* elf64-ppc.c (ppc_get_stub_entry): Change third param to a
[binutils.git] / gas / config / tc-mips.c
blobfd76eabb5ac80dd9b380a8690073cfb0b3628118
1 /* tc-mips.c -- assemble code for a MIPS chip.
2 Copyright 1993, 1994, 1995, 1996, 1997, 1998, 1999, 2000, 2001, 2002,
3 2003, 2004 Free Software Foundation, Inc.
4 Contributed by the OSF and Ralph Campbell.
5 Written by Keith Knowles and Ralph Campbell, working independently.
6 Modified for ECOFF and R4000 support by Ian Lance Taylor of Cygnus
7 Support.
9 This file is part of GAS.
11 GAS 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)
14 any later version.
16 GAS 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 GAS; see the file COPYING. If not, write to the Free
23 Software Foundation, 59 Temple Place - Suite 330, Boston, MA
24 02111-1307, USA. */
26 #include "as.h"
27 #include "config.h"
28 #include "subsegs.h"
29 #include "safe-ctype.h"
31 #include <stdarg.h>
33 #include "opcode/mips.h"
34 #include "itbl-ops.h"
35 #include "dwarf2dbg.h"
37 #ifdef DEBUG
38 #define DBG(x) printf x
39 #else
40 #define DBG(x)
41 #endif
43 #ifdef OBJ_MAYBE_ELF
44 /* Clean up namespace so we can include obj-elf.h too. */
45 static int mips_output_flavor (void);
46 static int mips_output_flavor (void) { return OUTPUT_FLAVOR; }
47 #undef OBJ_PROCESS_STAB
48 #undef OUTPUT_FLAVOR
49 #undef S_GET_ALIGN
50 #undef S_GET_SIZE
51 #undef S_SET_ALIGN
52 #undef S_SET_SIZE
53 #undef obj_frob_file
54 #undef obj_frob_file_after_relocs
55 #undef obj_frob_symbol
56 #undef obj_pop_insert
57 #undef obj_sec_sym_ok_for_reloc
58 #undef OBJ_COPY_SYMBOL_ATTRIBUTES
60 #include "obj-elf.h"
61 /* Fix any of them that we actually care about. */
62 #undef OUTPUT_FLAVOR
63 #define OUTPUT_FLAVOR mips_output_flavor()
64 #endif
66 #if defined (OBJ_ELF)
67 #include "elf/mips.h"
68 #endif
70 #ifndef ECOFF_DEBUGGING
71 #define NO_ECOFF_DEBUGGING
72 #define ECOFF_DEBUGGING 0
73 #endif
75 int mips_flag_mdebug = -1;
77 /* Control generation of .pdr sections. Off by default on IRIX: the native
78 linker doesn't know about and discards them, but relocations against them
79 remain, leading to rld crashes. */
80 #ifdef TE_IRIX
81 int mips_flag_pdr = FALSE;
82 #else
83 int mips_flag_pdr = TRUE;
84 #endif
86 #include "ecoff.h"
88 #if defined (OBJ_ELF) || defined (OBJ_MAYBE_ELF)
89 static char *mips_regmask_frag;
90 #endif
92 #define ZERO 0
93 #define AT 1
94 #define TREG 24
95 #define PIC_CALL_REG 25
96 #define KT0 26
97 #define KT1 27
98 #define GP 28
99 #define SP 29
100 #define FP 30
101 #define RA 31
103 #define ILLEGAL_REG (32)
105 /* Allow override of standard little-endian ECOFF format. */
107 #ifndef ECOFF_LITTLE_FORMAT
108 #define ECOFF_LITTLE_FORMAT "ecoff-littlemips"
109 #endif
111 extern int target_big_endian;
113 /* The name of the readonly data section. */
114 #define RDATA_SECTION_NAME (OUTPUT_FLAVOR == bfd_target_ecoff_flavour \
115 ? ".rdata" \
116 : OUTPUT_FLAVOR == bfd_target_coff_flavour \
117 ? ".rdata" \
118 : OUTPUT_FLAVOR == bfd_target_elf_flavour \
119 ? ".rodata" \
120 : (abort (), ""))
122 /* The ABI to use. */
123 enum mips_abi_level
125 NO_ABI = 0,
126 O32_ABI,
127 O64_ABI,
128 N32_ABI,
129 N64_ABI,
130 EABI_ABI
133 /* MIPS ABI we are using for this output file. */
134 static enum mips_abi_level mips_abi = NO_ABI;
136 /* Whether or not we have code that can call pic code. */
137 int mips_abicalls = FALSE;
139 /* This is the set of options which may be modified by the .set
140 pseudo-op. We use a struct so that .set push and .set pop are more
141 reliable. */
143 struct mips_set_options
145 /* MIPS ISA (Instruction Set Architecture) level. This is set to -1
146 if it has not been initialized. Changed by `.set mipsN', and the
147 -mipsN command line option, and the default CPU. */
148 int isa;
149 /* Enabled Application Specific Extensions (ASEs). These are set to -1
150 if they have not been initialized. Changed by `.set <asename>', by
151 command line options, and based on the default architecture. */
152 int ase_mips3d;
153 int ase_mdmx;
154 /* Whether we are assembling for the mips16 processor. 0 if we are
155 not, 1 if we are, and -1 if the value has not been initialized.
156 Changed by `.set mips16' and `.set nomips16', and the -mips16 and
157 -nomips16 command line options, and the default CPU. */
158 int mips16;
159 /* Non-zero if we should not reorder instructions. Changed by `.set
160 reorder' and `.set noreorder'. */
161 int noreorder;
162 /* Non-zero if we should not permit the $at ($1) register to be used
163 in instructions. Changed by `.set at' and `.set noat'. */
164 int noat;
165 /* Non-zero if we should warn when a macro instruction expands into
166 more than one machine instruction. Changed by `.set nomacro' and
167 `.set macro'. */
168 int warn_about_macros;
169 /* Non-zero if we should not move instructions. Changed by `.set
170 move', `.set volatile', `.set nomove', and `.set novolatile'. */
171 int nomove;
172 /* Non-zero if we should not optimize branches by moving the target
173 of the branch into the delay slot. Actually, we don't perform
174 this optimization anyhow. Changed by `.set bopt' and `.set
175 nobopt'. */
176 int nobopt;
177 /* Non-zero if we should not autoextend mips16 instructions.
178 Changed by `.set autoextend' and `.set noautoextend'. */
179 int noautoextend;
180 /* Restrict general purpose registers and floating point registers
181 to 32 bit. This is initially determined when -mgp32 or -mfp32
182 is passed but can changed if the assembler code uses .set mipsN. */
183 int gp32;
184 int fp32;
185 /* MIPS architecture (CPU) type. Changed by .set arch=FOO, the -march
186 command line option, and the default CPU. */
187 int arch;
190 /* True if -mgp32 was passed. */
191 static int file_mips_gp32 = -1;
193 /* True if -mfp32 was passed. */
194 static int file_mips_fp32 = -1;
196 /* This is the struct we use to hold the current set of options. Note
197 that we must set the isa field to ISA_UNKNOWN and the ASE fields to
198 -1 to indicate that they have not been initialized. */
200 static struct mips_set_options mips_opts =
202 ISA_UNKNOWN, -1, -1, -1, 0, 0, 0, 0, 0, 0, 0, 0, CPU_UNKNOWN
205 /* These variables are filled in with the masks of registers used.
206 The object format code reads them and puts them in the appropriate
207 place. */
208 unsigned long mips_gprmask;
209 unsigned long mips_cprmask[4];
211 /* MIPS ISA we are using for this output file. */
212 static int file_mips_isa = ISA_UNKNOWN;
214 /* True if -mips16 was passed or implied by arguments passed on the
215 command line (e.g., by -march). */
216 static int file_ase_mips16;
218 /* True if -mips3d was passed or implied by arguments passed on the
219 command line (e.g., by -march). */
220 static int file_ase_mips3d;
222 /* True if -mdmx was passed or implied by arguments passed on the
223 command line (e.g., by -march). */
224 static int file_ase_mdmx;
226 /* The argument of the -march= flag. The architecture we are assembling. */
227 static int file_mips_arch = CPU_UNKNOWN;
228 static const char *mips_arch_string;
230 /* The argument of the -mtune= flag. The architecture for which we
231 are optimizing. */
232 static int mips_tune = CPU_UNKNOWN;
233 static const char *mips_tune_string;
235 /* True when generating 32-bit code for a 64-bit processor. */
236 static int mips_32bitmode = 0;
238 /* True if the given ABI requires 32-bit registers. */
239 #define ABI_NEEDS_32BIT_REGS(ABI) ((ABI) == O32_ABI)
241 /* Likewise 64-bit registers. */
242 #define ABI_NEEDS_64BIT_REGS(ABI) \
243 ((ABI) == N32_ABI \
244 || (ABI) == N64_ABI \
245 || (ABI) == O64_ABI)
247 /* Return true if ISA supports 64 bit gp register instructions. */
248 #define ISA_HAS_64BIT_REGS(ISA) ( \
249 (ISA) == ISA_MIPS3 \
250 || (ISA) == ISA_MIPS4 \
251 || (ISA) == ISA_MIPS5 \
252 || (ISA) == ISA_MIPS64 \
253 || (ISA) == ISA_MIPS64R2 \
256 /* Return true if ISA supports 64-bit right rotate (dror et al.)
257 instructions. */
258 #define ISA_HAS_DROR(ISA) ( \
259 (ISA) == ISA_MIPS64R2 \
262 /* Return true if ISA supports 32-bit right rotate (ror et al.)
263 instructions. */
264 #define ISA_HAS_ROR(ISA) ( \
265 (ISA) == ISA_MIPS32R2 \
266 || (ISA) == ISA_MIPS64R2 \
269 #define HAVE_32BIT_GPRS \
270 (mips_opts.gp32 || ! ISA_HAS_64BIT_REGS (mips_opts.isa))
272 #define HAVE_32BIT_FPRS \
273 (mips_opts.fp32 || ! ISA_HAS_64BIT_REGS (mips_opts.isa))
275 #define HAVE_64BIT_GPRS (! HAVE_32BIT_GPRS)
276 #define HAVE_64BIT_FPRS (! HAVE_32BIT_FPRS)
278 #define HAVE_NEWABI (mips_abi == N32_ABI || mips_abi == N64_ABI)
280 #define HAVE_64BIT_OBJECTS (mips_abi == N64_ABI)
282 /* True if relocations are stored in-place. */
283 #define HAVE_IN_PLACE_ADDENDS (!HAVE_NEWABI)
285 /* We can only have 64bit addresses if the object file format supports it. */
286 #define HAVE_32BIT_ADDRESSES \
287 (HAVE_32BIT_GPRS \
288 || (bfd_arch_bits_per_address (stdoutput) == 32 \
289 || ! HAVE_64BIT_OBJECTS)) \
291 #define HAVE_64BIT_ADDRESSES (! HAVE_32BIT_ADDRESSES)
293 /* Addresses are loaded in different ways, depending on the address size
294 in use. The n32 ABI Documentation also mandates the use of additions
295 with overflow checking, but existing implementations don't follow it. */
296 #define ADDRESS_ADD_INSN \
297 (HAVE_32BIT_ADDRESSES ? "addu" : "daddu")
299 #define ADDRESS_ADDI_INSN \
300 (HAVE_32BIT_ADDRESSES ? "addiu" : "daddiu")
302 #define ADDRESS_LOAD_INSN \
303 (HAVE_32BIT_ADDRESSES ? "lw" : "ld")
305 #define ADDRESS_STORE_INSN \
306 (HAVE_32BIT_ADDRESSES ? "sw" : "sd")
308 /* Return true if the given CPU supports the MIPS16 ASE. */
309 #define CPU_HAS_MIPS16(cpu) \
310 (strncmp (TARGET_CPU, "mips16", sizeof ("mips16") - 1) == 0 \
311 || strncmp (TARGET_CANONICAL, "mips-lsi-elf", sizeof ("mips-lsi-elf") - 1) == 0)
313 /* Return true if the given CPU supports the MIPS3D ASE. */
314 #define CPU_HAS_MIPS3D(cpu) ((cpu) == CPU_SB1 \
317 /* Return true if the given CPU supports the MDMX ASE. */
318 #define CPU_HAS_MDMX(cpu) (FALSE \
321 /* True if CPU has a dror instruction. */
322 #define CPU_HAS_DROR(CPU) ((CPU) == CPU_VR5400 || (CPU) == CPU_VR5500)
324 /* True if CPU has a ror instruction. */
325 #define CPU_HAS_ROR(CPU) CPU_HAS_DROR (CPU)
327 /* True if mflo and mfhi can be immediately followed by instructions
328 which write to the HI and LO registers.
330 According to MIPS specifications, MIPS ISAs I, II, and III need
331 (at least) two instructions between the reads of HI/LO and
332 instructions which write them, and later ISAs do not. Contradicting
333 the MIPS specifications, some MIPS IV processor user manuals (e.g.
334 the UM for the NEC Vr5000) document needing the instructions between
335 HI/LO reads and writes, as well. Therefore, we declare only MIPS32,
336 MIPS64 and later ISAs to have the interlocks, plus any specific
337 earlier-ISA CPUs for which CPU documentation declares that the
338 instructions are really interlocked. */
339 #define hilo_interlocks \
340 (mips_opts.isa == ISA_MIPS32 \
341 || mips_opts.isa == ISA_MIPS32R2 \
342 || mips_opts.isa == ISA_MIPS64 \
343 || mips_opts.isa == ISA_MIPS64R2 \
344 || mips_opts.arch == CPU_R4010 \
345 || mips_opts.arch == CPU_R10000 \
346 || mips_opts.arch == CPU_R12000 \
347 || mips_opts.arch == CPU_RM7000 \
348 || mips_opts.arch == CPU_VR5500 \
351 /* Whether the processor uses hardware interlocks to protect reads
352 from the GPRs after they are loaded from memory, and thus does not
353 require nops to be inserted. This applies to instructions marked
354 INSN_LOAD_MEMORY_DELAY. These nops are only required at MIPS ISA
355 level I. */
356 #define gpr_interlocks \
357 (mips_opts.isa != ISA_MIPS1 \
358 || mips_opts.arch == CPU_R3900)
360 /* Whether the processor uses hardware interlocks to avoid delays
361 required by coprocessor instructions, and thus does not require
362 nops to be inserted. This applies to instructions marked
363 INSN_LOAD_COPROC_DELAY, INSN_COPROC_MOVE_DELAY, and to delays
364 between instructions marked INSN_WRITE_COND_CODE and ones marked
365 INSN_READ_COND_CODE. These nops are only required at MIPS ISA
366 levels I, II, and III. */
367 /* Itbl support may require additional care here. */
368 #define cop_interlocks \
369 ((mips_opts.isa != ISA_MIPS1 \
370 && mips_opts.isa != ISA_MIPS2 \
371 && mips_opts.isa != ISA_MIPS3) \
372 || mips_opts.arch == CPU_R4300 \
375 /* Whether the processor uses hardware interlocks to protect reads
376 from coprocessor registers after they are loaded from memory, and
377 thus does not require nops to be inserted. This applies to
378 instructions marked INSN_COPROC_MEMORY_DELAY. These nops are only
379 requires at MIPS ISA level I. */
380 #define cop_mem_interlocks (mips_opts.isa != ISA_MIPS1)
382 /* Is this a mfhi or mflo instruction? */
383 #define MF_HILO_INSN(PINFO) \
384 ((PINFO & INSN_READ_HI) || (PINFO & INSN_READ_LO))
386 /* MIPS PIC level. */
388 enum mips_pic_level mips_pic;
390 /* 1 if we should generate 32 bit offsets from the $gp register in
391 SVR4_PIC mode. Currently has no meaning in other modes. */
392 static int mips_big_got = 0;
394 /* 1 if trap instructions should used for overflow rather than break
395 instructions. */
396 static int mips_trap = 0;
398 /* 1 if double width floating point constants should not be constructed
399 by assembling two single width halves into two single width floating
400 point registers which just happen to alias the double width destination
401 register. On some architectures this aliasing can be disabled by a bit
402 in the status register, and the setting of this bit cannot be determined
403 automatically at assemble time. */
404 static int mips_disable_float_construction;
406 /* Non-zero if any .set noreorder directives were used. */
408 static int mips_any_noreorder;
410 /* Non-zero if nops should be inserted when the register referenced in
411 an mfhi/mflo instruction is read in the next two instructions. */
412 static int mips_7000_hilo_fix;
414 /* The size of the small data section. */
415 static unsigned int g_switch_value = 8;
416 /* Whether the -G option was used. */
417 static int g_switch_seen = 0;
419 #define N_RMASK 0xc4
420 #define N_VFP 0xd4
422 /* If we can determine in advance that GP optimization won't be
423 possible, we can skip the relaxation stuff that tries to produce
424 GP-relative references. This makes delay slot optimization work
425 better.
427 This function can only provide a guess, but it seems to work for
428 gcc output. It needs to guess right for gcc, otherwise gcc
429 will put what it thinks is a GP-relative instruction in a branch
430 delay slot.
432 I don't know if a fix is needed for the SVR4_PIC mode. I've only
433 fixed it for the non-PIC mode. KR 95/04/07 */
434 static int nopic_need_relax (symbolS *, int);
436 /* handle of the OPCODE hash table */
437 static struct hash_control *op_hash = NULL;
439 /* The opcode hash table we use for the mips16. */
440 static struct hash_control *mips16_op_hash = NULL;
442 /* This array holds the chars that always start a comment. If the
443 pre-processor is disabled, these aren't very useful */
444 const char comment_chars[] = "#";
446 /* This array holds the chars that only start a comment at the beginning of
447 a line. If the line seems to have the form '# 123 filename'
448 .line and .file directives will appear in the pre-processed output */
449 /* Note that input_file.c hand checks for '#' at the beginning of the
450 first line of the input file. This is because the compiler outputs
451 #NO_APP at the beginning of its output. */
452 /* Also note that C style comments are always supported. */
453 const char line_comment_chars[] = "#";
455 /* This array holds machine specific line separator characters. */
456 const char line_separator_chars[] = ";";
458 /* Chars that can be used to separate mant from exp in floating point nums */
459 const char EXP_CHARS[] = "eE";
461 /* Chars that mean this number is a floating point constant */
462 /* As in 0f12.456 */
463 /* or 0d1.2345e12 */
464 const char FLT_CHARS[] = "rRsSfFdDxXpP";
466 /* Also be aware that MAXIMUM_NUMBER_OF_CHARS_FOR_FLOAT may have to be
467 changed in read.c . Ideally it shouldn't have to know about it at all,
468 but nothing is ideal around here.
471 static char *insn_error;
473 static int auto_align = 1;
475 /* When outputting SVR4 PIC code, the assembler needs to know the
476 offset in the stack frame from which to restore the $gp register.
477 This is set by the .cprestore pseudo-op, and saved in this
478 variable. */
479 static offsetT mips_cprestore_offset = -1;
481 /* Similar for NewABI PIC code, where $gp is callee-saved. NewABI has some
482 more optimizations, it can use a register value instead of a memory-saved
483 offset and even an other register than $gp as global pointer. */
484 static offsetT mips_cpreturn_offset = -1;
485 static int mips_cpreturn_register = -1;
486 static int mips_gp_register = GP;
487 static int mips_gprel_offset = 0;
489 /* Whether mips_cprestore_offset has been set in the current function
490 (or whether it has already been warned about, if not). */
491 static int mips_cprestore_valid = 0;
493 /* This is the register which holds the stack frame, as set by the
494 .frame pseudo-op. This is needed to implement .cprestore. */
495 static int mips_frame_reg = SP;
497 /* Whether mips_frame_reg has been set in the current function
498 (or whether it has already been warned about, if not). */
499 static int mips_frame_reg_valid = 0;
501 /* To output NOP instructions correctly, we need to keep information
502 about the previous two instructions. */
504 /* Whether we are optimizing. The default value of 2 means to remove
505 unneeded NOPs and swap branch instructions when possible. A value
506 of 1 means to not swap branches. A value of 0 means to always
507 insert NOPs. */
508 static int mips_optimize = 2;
510 /* Debugging level. -g sets this to 2. -gN sets this to N. -g0 is
511 equivalent to seeing no -g option at all. */
512 static int mips_debug = 0;
514 /* The previous instruction. */
515 static struct mips_cl_insn prev_insn;
517 /* The instruction before prev_insn. */
518 static struct mips_cl_insn prev_prev_insn;
520 /* If we don't want information for prev_insn or prev_prev_insn, we
521 point the insn_mo field at this dummy integer. */
522 static const struct mips_opcode dummy_opcode = { NULL, NULL, 0, 0, 0, 0 };
524 /* Non-zero if prev_insn is valid. */
525 static int prev_insn_valid;
527 /* The frag for the previous instruction. */
528 static struct frag *prev_insn_frag;
530 /* The offset into prev_insn_frag for the previous instruction. */
531 static long prev_insn_where;
533 /* The reloc type for the previous instruction, if any. */
534 static bfd_reloc_code_real_type prev_insn_reloc_type[3];
536 /* The reloc for the previous instruction, if any. */
537 static fixS *prev_insn_fixp[3];
539 /* Non-zero if the previous instruction was in a delay slot. */
540 static int prev_insn_is_delay_slot;
542 /* Non-zero if the previous instruction was in a .set noreorder. */
543 static int prev_insn_unreordered;
545 /* Non-zero if the previous instruction uses an extend opcode (if
546 mips16). */
547 static int prev_insn_extended;
549 /* Non-zero if the previous previous instruction was in a .set
550 noreorder. */
551 static int prev_prev_insn_unreordered;
553 /* If this is set, it points to a frag holding nop instructions which
554 were inserted before the start of a noreorder section. If those
555 nops turn out to be unnecessary, the size of the frag can be
556 decreased. */
557 static fragS *prev_nop_frag;
559 /* The number of nop instructions we created in prev_nop_frag. */
560 static int prev_nop_frag_holds;
562 /* The number of nop instructions that we know we need in
563 prev_nop_frag. */
564 static int prev_nop_frag_required;
566 /* The number of instructions we've seen since prev_nop_frag. */
567 static int prev_nop_frag_since;
569 /* For ECOFF and ELF, relocations against symbols are done in two
570 parts, with a HI relocation and a LO relocation. Each relocation
571 has only 16 bits of space to store an addend. This means that in
572 order for the linker to handle carries correctly, it must be able
573 to locate both the HI and the LO relocation. This means that the
574 relocations must appear in order in the relocation table.
576 In order to implement this, we keep track of each unmatched HI
577 relocation. We then sort them so that they immediately precede the
578 corresponding LO relocation. */
580 struct mips_hi_fixup
582 /* Next HI fixup. */
583 struct mips_hi_fixup *next;
584 /* This fixup. */
585 fixS *fixp;
586 /* The section this fixup is in. */
587 segT seg;
590 /* The list of unmatched HI relocs. */
592 static struct mips_hi_fixup *mips_hi_fixup_list;
594 /* The frag containing the last explicit relocation operator.
595 Null if explicit relocations have not been used. */
597 static fragS *prev_reloc_op_frag;
599 /* Map normal MIPS register numbers to mips16 register numbers. */
601 #define X ILLEGAL_REG
602 static const int mips32_to_16_reg_map[] =
604 X, X, 2, 3, 4, 5, 6, 7,
605 X, X, X, X, X, X, X, X,
606 0, 1, X, X, X, X, X, X,
607 X, X, X, X, X, X, X, X
609 #undef X
611 /* Map mips16 register numbers to normal MIPS register numbers. */
613 static const unsigned int mips16_to_32_reg_map[] =
615 16, 17, 2, 3, 4, 5, 6, 7
618 static int mips_fix_vr4120;
620 /* We don't relax branches by default, since this causes us to expand
621 `la .l2 - .l1' if there's a branch between .l1 and .l2, because we
622 fail to compute the offset before expanding the macro to the most
623 efficient expansion. */
625 static int mips_relax_branch;
627 /* The expansion of many macros depends on the type of symbol that
628 they refer to. For example, when generating position-dependent code,
629 a macro that refers to a symbol may have two different expansions,
630 one which uses GP-relative addresses and one which uses absolute
631 addresses. When generating SVR4-style PIC, a macro may have
632 different expansions for local and global symbols.
