEM respectively. */
3595 mips_adjust_block_mem (rtx mem, HOST_WIDE_INT length,
3596 rtx *loop_reg, rtx *loop_mem)
3598 *loop_reg = copy_addr_to_reg (XEXP (mem, 0));
3600 /* Although the new mem does not refer to a known location,
3601 it does keep up to LENGTH bytes of alignment. */
3602 *loop_mem = change_address (mem, BLKmode, *loop_reg);
3603 set_mem_align (*loop_mem, MIN (MEM_ALIGN (mem), length * BITS_PER_UNIT));
3607 /* Move LENGTH bytes from SRC to DEST using a loop that moves MAX_MOVE_BYTES
3608 per iteration. LENGTH must be at least MAX_MOVE_BYTES. Assume that the
3609 memory regions do not overlap. */
3612 mips_block_move_loop (rtx dest, rtx src, HOST_WIDE_INT length)
3614 rtx label, src_reg, dest_reg, final_src;
3615 HOST_WIDE_INT leftover;
3617 leftover = length % MAX_MOVE_BYTES;
3620 /* Create registers and memory references for use within the loop. */
3621 mips_adjust_block_mem (src, MAX_MOVE_BYTES, &src_reg, &src);
3622 mips_adjust_block_mem (dest, MAX_MOVE_BYTES, &dest_reg, &dest);
3624 /* Calculate the value that SRC_REG should have after the last iteration
3626 final_src = expand_simple_binop (Pmode, PLUS, src_reg, GEN_INT (length),
3629 /* Emit the start of the loop. */
3630 label = gen_label_rtx ();
3633 /* Emit the loop body. */
3634 mips_block_move_straight (dest, src, MAX_MOVE_BYTES);
3636 /* Move on to the next block. */
3637 emit_move_insn (src_reg, plus_constant (src_reg, MAX_MOVE_BYTES));
3638 emit_move_insn (dest_reg, plus_constant (dest_reg, MAX_MOVE_BYTES));
3640 /* Emit the loop condition. */
3641 if (Pmode == DImode)
3642 emit_insn (gen_cmpdi (src_reg, final_src));
3644 emit_insn (gen_cmpsi (src_reg, final_src));
3645 emit_jump_insn (gen_bne (label));
3647 /* Mop up any left-over bytes. */
3649 mips_block_move_straight (dest, src, leftover);
3652 /* Expand a movmemsi instruction. */
3655 mips_expand_block_move (rtx dest, rtx src, rtx length)
3657 if (GET_CODE (length) == CONST_INT)
3659 if (INTVAL (length) <= 2 * MAX_MOVE_BYTES)
3661 mips_block_move_straight (dest, src, INTVAL (length));
3666 mips_block_move_loop (dest, src, INTVAL (length));
3673 /* Argument support functions. */
3675 /* Initialize CUMULATIVE_ARGS for a function. */
3678 init_cumulative_args (CUMULATIVE_ARGS *cum, tree fntype,
3679 rtx libname ATTRIBUTE_UNUSED)
3681 static CUMULATIVE_ARGS zero_cum;
3682 tree param, next_param;
3685 cum->prototype = (fntype && TYPE_ARG_TYPES (fntype));
3687 /* Determine if this function has variable arguments. This is
3688 indicated by the last argument being 'void_type_mode' if there
3689 are no variable arguments. The standard MIPS calling sequence
3690 passes all arguments in the general purpose registers in this case. */
3692 for (param = fntype ? TYPE_ARG_TYPES (fntype) : 0;
3693 param != 0; param = next_param)
3695 next_param = TREE_CHAIN (param);
3696 if (next_param == 0 && TREE_VALUE (param) != void_type_node)
3697 cum->gp_reg_found = 1;
3702 /* Fill INFO with information about a single argument. CUM is the
3703 cumulative state for earlier arguments. MODE is the mode of this
3704 argument and TYPE is its type (if known). NAMED is true if this
3705 is a named (fixed) argument rather than a variable one. */
3708 mips_arg_info (const CUMULATIVE_ARGS *cum, enum machine_mode mode,
3709 tree type, int named, struct mips_arg_info *info)
3711 bool doubleword_aligned_p;
3712 unsigned int num_bytes, num_words, max_regs;
3714 /* Work out the size of the argument. */
3715 num_bytes = type ? int_size_in_bytes (type) : GET_MODE_SIZE (mode);
3716 num_words = (num_bytes + UNITS_PER_WORD - 1) / UNITS_PER_WORD;
3718 /* Decide whether it should go in a floating-point register, assuming
3719 one is free. Later code checks for availability.
3721 The checks against UNITS_PER_FPVALUE handle the soft-float and
3722 single-float cases. */
3726 /* The EABI conventions have traditionally been defined in terms
3727 of TYPE_MODE, regardless of the actual type. */
3728 info->fpr_p = ((GET_MODE_CLASS (mode) == MODE_FLOAT
3729 || GET_MODE_CLASS (mode) == MODE_VECTOR_FLOAT)
3730 && GET_MODE_SIZE (mode) <= UNITS_PER_FPVALUE);
3735 /* Only leading floating-point scalars are passed in
3736 floating-point registers. We also handle vector floats the same
3737 say, which is OK because they are not covered by the standard ABI. */
3738 info->fpr_p = (!cum->gp_reg_found
3739 && cum->arg_number < 2
3740 && (type == 0 || SCALAR_FLOAT_TYPE_P (type)
3741 || VECTOR_FLOAT_TYPE_P (type))
3742 && (GET_MODE_CLASS (mode) == MODE_FLOAT
3743 || GET_MODE_CLASS (mode) == MODE_VECTOR_FLOAT)
3744 && GET_MODE_SIZE (mode) <= UNITS_PER_FPVALUE);
3749 /* Scalar and complex floating-point types are passed in
3750 floating-point registers. */
3751 info->fpr_p = (named
3752 && (type == 0 || FLOAT_TYPE_P (type))
3753 && (GET_MODE_CLASS (mode) == MODE_FLOAT
3754 || GET_MODE_CLASS (mode) == MODE_COMPLEX_FLOAT
3755 || GET_MODE_CLASS (mode) == MODE_VECTOR_FLOAT)
3756 && GET_MODE_UNIT_SIZE (mode) <= UNITS_PER_FPVALUE);
3758 /* ??? According to the ABI documentation, the real and imaginary
3759 parts of complex floats should be passed in individual registers.
3760 The real and imaginary parts of stack arguments are supposed
3761 to be contiguous and there should be an extra word of padding
3764 This has two problems. First, it makes it impossible to use a
3765 single "void *" va_list type, since register and stack arguments
3766 are passed differently. (At the time of writing, MIPSpro cannot
3767 handle complex float varargs correctly.) Second, it's unclear
3768 what should happen when there is only one register free.
3770 For now, we assume that named complex floats should go into FPRs
3771 if there are two FPRs free, otherwise they should be passed in the
3772 same way as a struct containing two floats. */
3774 && GET_MODE_CLASS (mode) == MODE_COMPLEX_FLOAT
3775 && GET_MODE_UNIT_SIZE (mode) < UNITS_PER_FPVALUE)
3777 if (cum->num_gprs >= MAX_ARGS_IN_REGISTERS - 1)
3778 info->fpr_p = false;
3788 /* See whether the argument has doubleword alignment. */
3789 doubleword_aligned_p = FUNCTION_ARG_BOUNDARY (mode, type) > BITS_PER_WORD;
3791 /* Set REG_OFFSET to the register count we're interested in.
3792 The EABI allocates the floating-point registers separately,
3793 but the other ABIs allocate them like integer registers. */
3794 info->reg_offset = (mips_abi == ABI_EABI && info->fpr_p
3798 /* Advance to an even register if the argument is doubleword-aligned. */
3799 if (doubleword_aligned_p)
3800 info->reg_offset += info->reg_offset & 1;
3802 /* Work out the offset of a stack argument. */
3803 info->stack_offset = cum->stack_words;
3804 if (doubleword_aligned_p)
3805 info->stack_offset += info->stack_offset & 1;
3807 max_regs = MAX_ARGS_IN_REGISTERS - info->reg_offset;
3809 /* Partition the argument between registers and stack. */
3810 info->reg_words = MIN (num_words, max_regs);
3811 info->stack_words = num_words - info->reg_words;
3815 /* Implement FUNCTION_ARG_ADVANCE. */
3818 function_arg_advance (CUMULATIVE_ARGS *cum, enum machine_mode mode,
3819 tree type, int named)
3821 struct mips_arg_info info;
3823 mips_arg_info (cum, mode, type, named, &info);
3826 cum->gp_reg_found = true;
3828 /* See the comment above the cumulative args structure in mips.h
3829 for an explanation of what this code does. It assumes the O32
3830 ABI, which passes at most 2 arguments in float registers. */
3831 if (cum->arg_number < 2 && info.fpr_p)
3832 cum->fp_code += (mode == SFmode ? 1 : 2) << ((cum->arg_number - 1) * 2);
3834 if (mips_abi != ABI_EABI || !info.fpr_p)
3835 cum->num_gprs = info.reg_offset + info.reg_words;
3836 else if (info.reg_words > 0)
3837 cum->num_fprs += FP_INC;
3839 if (info.stack_words > 0)
3840 cum->stack_words = info.stack_offset + info.stack_words;
3845 /* Implement FUNCTION_ARG. */
3848 function_arg (const CUMULATIVE_ARGS *cum, enum machine_mode mode,
3849 tree type, int named)
3851 struct mips_arg_info info;
3853 /* We will be called with a mode of VOIDmode after the last argument
3854 has been seen. Whatever we return will be passed to the call
3855 insn. If we need a mips16 fp_code, return a REG with the code
3856 stored as the mode. */
3857 if (mode == VOIDmode)
3859 if (TARGET_MIPS16 && cum->fp_code != 0)
3860 return gen_rtx_REG ((enum machine_mode) cum->fp_code, 0);
3866 mips_arg_info (cum, mode, type, named, &info);
3868 /* Return straight away if the whole argument is passed on the stack. */
3869 if (info.reg_offset == MAX_ARGS_IN_REGISTERS)
3873 && TREE_CODE (type) == RECORD_TYPE
3875 && TYPE_SIZE_UNIT (type)
3876 && host_integerp (TYPE_SIZE_UNIT (type), 1)
3879 /* The Irix 6 n32/n64 ABIs say that if any 64 bit chunk of the
3880 structure contains a double in its entirety, then that 64 bit
3881 chunk is passed in a floating point register. */
3884 /* First check to see if there is any such field. */
3885 for (field = TYPE_FIELDS (type); field; field = TREE_CHAIN (field))
3886 if (TREE_CODE (field) == FIELD_DECL
3887 && TREE_CODE (TREE_TYPE (field)) == REAL_TYPE
3888 && TYPE_PRECISION (TREE_TYPE (field)) == BITS_PER_WORD
3889 && host_integerp (bit_position (field), 0)
3890 && int_bit_position (field) % BITS_PER_WORD == 0)
3895 /* Now handle the special case by returning a PARALLEL
3896 indicating where each 64 bit chunk goes. INFO.REG_WORDS
3897 chunks are passed in registers. */
3899 HOST_WIDE_INT bitpos;
3902 /* assign_parms checks the mode of ENTRY_PARM, so we must
3903 use the actual mode here. */
3904 ret = gen_rtx_PARALLEL (mode, rtvec_alloc (info.reg_words));
3907 field = TYPE_FIELDS (type);
3908 for (i = 0; i < info.reg_words; i++)
3912 for (; field; field = TREE_CHAIN (field))
3913 if (TREE_CODE (field) == FIELD_DECL
3914 && int_bit_position (field) >= bitpos)
3918 && int_bit_position (field) == bitpos
3919 && TREE_CODE (TREE_TYPE (field)) == REAL_TYPE
3920 && !TARGET_SOFT_FLOAT
3921 && TYPE_PRECISION (TREE_TYPE (field)) == BITS_PER_WORD)
3922 reg = gen_rtx_REG (DFmode, FP_ARG_FIRST + info.reg_offset + i);
3924 reg = gen_rtx_REG (DImode, GP_ARG_FIRST + info.reg_offset + i);
3927 = gen_rtx_EXPR_LIST (VOIDmode, reg,
3928 GEN_INT (bitpos / BITS_PER_UNIT));
3930 bitpos += BITS_PER_WORD;
3936 /* Handle the n32/n64 conventions for passing complex floating-point
3937 arguments in FPR pairs. The real part goes in the lower register
3938 and the imaginary part goes in the upper register. */
3941 && GET_MODE_CLASS (mode) == MODE_COMPLEX_FLOAT)
3944 enum machine_mode inner;
3947 inner = GET_MODE_INNER (mode);
3948 reg = FP_ARG_FIRST + info.reg_offset;
3949 if (info.reg_words * UNITS_PER_WORD == GET_MODE_SIZE (inner))
3951 /* Real part in registers, imaginary part on stack. */
3952 gcc_assert (info.stack_words == info.reg_words);
3953 return gen_rtx_REG (inner, reg);
3957 gcc_assert (info.stack_words == 0);
3958 real = gen_rtx_EXPR_LIST (VOIDmode,
3959 gen_rtx_REG (inner, reg),
3961 imag = gen_rtx_EXPR_LIST (VOIDmode,
3963 reg + info.reg_words / 2),
3964 GEN_INT (GET_MODE_SIZE (inner)));
3965 return gen_rtx_PARALLEL (mode, gen_rtvec (2, real, imag));
3970 return gen_rtx_REG (mode, GP_ARG_FIRST + info.reg_offset);
3971 else if (info.reg_offset == 1)
3972 /* This code handles the special o32 case in which the second word
3973 of the argument structure is passed in floating-point registers. */
3974 return gen_rtx_REG (mode, FP_ARG_FIRST + FP_INC);
3976 return gen_rtx_REG (mode, FP_ARG_FIRST + info.reg_offset);
3980 /* Implement TARGET_ARG_PARTIAL_BYTES. */
3983 mips_arg_partial_bytes (CUMULATIVE_ARGS *cum,
3984 enum machine_mode mode, tree type, bool named)
3986 struct mips_arg_info info;
3988 mips_arg_info (cum, mode, type, named, &info);
3989 return info.stack_words > 0 ? info.reg_words * UNITS_PER_WORD : 0;
3993 /* Implement FUNCTION_ARG_BOUNDARY. Every parameter gets at least
3994 PARM_BOUNDARY bits of alignment, but will be given anything up
3995 to STACK_BOUNDARY bits if the type requires it. */
3998 function_arg_boundary (enum machine_mode mode, tree type)
4000 unsigned int alignment;
4002 alignment = type ? TYPE_ALIGN (type) : GET_MODE_ALIGNMENT (mode);
4003 if (alignment < PARM_BOUNDARY)
4004 alignment = PARM_BOUNDARY;
4005 if (alignment > STACK_BOUNDARY)
4006 alignment = STACK_BOUNDARY;
4010 /* Return true if FUNCTION_ARG_PADDING (MODE, TYPE) should return
4011 upward rather than downward. In other words, return true if the
4012 first byte of the stack slot has useful data, false if the last
4016 mips_pad_arg_upward (enum machine_mode mode, tree type)
4018 /* On little-endian targets, the first byte of every stack argument
4019 is passed in the first byte of the stack slot. */
4020 if (!BYTES_BIG_ENDIAN)
4023 /* Otherwise, integral types are padded downward: the last byte of a
4024 stack argument is passed in the last byte of the stack slot. */
4026 ? INTEGRAL_TYPE_P (type) || POINTER_TYPE_P (type)
4027 : GET_MODE_CLASS (mode) == MODE_INT)
4030 /* Big-endian o64 pads floating-point arguments downward. */
4031 if (mips_abi == ABI_O64)
4032 if (type != 0 ? FLOAT_TYPE_P (type) : GET_MODE_CLASS (mode) == MODE_FLOAT)
4035 /* Other types are padded upward for o32, o64, n32 and n64. */
4036 if (mips_abi != ABI_EABI)
4039 /* Arguments smaller than a stack slot are padded downward. */
4040 if (mode != BLKmode)
4041 return (GET_MODE_BITSIZE (mode) >= PARM_BOUNDARY);
4043 return (int_size_in_bytes (type) >= (PARM_BOUNDARY / BITS_PER_UNIT));
4047 /* Likewise BLOCK_REG_PADDING (MODE, TYPE, ...). Return !BYTES_BIG_ENDIAN
4048 if the least significant byte of the register has useful data. Return
4049 the opposite if the most significant byte does. */
4052 mips_pad_reg_upward (enum machine_mode mode, tree type)
4054 /* No shifting is required for floating-point arguments. */
4055 if (type != 0 ? FLOAT_TYPE_P (type) : GET_MODE_CLASS (mode) == MODE_FLOAT)
4056 return !BYTES_BIG_ENDIAN;
4058 /* Otherwise, apply the same padding to register arguments as we do
4059 to stack arguments. */
4060 return mips_pad_arg_upward (mode, type);
4064 mips_setup_incoming_varargs (CUMULATIVE_ARGS *cum, enum machine_mode mode,
4065 tree type, int *pretend_size ATTRIBUTE_UNUSED,
4068 CUMULATIVE_ARGS local_cum;
4069 int gp_saved, fp_saved;
4071 /* The caller has advanced CUM up to, but not beyond, the last named
4072 argument. Advance a local copy of CUM past the last "real" named
4073 argument, to find out how many registers are left over. */
4076 FUNCTION_ARG_ADVANCE (local_cum, mode, type, 1);
4078 /* Found out how many registers we need to save. */
4079 gp_saved = MAX_ARGS_IN_REGISTERS - local_cum.num_gprs;
4080 fp_saved = (EABI_FLOAT_VARARGS_P
4081 ? MAX_ARGS_IN_REGISTERS - local_cum.num_fprs
4090 ptr = plus_constant (virtual_incoming_args_rtx,
4091 REG_PARM_STACK_SPACE (cfun->decl)
4092 - gp_saved * UNITS_PER_WORD);
4093 mem = gen_rtx_MEM (BLKmode, ptr);
4094 set_mem_alias_set (mem, get_varargs_alias_set ());
4096 move_block_from_reg (local_cum.num_gprs + GP_ARG_FIRST,
4101 /* We can't use move_block_from_reg, because it will use
4103 enum machine_mode mode;
4106 /* Set OFF to the offset from virtual_incoming_args_rtx of
4107 the first float register. The FP save area lies below
4108 the integer one, and is aligned to UNITS_PER_FPVALUE bytes. */
4109 off = -gp_saved * UNITS_PER_WORD;
4110 off &= ~(UNITS_PER_FPVALUE - 1);
4111 off -= fp_saved * UNITS_PER_FPREG;
4113 mode = TARGET_SINGLE_FLOAT ? SFmode : DFmode;
4115 for (i = local_cum.num_fprs; i < MAX_ARGS_IN_REGISTERS; i += FP_INC)
4119 ptr = plus_constant (virtual_incoming_args_rtx, off);
4120 mem = gen_rtx_MEM (mode, ptr);
4121 set_mem_alias_set (mem, get_varargs_alias_set ());
4122 emit_move_insn (mem, gen_rtx_REG (mode, FP_ARG_FIRST + i));
4123 off += UNITS_PER_HWFPVALUE;
4127 if (REG_PARM_STACK_SPACE (cfun->decl) == 0)
4128 cfun->machine->varargs_size = (gp_saved * UNITS_PER_WORD
4129 + fp_saved * UNITS_PER_FPREG);
4132 /* Create the va_list data type.
4133 We keep 3 pointers, and two offsets.
4134 Two pointers are to the overflow area, which starts at the CFA.
4135 One of these is constant, for addressing into the GPR save area below it.
4136 The other is advanced up the stack through the overflow region.
4137 The third pointer is to the GPR save area. Since the FPR save area
4138 is just below it, we can address FPR slots off this pointer.
4139 We also keep two one-byte offsets, which are to be subtracted from the
4140 constant pointers to yield addresses in the GPR and FPR save areas.
4141 These are downcounted as float or non-float arguments are used,
4142 and when they get to zero, the argument must be obtained from the
4144 If !EABI_FLOAT_VARARGS_P, then no FPR save area exists, and a single
4145 pointer is enough. It's started at the GPR save area, and is
4147 Note that the GPR save area is not constant size, due to optimization
4148 in the prologue. Hence, we can't use a design with two pointers
4149 and two offsets, although we could have designed this with two pointers
4150 and three offsets. */
4153 mips_build_builtin_va_list (void)
4155 if (EABI_FLOAT_VARARGS_P)
4157 tree f_ovfl, f_gtop, f_ftop, f_goff, f_foff, f_res, record;
4160 record = (*lang_hooks.types.make_type) (RECORD_TYPE);
4162 f_ovfl = build_decl (FIELD_DECL, get_identifier ("__overflow_argptr"),
4164 f_gtop = build_decl (FIELD_DECL, get_identifier ("__gpr_top"),
4166 f_ftop = build_decl (FIELD_DECL, get_identifier ("__fpr_top"),
4168 f_goff = build_decl (FIELD_DECL, get_identifier ("__gpr_offset"),
4169 unsigned_char_type_node);
4170 f_foff = build_decl (FIELD_DECL, get_identifier ("__fpr_offset"),
4171 unsigned_char_type_node);
4172 /* Explicitly pad to the size of a pointer, so that -Wpadded won't
4173 warn on every user file. */
4174 index = build_int_cst (NULL_TREE, GET_MODE_SIZE (ptr_mode) - 2 - 1);
4175 array = build_array_type (unsigned_char_type_node,
4176 build_index_type (index));
4177 f_res = build_decl (FIELD_DECL, get_identifier ("__reserved"), array);
4179 DECL_FIELD_CONTEXT (f_ovfl) = record;
4180 DECL_FIELD_CONTEXT (f_gtop) = record;
4181 DECL_FIELD_CONTEXT (f_ftop) = record;
4182 DECL_FIELD_CONTEXT (f_goff) = record;
4183 DECL_FIELD_CONTEXT (f_foff) = record;
4184 DECL_FIELD_CONTEXT (f_res) = record;
4186 TYPE_FIELDS (record) = f_ovfl;
4187 TREE_CHAIN (f_ovfl) = f_gtop;
4188 TREE_CHAIN (f_gtop) = f_ftop;
4189 TREE_CHAIN (f_ftop) = f_goff;
4190 TREE_CHAIN (f_goff) = f_foff;
4191 TREE_CHAIN (f_foff) = f_res;
4193 layout_type (record);
4196 else if (TARGET_IRIX && TARGET_IRIX6)
4197 /* On IRIX 6, this type is 'char *'. */
4198 return build_pointer_type (char_type_node);
4200 /* Otherwise, we use 'void *'. */
4201 return ptr_type_node;
4204 /* Implement va_start. */
4207 mips_va_start (tree valist, rtx nextarg)
4209 if (EABI_FLOAT_VARARGS_P)
4211 const CUMULATIVE_ARGS *cum;
4212 tree f_ovfl, f_gtop, f_ftop, f_goff, f_foff;
4213 tree ovfl, gtop, ftop, goff, foff;
4215 int gpr_save_area_size;
4216 int fpr_save_area_size;
4219 cum = ¤t_function_args_info;
4221 = (MAX_ARGS_IN_REGISTERS - cum->num_gprs) * UNITS_PER_WORD;
4223 = (MAX_ARGS_IN_REGISTERS - cum->num_fprs) * UNITS_PER_FPREG;
4225 f_ovfl = TYPE_FIELDS (va_list_type_node);
4226 f_gtop = TREE_CHAIN (f_ovfl);
4227 f_ftop = TREE_CHAIN (f_gtop);
4228 f_goff = TREE_CHAIN (f_ftop);
4229 f_foff = TREE_CHAIN (f_goff);
4231 ovfl = build3 (COMPONENT_REF, TREE_TYPE (f_ovfl), valist, f_ovfl,
4233 gtop = build3 (COMPONENT_REF, TREE_TYPE (f_gtop), valist, f_gtop,
4235 ftop = build3 (COMPONENT_REF, TREE_TYPE (f_ftop), valist, f_ftop,
4237 goff = build3 (COMPONENT_REF, TREE_TYPE (f_goff), valist, f_goff,
4239 foff = build3 (COMPONENT_REF, TREE_TYPE (f_foff), valist, f_foff,
4242 /* Emit code to initialize OVFL, which points to the next varargs
4243 stack argument. CUM->STACK_WORDS gives the number of stack
4244 words used by named arguments. */
4245 t = make_tree (TREE_TYPE (ovfl), virtual_incoming_args_rtx);
4246 if (cum->stack_words > 0)
4247 t = build2 (PLUS_EXPR, TREE_TYPE (ovfl), t,
4248 build_int_cst (NULL_TREE,
4249 cum->stack_words * UNITS_PER_WORD));
4250 t = build2 (MODIFY_EXPR, TREE_TYPE (ovfl), ovfl, t);
4251 expand_expr (t, const0_rtx, VOIDmode, EXPAND_NORMAL);
4253 /* Emit code to initialize GTOP, the top of the GPR save area. */
4254 t = make_tree (TREE_TYPE (gtop), virtual_incoming_args_rtx);
4255 t = build2 (MODIFY_EXPR, TREE_TYPE (gtop), gtop, t);
4256 expand_expr (t, const0_rtx, VOIDmode, EXPAND_NORMAL);
4258 /* Emit code to initialize FTOP, the top of the FPR save area.
4259 This address is gpr_save_area_bytes below GTOP, rounded
4260 down to the next fp-aligned boundary. */
4261 t = make_tree (TREE_TYPE (ftop), virtual_incoming_args_rtx);
4262 fpr_offset = gpr_save_area_size + UNITS_PER_FPVALUE - 1;
4263 fpr_offset &= ~(UNITS_PER_FPVALUE - 1);
4265 t = build2 (PLUS_EXPR, TREE_TYPE (ftop), t,
4266 build_int_cst (NULL_TREE, -fpr_offset));
4267 t = build2 (MODIFY_EXPR, TREE_TYPE (ftop), ftop, t);
4268 expand_expr (t, const0_rtx, VOIDmode, EXPAND_NORMAL);
4270 /* Emit code to initialize GOFF, the offset from GTOP of the
4271 next GPR argument. */
4272 t = build2 (MODIFY_EXPR, TREE_TYPE (goff), goff,
4273 build_int_cst (NULL_TREE, gpr_save_area_size));
4274 expand_expr (t, const0_rtx, VOIDmode, EXPAND_NORMAL);
4276 /* Likewise emit code to initialize FOFF, the offset from FTOP
4277 of the next FPR argument. */
4278 t = build2 (MODIFY_EXPR, TREE_TYPE (foff), foff,
4279 build_int_cst (NULL_TREE, fpr_save_area_size));
4280 expand_expr (t, const0_rtx, VOIDmode, EXPAND_NORMAL);
4284 nextarg = plus_constant (nextarg, -cfun->machine->varargs_size);
4285 std_expand_builtin_va_start (valist, nextarg);
4289 /* Implement va_arg. */
4292 mips_gimplify_va_arg_expr (tree valist, tree type, tree *pre_p, tree *post_p)
4294 HOST_WIDE_INT size, rsize;
4298 indirect = pass_by_reference (NULL, TYPE_MODE (type), type, 0);
4301 type = build_pointer_type (type);
4303 size = int_size_in_bytes (type);
4304 rsize = (size + UNITS_PER_WORD - 1) & -UNITS_PER_WORD;
4306 if (mips_abi != ABI_EABI || !EABI_FLOAT_VARARGS_P)
4307 addr = std_gimplify_va_arg_expr (valist, type, pre_p, post_p);
4310 /* Not a simple merged stack. */
4312 tree f_ovfl, f_gtop, f_ftop, f_goff, f_foff;
4313 tree ovfl, top, off, align;
4314 HOST_WIDE_INT osize;
4317 f_ovfl = TYPE_FIELDS (va_list_type_node);
4318 f_gtop = TREE_CHAIN (f_ovfl);
4319 f_ftop = TREE_CHAIN (f_gtop);
4320 f_goff = TREE_CHAIN (f_ftop);
4321 f_foff = TREE_CHAIN (f_goff);
4323 /* We maintain separate pointers and offsets for floating-point
4324 and integer arguments, but we need similar code in both cases.
4327 TOP be the top of the register save area;
4328 OFF be the offset from TOP of the next register;
4329 ADDR_RTX be the address of the argument;
4330 RSIZE be the number of bytes used to store the argument
4331 when it's in the register save area;
4332 OSIZE be the number of bytes used to store it when it's
4333 in the stack overflow area; and
4334 PADDING be (BYTES_BIG_ENDIAN ? OSIZE - RSIZE : 0)
4336 The code we want is:
4338 1: off &= -rsize; // round down
4341 4: addr_rtx = top - off;
4346 9: ovfl += ((intptr_t) ovfl + osize - 1) & -osize;
4347 10: addr_rtx = ovfl + PADDING;
4351 [1] and [9] can sometimes be optimized away. */
4353 ovfl = build3 (COMPONENT_REF, TREE_TYPE (f_ovfl), valist, f_ovfl,
4356 if (GET_MODE_CLASS (TYPE_MODE (type)) == MODE_FLOAT
4357 && GET_MODE_SIZE (TYPE_MODE (type)) <= UNITS_PER_FPVALUE)
4359 top = build3 (COMPONENT_REF, TREE_TYPE (f_ftop), valist, f_ftop,
4361 off = build3 (COMPONENT_REF, TREE_TYPE (f_foff), valist, f_foff,
4364 /* When floating-point registers are saved to the stack,
4365 each one will take up UNITS_PER_HWFPVALUE bytes, regardless
4366 of the float's precision. */
4367 rsize = UNITS_PER_HWFPVALUE;
4369 /* Overflow arguments are padded to UNITS_PER_WORD bytes
4370 (= PARM_BOUNDARY bits). This can be different from RSIZE
4373 (1) On 32-bit targets when TYPE is a structure such as:
4375 struct s { float f; };
4377 Such structures are passed in paired FPRs, so RSIZE
4378 will be 8 bytes. However, the structure only takes
4379 up 4 bytes of memory, so OSIZE will only be 4.
4381 (2) In combinations such as -mgp64 -msingle-float
4382 -fshort-double. Doubles passed in registers
4383 will then take up 4 (UNITS_PER_HWFPVALUE) bytes,
4384 but those passed on the stack take up
4385 UNITS_PER_WORD bytes. */
4386 osize = MAX (GET_MODE_SIZE (TYPE_MODE (type)), UNITS_PER_WORD);
4390 top = build3 (COMPONENT_REF, TREE_TYPE (f_gtop), valist, f_gtop,
4392 off = build3 (COMPONENT_REF, TREE_TYPE (f_goff), valist, f_goff,
4394 if (rsize > UNITS_PER_WORD)
4396 /* [1] Emit code for: off &= -rsize. */
4397 t = build2 (BIT_AND_EXPR, TREE_TYPE (off), off,
4398 build_int_cst (NULL_TREE, -rsize));
4399 t = build2 (MODIFY_EXPR, TREE_TYPE (off), off, t);
4400 gimplify_and_add (t, pre_p);
4405 /* [2] Emit code to branch if off == 0. */
4406 t = build2 (NE_EXPR, boolean_type_node, off,
4407 build_int_cst (TREE_TYPE (off), 0));
4408 addr = build3 (COND_EXPR, ptr_type_node, t, NULL_TREE, NULL_TREE);
4410 /* [5] Emit code for: off -= rsize. We do this as a form of
4411 post-increment not available to C. Also widen for the
4412 coming pointer arithmetic. */
4413 t = fold_convert (TREE_TYPE (off), build_int_cst (NULL_TREE, rsize));
4414 t = build2 (POSTDECREMENT_EXPR, TREE_TYPE (off), off, t);
4415 t = fold_convert (sizetype, t);
4416 t = fold_convert (TREE_TYPE (top), t);
4418 /* [4] Emit code for: addr_rtx = top - off. On big endian machines,
4419 the argument has RSIZE - SIZE bytes of leading padding. */
4420 t = build2 (MINUS_EXPR, TREE_TYPE (top), top, t);
4421 if (BYTES_BIG_ENDIAN && rsize > size)
4423 u = fold_convert (TREE_TYPE (t), build_int_cst (NULL_TREE,
4425 t = build2 (PLUS_EXPR, TREE_TYPE (t), t, u);
4427 COND_EXPR_THEN (addr) = t;
4429 if (osize > UNITS_PER_WORD)
4431 /* [9] Emit: ovfl += ((intptr_t) ovfl + osize - 1) & -osize. */
4432 u = fold_convert (TREE_TYPE (ovfl),
4433 build_int_cst (NULL_TREE, osize - 1));
4434 t = build2 (PLUS_EXPR, TREE_TYPE (ovfl), ovfl, u);
4435 u = fold_convert (TREE_TYPE (ovfl),
4436 build_int_cst (NULL_TREE, -osize));
4437 t = build2 (BIT_AND_EXPR, TREE_TYPE (ovfl), t, u);
4438 align = build2 (MODIFY_EXPR, TREE_TYPE (ovfl), ovfl, t);
4443 /* [10, 11]. Emit code to store ovfl in addr_rtx, then
4444 post-increment ovfl by osize. On big-endian machines,
4445 the argument has OSIZE - SIZE bytes of leading padding. */
4446 u = fold_convert (TREE_TYPE (ovfl),
4447 build_int_cst (NULL_TREE, osize));
4448 t = build2 (POSTINCREMENT_EXPR, TREE_TYPE (ovfl), ovfl, u);
4449 if (BYTES_BIG_ENDIAN && osize > size)
4451 u = fold_convert (TREE_TYPE (t),
4452 build_int_cst (NULL_TREE, osize - size));
4453 t = build2 (PLUS_EXPR, TREE_TYPE (t), t, u);
4456 /* String [9] and [10,11] together. */
4458 t = build2 (COMPOUND_EXPR, TREE_TYPE (t), align, t);
4459 COND_EXPR_ELSE (addr) = t;
4461 addr = fold_convert (build_pointer_type (type), addr);
4462 addr = build_va_arg_indirect_ref (addr);
4466 addr = build_va_arg_indirect_ref (addr);
4471 /* Return true if it is possible to use left/right accesses for a
4472 bitfield of WIDTH bits starting BITPOS bits into *OP. When
4473 returning true, update *OP, *LEFT and *RIGHT as follows:
4475 *OP is a BLKmode reference to the whole field.
4477 *LEFT is a QImode reference to the first byte if big endian or
4478 the last byte if little endian. This address can be used in the
4479 left-side instructions (lwl, swl, ldl, sdl).
4481 *RIGHT is a QImode reference to the opposite end of the field and
4482 can be used in the patterning right-side instruction. */
4485 mips_get_unaligned_mem (rtx *op, unsigned int width, int bitpos,
4486 rtx *left, rtx *right)
4490 /* Check that the operand really is a MEM. Not all the extv and
4491 extzv predicates are checked. */
4495 /* Check that the size is valid. */
4496 if (width != 32 && (!TARGET_64BIT || width != 64))
4499 /* We can only access byte-aligned values. Since we are always passed
4500 a reference to the first byte of the field, it is not necessary to
4501 do anything with BITPOS after this check. */
4502 if (bitpos % BITS_PER_UNIT != 0)
4505 /* Reject aligned bitfields: we want to use a normal load or store
4506 instead of a left/right pair. */
4507 if (MEM_ALIGN (*op) >= width)
4510 /* Adjust *OP to refer to the whole field. This also has the effect
4511 of legitimizing *OP's address for BLKmode, possibly simplifying it. */
4512 *op = adjust_address (*op, BLKmode, 0);
4513 set_mem_size (*op, GEN_INT (width / BITS_PER_UNIT));
4515 /* Get references to both ends of the field. We deliberately don't
4516 use the original QImode *OP for FIRST since the new BLKmode one
4517 might have a simpler address. */
4518 first = adjust_address (*op, QImode, 0);
4519 last = adjust_address (*op, QImode, width / BITS_PER_UNIT - 1);
4521 /* Allocate to LEFT and RIGHT according to endianness. LEFT should
4522 be the upper word and RIGHT the lower word. */
4523 if (TARGET_BIG_ENDIAN)
4524 *left = first, *right = last;
4526 *left = last, *right = first;
4532 /* Try to emit the equivalent of (set DEST (zero_extract SRC WIDTH BITPOS)).
4533 Return true on success. We only handle cases where zero_extract is
4534 equivalent to sign_extract. */
4537 mips_expand_unaligned_load (rtx dest, rtx src, unsigned int width, int bitpos)
4539 rtx left, right, temp;
4541 /* If TARGET_64BIT, the destination of a 32-bit load will be a
4542 paradoxical word_mode subreg. This is the only case in which
4543 we allow the destination to be larger than the source. */
4544 if (GET_CODE (dest) == SUBREG
4545 && GET_MODE (dest) == DImode
4546 && SUBREG_BYTE (dest) == 0
4547 && GET_MODE (SUBREG_REG (dest)) == SImode)
4548 dest = SUBREG_REG (dest);
4550 /* After the above adjustment, the destination must be the same
4551 width as the source. */
4552 if (GET_MODE_BITSIZE (GET_MODE (dest)) != width)
4555 if (!mips_get_unaligned_mem (&src, width, bitpos, &left, &right))
4558 temp = gen_reg_rtx (GET_MODE (dest));
4559 if (GET_MODE (dest) == DImode)
4561 emit_insn (gen_mov_ldl (temp, src, left));
4562 emit_insn (gen_mov_ldr (dest, copy_rtx (src), right, temp));
4566 emit_insn (gen_mov_lwl (temp, src, left));
4567 emit_insn (gen_mov_lwr (dest, copy_rtx (src), right, temp));
4573 /* Try to expand (set (zero_extract DEST WIDTH BITPOS) SRC). Return
4577 mips_expand_unaligned_store (rtx dest, rtx src, unsigned int width, int bitpos)
4580 enum machine_mode mode;
4582 if (!mips_get_unaligned_mem (&dest, width, bitpos, &left, &right))
4585 mode = mode_for_size (width, MODE_INT, 0);
4586 src = gen_lowpart (mode, src);
4590 emit_insn (gen_mov_sdl (dest, src, left));
4591 emit_insn (gen_mov_sdr (copy_rtx (dest), copy_rtx (src), right));
4595 emit_insn (gen_mov_swl (dest, src, left));
4596 emit_insn (gen_mov_swr (copy_rtx (dest), copy_rtx (src), right));
4601 /* Return true if X is a MEM with the same size as MODE. */
4604 mips_mem_fits_mode_p (enum machine_mode mode, rtx x)
4611 size = MEM_SIZE (x);
4612 return size && INTVAL (size) == GET_MODE_SIZE (mode);
4615 /* Return true if (zero_extract OP SIZE POSITION) can be used as the
4616 source of an "ext" instruction or the destination of an "ins"
4617 instruction. OP must be a register operand and the following
4618 conditions must hold:
4620 0 <= POSITION < GET_MODE_BITSIZE (GET_MODE (op))
4621 0 < SIZE <= GET_MODE_BITSIZE (GET_MODE (op))
4622 0 < POSITION + SIZE <= GET_MODE_BITSIZE (GET_MODE (op))
4624 Also reject lengths equal to a word as they are better handled
4625 by the move patterns. */
4628 mips_use_ins_ext_p (rtx op, rtx size, rtx position)
4630 HOST_WIDE_INT len, pos;
4632 if (!ISA_HAS_EXT_INS
4633 || !register_operand (op, VOIDmode)
4634 || GET_MODE_BITSIZE (GET_MODE (op)) > BITS_PER_WORD)
4637 len = INTVAL (size);
4638 pos = INTVAL (position);
4640 if (len <= 0 || len >= GET_MODE_BITSIZE (GET_MODE (op))
4641 || pos < 0 || pos + len > GET_MODE_BITSIZE (GET_MODE (op)))
4647 /* Set up globals to generate code for the ISA or processor
4648 described by INFO. */
4651 mips_set_architecture (const struct mips_cpu_info *info)
4655 mips_arch_info = info;
4656 mips_arch = info->cpu;
4657 mips_isa = info->isa;
4662 /* Likewise for tuning. */
4665 mips_set_tune (const struct mips_cpu_info *info)
4669 mips_tune_info = info;
4670 mips_tune = info->cpu;
4674 /* Implement TARGET_HANDLE_OPTION. */
4677 mips_handle_option (size_t code, const char *arg, int value ATTRIBUTE_UNUSED)
4682 if (strcmp (arg, "32") == 0)
4684 else if (strcmp (arg, "o64") == 0)
4686 else if (strcmp (arg, "n32") == 0)
4688 else if (strcmp (arg, "64") == 0)
4690 else if (strcmp (arg, "eabi") == 0)
4691 mips_abi = ABI_EABI;
4698 return mips_parse_cpu (arg) != 0;
4701 mips_isa_info = mips_parse_cpu (ACONCAT (("mips", arg, NULL)));
4702 return mips_isa_info != 0;
4704 case OPT_mno_flush_func:
4705 mips_cache_flush_func = NULL;
4713 /* Set up the threshold for data to go into the small data area, instead
4714 of the normal data area, and detect any conflicts in the switches. */
4717 override_options (void)
4719 int i, start, regno;
4720 enum machine_mode mode;
4722 mips_section_threshold = g_switch_set ? g_switch_value : MIPS_DEFAULT_GVALUE;
4724 /* The following code determines the architecture and register size.
4725 Similar code was added to GAS 2.14 (see tc-mips.c:md_after_parse_args()).
4726 The GAS and GCC code should be kept in sync as much as possible. */
4728 if (mips_arch_string != 0)
4729 mips_set_architecture (mips_parse_cpu (mips_arch_string));
4731 if (mips_isa_info != 0)
4733 if (mips_arch_info == 0)
4734 mips_set_architecture (mips_isa_info);
4735 else if (mips_arch_info->isa != mips_isa_info->isa)
4736 error ("-%s conflicts with the other architecture options, "
4737 "which specify a %s processor",
4738 mips_isa_info->name,
4739 mips_cpu_info_from_isa (mips_arch_info->isa)->name);
4742 if (mips_arch_info == 0)
4744 #ifdef MIPS_CPU_STRING_DEFAULT
4745 mips_set_architecture (mips_parse_cpu (MIPS_CPU_STRING_DEFAULT));
4747 mips_set_architecture (mips_cpu_info_from_isa (MIPS_ISA_DEFAULT));
4751 if (ABI_NEEDS_64BIT_REGS && !ISA_HAS_64BIT_REGS)
4752 error ("-march=%s is not compatible with the selected ABI",
4753 mips_arch_info->name);
4755 /* Optimize for mips_arch, unless -mtune selects a different processor. */
4756 if (mips_tune_string != 0)
4757 mips_set_tune (mips_parse_cpu (mips_tune_string));
4759 if (mips_tune_info == 0)
4760 mips_set_tune (mips_arch_info);
4762 /* Set cost structure for the processor. */
4763 mips_cost = &mips_rtx_cost_data[mips_tune];
4765 if ((target_flags_explicit & MASK_64BIT) != 0)
4767 /* The user specified the size of the integer registers. Make sure
4768 it agrees with the ABI and ISA. */
4769 if (TARGET_64BIT && !ISA_HAS_64BIT_REGS)
4770 error ("-mgp64 used with a 32-bit processor");
4771 else if (!TARGET_64BIT && ABI_NEEDS_64BIT_REGS)
4772 error ("-mgp32 used with a 64-bit ABI");
4773 else if (TARGET_64BIT && ABI_NEEDS_32BIT_REGS)
4774 error ("-mgp64 used with a 32-bit ABI");
4778 /* Infer the integer register size from the ABI and processor.
4779 Restrict ourselves to 32-bit registers if that's all the
4780 processor has, or if the ABI cannot handle 64-bit registers. */
4781 if (ABI_NEEDS_32BIT_REGS || !ISA_HAS_64BIT_REGS)
4782 target_flags &= ~MASK_64BIT;
4784 target_flags |= MASK_64BIT;
4787 if ((target_flags_explicit & MASK_FLOAT64) != 0)
4789 /* Really, -mfp32 and -mfp64 are ornamental options. There's
4790 only one right answer here. */
4791 if (TARGET_64BIT && TARGET_DOUBLE_FLOAT && !TARGET_FLOAT64)
4792 error ("unsupported combination: %s", "-mgp64 -mfp32 -mdouble-float");
4793 else if (!TARGET_64BIT && TARGET_FLOAT64)
4794 error ("unsupported combination: %s", "-mgp32 -mfp64");
4795 else if (TARGET_SINGLE_FLOAT && TARGET_FLOAT64)
4796 error ("unsupported combination: %s", "-mfp64 -msingle-float");
4800 /* -msingle-float selects 32-bit float registers. Otherwise the
4801 float registers should be the same size as the integer ones. */
4802 if (TARGET_64BIT && TARGET_DOUBLE_FLOAT)
4803 target_flags |= MASK_FLOAT64;
4805 target_flags &= ~MASK_FLOAT64;
4808 /* End of code shared with GAS. */
4810 if ((target_flags_explicit & MASK_LONG64) == 0)
4812 if ((mips_abi == ABI_EABI && TARGET_64BIT) || mips_abi == ABI_64)
4813 target_flags |= MASK_LONG64;
4815 target_flags &= ~MASK_LONG64;
4818 if (MIPS_MARCH_CONTROLS_SOFT_FLOAT
4819 && (target_flags_explicit & MASK_SOFT_FLOAT) == 0)
4821 /* For some configurations, it is useful to have -march control
4822 the default setting of MASK_SOFT_FLOAT. */
4823 switch ((int) mips_arch)
4825 case PROCESSOR_R4100:
4826 case PROCESSOR_R4111:
4827 case PROCESSOR_R4120:
4828 case PROCESSOR_R4130:
4829 target_flags |= MASK_SOFT_FLOAT;
4833 target_flags &= ~MASK_SOFT_FLOAT;
4839 flag_pcc_struct_return = 0;
4841 if ((target_flags_explicit & MASK_BRANCHLIKELY) == 0)
4843 /* If neither -mbranch-likely nor -mno-branch-likely was given
4844 on the command line, set MASK_BRANCHLIKELY based on the target
4847 By default, we enable use of Branch Likely instructions on
4848 all architectures which support them with the following
4849 exceptions: when creating MIPS32 or MIPS64 code, and when
4850 tuning for architectures where their use tends to hurt
4853 The MIPS32 and MIPS64 architecture specifications say "Software
4854 is strongly encouraged to avoid use of Branch Likely
4855 instructions, as they will be removed from a future revision
4856 of the [MIPS32 and MIPS64] architecture." Therefore, we do not
4857 issue those instructions unless instructed to do so by
4859 if (ISA_HAS_BRANCHLIKELY
4860 && !(ISA_MIPS32 || ISA_MIPS32R2 || ISA_MIPS64 || ISA_MIPS64R2)
4861 && !(TUNE_MIPS5500 || TUNE_SB1))
4862 target_flags |= MASK_BRANCHLIKELY;
4864 target_flags &= ~MASK_BRANCHLIKELY;
4866 if (TARGET_BRANCHLIKELY && !ISA_HAS_BRANCHLIKELY)
4867 warning (0, "generation of Branch Likely instructions enabled, but not supported by architecture");
4869 /* The effect of -mabicalls isn't defined for the EABI. */
4870 if (mips_abi == ABI_EABI && TARGET_ABICALLS)
4872 error ("unsupported combination: %s", "-mabicalls -mabi=eabi");
4873 target_flags &= ~MASK_ABICALLS;
4876 if (TARGET_ABICALLS)
4878 /* We need to set flag_pic for executables as well as DSOs
4879 because we may reference symbols that are not defined in
4880 the final executable. (MIPS does not use things like
4881 copy relocs, for example.)
4883 Also, there is a body of code that uses __PIC__ to distinguish
4884 between -mabicalls and -mno-abicalls code. */
4886 if (mips_section_threshold > 0)
4887 warning (0, "%<-G%> is incompatible with %<-mabicalls%>");
4890 /* mips_split_addresses is a half-way house between explicit
4891 relocations and the traditional assembler macros. It can
4892 split absolute 32-bit symbolic constants into a high/lo_sum
4893 pair but uses macros for other sorts of access.
4895 Like explicit relocation support for REL targets, it relies
4896 on GNU extensions in the assembler and the linker.
4898 Although this code should work for -O0, it has traditionally
4899 been treated as an optimization. */
4900 if (!TARGET_MIPS16 && TARGET_SPLIT_ADDRESSES
4901 && optimize && !flag_pic
4902 && !ABI_HAS_64BIT_SYMBOLS)
4903 mips_split_addresses = 1;
4905 mips_split_addresses = 0;
4907 /* -mvr4130-align is a "speed over size" optimization: it usually produces
4908 faster code, but at the expense of more nops. Enable it at -O3 and
4910 if (optimize > 2 && (target_flags_explicit & MASK_VR4130_ALIGN) == 0)
4911 target_flags |= MASK_VR4130_ALIGN;
4913 /* When compiling for the mips16, we cannot use floating point. We
4914 record the original hard float value in mips16_hard_float. */
4917 if (TARGET_SOFT_FLOAT)
4918 mips16_hard_float = 0;
4920 mips16_hard_float = 1;
4921 target_flags |= MASK_SOFT_FLOAT;
4923 /* Don't run the scheduler before reload, since it tends to
4924 increase register pressure. */
4925 flag_schedule_insns = 0;
4927 /* Don't do hot/cold partitioning. The constant layout code expects
4928 the whole function to be in a single section. */
4929 flag_reorder_blocks_and_partition = 0;
4931 /* Silently disable -mexplicit-relocs since it doesn't apply
4932 to mips16 code. Even so, it would overly pedantic to warn
4933 about "-mips16 -mexplicit-relocs", especially given that
4934 we use a %gprel() operator. */
4935 target_flags &= ~MASK_EXPLICIT_RELOCS;
4938 /* When using explicit relocs, we call dbr_schedule from within
4940 if (TARGET_EXPLICIT_RELOCS)
4942 mips_flag_delayed_branch = flag_delayed_branch;
4943 flag_delayed_branch = 0;
4946 #ifdef MIPS_TFMODE_FORMAT
4947 REAL_MODE_FORMAT (TFmode) = &MIPS_TFMODE_FORMAT;
4950 /* Make sure that the user didn't turn off paired single support when
4951 MIPS-3D support is requested. */
4952 if (TARGET_MIPS3D && (target_flags_explicit & MASK_PAIRED_SINGLE_FLOAT)
4953 && !TARGET_PAIRED_SINGLE_FLOAT)
4954 error ("-mips3d requires -mpaired-single");
4956 /* If TARGET_MIPS3D, enable MASK_PAIRED_SINGLE_FLOAT. */
4958 target_flags |= MASK_PAIRED_SINGLE_FLOAT;
4960 /* Make sure that when TARGET_PAIRED_SINGLE_FLOAT is true, TARGET_FLOAT64
4961 and TARGET_HARD_FLOAT are both true. */
4962 if (TARGET_PAIRED_SINGLE_FLOAT && !(TARGET_FLOAT64 && TARGET_HARD_FLOAT))
4963 error ("-mips3d/-mpaired-single must be used with -mfp64 -mhard-float");
4965 /* Make sure that the ISA supports TARGET_PAIRED_SINGLE_FLOAT when it is
4967 if (TARGET_PAIRED_SINGLE_FLOAT && !ISA_MIPS64)
4968 error ("-mips3d/-mpaired-single must be used with -mips64");
4970 if (TARGET_MIPS16 && TARGET_DSP)
4971 error ("-mips16 and -mdsp cannot be used together");
4973 mips_print_operand_punct['?'] = 1;
4974 mips_print_operand_punct['#'] = 1;
4975 mips_print_operand_punct['/'] = 1;
4976 mips_print_operand_punct['&'] = 1;
4977 mips_print_operand_punct['!'] = 1;
4978 mips_print_operand_punct['*'] = 1;
4979 mips_print_operand_punct['@'] = 1;
4980 mips_print_operand_punct['.'] = 1;
4981 mips_print_operand_punct['('] = 1;
4982 mips_print_operand_punct[')'] = 1;
4983 mips_print_operand_punct['['] = 1;
4984 mips_print_operand_punct[']'] = 1;
4985 mips_print_operand_punct['<'] = 1;
4986 mips_print_operand_punct['>'] = 1;
4987 mips_print_operand_punct['{'] = 1;
4988 mips_print_operand_punct['}'] = 1;
4989 mips_print_operand_punct['^'] = 1;
4990 mips_print_operand_punct['$'] = 1;
4991 mips_print_operand_punct['+'] = 1;
4992 mips_print_operand_punct['~'] = 1;
4994 /* Set up array to map GCC register number to debug register number.
4995 Ignore the special purpose register numbers. */
4997 for (i = 0; i < FIRST_PSEUDO_REGISTER; i++)
4998 mips_dbx_regno[i] = -1;
5000 start = GP_DBX_FIRST - GP_REG_FIRST;
5001 for (i = GP_REG_FIRST; i <= GP_REG_LAST; i++)
5002 mips_dbx_regno[i] = i + start;
5004 start = FP_DBX_FIRST - FP_REG_FIRST;
5005 for (i = FP_REG_FIRST; i <= FP_REG_LAST; i++)
5006 mips_dbx_regno[i] = i + start;
5008 mips_dbx_regno[HI_REGNUM] = MD_DBX_FIRST + 0;
5009 mips_dbx_regno[LO_REGNUM] = MD_DBX_FIRST + 1;
5011 /* Set up array giving whether a given register can hold a given mode. */
5013 for (mode = VOIDmode;
5014 mode != MAX_MACHINE_MODE;
5015 mode = (enum machine_mode) ((int)mode + 1))
5017 register int size = GET_MODE_SIZE (mode);
5018 register enum mode_class class = GET_MODE_CLASS (mode);
5020 for (regno = 0; regno < FIRST_PSEUDO_REGISTER; regno++)
5024 if (mode == CCV2mode)
5027 && (regno - ST_REG_FIRST) % 2 == 0);
5029 else if (mode == CCV4mode)
5032 && (regno - ST_REG_FIRST) % 4 == 0);
5034 else if (mode == CCmode)
5037 temp = (regno == FPSW_REGNUM);
5039 temp = (ST_REG_P (regno) || GP_REG_P (regno)
5040 || FP_REG_P (regno));
5043 else if (GP_REG_P (regno))
5044 temp = ((regno & 1) == 0 || size <= UNITS_PER_WORD);
5046 else if (FP_REG_P (regno))
5047 temp = ((regno % FP_INC) == 0)
5048 && (((class == MODE_FLOAT || class == MODE_COMPLEX_FLOAT
5049 || class == MODE_VECTOR_FLOAT)
5050 && size <= UNITS_PER_FPVALUE)
5051 /* Allow integer modes that fit into a single
5052 register. We need to put integers into FPRs
5053 when using instructions like cvt and trunc.
5054 We can't allow sizes smaller than a word,
5055 the FPU has no appropriate load/store
5056 instructions for those. */
5057 || (class == MODE_INT
5058 && size >= MIN_UNITS_PER_WORD
5059 && size <= UNITS_PER_FPREG)
5060 /* Allow TFmode for CCmode reloads. */
5061 || (ISA_HAS_8CC && mode == TFmode));
5063 else if (ACC_REG_P (regno))
5064 temp = (INTEGRAL_MODE_P (mode)
5065 && (size <= UNITS_PER_WORD
5066 || (ACC_HI_REG_P (regno)
5067 && size == 2 * UNITS_PER_WORD)));
5069 else if (ALL_COP_REG_P (regno))
5070 temp = (class == MODE_INT && size <= UNITS_PER_WORD);
5074 mips_hard_regno_mode_ok[(int)mode][regno] = temp;
5078 /* Save GPR registers in word_mode sized hunks. word_mode hasn't been
5079 initialized yet, so we can't use that here. */
5080 gpr_mode = TARGET_64BIT ? DImode : SImode;
5082 /* Provide default values for align_* for 64-bit targets. */
5083 if (TARGET_64BIT && !TARGET_MIPS16)
5085 if (align_loops == 0)
5087 if (align_jumps == 0)
5089 if (align_functions == 0)
5090 align_functions = 8;
5093 /* Function to allocate machine-dependent function status. */
5094 init_machine_status = &mips_init_machine_status;
5096 if (ABI_HAS_64BIT_SYMBOLS)
5098 if (TARGET_EXPLICIT_RELOCS)
5100 mips_split_p[SYMBOL_64_HIGH] = true;
5101 mips_hi_relocs[SYMBOL_64_HIGH] = "%highest(";
5102 mips_lo_relocs[SYMBOL_64_HIGH] = "%higher(";
5104 mips_split_p[SYMBOL_64_MID] = true;
5105 mips_hi_relocs[SYMBOL_64_MID] = "%higher(";
5106 mips_lo_relocs[SYMBOL_64_MID] = "%hi(";
5108 mips_split_p[SYMBOL_64_LOW] = true;
5109 mips_hi_relocs[SYMBOL_64_LOW] = "%hi(";
5110 mips_lo_relocs[SYMBOL_64_LOW] = "%lo(";
5112 mips_split_p[SYMBOL_GENERAL] = true;
5113 mips_lo_relocs[SYMBOL_GENERAL] = "%lo(";
5118 if (TARGET_EXPLICIT_RELOCS || mips_split_addresses)
5120 mips_split_p[SYMBOL_GENERAL] = true;
5121 mips_hi_relocs[SYMBOL_GENERAL] = "%hi(";
5122 mips_lo_relocs[SYMBOL_GENERAL] = "%lo(";
5128 /* The high part is provided by a pseudo copy of $gp. */
5129 mips_split_p[SYMBOL_SMALL_DATA] = true;
5130 mips_lo_relocs[SYMBOL_SMALL_DATA] = "%gprel(";
5133 if (TARGET_EXPLICIT_RELOCS)
5135 /* Small data constants are kept whole until after reload,
5136 then lowered by mips_rewrite_small_data. */
5137 mips_lo_relocs[SYMBOL_SMALL_DATA] = "%gp_rel(";
5139 mips_split_p[SYMBOL_GOT_LOCAL] = true;
5142 mips_lo_relocs[SYMBOL_GOTOFF_PAGE] = "%got_page(";
5143 mips_lo_relocs[SYMBOL_GOT_LOCAL] = "%got_ofst(";
5147 mips_lo_relocs[SYMBOL_GOTOFF_PAGE] = "%got(";
5148 mips_lo_relocs[SYMBOL_GOT_LOCAL] = "%lo(";
5153 /* The HIGH and LO_SUM are matched by special .md patterns. */
5154 mips_split_p[SYMBOL_GOT_GLOBAL] = true;
5156 mips_split_p[SYMBOL_GOTOFF_GLOBAL] = true;
5157 mips_hi_relocs[SYMBOL_GOTOFF_GLOBAL] = "%got_hi(";
5158 mips_lo_relocs[SYMBOL_GOTOFF_GLOBAL] = "%got_lo(";
5160 mips_split_p[SYMBOL_GOTOFF_CALL] = true;
5161 mips_hi_relocs[SYMBOL_GOTOFF_CALL] = "%call_hi(";
5162 mips_lo_relocs[SYMBOL_GOTOFF_CALL] = "%call_lo(";
5167 mips_lo_relocs[SYMBOL_GOTOFF_GLOBAL] = "%got_disp(";
5169 mips_lo_relocs[SYMBOL_GOTOFF_GLOBAL] = "%got(";
5170 mips_lo_relocs[SYMBOL_GOTOFF_CALL] = "%call16(";
5176 mips_split_p[SYMBOL_GOTOFF_LOADGP] = true;
5177 mips_hi_relocs[SYMBOL_GOTOFF_LOADGP] = "%hi(%neg(%gp_rel(";
5178 mips_lo_relocs[SYMBOL_GOTOFF_LOADGP] = "%lo(%neg(%gp_rel(";
5181 /* Thread-local relocation operators. */
5182 mips_lo_relocs[SYMBOL_TLSGD] = "%tlsgd(";
5183 mips_lo_relocs[SYMBOL_TLSLDM] = "%tlsldm(";
5184 mips_split_p[SYMBOL_DTPREL] = 1;
5185 mips_hi_relocs[SYMBOL_DTPREL] = "%dtprel_hi(";
5186 mips_lo_relocs[SYMBOL_DTPREL] = "%dtprel_lo(";
5187 mips_lo_relocs[SYMBOL_GOTTPREL] = "%gottprel(";
5188 mips_split_p[SYMBOL_TPREL] = 1;
5189 mips_hi_relocs[SYMBOL_TPREL] = "%tprel_hi(";
5190 mips_lo_relocs[SYMBOL_TPREL] = "%tprel_lo(";
5192 /* We don't have a thread pointer access instruction on MIPS16, or
5193 appropriate TLS relocations. */
5195 targetm.have_tls = false;
5197 /* Default to working around R4000 errata only if the processor
5198 was selected explicitly. */
5199 if ((target_flags_explicit & MASK_FIX_R4000) == 0
5200 && mips_matching_cpu_name_p (mips_arch_info->name, "r4000"))
5201 target_flags |= MASK_FIX_R4000;
5203 /* Default to working around R4400 errata only if the processor
5204 was selected explicitly. */
5205 if ((target_flags_explicit & MASK_FIX_R4400) == 0
5206 && mips_matching_cpu_name_p (mips_arch_info->name, "r4400"))
5207 target_flags |= MASK_FIX_R4400;
5210 /* Implement CONDITIONAL_REGISTER_USAGE. */
5213 mips_conditional_register_usage (void)
5219 for (regno = DSP_ACC_REG_FIRST; regno <= DSP_ACC_REG_LAST; regno++)
5220 fixed_regs[regno] = call_used_regs[regno] = 1;
5222 if (!TARGET_HARD_FLOAT)
5226 for (regno = FP_REG_FIRST; regno <= FP_REG_LAST; regno++)
5227 fixed_regs[regno] = call_used_regs[regno] = 1;
5228 for (regno = ST_REG_FIRST; regno <= ST_REG_LAST; regno++)
5229 fixed_regs[regno] = call_used_regs[regno] = 1;
5231 else if (! ISA_HAS_8CC)
5235 /* We only have a single condition code register. We
5236 implement this by hiding all the condition code registers,
5237 and generating RTL that refers directly to ST_REG_FIRST. */
5238 for (regno = ST_REG_FIRST; regno <= ST_REG_LAST; regno++)
5239 fixed_regs[regno] = call_used_regs[regno] = 1;
5241 /* In mips16 mode, we permit the $t temporary registers to be used
5242 for reload. We prohibit the unused $s registers, since they
5243 are caller saved, and saving them via a mips16 register would
5244 probably waste more time than just reloading the value. */
5247 fixed_regs[18] = call_used_regs[18] = 1;
5248 fixed_regs[19] = call_used_regs[19] = 1;
5249 fixed_regs[20] = call_used_regs[20] = 1;
5250 fixed_regs[21] = call_used_regs[21] = 1;
5251 fixed_regs[22] = call_used_regs[22] = 1;
5252 fixed_regs[23] = call_used_regs[23] = 1;
5253 fixed_regs[26] = call_used_regs[26] = 1;
5254 fixed_regs[27] = call_used_regs[27] = 1;
5255 fixed_regs[30] = call_used_regs[30] = 1;
5257 /* fp20-23 are now caller saved. */
5258 if (mips_abi == ABI_64)
5261 for (regno = FP_REG_FIRST + 20; regno < FP_REG_FIRST + 24; regno++)
5262 call_really_used_regs[regno] = call_used_regs[regno] = 1;
5264 /* Odd registers from fp21 to fp31 are now caller saved. */
5265 if (mips_abi == ABI_N32)
5268 for (regno = FP_REG_FIRST + 21; regno <= FP_REG_FIRST + 31; regno+=2)
5269 call_really_used_regs[regno] = call_used_regs[regno] = 1;
5273 /* Allocate a chunk of memory for per-function machine-dependent data. */
5274 static struct machine_function *
5275 mips_init_machine_status (void)
5277 return ((struct machine_function *)
5278 ggc_alloc_cleared (sizeof (struct machine_function)));
5281 /* On the mips16, we want to allocate $24 (T_REG) before other
5282 registers for instructions for which it is possible. This helps
5283 avoid shuffling registers around in order to set up for an xor,
5284 encouraging the compiler to use a cmp instead. */
5287 mips_order_regs_for_local_alloc (void)
5291 for (i = 0; i < FIRST_PSEUDO_REGISTER; i++)
5292 reg_alloc_order[i] = i;
5296 /* It really doesn't matter where we put register 0, since it is
5297 a fixed register anyhow. */
5298 reg_alloc_order[0] = 24;
5299 reg_alloc_order[24] = 0;
5304 /* The MIPS debug format wants all automatic variables and arguments
5305 to be in terms of the virtual frame pointer (stack pointer before
5306 any adjustment in the function), while the MIPS 3.0 linker wants
5307 the frame pointer to be the stack pointer after the initial
5308 adjustment. So, we do the adjustment here. The arg pointer (which
5309 is eliminated) points to the virtual frame pointer, while the frame
5310 pointer (which may be eliminated) points to the stack pointer after
5311 the initial adjustments. */
5314 mips_debugger_offset (rtx addr, HOST_WIDE_INT offset)
5316 rtx offset2 = const0_rtx;
5317 rtx reg = eliminate_constant_term (addr, &offset2);
5320 offset = INTVAL (offset2);
5322 if (reg == stack_pointer_rtx || reg == frame_pointer_rtx
5323 || reg == hard_frame_pointer_rtx)
5325 HOST_WIDE_INT frame_size = (!cfun->machine->frame.initialized)
5326 ? compute_frame_size (get_frame_size ())
5327 : cfun->machine->frame.total_size;
5329 /* MIPS16 frame is smaller */
5330 if (frame_pointer_needed && TARGET_MIPS16)
5331 frame_size -= cfun->machine->frame.args_size;
5333 offset = offset - frame_size;
5336 /* sdbout_parms does not want this to crash for unrecognized cases. */
5338 else if (reg != arg_pointer_rtx)
5339 fatal_insn ("mips_debugger_offset called with non stack/frame/arg pointer",
5346 /* Implement the PRINT_OPERAND macro. The MIPS-specific operand codes are:
5348 'X' OP is CONST_INT, prints 32 bits in hexadecimal format = "0x%08x",
5349 'x' OP is CONST_INT, prints 16 bits in hexadecimal format = "0x%04x",
5350 'h' OP is HIGH, prints %hi(X),
5351 'd' output integer constant in decimal,
5352 'z' if the operand is 0, use $0 instead of normal operand.