634 We handle these situations by generating both sequences and putting
635 them in variant frags. In position-dependent code, the first sequence
636 will be the GP-relative one and the second sequence will be the
637 absolute one. In SVR4 PIC, the first sequence will be for global
638 symbols and the second will be for local symbols.
640 The frag's "subtype" is RELAX_ENCODE (FIRST, SECOND), where FIRST and
641 SECOND are the lengths of the two sequences in bytes. These fields
642 can be extracted using RELAX_FIRST() and RELAX_SECOND(). In addition,
643 the subtype has the following flags:
645 RELAX_USE_SECOND
646 Set if it has been decided that we should use the second
647 sequence instead of the first.
649 RELAX_SECOND_LONGER
650 Set in the first variant frag if the macro's second implementation
651 is longer than its first. This refers to the macro as a whole,
652 not an individual relaxation.
654 RELAX_NOMACRO
655 Set in the first variant frag if the macro appeared in a .set nomacro
656 block and if one alternative requires a warning but the other does not.
658 RELAX_DELAY_SLOT
659 Like RELAX_NOMACRO, but indicates that the macro appears in a branch
660 delay slot.
662 The frag's "opcode" points to the first fixup for relaxable code.
664 Relaxable macros are generated using a sequence such as:
666 relax_start (SYMBOL);
667 ... generate first expansion ...
668 relax_switch ();
669 ... generate second expansion ...
670 relax_end ();
672 The code and fixups for the unwanted alternative are discarded
673 by md_convert_frag. */
674 #define RELAX_ENCODE(FIRST, SECOND) (((FIRST) << 8) | (SECOND))
676 #define RELAX_FIRST(X) (((X) >> 8) & 0xff)
677 #define RELAX_SECOND(X) ((X) & 0xff)
678 #define RELAX_USE_SECOND 0x10000
679 #define RELAX_SECOND_LONGER 0x20000
680 #define RELAX_NOMACRO 0x40000
681 #define RELAX_DELAY_SLOT 0x80000
683 /* Branch without likely bit. If label is out of range, we turn:
685 beq reg1, reg2, label
686 delay slot
688 into
690 bne reg1, reg2, 0f
692 j label
693 0: delay slot
695 with the following opcode replacements:
697 beq <-> bne
698 blez <-> bgtz
699 bltz <-> bgez
700 bc1f <-> bc1t
702 bltzal <-> bgezal (with jal label instead of j label)
704 Even though keeping the delay slot instruction in the delay slot of
705 the branch would be more efficient, it would be very tricky to do
706 correctly, because we'd have to introduce a variable frag *after*
707 the delay slot instruction, and expand that instead. Let's do it
708 the easy way for now, even if the branch-not-taken case now costs
709 one additional instruction. Out-of-range branches are not supposed
710 to be common, anyway.
712 Branch likely. If label is out of range, we turn:
714 beql reg1, reg2, label
715 delay slot (annulled if branch not taken)
717 into
719 beql reg1, reg2, 1f
721 beql $0, $0, 2f
723 1: j[al] label
724 delay slot (executed only if branch taken)
727 It would be possible to generate a shorter sequence by losing the
728 likely bit, generating something like:
730 bne reg1, reg2, 0f
732 j[al] label
733 delay slot (executed only if branch taken)
736 beql -> bne
737 bnel -> beq
738 blezl -> bgtz
739 bgtzl -> blez
740 bltzl -> bgez
741 bgezl -> bltz
742 bc1fl -> bc1t
743 bc1tl -> bc1f
745 bltzall -> bgezal (with jal label instead of j label)
746 bgezall -> bltzal (ditto)
749 but it's not clear that it would actually improve performance. */
750 #define RELAX_BRANCH_ENCODE(uncond, likely, link, toofar) \
751 ((relax_substateT) \
752 (0xc0000000 \
753 | ((toofar) ? 1 : 0) \
754 | ((link) ? 2 : 0) \
755 | ((likely) ? 4 : 0) \
756 | ((uncond) ? 8 : 0)))
757 #define RELAX_BRANCH_P(i) (((i) & 0xf0000000) == 0xc0000000)
758 #define RELAX_BRANCH_UNCOND(i) (((i) & 8) != 0)
759 #define RELAX_BRANCH_LIKELY(i) (((i) & 4) != 0)
760 #define RELAX_BRANCH_LINK(i) (((i) & 2) != 0)
761 #define RELAX_BRANCH_TOOFAR(i) (((i) & 1) != 0)
763 /* For mips16 code, we use an entirely different form of relaxation.
764 mips16 supports two versions of most instructions which take
765 immediate values: a small one which takes some small value, and a
766 larger one which takes a 16 bit value. Since branches also follow
767 this pattern, relaxing these values is required.
769 We can assemble both mips16 and normal MIPS code in a single
770 object. Therefore, we need to support this type of relaxation at
771 the same time that we support the relaxation described above. We
772 use the high bit of the subtype field to distinguish these cases.
774 The information we store for this type of relaxation is the
775 argument code found in the opcode file for this relocation, whether
776 the user explicitly requested a small or extended form, and whether
777 the relocation is in a jump or jal delay slot. That tells us the
778 size of the value, and how it should be stored. We also store
779 whether the fragment is considered to be extended or not. We also
780 store whether this is known to be a branch to a different section,
781 whether we have tried to relax this frag yet, and whether we have
782 ever extended a PC relative fragment because of a shift count. */
783 #define RELAX_MIPS16_ENCODE(type, small, ext, dslot, jal_dslot) \
784 (0x80000000 \
785 | ((type) & 0xff) \
786 | ((small) ? 0x100 : 0) \
787 | ((ext) ? 0x200 : 0) \
788 | ((dslot) ? 0x400 : 0) \
789 | ((jal_dslot) ? 0x800 : 0))
790 #define RELAX_MIPS16_P(i) (((i) & 0xc0000000) == 0x80000000)
791 #define RELAX_MIPS16_TYPE(i) ((i) & 0xff)
792 #define RELAX_MIPS16_USER_SMALL(i) (((i) & 0x100) != 0)
793 #define RELAX_MIPS16_USER_EXT(i) (((i) & 0x200) != 0)
794 #define RELAX_MIPS16_DSLOT(i) (((i) & 0x400) != 0)
795 #define RELAX_MIPS16_JAL_DSLOT(i) (((i) & 0x800) != 0)
796 #define RELAX_MIPS16_EXTENDED(i) (((i) & 0x1000) != 0)
797 #define RELAX_MIPS16_MARK_EXTENDED(i) ((i) | 0x1000)
798 #define RELAX_MIPS16_CLEAR_EXTENDED(i) ((i) &~ 0x1000)
799 #define RELAX_MIPS16_LONG_BRANCH(i) (((i) & 0x2000) != 0)
800 #define RELAX_MIPS16_MARK_LONG_BRANCH(i) ((i) | 0x2000)
801 #define RELAX_MIPS16_CLEAR_LONG_BRANCH(i) ((i) &~ 0x2000)
803 /* Is the given value a sign-extended 32-bit value? */
804 #define IS_SEXT_32BIT_NUM(x) \
805 (((x) &~ (offsetT) 0x7fffffff) == 0 \
806 || (((x) &~ (offsetT) 0x7fffffff) == ~ (offsetT) 0x7fffffff))
808 /* Is the given value a sign-extended 16-bit value? */
809 #define IS_SEXT_16BIT_NUM(x) \
810 (((x) &~ (offsetT) 0x7fff) == 0 \
811 || (((x) &~ (offsetT) 0x7fff) == ~ (offsetT) 0x7fff))
814 /* Global variables used when generating relaxable macros. See the
815 comment above RELAX_ENCODE for more details about how relaxation
816 is used. */
817 static struct {
818 /* 0 if we're not emitting a relaxable macro.
819 1 if we're emitting the first of the two relaxation alternatives.
820 2 if we're emitting the second alternative. */
821 int sequence;
823 /* The first relaxable fixup in the current frag. (In other words,
824 the first fixup that refers to relaxable code.) */
825 fixS *first_fixup;
827 /* sizes[0] says how many bytes of the first alternative are stored in
828 the current frag. Likewise sizes[1] for the second alternative. */
829 unsigned int sizes[2];
831 /* The symbol on which the choice of sequence depends. */
832 symbolS *symbol;
833 } mips_relax;
835 /* Global variables used to decide whether a macro needs a warning. */
836 static struct {
837 /* True if the macro is in a branch delay slot. */
838 bfd_boolean delay_slot_p;
840 /* For relaxable macros, sizes[0] is the length of the first alternative
841 in bytes and sizes[1] is the length of the second alternative.
842 For non-relaxable macros, both elements give the length of the
843 macro in bytes. */
844 unsigned int sizes[2];
846 /* The first variant frag for this macro. */
847 fragS *first_frag;
848 } mips_macro_warning;
850 /* Prototypes for static functions. */
852 #define internalError() \
853 as_fatal (_("internal Error, line %d, %s"), __LINE__, __FILE__)
855 enum mips_regclass { MIPS_GR_REG, MIPS_FP_REG, MIPS16_REG };
857 static void append_insn
858 (struct mips_cl_insn *ip, expressionS *p, bfd_reloc_code_real_type *r);
859 static void mips_no_prev_insn (int);
860 static void mips16_macro_build
861 (expressionS *, const char *, const char *, va_list);
862 static void load_register (int, expressionS *, int);
863 static void macro_start (void);
864 static void macro_end (void);
865 static void macro (struct mips_cl_insn * ip);
866 static void mips16_macro (struct mips_cl_insn * ip);
867 #ifdef LOSING_COMPILER
868 static void macro2 (struct mips_cl_insn * ip);
869 #endif
870 static void mips_ip (char *str, struct mips_cl_insn * ip);
871 static void mips16_ip (char *str, struct mips_cl_insn * ip);
872 static void mips16_immed
873 (char *, unsigned int, int, offsetT, bfd_boolean, bfd_boolean, bfd_boolean,
874 unsigned long *, bfd_boolean *, unsigned short *);
875 static size_t my_getSmallExpression
876 (expressionS *, bfd_reloc_code_real_type *, char *);
877 static void my_getExpression (expressionS *, char *);
878 static void s_align (int);
879 static void s_change_sec (int);
880 static void s_change_section (int);
881 static void s_cons (int);
882 static void s_float_cons (int);
883 static void s_mips_globl (int);
884 static void s_option (int);
885 static void s_mipsset (int);
886 static void s_abicalls (int);
887 static void s_cpload (int);
888 static void s_cpsetup (int);
889 static void s_cplocal (int);
890 static void s_cprestore (int);
891 static void s_cpreturn (int);
892 static void s_gpvalue (int);
893 static void s_gpword (int);
894 static void s_gpdword (int);
895 static void s_cpadd (int);
896 static void s_insn (int);
897 static void md_obj_begin (void);
898 static void md_obj_end (void);
899 static void s_mips_ent (int);
900 static void s_mips_end (int);
901 static void s_mips_frame (int);
902 static void s_mips_mask (int reg_type);
903 static void s_mips_stab (int);
904 static void s_mips_weakext (int);
905 static void s_mips_file (int);
906 static void s_mips_loc (int);
907 static bfd_boolean pic_need_relax (symbolS *, asection *);
908 static int relaxed_branch_length (fragS *, asection *, int);
909 static int validate_mips_insn (const struct mips_opcode *);
911 /* Table and functions used to map between CPU/ISA names, and
912 ISA levels, and CPU numbers. */
914 struct mips_cpu_info
916 const char *name; /* CPU or ISA name. */
917 int is_isa; /* Is this an ISA? (If 0, a CPU.) */
918 int isa; /* ISA level. */
919 int cpu; /* CPU number (default CPU if ISA). */
922 static const struct mips_cpu_info *mips_parse_cpu (const char *, const char *);
923 static const struct mips_cpu_info *mips_cpu_info_from_isa (int);
924 static const struct mips_cpu_info *mips_cpu_info_from_arch (int);
926 /* Pseudo-op table.
928 The following pseudo-ops from the Kane and Heinrich MIPS book
929 should be defined here, but are currently unsupported: .alias,
930 .galive, .gjaldef, .gjrlive, .livereg, .noalias.
932 The following pseudo-ops from the Kane and Heinrich MIPS book are
933 specific to the type of debugging information being generated, and
934 should be defined by the object format: .aent, .begin, .bend,
935 .bgnb, .end, .endb, .ent, .fmask, .frame, .loc, .mask, .verstamp,
936 .vreg.
938 The following pseudo-ops from the Kane and Heinrich MIPS book are
939 not MIPS CPU specific, but are also not specific to the object file
940 format. This file is probably the best place to define them, but
941 they are not currently supported: .asm0, .endr, .lab, .repeat,
942 .struct. */
944 static const pseudo_typeS mips_pseudo_table[] =
946 /* MIPS specific pseudo-ops. */
947 {"option", s_option, 0},
948 {"set", s_mipsset, 0},
949 {"rdata", s_change_sec, 'r'},
950 {"sdata", s_change_sec, 's'},
951 {"livereg", s_ignore, 0},
952 {"abicalls", s_abicalls, 0},
953 {"cpload", s_cpload, 0},
954 {"cpsetup", s_cpsetup, 0},
955 {"cplocal", s_cplocal, 0},
956 {"cprestore", s_cprestore, 0},
957 {"cpreturn", s_cpreturn, 0},
958 {"gpvalue", s_gpvalue, 0},
959 {"gpword", s_gpword, 0},
960 {"gpdword", s_gpdword, 0},
961 {"cpadd", s_cpadd, 0},
962 {"insn", s_insn, 0},
964 /* Relatively generic pseudo-ops that happen to be used on MIPS
965 chips. */
966 {"asciiz", stringer, 1},
967 {"bss", s_change_sec, 'b'},
968 {"err", s_err, 0},
969 {"half", s_cons, 1},
970 {"dword", s_cons, 3},
971 {"weakext", s_mips_weakext, 0},
973 /* These pseudo-ops are defined in read.c, but must be overridden
974 here for one reason or another. */
975 {"align", s_align, 0},
976 {"byte", s_cons, 0},
977 {"data", s_change_sec, 'd'},
978 {"double", s_float_cons, 'd'},
979 {"float", s_float_cons, 'f'},
980 {"globl", s_mips_globl, 0},
981 {"global", s_mips_globl, 0},
982 {"hword", s_cons, 1},
983 {"int", s_cons, 2},
984 {"long", s_cons, 2},
985 {"octa", s_cons, 4},
986 {"quad", s_cons, 3},
987 {"section", s_change_section, 0},
988 {"short", s_cons, 1},
989 {"single", s_float_cons, 'f'},
990 {"stabn", s_mips_stab, 'n'},
991 {"text", s_change_sec, 't'},
992 {"word", s_cons, 2},
994 { "extern", ecoff_directive_extern, 0},
996 { NULL, NULL, 0 },
999 static const pseudo_typeS mips_nonecoff_pseudo_table[] =
1001 /* These pseudo-ops should be defined by the object file format.
1002 However, a.out doesn't support them, so we have versions here. */
1003 {"aent", s_mips_ent, 1},
1004 {"bgnb", s_ignore, 0},
1005 {"end", s_mips_end, 0},
1006 {"endb", s_ignore, 0},
1007 {"ent", s_mips_ent, 0},
1008 {"file", s_mips_file, 0},
1009 {"fmask", s_mips_mask, 'F'},
1010 {"frame", s_mips_frame, 0},
1011 {"loc", s_mips_loc, 0},
1012 {"mask", s_mips_mask, 'R'},
1013 {"verstamp", s_ignore, 0},
1014 { NULL, NULL, 0 },
1017 extern void pop_insert (const pseudo_typeS *);
1019 void
1020 mips_pop_insert (void)
1022 pop_insert (mips_pseudo_table);
1023 if (! ECOFF_DEBUGGING)
1024 pop_insert (mips_nonecoff_pseudo_table);
1027 /* Symbols labelling the current insn. */
1029 struct insn_label_list
1031 struct insn_label_list *next;
1032 symbolS *label;
1035 static struct insn_label_list *insn_labels;
1036 static struct insn_label_list *free_insn_labels;
1038 static void mips_clear_insn_labels (void);
1040 static inline void
1041 mips_clear_insn_labels (void)
1043 register struct insn_label_list **pl;
1045 for (pl = &free_insn_labels; *pl != NULL; pl = &(*pl)->next)
1047 *pl = insn_labels;
1048 insn_labels = NULL;
1051 static char *expr_end;
1053 /* Expressions which appear in instructions. These are set by
1054 mips_ip. */
1056 static expressionS imm_expr;
1057 static expressionS imm2_expr;
1058 static expressionS offset_expr;
1060 /* Relocs associated with imm_expr and offset_expr. */
1062 static bfd_reloc_code_real_type imm_reloc[3]
1063 = {BFD_RELOC_UNUSED, BFD_RELOC_UNUSED, BFD_RELOC_UNUSED};
1064 static bfd_reloc_code_real_type offset_reloc[3]
1065 = {BFD_RELOC_UNUSED, BFD_RELOC_UNUSED, BFD_RELOC_UNUSED};
1067 /* These are set by mips16_ip if an explicit extension is used. */
1069 static bfd_boolean mips16_small, mips16_ext;
1071 #ifdef OBJ_ELF
1072 /* The pdr segment for per procedure frame/regmask info. Not used for
1073 ECOFF debugging. */
1075 static segT pdr_seg;
1076 #endif
1078 /* The default target format to use. */
1080 const char *
1081 mips_target_format (void)
1083 switch (OUTPUT_FLAVOR)
1085 case bfd_target_ecoff_flavour:
1086 return target_big_endian ? "ecoff-bigmips" : ECOFF_LITTLE_FORMAT;
1087 case bfd_target_coff_flavour:
1088 return "pe-mips";
1089 case bfd_target_elf_flavour:
1090 #ifdef TE_TMIPS
1091 /* This is traditional mips. */
1092 return (target_big_endian
1093 ? (HAVE_64BIT_OBJECTS
1094 ? "elf64-tradbigmips"
1095 : (HAVE_NEWABI
1096 ? "elf32-ntradbigmips" : "elf32-tradbigmips"))
1097 : (HAVE_64BIT_OBJECTS
1098 ? "elf64-tradlittlemips"
1099 : (HAVE_NEWABI
1100 ? "elf32-ntradlittlemips" : "elf32-tradlittlemips")));
1101 #else
1102 return (target_big_endian
1103 ? (HAVE_64BIT_OBJECTS
1104 ? "elf64-bigmips"
1105 : (HAVE_NEWABI
1106 ? "elf32-nbigmips" : "elf32-bigmips"))
1107 : (HAVE_64BIT_OBJECTS
1108 ? "elf64-littlemips"
1109 : (HAVE_NEWABI
1110 ? "elf32-nlittlemips" : "elf32-littlemips")));
1111 #endif
1112 default:
1113 abort ();
1114 return NULL;
1118 /* This function is called once, at assembler startup time. It should
1119 set up all the tables, etc. that the MD part of the assembler will need. */
1121 void
1122 md_begin (void)
1124 register const char *retval = NULL;
1125 int i = 0;
1126 int broken = 0;
1128 if (! bfd_set_arch_mach (stdoutput, bfd_arch_mips, file_mips_arch))
1129 as_warn (_("Could not set architecture and machine"));
1131 op_hash = hash_new ();
1133 for (i = 0; i < NUMOPCODES;)
1135 const char *name = mips_opcodes[i].name;
1137 retval = hash_insert (op_hash, name, (void *) &mips_opcodes[i]);
1138 if (retval != NULL)
1140 fprintf (stderr, _("internal error: can't hash `%s': %s\n"),
1141 mips_opcodes[i].name, retval);
1142 /* Probably a memory allocation problem? Give up now. */
1143 as_fatal (_("Broken assembler. No assembly attempted."));
1147 if (mips_opcodes[i].pinfo != INSN_MACRO)
1149 if (!validate_mips_insn (&mips_opcodes[i]))
1150 broken = 1;
1152 ++i;
1154 while ((i < NUMOPCODES) && !strcmp (mips_opcodes[i].name, name));
1157 mips16_op_hash = hash_new ();
1159 i = 0;
1160 while (i < bfd_mips16_num_opcodes)
1162 const char *name = mips16_opcodes[i].name;
1164 retval = hash_insert (mips16_op_hash, name, (void *) &mips16_opcodes[i]);
1165 if (retval != NULL)
1166 as_fatal (_("internal: can't hash `%s': %s"),
1167 mips16_opcodes[i].name, retval);
1170 if (mips16_opcodes[i].pinfo != INSN_MACRO
1171 && ((mips16_opcodes[i].match & mips16_opcodes[i].mask)
1172 != mips16_opcodes[i].match))
1174 fprintf (stderr, _("internal error: bad mips16 opcode: %s %s\n"),
1175 mips16_opcodes[i].name, mips16_opcodes[i].args);
1176 broken = 1;
1178 ++i;
1180 while (i < bfd_mips16_num_opcodes
1181 && strcmp (mips16_opcodes[i].name, name) == 0);
1184 if (broken)
1185 as_fatal (_("Broken assembler. No assembly attempted."));
1187 /* We add all the general register names to the symbol table. This
1188 helps us detect invalid uses of them. */
1189 for (i = 0; i < 32; i++)
1191 char buf[5];
1193 sprintf (buf, "$%d", i);
1194 symbol_table_insert (symbol_new (buf, reg_section, i,
1195 &zero_address_frag));
1197 symbol_table_insert (symbol_new ("$ra", reg_section, RA,
1198 &zero_address_frag));
1199 symbol_table_insert (symbol_new ("$fp", reg_section, FP,
1200 &zero_address_frag));
1201 symbol_table_insert (symbol_new ("$sp", reg_section, SP,
1202 &zero_address_frag));
1203 symbol_table_insert (symbol_new ("$gp", reg_section, GP,
1204 &zero_address_frag));
1205 symbol_table_insert (symbol_new ("$at", reg_section, AT,
1206 &zero_address_frag));
1207 symbol_table_insert (symbol_new ("$kt0", reg_section, KT0,
1208 &zero_address_frag));
1209 symbol_table_insert (symbol_new ("$kt1", reg_section, KT1,
1210 &zero_address_frag));
1211 symbol_table_insert (symbol_new ("$zero", reg_section, ZERO,
1212 &zero_address_frag));
1213 symbol_table_insert (symbol_new ("$pc", reg_section, -1,
1214 &zero_address_frag));
1216 /* If we don't add these register names to the symbol table, they
1217 may end up being added as regular symbols by operand(), and then
1218 make it to the object file as undefined in case they're not
1219 regarded as local symbols. They're local in o32, since `$' is a
1220 local symbol prefix, but not in n32 or n64. */
1221 for (i = 0; i < 8; i++)
1223 char buf[6];
1225 sprintf (buf, "$fcc%i", i);
1226 symbol_table_insert (symbol_new (buf, reg_section, -1,
1227 &zero_address_frag));
1230 mips_no_prev_insn (FALSE);
1232 mips_gprmask = 0;
1233 mips_cprmask[0] = 0;
1234 mips_cprmask[1] = 0;
1235 mips_cprmask[2] = 0;
1236 mips_cprmask[3] = 0;
1238 /* set the default alignment for the text section (2**2) */
1239 record_alignment (text_section, 2);
1241 bfd_set_gp_size (stdoutput, g_switch_value);
1243 if (OUTPUT_FLAVOR == bfd_target_elf_flavour)
1245 /* On a native system, sections must be aligned to 16 byte
1246 boundaries. When configured for an embedded ELF target, we
1247 don't bother. */
1248 if (strcmp (TARGET_OS, "elf") != 0)
1250 (void) bfd_set_section_alignment (stdoutput, text_section, 4);
1251 (void) bfd_set_section_alignment (stdoutput, data_section, 4);
1252 (void) bfd_set_section_alignment (stdoutput, bss_section, 4);
1255 /* Create a .reginfo section for register masks and a .mdebug
1256 section for debugging information. */
1258 segT seg;
1259 subsegT subseg;
1260 flagword flags;
1261 segT sec;
1263 seg = now_seg;
1264 subseg = now_subseg;
1266 /* The ABI says this section should be loaded so that the
1267 running program can access it. However, we don't load it
1268 if we are configured for an embedded target */
1269 flags = SEC_READONLY | SEC_DATA;
1270 if (strcmp (TARGET_OS, "elf") != 0)
1271 flags |= SEC_ALLOC | SEC_LOAD;
1273 if (mips_abi != N64_ABI)
1275 sec = subseg_new (".reginfo", (subsegT) 0);
1277 bfd_set_section_flags (stdoutput, sec, flags);
1278 bfd_set_section_alignment (stdoutput, sec, HAVE_NEWABI ? 3 : 2);
1280 #ifdef OBJ_ELF
1281 mips_regmask_frag = frag_more (sizeof (Elf32_External_RegInfo));
1282 #endif
1284 else
1286 /* The 64-bit ABI uses a .MIPS.options section rather than
1287 .reginfo section. */
1288 sec = subseg_new (".MIPS.options", (subsegT) 0);
1289 bfd_set_section_flags (stdoutput, sec, flags);
1290 bfd_set_section_alignment (stdoutput, sec, 3);
1292 #ifdef OBJ_ELF
1293 /* Set up the option header. */
1295 Elf_Internal_Options opthdr;
1296 char *f;
1298 opthdr.kind = ODK_REGINFO;
1299 opthdr.size = (sizeof (Elf_External_Options)
1300 + sizeof (Elf64_External_RegInfo));
1301 opthdr.section = 0;
1302 opthdr.info = 0;
1303 f = frag_more (sizeof (Elf_External_Options));
1304 bfd_mips_elf_swap_options_out (stdoutput, &opthdr,
1305 (Elf_External_Options *) f);
1307 mips_regmask_frag = frag_more (sizeof (Elf64_External_RegInfo));
1309 #endif
1312 if (ECOFF_DEBUGGING)
1314 sec = subseg_new (".mdebug", (subsegT) 0);
1315 (void) bfd_set_section_flags (stdoutput, sec,
1316 SEC_HAS_CONTENTS | SEC_READONLY);
1317 (void) bfd_set_section_alignment (stdoutput, sec, 2);
1319 #ifdef OBJ_ELF
1320 else if (OUTPUT_FLAVOR == bfd_target_elf_flavour && mips_flag_pdr)
1322 pdr_seg = subseg_new (".pdr", (subsegT) 0);
1323 (void) bfd_set_section_flags (stdoutput, pdr_seg,
1324 SEC_READONLY | SEC_RELOC
1325 | SEC_DEBUGGING);
1326 (void) bfd_set_section_alignment (stdoutput, pdr_seg, 2);
1328 #endif
1330 subseg_set (seg, subseg);
1334 if (! ECOFF_DEBUGGING)
1335 md_obj_begin ();
1338 void
1339 md_mips_end (void)
1341 if (! ECOFF_DEBUGGING)
1342 md_obj_end ();
1345 void
1346 md_assemble (char *str)
1348 struct mips_cl_insn insn;
1349 bfd_reloc_code_real_type unused_reloc[3]
1350 = {BFD_RELOC_UNUSED, BFD_RELOC_UNUSED, BFD_RELOC_UNUSED};
1352 imm_expr.X_op = O_absent;
1353 imm2_expr.X_op = O_absent;
1354 offset_expr.X_op = O_absent;
1355 imm_reloc[0] = BFD_RELOC_UNUSED;
1356 imm_reloc[1] = BFD_RELOC_UNUSED;
1357 imm_reloc[2] = BFD_RELOC_UNUSED;
1358 offset_reloc[0] = BFD_RELOC_UNUSED;
1359 offset_reloc[1] = BFD_RELOC_UNUSED;
1360 offset_reloc[2] = BFD_RELOC_UNUSED;
1362 if (mips_opts.mips16)
1363 mips16_ip (str, &insn);
1364 else
1366 mips_ip (str, &insn);
1367 DBG ((_("returned from mips_ip(%s) insn_opcode = 0x%x\n"),
1368 str, insn.insn_opcode));
1371 if (insn_error)
1373 as_bad ("%s `%s'", insn_error, str);
1374 return;
1377 if (insn.insn_mo->pinfo == INSN_MACRO)
1379 macro_start ();
1380 if (mips_opts.mips16)
1381 mips16_macro (&insn);
1382 else
1383 macro (&insn);
1384 macro_end ();
1386 else
1388 if (imm_expr.X_op != O_absent)
1389 append_insn (&insn, &imm_expr, imm_reloc);
1390 else if (offset_expr.X_op != O_absent)
1391 append_insn (&insn, &offset_expr, offset_reloc);
1392 else
1393 append_insn (&insn, NULL, unused_reloc);
1397 /* Return true if the given relocation might need a matching %lo().