5353 'D' print second part of double-word register or memory operand.
5354 'L' print low-order register of double-word register operand.
5355 'M' print high-order register of double-word register operand.
5356 'C' print part of opcode for a branch condition.
5357 'F' print part of opcode for a floating-point branch condition.
5358 'N' print part of opcode for a branch condition, inverted.
5359 'W' print part of opcode for a floating-point branch condition, inverted.
5360 'T' print 'f' for (eq:CC ...), 't' for (ne:CC ...),
5361 'z' for (eq:?I ...), 'n' for (ne:?I ...).
5362 't' like 'T', but with the EQ/NE cases reversed
5363 'Y' for a CONST_INT X, print mips_fp_conditions[X]
5364 'Z' print the operand and a comma for ISA_HAS_8CC, otherwise print nothing
5365 'R' print the reloc associated with LO_SUM
5366 'q' print DSP accumulator registers
5368 The punctuation characters are:
5370 '(' Turn on .set noreorder
5371 ')' Turn on .set reorder
5372 '[' Turn on .set noat
5374 '<' Turn on .set nomacro
5375 '>' Turn on .set macro
5376 '{' Turn on .set volatile (not GAS)
5377 '}' Turn on .set novolatile (not GAS)
5378 '&' Turn on .set noreorder if filling delay slots
5379 '*' Turn on both .set noreorder and .set nomacro if filling delay slots
5380 '!' Turn on .set nomacro if filling delay slots
5381 '#' Print nop if in a .set noreorder section.
5382 '/' Like '#', but does nothing within a delayed branch sequence
5383 '?' Print 'l' if we are to use a branch likely instead of normal branch.
5384 '@' Print the name of the assembler temporary register (at or $1).
5385 '.' Print the name of the register with a hard-wired zero (zero or $0).
5386 '^' Print the name of the pic call-through register (t9 or $25).
5387 '$' Print the name of the stack pointer register (sp or $29).
5388 '+' Print the name of the gp register (usually gp or $28).
5389 '~' Output a branch alignment to LABEL_ALIGN(NULL). */
5392 print_operand (FILE *file, rtx op, int letter)
5394 register enum rtx_code code;
5396 if (PRINT_OPERAND_PUNCT_VALID_P (letter))
5401 if (mips_branch_likely)
5406 fputs (reg_names [GP_REG_FIRST + 1], file);
5410 fputs (reg_names [PIC_FUNCTION_ADDR_REGNUM], file);
5414 fputs (reg_names [GP_REG_FIRST + 0], file);
5418 fputs (reg_names[STACK_POINTER_REGNUM], file);
5422 fputs (reg_names[PIC_OFFSET_TABLE_REGNUM], file);
5426 if (final_sequence != 0 && set_noreorder++ == 0)
5427 fputs (".set\tnoreorder\n\t", file);
5431 if (final_sequence != 0)
5433 if (set_noreorder++ == 0)
5434 fputs (".set\tnoreorder\n\t", file);
5436 if (set_nomacro++ == 0)
5437 fputs (".set\tnomacro\n\t", file);
5442 if (final_sequence != 0 && set_nomacro++ == 0)
5443 fputs ("\n\t.set\tnomacro", file);
5447 if (set_noreorder != 0)
5448 fputs ("\n\tnop", file);
5452 /* Print an extra newline so that the delayed insn is separated
5453 from the following ones. This looks neater and is consistent
5454 with non-nop delayed sequences. */
5455 if (set_noreorder != 0 && final_sequence == 0)
5456 fputs ("\n\tnop\n", file);
5460 if (set_noreorder++ == 0)
5461 fputs (".set\tnoreorder\n\t", file);
5465 if (set_noreorder == 0)
5466 error ("internal error: %%) found without a %%( in assembler pattern");
5468 else if (--set_noreorder == 0)
5469 fputs ("\n\t.set\treorder", file);
5474 if (set_noat++ == 0)
5475 fputs (".set\tnoat\n\t", file);
5480 error ("internal error: %%] found without a %%[ in assembler pattern");
5481 else if (--set_noat == 0)
5482 fputs ("\n\t.set\tat", file);
5487 if (set_nomacro++ == 0)
5488 fputs (".set\tnomacro\n\t", file);
5492 if (set_nomacro == 0)
5493 error ("internal error: %%> found without a %%< in assembler pattern");
5494 else if (--set_nomacro == 0)
5495 fputs ("\n\t.set\tmacro", file);
5500 if (set_volatile++ == 0)
5501 fputs ("#.set\tvolatile\n\t", file);
5505 if (set_volatile == 0)
5506 error ("internal error: %%} found without a %%{ in assembler pattern");
5507 else if (--set_volatile == 0)
5508 fputs ("\n\t#.set\tnovolatile", file);
5514 if (align_labels_log > 0)
5515 ASM_OUTPUT_ALIGN (file, align_labels_log);
5520 error ("PRINT_OPERAND: unknown punctuation '%c'", letter);
5529 error ("PRINT_OPERAND null pointer");
5533 code = GET_CODE (op);
5538 case EQ: fputs ("eq", file); break;
5539 case NE: fputs ("ne", file); break;
5540 case GT: fputs ("gt", file); break;
5541 case GE: fputs ("ge", file); break;
5542 case LT: fputs ("lt", file); break;
5543 case LE: fputs ("le", file); break;
5544 case GTU: fputs ("gtu", file); break;
5545 case GEU: fputs ("geu", file); break;
5546 case LTU: fputs ("ltu", file); break;
5547 case LEU: fputs ("leu", file); break;
5549 fatal_insn ("PRINT_OPERAND, invalid insn for %%C", op);
5552 else if (letter == 'N')
5555 case EQ: fputs ("ne", file); break;
5556 case NE: fputs ("eq", file); break;
5557 case GT: fputs ("le", file); break;
5558 case GE: fputs ("lt", file); break;
5559 case LT: fputs ("ge", file); break;
5560 case LE: fputs ("gt", file); break;
5561 case GTU: fputs ("leu", file); break;
5562 case GEU: fputs ("ltu", file); break;
5563 case LTU: fputs ("geu", file); break;
5564 case LEU: fputs ("gtu", file); break;
5566 fatal_insn ("PRINT_OPERAND, invalid insn for %%N", op);
5569 else if (letter == 'F')
5572 case EQ: fputs ("c1f", file); break;
5573 case NE: fputs ("c1t", file); break;
5575 fatal_insn ("PRINT_OPERAND, invalid insn for %%F", op);
5578 else if (letter == 'W')
5581 case EQ: fputs ("c1t", file); break;
5582 case NE: fputs ("c1f", file); break;
5584 fatal_insn ("PRINT_OPERAND, invalid insn for %%W", op);
5587 else if (letter == 'h')
5589 if (GET_CODE (op) == HIGH)
5592 print_operand_reloc (file, op, mips_hi_relocs);
5595 else if (letter == 'R')
5596 print_operand_reloc (file, op, mips_lo_relocs);
5598 else if (letter == 'Y')
5600 if (GET_CODE (op) == CONST_INT
5601 && ((unsigned HOST_WIDE_INT) INTVAL (op)
5602 < ARRAY_SIZE (mips_fp_conditions)))
5603 fputs (mips_fp_conditions[INTVAL (op)], file);
5605 output_operand_lossage ("invalid %%Y value");
5608 else if (letter == 'Z')
5612 print_operand (file, op, 0);
5617 else if (letter == 'q')
5622 fatal_insn ("PRINT_OPERAND, invalid insn for %%q", op);
5624 regnum = REGNO (op);
5625 if (MD_REG_P (regnum))
5626 fprintf (file, "$ac0");
5627 else if (DSP_ACC_REG_P (regnum))
5628 fprintf (file, "$ac%c", reg_names[regnum][3]);
5630 fatal_insn ("PRINT_OPERAND, invalid insn for %%q", op);
5633 else if (code == REG || code == SUBREG)
5635 register int regnum;
5638 regnum = REGNO (op);
5640 regnum = true_regnum (op);
5642 if ((letter == 'M' && ! WORDS_BIG_ENDIAN)
5643 || (letter == 'L' && WORDS_BIG_ENDIAN)
5647 fprintf (file, "%s", reg_names[regnum]);
5650 else if (code == MEM)
5653 output_address (plus_constant (XEXP (op, 0), 4));
5655 output_address (XEXP (op, 0));
5658 else if (letter == 'x' && GET_CODE (op) == CONST_INT)
5659 fprintf (file, HOST_WIDE_INT_PRINT_HEX, 0xffff & INTVAL(op));
5661 else if (letter == 'X' && GET_CODE(op) == CONST_INT)
5662 fprintf (file, HOST_WIDE_INT_PRINT_HEX, INTVAL (op));
5664 else if (letter == 'd' && GET_CODE(op) == CONST_INT)
5665 fprintf (file, HOST_WIDE_INT_PRINT_DEC, (INTVAL(op)));
5667 else if (letter == 'z' && op == CONST0_RTX (GET_MODE (op)))
5668 fputs (reg_names[GP_REG_FIRST], file);
5670 else if (letter == 'd' || letter == 'x' || letter == 'X')
5671 output_operand_lossage ("invalid use of %%d, %%x, or %%X");
5673 else if (letter == 'T' || letter == 't')
5675 int truth = (code == NE) == (letter == 'T');
5676 fputc ("zfnt"[truth * 2 + (GET_MODE (op) == CCmode)], file);
5679 else if (CONST_GP_P (op))
5680 fputs (reg_names[GLOBAL_POINTER_REGNUM], file);
5683 output_addr_const (file, op);
5687 /* Print symbolic operand OP, which is part of a HIGH or LO_SUM.
5688 RELOCS is the array of relocations to use. */
5691 print_operand_reloc (FILE *file, rtx op, const char **relocs)
5693 enum mips_symbol_type symbol_type;
5696 HOST_WIDE_INT offset;
5698 symbol_type = mips_classify_symbolic_expression (op);
5699 if (relocs[symbol_type] == 0)
5700 fatal_insn ("PRINT_OPERAND, invalid operand for relocation", op);
5702 /* If OP uses an UNSPEC address, we want to print the inner symbol. */
5703 mips_split_const (op, &base, &offset);
5704 if (UNSPEC_ADDRESS_P (base))
5705 op = plus_constant (UNSPEC_ADDRESS (base), offset);
5707 fputs (relocs[symbol_type], file);
5708 output_addr_const (file, op);
5709 for (p = relocs[symbol_type]; *p != 0; p++)
5714 /* Output address operand X to FILE. */
5717 print_operand_address (FILE *file, rtx x)
5719 struct mips_address_info addr;
5721 if (mips_classify_address (&addr, x, word_mode, true))
5725 print_operand (file, addr.offset, 0);
5726 fprintf (file, "(%s)", reg_names[REGNO (addr.reg)]);
5729 case ADDRESS_LO_SUM:
5730 print_operand (file, addr.offset, 'R');
5731 fprintf (file, "(%s)", reg_names[REGNO (addr.reg)]);
5734 case ADDRESS_CONST_INT:
5735 output_addr_const (file, x);
5736 fprintf (file, "(%s)", reg_names[0]);
5739 case ADDRESS_SYMBOLIC:
5740 output_addr_const (file, x);
5746 /* When using assembler macros, keep track of all of small-data externs
5747 so that mips_file_end can emit the appropriate declarations for them.
5749 In most cases it would be safe (though pointless) to emit .externs
5750 for other symbols too. One exception is when an object is within
5751 the -G limit but declared by the user to be in a section other
5752 than .sbss or .sdata. */
5755 mips_output_external (FILE *file ATTRIBUTE_UNUSED, tree decl, const char *name)
5757 register struct extern_list *p;
5759 if (!TARGET_EXPLICIT_RELOCS && mips_in_small_data_p (decl))
5761 p = (struct extern_list *) ggc_alloc (sizeof (struct extern_list));
5762 p->next = extern_head;
5764 p->size = int_size_in_bytes (TREE_TYPE (decl));
5768 if (TARGET_IRIX && mips_abi == ABI_32 && TREE_CODE (decl) == FUNCTION_DECL)
5770 p = (struct extern_list *) ggc_alloc (sizeof (struct extern_list));
5771 p->next = extern_head;
5782 irix_output_external_libcall (rtx fun)
5784 register struct extern_list *p;
5786 if (mips_abi == ABI_32)
5788 p = (struct extern_list *) ggc_alloc (sizeof (struct extern_list));
5789 p->next = extern_head;
5790 p->name = XSTR (fun, 0);
5797 /* Emit a new filename to a stream. If we are smuggling stabs, try to
5798 put out a MIPS ECOFF file and a stab. */
5801 mips_output_filename (FILE *stream, const char *name)
5804 /* If we are emitting DWARF-2, let dwarf2out handle the ".file"
5806 if (write_symbols == DWARF2_DEBUG)
5808 else if (mips_output_filename_first_time)
5810 mips_output_filename_first_time = 0;
5811 num_source_filenames += 1;
5812 current_function_file = name;
5813 fprintf (stream, "\t.file\t%d ", num_source_filenames);
5814 output_quoted_string (stream, name);
5815 putc ('\n', stream);
5818 /* If we are emitting stabs, let dbxout.c handle this (except for
5819 the mips_output_filename_first_time case). */
5820 else if (write_symbols == DBX_DEBUG)
5823 else if (name != current_function_file
5824 && strcmp (name, current_function_file) != 0)
5826 num_source_filenames += 1;
5827 current_function_file = name;
5828 fprintf (stream, "\t.file\t%d ", num_source_filenames);
5829 output_quoted_string (stream, name);
5830 putc ('\n', stream);
5834 /* Output an ASCII string, in a space-saving way. PREFIX is the string
5835 that should be written before the opening quote, such as "\t.ascii\t"
5836 for real string data or "\t# " for a comment. */
5839 mips_output_ascii (FILE *stream, const char *string_param, size_t len,
5844 register const unsigned char *string =
5845 (const unsigned char *)string_param;
5847 fprintf (stream, "%s\"", prefix);
5848 for (i = 0; i < len; i++)
5850 register int c = string[i];
5854 if (c == '\\' || c == '\"')
5856 putc ('\\', stream);
5864 fprintf (stream, "\\%03o", c);
5868 if (cur_pos > 72 && i+1 < len)
5871 fprintf (stream, "\"\n%s\"", prefix);
5874 fprintf (stream, "\"\n");
5877 /* Implement TARGET_ASM_FILE_START. */
5880 mips_file_start (void)
5882 default_file_start ();
5886 /* Generate a special section to describe the ABI switches used to
5887 produce the resultant binary. This used to be done by the assembler
5888 setting bits in the ELF header's flags field, but we have run out of
5889 bits. GDB needs this information in order to be able to correctly
5890 debug these binaries. See the function mips_gdbarch_init() in
5891 gdb/mips-tdep.c. This is unnecessary for the IRIX 5/6 ABIs and
5892 causes unnecessary IRIX 6 ld warnings. */
5893 const char * abi_string = NULL;
5897 case ABI_32: abi_string = "abi32"; break;
5898 case ABI_N32: abi_string = "abiN32"; break;
5899 case ABI_64: abi_string = "abi64"; break;
5900 case ABI_O64: abi_string = "abiO64"; break;
5901 case ABI_EABI: abi_string = TARGET_64BIT ? "eabi64" : "eabi32"; break;
5905 /* Note - we use fprintf directly rather than calling switch_to_section
5906 because in this way we can avoid creating an allocated section. We
5907 do not want this section to take up any space in the running
5909 fprintf (asm_out_file, "\t.section .mdebug.%s\n", abi_string);
5911 /* There is no ELF header flag to distinguish long32 forms of the
5912 EABI from long64 forms. Emit a special section to help tools
5913 such as GDB. Do the same for o64, which is sometimes used with
5915 if (mips_abi == ABI_EABI || mips_abi == ABI_O64)
5916 fprintf (asm_out_file, "\t.section .gcc_compiled_long%d\n",
5917 TARGET_LONG64 ? 64 : 32);
5919 /* Restore the default section. */
5920 fprintf (asm_out_file, "\t.previous\n");
5923 /* Generate the pseudo ops that System V.4 wants. */
5924 if (TARGET_ABICALLS)
5925 fprintf (asm_out_file, "\t.abicalls\n");
5928 fprintf (asm_out_file, "\t.set\tmips16\n");
5930 if (flag_verbose_asm)
5931 fprintf (asm_out_file, "\n%s -G value = %d, Arch = %s, ISA = %d\n",
5933 mips_section_threshold, mips_arch_info->name, mips_isa);
5936 #ifdef BSS_SECTION_ASM_OP
5937 /* Implement ASM_OUTPUT_ALIGNED_BSS. This differs from the default only
5938 in the use of sbss. */
5941 mips_output_aligned_bss (FILE *stream, tree decl, const char *name,
5942 unsigned HOST_WIDE_INT size, int align)
5944 extern tree last_assemble_variable_decl;
5946 if (mips_in_small_data_p (decl))
5947 switch_to_section (get_named_section (NULL, ".sbss", 0));
5949 switch_to_section (bss_section);
5950 ASM_OUTPUT_ALIGN (stream, floor_log2 (align / BITS_PER_UNIT));
5951 last_assemble_variable_decl = decl;
5952 ASM_DECLARE_OBJECT_NAME (stream, name, decl);
5953 ASM_OUTPUT_SKIP (stream, size != 0 ? size : 1);
5957 /* Implement TARGET_ASM_FILE_END. When using assembler macros, emit
5958 .externs for any small-data variables that turned out to be external. */
5961 mips_file_end (void)
5964 struct extern_list *p;
5968 fputs ("\n", asm_out_file);
5970 for (p = extern_head; p != 0; p = p->next)
5972 name_tree = get_identifier (p->name);
5974 /* Positively ensure only one .extern for any given symbol. */
5975 if (!TREE_ASM_WRITTEN (name_tree)
5976 && TREE_SYMBOL_REFERENCED (name_tree))
5978 TREE_ASM_WRITTEN (name_tree) = 1;
5979 /* In IRIX 5 or IRIX 6 for the O32 ABI, we must output a
5980 `.global name .text' directive for every used but
5981 undefined function. If we don't, the linker may perform
5982 an optimization (skipping over the insns that set $gp)
5983 when it is unsafe. */
5984 if (TARGET_IRIX && mips_abi == ABI_32 && p->size == -1)
5986 fputs ("\t.globl ", asm_out_file);
5987 assemble_name (asm_out_file, p->name);
5988 fputs (" .text\n", asm_out_file);
5992 fputs ("\t.extern\t", asm_out_file);
5993 assemble_name (asm_out_file, p->name);
5994 fprintf (asm_out_file, ", %d\n", p->size);
6001 /* Implement ASM_OUTPUT_ALIGNED_DECL_COMMON. This is usually the same as the
6002 elfos.h version, but we also need to handle -muninit-const-in-rodata. */
6005 mips_output_aligned_decl_common (FILE *stream, tree decl, const char *name,
6006 unsigned HOST_WIDE_INT size,
6009 /* If the target wants uninitialized const declarations in
6010 .rdata then don't put them in .comm. */
6011 if (TARGET_EMBEDDED_DATA && TARGET_UNINIT_CONST_IN_RODATA
6012 && TREE_CODE (decl) == VAR_DECL && TREE_READONLY (decl)
6013 && (DECL_INITIAL (decl) == 0 || DECL_INITIAL (decl) == error_mark_node))
6015 if (TREE_PUBLIC (decl) && DECL_NAME (decl))
6016 targetm.asm_out.globalize_label (stream, name);
6018 switch_to_section (readonly_data_section);
6019 ASM_OUTPUT_ALIGN (stream, floor_log2 (align / BITS_PER_UNIT));
6020 mips_declare_object (stream, name, "",
6021 ":\n\t.space\t" HOST_WIDE_INT_PRINT_UNSIGNED "\n",
6025 mips_declare_common_object (stream, name, "\n\t.comm\t",
6029 /* Declare a common object of SIZE bytes using asm directive INIT_STRING.
6030 NAME is the name of the object and ALIGN is the required alignment
6031 in bytes. TAKES_ALIGNMENT_P is true if the directive takes a third
6032 alignment argument. */
6035 mips_declare_common_object (FILE *stream, const char *name,
6036 const char *init_string,
6037 unsigned HOST_WIDE_INT size,
6038 unsigned int align, bool takes_alignment_p)
6040 if (!takes_alignment_p)
6042 size += (align / BITS_PER_UNIT) - 1;
6043 size -= size % (align / BITS_PER_UNIT);
6044 mips_declare_object (stream, name, init_string,
6045 "," HOST_WIDE_INT_PRINT_UNSIGNED "\n", size);
6048 mips_declare_object (stream, name, init_string,
6049 "," HOST_WIDE_INT_PRINT_UNSIGNED ",%u\n",
6050 size, align / BITS_PER_UNIT);
6053 /* Emit either a label, .comm, or .lcomm directive. When using assembler
6054 macros, mark the symbol as written so that mips_file_end won't emit an
6055 .extern for it. STREAM is the output file, NAME is the name of the
6056 symbol, INIT_STRING is the string that should be written before the
6057 symbol and FINAL_STRING is the string that should be written after it.
6058 FINAL_STRING is a printf() format that consumes the remaining arguments. */
6061 mips_declare_object (FILE *stream, const char *name, const char *init_string,
6062 const char *final_string, ...)
6066 fputs (init_string, stream);
6067 assemble_name (stream, name);
6068 va_start (ap, final_string);
6069 vfprintf (stream, final_string, ap);
6072 if (!TARGET_EXPLICIT_RELOCS)
6074 tree name_tree = get_identifier (name);
6075 TREE_ASM_WRITTEN (name_tree) = 1;
6079 #ifdef ASM_OUTPUT_SIZE_DIRECTIVE
6080 extern int size_directive_output;
6082 /* Implement ASM_DECLARE_OBJECT_NAME. This is like most of the standard ELF
6083 definitions except that it uses mips_declare_object() to emit the label. */
6086 mips_declare_object_name (FILE *stream, const char *name,
6087 tree decl ATTRIBUTE_UNUSED)
6089 #ifdef ASM_OUTPUT_TYPE_DIRECTIVE
6090 ASM_OUTPUT_TYPE_DIRECTIVE (stream, name, "object");
6093 size_directive_output = 0;
6094 if (!flag_inhibit_size_directive && DECL_SIZE (decl))
6098 size_directive_output = 1;
6099 size = int_size_in_bytes (TREE_TYPE (decl));
6100 ASM_OUTPUT_SIZE_DIRECTIVE (stream, name, size);
6103 mips_declare_object (stream, name, "", ":\n");
6106 /* Implement ASM_FINISH_DECLARE_OBJECT. This is generic ELF stuff. */
6109 mips_finish_declare_object (FILE *stream, tree decl, int top_level, int at_end)
6113 name = XSTR (XEXP (DECL_RTL (decl), 0), 0);
6114 if (!flag_inhibit_size_directive
6115 && DECL_SIZE (decl) != 0
6116 && !at_end && top_level
6117 && DECL_INITIAL (decl) == error_mark_node
6118 && !size_directive_output)
6122 size_directive_output = 1;
6123 size = int_size_in_bytes (TREE_TYPE (decl));
6124 ASM_OUTPUT_SIZE_DIRECTIVE (stream, name, size);
6129 /* Return true if X is a small data address that can be rewritten
6133 mips_rewrite_small_data_p (rtx x)
6135 enum mips_symbol_type symbol_type;
6137 return (TARGET_EXPLICIT_RELOCS
6138 && mips_symbolic_constant_p (x, &symbol_type)
6139 && symbol_type == SYMBOL_SMALL_DATA);
6143 /* A for_each_rtx callback for mips_small_data_pattern_p. */
6146 mips_small_data_pattern_1 (rtx *loc, void *data ATTRIBUTE_UNUSED)
6148 if (GET_CODE (*loc) == LO_SUM)
6151 return mips_rewrite_small_data_p (*loc);
6154 /* Return true if OP refers to small data symbols directly, not through
6158 mips_small_data_pattern_p (rtx op)
6160 return for_each_rtx (&op, mips_small_data_pattern_1, 0);
6163 /* A for_each_rtx callback, used by mips_rewrite_small_data. */
6166 mips_rewrite_small_data_1 (rtx *loc, void *data ATTRIBUTE_UNUSED)
6168 if (mips_rewrite_small_data_p (*loc))
6169 *loc = gen_rtx_LO_SUM (Pmode, pic_offset_table_rtx, *loc);
6171 if (GET_CODE (*loc) == LO_SUM)
6177 /* If possible, rewrite OP so that it refers to small data using
6178 explicit relocations. */
6181 mips_rewrite_small_data (rtx op)
6183 op = copy_insn (op);
6184 for_each_rtx (&op, mips_rewrite_small_data_1, 0);
6188 /* Return true if the current function has an insn that implicitly
6192 mips_function_has_gp_insn (void)
6194 /* Don't bother rechecking if we found one last time. */
6195 if (!cfun->machine->has_gp_insn_p)
6199 push_topmost_sequence ();
6200 for (insn = get_insns (); insn; insn = NEXT_INSN (insn))
6202 && GET_CODE (PATTERN (insn)) != USE
6203 && GET_CODE (PATTERN (insn)) != CLOBBER
6204 && (get_attr_got (insn) != GOT_UNSET
6205 || small_data_pattern (PATTERN (insn), VOIDmode)))
6207 pop_topmost_sequence ();
6209 cfun->machine->has_gp_insn_p = (insn != 0);
6211 return cfun->machine->has_gp_insn_p;
6215 /* Return the register that should be used as the global pointer
6216 within this function. Return 0 if the function doesn't need
6217 a global pointer. */
6220 mips_global_pointer (void)
6224 /* $gp is always available in non-abicalls code. */
6225 if (!TARGET_ABICALLS)
6226 return GLOBAL_POINTER_REGNUM;
6228 /* We must always provide $gp when it is used implicitly. */
6229 if (!TARGET_EXPLICIT_RELOCS)
6230 return GLOBAL_POINTER_REGNUM;
6232 /* FUNCTION_PROFILER includes a jal macro, so we need to give it
6234 if (current_function_profile)
6235 return GLOBAL_POINTER_REGNUM;
6237 /* If the function has a nonlocal goto, $gp must hold the correct
6238 global pointer for the target function. */
6239 if (current_function_has_nonlocal_goto)
6240 return GLOBAL_POINTER_REGNUM;
6242 /* If the gp is never referenced, there's no need to initialize it.
6243 Note that reload can sometimes introduce constant pool references
6244 into a function that otherwise didn't need them. For example,
6245 suppose we have an instruction like:
6247 (set (reg:DF R1) (float:DF (reg:SI R2)))
6249 If R2 turns out to be constant such as 1, the instruction may have a
6250 REG_EQUAL note saying that R1 == 1.0. Reload then has the option of
6251 using this constant if R2 doesn't get allocated to a register.
6253 In cases like these, reload will have added the constant to the pool
6254 but no instruction will yet refer to it. */
6255 if (!regs_ever_live[GLOBAL_POINTER_REGNUM]
6256 && !current_function_uses_const_pool
6257 && !mips_function_has_gp_insn ())
6260 /* We need a global pointer, but perhaps we can use a call-clobbered
6261 register instead of $gp. */
6262 if (TARGET_NEWABI && current_function_is_leaf)
6263 for (regno = GP_REG_FIRST; regno <= GP_REG_LAST; regno++)
6264 if (!regs_ever_live[regno]
6265 && call_used_regs[regno]
6266 && !fixed_regs[regno]
6267 && regno != PIC_FUNCTION_ADDR_REGNUM)
6270 return GLOBAL_POINTER_REGNUM;
6274 /* Return true if the current function must save REGNO. */
6277 mips_save_reg_p (unsigned int regno)
6279 /* We only need to save $gp for NewABI PIC. */
6280 if (regno == GLOBAL_POINTER_REGNUM)
6281 return (TARGET_ABICALLS && TARGET_NEWABI
6282 && cfun->machine->global_pointer == regno);
6284 /* Check call-saved registers. */
6285 if (regs_ever_live[regno] && !call_used_regs[regno])
6288 /* We need to save the old frame pointer before setting up a new one. */
6289 if (regno == HARD_FRAME_POINTER_REGNUM && frame_pointer_needed)
6292 /* We need to save the incoming return address if it is ever clobbered
6293 within the function. */
6294 if (regno == GP_REG_FIRST + 31 && regs_ever_live[regno])
6301 return_type = DECL_RESULT (current_function_decl);
6303 /* $18 is a special case in mips16 code. It may be used to call
6304 a function which returns a floating point value, but it is
6305 marked in call_used_regs. */
6306 if (regno == GP_REG_FIRST + 18 && regs_ever_live[regno])
6309 /* $31 is also a special case. It will be used to copy a return
6310 value into the floating point registers if the return value is
6312 if (regno == GP_REG_FIRST + 31
6313 && mips16_hard_float
6314 && !aggregate_value_p (return_type, current_function_decl)
6315 && GET_MODE_CLASS (DECL_MODE (return_type)) == MODE_FLOAT
6316 && GET_MODE_SIZE (DECL_MODE (return_type)) <= UNITS_PER_FPVALUE)
6324 /* Return the bytes needed to compute the frame pointer from the current
6325 stack pointer. SIZE is the size (in bytes) of the local variables.