1398 Note that R_MIPS_GOT16 relocations only need a matching %lo() when
1399 applied to local symbols. */
1401 static inline bfd_boolean
1402 reloc_needs_lo_p (bfd_reloc_code_real_type reloc)
1404 return (HAVE_IN_PLACE_ADDENDS
1405 && (reloc == BFD_RELOC_HI16_S
1406 || reloc == BFD_RELOC_MIPS_GOT16));
1409 /* Return true if the given fixup is followed by a matching R_MIPS_LO16
1410 relocation. */
1412 static inline bfd_boolean
1413 fixup_has_matching_lo_p (fixS *fixp)
1415 return (fixp->fx_next != NULL
1416 && fixp->fx_next->fx_r_type == BFD_RELOC_LO16
1417 && fixp->fx_addsy == fixp->fx_next->fx_addsy
1418 && fixp->fx_offset == fixp->fx_next->fx_offset);
1421 /* See whether instruction IP reads register REG. CLASS is the type
1422 of register. */
1424 static int
1425 insn_uses_reg (struct mips_cl_insn *ip, unsigned int reg,
1426 enum mips_regclass class)
1428 if (class == MIPS16_REG)
1430 assert (mips_opts.mips16);
1431 reg = mips16_to_32_reg_map[reg];
1432 class = MIPS_GR_REG;
1435 /* Don't report on general register ZERO, since it never changes. */
1436 if (class == MIPS_GR_REG && reg == ZERO)
1437 return 0;
1439 if (class == MIPS_FP_REG)
1441 assert (! mips_opts.mips16);
1442 /* If we are called with either $f0 or $f1, we must check $f0.
1443 This is not optimal, because it will introduce an unnecessary
1444 NOP between "lwc1 $f0" and "swc1 $f1". To fix this we would
1445 need to distinguish reading both $f0 and $f1 or just one of
1446 them. Note that we don't have to check the other way,
1447 because there is no instruction that sets both $f0 and $f1
1448 and requires a delay. */
1449 if ((ip->insn_mo->pinfo & INSN_READ_FPR_S)
1450 && ((((ip->insn_opcode >> OP_SH_FS) & OP_MASK_FS) &~(unsigned)1)
1451 == (reg &~ (unsigned) 1)))
1452 return 1;
1453 if ((ip->insn_mo->pinfo & INSN_READ_FPR_T)
1454 && ((((ip->insn_opcode >> OP_SH_FT) & OP_MASK_FT) &~(unsigned)1)
1455 == (reg &~ (unsigned) 1)))
1456 return 1;
1458 else if (! mips_opts.mips16)
1460 if ((ip->insn_mo->pinfo & INSN_READ_GPR_S)
1461 && ((ip->insn_opcode >> OP_SH_RS) & OP_MASK_RS) == reg)
1462 return 1;
1463 if ((ip->insn_mo->pinfo & INSN_READ_GPR_T)
1464 && ((ip->insn_opcode >> OP_SH_RT) & OP_MASK_RT) == reg)
1465 return 1;
1467 else
1469 if ((ip->insn_mo->pinfo & MIPS16_INSN_READ_X)
1470 && (mips16_to_32_reg_map[((ip->insn_opcode >> MIPS16OP_SH_RX)
1471 & MIPS16OP_MASK_RX)]
1472 == reg))
1473 return 1;
1474 if ((ip->insn_mo->pinfo & MIPS16_INSN_READ_Y)
1475 && (mips16_to_32_reg_map[((ip->insn_opcode >> MIPS16OP_SH_RY)
1476 & MIPS16OP_MASK_RY)]
1477 == reg))
1478 return 1;
1479 if ((ip->insn_mo->pinfo & MIPS16_INSN_READ_Z)
1480 && (mips16_to_32_reg_map[((ip->insn_opcode >> MIPS16OP_SH_MOVE32Z)
1481 & MIPS16OP_MASK_MOVE32Z)]
1482 == reg))
1483 return 1;
1484 if ((ip->insn_mo->pinfo & MIPS16_INSN_READ_T) && reg == TREG)
1485 return 1;
1486 if ((ip->insn_mo->pinfo & MIPS16_INSN_READ_SP) && reg == SP)
1487 return 1;
1488 if ((ip->insn_mo->pinfo & MIPS16_INSN_READ_31) && reg == RA)
1489 return 1;
1490 if ((ip->insn_mo->pinfo & MIPS16_INSN_READ_GPR_X)
1491 && ((ip->insn_opcode >> MIPS16OP_SH_REGR32)
1492 & MIPS16OP_MASK_REGR32) == reg)
1493 return 1;
1496 return 0;
1499 /* This function returns true if modifying a register requires a
1500 delay. */
1502 static int
1503 reg_needs_delay (unsigned int reg)
1505 unsigned long prev_pinfo;
1507 prev_pinfo = prev_insn.insn_mo->pinfo;
1508 if (! mips_opts.noreorder
1509 && (((prev_pinfo & INSN_LOAD_MEMORY_DELAY)
1510 && ! gpr_interlocks)
1511 || ((prev_pinfo & INSN_LOAD_COPROC_DELAY)
1512 && ! cop_interlocks)))
1514 /* A load from a coprocessor or from memory. All load delays
1515 delay the use of general register rt for one instruction. */
1516 /* Itbl support may require additional care here. */
1517 know (prev_pinfo & INSN_WRITE_GPR_T);
1518 if (reg == ((prev_insn.insn_opcode >> OP_SH_RT) & OP_MASK_RT))
1519 return 1;
1522 return 0;
1525 /* Mark instruction labels in mips16 mode. This permits the linker to
1526 handle them specially, such as generating jalx instructions when
1527 needed. We also make them odd for the duration of the assembly, in
1528 order to generate the right sort of code. We will make them even
1529 in the adjust_symtab routine, while leaving them marked. This is
1530 convenient for the debugger and the disassembler. The linker knows
1531 to make them odd again. */
1533 static void
1534 mips16_mark_labels (void)
1536 if (mips_opts.mips16)
1538 struct insn_label_list *l;
1539 valueT val;
1541 for (l = insn_labels; l != NULL; l = l->next)
1543 #ifdef OBJ_ELF
1544 if (OUTPUT_FLAVOR == bfd_target_elf_flavour)
1545 S_SET_OTHER (l->label, STO_MIPS16);
1546 #endif
1547 val = S_GET_VALUE (l->label);
1548 if ((val & 1) == 0)
1549 S_SET_VALUE (l->label, val + 1);
1554 /* End the current frag. Make it a variant frag and record the
1555 relaxation info. */
1557 static void
1558 relax_close_frag (void)
1560 mips_macro_warning.first_frag = frag_now;
1561 frag_var (rs_machine_dependent, 0, 0,
1562 RELAX_ENCODE (mips_relax.sizes[0], mips_relax.sizes[1]),
1563 mips_relax.symbol, 0, (char *) mips_relax.first_fixup);
1565 memset (&mips_relax.sizes, 0, sizeof (mips_relax.sizes));
1566 mips_relax.first_fixup = 0;
1569 /* Start a new relaxation sequence whose expansion depends on SYMBOL.
1570 See the comment above RELAX_ENCODE for more details. */
1572 static void
1573 relax_start (symbolS *symbol)
1575 assert (mips_relax.sequence == 0);
1576 mips_relax.sequence = 1;
1577 mips_relax.symbol = symbol;
1580 /* Start generating the second version of a relaxable sequence.
1581 See the comment above RELAX_ENCODE for more details. */
1583 static void
1584 relax_switch (void)
1586 assert (mips_relax.sequence == 1);
1587 mips_relax.sequence = 2;
1590 /* End the current relaxable sequence. */
1592 static void
1593 relax_end (void)
1595 assert (mips_relax.sequence == 2);
1596 relax_close_frag ();
1597 mips_relax.sequence = 0;
1600 /* Output an instruction. IP is the instruction information.
1601 ADDRESS_EXPR is an operand of the instruction to be used with
1602 RELOC_TYPE. */
1604 static void
1605 append_insn (struct mips_cl_insn *ip, expressionS *address_expr,
1606 bfd_reloc_code_real_type *reloc_type)
1608 register unsigned long prev_pinfo, pinfo;
1609 char *f;
1610 fixS *fixp[3];
1611 int nops = 0;
1612 relax_stateT prev_insn_frag_type = 0;
1613 bfd_boolean relaxed_branch = FALSE;
1614 bfd_boolean force_new_frag = FALSE;
1616 /* Mark instruction labels in mips16 mode. */
1617 mips16_mark_labels ();
1619 prev_pinfo = prev_insn.insn_mo->pinfo;
1620 pinfo = ip->insn_mo->pinfo;
1622 if (mips_relax.sequence != 2
1623 && (!mips_opts.noreorder || prev_nop_frag != NULL))
1625 int prev_prev_nop;
1627 /* If the previous insn required any delay slots, see if we need
1628 to insert a NOP or two. There are eight kinds of possible
1629 hazards, of which an instruction can have at most one type.
1630 (1) a load from memory delay
1631 (2) a load from a coprocessor delay
1632 (3) an unconditional branch delay
1633 (4) a conditional branch delay
1634 (5) a move to coprocessor register delay
1635 (6) a load coprocessor register from memory delay
1636 (7) a coprocessor condition code delay
1637 (8) a HI/LO special register delay
1639 There are a lot of optimizations we could do that we don't.
1640 In particular, we do not, in general, reorder instructions.
1641 If you use gcc with optimization, it will reorder
1642 instructions and generally do much more optimization then we
1643 do here; repeating all that work in the assembler would only
1644 benefit hand written assembly code, and does not seem worth
1645 it. */
1647 /* This is how a NOP is emitted. */
1648 #define emit_nop() \
1649 (mips_opts.mips16 \
1650 ? md_number_to_chars (frag_more (2), 0x6500, 2) \
1651 : md_number_to_chars (frag_more (4), 0, 4))
1653 /* The previous insn might require a delay slot, depending upon
1654 the contents of the current insn. */
1655 if (! mips_opts.mips16
1656 && (((prev_pinfo & INSN_LOAD_MEMORY_DELAY)
1657 && ! gpr_interlocks)
1658 || ((prev_pinfo & INSN_LOAD_COPROC_DELAY)
1659 && ! cop_interlocks)))
1661 /* A load from a coprocessor or from memory. All load
1662 delays delay the use of general register rt for one
1663 instruction. */
1664 /* Itbl support may require additional care here. */
1665 know (prev_pinfo & INSN_WRITE_GPR_T);
1666 if (mips_optimize == 0
1667 || insn_uses_reg (ip,
1668 ((prev_insn.insn_opcode >> OP_SH_RT)
1669 & OP_MASK_RT),
1670 MIPS_GR_REG))
1671 ++nops;
1673 else if (! mips_opts.mips16
1674 && (((prev_pinfo & INSN_COPROC_MOVE_DELAY)
1675 && ! cop_interlocks)
1676 || ((prev_pinfo & INSN_COPROC_MEMORY_DELAY)
1677 && ! cop_mem_interlocks)))
1679 /* A generic coprocessor delay. The previous instruction
1680 modified a coprocessor general or control register. If
1681 it modified a control register, we need to avoid any
1682 coprocessor instruction (this is probably not always
1683 required, but it sometimes is). If it modified a general
1684 register, we avoid using that register.
1686 This case is not handled very well. There is no special
1687 knowledge of CP0 handling, and the coprocessors other
1688 than the floating point unit are not distinguished at
1689 all. */
1690 /* Itbl support may require additional care here. FIXME!
1691 Need to modify this to include knowledge about
1692 user specified delays! */
1693 if (prev_pinfo & INSN_WRITE_FPR_T)
1695 if (mips_optimize == 0
1696 || insn_uses_reg (ip,
1697 ((prev_insn.insn_opcode >> OP_SH_FT)
1698 & OP_MASK_FT),
1699 MIPS_FP_REG))
1700 ++nops;
1702 else if (prev_pinfo & INSN_WRITE_FPR_S)
1704 if (mips_optimize == 0
1705 || insn_uses_reg (ip,
1706 ((prev_insn.insn_opcode >> OP_SH_FS)
1707 & OP_MASK_FS),
1708 MIPS_FP_REG))
1709 ++nops;
1711 else
1713 /* We don't know exactly what the previous instruction
1714 does. If the current instruction uses a coprocessor
1715 register, we must insert a NOP. If previous
1716 instruction may set the condition codes, and the
1717 current instruction uses them, we must insert two
1718 NOPS. */
1719 /* Itbl support may require additional care here. */
1720 if (mips_optimize == 0
1721 || ((prev_pinfo & INSN_WRITE_COND_CODE)
1722 && (pinfo & INSN_READ_COND_CODE)))
1723 nops += 2;
1724 else if (pinfo & INSN_COP)
1725 ++nops;
1728 else if (! mips_opts.mips16
1729 && (prev_pinfo & INSN_WRITE_COND_CODE)
1730 && ! cop_interlocks)
1732 /* The previous instruction sets the coprocessor condition
1733 codes, but does not require a general coprocessor delay
1734 (this means it is a floating point comparison
1735 instruction). If this instruction uses the condition
1736 codes, we need to insert a single NOP. */
1737 /* Itbl support may require additional care here. */
1738 if (mips_optimize == 0
1739 || (pinfo & INSN_READ_COND_CODE))
1740 ++nops;
1743 /* If we're fixing up mfhi/mflo for the r7000 and the
1744 previous insn was an mfhi/mflo and the current insn
1745 reads the register that the mfhi/mflo wrote to, then
1746 insert two nops. */
1748 else if (mips_7000_hilo_fix
1749 && MF_HILO_INSN (prev_pinfo)
1750 && insn_uses_reg (ip, ((prev_insn.insn_opcode >> OP_SH_RD)
1751 & OP_MASK_RD),
1752 MIPS_GR_REG))
1754 nops += 2;
1757 /* If we're fixing up mfhi/mflo for the r7000 and the
1758 2nd previous insn was an mfhi/mflo and the current insn
1759 reads the register that the mfhi/mflo wrote to, then
1760 insert one nop. */
1762 else if (mips_7000_hilo_fix
1763 && MF_HILO_INSN (prev_prev_insn.insn_opcode)
1764 && insn_uses_reg (ip, ((prev_prev_insn.insn_opcode >> OP_SH_RD)
1765 & OP_MASK_RD),
1766 MIPS_GR_REG))
1769 ++nops;
1772 else if (prev_pinfo & INSN_READ_LO)
1774 /* The previous instruction reads the LO register; if the
1775 current instruction writes to the LO register, we must
1776 insert two NOPS. Some newer processors have interlocks.
1777 Also the tx39's multiply instructions can be executed
1778 immediately after a read from HI/LO (without the delay),
1779 though the tx39's divide insns still do require the
1780 delay. */
1781 if (! (hilo_interlocks
1782 || (mips_opts.arch == CPU_R3900 && (pinfo & INSN_MULT)))
1783 && (mips_optimize == 0
1784 || (pinfo & INSN_WRITE_LO)))
1785 nops += 2;
1786 /* Most mips16 branch insns don't have a delay slot.
1787 If a read from LO is immediately followed by a branch
1788 to a write to LO we have a read followed by a write
1789 less than 2 insns away. We assume the target of
1790 a branch might be a write to LO, and insert a nop
1791 between a read and an immediately following branch. */
1792 else if (mips_opts.mips16
1793 && (mips_optimize == 0
1794 || (pinfo & MIPS16_INSN_BRANCH)))
1795 ++nops;
1797 else if (prev_insn.insn_mo->pinfo & INSN_READ_HI)
1799 /* The previous instruction reads the HI register; if the
1800 current instruction writes to the HI register, we must
1801 insert a NOP. Some newer processors have interlocks.
1802 Also the note tx39's multiply above. */
1803 if (! (hilo_interlocks
1804 || (mips_opts.arch == CPU_R3900 && (pinfo & INSN_MULT)))
1805 && (mips_optimize == 0
1806 || (pinfo & INSN_WRITE_HI)))
1807 nops += 2;
1808 /* Most mips16 branch insns don't have a delay slot.
1809 If a read from HI is immediately followed by a branch
1810 to a write to HI we have a read followed by a write
1811 less than 2 insns away. We assume the target of
1812 a branch might be a write to HI, and insert a nop
1813 between a read and an immediately following branch. */
1814 else if (mips_opts.mips16
1815 && (mips_optimize == 0
1816 || (pinfo & MIPS16_INSN_BRANCH)))
1817 ++nops;
1820 /* If the previous instruction was in a noreorder section, then
1821 we don't want to insert the nop after all. */
1822 /* Itbl support may require additional care here. */
1823 if (prev_insn_unreordered)
1824 nops = 0;
1826 /* There are two cases which require two intervening
1827 instructions: 1) setting the condition codes using a move to
1828 coprocessor instruction which requires a general coprocessor
1829 delay and then reading the condition codes 2) reading the HI
1830 or LO register and then writing to it (except on processors
1831 which have interlocks). If we are not already emitting a NOP
1832 instruction, we must check for these cases compared to the
1833 instruction previous to the previous instruction. */
1834 if ((! mips_opts.mips16
1835 && (prev_prev_insn.insn_mo->pinfo & INSN_COPROC_MOVE_DELAY)
1836 && (prev_prev_insn.insn_mo->pinfo & INSN_WRITE_COND_CODE)
1837 && (pinfo & INSN_READ_COND_CODE)
1838 && ! cop_interlocks)
1839 || ((prev_prev_insn.insn_mo->pinfo & INSN_READ_LO)
1840 && (pinfo & INSN_WRITE_LO)
1841 && ! (hilo_interlocks
1842 || (mips_opts.arch == CPU_R3900 && (pinfo & INSN_MULT))))
1843 || ((prev_prev_insn.insn_mo->pinfo & INSN_READ_HI)
1844 && (pinfo & INSN_WRITE_HI)
1845 && ! (hilo_interlocks
1846 || (mips_opts.arch == CPU_R3900 && (pinfo & INSN_MULT)))))
1847 prev_prev_nop = 1;
1848 else
1849 prev_prev_nop = 0;
1851 if (prev_prev_insn_unreordered)
1852 prev_prev_nop = 0;
1854 if (prev_prev_nop && nops == 0)
1855 ++nops;
1857 if (mips_fix_vr4120 && prev_insn.insn_mo->name)
1859 /* We're out of bits in pinfo, so we must resort to string
1860 ops here. Shortcuts are selected based on opcodes being
1861 limited to the VR4120 instruction set. */
1862 int min_nops = 0;
1863 const char *pn = prev_insn.insn_mo->name;
1864 const char *tn = ip->insn_mo->name;
1865 if (strncmp (pn, "macc", 4) == 0
1866 || strncmp (pn, "dmacc", 5) == 0)
1868 /* Errata 21 - [D]DIV[U] after [D]MACC */
1869 if (strstr (tn, "div"))
1870 min_nops = 1;
1872 /* VR4181A errata MD(1): "If a MULT, MULTU, DMULT or DMULTU
1873 instruction is executed immediately after a MACC or
1874 DMACC instruction, the result of [either instruction]
1875 is incorrect." */
1876 if (strncmp (tn, "mult", 4) == 0
1877 || strncmp (tn, "dmult", 5) == 0)
1878 min_nops = 1;
1880 /* Errata 23 - Continuous DMULT[U]/DMACC instructions.