6327 MIPS stack frames look like:
6329 Before call After call
6330 +-----------------------+ +-----------------------+
6333 | caller's temps. | | caller's temps. |
6335 +-----------------------+ +-----------------------+
6337 | arguments on stack. | | arguments on stack. |
6339 +-----------------------+ +-----------------------+
6340 | 4 words to save | | 4 words to save |
6341 | arguments passed | | arguments passed |
6342 | in registers, even | | in registers, even |
6343 SP->| if not passed. | VFP->| if not passed. |
6344 +-----------------------+ +-----------------------+
6346 | fp register save |
6348 +-----------------------+
6350 | gp register save |
6352 +-----------------------+
6356 +-----------------------+
6358 | alloca allocations |
6360 +-----------------------+
6362 | GP save for V.4 abi |
6364 +-----------------------+
6366 | arguments on stack |
6368 +-----------------------+
6370 | arguments passed |
6371 | in registers, even |
6372 low SP->| if not passed. |
6373 memory +-----------------------+
6378 compute_frame_size (HOST_WIDE_INT size)
6381 HOST_WIDE_INT total_size; /* # bytes that the entire frame takes up */
6382 HOST_WIDE_INT var_size; /* # bytes that variables take up */
6383 HOST_WIDE_INT args_size; /* # bytes that outgoing arguments take up */
6384 HOST_WIDE_INT cprestore_size; /* # bytes that the cprestore slot takes up */
6385 HOST_WIDE_INT gp_reg_rounded; /* # bytes needed to store gp after rounding */
6386 HOST_WIDE_INT gp_reg_size; /* # bytes needed to store gp regs */
6387 HOST_WIDE_INT fp_reg_size; /* # bytes needed to store fp regs */
6388 unsigned int mask; /* mask of saved gp registers */
6389 unsigned int fmask; /* mask of saved fp registers */
6391 cfun->machine->global_pointer = mips_global_pointer ();
6397 var_size = MIPS_STACK_ALIGN (size);
6398 args_size = current_function_outgoing_args_size;
6399 cprestore_size = MIPS_STACK_ALIGN (STARTING_FRAME_OFFSET) - args_size;
6401 /* The space set aside by STARTING_FRAME_OFFSET isn't needed in leaf
6402 functions. If the function has local variables, we're committed
6403 to allocating it anyway. Otherwise reclaim it here. */
6404 if (var_size == 0 && current_function_is_leaf)
6405 cprestore_size = args_size = 0;
6407 /* The MIPS 3.0 linker does not like functions that dynamically
6408 allocate the stack and have 0 for STACK_DYNAMIC_OFFSET, since it
6409 looks like we are trying to create a second frame pointer to the
6410 function, so allocate some stack space to make it happy. */
6412 if (args_size == 0 && current_function_calls_alloca)
6413 args_size = 4 * UNITS_PER_WORD;
6415 total_size = var_size + args_size + cprestore_size;
6417 /* Calculate space needed for gp registers. */
6418 for (regno = GP_REG_FIRST; regno <= GP_REG_LAST; regno++)
6419 if (mips_save_reg_p (regno))
6421 gp_reg_size += GET_MODE_SIZE (gpr_mode);
6422 mask |= 1 << (regno - GP_REG_FIRST);
6425 /* We need to restore these for the handler. */
6426 if (current_function_calls_eh_return)
6431 regno = EH_RETURN_DATA_REGNO (i);
6432 if (regno == INVALID_REGNUM)
6434 gp_reg_size += GET_MODE_SIZE (gpr_mode);
6435 mask |= 1 << (regno - GP_REG_FIRST);
6439 /* This loop must iterate over the same space as its companion in
6440 save_restore_insns. */
6441 for (regno = (FP_REG_LAST - FP_INC + 1);
6442 regno >= FP_REG_FIRST;
6445 if (mips_save_reg_p (regno))
6447 fp_reg_size += FP_INC * UNITS_PER_FPREG;
6448 fmask |= ((1 << FP_INC) - 1) << (regno - FP_REG_FIRST);
6452 gp_reg_rounded = MIPS_STACK_ALIGN (gp_reg_size);
6453 total_size += gp_reg_rounded + MIPS_STACK_ALIGN (fp_reg_size);
6455 /* Add in the space required for saving incoming register arguments. */
6456 total_size += current_function_pretend_args_size;
6457 total_size += MIPS_STACK_ALIGN (cfun->machine->varargs_size);
6459 /* Save other computed information. */
6460 cfun->machine->frame.total_size = total_size;
6461 cfun->machine->frame.var_size = var_size;
6462 cfun->machine->frame.args_size = args_size;
6463 cfun->machine->frame.cprestore_size = cprestore_size;
6464 cfun->machine->frame.gp_reg_size = gp_reg_size;
6465 cfun->machine->frame.fp_reg_size = fp_reg_size;
6466 cfun->machine->frame.mask = mask;
6467 cfun->machine->frame.fmask = fmask;
6468 cfun->machine->frame.initialized = reload_completed;
6469 cfun->machine->frame.num_gp = gp_reg_size / UNITS_PER_WORD;
6470 cfun->machine->frame.num_fp = fp_reg_size / (FP_INC * UNITS_PER_FPREG);
6474 HOST_WIDE_INT offset;
6476 offset = (args_size + cprestore_size + var_size
6477 + gp_reg_size - GET_MODE_SIZE (gpr_mode));
6478 cfun->machine->frame.gp_sp_offset = offset;
6479 cfun->machine->frame.gp_save_offset = offset - total_size;
6483 cfun->machine->frame.gp_sp_offset = 0;
6484 cfun->machine->frame.gp_save_offset = 0;
6489 HOST_WIDE_INT offset;
6491 offset = (args_size + cprestore_size + var_size
6492 + gp_reg_rounded + fp_reg_size
6493 - FP_INC * UNITS_PER_FPREG);
6494 cfun->machine->frame.fp_sp_offset = offset;
6495 cfun->machine->frame.fp_save_offset = offset - total_size;
6499 cfun->machine->frame.fp_sp_offset = 0;
6500 cfun->machine->frame.fp_save_offset = 0;
6503 /* Ok, we're done. */
6507 /* Implement INITIAL_ELIMINATION_OFFSET. FROM is either the frame
6508 pointer or argument pointer. TO is either the stack pointer or
6509 hard frame pointer. */
6512 mips_initial_elimination_offset (int from, int to)
6514 HOST_WIDE_INT offset;
6516 compute_frame_size (get_frame_size ());
6518 /* Set OFFSET to the offset from the stack pointer. */
6521 case FRAME_POINTER_REGNUM:
6525 case ARG_POINTER_REGNUM:
6526 offset = (cfun->machine->frame.total_size
6527 - current_function_pretend_args_size);
6534 if (TARGET_MIPS16 && to == HARD_FRAME_POINTER_REGNUM)
6535 offset -= cfun->machine->frame.args_size;
6540 /* Implement RETURN_ADDR_RTX. Note, we do not support moving
6541 back to a previous frame. */
6543 mips_return_addr (int count, rtx frame ATTRIBUTE_UNUSED)
6548 return get_hard_reg_initial_val (Pmode, GP_REG_FIRST + 31);
6551 /* Use FN to save or restore register REGNO. MODE is the register's
6552 mode and OFFSET is the offset of its save slot from the current
6556 mips_save_restore_reg (enum machine_mode mode, int regno,
6557 HOST_WIDE_INT offset, mips_save_restore_fn fn)
6561 mem = gen_frame_mem (mode, plus_constant (stack_pointer_rtx, offset));
6563 fn (gen_rtx_REG (mode, regno), mem);
6567 /* Call FN for each register that is saved by the current function.
6568 SP_OFFSET is the offset of the current stack pointer from the start
6572 mips_for_each_saved_reg (HOST_WIDE_INT sp_offset, mips_save_restore_fn fn)
6574 #define BITSET_P(VALUE, BIT) (((VALUE) & (1L << (BIT))) != 0)
6576 enum machine_mode fpr_mode;
6577 HOST_WIDE_INT offset;
6580 /* Save registers starting from high to low. The debuggers prefer at least
6581 the return register be stored at func+4, and also it allows us not to
6582 need a nop in the epilog if at least one register is reloaded in
6583 addition to return address. */
6584 offset = cfun->machine->frame.gp_sp_offset - sp_offset;
6585 for (regno = GP_REG_LAST; regno >= GP_REG_FIRST; regno--)
6586 if (BITSET_P (cfun->machine->frame.mask, regno - GP_REG_FIRST))
6588 mips_save_restore_reg (gpr_mode, regno, offset, fn);
6589 offset -= GET_MODE_SIZE (gpr_mode);
6592 /* This loop must iterate over the same space as its companion in
6593 compute_frame_size. */
6594 offset = cfun->machine->frame.fp_sp_offset - sp_offset;
6595 fpr_mode = (TARGET_SINGLE_FLOAT ? SFmode : DFmode);
6596 for (regno = (FP_REG_LAST - FP_INC + 1);
6597 regno >= FP_REG_FIRST;
6599 if (BITSET_P (cfun->machine->frame.fmask, regno - FP_REG_FIRST))
6601 mips_save_restore_reg (fpr_mode, regno, offset, fn);
6602 offset -= GET_MODE_SIZE (fpr_mode);
6607 /* If we're generating n32 or n64 abicalls, and the current function
6608 does not use $28 as its global pointer, emit a cplocal directive.
6609 Use pic_offset_table_rtx as the argument to the directive. */
6612 mips_output_cplocal (void)
6614 if (!TARGET_EXPLICIT_RELOCS
6615 && cfun->machine->global_pointer > 0
6616 && cfun->machine->global_pointer != GLOBAL_POINTER_REGNUM)
6617 output_asm_insn (".cplocal %+", 0);
6620 /* Return the style of GP load sequence that is being used for the
6621 current function. */
6623 enum mips_loadgp_style
6624 mips_current_loadgp_style (void)
6626 if (!TARGET_ABICALLS || cfun->machine->global_pointer == 0)
6629 if (TARGET_ABSOLUTE_ABICALLS)
6630 return LOADGP_ABSOLUTE;
6632 return TARGET_NEWABI ? LOADGP_NEWABI : LOADGP_OLDABI;
6635 /* The __gnu_local_gp symbol. */
6637 static GTY(()) rtx mips_gnu_local_gp;
6639 /* If we're generating n32 or n64 abicalls, emit instructions
6640 to set up the global pointer. */
6643 mips_emit_loadgp (void)
6645 rtx addr, offset, incoming_address;
6647 switch (mips_current_loadgp_style ())
6649 case LOADGP_ABSOLUTE:
6650 if (mips_gnu_local_gp == NULL)
6652 mips_gnu_local_gp = gen_rtx_SYMBOL_REF (Pmode, "__gnu_local_gp");
6653 SYMBOL_REF_FLAGS (mips_gnu_local_gp) |= SYMBOL_FLAG_LOCAL;
6655 emit_insn (gen_loadgp_noshared (mips_gnu_local_gp));
6659 addr = XEXP (DECL_RTL (current_function_decl), 0);
6660 offset = mips_unspec_address (addr, SYMBOL_GOTOFF_LOADGP);
6661 incoming_address = gen_rtx_REG (Pmode, PIC_FUNCTION_ADDR_REGNUM);
6662 emit_insn (gen_loadgp (offset, incoming_address));
6663 if (!TARGET_EXPLICIT_RELOCS)
6664 emit_insn (gen_loadgp_blockage ());
6672 /* Set up the stack and frame (if desired) for the function. */
6675 mips_output_function_prologue (FILE *file, HOST_WIDE_INT size ATTRIBUTE_UNUSED)
6678 HOST_WIDE_INT tsize = cfun->machine->frame.total_size;
6680 #ifdef SDB_DEBUGGING_INFO
6681 if (debug_info_level != DINFO_LEVEL_TERSE && write_symbols == SDB_DEBUG)
6682 SDB_OUTPUT_SOURCE_LINE (file, DECL_SOURCE_LINE (current_function_decl));
6685 /* In mips16 mode, we may need to generate a 32 bit to handle
6686 floating point arguments. The linker will arrange for any 32 bit
6687 functions to call this stub, which will then jump to the 16 bit
6689 if (TARGET_MIPS16 && !TARGET_SOFT_FLOAT
6690 && current_function_args_info.fp_code != 0)
6691 build_mips16_function_stub (file);
6693 if (!FUNCTION_NAME_ALREADY_DECLARED)
6695 /* Get the function name the same way that toplev.c does before calling
6696 assemble_start_function. This is needed so that the name used here
6697 exactly matches the name used in ASM_DECLARE_FUNCTION_NAME. */
6698 fnname = XSTR (XEXP (DECL_RTL (current_function_decl), 0), 0);
6700 if (!flag_inhibit_size_directive)
6702 fputs ("\t.ent\t", file);
6703 assemble_name (file, fnname);
6707 assemble_name (file, fnname);
6708 fputs (":\n", file);
6711 /* Stop mips_file_end from treating this function as external. */
6712 if (TARGET_IRIX && mips_abi == ABI_32)
6713 TREE_ASM_WRITTEN (DECL_NAME (cfun->decl)) = 1;
6715 if (!flag_inhibit_size_directive)
6717 /* .frame FRAMEREG, FRAMESIZE, RETREG */
6719 "\t.frame\t%s," HOST_WIDE_INT_PRINT_DEC ",%s\t\t"
6720 "# vars= " HOST_WIDE_INT_PRINT_DEC ", regs= %d/%d"
6721 ", args= " HOST_WIDE_INT_PRINT_DEC
6722 ", gp= " HOST_WIDE_INT_PRINT_DEC "\n",
6723 (reg_names[(frame_pointer_needed)
6724 ? HARD_FRAME_POINTER_REGNUM : STACK_POINTER_REGNUM]),
6725 ((frame_pointer_needed && TARGET_MIPS16)
6726 ? tsize - cfun->machine->frame.args_size
6728 reg_names[GP_REG_FIRST + 31],
6729 cfun->machine->frame.var_size,
6730 cfun->machine->frame.num_gp,
6731 cfun->machine->frame.num_fp,
6732 cfun->machine->frame.args_size,
6733 cfun->machine->frame.cprestore_size);
6735 /* .mask MASK, GPOFFSET; .fmask FPOFFSET */
6736 fprintf (file, "\t.mask\t0x%08x," HOST_WIDE_INT_PRINT_DEC "\n",
6737 cfun->machine->frame.mask,
6738 cfun->machine->frame.gp_save_offset);
6739 fprintf (file, "\t.fmask\t0x%08x," HOST_WIDE_INT_PRINT_DEC "\n",
6740 cfun->machine->frame.fmask,
6741 cfun->machine->frame.fp_save_offset);
6744 OLD_SP == *FRAMEREG + FRAMESIZE => can find old_sp from nominated FP reg.
6745 HIGHEST_GP_SAVED == *FRAMEREG + FRAMESIZE + GPOFFSET => can find saved regs. */
6748 if (mips_current_loadgp_style () == LOADGP_OLDABI)
6750 /* Handle the initialization of $gp for SVR4 PIC. */
6751 if (!cfun->machine->all_noreorder_p)
6752 output_asm_insn ("%(.cpload\t%^%)", 0);
6754 output_asm_insn ("%(.cpload\t%^\n\t%<", 0);
6756 else if (cfun->machine->all_noreorder_p)
6757 output_asm_insn ("%(%<", 0);
6759 /* Tell the assembler which register we're using as the global
6760 pointer. This is needed for thunks, since they can use either
6761 explicit relocs or assembler macros. */
6762 mips_output_cplocal ();
6765 /* Make the last instruction frame related and note that it performs
6766 the operation described by FRAME_PATTERN. */
6769 mips_set_frame_expr (rtx frame_pattern)
6773 insn = get_last_insn ();
6774 RTX_FRAME_RELATED_P (insn) = 1;
6775 REG_NOTES (insn) = alloc_EXPR_LIST (REG_FRAME_RELATED_EXPR,
6781 /* Return a frame-related rtx that stores REG at MEM.
6782 REG must be a single register. */
6785 mips_frame_set (rtx mem, rtx reg)
6789 /* If we're saving the return address register and the dwarf return
6790 address column differs from the hard register number, adjust the
6791 note reg to refer to the former. */
6792 if (REGNO (reg) == GP_REG_FIRST + 31
6793 && DWARF_FRAME_RETURN_COLUMN != GP_REG_FIRST + 31)
6794 reg = gen_rtx_REG (GET_MODE (reg), DWARF_FRAME_RETURN_COLUMN);
6796 set = gen_rtx_SET (VOIDmode, mem, reg);
6797 RTX_FRAME_RELATED_P (set) = 1;
6803 /* Save register REG to MEM. Make the instruction frame-related. */
6806 mips_save_reg (rtx reg, rtx mem)
6808 if (GET_MODE (reg) == DFmode && !TARGET_FLOAT64)
6812 if (mips_split_64bit_move_p (mem, reg))
6813 mips_split_64bit_move (mem, reg);
6815 emit_move_insn (mem, reg);
6817 x1 = mips_frame_set (mips_subword (mem, 0), mips_subword (reg, 0));
6818 x2 = mips_frame_set (mips_subword (mem, 1), mips_subword (reg, 1));
6819 mips_set_frame_expr (gen_rtx_PARALLEL (VOIDmode, gen_rtvec (2, x1, x2)));
6824 && REGNO (reg) != GP_REG_FIRST + 31
6825 && !M16_REG_P (REGNO (reg)))
6827 /* Save a non-mips16 register by moving it through a temporary.
6828 We don't need to do this for $31 since there's a special
6829 instruction for it. */
6830 emit_move_insn (MIPS_PROLOGUE_TEMP (GET_MODE (reg)), reg);
6831 emit_move_insn (mem, MIPS_PROLOGUE_TEMP (GET_MODE (reg)));
6834 emit_move_insn (mem, reg);
6836 mips_set_frame_expr (mips_frame_set (mem, reg));
6841 /* Expand the prologue into a bunch of separate insns. */
6844 mips_expand_prologue (void)
6848 if (cfun->machine->global_pointer > 0)
6849 REGNO (pic_offset_table_rtx) = cfun->machine->global_pointer;
6851 size = compute_frame_size (get_frame_size ());
6853 /* Save the registers. Allocate up to MIPS_MAX_FIRST_STACK_STEP
6854 bytes beforehand; this is enough to cover the register save area
6855 without going out of range. */
6856 if ((cfun->machine->frame.mask | cfun->machine->frame.fmask) != 0)
6858 HOST_WIDE_INT step1;
6860 step1 = MIN (size, MIPS_MAX_FIRST_STACK_STEP);
6861 RTX_FRAME_RELATED_P (emit_insn (gen_add3_insn (stack_pointer_rtx,
6863 GEN_INT (-step1)))) = 1;
6865 mips_for_each_saved_reg (size, mips_save_reg);
6868 /* Allocate the rest of the frame. */
6871 if (SMALL_OPERAND (-size))
6872 RTX_FRAME_RELATED_P (emit_insn (gen_add3_insn (stack_pointer_rtx,
6874 GEN_INT (-size)))) = 1;
6877 emit_move_insn (MIPS_PROLOGUE_TEMP (Pmode), GEN_INT (size));
6880 /* There are no instructions to add or subtract registers
6881 from the stack pointer, so use the frame pointer as a
6882 temporary. We should always be using a frame pointer
6883 in this case anyway. */
6884 gcc_assert (frame_pointer_needed);
6885 emit_move_insn (hard_frame_pointer_rtx, stack_pointer_rtx);
6886 emit_insn (gen_sub3_insn (hard_frame_pointer_rtx,
6887 hard_frame_pointer_rtx,
6888 MIPS_PROLOGUE_TEMP (Pmode)));
6889 emit_move_insn (stack_pointer_rtx, hard_frame_pointer_rtx);
6892 emit_insn (gen_sub3_insn (stack_pointer_rtx,
6894 MIPS_PROLOGUE_TEMP (Pmode)));
6896 /* Describe the combined effect of the previous instructions. */
6898 (gen_rtx_SET (VOIDmode, stack_pointer_rtx,
6899 plus_constant (stack_pointer_rtx, -size)));
6903 /* Set up the frame pointer, if we're using one. In mips16 code,
6904 we point the frame pointer ahead of the outgoing argument area.
6905 This should allow more variables & incoming arguments to be
6906 accessed with unextended instructions. */
6907 if (frame_pointer_needed)
6909 if (TARGET_MIPS16 && cfun->machine->frame.args_size != 0)
6911 rtx offset = GEN_INT (cfun->machine->frame.args_size);
6912 if (SMALL_OPERAND (cfun->machine->frame.args_size))
6914 (emit_insn (gen_add3_insn (hard_frame_pointer_rtx,
6919 emit_move_insn (MIPS_PROLOGUE_TEMP (Pmode), offset);
6920 emit_move_insn (hard_frame_pointer_rtx, stack_pointer_rtx);
6921 emit_insn (gen_add3_insn (hard_frame_pointer_rtx,
6922 hard_frame_pointer_rtx,
6923 MIPS_PROLOGUE_TEMP (Pmode)));
6925 (gen_rtx_SET (VOIDmode, hard_frame_pointer_rtx,
6926 plus_constant (stack_pointer_rtx,
6927 cfun->machine->frame.args_size)));
6931 RTX_FRAME_RELATED_P (emit_move_insn (hard_frame_pointer_rtx,
6932 stack_pointer_rtx)) = 1;
6935 mips_emit_loadgp ();
6937 /* If generating o32/o64 abicalls, save $gp on the stack. */
6938 if (TARGET_ABICALLS && !TARGET_NEWABI && !current_function_is_leaf)
6939 emit_insn (gen_cprestore (GEN_INT (current_function_outgoing_args_size)));
6941 /* If we are profiling, make sure no instructions are scheduled before
6942 the call to mcount. */
6944 if (current_function_profile)
6945 emit_insn (gen_blockage ());
6948 /* Do any necessary cleanup after a function to restore stack, frame,
6951 #define RA_MASK BITMASK_HIGH /* 1 << 31 */
6954 mips_output_function_epilogue (FILE *file ATTRIBUTE_UNUSED,
6955 HOST_WIDE_INT size ATTRIBUTE_UNUSED)
6957 /* Reinstate the normal $gp. */
6958 REGNO (pic_offset_table_rtx) = GLOBAL_POINTER_REGNUM;
6959 mips_output_cplocal ();
6961 if (cfun->machine->all_noreorder_p)
6963 /* Avoid using %>%) since it adds excess whitespace. */
6964 output_asm_insn (".set\tmacro", 0);
6965 output_asm_insn (".set\treorder", 0);
6966 set_noreorder = set_nomacro = 0;
6969 if (!FUNCTION_NAME_ALREADY_DECLARED && !flag_inhibit_size_directive)
6973 /* Get the function name the same way that toplev.c does before calling
6974 assemble_start_function. This is needed so that the name used here
6975 exactly matches the name used in ASM_DECLARE_FUNCTION_NAME. */
6976 fnname = XSTR (XEXP (DECL_RTL (current_function_decl), 0), 0);
6977 fputs ("\t.end\t", file);
6978 assemble_name (file, fnname);
6983 /* Emit instructions to restore register REG from slot MEM. */
6986 mips_restore_reg (rtx reg, rtx mem)
6988 /* There's no mips16 instruction to load $31 directly. Load into
6989 $7 instead and adjust the return insn appropriately. */
6990 if (TARGET_MIPS16 && REGNO (reg) == GP_REG_FIRST + 31)
6991 reg = gen_rtx_REG (GET_MODE (reg), 7);
6993 if (TARGET_MIPS16 && !M16_REG_P (REGNO (reg)))
6995 /* Can't restore directly; move through a temporary. */
6996 emit_move_insn (MIPS_EPILOGUE_TEMP (GET_MODE (reg)), mem);
6997 emit_move_insn (reg, MIPS_EPILOGUE_TEMP (GET_MODE (reg)));
7000 emit_move_insn (reg, mem);
7004 /* Expand the epilogue into a bunch of separate insns. SIBCALL_P is true
7005 if this epilogue precedes a sibling call, false if it is for a normal
7006 "epilogue" pattern. */
7009 mips_expand_epilogue (int sibcall_p)
7011 HOST_WIDE_INT step1, step2;
7014 if (!sibcall_p && mips_can_use_return_insn ())
7016 emit_jump_insn (gen_return ());
7020 /* Split the frame into two. STEP1 is the amount of stack we should
7021 deallocate before restoring the registers. STEP2 is the amount we
7022 should deallocate afterwards.
7024 Start off by assuming that no registers need to be restored. */
7025 step1 = cfun->machine->frame.total_size;
7028 /* Work out which register holds the frame address. Account for the
7029 frame pointer offset used by mips16 code. */
7030 if (!frame_pointer_needed)
7031 base = stack_pointer_rtx;
7034 base = hard_frame_pointer_rtx;
7036 step1 -= cfun->machine->frame.args_size;
7039 /* If we need to restore registers, deallocate as much stack as
7040 possible in the second step without going out of range. */
7041 if ((cfun->machine->frame.mask | cfun->machine->frame.fmask) != 0)
7043 step2 = MIN (step1, MIPS_MAX_FIRST_STACK_STEP);
7047 /* Set TARGET to BASE + STEP1. */
7053 /* Get an rtx for STEP1 that we can add to BASE. */
7054 adjust = GEN_INT (step1);
7055 if (!SMALL_OPERAND (step1))
7057 emit_move_insn (MIPS_EPILOGUE_TEMP (Pmode), adjust);
7058 adjust = MIPS_EPILOGUE_TEMP (Pmode);
7061 /* Normal mode code can copy the result straight into $sp. */
7063 target = stack_pointer_rtx;
7065 emit_insn (gen_add3_insn (target, base, adjust));
7068 /* Copy TARGET into the stack pointer. */
7069 if (target != stack_pointer_rtx)
7070 emit_move_insn (stack_pointer_rtx, target);
7072 /* If we're using addressing macros for n32/n64 abicalls, $gp is
7073 implicitly used by all SYMBOL_REFs. We must emit a blockage
7074 insn before restoring it. */
7075 if (TARGET_ABICALLS && TARGET_NEWABI && !TARGET_EXPLICIT_RELOCS)
7076 emit_insn (gen_blockage ());
7078 /* Restore the registers. */
7079 mips_for_each_saved_reg (cfun->machine->frame.total_size - step2,
7082 /* Deallocate the final bit of the frame. */
7084 emit_insn (gen_add3_insn (stack_pointer_rtx,
7088 /* Add in the __builtin_eh_return stack adjustment. We need to
7089 use a temporary in mips16 code. */
7090 if (current_function_calls_eh_return)
7094 emit_move_insn (MIPS_EPILOGUE_TEMP (Pmode), stack_pointer_rtx);
7095 emit_insn (gen_add3_insn (MIPS_EPILOGUE_TEMP (Pmode),
7096 MIPS_EPILOGUE_TEMP (Pmode),
7097 EH_RETURN_STACKADJ_RTX));
7098 emit_move_insn (stack_pointer_rtx, MIPS_EPILOGUE_TEMP (Pmode));
7101 emit_insn (gen_add3_insn (stack_pointer_rtx,
7103 EH_RETURN_STACKADJ_RTX));
7108 /* The mips16 loads the return address into $7, not $31. */
7109 if (TARGET_MIPS16 && (cfun->machine->frame.mask & RA_MASK) != 0)
7110 emit_jump_insn (gen_return_internal (gen_rtx_REG (Pmode,
7111 GP_REG_FIRST + 7)));
7113 emit_jump_insn (gen_return_internal (gen_rtx_REG (Pmode,
7114 GP_REG_FIRST + 31)));
7118 /* Return nonzero if this function is known to have a null epilogue.
7119 This allows the optimizer to omit jumps to jumps if no stack
7123 mips_can_use_return_insn (void)
7127 if (! reload_completed)
7130 if (regs_ever_live[31] || current_function_profile)
7133 return_type = DECL_RESULT (current_function_decl);
7135 /* In mips16 mode, a function which returns a floating point value
7136 needs to arrange to copy the return value into the floating point
7139 && mips16_hard_float
7140 && ! aggregate_value_p (return_type, current_function_decl)
7141 && GET_MODE_CLASS (DECL_MODE (return_type)) == MODE_FLOAT
7142 && GET_MODE_SIZE (DECL_MODE (return_type)) <= UNITS_PER_FPVALUE)
7145 if (cfun->machine->frame.initialized)
7146 return cfun->machine->frame.total_size == 0;
7148 return compute_frame_size (get_frame_size ()) == 0;
7151 /* Implement TARGET_ASM_OUTPUT_MI_THUNK. Generate rtl rather than asm text
7152 in order to avoid duplicating too much logic from elsewhere. */
7155 mips_output_mi_thunk (FILE *file, tree thunk_fndecl ATTRIBUTE_UNUSED,
7156 HOST_WIDE_INT delta, HOST_WIDE_INT vcall_offset,
7159 rtx this, temp1, temp2, insn, fnaddr;
7161 /* Pretend to be a post-reload pass while generating rtl. */
7163 reload_completed = 1;
7164 reset_block_changes ();
7166 /* Pick a global pointer for -mabicalls. Use $15 rather than $28
7167 for TARGET_NEWABI since the latter is a call-saved register. */
7168 if (TARGET_ABICALLS)
7169 cfun->machine->global_pointer
7170 = REGNO (pic_offset_table_rtx)
7171 = TARGET_NEWABI ? 15 : GLOBAL_POINTER_REGNUM;
7173 /* Set up the global pointer for n32 or n64 abicalls. */
7174 mips_emit_loadgp ();
7176 /* We need two temporary registers in some cases. */
7177 temp1 = gen_rtx_REG (Pmode, 2);
7178 temp2 = gen_rtx_REG (Pmode, 3);
7180 /* Find out which register contains the "this" pointer. */
7181 if (aggregate_value_p (TREE_TYPE (TREE_TYPE (function)), function))
7182 this = gen_rtx_REG (Pmode, GP_ARG_FIRST + 1);
7184 this = gen_rtx_REG (Pmode, GP_ARG_FIRST);
7186 /* Add DELTA to THIS. */
7189 rtx offset = GEN_INT (delta);
7190 if (!SMALL_OPERAND (delta))
7192 emit_move_insn (temp1, offset);
7195 emit_insn (gen_add3_insn (this, this, offset));
7198 /* If needed, add *(*THIS + VCALL_OFFSET) to THIS. */
7199 if (vcall_offset != 0)
7203 /* Set TEMP1 to *THIS. */
7204 emit_move_insn (temp1, gen_rtx_MEM (Pmode, this));
7206 /* Set ADDR to a legitimate address for *THIS + VCALL_OFFSET. */
7207 addr = mips_add_offset (temp2, temp1, vcall_offset);
7209 /* Load the offset and add it to THIS. */
7210 emit_move_insn (temp1, gen_rtx_MEM (Pmode, addr));
7211 emit_insn (gen_add3_insn (this, this, temp1));
7214 /* Jump to the target function. Use a sibcall if direct jumps are
7215 allowed, otherwise load the address into a register first. */
7216 fnaddr = XEXP (DECL_RTL (function), 0);
7217 if (TARGET_MIPS16 || TARGET_ABICALLS || TARGET_LONG_CALLS)
7219 /* This is messy. gas treats "la $25,foo" as part of a call
7220 sequence and may allow a global "foo" to be lazily bound.
7221 The general move patterns therefore reject this combination.
7223 In this context, lazy binding would actually be OK for o32 and o64,
7224 but it's still wrong for n32 and n64; see mips_load_call_address.
7225 We must therefore load the address via a temporary register if
7226 mips_dangerous_for_la25_p.
7228 If we jump to the temporary register rather than $25, the assembler
7229 can use the move insn to fill the jump's delay slot. */
7230 if (TARGET_ABICALLS && !mips_dangerous_for_la25_p (fnaddr))
7231 temp1 = gen_rtx_REG (Pmode, PIC_FUNCTION_ADDR_REGNUM);
7232 mips_load_call_address (temp1, fnaddr, true);
7234 if (TARGET_ABICALLS && REGNO (temp1) != PIC_FUNCTION_ADDR_REGNUM)
7235 emit_move_insn (gen_rtx_REG (Pmode, PIC_FUNCTION_ADDR_REGNUM), temp1);
7236 emit_jump_insn (gen_indirect_jump (temp1));
7240 insn = emit_call_insn (gen_sibcall_internal (fnaddr, const0_rtx));
7241 SIBLING_CALL_P (insn) = 1;
7244 /* Run just enough of rest_of_compilation. This sequence was
7245 "borrowed" from alpha.c. */
7246 insn = get_insns ();
7247 insn_locators_initialize ();
7248 split_all_insns_noflow ();
7250 mips16_lay_out_constants ();
7251 shorten_branches (insn);
7252 final_start_function (insn, file, 1);
7253 final (insn, file, 1);
7254 final_end_function ();
7256 /* Clean up the vars set above. Note that final_end_function resets
7257 the global pointer for us. */
7258 reload_completed = 0;
7262 /* Returns nonzero if X contains a SYMBOL_REF. */
7265 symbolic_expression_p (rtx x)
7267 if (GET_CODE (x) == SYMBOL_REF)
7270 if (GET_CODE (x) == CONST)
7271 return symbolic_expression_p (XEXP (x, 0));
7274 return symbolic_expression_p (XEXP (x, 0));
7276 if (ARITHMETIC_P (x))
7277 return (symbolic_expression_p (XEXP (x, 0))
7278 || symbolic_expression_p (XEXP (x, 1)));
7283 /* Choose the section to use for the constant rtx expression X that has
7287 mips_select_rtx_section (enum machine_mode mode, rtx x,
7288 unsigned HOST_WIDE_INT align)
7292 /* In mips16 mode, the constant table always goes in the same section
7293 as the function, so that constants can be loaded using PC relative
7295 return function_section (current_function_decl);
7297 else if (TARGET_EMBEDDED_DATA)
7299 /* For embedded applications, always put constants in read-only data,
7300 in order to reduce RAM usage. */
7301 return mergeable_constant_section (mode, align, 0);
7305 /* For hosted applications, always put constants in small data if
7306 possible, as this gives the best performance. */
7307 /* ??? Consider using mergeable small data sections. */
7309 if (GET_MODE_SIZE (mode) <= (unsigned) mips_section_threshold
7310 && mips_section_threshold > 0)
7311 return get_named_section (NULL, ".sdata", 0);
7312 else if (flag_pic && symbolic_expression_p (x))
7313 return get_named_section (NULL, ".data.rel.ro", 3);
7315 return mergeable_constant_section (mode, align, 0);
7319 /* Implement TARGET_ASM_FUNCTION_RODATA_SECTION.