1881 Applies on top of VR4181A MD(1) errata. */
1882 if (pn[0] == 'd' && strncmp (tn, "dmacc", 5) == 0)
1883 min_nops = 1;
1885 /* Errata 24 - MT{LO,HI} after [D]MACC */
1886 if (strcmp (tn, "mtlo") == 0
1887 || strcmp (tn, "mthi") == 0)
1888 min_nops = 1;
1890 else if (strncmp (pn, "dmult", 5) == 0
1891 && (strncmp (tn, "dmult", 5) == 0
1892 || strncmp (tn, "dmacc", 5) == 0))
1894 /* Here is the rest of errata 23. */
1895 min_nops = 1;
1897 else if ((strncmp (pn, "dmult", 5) == 0 || strstr (pn, "div"))
1898 && (strncmp (tn, "macc", 4) == 0
1899 || strncmp (tn, "dmacc", 5) == 0))
1901 /* VR4181A errata MD(4): "If a MACC or DMACC instruction is
1902 executed immediately after a DMULT, DMULTU, DIV, DIVU,
1903 DDIV or DDIVU instruction, the result of the MACC or
1904 DMACC instruction is incorrect.". This partly overlaps
1905 the workaround for errata 23. */
1906 min_nops = 1;
1908 if (nops < min_nops)
1909 nops = min_nops;
1912 /* If we are being given a nop instruction, don't bother with
1913 one of the nops we would otherwise output. This will only
1914 happen when a nop instruction is used with mips_optimize set
1915 to 0. */
1916 if (nops > 0
1917 && ! mips_opts.noreorder
1918 && ip->insn_opcode == (unsigned) (mips_opts.mips16 ? 0x6500 : 0))
1919 --nops;
1921 /* Now emit the right number of NOP instructions. */
1922 if (nops > 0 && ! mips_opts.noreorder)
1924 fragS *old_frag;
1925 unsigned long old_frag_offset;
1926 int i;
1927 struct insn_label_list *l;
1929 old_frag = frag_now;
1930 old_frag_offset = frag_now_fix ();
1932 for (i = 0; i < nops; i++)
1933 emit_nop ();
1935 if (listing)
1937 listing_prev_line ();
1938 /* We may be at the start of a variant frag. In case we
1939 are, make sure there is enough space for the frag
1940 after the frags created by listing_prev_line. The
1941 argument to frag_grow here must be at least as large
1942 as the argument to all other calls to frag_grow in
1943 this file. We don't have to worry about being in the
1944 middle of a variant frag, because the variants insert
1945 all needed nop instructions themselves. */
1946 frag_grow (40);
1949 for (l = insn_labels; l != NULL; l = l->next)
1951 valueT val;
1953 assert (S_GET_SEGMENT (l->label) == now_seg);
1954 symbol_set_frag (l->label, frag_now);
1955 val = (valueT) frag_now_fix ();
1956 /* mips16 text labels are stored as odd. */
1957 if (mips_opts.mips16)
1958 ++val;
1959 S_SET_VALUE (l->label, val);
1962 #ifndef NO_ECOFF_DEBUGGING
1963 if (ECOFF_DEBUGGING)
1964 ecoff_fix_loc (old_frag, old_frag_offset);
1965 #endif
1967 else if (prev_nop_frag != NULL)
1969 /* We have a frag holding nops we may be able to remove. If
1970 we don't need any nops, we can decrease the size of
1971 prev_nop_frag by the size of one instruction. If we do
1972 need some nops, we count them in prev_nops_required. */
1973 if (prev_nop_frag_since == 0)
1975 if (nops == 0)
1977 prev_nop_frag->fr_fix -= mips_opts.mips16 ? 2 : 4;
1978 --prev_nop_frag_holds;
1980 else
1981 prev_nop_frag_required += nops;
1983 else
1985 if (prev_prev_nop == 0)
1987 prev_nop_frag->fr_fix -= mips_opts.mips16 ? 2 : 4;
1988 --prev_nop_frag_holds;
1990 else
1991 ++prev_nop_frag_required;
1994 if (prev_nop_frag_holds <= prev_nop_frag_required)
1995 prev_nop_frag = NULL;
1997 ++prev_nop_frag_since;
1999 /* Sanity check: by the time we reach the second instruction
2000 after prev_nop_frag, we should have used up all the nops
2001 one way or another. */
2002 assert (prev_nop_frag_since <= 1 || prev_nop_frag == NULL);
2006 /* Record the frag type before frag_var. */
2007 if (prev_insn_frag)
2008 prev_insn_frag_type = prev_insn_frag->fr_type;
2010 if (address_expr
2011 && *reloc_type == BFD_RELOC_16_PCREL_S2
2012 && (pinfo & INSN_UNCOND_BRANCH_DELAY || pinfo & INSN_COND_BRANCH_DELAY
2013 || pinfo & INSN_COND_BRANCH_LIKELY)
2014 && mips_relax_branch
2015 /* Don't try branch relaxation within .set nomacro, or within
2016 .set noat if we use $at for PIC computations. If it turns
2017 out that the branch was out-of-range, we'll get an error. */
2018 && !mips_opts.warn_about_macros
2019 && !(mips_opts.noat && mips_pic != NO_PIC)
2020 && !mips_opts.mips16)
2022 relaxed_branch = TRUE;
2023 f = frag_var (rs_machine_dependent,
2024 relaxed_branch_length
2025 (NULL, NULL,
2026 (pinfo & INSN_UNCOND_BRANCH_DELAY) ? -1
2027 : (pinfo & INSN_COND_BRANCH_LIKELY) ? 1 : 0), 4,
2028 RELAX_BRANCH_ENCODE
2029 (pinfo & INSN_UNCOND_BRANCH_DELAY,
2030 pinfo & INSN_COND_BRANCH_LIKELY,
2031 pinfo & INSN_WRITE_GPR_31,
2033 address_expr->X_add_symbol,
2034 address_expr->X_add_number,
2036 *reloc_type = BFD_RELOC_UNUSED;
2038 else if (*reloc_type > BFD_RELOC_UNUSED)
2040 /* We need to set up a variant frag. */
2041 assert (mips_opts.mips16 && address_expr != NULL);
2042 f = frag_var (rs_machine_dependent, 4, 0,
2043 RELAX_MIPS16_ENCODE (*reloc_type - BFD_RELOC_UNUSED,
2044 mips16_small, mips16_ext,
2045 (prev_pinfo
2046 & INSN_UNCOND_BRANCH_DELAY),
2047 (*prev_insn_reloc_type
2048 == BFD_RELOC_MIPS16_JMP)),
2049 make_expr_symbol (address_expr), 0, NULL);
2051 else if (mips_opts.mips16
2052 && ! ip->use_extend
2053 && *reloc_type != BFD_RELOC_MIPS16_JMP)
2055 /* Make sure there is enough room to swap this instruction with
2056 a following jump instruction. */
2057 frag_grow (6);
2058 f = frag_more (2);
2060 else
2062 if (mips_opts.mips16
2063 && mips_opts.noreorder
2064 && (prev_pinfo & INSN_UNCOND_BRANCH_DELAY) != 0)
2065 as_warn (_("extended instruction in delay slot"));
2067 if (mips_relax.sequence)
2069 /* If we've reached the end of this frag, turn it into a variant
2070 frag and record the information for the instructions we've
2071 written so far. */
2072 if (frag_room () < 4)
2073 relax_close_frag ();
2074 mips_relax.sizes[mips_relax.sequence - 1] += 4;
2077 if (mips_relax.sequence != 2)
2078 mips_macro_warning.sizes[0] += 4;
2079 if (mips_relax.sequence != 1)
2080 mips_macro_warning.sizes[1] += 4;
2082 f = frag_more (4);
2085 fixp[0] = fixp[1] = fixp[2] = NULL;
2086 if (address_expr != NULL && *reloc_type <= BFD_RELOC_UNUSED)
2088 if (address_expr->X_op == O_constant)
2090 valueT tmp;
2092 switch (*reloc_type)
2094 case BFD_RELOC_32:
2095 ip->insn_opcode |= address_expr->X_add_number;
2096 break;
2098 case BFD_RELOC_MIPS_HIGHEST:
2099 tmp = (address_expr->X_add_number
2100 + ((valueT) 0x8000 << 32) + 0x80008000) >> 16;
2101 tmp >>= 16;
2102 ip->insn_opcode |= (tmp >> 16) & 0xffff;
2103 break;
2105 case BFD_RELOC_MIPS_HIGHER:
2106 tmp = (address_expr->X_add_number + 0x80008000) >> 16;
2107 ip->insn_opcode |= (tmp >> 16) & 0xffff;
2108 break;
2110 case BFD_RELOC_HI16_S:
2111 ip->insn_opcode |= ((address_expr->X_add_number + 0x8000)
2112 >> 16) & 0xffff;
2113 break;
2115 case BFD_RELOC_HI16:
2116 ip->insn_opcode |= (address_expr->X_add_number >> 16) & 0xffff;
2117 break;
2119 case BFD_RELOC_UNUSED:
2120 case BFD_RELOC_LO16:
2121 case BFD_RELOC_MIPS_GOT_DISP:
2122 ip->insn_opcode |= address_expr->X_add_number & 0xffff;
2123 break;
2125 case BFD_RELOC_MIPS_JMP:
2126 if ((address_expr->X_add_number & 3) != 0)
2127 as_bad (_("jump to misaligned address (0x%lx)"),
2128 (unsigned long) address_expr->X_add_number);
2129 if (address_expr->X_add_number & ~0xfffffff)
2130 as_bad (_("jump address range overflow (0x%lx)"),
2131 (unsigned long) address_expr->X_add_number);
2132 ip->insn_opcode |= (address_expr->X_add_number >> 2) & 0x3ffffff;
2133 break;
2135 case BFD_RELOC_MIPS16_JMP:
2136 if ((address_expr->X_add_number & 3) != 0)
2137 as_bad (_("jump to misaligned address (0x%lx)"),
2138 (unsigned long) address_expr->X_add_number);
2139 if (address_expr->X_add_number & ~0xfffffff)
2140 as_bad (_("jump address range overflow (0x%lx)"),
2141 (unsigned long) address_expr->X_add_number);
2142 ip->insn_opcode |=
2143 (((address_expr->X_add_number & 0x7c0000) << 3)
2144 | ((address_expr->X_add_number & 0xf800000) >> 7)
2145 | ((address_expr->X_add_number & 0x3fffc) >> 2));
2146 break;
2148 case BFD_RELOC_16_PCREL_S2:
2149 goto need_reloc;
2151 default:
2152 internalError ();
2155 else if (*reloc_type < BFD_RELOC_UNUSED)
2156 need_reloc:
2158 reloc_howto_type *howto;
2159 int i;
2161 /* In a compound relocation, it is the final (outermost)
2162 operator that determines the relocated field. */
2163 for (i = 1; i < 3; i++)
2164 if (reloc_type[i] == BFD_RELOC_UNUSED)
2165 break;
2167 howto = bfd_reloc_type_lookup (stdoutput, reloc_type[i - 1]);
2168 fixp[0] = fix_new_exp (frag_now, f - frag_now->fr_literal,
2169 bfd_get_reloc_size(howto),
2170 address_expr,
2171 reloc_type[0] == BFD_RELOC_16_PCREL_S2,
2172 reloc_type[0]);
2174 /* These relocations can have an addend that won't fit in
2175 4 octets for 64bit assembly. */
2176 if (HAVE_64BIT_GPRS
2177 && ! howto->partial_inplace
2178 && (reloc_type[0] == BFD_RELOC_16
2179 || reloc_type[0] == BFD_RELOC_32
2180 || reloc_type[0] == BFD_RELOC_MIPS_JMP
2181 || reloc_type[0] == BFD_RELOC_HI16_S
2182 || reloc_type[0] == BFD_RELOC_LO16
2183 || reloc_type[0] == BFD_RELOC_GPREL16
2184 || reloc_type[0] == BFD_RELOC_MIPS_LITERAL
2185 || reloc_type[0] == BFD_RELOC_GPREL32
2186 || reloc_type[0] == BFD_RELOC_64
2187 || reloc_type[0] == BFD_RELOC_CTOR
2188 || reloc_type[0] == BFD_RELOC_MIPS_SUB
2189 || reloc_type[0] == BFD_RELOC_MIPS_HIGHEST
2190 || reloc_type[0] == BFD_RELOC_MIPS_HIGHER
2191 || reloc_type[0] == BFD_RELOC_MIPS_SCN_DISP
2192 || reloc_type[0] == BFD_RELOC_MIPS_REL16
2193 || reloc_type[0] == BFD_RELOC_MIPS_RELGOT))
2194 fixp[0]->fx_no_overflow = 1;
2196 if (mips_relax.sequence)
2198 if (mips_relax.first_fixup == 0)
2199 mips_relax.first_fixup = fixp[0];
2201 else if (reloc_needs_lo_p (*reloc_type))
2203 struct mips_hi_fixup *hi_fixup;
2205 /* Reuse the last entry if it already has a matching %lo. */
2206 hi_fixup = mips_hi_fixup_list;
2207 if (hi_fixup == 0
2208 || !fixup_has_matching_lo_p (hi_fixup->fixp))
2210 hi_fixup = ((struct mips_hi_fixup *)
2211 xmalloc (sizeof (struct mips_hi_fixup)));
2212 hi_fixup->next = mips_hi_fixup_list;
2213 mips_hi_fixup_list = hi_fixup;
2215 hi_fixup->fixp = fixp[0];
2216 hi_fixup->seg = now_seg;
2219 /* Add fixups for the second and third relocations, if given.
2220 Note that the ABI allows the second relocation to be
2221 against RSS_UNDEF, RSS_GP, RSS_GP0 or RSS_LOC. At the
2222 moment we only use RSS_UNDEF, but we could add support
2223 for the others if it ever becomes necessary. */
2224 for (i = 1; i < 3; i++)
2225 if (reloc_type[i] != BFD_RELOC_UNUSED)
2227 address_expr->X_op = O_absent;
2228 address_expr->X_add_symbol = 0;
2229 address_expr->X_add_number = 0;
2231 fixp[i] = fix_new_exp (frag_now, fixp[0]->fx_where,
2232 fixp[0]->fx_size, address_expr,
2233 FALSE, reloc_type[i]);
2238 if (! mips_opts.mips16)
2240 md_number_to_chars (f, ip->insn_opcode, 4);
2241 #ifdef OBJ_ELF
2242 dwarf2_emit_insn (4);
2243 #endif
2245 else if (*reloc_type == BFD_RELOC_MIPS16_JMP)
2247 md_number_to_chars (f, ip->insn_opcode >> 16, 2);
2248 md_number_to_chars (f + 2, ip->insn_opcode & 0xffff, 2);
2249 #ifdef OBJ_ELF
2250 /* The value passed to dwarf2_emit_insn is the distance between
2251 the end of the current instruction and the address that should
2252 be recorded in the debug tables. Since we want to use ISA-encoded
2253 addresses in MIPS16 debug info, the value is one byte less than
2254 the real instruction length. */
2255 dwarf2_emit_insn (3);
2256 #endif
2258 else
2260 if (ip->use_extend)
2262 md_number_to_chars (f, 0xf000 | ip->extend, 2);
2263 f += 2;
2265 md_number_to_chars (f, ip->insn_opcode, 2);
2266 #ifdef OBJ_ELF
2267 dwarf2_emit_insn (ip->use_extend ? 3 : 1);
2268 #endif
2271 /* Update the register mask information. */
2272 if (! mips_opts.mips16)
2274 if (pinfo & INSN_WRITE_GPR_D)
2275 mips_gprmask |= 1 << ((ip->insn_opcode >> OP_SH_RD) & OP_MASK_RD);
2276 if ((pinfo & (INSN_WRITE_GPR_T | INSN_READ_GPR_T)) != 0)
2277 mips_gprmask |= 1 << ((ip->insn_opcode >> OP_SH_RT) & OP_MASK_RT);
2278 if (pinfo & INSN_READ_GPR_S)
2279 mips_gprmask |= 1 << ((ip->insn_opcode >> OP_SH_RS) & OP_MASK_RS);
2280 if (pinfo & INSN_WRITE_GPR_31)
2281 mips_gprmask |= 1 << RA;
2282 if (pinfo & INSN_WRITE_FPR_D)
2283 mips_cprmask[1] |= 1 << ((ip->insn_opcode >> OP_SH_FD) & OP_MASK_FD);
2284 if ((pinfo & (INSN_WRITE_FPR_S | INSN_READ_FPR_S)) != 0)
2285 mips_cprmask[1] |= 1 << ((ip->insn_opcode >> OP_SH_FS) & OP_MASK_FS);
2286 if ((pinfo & (INSN_WRITE_FPR_T | INSN_READ_FPR_T)) != 0)
2287 mips_cprmask[1] |= 1 << ((ip->insn_opcode >> OP_SH_FT) & OP_MASK_FT);
2288 if ((pinfo & INSN_READ_FPR_R) != 0)
2289 mips_cprmask[1] |= 1 << ((ip->insn_opcode >> OP_SH_FR) & OP_MASK_FR);
2290 if (pinfo & INSN_COP)
2292 /* We don't keep enough information to sort these cases out.
2293 The itbl support does keep this information however, although
2294 we currently don't support itbl fprmats as part of the cop
2295 instruction. May want to add this support in the future. */
2297 /* Never set the bit for $0, which is always zero. */
2298 mips_gprmask &= ~1 << 0;
2300 else
2302 if (pinfo & (MIPS16_INSN_WRITE_X | MIPS16_INSN_READ_X))
2303 mips_gprmask |= 1 << ((ip->insn_opcode >> MIPS16OP_SH_RX)
2304 & MIPS16OP_MASK_RX);
2305 if (pinfo & (MIPS16_INSN_WRITE_Y | MIPS16_INSN_READ_Y))
2306 mips_gprmask |= 1 << ((ip->insn_opcode >> MIPS16OP_SH_RY)
2307 & MIPS16OP_MASK_RY);
2308 if (pinfo & MIPS16_INSN_WRITE_Z)
2309 mips_gprmask |= 1 << ((ip->insn_opcode >> MIPS16OP_SH_RZ)
2310 & MIPS16OP_MASK_RZ);
2311 if (pinfo & (MIPS16_INSN_WRITE_T | MIPS16_INSN_READ_T))
2312 mips_gprmask |= 1 << TREG;
2313 if (pinfo & (MIPS16_INSN_WRITE_SP | MIPS16_INSN_READ_SP))
2314 mips_gprmask |= 1 << SP;
2315 if (pinfo & (MIPS16_INSN_WRITE_31 | MIPS16_INSN_READ_31))
2316 mips_gprmask |= 1 << RA;
2317 if (pinfo & MIPS16_INSN_WRITE_GPR_Y)
2318 mips_gprmask |= 1 << MIPS16OP_EXTRACT_REG32R (ip->insn_opcode);
2319 if (pinfo & MIPS16_INSN_READ_Z)
2320 mips_gprmask |= 1 << ((ip->insn_opcode >> MIPS16OP_SH_MOVE32Z)
2321 & MIPS16OP_MASK_MOVE32Z);
2322 if (pinfo & MIPS16_INSN_READ_GPR_X)
2323 mips_gprmask |= 1 << ((ip->insn_opcode >> MIPS16OP_SH_REGR32)
2324 & MIPS16OP_MASK_REGR32);
2327 if (mips_relax.sequence != 2 && !mips_opts.noreorder)
2329 /* Filling the branch delay slot is more complex. We try to
2330 switch the branch with the previous instruction, which we can
2331 do if the previous instruction does not set up a condition
2332 that the branch tests and if the branch is not itself the
2333 target of any branch. */
2334 if ((pinfo & INSN_UNCOND_BRANCH_DELAY)
2335 || (pinfo & INSN_COND_BRANCH_DELAY))
2337 if (mips_optimize < 2
2338 /* If we have seen .set volatile or .set nomove, don't
2339 optimize. */
2340 || mips_opts.nomove != 0
2341 /* If we had to emit any NOP instructions, then we
2342 already know we can not swap. */
2343 || nops != 0
2344 /* If we don't even know the previous insn, we can not
2345 swap. */
2346 || ! prev_insn_valid
2347 /* If the previous insn is already in a branch delay
2348 slot, then we can not swap. */
2349 || prev_insn_is_delay_slot
2350 /* If the previous previous insn was in a .set
2351 noreorder, we can't swap. Actually, the MIPS
2352 assembler will swap in this situation. However, gcc
2353 configured -with-gnu-as will generate code like
2354 .set noreorder
2355 lw $4,XXX
2356 .set reorder
2357 INSN
2358 bne $4,$0,foo
2359 in which we can not swap the bne and INSN. If gcc is
2360 not configured -with-gnu-as, it does not output the
2361 .set pseudo-ops. We don't have to check
2362 prev_insn_unreordered, because prev_insn_valid will
2363 be 0 in that case. We don't want to use
2364 prev_prev_insn_valid, because we do want to be able
2365 to swap at the start of a function. */
2366 || prev_prev_insn_unreordered
2367 /* If the branch is itself the target of a branch, we
2368 can not swap. We cheat on this; all we check for is
2369 whether there is a label on this instruction. If
2370 there are any branches to anything other than a
2371 label, users must use .set noreorder. */
2372 || insn_labels != NULL
2373 /* If the previous instruction is in a variant frag
2374 other than this branch's one, we cannot do the swap.
2375 This does not apply to the mips16, which uses variant
2376 frags for different purposes. */
2377 || (! mips_opts.mips16
2378 && prev_insn_frag_type == rs_machine_dependent)
2379 /* If the branch reads the condition codes, we don't
2380 even try to swap, because in the sequence
2381 ctc1 $X,$31
2382 INSN
2383 INSN
2384 bc1t LABEL
2385 we can not swap, and I don't feel like handling that
2386 case. */
2387 || (! mips_opts.mips16
2388 && (pinfo & INSN_READ_COND_CODE)
2389 && ! cop_interlocks)
2390 /* We can not swap with an instruction that requires a
2391 delay slot, because the target of the branch might
2392 interfere with that instruction. */
2393 || (! mips_opts.mips16
2394 && (prev_pinfo
2395 /* Itbl support may require additional care here. */
2396 & (INSN_LOAD_COPROC_DELAY
2397 | INSN_COPROC_MOVE_DELAY
2398 | INSN_WRITE_COND_CODE))
2399 && ! cop_interlocks)
2400 || (! (hilo_interlocks
2401 || (mips_opts.arch == CPU_R3900 && (pinfo & INSN_MULT)))
2402 && (prev_pinfo
2403 & (INSN_READ_LO
2404 | INSN_READ_HI)))
2405 || (! mips_opts.mips16
2406 && (prev_pinfo & INSN_LOAD_MEMORY_DELAY)
2407 && ! gpr_interlocks)
2408 || (! mips_opts.mips16
2409 /* Itbl support may require additional care here. */
2410 && (prev_pinfo & INSN_COPROC_MEMORY_DELAY)
2411 && ! cop_mem_interlocks)
2412 /* We can not swap with a branch instruction. */
2413 || (prev_pinfo
2414 & (INSN_UNCOND_BRANCH_DELAY
2415 | INSN_COND_BRANCH_DELAY
2416 | INSN_COND_BRANCH_LIKELY))
2417 /* We do not swap with a trap instruction, since it
2418 complicates trap handlers to have the trap
2419 instruction be in a delay slot. */
2420 || (prev_pinfo & INSN_TRAP)
2421 /* If the branch reads a register that the previous
2422 instruction sets, we can not swap. */
2423 || (! mips_opts.mips16
2424 && (prev_pinfo & INSN_WRITE_GPR_T)
2425 && insn_uses_reg (ip,
2426 ((prev_insn.insn_opcode >> OP_SH_RT)
2427 & OP_MASK_RT),
2428 MIPS_GR_REG))
2429 || (! mips_opts.mips16
2430 && (prev_pinfo & INSN_WRITE_GPR_D)
2431 && insn_uses_reg (ip,
2432 ((prev_insn.insn_opcode >> OP_SH_RD)
2433 & OP_MASK_RD),
2434 MIPS_GR_REG))
2435 || (mips_opts.mips16
2436 && (((prev_pinfo & MIPS16_INSN_WRITE_X)
2437 && insn_uses_reg (ip,
2438 ((prev_insn.insn_opcode
2439 >> MIPS16OP_SH_RX)
2440 & MIPS16OP_MASK_RX),
2441 MIPS16_REG))
2442 || ((prev_pinfo & MIPS16_INSN_WRITE_Y)
2443 && insn_uses_reg (ip,
2444 ((prev_insn.insn_opcode
2445 >> MIPS16OP_SH_RY)
2446 & MIPS16OP_MASK_RY),
2447 MIPS16_REG))
2448 || ((prev_pinfo & MIPS16_INSN_WRITE_Z)
2449 && insn_uses_reg (ip,
2450 ((prev_insn.insn_opcode
2451 >> MIPS16OP_SH_RZ)
2452 & MIPS16OP_MASK_RZ),
2453 MIPS16_REG))
2454 || ((prev_pinfo & MIPS16_INSN_WRITE_T)
2455 && insn_uses_reg (ip, TREG, MIPS_GR_REG))
2456 || ((prev_pinfo & MIPS16_INSN_WRITE_31)
2457 && insn_uses_reg (ip, RA, MIPS_GR_REG))
2458 || ((prev_pinfo & MIPS16_INSN_WRITE_GPR_Y)
2459 && insn_uses_reg (ip,
2460 MIPS16OP_EXTRACT_REG32R (prev_insn.
2461 insn_opcode),
2462 MIPS_GR_REG))))
2463 /* If the branch writes a register that the previous
2464 instruction sets, we can not swap (we know that
2465 branches write only to RD or to $31). */
2466 || (! mips_opts.mips16
2467 && (prev_pinfo & INSN_WRITE_GPR_T)
2468 && (((pinfo & INSN_WRITE_GPR_D)
2469 && (((prev_insn.insn_opcode >> OP_SH_RT) & OP_MASK_RT)
2470 == ((ip->insn_opcode >> OP_SH_RD) & OP_MASK_RD)))
2471 || ((pinfo & INSN_WRITE_GPR_31)
2472 && (((prev_insn.insn_opcode >> OP_SH_RT)
2473 & OP_MASK_RT)
2474 == RA))))
2475 || (! mips_opts.mips16
2476 && (prev_pinfo & INSN_WRITE_GPR_D)
2477 && (((pinfo & INSN_WRITE_GPR_D)
2478 && (((prev_insn.insn_opcode >> OP_SH_RD) & OP_MASK_RD)
2479 == ((ip->insn_opcode >> OP_SH_RD) & OP_MASK_RD)))
2480 || ((pinfo & INSN_WRITE_GPR_31)
2481 && (((prev_insn.insn_opcode >> OP_SH_RD)
2482 & OP_MASK_RD)
2483 == RA))))
2484 || (mips_opts.mips16
2485 && (pinfo & MIPS16_INSN_WRITE_31)
2486 && ((prev_pinfo & MIPS16_INSN_WRITE_31)
2487 || ((prev_pinfo & MIPS16_INSN_WRITE_GPR_Y)
2488 && (MIPS16OP_EXTRACT_REG32R (prev_insn.insn_opcode)
2489 == RA))))
2490 /* If the branch writes a register that the previous
2491 instruction reads, we can not swap (we know that
2492 branches only write to RD or to $31). */
2493 || (! mips_opts.mips16
2494 && (pinfo & INSN_WRITE_GPR_D)
2495 && insn_uses_reg (&prev_insn,
2496 ((ip->insn_opcode >> OP_SH_RD)
2497 & OP_MASK_RD),
2498 MIPS_GR_REG))
2499 || (! mips_opts.mips16
2500 && (pinfo & INSN_WRITE_GPR_31)
2501 && insn_uses_reg (&prev_insn, RA, MIPS_GR_REG))
2502 || (mips_opts.mips16
2503 && (pinfo & MIPS16_INSN_WRITE_31)
2504 && insn_uses_reg (&prev_insn, RA, MIPS_GR_REG))
2505 /* If the previous previous instruction has a load
2506 delay, and sets a register that the branch reads, we
2507 can not swap. */
2508 || (! mips_opts.mips16
2509 /* Itbl support may require additional care here. */
2510 && (((prev_prev_insn.insn_mo->pinfo & INSN_LOAD_COPROC_DELAY)
2511 && ! cop_interlocks)
2512 || ((prev_prev_insn.insn_mo->pinfo
2513 & INSN_LOAD_MEMORY_DELAY)
2514 && ! gpr_interlocks))
2515 && insn_uses_reg (ip,
2516 ((prev_prev_insn.insn_opcode >> OP_SH_RT)
2517 & OP_MASK_RT),
2518 MIPS_GR_REG))
2519 /* If one instruction sets a condition code and the
2520 other one uses a condition code, we can not swap. */
2521 || ((pinfo & INSN_READ_COND_CODE)
2522 && (prev_pinfo & INSN_WRITE_COND_CODE))
2523 || ((pinfo & INSN_WRITE_COND_CODE)
2524 && (prev_pinfo & INSN_READ_COND_CODE))
2525 /* If the previous instruction uses the PC, we can not
2526 swap. */
2527 || (mips_opts.mips16
2528 && (prev_pinfo & MIPS16_INSN_READ_PC))
2529 /* If the previous instruction was extended, we can not
2530 swap. */
2531 || (mips_opts.mips16 && prev_insn_extended)
2532 /* If the previous instruction had a fixup in mips16
2533 mode, we can not swap. This normally means that the
2534 previous instruction was a 4 byte branch anyhow. */
2535 || (mips_opts.mips16 && prev_insn_fixp[0])
2536 /* If the previous instruction is a sync, sync.l, or
2537 sync.p, we can not swap. */
2538 || (prev_pinfo & INSN_SYNC))
2540 /* We could do even better for unconditional branches to
2541 portions of this object file; we could pick up the
2542 instruction at the destination, put it in the delay
2543 slot, and bump the destination address. */
2544 emit_nop ();
2545 /* Update the previous insn information. */
2546 prev_prev_insn = *ip;
2547 prev_insn.insn_mo = &dummy_opcode;
2549 else
2551 /* It looks like we can actually do the swap. */
2552 if (! mips_opts.mips16)
2554 char *prev_f;
2555 char temp[4];
2557 prev_f = prev_insn_frag->fr_literal + prev_insn_where;
2558 if (!relaxed_branch)
2560 /* If this is not a relaxed branch, then just
2561 swap the instructions. */
2562 memcpy (temp, prev_f, 4);
2563 memcpy (prev_f, f, 4);
2564 memcpy (f, temp, 4);
2566 else
2568 /* If this is a relaxed branch, then we move the
2569 instruction to be placed in the delay slot to
2570 the current frag, shrinking the fixed part of
2571 the originating frag. If the branch occupies
2572 the tail of the latter, we move it backwards,
2573 into the space freed by the moved instruction. */
2574 f = frag_more (4);
2575 memcpy (f, prev_f, 4);
2576 prev_insn_frag->fr_fix -= 4;
2577 if (prev_insn_frag->fr_type == rs_machine_dependent)
2578 memmove (prev_f, prev_f + 4, prev_insn_frag->fr_var);
2581 if (prev_insn_fixp[0])
2583 prev_insn_fixp[0]->fx_frag = frag_now;
2584 prev_insn_fixp[0]->fx_where = f - frag_now->fr_literal;
2586 if (prev_insn_fixp[1])
2588 prev_insn_fixp[1]->fx_frag = frag_now;
2589 prev_insn_fixp[1]->fx_where = f - frag_now->fr_literal;
2591 if (prev_insn_fixp[2])
2593 prev_insn_fixp[2]->fx_frag = frag_now;
2594 prev_insn_fixp[2]->fx_where = f - frag_now->fr_literal;
2596 if (prev_insn_fixp[0] && HAVE_NEWABI
2597 && prev_insn_frag != frag_now
2598 && (prev_insn_fixp[0]->fx_r_type
2599 == BFD_RELOC_MIPS_GOT_DISP
2600 || (prev_insn_fixp[0]->fx_r_type
2601 == BFD_RELOC_MIPS_CALL16)))
2603 /* To avoid confusion in tc_gen_reloc, we must
2604 ensure that this does not become a variant
2605 frag. */
2606 force_new_frag = TRUE;
2609 if (!relaxed_branch)
2611 if (fixp[0])
2613 fixp[0]->fx_frag = prev_insn_frag;
2614 fixp[0]->fx_where = prev_insn_where;
2616 if (fixp[1])
2618 fixp[1]->fx_frag = prev_insn_frag;
2619 fixp[1]->fx_where = prev_insn_where;
2621 if (fixp[2])
2623 fixp[2]->fx_frag = prev_insn_frag;
2624 fixp[2]->fx_where = prev_insn_where;
2627 else if (prev_insn_frag->fr_type == rs_machine_dependent)
2629 if (fixp[0])
2630 fixp[0]->fx_where -= 4;
2631 if (fixp[1])
2632 fixp[1]->fx_where -= 4;
2633 if (fixp[2])
2634 fixp[2]->fx_where -= 4;
2637 else
2639 char *prev_f;
2640 char temp[2];
2642 assert (prev_insn_fixp[0] == NULL);
2643 assert (prev_insn_fixp[1] == NULL);
2644 assert (prev_insn_fixp[2] == NULL);
2645 prev_f = prev_insn_frag->fr_literal + prev_insn_where;
2646 memcpy (temp, prev_f, 2);
2647 memcpy (prev_f, f, 2);
2648 if (*reloc_type != BFD_RELOC_MIPS16_JMP)
2650 assert (*reloc_type == BFD_RELOC_UNUSED);
2651 memcpy (f, temp, 2);
2653 else
2655 memcpy (f, f + 2, 2);
2656 memcpy (f + 2, temp, 2);
2658 if (fixp[0])
2660 fixp[0]->fx_frag = prev_insn_frag;
2661 fixp[0]->fx_where = prev_insn_where;
2663 if (fixp[1])
2665 fixp[1]->fx_frag = prev_insn_frag;
2666 fixp[1]->fx_where = prev_insn_where;
2668 if (fixp[2])
2670 fixp[2]->fx_frag = prev_insn_frag;
2671 fixp[2]->fx_where = prev_insn_where;
2675 /* Update the previous insn information; leave prev_insn
2676 unchanged. */
2677 prev_prev_insn = *ip;
2679 prev_insn_is_delay_slot = 1;
2681 /* If that was an unconditional branch, forget the previous
2682 insn information. */
2683 if (pinfo & INSN_UNCOND_BRANCH_DELAY)
2685 prev_prev_insn.insn_mo = &dummy_opcode;
2686 prev_insn.insn_mo = &dummy_opcode;
2689 prev_insn_fixp[0] = NULL;
2690 prev_insn_fixp[1] = NULL;
2691 prev_insn_fixp[2] = NULL;
2692 prev_insn_reloc_type[0] = BFD_RELOC_UNUSED;
2693 prev_insn_reloc_type[1] = BFD_RELOC_UNUSED;
2694 prev_insn_reloc_type[2] = BFD_RELOC_UNUSED;
2695 prev_insn_extended = 0;
2697 else if (pinfo & INSN_COND_BRANCH_LIKELY)
2699 /* We don't yet optimize a branch likely. What we should do
2700 is look at the target, copy the instruction found there
2701 into the delay slot, and increment the branch to jump to
2702 the next instruction. */
2703 emit_nop ();
2704 /* Update the previous insn information. */
2705 prev_prev_insn = *ip;
2706 prev_insn.insn_mo = &dummy_opcode;
2707 prev_insn_fixp[0] = NULL;
2708 prev_insn_fixp[1] = NULL;
2709 prev_insn_fixp[2] = NULL;
2710 prev_insn_reloc_type[0] = BFD_RELOC_UNUSED;
2711 prev_insn_reloc_type[1] = BFD_RELOC_UNUSED;
2712 prev_insn_reloc_type[2] = BFD_RELOC_UNUSED;
2713 prev_insn_extended = 0;
2714 prev_insn_is_delay_slot = 1;
2716 else
2718 /* Update the previous insn information. */
2719 if (nops > 0)
2720 prev_prev_insn.insn_mo = &dummy_opcode;
2721 else
2722 prev_prev_insn = prev_insn;
2723 prev_insn = *ip;
2725 /* Any time we see a branch, we always fill the delay slot
2726 immediately; since this insn is not a branch, we know it
2727 is not in a delay slot. */
2728 prev_insn_is_delay_slot = 0;
2730 prev_insn_fixp[0] = fixp[0];
2731 prev_insn_fixp[1] = fixp[1];
2732 prev_insn_fixp[2] = fixp[2];
2733 prev_insn_reloc_type[0] = reloc_type[0];
2734 prev_insn_reloc_type[1] = reloc_type[1];
2735 prev_insn_reloc_type[2] = reloc_type[2];
2736 if (mips_opts.mips16)
2737 prev_insn_extended = (ip->use_extend
2738 || *reloc_type > BFD_RELOC_UNUSED);
2741 prev_prev_insn_unreordered = prev_insn_unreordered;
2742 prev_insn_unreordered = 0;
2743 prev_insn_frag = frag_now;
2744 prev_insn_where = f - frag_now->fr_literal;
2745 prev_insn_valid = 1;
2747 else if (mips_relax.sequence != 2)
2749 /* We need to record a bit of information even when we are not
2750 reordering, in order to determine the base address for mips16
2751 PC relative relocs. */
2752 prev_prev_insn = prev_insn;
2753 prev_insn = *ip;
2754 prev_insn_reloc_type[0] = reloc_type[0];
2755 prev_insn_reloc_type[1] = reloc_type[1];
2756 prev_insn_reloc_type[2] = reloc_type[2];
2757 prev_prev_insn_unreordered = prev_insn_unreordered;
2758 prev_insn_unreordered = 1;
2761 /* We just output an insn, so the next one doesn't have a label. */
2762 mips_clear_insn_labels ();
2765 /* This function forgets that there was any previous instruction or
2766 label. If PRESERVE is non-zero, it remembers enough information to
2767 know whether nops are needed before a noreorder section. */
2769 static void
2770 mips_no_prev_insn (int preserve)
2772 if (! preserve)
2774 prev_insn.insn_mo = &dummy_opcode;
2775 prev_prev_insn.insn_mo = &dummy_opcode;
2776 prev_nop_frag = NULL;
2777 prev_nop_frag_holds = 0;
2778 prev_nop_frag_required = 0;
2779 prev_nop_frag_since = 0;
2781 prev_insn_valid = 0;
2782 prev_insn_is_delay_slot = 0;
2783 prev_insn_unreordered = 0;
2784 prev_insn_extended = 0;
2785 prev_insn_reloc_type[0] = BFD_RELOC_UNUSED;
2786 prev_insn_reloc_type[1] = BFD_RELOC_UNUSED;
2787 prev_insn_reloc_type[2] = BFD_RELOC_UNUSED;
2788 prev_prev_insn_unreordered = 0;
2789 mips_clear_insn_labels ();
2792 /* This function must be called whenever we turn on noreorder or emit
2793 something other than instructions. It inserts any NOPS which might
2794 be needed by the previous instruction, and clears the information
2795 kept for the previous instructions. The INSNS parameter is true if
2796 instructions are to follow. */
2798 static void
2799 mips_emit_delays (bfd_boolean insns)
2801 if (! mips_opts.noreorder)
2803 int nops;
2805 nops = 0;
2806 if ((! mips_opts.mips16
2807 && ((prev_insn.insn_mo->pinfo
2808 & (INSN_LOAD_COPROC_DELAY
2809 | INSN_COPROC_MOVE_DELAY
2810 | INSN_WRITE_COND_CODE))
2811 && ! cop_interlocks))
2812 || (! hilo_interlocks
2813 && (prev_insn.insn_mo->pinfo
2814 & (INSN_READ_LO
2815 | INSN_READ_HI)))
2816 || (! mips_opts.mips16
2817 && (prev_insn.insn_mo->pinfo & INSN_LOAD_MEMORY_DELAY)
2818 && ! gpr_interlocks)
2819 || (! mips_opts.mips16
2820 && (prev_insn.insn_mo->pinfo & INSN_COPROC_MEMORY_DELAY)
2821 && ! cop_mem_interlocks))
2823 /* Itbl support may require additional care here. */
2824 ++nops;
2825 if ((! mips_opts.mips16
2826 && ((prev_insn.insn_mo->pinfo & INSN_WRITE_COND_CODE)
2827 && ! cop_interlocks))
2828 || (! hilo_interlocks
2829 && ((prev_insn.insn_mo->pinfo & INSN_READ_HI)
2830 || (prev_insn.insn_mo->pinfo & INSN_READ_LO))))
2831 ++nops;
2833 if (prev_insn_unreordered)
2834 nops = 0;
2836 else if ((! mips_opts.mips16
2837 && ((prev_prev_insn.insn_mo->pinfo & INSN_WRITE_COND_CODE)
2838 && ! cop_interlocks))
2839 || (! hilo_interlocks
2840 && ((prev_prev_insn.insn_mo->pinfo & INSN_READ_HI)
2841 || (prev_prev_insn.insn_mo->pinfo & INSN_READ_LO))))
2843 /* Itbl support may require additional care here. */
2844 if (! prev_prev_insn_unreordered)
2845 ++nops;
2848 if (mips_fix_vr4120 && prev_insn.insn_mo->name)
2850 int min_nops = 0;
2851 const char *pn = prev_insn.insn_mo->name;
2852 if (strncmp (pn, "macc", 4) == 0
2853 || strncmp (pn, "dmacc", 5) == 0
2854 || strncmp (pn, "dmult", 5) == 0
2855 || strstr (pn, "div"))
2856 min_nops = 1;
2857 if (nops < min_nops)
2858 nops = min_nops;
2861 if (nops > 0)
2863 struct insn_label_list *l;
2865 if (insns)
2867 /* Record the frag which holds the nop instructions, so
2868 that we can remove them if we don't need them. */
2869 frag_grow (mips_opts.mips16 ? nops * 2 : nops * 4);
2870 prev_nop_frag = frag_now;
2871 prev_nop_frag_holds = nops;
2872 prev_nop_frag_required = 0;
2873 prev_nop_frag_since = 0;
2876 for (; nops > 0; --nops)
2877 emit_nop ();
2879 if (insns)
2881 /* Move on to a new frag, so that it is safe to simply
2882 decrease the size of prev_nop_frag. */
2883 frag_wane (frag_now);
2884 frag_new (0);
2887 for (l = insn_labels; l != NULL; l = l->next)
2889 valueT val;
2891 assert (S_GET_SEGMENT (l->label) == now_seg);
2892 symbol_set_frag (l->label, frag_now);
2893 val = (valueT) frag_now_fix ();
2894 /* mips16 text labels are stored as odd. */
2895 if (mips_opts.mips16)
2896 ++val;
2897 S_SET_VALUE (l->label, val);
2902 /* Mark instruction labels in mips16 mode. */
2903 if (insns)
2904 mips16_mark_labels ();
2906 mips_no_prev_insn (insns);
2909 /* Set up global variables for the start of a new macro. */
2911 static void
2912 macro_start (void)
2914 memset (&mips_macro_warning.sizes, 0, sizeof (mips_macro_warning.sizes));
2915 mips_macro_warning.delay_slot_p = (mips_opts.noreorder
2916 && (prev_insn.insn_mo->pinfo
2917 & (INSN_UNCOND_BRANCH_DELAY
2918 | INSN_COND_BRANCH_DELAY
2919 | INSN_COND_BRANCH_LIKELY)) != 0);
2922 /* Given that a macro is longer than 4 bytes, return the appropriate warning
2923 for it. Return null if no warning is needed. SUBTYPE is a bitmask of
2924 RELAX_DELAY_SLOT and RELAX_NOMACRO. */
2926 static const char *
2927 macro_warning (relax_substateT subtype)
2929 if (subtype & RELAX_DELAY_SLOT)
2930 return _("Macro instruction expanded into multiple instructions"
2931 " in a branch delay slot");
2932 else if (subtype & RELAX_NOMACRO)
2933 return _("Macro instruction expanded into multiple instructions");
2934 else
2935 return 0;
2938 /* Finish up a macro. Emit warnings as appropriate. */
2940 static void
2941 macro_end (void)
2943 if (mips_macro_warning.sizes[0] > 4 || mips_macro_warning.sizes[1] > 4)
2945 relax_substateT subtype;
2947 /* Set up the relaxation warning flags. */
2948 subtype = 0;
2949 if (mips_macro_warning.sizes[1] > mips_macro_warning.sizes[0])
2950 subtype |= RELAX_SECOND_LONGER;
2951 if (mips_opts.warn_about_macros)
2952 subtype |= RELAX_NOMACRO;
2953 if (mips_macro_warning.delay_slot_p)
2954 subtype |= RELAX_DELAY_SLOT;
2956 if (mips_macro_warning.sizes[0] > 4 && mips_macro_warning.sizes[1] > 4)
2958 /* Either the macro has a single implementation or both
2959 implementations are longer than 4 bytes. Emit the
2960 warning now. */
2961 const char *msg = macro_warning (subtype);
2962 if (msg != 0)
2963 as_warn (msg);
2965 else
2967 /* One implementation might need a warning but the other
2968 definitely doesn't. */
2969 mips_macro_warning.first_frag->fr_subtype |= subtype;
2974 /* Build an instruction created by a macro expansion. This is passed
2975 a pointer to the count of instructions created so far, an
2976 expression, the name of the instruction to build, an operand format
2977 string, and corresponding arguments. */
2979 static void
2980 macro_build (expressionS *ep, const char *name, const char *fmt, ...)