7321 The complication here is that, with the combination TARGET_ABICALLS
7322 && !TARGET_GPWORD, jump tables will use absolute addresses, and should
7323 therefore not be included in the read-only part of a DSO. Handle such
7324 cases by selecting a normal data section instead of a read-only one.
7325 The logic apes that in default_function_rodata_section. */
7328 mips_function_rodata_section (tree decl)
7330 if (!TARGET_ABICALLS || TARGET_GPWORD)
7331 return default_function_rodata_section (decl);
7333 if (decl && DECL_SECTION_NAME (decl))
7335 const char *name = TREE_STRING_POINTER (DECL_SECTION_NAME (decl));
7336 if (DECL_ONE_ONLY (decl) && strncmp (name, ".gnu.linkonce.t.", 16) == 0)
7338 char *rname = ASTRDUP (name);
7340 return get_section (rname, SECTION_LINKONCE | SECTION_WRITE, decl);
7342 else if (flag_function_sections && flag_data_sections
7343 && strncmp (name, ".text.", 6) == 0)
7345 char *rname = ASTRDUP (name);
7346 memcpy (rname + 1, "data", 4);
7347 return get_section (rname, SECTION_WRITE, decl);
7350 return data_section;
7353 /* Implement TARGET_IN_SMALL_DATA_P. This function controls whether
7354 locally-defined objects go in a small data section. It also controls
7355 the setting of the SYMBOL_REF_SMALL_P flag, which in turn helps
7356 mips_classify_symbol decide when to use %gp_rel(...)($gp) accesses. */
7359 mips_in_small_data_p (tree decl)
7363 if (TREE_CODE (decl) == STRING_CST || TREE_CODE (decl) == FUNCTION_DECL)
7366 /* We don't yet generate small-data references for -mabicalls. See related
7367 -G handling in override_options. */
7368 if (TARGET_ABICALLS)
7371 if (TREE_CODE (decl) == VAR_DECL && DECL_SECTION_NAME (decl) != 0)
7375 /* Reject anything that isn't in a known small-data section. */
7376 name = TREE_STRING_POINTER (DECL_SECTION_NAME (decl));
7377 if (strcmp (name, ".sdata") != 0 && strcmp (name, ".sbss") != 0)
7380 /* If a symbol is defined externally, the assembler will use the
7381 usual -G rules when deciding how to implement macros. */
7382 if (TARGET_EXPLICIT_RELOCS || !DECL_EXTERNAL (decl))
7385 else if (TARGET_EMBEDDED_DATA)
7387 /* Don't put constants into the small data section: we want them
7388 to be in ROM rather than RAM. */
7389 if (TREE_CODE (decl) != VAR_DECL)
7392 if (TREE_READONLY (decl)
7393 && !TREE_SIDE_EFFECTS (decl)
7394 && (!DECL_INITIAL (decl) || TREE_CONSTANT (DECL_INITIAL (decl))))
7398 size = int_size_in_bytes (TREE_TYPE (decl));
7399 return (size > 0 && size <= mips_section_threshold);
7402 /* Implement TARGET_USE_ANCHORS_FOR_SYMBOL_P. We don't want to use
7403 anchors for small data: the GP register acts as an anchor in that
7404 case. We also don't want to use them for PC-relative accesses,
7405 where the PC acts as an anchor. */
7408 mips_use_anchors_for_symbol_p (rtx symbol)
7410 switch (mips_classify_symbol (symbol))
7412 case SYMBOL_CONSTANT_POOL:
7413 case SYMBOL_SMALL_DATA:
7421 /* See whether VALTYPE is a record whose fields should be returned in
7422 floating-point registers. If so, return the number of fields and
7423 list them in FIELDS (which should have two elements). Return 0
7426 For n32 & n64, a structure with one or two fields is returned in
7427 floating-point registers as long as every field has a floating-point
7431 mips_fpr_return_fields (tree valtype, tree *fields)
7439 if (TREE_CODE (valtype) != RECORD_TYPE)
7443 for (field = TYPE_FIELDS (valtype); field != 0; field = TREE_CHAIN (field))
7445 if (TREE_CODE (field) != FIELD_DECL)
7448 if (TREE_CODE (TREE_TYPE (field)) != REAL_TYPE)
7454 fields[i++] = field;
7460 /* Implement TARGET_RETURN_IN_MSB. For n32 & n64, we should return
7461 a value in the most significant part of $2/$3 if:
7463 - the target is big-endian;
7465 - the value has a structure or union type (we generalize this to
7466 cover aggregates from other languages too); and
7468 - the structure is not returned in floating-point registers. */
7471 mips_return_in_msb (tree valtype)
7475 return (TARGET_NEWABI
7476 && TARGET_BIG_ENDIAN
7477 && AGGREGATE_TYPE_P (valtype)
7478 && mips_fpr_return_fields (valtype, fields) == 0);
7482 /* Return a composite value in a pair of floating-point registers.
7483 MODE1 and OFFSET1 are the mode and byte offset for the first value,
7484 likewise MODE2 and OFFSET2 for the second. MODE is the mode of the
7487 For n32 & n64, $f0 always holds the first value and $f2 the second.
7488 Otherwise the values are packed together as closely as possible. */
7491 mips_return_fpr_pair (enum machine_mode mode,
7492 enum machine_mode mode1, HOST_WIDE_INT offset1,
7493 enum machine_mode mode2, HOST_WIDE_INT offset2)
7497 inc = (TARGET_NEWABI ? 2 : FP_INC);
7498 return gen_rtx_PARALLEL
7501 gen_rtx_EXPR_LIST (VOIDmode,
7502 gen_rtx_REG (mode1, FP_RETURN),
7504 gen_rtx_EXPR_LIST (VOIDmode,
7505 gen_rtx_REG (mode2, FP_RETURN + inc),
7506 GEN_INT (offset2))));
7511 /* Implement FUNCTION_VALUE and LIBCALL_VALUE. For normal calls,
7512 VALTYPE is the return type and MODE is VOIDmode. For libcalls,
7513 VALTYPE is null and MODE is the mode of the return value. */
7516 mips_function_value (tree valtype, tree func ATTRIBUTE_UNUSED,
7517 enum machine_mode mode)
7524 mode = TYPE_MODE (valtype);
7525 unsignedp = TYPE_UNSIGNED (valtype);
7527 /* Since we define TARGET_PROMOTE_FUNCTION_RETURN that returns
7528 true, we must promote the mode just as PROMOTE_MODE does. */
7529 mode = promote_mode (valtype, mode, &unsignedp, 1);
7531 /* Handle structures whose fields are returned in $f0/$f2. */
7532 switch (mips_fpr_return_fields (valtype, fields))
7535 return gen_rtx_REG (mode, FP_RETURN);
7538 return mips_return_fpr_pair (mode,
7539 TYPE_MODE (TREE_TYPE (fields[0])),
7540 int_byte_position (fields[0]),
7541 TYPE_MODE (TREE_TYPE (fields[1])),
7542 int_byte_position (fields[1]));
7545 /* If a value is passed in the most significant part of a register, see
7546 whether we have to round the mode up to a whole number of words. */
7547 if (mips_return_in_msb (valtype))
7549 HOST_WIDE_INT size = int_size_in_bytes (valtype);
7550 if (size % UNITS_PER_WORD != 0)
7552 size += UNITS_PER_WORD - size % UNITS_PER_WORD;
7553 mode = mode_for_size (size * BITS_PER_UNIT, MODE_INT, 0);
7557 /* For EABI, the class of return register depends entirely on MODE.
7558 For example, "struct { some_type x; }" and "union { some_type x; }"
7559 are returned in the same way as a bare "some_type" would be.
7560 Other ABIs only use FPRs for scalar, complex or vector types. */
7561 if (mips_abi != ABI_EABI && !FLOAT_TYPE_P (valtype))
7562 return gen_rtx_REG (mode, GP_RETURN);
7565 if ((GET_MODE_CLASS (mode) == MODE_FLOAT
7566 || GET_MODE_CLASS (mode) == MODE_VECTOR_FLOAT)
7567 && GET_MODE_SIZE (mode) <= UNITS_PER_HWFPVALUE)
7568 return gen_rtx_REG (mode, FP_RETURN);
7570 /* Handle long doubles for n32 & n64. */
7572 return mips_return_fpr_pair (mode,
7574 DImode, GET_MODE_SIZE (mode) / 2);
7576 if (GET_MODE_CLASS (mode) == MODE_COMPLEX_FLOAT
7577 && GET_MODE_SIZE (mode) <= UNITS_PER_HWFPVALUE * 2)
7578 return mips_return_fpr_pair (mode,
7579 GET_MODE_INNER (mode), 0,
7580 GET_MODE_INNER (mode),
7581 GET_MODE_SIZE (mode) / 2);
7583 return gen_rtx_REG (mode, GP_RETURN);
7586 /* Return nonzero when an argument must be passed by reference. */
7589 mips_pass_by_reference (CUMULATIVE_ARGS *cum ATTRIBUTE_UNUSED,
7590 enum machine_mode mode, tree type,
7591 bool named ATTRIBUTE_UNUSED)
7593 if (mips_abi == ABI_EABI)
7597 /* ??? How should SCmode be handled? */
7598 if (mode == DImode || mode == DFmode)
7601 size = type ? int_size_in_bytes (type) : GET_MODE_SIZE (mode);
7602 return size == -1 || size > UNITS_PER_WORD;
7606 /* If we have a variable-sized parameter, we have no choice. */
7607 return targetm.calls.must_pass_in_stack (mode, type);
7612 mips_callee_copies (CUMULATIVE_ARGS *cum ATTRIBUTE_UNUSED,
7613 enum machine_mode mode ATTRIBUTE_UNUSED,
7614 tree type ATTRIBUTE_UNUSED, bool named)
7616 return mips_abi == ABI_EABI && named;
7619 /* Return true if registers of class CLASS cannot change from mode FROM
7623 mips_cannot_change_mode_class (enum machine_mode from,
7624 enum machine_mode to, enum reg_class class)
7626 if (MIN (GET_MODE_SIZE (from), GET_MODE_SIZE (to)) <= UNITS_PER_WORD
7627 && MAX (GET_MODE_SIZE (from), GET_MODE_SIZE (to)) > UNITS_PER_WORD)
7629 if (TARGET_BIG_ENDIAN)
7631 /* When a multi-word value is stored in paired floating-point
7632 registers, the first register always holds the low word.
7633 We therefore can't allow FPRs to change between single-word
7634 and multi-word modes. */
7635 if (FP_INC > 1 && reg_classes_intersect_p (FP_REGS, class))
7640 /* LO_REGNO == HI_REGNO + 1, so if a multi-word value is stored
7641 in LO and HI, the high word always comes first. We therefore
7642 can't allow values stored in HI to change between single-word
7643 and multi-word modes.
7644 This rule applies to both the original HI/LO pair and the new
7645 DSP accumulators. */
7646 if (reg_classes_intersect_p (ACC_REGS, class))
7650 /* Loading a 32-bit value into a 64-bit floating-point register
7651 will not sign-extend the value, despite what LOAD_EXTEND_OP says.
7652 We can't allow 64-bit float registers to change from SImode to
7656 && GET_MODE_SIZE (to) >= UNITS_PER_WORD
7657 && reg_classes_intersect_p (FP_REGS, class))
7662 /* Return true if X should not be moved directly into register $25.
7663 We need this because many versions of GAS will treat "la $25,foo" as
7664 part of a call sequence and so allow a global "foo" to be lazily bound. */
7667 mips_dangerous_for_la25_p (rtx x)
7669 HOST_WIDE_INT offset;
7671 if (TARGET_EXPLICIT_RELOCS)
7674 mips_split_const (x, &x, &offset);
7675 return global_got_operand (x, VOIDmode);
7678 /* Implement PREFERRED_RELOAD_CLASS. */
7681 mips_preferred_reload_class (rtx x, enum reg_class class)
7683 if (mips_dangerous_for_la25_p (x) && reg_class_subset_p (LEA_REGS, class))
7686 if (TARGET_HARD_FLOAT
7687 && FLOAT_MODE_P (GET_MODE (x))
7688 && reg_class_subset_p (FP_REGS, class))
7691 if (reg_class_subset_p (GR_REGS, class))
7694 if (TARGET_MIPS16 && reg_class_subset_p (M16_REGS, class))
7700 /* This function returns the register class required for a secondary
7701 register when copying between one of the registers in CLASS, and X,
7702 using MODE. If IN_P is nonzero, the copy is going from X to the
7703 register, otherwise the register is the source. A return value of
7704 NO_REGS means that no secondary register is required. */
7707 mips_secondary_reload_class (enum reg_class class,
7708 enum machine_mode mode, rtx x, int in_p)
7710 enum reg_class gr_regs = TARGET_MIPS16 ? M16_REGS : GR_REGS;
7714 if (REG_P (x)|| GET_CODE (x) == SUBREG)
7715 regno = true_regnum (x);
7717 gp_reg_p = TARGET_MIPS16 ? M16_REG_P (regno) : GP_REG_P (regno);
7719 if (mips_dangerous_for_la25_p (x))
7722 if (TEST_HARD_REG_BIT (reg_class_contents[(int) class], 25))
7726 /* Copying from HI or LO to anywhere other than a general register
7727 requires a general register.
7728 This rule applies to both the original HI/LO pair and the new
7729 DSP accumulators. */
7730 if (reg_class_subset_p (class, ACC_REGS))
7732 if (TARGET_MIPS16 && in_p)
7734 /* We can't really copy to HI or LO at all in mips16 mode. */
7737 return gp_reg_p ? NO_REGS : gr_regs;
7739 if (ACC_REG_P (regno))
7741 if (TARGET_MIPS16 && ! in_p)
7743 /* We can't really copy to HI or LO at all in mips16 mode. */
7746 return class == gr_regs ? NO_REGS : gr_regs;
7749 /* We can only copy a value to a condition code register from a
7750 floating point register, and even then we require a scratch
7751 floating point register. We can only copy a value out of a
7752 condition code register into a general register. */
7753 if (class == ST_REGS)
7757 return gp_reg_p ? NO_REGS : gr_regs;
7759 if (ST_REG_P (regno))
7763 return class == gr_regs ? NO_REGS : gr_regs;
7766 if (class == FP_REGS)
7770 /* In this case we can use lwc1, swc1, ldc1 or sdc1. */
7773 else if (CONSTANT_P (x) && GET_MODE_CLASS (mode) == MODE_FLOAT)
7775 /* We can use the l.s and l.d macros to load floating-point
7776 constants. ??? For l.s, we could probably get better
7777 code by returning GR_REGS here. */
7780 else if (gp_reg_p || x == CONST0_RTX (mode))
7782 /* In this case we can use mtc1, mfc1, dmtc1 or dmfc1. */
7785 else if (FP_REG_P (regno))
7787 /* In this case we can use mov.s or mov.d. */
7792 /* Otherwise, we need to reload through an integer register. */
7797 /* In mips16 mode, going between memory and anything but M16_REGS
7798 requires an M16_REG. */
7801 if (class != M16_REGS && class != M16_NA_REGS)
7809 if (class == M16_REGS || class == M16_NA_REGS)
7818 /* Implement CLASS_MAX_NREGS.
7820 Usually all registers are word-sized. The only supported exception
7821 is -mgp64 -msingle-float, which has 64-bit words but 32-bit float
7822 registers. A word-based calculation is correct even in that case,
7823 since -msingle-float disallows multi-FPR values.
7825 The FP status registers are an exception to this rule. They are always
7826 4 bytes wide as they only hold condition code modes, and CCmode is always
7827 considered to be 4 bytes wide. */
7830 mips_class_max_nregs (enum reg_class class ATTRIBUTE_UNUSED,
7831 enum machine_mode mode)
7833 if (class == ST_REGS)
7834 return (GET_MODE_SIZE (mode) + 3) / 4;
7836 return (GET_MODE_SIZE (mode) + UNITS_PER_WORD - 1) / UNITS_PER_WORD;
7840 mips_valid_pointer_mode (enum machine_mode mode)
7842 return (mode == SImode || (TARGET_64BIT && mode == DImode));
7845 /* Target hook for vector_mode_supported_p. */
7848 mips_vector_mode_supported_p (enum machine_mode mode)
7853 return TARGET_PAIRED_SINGLE_FLOAT;
7864 /* If we can access small data directly (using gp-relative relocation
7865 operators) return the small data pointer, otherwise return null.
7867 For each mips16 function which refers to GP relative symbols, we
7868 use a pseudo register, initialized at the start of the function, to
7869 hold the $gp value. */
7872 mips16_gp_pseudo_reg (void)
7874 if (cfun->machine->mips16_gp_pseudo_rtx == NULL_RTX)
7879 cfun->machine->mips16_gp_pseudo_rtx = gen_reg_rtx (Pmode);
7881 /* We want to initialize this to a value which gcc will believe
7884 unspec = gen_rtx_UNSPEC (VOIDmode, gen_rtvec (1, const0_rtx), UNSPEC_GP);
7885 emit_move_insn (cfun->machine->mips16_gp_pseudo_rtx,
7886 gen_rtx_CONST (Pmode, unspec));
7887 insn = get_insns ();
7890 push_topmost_sequence ();
7891 /* We need to emit the initialization after the FUNCTION_BEG
7892 note, so that it will be integrated. */
7893 for (scan = get_insns (); scan != NULL_RTX; scan = NEXT_INSN (scan))
7895 && NOTE_LINE_NUMBER (scan) == NOTE_INSN_FUNCTION_BEG)
7897 if (scan == NULL_RTX)
7898 scan = get_insns ();
7899 insn = emit_insn_after (insn, scan);
7900 pop_topmost_sequence ();
7903 return cfun->machine->mips16_gp_pseudo_rtx;
7906 /* Write out code to move floating point arguments in or out of
7907 general registers. Output the instructions to FILE. FP_CODE is
7908 the code describing which arguments are present (see the comment at
7909 the definition of CUMULATIVE_ARGS in mips.h). FROM_FP_P is nonzero if
7910 we are copying from the floating point registers. */
7913 mips16_fp_args (FILE *file, int fp_code, int from_fp_p)
7919 /* This code only works for the original 32 bit ABI and the O64 ABI. */
7920 gcc_assert (TARGET_OLDABI);
7926 gparg = GP_ARG_FIRST;
7927 fparg = FP_ARG_FIRST;
7928 for (f = (unsigned int) fp_code; f != 0; f >>= 2)
7932 if ((fparg & 1) != 0)
7934 fprintf (file, "\t%s\t%s,%s\n", s,
7935 reg_names[gparg], reg_names[fparg]);
7937 else if ((f & 3) == 2)
7940 fprintf (file, "\td%s\t%s,%s\n", s,
7941 reg_names[gparg], reg_names[fparg]);
7944 if ((fparg & 1) != 0)
7946 if (TARGET_BIG_ENDIAN)
7947 fprintf (file, "\t%s\t%s,%s\n\t%s\t%s,%s\n", s,
7948 reg_names[gparg], reg_names[fparg + 1], s,
7949 reg_names[gparg + 1], reg_names[fparg]);
7951 fprintf (file, "\t%s\t%s,%s\n\t%s\t%s,%s\n", s,
7952 reg_names[gparg], reg_names[fparg], s,
7953 reg_names[gparg + 1], reg_names[fparg + 1]);
7966 /* Build a mips16 function stub. This is used for functions which
7967 take arguments in the floating point registers. It is 32 bit code
7968 that moves the floating point args into the general registers, and
7969 then jumps to the 16 bit code. */
7972 build_mips16_function_stub (FILE *file)
7975 char *secname, *stubname;
7976 tree stubid, stubdecl;
7980 fnname = XSTR (XEXP (DECL_RTL (current_function_decl), 0), 0);
7981 secname = (char *) alloca (strlen (fnname) + 20);
7982 sprintf (secname, ".mips16.fn.%s", fnname);
7983 stubname = (char *) alloca (strlen (fnname) + 20);
7984 sprintf (stubname, "__fn_stub_%s", fnname);
7985 stubid = get_identifier (stubname);
7986 stubdecl = build_decl (FUNCTION_DECL, stubid,
7987 build_function_type (void_type_node, NULL_TREE));
7988 DECL_SECTION_NAME (stubdecl) = build_string (strlen (secname), secname);
7990 fprintf (file, "\t# Stub function for %s (", current_function_name ());
7992 for (f = (unsigned int) current_function_args_info.fp_code; f != 0; f >>= 2)
7994 fprintf (file, "%s%s",
7995 need_comma ? ", " : "",
7996 (f & 3) == 1 ? "float" : "double");
7999 fprintf (file, ")\n");
8001 fprintf (file, "\t.set\tnomips16\n");
8002 switch_to_section (function_section (stubdecl));
8003 ASM_OUTPUT_ALIGN (file, floor_log2 (FUNCTION_BOUNDARY / BITS_PER_UNIT));
8005 /* ??? If FUNCTION_NAME_ALREADY_DECLARED is defined, then we are
8006 within a .ent, and we cannot emit another .ent. */
8007 if (!FUNCTION_NAME_ALREADY_DECLARED)
8009 fputs ("\t.ent\t", file);
8010 assemble_name (file, stubname);
8014 assemble_name (file, stubname);
8015 fputs (":\n", file);
8017 /* We don't want the assembler to insert any nops here. */
8018 fprintf (file, "\t.set\tnoreorder\n");
8020 mips16_fp_args (file, current_function_args_info.fp_code, 1);
8022 fprintf (asm_out_file, "\t.set\tnoat\n");
8023 fprintf (asm_out_file, "\tla\t%s,", reg_names[GP_REG_FIRST + 1]);
8024 assemble_name (file, fnname);
8025 fprintf (file, "\n");
8026 fprintf (asm_out_file, "\tjr\t%s\n", reg_names[GP_REG_FIRST + 1]);
8027 fprintf (asm_out_file, "\t.set\tat\n");
8029 /* Unfortunately, we can't fill the jump delay slot. We can't fill
8030 with one of the mfc1 instructions, because the result is not
8031 available for one instruction, so if the very first instruction
8032 in the function refers to the register, it will see the wrong
8034 fprintf (file, "\tnop\n");
8036 fprintf (file, "\t.set\treorder\n");
8038 if (!FUNCTION_NAME_ALREADY_DECLARED)
8040 fputs ("\t.end\t", file);
8041 assemble_name (file, stubname);
8045 fprintf (file, "\t.set\tmips16\n");
8047 switch_to_section (function_section (current_function_decl));
8050 /* We keep a list of functions for which we have already built stubs
8051 in build_mips16_call_stub. */
8055 struct mips16_stub *next;
8060 static struct mips16_stub *mips16_stubs;
8062 /* Build a call stub for a mips16 call. A stub is needed if we are
8063 passing any floating point values which should go into the floating
8064 point registers. If we are, and the call turns out to be to a 32
8065 bit function, the stub will be used to move the values into the
8066 floating point registers before calling the 32 bit function. The
8067 linker will magically adjust the function call to either the 16 bit
8068 function or the 32 bit stub, depending upon where the function call
8069 is actually defined.
8071 Similarly, we need a stub if the return value might come back in a
8072 floating point register.
8074 RETVAL is the location of the return value, or null if this is
8075 a call rather than a call_value. FN is the address of the
8076 function and ARG_SIZE is the size of the arguments. FP_CODE
8077 is the code built by function_arg. This function returns a nonzero
8078 value if it builds the call instruction itself. */
8081 build_mips16_call_stub (rtx retval, rtx fn, rtx arg_size, int fp_code)
8085 char *secname, *stubname;
8086 struct mips16_stub *l;
8087 tree stubid, stubdecl;
8091 /* We don't need to do anything if we aren't in mips16 mode, or if
8092 we were invoked with the -msoft-float option. */
8093 if (! TARGET_MIPS16 || ! mips16_hard_float)
8096 /* Figure out whether the value might come back in a floating point
8098 fpret = (retval != 0
8099 && GET_MODE_CLASS (GET_MODE (retval)) == MODE_FLOAT
8100 && GET_MODE_SIZE (GET_MODE (retval)) <= UNITS_PER_FPVALUE);
8102 /* We don't need to do anything if there were no floating point
8103 arguments and the value will not be returned in a floating point
8105 if (fp_code == 0 && ! fpret)
8108 /* We don't need to do anything if this is a call to a special
8109 mips16 support function. */
8110 if (GET_CODE (fn) == SYMBOL_REF
8111 && strncmp (XSTR (fn, 0), "__mips16_", 9) == 0)
8114 /* This code will only work for o32 and o64 abis. The other ABI's
8115 require more sophisticated support. */
8116 gcc_assert (TARGET_OLDABI);
8118 /* We can only handle SFmode and DFmode floating point return
8121 gcc_assert (GET_MODE (retval) == SFmode || GET_MODE (retval) == DFmode);
8123 /* If we're calling via a function pointer, then we must always call
8124 via a stub. There are magic stubs provided in libgcc.a for each
8125 of the required cases. Each of them expects the function address
8126 to arrive in register $2. */
8128 if (GET_CODE (fn) != SYMBOL_REF)
8134 /* ??? If this code is modified to support other ABI's, we need
8135 to handle PARALLEL return values here. */
8137 sprintf (buf, "__mips16_call_stub_%s%d",
8139 ? (GET_MODE (retval) == SFmode ? "sf_" : "df_")
8142 id = get_identifier (buf);
8143 stub_fn = gen_rtx_SYMBOL_REF (Pmode, IDENTIFIER_POINTER (id));
8145 emit_move_insn (gen_rtx_REG (Pmode, 2), fn);
8147 if (retval == NULL_RTX)
8148 insn = gen_call_internal (stub_fn, arg_size);
8150 insn = gen_call_value_internal (retval, stub_fn, arg_size);
8151 insn = emit_call_insn (insn);
8153 /* Put the register usage information on the CALL. */
8154 CALL_INSN_FUNCTION_USAGE (insn) =
8155 gen_rtx_EXPR_LIST (VOIDmode,
8156 gen_rtx_USE (VOIDmode, gen_rtx_REG (Pmode, 2)),
8157 CALL_INSN_FUNCTION_USAGE (insn));
8159 /* If we are handling a floating point return value, we need to
8160 save $18 in the function prologue. Putting a note on the
8161 call will mean that regs_ever_live[$18] will be true if the
8162 call is not eliminated, and we can check that in the prologue
8165 CALL_INSN_FUNCTION_USAGE (insn) =
8166 gen_rtx_EXPR_LIST (VOIDmode,
8167 gen_rtx_USE (VOIDmode,
8168 gen_rtx_REG (word_mode, 18)),
8169 CALL_INSN_FUNCTION_USAGE (insn));
8171 /* Return 1 to tell the caller that we've generated the call
8176 /* We know the function we are going to call. If we have already
8177 built a stub, we don't need to do anything further. */
8179 fnname = XSTR (fn, 0);
8180 for (l = mips16_stubs; l != NULL; l = l->next)
8181 if (strcmp (l->name, fnname) == 0)
8186 /* Build a special purpose stub. When the linker sees a
8187 function call in mips16 code, it will check where the target
8188 is defined. If the target is a 32 bit call, the linker will
8189 search for the section defined here. It can tell which
8190 symbol this section is associated with by looking at the
8191 relocation information (the name is unreliable, since this
8192 might be a static function). If such a section is found, the
8193 linker will redirect the call to the start of the magic
8196 If the function does not return a floating point value, the
8197 special stub section is named
8200 If the function does return a floating point value, the stub
8202 .mips16.call.fp.FNNAME
8205 secname = (char *) alloca (strlen (fnname) + 40);
8206 sprintf (secname, ".mips16.call.%s%s",
8209 stubname = (char *) alloca (strlen (fnname) + 20);
8210 sprintf (stubname, "__call_stub_%s%s",
8213 stubid = get_identifier (stubname);
8214 stubdecl = build_decl (FUNCTION_DECL, stubid,
8215 build_function_type (void_type_node, NULL_TREE));
8216 DECL_SECTION_NAME (stubdecl) = build_string (strlen (secname), secname);
8218 fprintf (asm_out_file, "\t# Stub function to call %s%s (",
8220 ? (GET_MODE (retval) == SFmode ? "float " : "double ")
8224 for (f = (unsigned int) fp_code; f != 0; f >>= 2)
8226 fprintf (asm_out_file, "%s%s",
8227 need_comma ? ", " : "",
8228 (f & 3) == 1 ? "float" : "double");
8231 fprintf (asm_out_file, ")\n");
8233 fprintf (asm_out_file, "\t.set\tnomips16\n");
8234 assemble_start_function (stubdecl, stubname);
8236 if (!FUNCTION_NAME_ALREADY_DECLARED)
8238 fputs ("\t.ent\t", asm_out_file);
8239 assemble_name (asm_out_file, stubname);
8240 fputs ("\n", asm_out_file);
8242 assemble_name (asm_out_file, stubname);
8243 fputs (":\n", asm_out_file);
8246 /* We build the stub code by hand. That's the only way we can
8247 do it, since we can't generate 32 bit code during a 16 bit
8250 /* We don't want the assembler to insert any nops here. */
8251 fprintf (asm_out_file, "\t.set\tnoreorder\n");
8253 mips16_fp_args (asm_out_file, fp_code, 0);
8257 fprintf (asm_out_file, "\t.set\tnoat\n");
8258 fprintf (asm_out_file, "\tla\t%s,%s\n", reg_names[GP_REG_FIRST + 1],
8260 fprintf (asm_out_file, "\tjr\t%s\n", reg_names[GP_REG_FIRST + 1]);
8261 fprintf (asm_out_file, "\t.set\tat\n");
8262 /* Unfortunately, we can't fill the jump delay slot. We
8263 can't fill with one of the mtc1 instructions, because the
8264 result is not available for one instruction, so if the
8265 very first instruction in the function refers to the
8266 register, it will see the wrong value. */
8267 fprintf (asm_out_file, "\tnop\n");
8271 fprintf (asm_out_file, "\tmove\t%s,%s\n",
8272 reg_names[GP_REG_FIRST + 18], reg_names[GP_REG_FIRST + 31]);
8273 fprintf (asm_out_file, "\tjal\t%s\n", fnname);
8274 /* As above, we can't fill the delay slot. */
8275 fprintf (asm_out_file, "\tnop\n");
8276 if (GET_MODE (retval) == SFmode)
8277 fprintf (asm_out_file, "\tmfc1\t%s,%s\n",
8278 reg_names[GP_REG_FIRST + 2], reg_names[FP_REG_FIRST + 0]);
8281 if (TARGET_BIG_ENDIAN)
8283 fprintf (asm_out_file, "\tmfc1\t%s,%s\n",
8284 reg_names[GP_REG_FIRST + 2],
8285 reg_names[FP_REG_FIRST + 1]);
8286 fprintf (asm_out_file, "\tmfc1\t%s,%s\n",
8287 reg_names[GP_REG_FIRST + 3],
8288 reg_names[FP_REG_FIRST + 0]);
8292 fprintf (asm_out_file, "\tmfc1\t%s,%s\n",
8293 reg_names[GP_REG_FIRST + 2],
8294 reg_names[FP_REG_FIRST + 0]);
8295 fprintf (asm_out_file, "\tmfc1\t%s,%s\n",
8296 reg_names[GP_REG_FIRST + 3],
8297 reg_names[FP_REG_FIRST + 1]);
8300 fprintf (asm_out_file, "\tj\t%s\n", reg_names[GP_REG_FIRST + 18]);
8301 /* As above, we can't fill the delay slot. */
8302 fprintf (asm_out_file, "\tnop\n");
8305 fprintf (asm_out_file, "\t.set\treorder\n");
8307 #ifdef ASM_DECLARE_FUNCTION_SIZE
8308 ASM_DECLARE_FUNCTION_SIZE (asm_out_file, stubname, stubdecl);
8311 if (!FUNCTION_NAME_ALREADY_DECLARED)
8313 fputs ("\t.end\t", asm_out_file);
8314 assemble_name (asm_out_file, stubname);
8315 fputs ("\n", asm_out_file);
8318 fprintf (asm_out_file, "\t.set\tmips16\n");
8320 /* Record this stub. */
8321 l = (struct mips16_stub *) xmalloc (sizeof *l);
8322 l->name = xstrdup (fnname);
8324 l->next = mips16_stubs;
8328 /* If we expect a floating point return value, but we've built a
8329 stub which does not expect one, then we're in trouble. We can't
8330 use the existing stub, because it won't handle the floating point
8331 value. We can't build a new stub, because the linker won't know
8332 which stub to use for the various calls in this object file.