2982 struct mips_cl_insn insn;
2983 bfd_reloc_code_real_type r[3];
2984 va_list args;
2986 va_start (args, fmt);
2988 if (mips_opts.mips16)
2990 mips16_macro_build (ep, name, fmt, args);
2991 va_end (args);
2992 return;
2995 r[0] = BFD_RELOC_UNUSED;
2996 r[1] = BFD_RELOC_UNUSED;
2997 r[2] = BFD_RELOC_UNUSED;
2998 insn.insn_mo = (struct mips_opcode *) hash_find (op_hash, name);
2999 assert (insn.insn_mo);
3000 assert (strcmp (name, insn.insn_mo->name) == 0);
3002 /* Search until we get a match for NAME. */
3003 while (1)
3005 /* It is assumed here that macros will never generate
3006 MDMX or MIPS-3D instructions. */
3007 if (strcmp (fmt, insn.insn_mo->args) == 0
3008 && insn.insn_mo->pinfo != INSN_MACRO
3009 && OPCODE_IS_MEMBER (insn.insn_mo,
3010 (mips_opts.isa
3011 | (file_ase_mips16 ? INSN_MIPS16 : 0)),
3012 mips_opts.arch)
3013 && (mips_opts.arch != CPU_R4650 || (insn.insn_mo->pinfo & FP_D) == 0))
3014 break;
3016 ++insn.insn_mo;
3017 assert (insn.insn_mo->name);
3018 assert (strcmp (name, insn.insn_mo->name) == 0);
3021 insn.insn_opcode = insn.insn_mo->match;
3022 for (;;)
3024 switch (*fmt++)
3026 case '\0':
3027 break;
3029 case ',':
3030 case '(':
3031 case ')':
3032 continue;
3034 case '+':
3035 switch (*fmt++)
3037 case 'A':
3038 case 'E':
3039 insn.insn_opcode |= (va_arg (args, int)
3040 & OP_MASK_SHAMT) << OP_SH_SHAMT;
3041 continue;
3043 case 'B':
3044 case 'F':
3045 /* Note that in the macro case, these arguments are already
3046 in MSB form. (When handling the instruction in the
3047 non-macro case, these arguments are sizes from which
3048 MSB values must be calculated.) */
3049 insn.insn_opcode |= (va_arg (args, int)
3050 & OP_MASK_INSMSB) << OP_SH_INSMSB;
3051 continue;
3053 case 'C':
3054 case 'G':
3055 case 'H':
3056 /* Note that in the macro case, these arguments are already
3057 in MSBD form. (When handling the instruction in the
3058 non-macro case, these arguments are sizes from which
3059 MSBD values must be calculated.) */
3060 insn.insn_opcode |= (va_arg (args, int)
3061 & OP_MASK_EXTMSBD) << OP_SH_EXTMSBD;
3062 continue;
3064 default:
3065 internalError ();
3067 continue;
3069 case 't':
3070 case 'w':
3071 case 'E':
3072 insn.insn_opcode |= va_arg (args, int) << OP_SH_RT;
3073 continue;
3075 case 'c':
3076 insn.insn_opcode |= va_arg (args, int) << OP_SH_CODE;
3077 continue;
3079 case 'T':
3080 case 'W':
3081 insn.insn_opcode |= va_arg (args, int) << OP_SH_FT;
3082 continue;
3084 case 'd':
3085 case 'G':
3086 case 'K':
3087 insn.insn_opcode |= va_arg (args, int) << OP_SH_RD;
3088 continue;
3090 case 'U':
3092 int tmp = va_arg (args, int);
3094 insn.insn_opcode |= tmp << OP_SH_RT;
3095 insn.insn_opcode |= tmp << OP_SH_RD;
3096 continue;
3099 case 'V':
3100 case 'S':
3101 insn.insn_opcode |= va_arg (args, int) << OP_SH_FS;
3102 continue;
3104 case 'z':
3105 continue;
3107 case '<':
3108 insn.insn_opcode |= va_arg (args, int) << OP_SH_SHAMT;
3109 continue;
3111 case 'D':
3112 insn.insn_opcode |= va_arg (args, int) << OP_SH_FD;
3113 continue;
3115 case 'B':
3116 insn.insn_opcode |= va_arg (args, int) << OP_SH_CODE20;
3117 continue;
3119 case 'J':
3120 insn.insn_opcode |= va_arg (args, int) << OP_SH_CODE19;
3121 continue;
3123 case 'q':
3124 insn.insn_opcode |= va_arg (args, int) << OP_SH_CODE2;
3125 continue;
3127 case 'b':
3128 case 's':
3129 case 'r':
3130 case 'v':
3131 insn.insn_opcode |= va_arg (args, int) << OP_SH_RS;
3132 continue;
3134 case 'i':
3135 case 'j':
3136 case 'o':
3137 *r = (bfd_reloc_code_real_type) va_arg (args, int);
3138 assert (*r == BFD_RELOC_GPREL16
3139 || *r == BFD_RELOC_MIPS_LITERAL
3140 || *r == BFD_RELOC_MIPS_HIGHER
3141 || *r == BFD_RELOC_HI16_S
3142 || *r == BFD_RELOC_LO16
3143 || *r == BFD_RELOC_MIPS_GOT16
3144 || *r == BFD_RELOC_MIPS_CALL16
3145 || *r == BFD_RELOC_MIPS_GOT_DISP
3146 || *r == BFD_RELOC_MIPS_GOT_PAGE
3147 || *r == BFD_RELOC_MIPS_GOT_OFST
3148 || *r == BFD_RELOC_MIPS_GOT_LO16
3149 || *r == BFD_RELOC_MIPS_CALL_LO16);
3150 continue;
3152 case 'u':
3153 *r = (bfd_reloc_code_real_type) va_arg (args, int);
3154 assert (ep != NULL
3155 && (ep->X_op == O_constant
3156 || (ep->X_op == O_symbol
3157 && (*r == BFD_RELOC_MIPS_HIGHEST
3158 || *r == BFD_RELOC_HI16_S
3159 || *r == BFD_RELOC_HI16
3160 || *r == BFD_RELOC_GPREL16
3161 || *r == BFD_RELOC_MIPS_GOT_HI16
3162 || *r == BFD_RELOC_MIPS_CALL_HI16))));
3163 continue;
3165 case 'p':
3166 assert (ep != NULL);
3168 * This allows macro() to pass an immediate expression for
3169 * creating short branches without creating a symbol.
3170 * Note that the expression still might come from the assembly
3171 * input, in which case the value is not checked for range nor
3172 * is a relocation entry generated (yuck).
3174 if (ep->X_op == O_constant)
3176 insn.insn_opcode |= (ep->X_add_number >> 2) & 0xffff;
3177 ep = NULL;
3179 else
3180 *r = BFD_RELOC_16_PCREL_S2;
3181 continue;
3183 case 'a':
3184 assert (ep != NULL);
3185 *r = BFD_RELOC_MIPS_JMP;
3186 continue;
3188 case 'C':
3189 insn.insn_opcode |= va_arg (args, unsigned long);
3190 continue;
3192 default:
3193 internalError ();
3195 break;
3197 va_end (args);
3198 assert (*r == BFD_RELOC_UNUSED ? ep == NULL : ep != NULL);
3200 append_insn (&insn, ep, r);
3203 static void
3204 mips16_macro_build (expressionS *ep, const char *name, const char *fmt,
3205 va_list args)
3207 struct mips_cl_insn insn;
3208 bfd_reloc_code_real_type r[3]
3209 = {BFD_RELOC_UNUSED, BFD_RELOC_UNUSED, BFD_RELOC_UNUSED};
3211 insn.insn_mo = (struct mips_opcode *) hash_find (mips16_op_hash, name);
3212 assert (insn.insn_mo);
3213 assert (strcmp (name, insn.insn_mo->name) == 0);
3215 while (strcmp (fmt, insn.insn_mo->args) != 0
3216 || insn.insn_mo->pinfo == INSN_MACRO)
3218 ++insn.insn_mo;
3219 assert (insn.insn_mo->name);
3220 assert (strcmp (name, insn.insn_mo->name) == 0);
3223 insn.insn_opcode = insn.insn_mo->match;
3224 insn.use_extend = FALSE;
3226 for (;;)
3228 int c;
3230 c = *fmt++;
3231 switch (c)
3233 case '\0':
3234 break;
3236 case ',':
3237 case '(':
3238 case ')':
3239 continue;
3241 case 'y':
3242 case 'w':
3243 insn.insn_opcode |= va_arg (args, int) << MIPS16OP_SH_RY;
3244 continue;
3246 case 'x':
3247 case 'v':
3248 insn.insn_opcode |= va_arg (args, int) << MIPS16OP_SH_RX;
3249 continue;
3251 case 'z':
3252 insn.insn_opcode |= va_arg (args, int) << MIPS16OP_SH_RZ;
3253 continue;
3255 case 'Z':
3256 insn.insn_opcode |= va_arg (args, int) << MIPS16OP_SH_MOVE32Z;
3257 continue;
3259 case '0':
3260 case 'S':
3261 case 'P':
3262 case 'R':
3263 continue;
3265 case 'X':
3266 insn.insn_opcode |= va_arg (args, int) << MIPS16OP_SH_REGR32;
3267 continue;
3269 case 'Y':
3271 int regno;
3273 regno = va_arg (args, int);
3274 regno = ((regno & 7) << 2) | ((regno & 0x18) >> 3);
3275 insn.insn_opcode |= regno << MIPS16OP_SH_REG32R;
3277 continue;
3279 case '<':
3280 case '>':
3281 case '4':
3282 case '5':
3283 case 'H':
3284 case 'W':
3285 case 'D':
3286 case 'j':
3287 case '8':
3288 case 'V':
3289 case 'C':
3290 case 'U':
3291 case 'k':
3292 case 'K':
3293 case 'p':
3294 case 'q':
3296 assert (ep != NULL);
3298 if (ep->X_op != O_constant)
3299 *r = (int) BFD_RELOC_UNUSED + c;
3300 else
3302 mips16_immed (NULL, 0, c, ep->X_add_number, FALSE, FALSE,
3303 FALSE, &insn.insn_opcode, &insn.use_extend,
3304 &insn.extend);
3305 ep = NULL;
3306 *r = BFD_RELOC_UNUSED;
3309 continue;
3311 case '6':
3312 insn.insn_opcode |= va_arg (args, int) << MIPS16OP_SH_IMM6;
3313 continue;
3316 break;
3319 assert (*r == BFD_RELOC_UNUSED ? ep == NULL : ep != NULL);
3321 append_insn (&insn, ep, r);
3325 * Generate a "jalr" instruction with a relocation hint to the called
3326 * function. This occurs in NewABI PIC code.
3328 static void
3329 macro_build_jalr (expressionS *ep)
3331 char *f = NULL;
3333 if (HAVE_NEWABI)
3335 frag_grow (8);
3336 f = frag_more (0);
3338 macro_build (NULL, "jalr", "d,s", RA, PIC_CALL_REG);
3339 if (HAVE_NEWABI)
3340 fix_new_exp (frag_now, f - frag_now->fr_literal,
3341 4, ep, FALSE, BFD_RELOC_MIPS_JALR);
3345 * Generate a "lui" instruction.
3347 static void
3348 macro_build_lui (expressionS *ep, int regnum)
3350 expressionS high_expr;
3351 struct mips_cl_insn insn;
3352 bfd_reloc_code_real_type r[3]
3353 = {BFD_RELOC_UNUSED, BFD_RELOC_UNUSED, BFD_RELOC_UNUSED};
3354 const char *name = "lui";
3355 const char *fmt = "t,u";
3357 assert (! mips_opts.mips16);
3359 high_expr = *ep;
3361 if (high_expr.X_op == O_constant)
3363 /* we can compute the instruction now without a relocation entry */
3364 high_expr.X_add_number = ((high_expr.X_add_number + 0x8000)
3365 >> 16) & 0xffff;
3366 *r = BFD_RELOC_UNUSED;
3368 else
3370 assert (ep->X_op == O_symbol);
3371 /* _gp_disp is a special case, used from s_cpload. */
3372 assert (mips_pic == NO_PIC
3373 || (! HAVE_NEWABI
3374 && strcmp (S_GET_NAME (ep->X_add_symbol), "_gp_disp") == 0));
3375 *r = BFD_RELOC_HI16_S;
3378 insn.insn_mo = (struct mips_opcode *) hash_find (op_hash, name);
3379 assert (insn.insn_mo);
3380 assert (strcmp (name, insn.insn_mo->name) == 0);
3381 assert (strcmp (fmt, insn.insn_mo->args) == 0);
3383 insn.insn_opcode = insn.insn_mo->match | (regnum << OP_SH_RT);
3384 if (*r == BFD_RELOC_UNUSED)
3386 insn.insn_opcode |= high_expr.X_add_number;
3387 append_insn (&insn, NULL, r);
3389 else
3390 append_insn (&insn, &high_expr, r);
3393 /* Generate a sequence of instructions to do a load or store from a constant
3394 offset off of a base register (breg) into/from a target register (treg),
3395 using AT if necessary. */
3396 static void
3397 macro_build_ldst_constoffset (expressionS *ep, const char *op,
3398 int treg, int breg, int dbl)
3400 assert (ep->X_op == O_constant);
3402 /* Sign-extending 32-bit constants makes their handling easier. */
3403 if (! dbl && ! ((ep->X_add_number & ~((bfd_vma) 0x7fffffff))
3404 == ~((bfd_vma) 0x7fffffff)))
3406 if (ep->X_add_number & ~((bfd_vma) 0xffffffff))
3407 as_bad (_("constant too large"));
3409 ep->X_add_number = (((ep->X_add_number & 0xffffffff) ^ 0x80000000)
3410 - 0x80000000);
3413 /* Right now, this routine can only handle signed 32-bit constants. */
3414 if (! IS_SEXT_32BIT_NUM(ep->X_add_number + 0x8000))
3415 as_warn (_("operand overflow"));
3417 if (IS_SEXT_16BIT_NUM(ep->X_add_number))
3419 /* Signed 16-bit offset will fit in the op. Easy! */
3420 macro_build (ep, op, "t,o(b)", treg, BFD_RELOC_LO16, breg);
3422 else
3424 /* 32-bit offset, need multiple instructions and AT, like:
3425 lui $tempreg,const_hi (BFD_RELOC_HI16_S)
3426 addu $tempreg,$tempreg,$breg
3427 <op> $treg,const_lo($tempreg) (BFD_RELOC_LO16)
3428 to handle the complete offset. */
3429 macro_build_lui (ep, AT);
3430 macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t", AT, AT, breg);
3431 macro_build (ep, op, "t,o(b)", treg, BFD_RELOC_LO16, AT);
3433 if (mips_opts.noat)
3434 as_warn (_("Macro used $at after \".set noat\""));
3438 /* set_at()
3439 * Generates code to set the $at register to true (one)
3440 * if reg is less than the immediate expression.
3442 static void
3443 set_at (int reg, int unsignedp)
3445 if (imm_expr.X_op == O_constant
3446 && imm_expr.X_add_number >= -0x8000
3447 && imm_expr.X_add_number < 0x8000)
3448 macro_build (&imm_expr, unsignedp ? "sltiu" : "slti", "t,r,j",
3449 AT, reg, BFD_RELOC_LO16);
3450 else
3452 load_register (AT, &imm_expr, HAVE_64BIT_GPRS);
3453 macro_build (NULL, unsignedp ? "sltu" : "slt", "d,v,t", AT, reg, AT);
3457 static void
3458 normalize_constant_expr (expressionS *ex)
3460 if (ex->X_op == O_constant && HAVE_32BIT_GPRS)
3461 ex->X_add_number = (((ex->X_add_number & 0xffffffff) ^ 0x80000000)
3462 - 0x80000000);
3465 /* Warn if an expression is not a constant. */
3467 static void
3468 check_absolute_expr (struct mips_cl_insn *ip, expressionS *ex)
3470 if (ex->X_op == O_big)
3471 as_bad (_("unsupported large constant"));
3472 else if (ex->X_op != O_constant)
3473 as_bad (_("Instruction %s requires absolute expression"), ip->insn_mo->name);
3475 normalize_constant_expr (ex);
3478 /* Count the leading zeroes by performing a binary chop. This is a
3479 bulky bit of source, but performance is a LOT better for the
3480 majority of values than a simple loop to count the bits:
3481 for (lcnt = 0; (lcnt < 32); lcnt++)
3482 if ((v) & (1 << (31 - lcnt)))
3483 break;
3484 However it is not code size friendly, and the gain will drop a bit
3485 on certain cached systems.
3487 #define COUNT_TOP_ZEROES(v) \
3488 (((v) & ~0xffff) == 0 \
3489 ? ((v) & ~0xff) == 0 \
3490 ? ((v) & ~0xf) == 0 \
3491 ? ((v) & ~0x3) == 0 \
3492 ? ((v) & ~0x1) == 0 \
3493 ? !(v) \
3494 ? 32 \
3495 : 31 \
3496 : 30 \
3497 : ((v) & ~0x7) == 0 \
3498 ? 29 \
3499 : 28 \
3500 : ((v) & ~0x3f) == 0 \
3501 ? ((v) & ~0x1f) == 0 \
3502 ? 27 \
3503 : 26 \
3504 : ((v) & ~0x7f) == 0 \
3505 ? 25 \
3506 : 24 \
3507 : ((v) & ~0xfff) == 0 \
3508 ? ((v) & ~0x3ff) == 0 \
3509 ? ((v) & ~0x1ff) == 0 \
3510 ? 23 \
3511 : 22 \
3512 : ((v) & ~0x7ff) == 0 \
3513 ? 21 \
3514 : 20 \
3515 : ((v) & ~0x3fff) == 0 \
3516 ? ((v) & ~0x1fff) == 0 \
3517 ? 19 \
3518 : 18 \
3519 : ((v) & ~0x7fff) == 0 \
3520 ? 17 \
3521 : 16 \
3522 : ((v) & ~0xffffff) == 0 \
3523 ? ((v) & ~0xfffff) == 0 \
3524 ? ((v) & ~0x3ffff) == 0 \
3525 ? ((v) & ~0x1ffff) == 0 \
3526 ? 15 \
3527 : 14 \
3528 : ((v) & ~0x7ffff) == 0 \
3529 ? 13 \
3530 : 12 \
3531 : ((v) & ~0x3fffff) == 0 \
3532 ? ((v) & ~0x1fffff) == 0 \
3533 ? 11 \
3534 : 10 \
3535 : ((v) & ~0x7fffff) == 0 \
3536 ? 9 \
3537 : 8 \
3538 : ((v) & ~0xfffffff) == 0 \
3539 ? ((v) & ~0x3ffffff) == 0 \
3540 ? ((v) & ~0x1ffffff) == 0 \
3541 ? 7 \
3542 : 6 \
3543 : ((v) & ~0x7ffffff) == 0 \
3544 ? 5 \
3545 : 4 \
3546 : ((v) & ~0x3fffffff) == 0 \
3547 ? ((v) & ~0x1fffffff) == 0 \
3548 ? 3 \
3549 : 2 \
3550 : ((v) & ~0x7fffffff) == 0 \
3551 ? 1 \
3552 : 0)
3554 /* load_register()
3555 * This routine generates the least number of instructions necessary to load
3556 * an absolute expression value into a register.
3558 static void
3559 load_register (int reg, expressionS *ep, int dbl)
3561 int freg;
3562 expressionS hi32, lo32;
3564 if (ep->X_op != O_big)
3566 assert (ep->X_op == O_constant);
3568 /* Sign-extending 32-bit constants makes their handling easier. */
3569 if (! dbl && ! ((ep->X_add_number & ~((bfd_vma) 0x7fffffff))
3570 == ~((bfd_vma) 0x7fffffff)))
3572 if (ep->X_add_number & ~((bfd_vma) 0xffffffff))
3573 as_bad (_("constant too large"));
3575 ep->X_add_number = (((ep->X_add_number & 0xffffffff) ^ 0x80000000)
3576 - 0x80000000);
3579 if (IS_SEXT_16BIT_NUM (ep->X_add_number))
3581 /* We can handle 16 bit signed values with an addiu to
3582 $zero. No need to ever use daddiu here, since $zero and
3583 the result are always correct in 32 bit mode. */
3584 macro_build (ep, "addiu", "t,r,j", reg, 0, BFD_RELOC_LO16);
3585 return;
3587 else if (ep->X_add_number >= 0 && ep->X_add_number < 0x10000)
3589 /* We can handle 16 bit unsigned values with an ori to
3590 $zero. */
3591 macro_build (ep, "ori", "t,r,i", reg, 0, BFD_RELOC_LO16);
3592 return;
3594 else if ((IS_SEXT_32BIT_NUM (ep->X_add_number)))
3596 /* 32 bit values require an lui. */
3597 macro_build (ep, "lui", "t,u", reg, BFD_RELOC_HI16);
3598 if ((ep->X_add_number & 0xffff) != 0)
3599 macro_build (ep, "ori", "t,r,i", reg, reg, BFD_RELOC_LO16);
3600 return;
3604 /* The value is larger than 32 bits. */
3606 if (HAVE_32BIT_GPRS)
3608 as_bad (_("Number (0x%lx) larger than 32 bits"),
3609 (unsigned long) ep->X_add_number);
3610 macro_build (ep, "addiu", "t,r,j", reg, 0, BFD_RELOC_LO16);
3611 return;
3614 if (ep->X_op != O_big)
3616 hi32 = *ep;
3617 hi32.X_add_number = (valueT) hi32.X_add_number >> 16;
3618 hi32.X_add_number = (valueT) hi32.X_add_number >> 16;
3619 hi32.X_add_number &= 0xffffffff;
3620 lo32 = *ep;
3621 lo32.X_add_number &= 0xffffffff;
3623 else
3625 assert (ep->X_add_number > 2);
3626 if (ep->X_add_number == 3)
3627 generic_bignum[3] = 0;
3628 else if (ep->X_add_number > 4)
3629 as_bad (_("Number larger than 64 bits"));
3630 lo32.X_op = O_constant;
3631 lo32.X_add_number = generic_bignum[0] + (generic_bignum[1] << 16);
3632 hi32.X_op = O_constant;
3633 hi32.X_add_number = generic_bignum[2] + (generic_bignum[3] << 16);
3636 if (hi32.X_add_number == 0)
3637 freg = 0;
3638 else
3640 int shift, bit;
3641 unsigned long hi, lo;
3643 if (hi32.X_add_number == (offsetT) 0xffffffff)
3645 if ((lo32.X_add_number & 0xffff8000) == 0xffff8000)
3647 macro_build (&lo32, "addiu", "t,r,j", reg, 0, BFD_RELOC_LO16);
3648 return;
3650 if (lo32.X_add_number & 0x80000000)
3652 macro_build (&lo32, "lui", "t,u", reg, BFD_RELOC_HI16);
3653 if (lo32.X_add_number & 0xffff)
3654 macro_build (&lo32, "ori", "t,r,i", reg, reg, BFD_RELOC_LO16);
3655 return;
3659 /* Check for 16bit shifted constant. We know that hi32 is
3660 non-zero, so start the mask on the first bit of the hi32
3661 value. */
3662 shift = 17;
3665 unsigned long himask, lomask;
3667 if (shift < 32)
3669 himask = 0xffff >> (32 - shift);
3670 lomask = (0xffff << shift) & 0xffffffff;
3672 else
3674 himask = 0xffff << (shift - 32);
3675 lomask = 0;
3677 if ((hi32.X_add_number & ~(offsetT) himask) == 0
3678 && (lo32.X_add_number & ~(offsetT) lomask) == 0)
3680 expressionS tmp;
3682 tmp.X_op = O_constant;
3683 if (shift < 32)
3684 tmp.X_add_number = ((hi32.X_add_number << (32 - shift))
3685 | (lo32.X_add_number >> shift));
3686 else
3687 tmp.X_add_number = hi32.X_add_number >> (shift - 32);
3688 macro_build (&tmp, "ori", "t,r,i", reg, 0, BFD_RELOC_LO16);
3689 macro_build (NULL, (shift >= 32) ? "dsll32" : "dsll", "d,w,<",
3690 reg, reg, (shift >= 32) ? shift - 32 : shift);
3691 return;
3693 ++shift;
3695 while (shift <= (64 - 16));
3697 /* Find the bit number of the lowest one bit, and store the
3698 shifted value in hi/lo. */
3699 hi = (unsigned long) (hi32.X_add_number & 0xffffffff);
3700 lo = (unsigned long) (lo32.X_add_number & 0xffffffff);
3701 if (lo != 0)
3703 bit = 0;
3704 while ((lo & 1) == 0)
3706 lo >>= 1;
3707 ++bit;
3709 lo |= (hi & (((unsigned long) 1 << bit) - 1)) << (32 - bit);
3710 hi >>= bit;
3712 else
3714 bit = 32;
3715 while ((hi & 1) == 0)
3717 hi >>= 1;
3718 ++bit;
3720 lo = hi;
3721 hi = 0;
3724 /* Optimize if the shifted value is a (power of 2) - 1. */
3725 if ((hi == 0 && ((lo + 1) & lo) == 0)
3726 || (lo == 0xffffffff && ((hi + 1) & hi) == 0))
3728 shift = COUNT_TOP_ZEROES ((unsigned int) hi32.X_add_number);
3729 if (shift != 0)
3731 expressionS tmp;
3733 /* This instruction will set the register to be all
3734 ones. */
3735 tmp.X_op = O_constant;
3736 tmp.X_add_number = (offsetT) -1;
3737 macro_build (&tmp, "addiu", "t,r,j", reg, 0, BFD_RELOC_LO16);
3738 if (bit != 0)
3740 bit += shift;
3741 macro_build (NULL, (bit >= 32) ? "dsll32" : "dsll", "d,w,<",
3742 reg, reg, (bit >= 32) ? bit - 32 : bit);
3744 macro_build (NULL, (shift >= 32) ? "dsrl32" : "dsrl", "d,w,<",
3745 reg, reg, (shift >= 32) ? shift - 32 : shift);
3746 return;
3750 /* Sign extend hi32 before calling load_register, because we can
3751 generally get better code when we load a sign extended value. */
3752 if ((hi32.X_add_number & 0x80000000) != 0)
3753 hi32.X_add_number |= ~(offsetT) 0xffffffff;
3754 load_register (reg, &hi32, 0);
3755 freg = reg;
3757 if ((lo32.X_add_number & 0xffff0000) == 0)
3759 if (freg != 0)
3761 macro_build (NULL, "dsll32", "d,w,<", reg, freg, 0);
3762 freg = reg;
3765 else
3767 expressionS mid16;
3769 if ((freg == 0) && (lo32.X_add_number == (offsetT) 0xffffffff))
3771 macro_build (&lo32, "lui", "t,u", reg, BFD_RELOC_HI16);
3772 macro_build (NULL, "dsrl32", "d,w,<", reg, reg, 0);
3773 return;
3776 if (freg != 0)
3778 macro_build (NULL, "dsll", "d,w,<", reg, freg, 16);
3779 freg = reg;
3781 mid16 = lo32;
3782 mid16.X_add_number >>= 16;
3783 macro_build (&mid16, "ori", "t,r,i", reg, freg, BFD_RELOC_LO16);
3784 macro_build (NULL, "dsll", "d,w,<", reg, reg, 16);
3785 freg = reg;
3787 if ((lo32.X_add_number & 0xffff) != 0)
3788 macro_build (&lo32, "ori", "t,r,i", reg, freg, BFD_RELOC_LO16);
3791 static inline void
3792 load_delay_nop (void)
3794 if (!gpr_interlocks)
3795 macro_build (NULL, "nop", "");
3798 /* Load an address into a register. */
3800 static void
3801 load_address (int reg, expressionS *ep, int *used_at)
3803 if (ep->X_op != O_constant
3804 && ep->X_op != O_symbol)
3806 as_bad (_("expression too complex"));
3807 ep->X_op = O_constant;
3810 if (ep->X_op == O_constant)
3812 load_register (reg, ep, HAVE_64BIT_ADDRESSES);
3813 return;
3816 if (mips_pic == NO_PIC)
3818 /* If this is a reference to a GP relative symbol, we want
3819 addiu $reg,$gp,<sym> (BFD_RELOC_GPREL16)
3820 Otherwise we want
3821 lui $reg,<sym> (BFD_RELOC_HI16_S)
3822 addiu $reg,$reg,<sym> (BFD_RELOC_LO16)
3823 If we have an addend, we always use the latter form.
3825 With 64bit address space and a usable $at we want
3826 lui $reg,<sym> (BFD_RELOC_MIPS_HIGHEST)
3827 lui $at,<sym> (BFD_RELOC_HI16_S)
3828 daddiu $reg,<sym> (BFD_RELOC_MIPS_HIGHER)
3829 daddiu $at,<sym> (BFD_RELOC_LO16)
3830 dsll32 $reg,0
3831 daddu $reg,$reg,$at
3833 If $at is already in use, we use a path which is suboptimal
3834 on superscalar processors.
3835 lui $reg,<sym> (BFD_RELOC_MIPS_HIGHEST)
3836 daddiu $reg,<sym> (BFD_RELOC_MIPS_HIGHER)
3837 dsll $reg,16
3838 daddiu $reg,<sym> (BFD_RELOC_HI16_S)
3839 dsll $reg,16
3840 daddiu $reg,<sym> (BFD_RELOC_LO16)
3842 if (HAVE_64BIT_ADDRESSES)
3844 /* ??? We don't provide a GP-relative alternative for these macros.
3845 It used not to be possible with the original relaxation code,
3846 but it could be done now. */
3848 if (*used_at == 0 && ! mips_opts.noat)
3850 macro_build (ep, "lui", "t,u", reg, BFD_RELOC_MIPS_HIGHEST);
3851 macro_build (ep, "lui", "t,u", AT, BFD_RELOC_HI16_S);
3852 macro_build (ep, "daddiu", "t,r,j", reg, reg,
3853 BFD_RELOC_MIPS_HIGHER);
3854 macro_build (ep, "daddiu", "t,r,j", AT, AT, BFD_RELOC_LO16);
3855 macro_build (NULL, "dsll32", "d,w,<", reg, reg, 0);
3856 macro_build (NULL, "daddu", "d,v,t", reg, reg, AT);
3857 *used_at = 1;
3859 else
3861 macro_build (ep, "lui", "t,u", reg, BFD_RELOC_MIPS_HIGHEST);
3862 macro_build (ep, "daddiu", "t,r,j", reg, reg,
3863 BFD_RELOC_MIPS_HIGHER);
3864 macro_build (NULL, "dsll", "d,w,<", reg, reg, 16);
3865 macro_build (ep, "daddiu", "t,r,j", reg, reg, BFD_RELOC_HI16_S);
3866 macro_build (NULL, "dsll", "d,w,<", reg, reg, 16);
3867 macro_build (ep, "daddiu", "t,r,j", reg, reg, BFD_RELOC_LO16);
3870 else
3872 if ((valueT) ep->X_add_number <= MAX_GPREL_OFFSET
3873 && ! nopic_need_relax (ep->X_add_symbol, 1))
3875 relax_start (ep->X_add_symbol);
3876 macro_build (ep, ADDRESS_ADDI_INSN, "t,r,j", reg,
3877 mips_gp_register, BFD_RELOC_GPREL16);
3878 relax_switch ();
3880 macro_build_lui (ep, reg);
3881 macro_build (ep, ADDRESS_ADDI_INSN, "t,r,j",
3882 reg, reg, BFD_RELOC_LO16);
3883 if (mips_relax.sequence)
3884 relax_end ();
3887 else if (mips_pic == SVR4_PIC && ! mips_big_got)
3889 expressionS ex;
3891 /* If this is a reference to an external symbol, we want
3892 lw $reg,<sym>($gp) (BFD_RELOC_MIPS_GOT16)
3893 Otherwise we want
3894 lw $reg,<sym>($gp) (BFD_RELOC_MIPS_GOT16)
3896 addiu $reg,$reg,<sym> (BFD_RELOC_LO16)
3897 If there is a constant, it must be added in after.
3899 If we have NewABI, we want
3900 lw $reg,<sym+cst>($gp) (BFD_RELOC_MIPS_GOT_DISP)
3901 unless we're referencing a global symbol with a non-zero
3902 offset, in which case cst must be added separately. */
3903 if (HAVE_NEWABI)
3905 if (ep->X_add_number)
3907 ex.X_add_number = ep->X_add_number;
3908 ep->X_add_number = 0;
3909 relax_start (ep->X_add_symbol);
3910 macro_build (ep, ADDRESS_LOAD_INSN, "t,o(b)", reg,
3911 BFD_RELOC_MIPS_GOT_DISP, mips_gp_register);
3912 if (ex.X_add_number < -0x8000 || ex.X_add_number >= 0x8000)
3913 as_bad (_("PIC code offset overflow (max 16 signed bits)"));
3914 ex.X_op = O_constant;
3915 macro_build (&ex, ADDRESS_ADDI_INSN, "t,r,j",
3916 reg, reg, BFD_RELOC_LO16);
3917 ep->X_add_number = ex.X_add_number;
3918 relax_switch ();
3920 macro_build (ep, ADDRESS_LOAD_INSN, "t,o(b)", reg,
3921 BFD_RELOC_MIPS_GOT_DISP, mips_gp_register);
3922 if (mips_relax.sequence)
3923 relax_end ();
3925 else
3927 ex.X_add_number = ep->X_add_number;
3928 ep->X_add_number = 0;
3929 macro_build (ep, ADDRESS_LOAD_INSN, "t,o(b)", reg,
3930 BFD_RELOC_MIPS_GOT16, mips_gp_register);
3931 load_delay_nop ();
3932 relax_start (ep->X_add_symbol);
3933 relax_switch ();
3934 macro_build (ep, ADDRESS_ADDI_INSN, "t,r,j", reg, reg,
3935 BFD_RELOC_LO16);
3936 relax_end ();
3938 if (ex.X_add_number != 0)
3940 if (ex.X_add_number < -0x8000 || ex.X_add_number >= 0x8000)
3941 as_bad (_("PIC code offset overflow (max 16 signed bits)"));
3942 ex.X_op = O_constant;
3943 macro_build (&ex, ADDRESS_ADDI_INSN, "t,r,j",
3944 reg, reg, BFD_RELOC_LO16);
3948 else if (mips_pic == SVR4_PIC)
3950 expressionS ex;
3952 /* This is the large GOT case. If this is a reference to an
3953 external symbol, we want
3954 lui $reg,<sym> (BFD_RELOC_MIPS_GOT_HI16)
3955 addu $reg,$reg,$gp
3956 lw $reg,<sym>($reg) (BFD_RELOC_MIPS_GOT_LO16)
3958 Otherwise, for a reference to a local symbol in old ABI, we want
3959 lw $reg,<sym>($gp) (BFD_RELOC_MIPS_GOT16)
3961 addiu $reg,$reg,<sym> (BFD_RELOC_LO16)
3962 If there is a constant, it must be added in after.
3964 In the NewABI, for local symbols, with or without offsets, we want:
3965 lw $reg,<sym>($gp) (BFD_RELOC_MIPS_GOT_PAGE)
3966 addiu $reg,$reg,<sym> (BFD_RELOC_MIPS_GOT_OFST)
3968 if (HAVE_NEWABI)
3970 ex.X_add_number = ep->X_add_number;
3971 ep->X_add_number = 0;
3972 relax_start (ep->X_add_symbol);
3973 macro_build (ep, "lui", "t,u", reg, BFD_RELOC_MIPS_GOT_HI16);
3974 macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t",
3975 reg, reg, mips_gp_register);
3976 macro_build (ep, ADDRESS_LOAD_INSN, "t,o(b)",
3977 reg, BFD_RELOC_MIPS_GOT_LO16, reg);
3978 if (ex.X_add_number < -0x8000 || ex.X_add_number >= 0x8000)
3979 as_bad (_("PIC code offset overflow (max 16 signed bits)"));
3980 else if (ex.X_add_number)
3982 ex.X_op = O_constant;
3983 macro_build (&ex, ADDRESS_ADDI_INSN, "t,r,j", reg, reg,
3984 BFD_RELOC_LO16);
3987 ep->X_add_number = ex.X_add_number;
3988 relax_switch ();
3989 macro_build (ep, ADDRESS_LOAD_INSN, "t,o(b)", reg,
3990 BFD_RELOC_MIPS_GOT_PAGE, mips_gp_register);
3991 macro_build (ep, ADDRESS_ADDI_INSN, "t,r,j", reg, reg,
3992 BFD_RELOC_MIPS_GOT_OFST);
3993 relax_end ();
3995 else
3997 ex.X_add_number = ep->X_add_number;
3998 ep->X_add_number = 0;
3999 relax_start (ep->X_add_symbol);
4000 macro_build (ep, "lui", "t,u", reg, BFD_RELOC_MIPS_GOT_HI16);
4001 macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t",
4002 reg, reg, mips_gp_register);
4003 macro_build (ep, ADDRESS_LOAD_INSN, "t,o(b)",
4004 reg, BFD_RELOC_MIPS_GOT_LO16, reg);
4005 relax_switch ();
4006 if (reg_needs_delay (mips_gp_register))
4008 /* We need a nop before loading from $gp. This special
4009 check is required because the lui which starts the main
4010 instruction stream does not refer to $gp, and so will not
4011 insert the nop which may be required. */
4012 macro_build (NULL, "nop", "");
4014 macro_build (ep, ADDRESS_LOAD_INSN, "t,o(b)", reg,
4015 BFD_RELOC_MIPS_GOT16, mips_gp_register);
4016 load_delay_nop ();
4017 macro_build (ep, ADDRESS_ADDI_INSN, "t,r,j", reg, reg,
4018 BFD_RELOC_LO16);
4019 relax_end ();
4021 if (ex.X_add_number != 0)
4023 if (ex.X_add_number < -0x8000 || ex.X_add_number >= 0x8000)
4024 as_bad (_("PIC code offset overflow (max 16 signed bits)"));
4025 ex.X_op = O_constant;
4026 macro_build (&ex, ADDRESS_ADDI_INSN, "t,r,j", reg, reg,
4027 BFD_RELOC_LO16);
4031 else
4032 abort ();
4035 /* Move the contents of register SOURCE into register DEST. */
4037 static void
4038 move_register (int dest, int source)
4040 macro_build (NULL, HAVE_32BIT_GPRS ? "addu" : "daddu", "d,v,t",
4041 dest, source, 0);
4044 /* Emit an SVR4 PIC sequence to load address LOCAL into DEST, where
4045 LOCAL is the sum of a symbol and a 16-bit or 32-bit displacement.
4046 The two alternatives are:
4048 Global symbol Local sybmol
4049 ------------- ------------
4050 lw DEST,%got(SYMBOL) lw DEST,%got(SYMBOL + OFFSET)
4051 ... ...
4052 addiu DEST,DEST,OFFSET addiu DEST,DEST,%lo(SYMBOL + OFFSET)
4054 load_got_offset emits the first instruction and add_got_offset
4055 emits the second for a 16-bit offset or add_got_offset_hilo emits
4056 a sequence to add a 32-bit offset using a scratch register. */
4058 static void
4059 load_got_offset (int dest, expressionS *local)
4061 expressionS global;
4063 global = *local;
4064 global.X_add_number = 0;
4066 relax_start (local->X_add_symbol);
4067 macro_build (&global, ADDRESS_LOAD_INSN, "t,o(b)", dest,
4068 BFD_RELOC_MIPS_GOT16, mips_gp_register);
4069 relax_switch ();
4070 macro_build (local, ADDRESS_LOAD_INSN, "t,o(b)", dest,
4071 BFD_RELOC_MIPS_GOT16, mips_gp_register);
4072 relax_end ();
4075 static void
4076 add_got_offset (int dest, expressionS *local)
4078 expressionS global;
4080 global.X_op = O_constant;
4081 global.X_op_symbol = NULL;
4082 global.X_add_symbol = NULL;
4083 global.X_add_number = local->X_add_number;
4085 relax_start (local->X_add_symbol);
4086 macro_build (&global, ADDRESS_ADDI_INSN, "t,r,j",
4087 dest, dest, BFD_RELOC_LO16);
4088 relax_switch ();
4089 macro_build (local, ADDRESS_ADDI_INSN, "t,r,j", dest, dest, BFD_RELOC_LO16);
4090 relax_end ();
4093 static void
4094 add_got_offset_hilo (int dest, expressionS *local, int tmp)
4096 expressionS global;
4097 int hold_mips_optimize;
4099 global.X_op = O_constant;
4100 global.X_op_symbol = NULL;
4101 global.X_add_symbol = NULL;
4102 global.X_add_number = local->X_add_number;
4104 relax_start (local->X_add_symbol);
4105 load_register (tmp, &global, HAVE_64BIT_ADDRESSES);
4106 relax_switch ();
4107 /* Set mips_optimize around the lui instruction to avoid
4108 inserting an unnecessary nop after the lw. */
4109 hold_mips_optimize = mips_optimize;
4110 mips_optimize = 2;
4111 macro_build_lui (&global, tmp);
4112 mips_optimize = hold_mips_optimize;
4113 macro_build (local, ADDRESS_ADDI_INSN, "t,r,j", tmp, tmp, BFD_RELOC_LO16);
4114 relax_end ();
4116 macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t", dest, dest, tmp);
4120 * Build macros
4121 * This routine implements the seemingly endless macro or synthesized
4122 * instructions and addressing modes in the mips assembly language. Many
4123 * of these macros are simple and are similar to each other. These could
4124 * probably be handled by some kind of table or grammar approach instead of
4125 * this verbose method. Others are not simple macros but are more like
4126 * optimizing code generation.
4127 * One interesting optimization is when several store macros appear
4128 * consecutively that would load AT with the upper half of the same address.
4129 * The ensuing load upper instructions are ommited. This implies some kind
4130 * of global optimization. We currently only optimize within a single macro.
4131 * For many of the load and store macros if the address is specified as a
4132 * constant expression in the first 64k of memory (ie ld $2,0x4000c) we
4133 * first load register 'at' with zero and use it as the base register. The
4134 * mips assembler simply uses register $zero. Just one tiny optimization
4135 * we're missing.
4137 static void
4138 macro (struct mips_cl_insn *ip)
4140 register int treg, sreg, dreg, breg;
4141 int tempreg;
4142 int mask;
4143 int used_at = 0;
4144 expressionS expr1;
4145 const char *s;
4146 const char *s2;
4147 const char *fmt;
4148 int likely = 0;
4149 int dbl = 0;
4150 int coproc = 0;
4151 int lr = 0;
4152 int imm = 0;
4153 int call = 0;
4154 int off;
4155 offsetT maxnum;
4156 bfd_reloc_code_real_type r;
4157 int hold_mips_optimize;
4159 assert (! mips_opts.mips16);
4161 treg = (ip->insn_opcode >> 16) & 0x1f;
4162 dreg = (ip->insn_opcode >> 11) & 0x1f;
4163 sreg = breg = (ip->insn_opcode >> 21) & 0x1f;
4164 mask = ip->insn_mo->mask;
4166 expr1.X_op = O_constant;
4167 expr1.X_op_symbol = NULL;
4168 expr1.X_add_symbol = NULL;
4169 expr1.X_add_number = 1;
4171 switch (mask)
4173 case M_DABS:
4174 dbl = 1;
4175 case M_ABS:
4176 /* bgez $a0,.+12
4177 move v0,$a0
4178 sub v0,$zero,$a0
4181 mips_emit_delays (TRUE);
4182 ++mips_opts.noreorder;
4183 mips_any_noreorder = 1;
4185 expr1.X_add_number = 8;
4186 macro_build (&expr1, "bgez", "s,p", sreg);
4187 if (dreg == sreg)
4188 macro_build (NULL, "nop", "", 0);
4189 else
4190 move_register (dreg, sreg);
4191 macro_build (NULL, dbl ? "dsub" : "sub", "d,v,t", dreg, 0, sreg);
4193 --mips_opts.noreorder;
4194 return;
4196 case M_ADD_I:
4197 s = "addi";
4198 s2 = "add";
4199 goto do_addi;
4200 case M_ADDU_I:
4201 s = "addiu";
4202 s2 = "addu";
4203 goto do_addi;
4204 case M_DADD_I:
4205 dbl = 1;
4206 s = "daddi";
4207 s2 = "dadd";
4208 goto do_addi;
4209 case M_DADDU_I:
4210 dbl = 1;
4211 s = "daddiu";
4212 s2 = "daddu";
4213 do_addi:
4214 if (imm_expr.X_op == O_constant
4215 && imm_expr.X_add_number >= -0x8000
4216 && imm_expr.X_add_number < 0x8000)
4218 macro_build (&imm_expr, s, "t,r,j", treg, sreg, BFD_RELOC_LO16);
4219 return;
4221 load_register (AT, &imm_expr, dbl);
4222 macro_build (NULL, s2, "d,v,t", treg, sreg, AT);
4223 break;
4225 case M_AND_I:
4226 s = "andi";
4227 s2 = "and";
4228 goto do_bit;
4229 case M_OR_I:
4230 s = "ori";
4231 s2 = "or";
4232 goto do_bit;
4233 case M_NOR_I:
4234 s = "";
4235 s2 = "nor";
4236 goto do_bit;
4237 case M_XOR_I:
4238 s = "xori";
4239 s2 = "xor";
4240 do_bit:
4241 if (imm_expr.X_op == O_constant
4242 && imm_expr.X_add_number >= 0
4243 && imm_expr.X_add_number < 0x10000)
4245 if (mask != M_NOR_I)
4246 macro_build (&imm_expr, s, "t,r,i", treg, sreg, BFD_RELOC_LO16);
4247 else
4249 macro_build (&imm_expr, "ori", "t,r,i",
4250 treg, sreg, BFD_RELOC_LO16);
4251 macro_build (NULL, "nor", "d,v,t", treg, treg, 0);
4253 return;
4256 load_register (AT, &imm_expr, HAVE_64BIT_GPRS);
4257 macro_build (NULL, s2, "d,v,t", treg, sreg, AT);
4258 break;
4260 case M_BEQ_I:
4261 s = "beq";
4262 goto beq_i;
4263 case M_BEQL_I:
4264 s = "beql";
4265 likely = 1;
4266 goto beq_i;
4267 case M_BNE_I:
4268 s = "bne";
4269 goto beq_i;
4270 case M_BNEL_I:
4271 s = "bnel";
4272 likely = 1;
4273 beq_i:
4274 if (imm_expr.X_op == O_constant && imm_expr.X_add_number == 0)
4276 macro_build (&offset_expr, s, "s,t,p", sreg, 0);
4277 return;
4279 load_register (AT, &imm_expr, HAVE_64BIT_GPRS);
4280 macro_build (&offset_expr, s, "s,t,p", sreg, AT);
4281 break;
4283 case M_BGEL:
4284 likely = 1;
4285 case M_BGE:
4286 if (treg == 0)
4288 macro_build (&offset_expr, likely ? "bgezl" : "bgez", "s,p", sreg);
4289 return;
4291 if (sreg == 0)
4293 macro_build (&offset_expr, likely ? "blezl" : "blez", "s,p", treg);
4294 return;
4296 macro_build (NULL, "slt", "d,v,t", AT, sreg, treg);
4297 macro_build (&offset_expr, likely ? "beql" : "beq", "s,t,p", AT, 0);
4298 break;
4300 case M_BGTL_I:
4301 likely = 1;
4302 case M_BGT_I:
4303 /* check for > max integer */
4304 maxnum = 0x7fffffff;
4305 if (HAVE_64BIT_GPRS && sizeof (maxnum) > 4)
4307 maxnum <<= 16;
4308 maxnum |= 0xffff;
4309 maxnum <<= 16;
4310 maxnum |= 0xffff;
4312 if (imm_expr.X_op == O_constant
4313 && imm_expr.X_add_number >= maxnum
4314 && (HAVE_32BIT_GPRS || sizeof (maxnum) > 4))
4316 do_false:
4317 /* result is always false */
4318 if (! likely)
4319 macro_build (NULL, "nop", "", 0);
4320 else
4321 macro_build (&offset_expr, "bnel", "s,t,p", 0, 0);
4322 return;
4324 if (imm_expr.X_op != O_constant)
4325 as_bad (_("Unsupported large constant"));
4326 ++imm_expr.X_add_number;
4327 /* FALLTHROUGH */
4328 case M_BGE_I:
4329 case M_BGEL_I:
4330 if (mask == M_BGEL_I)
4331 likely = 1;
4332 if (imm_expr.X_op == O_constant && imm_expr.X_add_number == 0)
4334 macro_build (&offset_expr, likely ? "bgezl" : "bgez", "s,p", sreg);
4335 return;
4337 if (imm_expr.X_op == O_constant && imm_expr.X_add_number == 1)
4339 macro_build (&offset_expr, likely ? "bgtzl" : "bgtz", "s,p", sreg);
4340 return;
4342 maxnum = 0x7fffffff;
4343 if (HAVE_64BIT_GPRS && sizeof (maxnum) > 4)
4345 maxnum <<= 16;
4346 maxnum |= 0xffff;
4347 maxnum <<= 16;
4348 maxnum |= 0xffff;
4350 maxnum = - maxnum - 1;
4351 if (imm_expr.X_op == O_constant
4352 && imm_expr.X_add_number <= maxnum
4353 && (HAVE_32BIT_GPRS || sizeof (maxnum) > 4))
4355 do_true:
4356 /* result is always true */
4357 as_warn (_("Branch %s is always true"), ip->insn_mo->name);
4358 macro_build (&offset_expr, "b", "p");
4359 return;
4361 set_at (sreg, 0);
4362 macro_build (&offset_expr, likely ? "beql" : "beq", "s,t,p", AT, 0);
4363 break;
4365 case M_BGEUL:
4366 likely = 1;
4367 case M_BGEU:
4368 if (treg == 0)
4369 goto do_true;
4370 if (sreg == 0)
4372 macro_build (&offset_expr, likely ? "beql" : "beq",
4373 "s,t,p", 0, treg);
4374 return;
4376 macro_build (NULL, "sltu", "d,v,t", AT, sreg, treg);
4377 macro_build (&offset_expr, likely ? "beql" : "beq", "s,t,p", AT, 0);
4378 break;
4380 case M_BGTUL_I:
4381 likely = 1;
4382 case M_BGTU_I:
4383 if (sreg == 0
4384 || (HAVE_32BIT_GPRS
4385 && imm_expr.X_op == O_constant
4386 && imm_expr.X_add_number == (offsetT) 0xffffffff))
4387 goto do_false;
4388 if (imm_expr.X_op != O_constant)
4389 as_bad (_("Unsupported large constant"));
4390 ++imm_expr.X_add_number;
4391 /* FALLTHROUGH */
4392 case M_BGEU_I:
4393 case M_BGEUL_I:
4394 if (mask == M_BGEUL_I)
4395 likely = 1;
4396 if (imm_expr.X_op == O_constant && imm_expr.X_add_number == 0)
4397 goto do_true;
4398 if (imm_expr.X_op == O_constant && imm_expr.X_add_number == 1)
4400 macro_build (&offset_expr, likely ? "bnel" : "bne",
4401 "s,t,p", sreg, 0);
4402 return;
4404 set_at (sreg, 1);