8333 Fortunately, this case is illegal, since it means that a function
8334 was declared in two different ways in a single compilation. */
8335 if (fpret && ! l->fpret)
8336 error ("cannot handle inconsistent calls to %qs", fnname);
8338 /* If we are calling a stub which handles a floating point return
8339 value, we need to arrange to save $18 in the prologue. We do
8340 this by marking the function call as using the register. The
8341 prologue will later see that it is used, and emit code to save
8348 if (retval == NULL_RTX)
8349 insn = gen_call_internal (fn, arg_size);
8351 insn = gen_call_value_internal (retval, fn, arg_size);
8352 insn = emit_call_insn (insn);
8354 CALL_INSN_FUNCTION_USAGE (insn) =
8355 gen_rtx_EXPR_LIST (VOIDmode,
8356 gen_rtx_USE (VOIDmode, gen_rtx_REG (word_mode, 18)),
8357 CALL_INSN_FUNCTION_USAGE (insn));
8359 /* Return 1 to tell the caller that we've generated the call
8364 /* Return 0 to let the caller generate the call insn. */
8368 /* An entry in the mips16 constant pool. VALUE is the pool constant,
8369 MODE is its mode, and LABEL is the CODE_LABEL associated with it. */
8371 struct mips16_constant {
8372 struct mips16_constant *next;
8375 enum machine_mode mode;
8378 /* Information about an incomplete mips16 constant pool. FIRST is the
8379 first constant, HIGHEST_ADDRESS is the highest address that the first
8380 byte of the pool can have, and INSN_ADDRESS is the current instruction
8383 struct mips16_constant_pool {
8384 struct mips16_constant *first;
8385 int highest_address;
8389 /* Add constant VALUE to POOL and return its label. MODE is the
8390 value's mode (used for CONST_INTs, etc.). */
8393 add_constant (struct mips16_constant_pool *pool,
8394 rtx value, enum machine_mode mode)
8396 struct mips16_constant **p, *c;
8397 bool first_of_size_p;
8399 /* See whether the constant is already in the pool. If so, return the
8400 existing label, otherwise leave P pointing to the place where the
8401 constant should be added.
8403 Keep the pool sorted in increasing order of mode size so that we can
8404 reduce the number of alignments needed. */
8405 first_of_size_p = true;
8406 for (p = &pool->first; *p != 0; p = &(*p)->next)
8408 if (mode == (*p)->mode && rtx_equal_p (value, (*p)->value))
8410 if (GET_MODE_SIZE (mode) < GET_MODE_SIZE ((*p)->mode))
8412 if (GET_MODE_SIZE (mode) == GET_MODE_SIZE ((*p)->mode))
8413 first_of_size_p = false;
8416 /* In the worst case, the constant needed by the earliest instruction
8417 will end up at the end of the pool. The entire pool must then be
8418 accessible from that instruction.
8420 When adding the first constant, set the pool's highest address to
8421 the address of the first out-of-range byte. Adjust this address
8422 downwards each time a new constant is added. */
8423 if (pool->first == 0)
8424 /* For pc-relative lw, addiu and daddiu instructions, the base PC value
8425 is the address of the instruction with the lowest two bits clear.
8426 The base PC value for ld has the lowest three bits clear. Assume
8427 the worst case here. */
8428 pool->highest_address = pool->insn_address - (UNITS_PER_WORD - 2) + 0x8000;
8429 pool->highest_address -= GET_MODE_SIZE (mode);
8430 if (first_of_size_p)
8431 /* Take into account the worst possible padding due to alignment. */
8432 pool->highest_address -= GET_MODE_SIZE (mode) - 1;
8434 /* Create a new entry. */
8435 c = (struct mips16_constant *) xmalloc (sizeof *c);
8438 c->label = gen_label_rtx ();
8445 /* Output constant VALUE after instruction INSN and return the last
8446 instruction emitted. MODE is the mode of the constant. */
8449 dump_constants_1 (enum machine_mode mode, rtx value, rtx insn)
8451 switch (GET_MODE_CLASS (mode))
8455 rtx size = GEN_INT (GET_MODE_SIZE (mode));
8456 return emit_insn_after (gen_consttable_int (value, size), insn);
8460 return emit_insn_after (gen_consttable_float (value), insn);
8462 case MODE_VECTOR_FLOAT:
8463 case MODE_VECTOR_INT:
8466 for (i = 0; i < CONST_VECTOR_NUNITS (value); i++)
8467 insn = dump_constants_1 (GET_MODE_INNER (mode),
8468 CONST_VECTOR_ELT (value, i), insn);
8478 /* Dump out the constants in CONSTANTS after INSN. */
8481 dump_constants (struct mips16_constant *constants, rtx insn)
8483 struct mips16_constant *c, *next;
8487 for (c = constants; c != NULL; c = next)
8489 /* If necessary, increase the alignment of PC. */
8490 if (align < GET_MODE_SIZE (c->mode))
8492 int align_log = floor_log2 (GET_MODE_SIZE (c->mode));
8493 insn = emit_insn_after (gen_align (GEN_INT (align_log)), insn);
8495 align = GET_MODE_SIZE (c->mode);
8497 insn = emit_label_after (c->label, insn);
8498 insn = dump_constants_1 (c->mode, c->value, insn);
8504 emit_barrier_after (insn);
8507 /* Return the length of instruction INSN. */
8510 mips16_insn_length (rtx insn)
8514 rtx body = PATTERN (insn);
8515 if (GET_CODE (body) == ADDR_VEC)
8516 return GET_MODE_SIZE (GET_MODE (body)) * XVECLEN (body, 0);
8517 if (GET_CODE (body) == ADDR_DIFF_VEC)
8518 return GET_MODE_SIZE (GET_MODE (body)) * XVECLEN (body, 1);
8520 return get_attr_length (insn);
8523 /* Rewrite *X so that constant pool references refer to the constant's
8524 label instead. DATA points to the constant pool structure. */
8527 mips16_rewrite_pool_refs (rtx *x, void *data)
8529 struct mips16_constant_pool *pool = data;
8530 if (GET_CODE (*x) == SYMBOL_REF && CONSTANT_POOL_ADDRESS_P (*x))
8531 *x = gen_rtx_LABEL_REF (Pmode, add_constant (pool,
8532 get_pool_constant (*x),
8533 get_pool_mode (*x)));
8537 /* Build MIPS16 constant pools. */
8540 mips16_lay_out_constants (void)
8542 struct mips16_constant_pool pool;
8546 memset (&pool, 0, sizeof (pool));
8547 for (insn = get_insns (); insn; insn = NEXT_INSN (insn))
8549 /* Rewrite constant pool references in INSN. */
8551 for_each_rtx (&PATTERN (insn), mips16_rewrite_pool_refs, &pool);
8553 pool.insn_address += mips16_insn_length (insn);
8555 if (pool.first != NULL)
8557 /* If there are no natural barriers between the first user of
8558 the pool and the highest acceptable address, we'll need to
8559 create a new instruction to jump around the constant pool.
8560 In the worst case, this instruction will be 4 bytes long.
8562 If it's too late to do this transformation after INSN,
8563 do it immediately before INSN. */
8564 if (barrier == 0 && pool.insn_address + 4 > pool.highest_address)
8568 label = gen_label_rtx ();
8570 jump = emit_jump_insn_before (gen_jump (label), insn);
8571 JUMP_LABEL (jump) = label;
8572 LABEL_NUSES (label) = 1;
8573 barrier = emit_barrier_after (jump);
8575 emit_label_after (label, barrier);
8576 pool.insn_address += 4;
8579 /* See whether the constant pool is now out of range of the first
8580 user. If so, output the constants after the previous barrier.
8581 Note that any instructions between BARRIER and INSN (inclusive)
8582 will use negative offsets to refer to the pool. */
8583 if (pool.insn_address > pool.highest_address)
8585 dump_constants (pool.first, barrier);
8589 else if (BARRIER_P (insn))
8593 dump_constants (pool.first, get_last_insn ());
8596 /* A temporary variable used by for_each_rtx callbacks, etc. */
8597 static rtx mips_sim_insn;
8599 /* A structure representing the state of the processor pipeline.
8600 Used by the mips_sim_* family of functions. */
8602 /* The maximum number of instructions that can be issued in a cycle.
8603 (Caches mips_issue_rate.) */
8604 unsigned int issue_rate;
8606 /* The current simulation time. */
8609 /* How many more instructions can be issued in the current cycle. */
8610 unsigned int insns_left;
8612 /* LAST_SET[X].INSN is the last instruction to set register X.
8613 LAST_SET[X].TIME is the time at which that instruction was issued.
8614 INSN is null if no instruction has yet set register X. */
8618 } last_set[FIRST_PSEUDO_REGISTER];
8620 /* The pipeline's current DFA state. */
8624 /* Reset STATE to the initial simulation state. */
8627 mips_sim_reset (struct mips_sim *state)
8630 state->insns_left = state->issue_rate;
8631 memset (&state->last_set, 0, sizeof (state->last_set));
8632 state_reset (state->dfa_state);
8635 /* Initialize STATE before its first use. DFA_STATE points to an
8636 allocated but uninitialized DFA state. */
8639 mips_sim_init (struct mips_sim *state, state_t dfa_state)
8641 state->issue_rate = mips_issue_rate ();
8642 state->dfa_state = dfa_state;
8643 mips_sim_reset (state);
8646 /* Advance STATE by one clock cycle. */
8649 mips_sim_next_cycle (struct mips_sim *state)
8652 state->insns_left = state->issue_rate;
8653 state_transition (state->dfa_state, 0);
8656 /* Advance simulation state STATE until instruction INSN can read
8660 mips_sim_wait_reg (struct mips_sim *state, rtx insn, rtx reg)
8664 for (i = 0; i < HARD_REGNO_NREGS (REGNO (reg), GET_MODE (reg)); i++)
8665 if (state->last_set[REGNO (reg) + i].insn != 0)
8669 t = state->last_set[REGNO (reg) + i].time;
8670 t += insn_latency (state->last_set[REGNO (reg) + i].insn, insn);
8671 while (state->time < t)
8672 mips_sim_next_cycle (state);
8676 /* A for_each_rtx callback. If *X is a register, advance simulation state
8677 DATA until mips_sim_insn can read the register's value. */
8680 mips_sim_wait_regs_2 (rtx *x, void *data)
8683 mips_sim_wait_reg (data, mips_sim_insn, *x);
8687 /* Call mips_sim_wait_regs_2 (R, DATA) for each register R mentioned in *X. */
8690 mips_sim_wait_regs_1 (rtx *x, void *data)
8692 for_each_rtx (x, mips_sim_wait_regs_2, data);
8695 /* Advance simulation state STATE until all of INSN's register
8696 dependencies are satisfied. */
8699 mips_sim_wait_regs (struct mips_sim *state, rtx insn)
8701 mips_sim_insn = insn;
8702 note_uses (&PATTERN (insn), mips_sim_wait_regs_1, state);
8705 /* Advance simulation state STATE until the units required by
8706 instruction INSN are available. */
8709 mips_sim_wait_units (struct mips_sim *state, rtx insn)
8713 tmp_state = alloca (state_size ());
8714 while (state->insns_left == 0
8715 || (memcpy (tmp_state, state->dfa_state, state_size ()),
8716 state_transition (tmp_state, insn) >= 0))
8717 mips_sim_next_cycle (state);
8720 /* Advance simulation state STATE until INSN is ready to issue. */
8723 mips_sim_wait_insn (struct mips_sim *state, rtx insn)
8725 mips_sim_wait_regs (state, insn);
8726 mips_sim_wait_units (state, insn);
8729 /* mips_sim_insn has just set X. Update the LAST_SET array
8730 in simulation state DATA. */
8733 mips_sim_record_set (rtx x, rtx pat ATTRIBUTE_UNUSED, void *data)
8735 struct mips_sim *state;
8740 for (i = 0; i < HARD_REGNO_NREGS (REGNO (x), GET_MODE (x)); i++)
8742 state->last_set[REGNO (x) + i].insn = mips_sim_insn;
8743 state->last_set[REGNO (x) + i].time = state->time;
8747 /* Issue instruction INSN in scheduler state STATE. Assume that INSN
8748 can issue immediately (i.e., that mips_sim_wait_insn has already
8752 mips_sim_issue_insn (struct mips_sim *state, rtx insn)
8754 state_transition (state->dfa_state, insn);
8755 state->insns_left--;
8757 mips_sim_insn = insn;
8758 note_stores (PATTERN (insn), mips_sim_record_set, state);
8761 /* Simulate issuing a NOP in state STATE. */
8764 mips_sim_issue_nop (struct mips_sim *state)
8766 if (state->insns_left == 0)
8767 mips_sim_next_cycle (state);
8768 state->insns_left--;
8771 /* Update simulation state STATE so that it's ready to accept the instruction
8772 after INSN. INSN should be part of the main rtl chain, not a member of a
8776 mips_sim_finish_insn (struct mips_sim *state, rtx insn)
8778 /* If INSN is a jump with an implicit delay slot, simulate a nop. */
8780 mips_sim_issue_nop (state);
8782 switch (GET_CODE (SEQ_BEGIN (insn)))
8786 /* We can't predict the processor state after a call or label. */
8787 mips_sim_reset (state);
8791 /* The delay slots of branch likely instructions are only executed
8792 when the branch is taken. Therefore, if the caller has simulated
8793 the delay slot instruction, STATE does not really reflect the state
8794 of the pipeline for the instruction after the delay slot. Also,
8795 branch likely instructions tend to incur a penalty when not taken,
8796 so there will probably be an extra delay between the branch and
8797 the instruction after the delay slot. */
8798 if (INSN_ANNULLED_BRANCH_P (SEQ_BEGIN (insn)))
8799 mips_sim_reset (state);
8807 /* The VR4130 pipeline issues aligned pairs of instructions together,
8808 but it stalls the second instruction if it depends on the first.
8809 In order to cut down the amount of logic required, this dependence
8810 check is not based on a full instruction decode. Instead, any non-SPECIAL
8811 instruction is assumed to modify the register specified by bits 20-16
8812 (which is usually the "rt" field).
8814 In beq, beql, bne and bnel instructions, the rt field is actually an
8815 input, so we can end up with a false dependence between the branch
8816 and its delay slot. If this situation occurs in instruction INSN,
8817 try to avoid it by swapping rs and rt. */
8820 vr4130_avoid_branch_rt_conflict (rtx insn)
8824 first = SEQ_BEGIN (insn);
8825 second = SEQ_END (insn);
8827 && NONJUMP_INSN_P (second)
8828 && GET_CODE (PATTERN (first)) == SET
8829 && GET_CODE (SET_DEST (PATTERN (first))) == PC
8830 && GET_CODE (SET_SRC (PATTERN (first))) == IF_THEN_ELSE)
8832 /* Check for the right kind of condition. */
8833 rtx cond = XEXP (SET_SRC (PATTERN (first)), 0);
8834 if ((GET_CODE (cond) == EQ || GET_CODE (cond) == NE)
8835 && REG_P (XEXP (cond, 0))
8836 && REG_P (XEXP (cond, 1))
8837 && reg_referenced_p (XEXP (cond, 1), PATTERN (second))
8838 && !reg_referenced_p (XEXP (cond, 0), PATTERN (second)))
8840 /* SECOND mentions the rt register but not the rs register. */
8841 rtx tmp = XEXP (cond, 0);
8842 XEXP (cond, 0) = XEXP (cond, 1);
8843 XEXP (cond, 1) = tmp;
8848 /* Implement -mvr4130-align. Go through each basic block and simulate the
8849 processor pipeline. If we find that a pair of instructions could execute
8850 in parallel, and the first of those instruction is not 8-byte aligned,
8851 insert a nop to make it aligned. */
8854 vr4130_align_insns (void)
8856 struct mips_sim state;
8857 rtx insn, subinsn, last, last2, next;
8862 /* LAST is the last instruction before INSN to have a nonzero length.
8863 LAST2 is the last such instruction before LAST. */
8867 /* ALIGNED_P is true if INSN is known to be at an aligned address. */
8870 mips_sim_init (&state, alloca (state_size ()));
8871 for (insn = get_insns (); insn != 0; insn = next)
8873 unsigned int length;
8875 next = NEXT_INSN (insn);
8877 /* See the comment above vr4130_avoid_branch_rt_conflict for details.
8878 This isn't really related to the alignment pass, but we do it on
8879 the fly to avoid a separate instruction walk. */
8880 vr4130_avoid_branch_rt_conflict (insn);
8882 if (USEFUL_INSN_P (insn))
8883 FOR_EACH_SUBINSN (subinsn, insn)
8885 mips_sim_wait_insn (&state, subinsn);
8887 /* If we want this instruction to issue in parallel with the
8888 previous one, make sure that the previous instruction is
8889 aligned. There are several reasons why this isn't worthwhile
8890 when the second instruction is a call:
8892 - Calls are less likely to be performance critical,
8893 - There's a good chance that the delay slot can execute
8894 in parallel with the call.
8895 - The return address would then be unaligned.
8897 In general, if we're going to insert a nop between instructions
8898 X and Y, it's better to insert it immediately after X. That
8899 way, if the nop makes Y aligned, it will also align any labels
8901 if (state.insns_left != state.issue_rate
8902 && !CALL_P (subinsn))
8904 if (subinsn == SEQ_BEGIN (insn) && aligned_p)
8906 /* SUBINSN is the first instruction in INSN and INSN is
8907 aligned. We want to align the previous instruction
8908 instead, so insert a nop between LAST2 and LAST.
8910 Note that LAST could be either a single instruction
8911 or a branch with a delay slot. In the latter case,
8912 LAST, like INSN, is already aligned, but the delay
8913 slot must have some extra delay that stops it from
8914 issuing at the same time as the branch. We therefore
8915 insert a nop before the branch in order to align its
8917 emit_insn_after (gen_nop (), last2);
8920 else if (subinsn != SEQ_BEGIN (insn) && !aligned_p)
8922 /* SUBINSN is the delay slot of INSN, but INSN is
8923 currently unaligned. Insert a nop between
8924 LAST and INSN to align it. */
8925 emit_insn_after (gen_nop (), last);
8929 mips_sim_issue_insn (&state, subinsn);
8931 mips_sim_finish_insn (&state, insn);
8933 /* Update LAST, LAST2 and ALIGNED_P for the next instruction. */
8934 length = get_attr_length (insn);
8937 /* If the instruction is an asm statement or multi-instruction
8938 mips.md patern, the length is only an estimate. Insert an
8939 8 byte alignment after it so that the following instructions
8940 can be handled correctly. */
8941 if (NONJUMP_INSN_P (SEQ_BEGIN (insn))
8942 && (recog_memoized (insn) < 0 || length >= 8))
8944 next = emit_insn_after (gen_align (GEN_INT (3)), insn);
8945 next = NEXT_INSN (next);
8946 mips_sim_next_cycle (&state);
8949 else if (length & 4)
8950 aligned_p = !aligned_p;
8955 /* See whether INSN is an aligned label. */
8956 if (LABEL_P (insn) && label_to_alignment (insn) >= 3)
8962 /* Subroutine of mips_reorg. If there is a hazard between INSN
8963 and a previous instruction, avoid it by inserting nops after
8966 *DELAYED_REG and *HILO_DELAY describe the hazards that apply at
8967 this point. If *DELAYED_REG is non-null, INSN must wait a cycle
8968 before using the value of that register. *HILO_DELAY counts the
8969 number of instructions since the last hilo hazard (that is,
8970 the number of instructions since the last mflo or mfhi).
8972 After inserting nops for INSN, update *DELAYED_REG and *HILO_DELAY
8973 for the next instruction.
8975 LO_REG is an rtx for the LO register, used in dependence checking. */
8978 mips_avoid_hazard (rtx after, rtx insn, int *hilo_delay,
8979 rtx *delayed_reg, rtx lo_reg)
8987 pattern = PATTERN (insn);
8989 /* Do not put the whole function in .set noreorder if it contains
8990 an asm statement. We don't know whether there will be hazards
8991 between the asm statement and the gcc-generated code. */
8992 if (GET_CODE (pattern) == ASM_INPUT || asm_noperands (pattern) >= 0)
8993 cfun->machine->all_noreorder_p = false;
8995 /* Ignore zero-length instructions (barriers and the like). */
8996 ninsns = get_attr_length (insn) / 4;
9000 /* Work out how many nops are needed. Note that we only care about
9001 registers that are explicitly mentioned in the instruction's pattern.
9002 It doesn't matter that calls use the argument registers or that they
9003 clobber hi and lo. */
9004 if (*hilo_delay < 2 && reg_set_p (lo_reg, pattern))
9005 nops = 2 - *hilo_delay;
9006 else if (*delayed_reg != 0 && reg_referenced_p (*delayed_reg, pattern))
9011 /* Insert the nops between this instruction and the previous one.
9012 Each new nop takes us further from the last hilo hazard. */
9013 *hilo_delay += nops;
9015 emit_insn_after (gen_hazard_nop (), after);
9017 /* Set up the state for the next instruction. */
9018 *hilo_delay += ninsns;
9020 if (INSN_CODE (insn) >= 0)
9021 switch (get_attr_hazard (insn))
9031 set = single_set (insn);
9032 gcc_assert (set != 0);
9033 *delayed_reg = SET_DEST (set);
9039 /* Go through the instruction stream and insert nops where necessary.
9040 See if the whole function can then be put into .set noreorder &
9044 mips_avoid_hazards (void)
9046 rtx insn, last_insn, lo_reg, delayed_reg;
9049 /* Force all instructions to be split into their final form. */
9050 split_all_insns_noflow ();
9052 /* Recalculate instruction lengths without taking nops into account. */
9053 cfun->machine->ignore_hazard_length_p = true;
9054 shorten_branches (get_insns ());
9056 cfun->machine->all_noreorder_p = true;
9058 /* Profiled functions can't be all noreorder because the profiler
9059 support uses assembler macros. */
9060 if (current_function_profile)
9061 cfun->machine->all_noreorder_p = false;
9063 /* Code compiled with -mfix-vr4120 can't be all noreorder because
9064 we rely on the assembler to work around some errata. */
9065 if (TARGET_FIX_VR4120)
9066 cfun->machine->all_noreorder_p = false;
9068 /* The same is true for -mfix-vr4130 if we might generate mflo or
9069 mfhi instructions. Note that we avoid using mflo and mfhi if
9070 the VR4130 macc and dmacc instructions are available instead;
9071 see the *mfhilo_{si,di}_macc patterns. */
9072 if (TARGET_FIX_VR4130 && !ISA_HAS_MACCHI)
9073 cfun->machine->all_noreorder_p = false;
9078 lo_reg = gen_rtx_REG (SImode, LO_REGNUM);
9080 for (insn = get_insns (); insn != 0; insn = NEXT_INSN (insn))
9083 if (GET_CODE (PATTERN (insn)) == SEQUENCE)
9084 for (i = 0; i < XVECLEN (PATTERN (insn), 0); i++)
9085 mips_avoid_hazard (last_insn, XVECEXP (PATTERN (insn), 0, i),
9086 &hilo_delay, &delayed_reg, lo_reg);
9088 mips_avoid_hazard (last_insn, insn, &hilo_delay,
9089 &delayed_reg, lo_reg);
9096 /* Implement TARGET_MACHINE_DEPENDENT_REORG. */
9102 mips16_lay_out_constants ();
9103 else if (TARGET_EXPLICIT_RELOCS)
9105 if (mips_flag_delayed_branch)
9106 dbr_schedule (get_insns ());
9107 mips_avoid_hazards ();
9108 if (TUNE_MIPS4130 && TARGET_VR4130_ALIGN)
9109 vr4130_align_insns ();
9113 /* This function does three things:
9115 - Register the special divsi3 and modsi3 functions if -mfix-vr4120.
9116 - Register the mips16 hardware floating point stubs.
9117 - Register the gofast functions if selected using --enable-gofast. */
9119 #include "config/gofast.h"
9122 mips_init_libfuncs (void)
9124 if (TARGET_FIX_VR4120)
9126 set_optab_libfunc (sdiv_optab, SImode, "__vr4120_divsi3");
9127 set_optab_libfunc (smod_optab, SImode, "__vr4120_modsi3");
9130 if (TARGET_MIPS16 && mips16_hard_float)
9132 set_optab_libfunc (add_optab, SFmode, "__mips16_addsf3");
9133 set_optab_libfunc (sub_optab, SFmode, "__mips16_subsf3");
9134 set_optab_libfunc (smul_optab, SFmode, "__mips16_mulsf3");
9135 set_optab_libfunc (sdiv_optab, SFmode, "__mips16_divsf3");
9137 set_optab_libfunc (eq_optab, SFmode, "__mips16_eqsf2");
9138 set_optab_libfunc (ne_optab, SFmode, "__mips16_nesf2");
9139 set_optab_libfunc (gt_optab, SFmode, "__mips16_gtsf2");
9140 set_optab_libfunc (ge_optab, SFmode, "__mips16_gesf2");
9141 set_optab_libfunc (lt_optab, SFmode, "__mips16_ltsf2");
9142 set_optab_libfunc (le_optab, SFmode, "__mips16_lesf2");
9144 set_conv_libfunc (sfix_optab, SImode, SFmode, "__mips16_fix_truncsfsi");
9145 set_conv_libfunc (sfloat_optab, SFmode, SImode, "__mips16_floatsisf");
9147 if (TARGET_DOUBLE_FLOAT)
9149 set_optab_libfunc (add_optab, DFmode, "__mips16_adddf3");
9150 set_optab_libfunc (sub_optab, DFmode, "__mips16_subdf3");
9151 set_optab_libfunc (smul_optab, DFmode, "__mips16_muldf3");
9152 set_optab_libfunc (sdiv_optab, DFmode, "__mips16_divdf3");
9154 set_optab_libfunc (eq_optab, DFmode, "__mips16_eqdf2");
9155 set_optab_libfunc (ne_optab, DFmode, "__mips16_nedf2");
9156 set_optab_libfunc (gt_optab, DFmode, "__mips16_gtdf2");
9157 set_optab_libfunc (ge_optab, DFmode, "__mips16_gedf2");
9158 set_optab_libfunc (lt_optab, DFmode, "__mips16_ltdf2");
9159 set_optab_libfunc (le_optab, DFmode, "__mips16_ledf2");
9161 set_conv_libfunc (sext_optab, DFmode, SFmode, "__mips16_extendsfdf2");
9162 set_conv_libfunc (trunc_optab, SFmode, DFmode, "__mips16_truncdfsf2");
9164 set_conv_libfunc (sfix_optab, SImode, DFmode, "__mips16_fix_truncdfsi");
9165 set_conv_libfunc (sfloat_optab, DFmode, SImode, "__mips16_floatsidf");
9169 gofast_maybe_init_libfuncs ();
9172 /* Return a number assessing the cost of moving a register in class
9173 FROM to class TO. The classes are expressed using the enumeration
9174 values such as `GENERAL_REGS'. A value of 2 is the default; other
9175 values are interpreted relative to that.
9177 It is not required that the cost always equal 2 when FROM is the
9178 same as TO; on some machines it is expensive to move between
9179 registers if they are not general registers.
9181 If reload sees an insn consisting of a single `set' between two
9182 hard registers, and if `REGISTER_MOVE_COST' applied to their
9183 classes returns a value of 2, reload does not check to ensure that
9184 the constraints of the insn are met. Setting a cost of other than
9185 2 will allow reload to verify that the constraints are met. You
9186 should do this if the `movM' pattern's constraints do not allow
9189 ??? We make the cost of moving from HI/LO into general
9190 registers the same as for one of moving general registers to
9191 HI/LO for TARGET_MIPS16 in order to prevent allocating a
9192 pseudo to HI/LO. This might hurt optimizations though, it
9193 isn't clear if it is wise. And it might not work in all cases. We
9194 could solve the DImode LO reg problem by using a multiply, just
9195 like reload_{in,out}si. We could solve the SImode/HImode HI reg
9196 problem by using divide instructions. divu puts the remainder in
9197 the HI reg, so doing a divide by -1 will move the value in the HI
9198 reg for all values except -1. We could handle that case by using a
9199 signed divide, e.g. -1 / 2 (or maybe 1 / -2?). We'd have to emit
9200 a compare/branch to test the input value to see which instruction
9201 we need to use. This gets pretty messy, but it is feasible. */
9204 mips_register_move_cost (enum machine_mode mode ATTRIBUTE_UNUSED,
9205 enum reg_class to, enum reg_class from)
9207 if (from == M16_REGS && GR_REG_CLASS_P (to))
9209 else if (from == M16_NA_REGS && GR_REG_CLASS_P (to))
9211 else if (GR_REG_CLASS_P (from))
9215 else if (to == M16_NA_REGS)
9217 else if (GR_REG_CLASS_P (to))
9224 else if (to == FP_REGS)
9226 else if (reg_class_subset_p (to, ACC_REGS))
9233 else if (COP_REG_CLASS_P (to))
9238 else if (from == FP_REGS)
9240 if (GR_REG_CLASS_P (to))
9242 else if (to == FP_REGS)
9244 else if (to == ST_REGS)
9247 else if (reg_class_subset_p (from, ACC_REGS))
9249 if (GR_REG_CLASS_P (to))
9257 else if (from == ST_REGS && GR_REG_CLASS_P (to))
9259 else if (COP_REG_CLASS_P (from))
9265 ??? What cases are these? Shouldn't we return 2 here? */
9270 /* Return the length of INSN. LENGTH is the initial length computed by
9271 attributes in the machine-description file. */
9274 mips_adjust_insn_length (rtx insn, int length)
9276 /* A unconditional jump has an unfilled delay slot if it is not part
9277 of a sequence. A conditional jump normally has a delay slot, but
9278 does not on MIPS16. */
9279 if (CALL_P (insn) || (TARGET_MIPS16 ? simplejump_p (insn) : JUMP_P (insn)))
9282 /* See how many nops might be needed to avoid hardware hazards. */
9283 if (!cfun->machine->ignore_hazard_length_p && INSN_CODE (insn) >= 0)
9284 switch (get_attr_hazard (insn))
9298 /* All MIPS16 instructions are a measly two bytes. */
9306 /* Return an asm sequence to start a noat block and load the address
9307 of a label into $1. */
9310 mips_output_load_label (void)
9312 if (TARGET_EXPLICIT_RELOCS)
9316 return "%[lw\t%@,%%got_page(%0)(%+)\n\taddiu\t%@,%@,%%got_ofst(%0)";
9319 return "%[ld\t%@,%%got_page(%0)(%+)\n\tdaddiu\t%@,%@,%%got_ofst(%0)";
9322 if (ISA_HAS_LOAD_DELAY)
9323 return "%[lw\t%@,%%got(%0)(%+)%#\n\taddiu\t%@,%@,%%lo(%0)";
9324 return "%[lw\t%@,%%got(%0)(%+)\n\taddiu\t%@,%@,%%lo(%0)";
9328 if (Pmode == DImode)
9329 return "%[dla\t%@,%0";
9331 return "%[la\t%@,%0";
9335 /* Return the assembly code for INSN, which has the operands given by
9336 OPERANDS, and which branches to OPERANDS[1] if some condition is true.
9337 BRANCH_IF_TRUE is the asm template that should be used if OPERANDS[1]
9338 is in range of a direct branch. BRANCH_IF_FALSE is an inverted
9339 version of BRANCH_IF_TRUE. */
9342 mips_output_conditional_branch (rtx insn, rtx *operands,
9343 const char *branch_if_true,
9344 const char *branch_if_false)
9346 unsigned int length;
9347 rtx taken, not_taken;
9349 length = get_attr_length (insn);
9352 /* Just a simple conditional branch. */
9353 mips_branch_likely = (final_sequence && INSN_ANNULLED_BRANCH_P (insn));
9354 return branch_if_true;
9357 /* Generate a reversed branch around a direct jump. This fallback does
9358 not use branch-likely instructions. */
9359 mips_branch_likely = false;
9360 not_taken = gen_label_rtx ();
9361 taken = operands[1];
9363 /* Generate the reversed branch to NOT_TAKEN. */
9364 operands[1] = not_taken;
9365 output_asm_insn (branch_if_false, operands);
9367 /* If INSN has a delay slot, we must provide delay slots for both the
9368 branch to NOT_TAKEN and the conditional jump. We must also ensure
9369 that INSN's delay slot is executed in the appropriate cases. */
9372 /* This first delay slot will always be executed, so use INSN's
9373 delay slot if is not annulled. */
9374 if (!INSN_ANNULLED_BRANCH_P (insn))
9376 final_scan_insn (XVECEXP (final_sequence, 0, 1),
9377 asm_out_file, optimize, 1, NULL);
9378 INSN_DELETED_P (XVECEXP (final_sequence, 0, 1)) = 1;
9381 output_asm_insn ("nop", 0);
9382 fprintf (asm_out_file, "\n");
9385 /* Output the unconditional branch to TAKEN. */
9387 output_asm_insn ("j\t%0%/", &taken);
9390 output_asm_insn (mips_output_load_label (), &taken);
9391 output_asm_insn ("jr\t%@%]%/", 0);
9394 /* Now deal with its delay slot; see above. */
9397 /* This delay slot will only be executed if the branch is taken.
9398 Use INSN's delay slot if is annulled. */
9399 if (INSN_ANNULLED_BRANCH_P (insn))
9401 final_scan_insn (XVECEXP (final_sequence, 0, 1),
9402 asm_out_file, optimize, 1, NULL);
9403 INSN_DELETED_P (XVECEXP (final_sequence, 0, 1)) = 1;
9406 output_asm_insn ("nop", 0);
9407 fprintf (asm_out_file, "\n");
9410 /* Output NOT_TAKEN. */
9411 (*targetm.asm_out.internal_label) (asm_out_file, "L",
9412 CODE_LABEL_NUMBER (not_taken));
9416 /* Return the assembly code for INSN, which branches to OPERANDS[1]
9417 if some ordered condition is true. The condition is given by
9418 OPERANDS[0] if !INVERTED_P, otherwise it is the inverse of
9419 OPERANDS[0]. OPERANDS[2] is the comparison's first operand;
9420 its second is always zero. */
9423 mips_output_order_conditional_branch (rtx insn, rtx *operands, bool inverted_p)
9425 const char *branch[2];
9427 /* Make BRANCH[1] branch to OPERANDS[1] when the condition is true.
9428 Make BRANCH[0] branch on the inverse condition. */
9429 switch (GET_CODE (operands[0]))
9431 /* These cases are equivalent to comparisons against zero. */
9433 inverted_p = !inverted_p;
9436 branch[!inverted_p] = MIPS_BRANCH ("bne", "%2,%.,%1");
9437 branch[inverted_p] = MIPS_BRANCH ("beq", "%2,%.,%1");
9440 /* These cases are always true or always false. */
9442 inverted_p = !inverted_p;
9445 branch[!inverted_p] = MIPS_BRANCH ("beq", "%.,%.,%1");
9446 branch[inverted_p] = MIPS_BRANCH ("bne", "%.,%.,%1");
9450 branch[!inverted_p] = MIPS_BRANCH ("b%C0z", "%2,%1");
9451 branch[inverted_p] = MIPS_BRANCH ("b%N0z", "%2,%1");
9454 return mips_output_conditional_branch (insn, operands, branch[1], branch[0]);
9457 /* Used to output div or ddiv instruction DIVISION, which has the operands
9458 given by OPERANDS. Add in a divide-by-zero check if needed.
9460 When working around R4000 and R4400 errata, we need to make sure that
9461 the division is not immediately followed by a shift[1][2]. We also
9462 need to stop the division from being put into a branch delay slot[3].
9463 The easiest way to avoid both problems is to add a nop after the
9464 division. When a divide-by-zero check is needed, this nop can be
9465 used to fill the branch delay slot.
9467 [1] If a double-word or a variable shift executes immediately
9468 after starting an integer division, the shift may give an
9469 incorrect result. See quotations of errata #16 and #28 from
9470 "MIPS R4000PC/SC Errata, Processor Revision 2.2 and 3.0"
9471 in mips.md for details.
9473 [2] A similar bug to [1] exists for all revisions of the
9474 R4000 and the R4400 when run in an MC configuration.
9475 From "MIPS R4000MC Errata, Processor Revision 2.2 and 3.0":
9477 "19. In this following sequence:
9479 ddiv (or ddivu or div or divu)
9480 dsll32 (or dsrl32, dsra32)
9482 if an MPT stall occurs, while the divide is slipping the cpu
9483 pipeline, then the following double shift would end up with an
9486 Workaround: The compiler needs to avoid generating any
9487 sequence with divide followed by extended double shift."
9489 This erratum is also present in "MIPS R4400MC Errata, Processor
9490 Revision 1.0" and "MIPS R4400MC Errata, Processor Revision 2.0
9491 & 3.0" as errata #10 and #4, respectively.
9493 [3] From "MIPS R4000PC/SC Errata, Processor Revision 2.2 and 3.0"
9494 (also valid for MIPS R4000MC processors):
9496 "52. R4000SC: This bug does not apply for the R4000PC.
9498 There are two flavors of this bug:
9500 1) If the instruction just after divide takes an RF exception
9501 (tlb-refill, tlb-invalid) and gets an instruction cache
9502 miss (both primary and secondary) and the line which is
9503 currently in secondary cache at this index had the first
9504 data word, where the bits 5..2 are set, then R4000 would
9505 get a wrong result for the div.
9510 ------------------- # end-of page. -tlb-refill
9515 ------------------- # end-of page. -tlb-invalid
9518 2) If the divide is in the taken branch delay slot, where the
9519 target takes RF exception and gets an I-cache miss for the
9520 exception vector or where I-cache miss occurs for the
9521 target address, under the above mentioned scenarios, the
9522 div would get wrong results.
9525 j r2 # to next page mapped or unmapped
9526 div r8,r9 # this bug would be there as long
9527 # as there is an ICache miss and
9528 nop # the "data pattern" is present
9531 beq r0, r0, NextPage # to Next page
9535 This bug is present for div, divu, ddiv, and ddivu
9538 Workaround: For item 1), OS could make sure that the next page
9539 after the divide instruction is also mapped. For item 2), the
9540 compiler could make sure that the divide instruction is not in
9541 the branch delay slot."
9543 These processors have PRId values of 0x00004220 and 0x00004300 for
9544 the R4000 and 0x00004400, 0x00004500 and 0x00004600 for the R4400. */
9547 mips_output_division (const char *division, rtx *operands)
9552 if (TARGET_FIX_R4000 || TARGET_FIX_R4400)
9554 output_asm_insn (s, operands);
9557 if (TARGET_CHECK_ZERO_DIV)
9561 output_asm_insn (s, operands);
9562 s = "bnez\t%2,1f\n\tbreak\t7\n1:";
9564 else if (GENERATE_DIVIDE_TRAPS)
9566 output_asm_insn (s, operands);
9571 output_asm_insn ("%(bne\t%2,%.,1f", operands);
9572 output_asm_insn (s, operands);
9573 s = "break\t7%)\n1:";
9579 /* Return true if GIVEN is the same as CANONICAL, or if it is CANONICAL
9580 with a final "000" replaced by "k". Ignore case.
9582 Note: this function is shared between GCC and GAS. */
9585 mips_strict_matching_cpu_name_p (const char *canonical, const char *given)
9587 while (*given != 0 && TOLOWER (*given) == TOLOWER (*canonical))
9588 given++, canonical++;
9590 return ((*given == 0 && *canonical == 0)
9591 || (strcmp (canonical, "000") == 0 && strcasecmp (given, "k") == 0));
9595 /* Return true if GIVEN matches CANONICAL, where GIVEN is a user-supplied
9596 CPU name. We've traditionally allowed a lot of variation here.
9598 Note: this function is shared between GCC and GAS. */
9601 mips_matching_cpu_name_p (const char *canonical, const char *given)
9603 /* First see if the name matches exactly, or with a final "000"
9605 if (mips_strict_matching_cpu_name_p (canonical, given))
9608 /* If not, try comparing based on numerical designation alone.
9609 See if GIVEN is an unadorned number, or 'r' followed by a number. */
9610 if (TOLOWER (*given) == 'r')
9612 if (!ISDIGIT (*given))
9615 /* Skip over some well-known prefixes in the canonical name,
9616 hoping to find a number there too. */
9617 if (TOLOWER (canonical[0]) == 'v' && TOLOWER (canonical[1]) == 'r')
9619 else if (TOLOWER (canonical[0]) == 'r' && TOLOWER (canonical[1]) == 'm')
9621 else if (TOLOWER (canonical[0]) == 'r')
9624 return mips_strict_matching_cpu_name_p (canonical, given);
9628 /* Return the mips_cpu_info entry for the processor or ISA given
9629 by CPU_STRING. Return null if the string isn't recognized.
9631 A similar function exists in GAS. */
9633 static const struct mips_cpu_info *
9634 mips_parse_cpu (const char *cpu_string)
9636 const struct mips_cpu_info *p;
9639 /* In the past, we allowed upper-case CPU names, but it doesn't
9640 work well with the multilib machinery. */
9641 for (s = cpu_string; *s != 0; s++)
9644 warning (0, "the cpu name must be lower case");
9648 /* 'from-abi' selects the most compatible architecture for the given
9649 ABI: MIPS I for 32-bit ABIs and MIPS III for 64-bit ABIs. For the
9650 EABIs, we have to decide whether we're using the 32-bit or 64-bit
9651 version. Look first at the -mgp options, if given, otherwise base
9652 the choice on MASK_64BIT in TARGET_DEFAULT. */
9653 if (strcasecmp (cpu_string, "from-abi") == 0)
9654 return mips_cpu_info_from_isa (ABI_NEEDS_32BIT_REGS ? 1
9655 : ABI_NEEDS_64BIT_REGS ? 3
9656 : (TARGET_64BIT ? 3 : 1));
9658 /* 'default' has traditionally been a no-op. Probably not very useful. */
9659 if (strcasecmp (cpu_string, "default") == 0)
9662 for (p = mips_cpu_info_table; p->name != 0; p++)
9663 if (mips_matching_cpu_name_p (p->name, cpu_string))
9670 /* Return the processor associated with the given ISA level, or null
9671 if the ISA isn't valid. */
9673 static const struct mips_cpu_info *
9674 mips_cpu_info_from_isa (int isa)
9676 const struct mips_cpu_info *p;
9678 for (p = mips_cpu_info_table; p->name != 0; p++)
9685 /* Implement HARD_REGNO_NREGS. The size of FP registers is controlled
9686 by UNITS_PER_FPREG. The size of FP status registers is always 4, because
9687 they only hold condition code modes, and CCmode is always considered to
9688 be 4 bytes wide. All other registers are word sized. */
9691 mips_hard_regno_nregs (int regno, enum machine_mode mode)
9693 if (ST_REG_P (regno))
9694 return ((GET_MODE_SIZE (mode) + 3) / 4);
9695 else if (! FP_REG_P (regno))
9696 return ((GET_MODE_SIZE (mode) + UNITS_PER_WORD - 1) / UNITS_PER_WORD);
9698 return ((GET_MODE_SIZE (mode) + UNITS_PER_FPREG - 1) / UNITS_PER_FPREG);
9701 /* Implement TARGET_RETURN_IN_MEMORY. Under the old (i.e., 32 and O64 ABIs)
9702 all BLKmode objects are returned in memory. Under the new (N32 and
9703 64-bit MIPS ABIs) small structures are returned in a register.
9704 Objects with varying size must still be returned in memory, of
9708 mips_return_in_memory (tree type, tree fndecl ATTRIBUTE_UNUSED)
9711 return (TYPE_MODE (type) == BLKmode);
9713 return ((int_size_in_bytes (type) > (2 * UNITS_PER_WORD))
9714 || (int_size_in_bytes (type) == -1));
9718 mips_strict_argument_naming (CUMULATIVE_ARGS *ca ATTRIBUTE_UNUSED)
9720 return !TARGET_OLDABI;
9723 /* Return true if INSN is a multiply-add or multiply-subtract
9724 instruction and PREV assigns to the accumulator operand. */
9727 mips_linked_madd_p (rtx prev, rtx insn)
9731 x = single_set (insn);
9737 if (GET_CODE (x) == PLUS
9738 && GET_CODE (XEXP (x, 0)) == MULT
9739 && reg_set_p (XEXP (x, 1), prev))
9742 if (GET_CODE (x) == MINUS
9743 && GET_CODE (XEXP (x, 1)) == MULT
9744 && reg_set_p (XEXP (x, 0), prev))
9750 /* Used by TUNE_MACC_CHAINS to record the last scheduled instruction
9751 that may clobber hi or lo. */
9753 static rtx mips_macc_chains_last_hilo;
9755 /* A TUNE_MACC_CHAINS helper function. Record that instruction INSN has
9756 been scheduled, updating mips_macc_chains_last_hilo appropriately. */
9759 mips_macc_chains_record (rtx insn)
9761 if (get_attr_may_clobber_hilo (insn))
9762 mips_macc_chains_last_hilo = insn;
9765 /* A TUNE_MACC_CHAINS helper function. Search ready queue READY, which
9766 has NREADY elements, looking for a multiply-add or multiply-subtract
9767 instruction that is cumulative with mips_macc_chains_last_hilo.
9768 If there is one, promote it ahead of anything else that might
9769 clobber hi or lo. */
9772 mips_macc_chains_reorder (rtx *ready, int nready)
9776 if (mips_macc_chains_last_hilo != 0)
9777 for (i = nready - 1; i >= 0; i--)
9778 if (mips_linked_madd_p (mips_macc_chains_last_hilo, ready[i]))
9780 for (j = nready - 1; j > i; j--)
9781 if (recog_memoized (ready[j]) >= 0
9782 && get_attr_may_clobber_hilo (ready[j]))
9784 mips_promote_ready (ready, i, j);
9791 /* The last instruction to be scheduled. */
9793 static rtx vr4130_last_insn;
9795 /* A note_stores callback used by vr4130_true_reg_dependence_p. DATA
9796 points to an rtx that is initially an instruction. Nullify the rtx
9797 if the instruction uses the value of register X. */
9800 vr4130_true_reg_dependence_p_1 (rtx x, rtx pat ATTRIBUTE_UNUSED, void *data)
9802 rtx *insn_ptr = data;
9805 && reg_referenced_p (x, PATTERN (*insn_ptr)))
9809 /* Return true if there is true register dependence between vr4130_last_insn
9813 vr4130_true_reg_dependence_p (rtx insn)
9815 note_stores (PATTERN (vr4130_last_insn),
9816 vr4130_true_reg_dependence_p_1, &insn);
9820 /* A TUNE_MIPS4130 helper function. Given that INSN1 is at the head of
9821 the ready queue and that INSN2 is the instruction after it, return
9822 true if it is worth promoting INSN2 ahead of INSN1. Look for cases
9823 in which INSN1 and INSN2 can probably issue in parallel, but for
9824 which (INSN2, INSN1) should be less sensitive to instruction
9825 alignment than (INSN1, INSN2). See 4130.md for more details. */
9828 vr4130_swap_insns_p (rtx insn1, rtx insn2)
9832 /* Check for the following case:
9834 1) there is some other instruction X with an anti dependence on INSN1;
9835 2) X has a higher priority than INSN2; and
9836 3) X is an arithmetic instruction (and thus has no unit restrictions).
9838 If INSN1 is the last instruction blocking X, it would better to
9839 choose (INSN1, X) over (INSN2, INSN1). */
9840 for (dep = INSN_DEPEND (insn1); dep != 0; dep = XEXP (dep, 1))
9841 if (REG_NOTE_KIND (dep) == REG_DEP_ANTI
9842 && INSN_PRIORITY (XEXP (dep, 0)) > INSN_PRIORITY (insn2)
9843 && recog_memoized (XEXP (dep, 0)) >= 0
9844 && get_attr_vr4130_class (XEXP (dep, 0)) == VR4130_CLASS_ALU)
9847 if (vr4130_last_insn != 0
9848 && recog_memoized (insn1) >= 0
9849 && recog_memoized (insn2) >= 0)
9851 /* See whether INSN1 and INSN2 use different execution units,
9852 or if they are both ALU-type instructions. If so, they can
9853 probably execute in parallel. */
9854 enum attr_vr4130_class class1 = get_attr_vr4130_class (insn1);
9855 enum attr_vr4130_class class2 = get_attr_vr4130_class (insn2);
9856 if (class1 != class2 || class1 == VR4130_CLASS_ALU)
9858 /* If only one of the instructions has a dependence on
9859 vr4130_last_insn, prefer to schedule the other one first. */
9860 bool dep1 = vr4130_true_reg_dependence_p (insn1);
9861 bool dep2 = vr4130_true_reg_dependence_p (insn2);
9865 /* Prefer to schedule INSN2 ahead of INSN1 if vr4130_last_insn
9866 is not an ALU-type instruction and if INSN1 uses the same
9867 execution unit. (Note that if this condition holds, we already
9868 know that INSN2 uses a different execution unit.) */
9869 if (class1 != VR4130_CLASS_ALU
9870 && recog_memoized (vr4130_last_insn) >= 0
9871 && class1 == get_attr_vr4130_class (vr4130_last_insn))
9878 /* A TUNE_MIPS4130 helper function. (READY, NREADY) describes a ready
9879 queue with at least two instructions. Swap the first two if
9880 vr4130_swap_insns_p says that it could be worthwhile. */
9883 vr4130_reorder (rtx *ready, int nready)
9885 if (vr4130_swap_insns_p (ready[nready - 1], ready[nready - 2]))
9886 mips_promote_ready (ready, nready - 2, nready - 1);
9889 /* Remove the instruction at index LOWER from ready queue READY and
9890 reinsert it in front of the instruction at index HIGHER. LOWER must
9894 mips_promote_ready (rtx *ready, int lower, int higher)
9899 new_head = ready[lower];
9900 for (i = lower; i < higher; i++)
9901 ready[i] = ready[i + 1];
9902 ready[i] = new_head;
9905 /* Implement TARGET_SCHED_REORDER. */
9908 mips_sched_reorder (FILE *file ATTRIBUTE_UNUSED, int verbose ATTRIBUTE_UNUSED,
9909 rtx *ready, int *nreadyp, int cycle)
9911 if (!reload_completed && TUNE_MACC_CHAINS)
9914 mips_macc_chains_last_hilo = 0;
9916 mips_macc_chains_reorder (ready, *nreadyp);
9918 if (reload_completed && TUNE_MIPS4130 && !TARGET_VR4130_ALIGN)
9921 vr4130_last_insn = 0;
9923 vr4130_reorder (ready, *nreadyp);
9925 return mips_issue_rate ();
9928 /* Implement TARGET_SCHED_VARIABLE_ISSUE. */
9931 mips_variable_issue (FILE *file ATTRIBUTE_UNUSED, int verbose ATTRIBUTE_UNUSED,
9934 switch (GET_CODE (PATTERN (insn)))
9938 /* Don't count USEs and CLOBBERs against the issue rate. */
9943 if (!reload_completed && TUNE_MACC_CHAINS)
9944 mips_macc_chains_record (insn);
9945 vr4130_last_insn = insn;
9951 /* Implement TARGET_SCHED_ADJUST_COST. We assume that anti and output
9952 dependencies have no cost. */
9955 mips_adjust_cost (rtx insn ATTRIBUTE_UNUSED, rtx link,
9956 rtx dep ATTRIBUTE_UNUSED, int cost)
9958 if (REG_NOTE_KIND (link) != 0)
9963 /* Return the number of instructions that can be issued per cycle. */
9966 mips_issue_rate (void)
9970 case PROCESSOR_R4130:
9971 case PROCESSOR_R5400:
9972 case PROCESSOR_R5500:
9973 case PROCESSOR_R7000:
9974 case PROCESSOR_R9000:
9975 case PROCESSOR_OCTEON:
9979 case PROCESSOR_SB1A:
9980 /* This is actually 4, but we get better performance if we claim 3.
9981 This is partly because of unwanted speculative code motion with the
9982 larger number, and partly because in most common cases we can't
9983 reach the theoretical max of 4. */
9991 /* Implements TARGET_SCHED_FIRST_CYCLE_MULTIPASS_DFA_LOOKAHEAD. This should
9992 be as wide as the scheduling freedom in the DFA. */
9995 mips_multipass_dfa_lookahead (void)
9997 /* Can schedule up to 4 of the 6 function units in any one cycle. */
10004 /* Implements a store data bypass check. We need this because the cprestore
10005 pattern is type store, but defined using an UNSPEC. This UNSPEC causes the
10006 default routine to abort. We just return false for that case. */
10007 /* ??? Should try to give a better result here than assuming false. */
10010 mips_store_data_bypass_p (rtx out_insn, rtx in_insn)
10012 if (GET_CODE (PATTERN (in_insn)) == UNSPEC_VOLATILE)
10015 return ! store_data_bypass_p (out_insn, in_insn);
10018 /* Given that we have an rtx of the form (prefetch ... WRITE LOCALITY),
10019 return the first operand of the associated "pref" or "prefx" insn. */
10022 mips_prefetch_cookie (rtx write, rtx locality)
10024 /* store_streamed / load_streamed. */
10025 if (INTVAL (locality) <= 0)
10026 return GEN_INT (INTVAL (write) + 4);
10028 /* store / load. */
10029 if (INTVAL (locality) <= 2)
10032 /* store_retained / load_retained. */
10033 return GEN_INT (INTVAL (write) + 6);
10036 /* MIPS builtin function support. */
10038 struct builtin_description
10040 /* The code of the main .md file instruction. See mips_builtin_type
10041 for more information. */
10042 enum insn_code icode;
10044 /* The floating-point comparison code to use with ICODE, if any. */
10045 enum mips_fp_condition cond;
10047 /* The name of the builtin function. */
10050 /* Specifies how the function should be expanded. */
10051 enum mips_builtin_type builtin_type;
10053 /* The function's prototype. */
10054 enum mips_function_type function_type;
10056 /* The target flags required for this function. */
10060 /* Define a MIPS_BUILTIN_DIRECT function for instruction CODE_FOR_mips_<INSN>.
10061 FUNCTION_TYPE and TARGET_FLAGS are builtin_description fields. */
10062 #define DIRECT_BUILTIN(INSN, FUNCTION_TYPE, TARGET_FLAGS) \
10063 { CODE_FOR_mips_ ## INSN, 0, "__builtin_mips_" #INSN, \
10064 MIPS_BUILTIN_DIRECT, FUNCTION_TYPE, TARGET_FLAGS }
10066 /* Define __builtin_mips_<INSN>_<COND>_{s,d}, both of which require
10068 #define CMP_SCALAR_BUILTINS(INSN, COND, TARGET_FLAGS) \
10069 { CODE_FOR_mips_ ## INSN ## _cond_s, MIPS_FP_COND_ ## COND, \
10070 "__builtin_mips_" #INSN "_" #COND "_s", \
10071 MIPS_BUILTIN_CMP_SINGLE, MIPS_INT_FTYPE_SF_SF, TARGET_FLAGS }, \
10072 { CODE_FOR_mips_ ## INSN ## _cond_d, MIPS_FP_COND_ ## COND, \
10073 "__builtin_mips_" #INSN "_" #COND "_d", \
10074 MIPS_BUILTIN_CMP_SINGLE, MIPS_INT_FTYPE_DF_DF, TARGET_FLAGS }
10076 /* Define __builtin_mips_{any,all,upper,lower}_<INSN>_<COND>_ps.
10077 The lower and upper forms require TARGET_FLAGS while the any and all
10078 forms require MASK_MIPS3D. */
10079 #define CMP_PS_BUILTINS(INSN, COND, TARGET_FLAGS) \
10080 { CODE_FOR_mips_ ## INSN ## _cond_ps, MIPS_FP_COND_ ## COND, \
10081 "__builtin_mips_any_" #INSN "_" #COND "_ps", \
10082 MIPS_BUILTIN_CMP_ANY, MIPS_INT_FTYPE_V2SF_V2SF, MASK_MIPS3D }, \
10083 { CODE_FOR_mips_ ## INSN ## _cond_ps, MIPS_FP_COND_ ## COND, \
10084 "__builtin_mips_all_" #INSN "_" #COND "_ps", \
10085 MIPS_BUILTIN_CMP_ALL, MIPS_INT_FTYPE_V2SF_V2SF, MASK_MIPS3D }, \
10086 { CODE_FOR_mips_ ## INSN ## _cond_ps, MIPS_FP_COND_ ## COND, \
10087 "__builtin_mips_lower_" #INSN "_" #COND "_ps", \
10088 MIPS_BUILTIN_CMP_LOWER, MIPS_INT_FTYPE_V2SF_V2SF, TARGET_FLAGS }, \
10089 { CODE_FOR_mips_ ## INSN ## _cond_ps, MIPS_FP_COND_ ## COND, \
10090 "__builtin_mips_upper_" #INSN "_" #COND "_ps", \
10091 MIPS_BUILTIN_CMP_UPPER, MIPS_INT_FTYPE_V2SF_V2SF, TARGET_FLAGS }
10093 /* Define __builtin_mips_{any,all}_<INSN>_<COND>_4s. The functions
10094 require MASK_MIPS3D. */
10095 #define CMP_4S_BUILTINS(INSN, COND) \
10096 { CODE_FOR_mips_ ## INSN ## _cond_4s, MIPS_FP_COND_ ## COND, \
10097 "__builtin_mips_any_" #INSN "_" #COND "_4s", \
10098 MIPS_BUILTIN_CMP_ANY, MIPS_INT_FTYPE_V2SF_V2SF_V2SF_V2SF, \
10100 { CODE_FOR_mips_ ## INSN ## _cond_4s, MIPS_FP_COND_ ## COND, \
10101 "__builtin_mips_all_" #INSN "_" #COND "_4s", \
10102 MIPS_BUILTIN_CMP_ALL, MIPS_INT_FTYPE_V2SF_V2SF_V2SF_V2SF, \
10105 /* Define __builtin_mips_mov{t,f}_<INSN>_<COND>_ps. The comparison
10106 instruction requires TARGET_FLAGS. */
10107 #define MOVTF_BUILTINS(INSN, COND, TARGET_FLAGS) \
10108 { CODE_FOR_mips_ ## INSN ## _cond_ps, MIPS_FP_COND_ ## COND, \
10109 "__builtin_mips_movt_" #INSN "_" #COND "_ps", \
10110 MIPS_BUILTIN_MOVT, MIPS_V2SF_FTYPE_V2SF_V2SF_V2SF_V2SF, \
10112 { CODE_FOR_mips_ ## INSN ## _cond_ps, MIPS_FP_COND_ ## COND, \
10113 "__builtin_mips_movf_" #INSN "_" #COND "_ps", \
10114 MIPS_BUILTIN_MOVF, MIPS_V2SF_FTYPE_V2SF_V2SF_V2SF_V2SF, \
10117 /* Define all the builtins related to c.cond.fmt condition COND. */
10118 #define CMP_BUILTINS(COND) \
10119 MOVTF_BUILTINS (c, COND, MASK_PAIRED_SINGLE_FLOAT), \
10120 MOVTF_BUILTINS (cabs, COND, MASK_MIPS3D), \
10121 CMP_SCALAR_BUILTINS (cabs, COND, MASK_MIPS3D), \
10122 CMP_PS_BUILTINS (c, COND, MASK_PAIRED_SINGLE_FLOAT), \
10123 CMP_PS_BUILTINS (cabs, COND, MASK_MIPS3D), \
10124 CMP_4S_BUILTINS (c, COND), \
10125 CMP_4S_BUILTINS (cabs, COND)
10127 static const struct builtin_description mips_bdesc[] =
10129 DIRECT_BUILTIN (pll_ps, MIPS_V2SF_FTYPE_V2SF_V2SF, MASK_PAIRED_SINGLE_FLOAT),
10130 DIRECT_BUILTIN (pul_ps, MIPS_V2SF_FTYPE_V2SF_V2SF, MASK_PAIRED_SINGLE_FLOAT),
10131 DIRECT_BUILTIN (plu_ps, MIPS_V2SF_FTYPE_V2SF_V2SF, MASK_PAIRED_SINGLE_FLOAT),
10132 DIRECT_BUILTIN (puu_ps, MIPS_V2SF_FTYPE_V2SF_V2SF, MASK_PAIRED_SINGLE_FLOAT),
10133 DIRECT_BUILTIN (cvt_ps_s, MIPS_V2SF_FTYPE_SF_SF, MASK_PAIRED_SINGLE_FLOAT),
10134 DIRECT_BUILTIN (cvt_s_pl, MIPS_SF_FTYPE_V2SF, MASK_PAIRED_SINGLE_FLOAT),
10135 DIRECT_BUILTIN (cvt_s_pu, MIPS_SF_FTYPE_V2SF, MASK_PAIRED_SINGLE_FLOAT),
10136 DIRECT_BUILTIN (abs_ps, MIPS_V2SF_FTYPE_V2SF, MASK_PAIRED_SINGLE_FLOAT),
10138 DIRECT_BUILTIN (alnv_ps, MIPS_V2SF_FTYPE_V2SF_V2SF_INT,
10139 MASK_PAIRED_SINGLE_FLOAT),
10140 DIRECT_BUILTIN (addr_ps, MIPS_V2SF_FTYPE_V2SF_V2SF, MASK_MIPS3D),
10141 DIRECT_BUILTIN (mulr_ps, MIPS_V2SF_FTYPE_V2SF_V2SF, MASK_MIPS3D),
10142 DIRECT_BUILTIN (cvt_pw_ps, MIPS_V2SF_FTYPE_V2SF, MASK_MIPS3D),
10143 DIRECT_BUILTIN (cvt_ps_pw, MIPS_V2SF_FTYPE_V2SF, MASK_MIPS3D),
10145 DIRECT_BUILTIN (recip1_s, MIPS_SF_FTYPE_SF, MASK_MIPS3D),
10146 DIRECT_BUILTIN (recip1_d, MIPS_DF_FTYPE_DF, MASK_MIPS3D),
10147 DIRECT_BUILTIN (recip1_ps, MIPS_V2SF_FTYPE_V2SF, MASK_MIPS3D),
10148 DIRECT_BUILTIN (recip2_s, MIPS_SF_FTYPE_SF_SF, MASK_MIPS3D),
10149 DIRECT_BUILTIN (recip2_d, MIPS_DF_FTYPE_DF_DF, MASK_MIPS3D),
10150 DIRECT_BUILTIN (recip2_ps, MIPS_V2SF_FTYPE_V2SF_V2SF, MASK_MIPS3D),
10152 DIRECT_BUILTIN (rsqrt1_s, MIPS_SF_FTYPE_SF, MASK_MIPS3D),
10153 DIRECT_BUILTIN (rsqrt1_d, MIPS_DF_FTYPE_DF, MASK_MIPS3D),
10154 DIRECT_BUILTIN (rsqrt1_ps, MIPS_V2SF_FTYPE_V2SF, MASK_MIPS3D),
10155 DIRECT_BUILTIN (rsqrt2_s, MIPS_SF_FTYPE_SF_SF, MASK_MIPS3D),
10156 DIRECT_BUILTIN (rsqrt2_d, MIPS_DF_FTYPE_DF_DF, MASK_MIPS3D),
10157 DIRECT_BUILTIN (rsqrt2_ps, MIPS_V2SF_FTYPE_V2SF_V2SF, MASK_MIPS3D),
10159 MIPS_FP_CONDITIONS (CMP_BUILTINS)
10162 /* Builtin functions for the SB-1 processor. */
10164 #define CODE_FOR_mips_sqrt_ps CODE_FOR_sqrtv2sf2
10166 static const struct builtin_description sb1_bdesc[] =
10168 DIRECT_BUILTIN (sqrt_ps, MIPS_V2SF_FTYPE_V2SF, MASK_PAIRED_SINGLE_FLOAT)
10171 /* Builtin functions for DSP ASE. */
10173 #define CODE_FOR_mips_addq_ph CODE_FOR_addv2hi3
10174 #define CODE_FOR_mips_addu_qb CODE_FOR_addv4qi3
10175 #define CODE_FOR_mips_subq_ph CODE_FOR_subv2hi3
10176 #define CODE_FOR_mips_subu_qb CODE_FOR_subv4qi3
10178 /* Define a MIPS_BUILTIN_DIRECT_NO_TARGET function for instruction
10179 CODE_FOR_mips_<INSN>. FUNCTION_TYPE and TARGET_FLAGS are
10180 builtin_description fields. */
10181 #define DIRECT_NO_TARGET_BUILTIN(INSN, FUNCTION_TYPE, TARGET_FLAGS) \
10182 { CODE_FOR_mips_ ## INSN, 0, "__builtin_mips_" #INSN, \
10183 MIPS_BUILTIN_DIRECT_NO_TARGET, FUNCTION_TYPE, TARGET_FLAGS }
10185 /* Define __builtin_mips_bposge<VALUE>. <VALUE> is 32 for the MIPS32 DSP
10186 branch instruction. TARGET_FLAGS is a builtin_description field. */
10187 #define BPOSGE_BUILTIN(VALUE, TARGET_FLAGS) \
10188 { CODE_FOR_mips_bposge, 0, "__builtin_mips_bposge" #VALUE, \
10189 MIPS_BUILTIN_BPOSGE ## VALUE, MIPS_SI_FTYPE_VOID, TARGET_FLAGS }
10191 static const struct builtin_description dsp_bdesc[] =
10193 DIRECT_BUILTIN (addq_ph, MIPS_V2HI_FTYPE_V2HI_V2HI, MASK_DSP),
10194 DIRECT_BUILTIN (addq_s_ph, MIPS_V2HI_FTYPE_V2HI_V2HI, MASK_DSP),
10195 DIRECT_BUILTIN (addq_s_w, MIPS_SI_FTYPE_SI_SI, MASK_DSP),
10196 DIRECT_BUILTIN (addu_qb, MIPS_V4QI_FTYPE_V4QI_V4QI, MASK_DSP),
10197 DIRECT_BUILTIN (addu_s_qb, MIPS_V4QI_FTYPE_V4QI_V4QI, MASK_DSP),
10198 DIRECT_BUILTIN (subq_ph, MIPS_V2HI_FTYPE_V2HI_V2HI, MASK_DSP),
10199 DIRECT_BUILTIN (subq_s_ph, MIPS_V2HI_FTYPE_V2HI_V2HI, MASK_DSP),
10200 DIRECT_BUILTIN (subq_s_w, MIPS_SI_FTYPE_SI_SI, MASK_DSP),
10201 DIRECT_BUILTIN (subu_qb, MIPS_V4QI_FTYPE_V4QI_V4QI, MASK_DSP),
10202 DIRECT_BUILTIN (subu_s_qb, MIPS_V4QI_FTYPE_V4QI_V4QI, MASK_DSP),
10203 DIRECT_BUILTIN (addsc, MIPS_SI_FTYPE_SI_SI, MASK_DSP),
10204 DIRECT_BUILTIN (addwc, MIPS_SI_FTYPE_SI_SI, MASK_DSP),
10205 DIRECT_BUILTIN (modsub, MIPS_SI_FTYPE_SI_SI, MASK_DSP),
10206 DIRECT_BUILTIN (raddu_w_qb, MIPS_SI_FTYPE_V4QI, MASK_DSP),
10207 DIRECT_BUILTIN (absq_s_ph, MIPS_V2HI_FTYPE_V2HI, MASK_DSP),
10208 DIRECT_BUILTIN (absq_s_w, MIPS_SI_FTYPE_SI, MASK_DSP),
10209 DIRECT_BUILTIN (precrq_qb_ph, MIPS_V4QI_FTYPE_V2HI_V2HI, MASK_DSP),
10210 DIRECT_BUILTIN (precrq_ph_w, MIPS_V2HI_FTYPE_SI_SI, MASK_DSP),
10211 DIRECT_BUILTIN (precrq_rs_ph_w, MIPS_V2HI_FTYPE_SI_SI, MASK_DSP),
10212 DIRECT_BUILTIN (precrqu_s_qb_ph, MIPS_V4QI_FTYPE_V2HI_V2HI, MASK_DSP),
10213 DIRECT_BUILTIN (preceq_w_phl, MIPS_SI_FTYPE_V2HI, MASK_DSP),
10214 DIRECT_BUILTIN (preceq_w_phr, MIPS_SI_FTYPE_V2HI, MASK_DSP),
10215 DIRECT_BUILTIN (precequ_ph_qbl, MIPS_V2HI_FTYPE_V4QI, MASK_DSP),
10216 DIRECT_BUILTIN (precequ_ph_qbr, MIPS_V2HI_FTYPE_V4QI, MASK_DSP),
10217 DIRECT_BUILTIN (precequ_ph_qbla, MIPS_V2HI_FTYPE_V4QI, MASK_DSP),
10218 DIRECT_BUILTIN (precequ_ph_qbra, MIPS_V2HI_FTYPE_V4QI, MASK_DSP),
10219 DIRECT_BUILTIN (preceu_ph_qbl, MIPS_V2HI_FTYPE_V4QI, MASK_DSP),
10220 DIRECT_BUILTIN (preceu_ph_qbr, MIPS_V2HI_FTYPE_V4QI, MASK_DSP),
10221 DIRECT_BUILTIN (preceu_ph_qbla, MIPS_V2HI_FTYPE_V4QI, MASK_DSP),
10222 DIRECT_BUILTIN (preceu_ph_qbra, MIPS_V2HI_FTYPE_V4QI, MASK_DSP),
10223 DIRECT_BUILTIN (shll_qb, MIPS_V4QI_FTYPE_V4QI_SI, MASK_DSP),
10224 DIRECT_BUILTIN (shll_ph, MIPS_V2HI_FTYPE_V2HI_SI, MASK_DSP),
10225 DIRECT_BUILTIN (shll_s_ph, MIPS_V2HI_FTYPE_V2HI_SI, MASK_DSP),
10226 DIRECT_BUILTIN (shll_s_w, MIPS_SI_FTYPE_SI_SI, MASK_DSP),
10227 DIRECT_BUILTIN (shrl_qb, MIPS_V4QI_FTYPE_V4QI_SI, MASK_DSP),
10228 DIRECT_BUILTIN (shra_ph, MIPS_V2HI_FTYPE_V2HI_SI, MASK_DSP),
10229 DIRECT_BUILTIN (shra_r_ph, MIPS_V2HI_FTYPE_V2HI_SI, MASK_DSP),
10230 DIRECT_BUILTIN (shra_r_w, MIPS_SI_FTYPE_SI_SI, MASK_DSP),
10231 DIRECT_BUILTIN (muleu_s_ph_qbl, MIPS_V2HI_FTYPE_V4QI_V2HI, MASK_DSP),
10232 DIRECT_BUILTIN (muleu_s_ph_qbr, MIPS_V2HI_FTYPE_V4QI_V2HI, MASK_DSP),
10233 DIRECT_BUILTIN (mulq_rs_ph, MIPS_V2HI_FTYPE_V2HI_V2HI, MASK_DSP),
10234 DIRECT_BUILTIN (muleq_s_w_phl, MIPS_SI_FTYPE_V2HI_V2HI, MASK_DSP),
10235 DIRECT_BUILTIN (muleq_s_w_phr, MIPS_SI_FTYPE_V2HI_V2HI, MASK_DSP),
10236 DIRECT_BUILTIN (dpau_h_qbl, MIPS_DI_FTYPE_DI_V4QI_V4QI, MASK_DSP),
10237 DIRECT_BUILTIN (dpau_h_qbr, MIPS_DI_FTYPE_DI_V4QI_V4QI, MASK_DSP),
10238 DIRECT_BUILTIN (dpsu_h_qbl, MIPS_DI_FTYPE_DI_V4QI_V4QI, MASK_DSP),
10239 DIRECT_BUILTIN (dpsu_h_qbr, MIPS_DI_FTYPE_DI_V4QI_V4QI, MASK_DSP),
10240 DIRECT_BUILTIN (dpaq_s_w_ph, MIPS_DI_FTYPE_DI_V2HI_V2HI, MASK_DSP),
10241 DIRECT_BUILTIN (dpsq_s_w_ph, MIPS_DI_FTYPE_DI_V2HI_V2HI, MASK_DSP),
10242 DIRECT_BUILTIN (mulsaq_s_w_ph, MIPS_DI_FTYPE_DI_V2HI_V2HI, MASK_DSP),
10243 DIRECT_BUILTIN (dpaq_sa_l_w, MIPS_DI_FTYPE_DI_SI_SI, MASK_DSP),
10244 DIRECT_BUILTIN (dpsq_sa_l_w, MIPS_DI_FTYPE_DI_SI_SI, MASK_DSP),
10245 DIRECT_BUILTIN (maq_s_w_phl, MIPS_DI_FTYPE_DI_V2HI_V2HI, MASK_DSP),
10246 DIRECT_BUILTIN (maq_s_w_phr, MIPS_DI_FTYPE_DI_V2HI_V2HI, MASK_DSP),
10247 DIRECT_BUILTIN (maq_sa_w_phl, MIPS_DI_FTYPE_DI_V2HI_V2HI, MASK_DSP),
10248 DIRECT_BUILTIN (maq_sa_w_phr, MIPS_DI_FTYPE_DI_V2HI_V2HI, MASK_DSP),
10249 DIRECT_BUILTIN (bitrev, MIPS_SI_FTYPE_SI, MASK_DSP),
10250 DIRECT_BUILTIN (insv, MIPS_SI_FTYPE_SI_SI, MASK_DSP),
10251 DIRECT_BUILTIN (repl_qb, MIPS_V4QI_FTYPE_SI, MASK_DSP),
10252 DIRECT_BUILTIN (repl_ph, MIPS_V2HI_FTYPE_SI, MASK_DSP),
10253 DIRECT_NO_TARGET_BUILTIN (cmpu_eq_qb, MIPS_VOID_FTYPE_V4QI_V4QI, MASK_DSP),
10254 DIRECT_NO_TARGET_BUILTIN (cmpu_lt_qb, MIPS_VOID_FTYPE_V4QI_V4QI, MASK_DSP),
10255 DIRECT_NO_TARGET_BUILTIN (cmpu_le_qb, MIPS_VOID_FTYPE_V4QI_V4QI, MASK_DSP),
10256 DIRECT_BUILTIN (cmpgu_eq_qb, MIPS_SI_FTYPE_V4QI_V4QI, MASK_DSP),
10257 DIRECT_BUILTIN (cmpgu_lt_qb, MIPS_SI_FTYPE_V4QI_V4QI, MASK_DSP),
10258 DIRECT_BUILTIN (cmpgu_le_qb, MIPS_SI_FTYPE_V4QI_V4QI, MASK_DSP),
10259 DIRECT_NO_TARGET_BUILTIN (cmp_eq_ph, MIPS_VOID_FTYPE_V2HI_V2HI, MASK_DSP),
10260 DIRECT_NO_TARGET_BUILTIN (cmp_lt_ph, MIPS_VOID_FTYPE_V2HI_V2HI, MASK_DSP),
10261 DIRECT_NO_TARGET_BUILTIN (cmp_le_ph, MIPS_VOID_FTYPE_V2HI_V2HI, MASK_DSP),
10262 DIRECT_BUILTIN (pick_qb, MIPS_V4QI_FTYPE_V4QI_V4QI, MASK_DSP),
10263 DIRECT_BUILTIN (pick_ph, MIPS_V2HI_FTYPE_V2HI_V2HI, MASK_DSP),
10264 DIRECT_BUILTIN (packrl_ph, MIPS_V2HI_FTYPE_V2HI_V2HI, MASK_DSP),
10265 DIRECT_BUILTIN (extr_w, MIPS_SI_FTYPE_DI_SI, MASK_DSP),
10266 DIRECT_BUILTIN (extr_r_w, MIPS_SI_FTYPE_DI_SI, MASK_DSP),
10267 DIRECT_BUILTIN (extr_rs_w, MIPS_SI_FTYPE_DI_SI, MASK_DSP),
10268 DIRECT_BUILTIN (extr_s_h, MIPS_SI_FTYPE_DI_SI, MASK_DSP),
10269 DIRECT_BUILTIN (extp, MIPS_SI_FTYPE_DI_SI, MASK_DSP),
10270 DIRECT_BUILTIN (extpdp, MIPS_SI_FTYPE_DI_SI, MASK_DSP),
10271 DIRECT_BUILTIN (shilo, MIPS_DI_FTYPE_DI_SI, MASK_DSP),
10272 DIRECT_BUILTIN (mthlip, MIPS_DI_FTYPE_DI_SI, MASK_DSP),
10273 DIRECT_NO_TARGET_BUILTIN (wrdsp, MIPS_VOID_FTYPE_SI_SI, MASK_DSP),
10274 DIRECT_BUILTIN (rddsp, MIPS_SI_FTYPE_SI, MASK_DSP),
10275 DIRECT_BUILTIN (lbux, MIPS_SI_FTYPE_PTR_SI, MASK_DSP),
10276 DIRECT_BUILTIN (lhx, MIPS_SI_FTYPE_PTR_SI, MASK_DSP),
10277 DIRECT_BUILTIN (lwx, MIPS_SI_FTYPE_PTR_SI, MASK_DSP),
10278 BPOSGE_BUILTIN (32, MASK_DSP)
10281 /* This helps provide a mapping from builtin function codes to bdesc
10286 /* The builtin function table that this entry describes. */
10287 const struct builtin_description *bdesc;
10289 /* The number of entries in the builtin function table. */
10292 /* The target processor that supports these builtin functions.
10293 PROCESSOR_MAX means we enable them for all processors. */
10294 enum processor_type proc;
10297 static const struct bdesc_map bdesc_arrays[] =
10299 { mips_bdesc, ARRAY_SIZE (mips_bdesc), PROCESSOR_MAX },
10300 { sb1_bdesc, ARRAY_SIZE (sb1_bdesc), PROCESSOR_SB1 },
10301 { dsp_bdesc, ARRAY_SIZE (dsp_bdesc), PROCESSOR_MAX }
10304 /* Take the head of argument list *ARGLIST and convert it into a form
10305 suitable for input operand OP of instruction ICODE. Return the value
10306 and point *ARGLIST at the next element of the list. */
10309 mips_prepare_builtin_arg (enum insn_code icode,
10310 unsigned int op, tree *arglist)
10313 enum machine_mode mode;
10315 value = expand_normal (TREE_VALUE (*arglist));
10316 mode = insn_data[icode].operand[op].mode;
10317 if (!insn_data[icode].operand[op].predicate (value, mode))
10319 value = copy_to_mode_reg (mode, value);
10320 /* Check the predicate again. */
10321 if (!insn_data[icode].operand[op].predicate (value, mode))
10323 error ("invalid argument to builtin function");
10328 *arglist = TREE_CHAIN (*arglist);
10332 /* Return an rtx suitable for output operand OP of instruction ICODE.
10333 If TARGET is non-null, try to use it where possible. */
10336 mips_prepare_builtin_target (enum insn_code icode, unsigned int op, rtx target)
10338 enum machine_mode mode;
10340 mode = insn_data[icode].operand[op].mode;
10341 if (target == 0 || !insn_data[icode].operand[op].predicate (target, mode))
10342 target = gen_reg_rtx (mode);
10347 /* Expand builtin functions. This is called from TARGET_EXPAND_BUILTIN. */
10350 mips_expand_builtin (tree exp, rtx target, rtx subtarget ATTRIBUTE_UNUSED,
10351 enum machine_mode mode ATTRIBUTE_UNUSED,
10352 int ignore ATTRIBUTE_UNUSED)
10354 enum insn_code icode;
10355 enum mips_builtin_type type;
10356 tree fndecl, arglist;
10357 unsigned int fcode;
10358 const struct builtin_description *bdesc;
10359 const struct bdesc_map *m;
10361 fndecl = TREE_OPERAND (TREE_OPERAND (exp, 0), 0);
10362 arglist = TREE_OPERAND (exp, 1);
10363 fcode = DECL_FUNCTION_CODE (fndecl);
10366 for (m = bdesc_arrays; m < &bdesc_arrays[ARRAY_SIZE (bdesc_arrays)]; m++)
10368 if (fcode < m->size)
10371 icode = bdesc[fcode].icode;
10372 type = bdesc[fcode].builtin_type;
10382 case MIPS_BUILTIN_DIRECT:
10383 return mips_expand_builtin_direct (icode, target, arglist, true);
10385 case MIPS_BUILTIN_DIRECT_NO_TARGET:
10386 return mips_expand_builtin_direct (icode, target, arglist, false);
10388 case MIPS_BUILTIN_MOVT:
10389 case MIPS_BUILTIN_MOVF:
10390 return mips_expand_builtin_movtf (type, icode, bdesc[fcode].cond,
10393 case MIPS_BUILTIN_CMP_ANY:
10394 case MIPS_BUILTIN_CMP_ALL:
10395 case MIPS_BUILTIN_CMP_UPPER:
10396 case MIPS_BUILTIN_CMP_LOWER:
10397 case MIPS_BUILTIN_CMP_SINGLE:
10398 return mips_expand_builtin_compare (type, icode, bdesc[fcode].cond,
10401 case MIPS_BUILTIN_BPOSGE32:
10402 return mips_expand_builtin_bposge (type, target);
10409 /* Init builtin functions. This is called from TARGET_INIT_BUILTIN. */
10412 mips_init_builtins (void)
10414 const struct builtin_description *d;
10415 const struct bdesc_map *m;
10416 tree types[(int) MIPS_MAX_FTYPE_MAX];
10417 tree V2SF_type_node;
10418 tree V2HI_type_node;
10419 tree V4QI_type_node;
10420 unsigned int offset;
10422 /* We have only builtins for -mpaired-single, -mips3d and -mdsp. */
10423 if (!TARGET_PAIRED_SINGLE_FLOAT && !TARGET_DSP)
10426 if (TARGET_PAIRED_SINGLE_FLOAT)
10428 V2SF_type_node = build_vector_type_for_mode (float_type_node, V2SFmode);
10430 types[MIPS_V2SF_FTYPE_V2SF]
10431 = build_function_type_list (V2SF_type_node, V2SF_type_node, NULL_TREE);
10433 types[MIPS_V2SF_FTYPE_V2SF_V2SF]
10434 = build_function_type_list (V2SF_type_node,
10435 V2SF_type_node, V2SF_type_node, NULL_TREE);
10437 types[MIPS_V2SF_FTYPE_V2SF_V2SF_INT]
10438 = build_function_type_list (V2SF_type_node,
10439 V2SF_type_node, V2SF_type_node,
10440 integer_type_node, NULL_TREE);
10442 types[MIPS_V2SF_FTYPE_V2SF_V2SF_V2SF_V2SF]
10443 = build_function_type_list (V2SF_type_node,
10444 V2SF_type_node, V2SF_type_node,
10445 V2SF_type_node, V2SF_type_node, NULL_TREE);
10447 types[MIPS_V2SF_FTYPE_SF_SF]
10448 = build_function_type_list (V2SF_type_node,
10449 float_type_node, float_type_node, NULL_TREE);
10451 types[MIPS_INT_FTYPE_V2SF_V2SF]
10452 = build_function_type_list (integer_type_node,
10453 V2SF_type_node, V2SF_type_node, NULL_TREE);
10455 types[MIPS_INT_FTYPE_V2SF_V2SF_V2SF_V2SF]
10456 = build_function_type_list (integer_type_node,
10457 V2SF_type_node, V2SF_type_node,
10458 V2SF_type_node, V2SF_type_node, NULL_TREE);
10460 types[MIPS_INT_FTYPE_SF_SF]
10461 = build_function_type_list (integer_type_node,
10462 float_type_node, float_type_node, NULL_TREE);
10464 types[MIPS_INT_FTYPE_DF_DF]
10465 = build_function_type_list (integer_type_node,
10466 double_type_node, double_type_node, NULL_TREE);
10468 types[MIPS_SF_FTYPE_V2SF]
10469 = build_function_type_list (float_type_node, V2SF_type_node, NULL_TREE);
10471 types[MIPS_SF_FTYPE_SF]
10472 = build_function_type_list (float_type_node,
10473 float_type_node, NULL_TREE);
10475 types[MIPS_SF_FTYPE_SF_SF]
10476 = build_function_type_list (float_type_node,
10477 float_type_node, float_type_node, NULL_TREE);
10479 types[MIPS_DF_FTYPE_DF]
10480 = build_function_type_list (double_type_node,
10481 double_type_node, NULL_TREE);
10483 types[MIPS_DF_FTYPE_DF_DF]
10484 = build_function_type_list (double_type_node,
10485 double_type_node, double_type_node, NULL_TREE);
10490 V2HI_type_node = build_vector_type_for_mode (intHI_type_node, V2HImode);
10491 V4QI_type_node = build_vector_type_for_mode (intQI_type_node, V4QImode);
10493 types[MIPS_V2HI_FTYPE_V2HI_V2HI]
10494 = build_function_type_list (V2HI_type_node,
10495 V2HI_type_node, V2HI_type_node,
10498 types[MIPS_SI_FTYPE_SI_SI]
10499 = build_function_type_list (intSI_type_node,
10500 intSI_type_node, intSI_type_node,
10503 types[MIPS_V4QI_FTYPE_V4QI_V4QI]
10504 = build_function_type_list (V4QI_type_node,
10505 V4QI_type_node, V4QI_type_node,
10508 types[MIPS_SI_FTYPE_V4QI]
10509 = build_function_type_list (intSI_type_node,
10513 types[MIPS_V2HI_FTYPE_V2HI]
10514 = build_function_type_list (V2HI_type_node,
10518 types[MIPS_SI_FTYPE_SI]
10519 = build_function_type_list (intSI_type_node,
10523 types[MIPS_V4QI_FTYPE_V2HI_V2HI]
10524 = build_function_type_list (V4QI_type_node,
10525 V2HI_type_node, V2HI_type_node,
10528 types[MIPS_V2HI_FTYPE_SI_SI]
10529 = build_function_type_list (V2HI_type_node,
10530 intSI_type_node, intSI_type_node,
10533 types[MIPS_SI_FTYPE_V2HI]
10534 = build_function_type_list (intSI_type_node,
10538 types[MIPS_V2HI_FTYPE_V4QI]
10539 = build_function_type_list (V2HI_type_node,
10543 types[MIPS_V4QI_FTYPE_V4QI_SI]
10544 = build_function_type_list (V4QI_type_node,
10545 V4QI_type_node, intSI_type_node,
10548 types[MIPS_V2HI_FTYPE_V2HI_SI]
10549 = build_function_type_list (V2HI_type_node,
10550 V2HI_type_node, intSI_type_node,
10553 types[MIPS_V2HI_FTYPE_V4QI_V2HI]
10554 = build_function_type_list (V2HI_type_node,
10555 V4QI_type_node, V2HI_type_node,
10558 types[MIPS_SI_FTYPE_V2HI_V2HI]
10559 = build_function_type_list (intSI_type_node,
10560 V2HI_type_node, V2HI_type_node,
10563 types[MIPS_DI_FTYPE_DI_V4QI_V4QI]
10564 = build_function_type_list (intDI_type_node,
10565 intDI_type_node, V4QI_type_node, V4QI_type_node,
10568 types[MIPS_DI_FTYPE_DI_V2HI_V2HI]
10569 = build_function_type_list (intDI_type_node,
10570 intDI_type_node, V2HI_type_node, V2HI_type_node,
10573 types[MIPS_DI_FTYPE_DI_SI_SI]
10574 = build_function_type_list (intDI_type_node,
10575 intDI_type_node, intSI_type_node, intSI_type_node,
10578 types[MIPS_V4QI_FTYPE_SI]
10579 = build_function_type_list (V4QI_type_node,
10583 types[MIPS_V2HI_FTYPE_SI]
10584 = build_function_type_list (V2HI_type_node,
10588 types[MIPS_VOID_FTYPE_V4QI_V4QI]
10589 = build_function_type_list (void_type_node,
10590 V4QI_type_node, V4QI_type_node,
10593 types[MIPS_SI_FTYPE_V4QI_V4QI]
10594 = build_function_type_list (intSI_type_node,
10595 V4QI_type_node, V4QI_type_node,
10598 types[MIPS_VOID_FTYPE_V2HI_V2HI]
10599 = build_function_type_list (void_type_node,
10600 V2HI_type_node, V2HI_type_node,
10603 types[MIPS_SI_FTYPE_DI_SI]
10604 = build_function_type_list (intSI_type_node,
10605 intDI_type_node, intSI_type_node,
10608 types[MIPS_DI_FTYPE_DI_SI]
10609 = build_function_type_list (intDI_type_node,
10610 intDI_type_node, intSI_type_node,
10613 types[MIPS_VOID_FTYPE_SI_SI]
10614 = build_function_type_list (void_type_node,
10615 intSI_type_node, intSI_type_node,
10618 types[MIPS_SI_FTYPE_PTR_SI]
10619 = build_function_type_list (intSI_type_node,
10620 ptr_type_node, intSI_type_node,
10623 types[MIPS_SI_FTYPE_VOID]
10624 = build_function_type (intSI_type_node, void_list_node);
10627 /* Iterate through all of the bdesc arrays, initializing all of the
10628 builtin functions. */
10631 for (m = bdesc_arrays; m < &bdesc_arrays[ARRAY_SIZE (bdesc_arrays)]; m++)
10633 if (m->proc == PROCESSOR_MAX || (m->proc == mips_arch))
10634 for (d = m->bdesc; d < &m->bdesc[m->size]; d++)
10635 if ((d->target_flags & target_flags) == d->target_flags)
10636 lang_hooks.builtin_function (d->name, types[d->function_type],
10637 d - m->bdesc + offset,
10638 BUILT_IN_MD, NULL, NULL);
10643 /* Expand a MIPS_BUILTIN_DIRECT function. ICODE is the code of the
10644 .md pattern and ARGLIST is the list of function arguments. TARGET,
10645 if nonnull, suggests a good place to put the result.
10646 HAS_TARGET indicates the function must return something. */
10649 mips_expand_builtin_direct (enum insn_code icode, rtx target, tree arglist,
10652 rtx ops[MAX_RECOG_OPERANDS];
10657 /* We save target to ops[0]. */
10658 ops[0] = mips_prepare_builtin_target (icode, 0, target);
10662 /* We need to test if arglist is not zero. Some instructions have extra
10663 clobber registers. */
10664 for (; i < insn_data[icode].n_operands && arglist != 0; i++)
10665 ops[i] = mips_prepare_builtin_arg (icode, i, &arglist);
10670 emit_insn (GEN_FCN (icode) (ops[0], ops[1]));
10674 emit_insn (GEN_FCN (icode) (ops[0], ops[1], ops[2]));
10678 emit_insn (GEN_FCN (icode) (ops[0], ops[1], ops[2], ops[3]));
10682 gcc_unreachable ();
10687 /* Expand a __builtin_mips_movt_*_ps() or __builtin_mips_movf_*_ps()
10688 function (TYPE says which). ARGLIST is the list of arguments to the
10689 function, ICODE is the instruction that should be used to compare
10690 the first two arguments, and COND is the condition it should test.
10691 TARGET, if nonnull, suggests a good place to put the result. */
10694 mips_expand_builtin_movtf (enum mips_builtin_type type,
10695 enum insn_code icode, enum mips_fp_condition cond,
10696 rtx target, tree arglist)
10698 rtx cmp_result, op0, op1;
10700 cmp_result = mips_prepare_builtin_target (icode, 0, 0);
10701 op0 = mips_prepare_builtin_arg (icode, 1, &arglist);
10702 op1 = mips_prepare_builtin_arg (icode, 2, &arglist);
10703 emit_insn (GEN_FCN (icode) (cmp_result, op0, op1, GEN_INT (cond)));
10705 icode = CODE_FOR_mips_cond_move_tf_ps;
10706 target = mips_prepare_builtin_target (icode, 0, target);
10707 if (type == MIPS_BUILTIN_MOVT)
10709 op1 = mips_prepare_builtin_arg (icode, 2, &arglist);
10710 op0 = mips_prepare_builtin_arg (icode, 1, &arglist);
10714 op0 = mips_prepare_builtin_arg (icode, 1, &arglist);
10715 op1 = mips_prepare_builtin_arg (icode, 2, &arglist);
10717 emit_insn (gen_mips_cond_move_tf_ps (target, op0, op1, cmp_result));
10721 /* Move VALUE_IF_TRUE into TARGET if CONDITION is true; move VALUE_IF_FALSE
10722 into TARGET otherwise. Return TARGET. */
10725 mips_builtin_branch_and_move (rtx condition, rtx target,
10726 rtx value_if_true, rtx value_if_false)
10728 rtx true_label, done_label;
10730 true_label = gen_label_rtx ();
10731 done_label = gen_label_rtx ();
10733 /* First assume that CONDITION is false. */
10734 emit_move_insn (target, value_if_false);
10736 /* Branch to TRUE_LABEL if CONDITION is true and DONE_LABEL otherwise. */
10737 emit_jump_insn (gen_condjump (condition, true_label));
10738 emit_jump_insn (gen_jump (done_label));
10741 /* Fix TARGET if CONDITION is true. */
10742 emit_label (true_label);
10743 emit_move_insn (target, value_if_true);
10745 emit_label (done_label);
10749 /* Expand a comparison builtin of type BUILTIN_TYPE. ICODE is the code
10750 of the comparison instruction and COND is the condition it should test.
10751 ARGLIST is the list of function arguments and TARGET, if nonnull,
10752 suggests a good place to put the boolean result. */
10755 mips_expand_builtin_compare (enum mips_builtin_type builtin_type,
10756 enum insn_code icode, enum mips_fp_condition cond,
10757 rtx target, tree arglist)
10759 rtx offset, condition, cmp_result, ops[MAX_RECOG_OPERANDS];
10762 if (target == 0 || GET_MODE (target) != SImode)
10763 target = gen_reg_rtx (SImode);
10765 /* Prepare the operands to the comparison. */
10766 cmp_result = mips_prepare_builtin_target (icode, 0, 0);
10767 for (i = 1; i < insn_data[icode].n_operands - 1; i++)
10768 ops[i] = mips_prepare_builtin_arg (icode, i, &arglist);
10770 switch (insn_data[icode].n_operands)
10773 emit_insn (GEN_FCN (icode) (cmp_result, ops[1], ops[2], GEN_INT (cond)));
10777 emit_insn (GEN_FCN (icode) (cmp_result, ops[1], ops[2],
10778 ops[3], ops[4], GEN_INT (cond)));
10782 gcc_unreachable ();
10785 /* If the comparison sets more than one register, we define the result
10786 to be 0 if all registers are false and -1 if all registers are true.
10787 The value of the complete result is indeterminate otherwise. */
10788 switch (builtin_type)
10790 case MIPS_BUILTIN_CMP_ALL:
10791 condition = gen_rtx_NE (VOIDmode, cmp_result, constm1_rtx);
10792 return mips_builtin_branch_and_move (condition, target,
10793 const0_rtx, const1_rtx);
10795 case MIPS_BUILTIN_CMP_UPPER:
10796 case MIPS_BUILTIN_CMP_LOWER:
10797 offset = GEN_INT (builtin_type == MIPS_BUILTIN_CMP_UPPER);
10798 condition = gen_single_cc (cmp_result, offset);
10799 return mips_builtin_branch_and_move (condition, target,
10800 const1_rtx, const0_rtx);
10803 condition = gen_rtx_NE (VOIDmode, cmp_result, const0_rtx);
10804 return mips_builtin_branch_and_move (condition, target,
10805 const1_rtx, const0_rtx);
10809 /* Expand a bposge builtin of type BUILTIN_TYPE. TARGET, if nonnull,
10810 suggests a good place to put the boolean result. */
10813 mips_expand_builtin_bposge (enum mips_builtin_type builtin_type, rtx target)
10815 rtx condition, cmp_result;
10818 if (target == 0 || GET_MODE (target) != SImode)
10819 target = gen_reg_rtx (SImode);
10821 cmp_result = gen_rtx_REG (CCDSPmode, CCDSP_PO_REGNUM);
10823 if (builtin_type == MIPS_BUILTIN_BPOSGE32)
10828 condition = gen_rtx_GE (VOIDmode, cmp_result, GEN_INT (cmp_value));
10829 return mips_builtin_branch_and_move (condition, target,
10830 const1_rtx, const0_rtx);
10833 /* Set SYMBOL_REF_FLAGS for the SYMBOL_REF inside RTL, which belongs to DECL.
10834 FIRST is true if this is the first time handling this decl. */
10837 mips_encode_section_info (tree decl, rtx rtl, int first)
10839 default_encode_section_info (decl, rtl, first);
10841 if (TREE_CODE (decl) == FUNCTION_DECL
10842 && lookup_attribute ("long_call", TYPE_ATTRIBUTES (TREE_TYPE (decl))))
10844 rtx symbol = XEXP (rtl, 0);
10845 SYMBOL_REF_FLAGS (symbol) |= SYMBOL_FLAG_LONG_CALL;
10849 /* Implement TARGET_EXTRA_LIVE_ON_ENTRY. PIC_FUNCTION_ADDR_REGNUM is live
10850 on entry to a function when generating -mshared abicalls code. */
10853 mips_extra_live_on_entry (bitmap regs)
10855 if (TARGET_ABICALLS && !TARGET_ABSOLUTE_ABICALLS)
10856 bitmap_set_bit (regs, PIC_FUNCTION_ADDR_REGNUM);
10859 /* SImode values are represented as sign-extended to DImode. */
10862 mips_mode_rep_extended (enum machine_mode mode, enum machine_mode mode_rep)
10864 if (TARGET_64BIT && mode == SImode && mode_rep == DImode)
10865 return SIGN_EXTEND;
10870 #include "gt-mips.h"