4405 macro_build (&offset_expr, likely ? "beql" : "beq", "s,t,p", AT, 0);
4406 break;
4408 case M_BGTL:
4409 likely = 1;
4410 case M_BGT:
4411 if (treg == 0)
4413 macro_build (&offset_expr, likely ? "bgtzl" : "bgtz", "s,p", sreg);
4414 return;
4416 if (sreg == 0)
4418 macro_build (&offset_expr, likely ? "bltzl" : "bltz", "s,p", treg);
4419 return;
4421 macro_build (NULL, "slt", "d,v,t", AT, treg, sreg);
4422 macro_build (&offset_expr, likely ? "bnel" : "bne", "s,t,p", AT, 0);
4423 break;
4425 case M_BGTUL:
4426 likely = 1;
4427 case M_BGTU:
4428 if (treg == 0)
4430 macro_build (&offset_expr, likely ? "bnel" : "bne",
4431 "s,t,p", sreg, 0);
4432 return;
4434 if (sreg == 0)
4435 goto do_false;
4436 macro_build (NULL, "sltu", "d,v,t", AT, treg, sreg);
4437 macro_build (&offset_expr, likely ? "bnel" : "bne", "s,t,p", AT, 0);
4438 break;
4440 case M_BLEL:
4441 likely = 1;
4442 case M_BLE:
4443 if (treg == 0)
4445 macro_build (&offset_expr, likely ? "blezl" : "blez", "s,p", sreg);
4446 return;
4448 if (sreg == 0)
4450 macro_build (&offset_expr, likely ? "bgezl" : "bgez", "s,p", treg);
4451 return;
4453 macro_build (NULL, "slt", "d,v,t", AT, treg, sreg);
4454 macro_build (&offset_expr, likely ? "beql" : "beq", "s,t,p", AT, 0);
4455 break;
4457 case M_BLEL_I:
4458 likely = 1;
4459 case M_BLE_I:
4460 maxnum = 0x7fffffff;
4461 if (HAVE_64BIT_GPRS && sizeof (maxnum) > 4)
4463 maxnum <<= 16;
4464 maxnum |= 0xffff;
4465 maxnum <<= 16;
4466 maxnum |= 0xffff;
4468 if (imm_expr.X_op == O_constant
4469 && imm_expr.X_add_number >= maxnum
4470 && (HAVE_32BIT_GPRS || sizeof (maxnum) > 4))
4471 goto do_true;
4472 if (imm_expr.X_op != O_constant)
4473 as_bad (_("Unsupported large constant"));
4474 ++imm_expr.X_add_number;
4475 /* FALLTHROUGH */
4476 case M_BLT_I:
4477 case M_BLTL_I:
4478 if (mask == M_BLTL_I)
4479 likely = 1;
4480 if (imm_expr.X_op == O_constant && imm_expr.X_add_number == 0)
4482 macro_build (&offset_expr, likely ? "bltzl" : "bltz", "s,p", sreg);
4483 return;
4485 if (imm_expr.X_op == O_constant && imm_expr.X_add_number == 1)
4487 macro_build (&offset_expr, likely ? "blezl" : "blez", "s,p", sreg);
4488 return;
4490 set_at (sreg, 0);
4491 macro_build (&offset_expr, likely ? "bnel" : "bne", "s,t,p", AT, 0);
4492 break;
4494 case M_BLEUL:
4495 likely = 1;
4496 case M_BLEU:
4497 if (treg == 0)
4499 macro_build (&offset_expr, likely ? "beql" : "beq",
4500 "s,t,p", sreg, 0);
4501 return;
4503 if (sreg == 0)
4504 goto do_true;
4505 macro_build (NULL, "sltu", "d,v,t", AT, treg, sreg);
4506 macro_build (&offset_expr, likely ? "beql" : "beq", "s,t,p", AT, 0);
4507 break;
4509 case M_BLEUL_I:
4510 likely = 1;
4511 case M_BLEU_I:
4512 if (sreg == 0
4513 || (HAVE_32BIT_GPRS
4514 && imm_expr.X_op == O_constant
4515 && imm_expr.X_add_number == (offsetT) 0xffffffff))
4516 goto do_true;
4517 if (imm_expr.X_op != O_constant)
4518 as_bad (_("Unsupported large constant"));
4519 ++imm_expr.X_add_number;
4520 /* FALLTHROUGH */
4521 case M_BLTU_I:
4522 case M_BLTUL_I:
4523 if (mask == M_BLTUL_I)
4524 likely = 1;
4525 if (imm_expr.X_op == O_constant && imm_expr.X_add_number == 0)
4526 goto do_false;
4527 if (imm_expr.X_op == O_constant && imm_expr.X_add_number == 1)
4529 macro_build (&offset_expr, likely ? "beql" : "beq",
4530 "s,t,p", sreg, 0);
4531 return;
4533 set_at (sreg, 1);
4534 macro_build (&offset_expr, likely ? "bnel" : "bne", "s,t,p", AT, 0);
4535 break;
4537 case M_BLTL:
4538 likely = 1;
4539 case M_BLT:
4540 if (treg == 0)
4542 macro_build (&offset_expr, likely ? "bltzl" : "bltz", "s,p", sreg);
4543 return;
4545 if (sreg == 0)
4547 macro_build (&offset_expr, likely ? "bgtzl" : "bgtz", "s,p", treg);
4548 return;
4550 macro_build (NULL, "slt", "d,v,t", AT, sreg, treg);
4551 macro_build (&offset_expr, likely ? "bnel" : "bne", "s,t,p", AT, 0);
4552 break;
4554 case M_BLTUL:
4555 likely = 1;
4556 case M_BLTU:
4557 if (treg == 0)
4558 goto do_false;
4559 if (sreg == 0)
4561 macro_build (&offset_expr, likely ? "bnel" : "bne",
4562 "s,t,p", 0, treg);
4563 return;
4565 macro_build (NULL, "sltu", "d,v,t", AT, sreg, treg);
4566 macro_build (&offset_expr, likely ? "bnel" : "bne", "s,t,p", AT, 0);
4567 break;
4569 case M_DEXT:
4571 unsigned long pos;
4572 unsigned long size;
4574 if (imm_expr.X_op != O_constant || imm2_expr.X_op != O_constant)
4576 as_bad (_("Unsupported large constant"));
4577 pos = size = 1;
4579 else
4581 pos = (unsigned long) imm_expr.X_add_number;
4582 size = (unsigned long) imm2_expr.X_add_number;
4585 if (pos > 63)
4587 as_bad (_("Improper position (%lu)"), pos);
4588 pos = 1;
4590 if (size == 0 || size > 64
4591 || (pos + size - 1) > 63)
4593 as_bad (_("Improper extract size (%lu, position %lu)"),
4594 size, pos);
4595 size = 1;
4598 if (size <= 32 && pos < 32)
4600 s = "dext";
4601 fmt = "t,r,+A,+C";
4603 else if (size <= 32)
4605 s = "dextu";
4606 fmt = "t,r,+E,+H";
4608 else
4610 s = "dextm";
4611 fmt = "t,r,+A,+G";
4613 macro_build ((expressionS *) NULL, s, fmt, treg, sreg, pos, size - 1);
4615 return;
4617 case M_DINS:
4619 unsigned long pos;
4620 unsigned long size;
4622 if (imm_expr.X_op != O_constant || imm2_expr.X_op != O_constant)
4624 as_bad (_("Unsupported large constant"));
4625 pos = size = 1;
4627 else
4629 pos = (unsigned long) imm_expr.X_add_number;
4630 size = (unsigned long) imm2_expr.X_add_number;
4633 if (pos > 63)
4635 as_bad (_("Improper position (%lu)"), pos);
4636 pos = 1;
4638 if (size == 0 || size > 64
4639 || (pos + size - 1) > 63)
4641 as_bad (_("Improper insert size (%lu, position %lu)"),
4642 size, pos);
4643 size = 1;
4646 if (pos < 32 && (pos + size - 1) < 32)
4648 s = "dins";
4649 fmt = "t,r,+A,+B";
4651 else if (pos >= 32)
4653 s = "dinsu";
4654 fmt = "t,r,+E,+F";
4656 else
4658 s = "dinsm";
4659 fmt = "t,r,+A,+F";
4661 macro_build ((expressionS *) NULL, s, fmt, treg, sreg, pos,
4662 pos + size - 1);
4664 return;
4666 case M_DDIV_3:
4667 dbl = 1;
4668 case M_DIV_3:
4669 s = "mflo";
4670 goto do_div3;
4671 case M_DREM_3:
4672 dbl = 1;
4673 case M_REM_3:
4674 s = "mfhi";
4675 do_div3:
4676 if (treg == 0)
4678 as_warn (_("Divide by zero."));
4679 if (mips_trap)
4680 macro_build (NULL, "teq", "s,t,q", 0, 0, 7);
4681 else
4682 macro_build (NULL, "break", "c", 7);
4683 return;
4686 mips_emit_delays (TRUE);
4687 ++mips_opts.noreorder;
4688 mips_any_noreorder = 1;
4689 if (mips_trap)
4691 macro_build (NULL, "teq", "s,t,q", treg, 0, 7);
4692 macro_build (NULL, dbl ? "ddiv" : "div", "z,s,t", sreg, treg);
4694 else
4696 expr1.X_add_number = 8;
4697 macro_build (&expr1, "bne", "s,t,p", treg, 0);
4698 macro_build (NULL, dbl ? "ddiv" : "div", "z,s,t", sreg, treg);
4699 macro_build (NULL, "break", "c", 7);
4701 expr1.X_add_number = -1;
4702 load_register (AT, &expr1, dbl);
4703 expr1.X_add_number = mips_trap ? (dbl ? 12 : 8) : (dbl ? 20 : 16);
4704 macro_build (&expr1, "bne", "s,t,p", treg, AT);
4705 if (dbl)
4707 expr1.X_add_number = 1;
4708 load_register (AT, &expr1, dbl);
4709 macro_build (NULL, "dsll32", "d,w,<", AT, AT, 31);
4711 else
4713 expr1.X_add_number = 0x80000000;
4714 macro_build (&expr1, "lui", "t,u", AT, BFD_RELOC_HI16);
4716 if (mips_trap)
4718 macro_build (NULL, "teq", "s,t,q", sreg, AT, 6);
4719 /* We want to close the noreorder block as soon as possible, so
4720 that later insns are available for delay slot filling. */
4721 --mips_opts.noreorder;
4723 else
4725 expr1.X_add_number = 8;
4726 macro_build (&expr1, "bne", "s,t,p", sreg, AT);
4727 macro_build (NULL, "nop", "", 0);
4729 /* We want to close the noreorder block as soon as possible, so
4730 that later insns are available for delay slot filling. */
4731 --mips_opts.noreorder;
4733 macro_build (NULL, "break", "c", 6);
4735 macro_build (NULL, s, "d", dreg);
4736 break;
4738 case M_DIV_3I:
4739 s = "div";
4740 s2 = "mflo";
4741 goto do_divi;
4742 case M_DIVU_3I:
4743 s = "divu";
4744 s2 = "mflo";
4745 goto do_divi;
4746 case M_REM_3I:
4747 s = "div";
4748 s2 = "mfhi";
4749 goto do_divi;
4750 case M_REMU_3I:
4751 s = "divu";
4752 s2 = "mfhi";
4753 goto do_divi;
4754 case M_DDIV_3I:
4755 dbl = 1;
4756 s = "ddiv";
4757 s2 = "mflo";
4758 goto do_divi;
4759 case M_DDIVU_3I:
4760 dbl = 1;
4761 s = "ddivu";
4762 s2 = "mflo";
4763 goto do_divi;
4764 case M_DREM_3I:
4765 dbl = 1;
4766 s = "ddiv";
4767 s2 = "mfhi";
4768 goto do_divi;
4769 case M_DREMU_3I:
4770 dbl = 1;
4771 s = "ddivu";
4772 s2 = "mfhi";
4773 do_divi:
4774 if (imm_expr.X_op == O_constant && imm_expr.X_add_number == 0)
4776 as_warn (_("Divide by zero."));
4777 if (mips_trap)
4778 macro_build (NULL, "teq", "s,t,q", 0, 0, 7);
4779 else
4780 macro_build (NULL, "break", "c", 7);
4781 return;
4783 if (imm_expr.X_op == O_constant && imm_expr.X_add_number == 1)
4785 if (strcmp (s2, "mflo") == 0)
4786 move_register (dreg, sreg);
4787 else
4788 move_register (dreg, 0);
4789 return;
4791 if (imm_expr.X_op == O_constant
4792 && imm_expr.X_add_number == -1
4793 && s[strlen (s) - 1] != 'u')
4795 if (strcmp (s2, "mflo") == 0)
4797 macro_build (NULL, dbl ? "dneg" : "neg", "d,w", dreg, sreg);
4799 else
4800 move_register (dreg, 0);
4801 return;
4804 load_register (AT, &imm_expr, dbl);
4805 macro_build (NULL, s, "z,s,t", sreg, AT);
4806 macro_build (NULL, s2, "d", dreg);
4807 break;
4809 case M_DIVU_3:
4810 s = "divu";
4811 s2 = "mflo";
4812 goto do_divu3;
4813 case M_REMU_3:
4814 s = "divu";
4815 s2 = "mfhi";
4816 goto do_divu3;
4817 case M_DDIVU_3:
4818 s = "ddivu";
4819 s2 = "mflo";
4820 goto do_divu3;
4821 case M_DREMU_3:
4822 s = "ddivu";
4823 s2 = "mfhi";
4824 do_divu3:
4825 mips_emit_delays (TRUE);
4826 ++mips_opts.noreorder;
4827 mips_any_noreorder = 1;
4828 if (mips_trap)
4830 macro_build (NULL, "teq", "s,t,q", treg, 0, 7);
4831 macro_build (NULL, s, "z,s,t", sreg, treg);
4832 /* We want to close the noreorder block as soon as possible, so
4833 that later insns are available for delay slot filling. */
4834 --mips_opts.noreorder;
4836 else
4838 expr1.X_add_number = 8;
4839 macro_build (&expr1, "bne", "s,t,p", treg, 0);
4840 macro_build (NULL, s, "z,s,t", sreg, treg);
4842 /* We want to close the noreorder block as soon as possible, so
4843 that later insns are available for delay slot filling. */
4844 --mips_opts.noreorder;
4845 macro_build (NULL, "break", "c", 7);
4847 macro_build (NULL, s2, "d", dreg);
4848 return;
4850 case M_DLCA_AB:
4851 dbl = 1;
4852 case M_LCA_AB:
4853 call = 1;
4854 goto do_la;
4855 case M_DLA_AB:
4856 dbl = 1;
4857 case M_LA_AB:
4858 do_la:
4859 /* Load the address of a symbol into a register. If breg is not
4860 zero, we then add a base register to it. */
4862 if (dbl && HAVE_32BIT_GPRS)
4863 as_warn (_("dla used to load 32-bit register"));
4865 if (! dbl && HAVE_64BIT_OBJECTS)
4866 as_warn (_("la used to load 64-bit address"));
4868 if (offset_expr.X_op == O_constant
4869 && offset_expr.X_add_number >= -0x8000
4870 && offset_expr.X_add_number < 0x8000)
4872 macro_build (&offset_expr,
4873 (dbl || HAVE_64BIT_ADDRESSES) ? "daddiu" : "addiu",
4874 "t,r,j", treg, sreg, BFD_RELOC_LO16);
4875 return;
4878 if (treg == breg)
4880 tempreg = AT;
4881 used_at = 1;
4883 else
4885 tempreg = treg;
4886 used_at = 0;
4889 if (offset_expr.X_op != O_symbol
4890 && offset_expr.X_op != O_constant)
4892 as_bad (_("expression too complex"));
4893 offset_expr.X_op = O_constant;
4896 if (offset_expr.X_op == O_constant)
4897 load_register (tempreg, &offset_expr,
4898 (mips_pic == NO_PIC
4899 ? (dbl || HAVE_64BIT_ADDRESSES)
4900 : HAVE_64BIT_ADDRESSES));
4901 else if (mips_pic == NO_PIC)
4903 /* If this is a reference to a GP relative symbol, we want
4904 addiu $tempreg,$gp,<sym> (BFD_RELOC_GPREL16)
4905 Otherwise we want
4906 lui $tempreg,<sym> (BFD_RELOC_HI16_S)
4907 addiu $tempreg,$tempreg,<sym> (BFD_RELOC_LO16)
4908 If we have a constant, we need two instructions anyhow,
4909 so we may as well always use the latter form.
4911 With 64bit address space and a usable $at we want
4912 lui $tempreg,<sym> (BFD_RELOC_MIPS_HIGHEST)
4913 lui $at,<sym> (BFD_RELOC_HI16_S)
4914 daddiu $tempreg,<sym> (BFD_RELOC_MIPS_HIGHER)
4915 daddiu $at,<sym> (BFD_RELOC_LO16)
4916 dsll32 $tempreg,0
4917 daddu $tempreg,$tempreg,$at
4919 If $at is already in use, we use a path which is suboptimal
4920 on superscalar processors.
4921 lui $tempreg,<sym> (BFD_RELOC_MIPS_HIGHEST)
4922 daddiu $tempreg,<sym> (BFD_RELOC_MIPS_HIGHER)
4923 dsll $tempreg,16
4924 daddiu $tempreg,<sym> (BFD_RELOC_HI16_S)
4925 dsll $tempreg,16
4926 daddiu $tempreg,<sym> (BFD_RELOC_LO16)
4928 if (HAVE_64BIT_ADDRESSES)
4930 /* ??? We don't provide a GP-relative alternative for
4931 these macros. It used not to be possible with the
4932 original relaxation code, but it could be done now. */
4934 if (used_at == 0 && ! mips_opts.noat)
4936 macro_build (&offset_expr, "lui", "t,u",
4937 tempreg, BFD_RELOC_MIPS_HIGHEST);
4938 macro_build (&offset_expr, "lui", "t,u",
4939 AT, BFD_RELOC_HI16_S);
4940 macro_build (&offset_expr, "daddiu", "t,r,j",
4941 tempreg, tempreg, BFD_RELOC_MIPS_HIGHER);
4942 macro_build (&offset_expr, "daddiu", "t,r,j",
4943 AT, AT, BFD_RELOC_LO16);
4944 macro_build (NULL, "dsll32", "d,w,<", tempreg, tempreg, 0);
4945 macro_build (NULL, "daddu", "d,v,t", tempreg, tempreg, AT);
4946 used_at = 1;
4948 else
4950 macro_build (&offset_expr, "lui", "t,u",
4951 tempreg, BFD_RELOC_MIPS_HIGHEST);
4952 macro_build (&offset_expr, "daddiu", "t,r,j",
4953 tempreg, tempreg, BFD_RELOC_MIPS_HIGHER);
4954 macro_build (NULL, "dsll", "d,w,<", tempreg, tempreg, 16);
4955 macro_build (&offset_expr, "daddiu", "t,r,j",
4956 tempreg, tempreg, BFD_RELOC_HI16_S);
4957 macro_build (NULL, "dsll", "d,w,<", tempreg, tempreg, 16);
4958 macro_build (&offset_expr, "daddiu", "t,r,j",
4959 tempreg, tempreg, BFD_RELOC_LO16);
4962 else
4964 if ((valueT) offset_expr.X_add_number <= MAX_GPREL_OFFSET
4965 && ! nopic_need_relax (offset_expr.X_add_symbol, 1))
4967 relax_start (offset_expr.X_add_symbol);
4968 macro_build (&offset_expr, ADDRESS_ADDI_INSN, "t,r,j",
4969 tempreg, mips_gp_register, BFD_RELOC_GPREL16);
4970 relax_switch ();
4972 macro_build_lui (&offset_expr, tempreg);
4973 macro_build (&offset_expr, ADDRESS_ADDI_INSN, "t,r,j",
4974 tempreg, tempreg, BFD_RELOC_LO16);
4975 if (mips_relax.sequence)
4976 relax_end ();
4979 else if (mips_pic == SVR4_PIC && ! mips_big_got && ! HAVE_NEWABI)
4981 int lw_reloc_type = (int) BFD_RELOC_MIPS_GOT16;
4983 /* If this is a reference to an external symbol, and there
4984 is no constant, we want
4985 lw $tempreg,<sym>($gp) (BFD_RELOC_MIPS_GOT16)
4986 or for lca or if tempreg is PIC_CALL_REG
4987 lw $tempreg,<sym>($gp) (BFD_RELOC_MIPS_CALL16)
4988 For a local symbol, we want
4989 lw $tempreg,<sym>($gp) (BFD_RELOC_MIPS_GOT16)
4991 addiu $tempreg,$tempreg,<sym> (BFD_RELOC_LO16)
4993 If we have a small constant, and this is a reference to
4994 an external symbol, we want
4995 lw $tempreg,<sym>($gp) (BFD_RELOC_MIPS_GOT16)
4997 addiu $tempreg,$tempreg,<constant>
4998 For a local symbol, we want the same instruction
4999 sequence, but we output a BFD_RELOC_LO16 reloc on the
5000 addiu instruction.
5002 If we have a large constant, and this is a reference to
5003 an external symbol, we want
5004 lw $tempreg,<sym>($gp) (BFD_RELOC_MIPS_GOT16)
5005 lui $at,<hiconstant>
5006 addiu $at,$at,<loconstant>
5007 addu $tempreg,$tempreg,$at
5008 For a local symbol, we want the same instruction
5009 sequence, but we output a BFD_RELOC_LO16 reloc on the
5010 addiu instruction.
5013 if (offset_expr.X_add_number == 0)
5015 if (breg == 0 && (call || tempreg == PIC_CALL_REG))
5016 lw_reloc_type = (int) BFD_RELOC_MIPS_CALL16;
5018 relax_start (offset_expr.X_add_symbol);
5019 macro_build (&offset_expr, ADDRESS_LOAD_INSN, "t,o(b)", tempreg,
5020 lw_reloc_type, mips_gp_register);
5021 if (breg != 0)
5023 /* We're going to put in an addu instruction using
5024 tempreg, so we may as well insert the nop right
5025 now. */
5026 load_delay_nop ();
5028 relax_switch ();
5029 macro_build (&offset_expr, ADDRESS_LOAD_INSN, "t,o(b)",
5030 tempreg, BFD_RELOC_MIPS_GOT16, mips_gp_register);
5031 load_delay_nop ();
5032 macro_build (&offset_expr, ADDRESS_ADDI_INSN, "t,r,j",
5033 tempreg, tempreg, BFD_RELOC_LO16);
5034 relax_end ();
5035 /* FIXME: If breg == 0, and the next instruction uses
5036 $tempreg, then if this variant case is used an extra
5037 nop will be generated. */
5039 else if (offset_expr.X_add_number >= -0x8000
5040 && offset_expr.X_add_number < 0x8000)
5042 load_got_offset (tempreg, &offset_expr);
5043 load_delay_nop ();
5044 add_got_offset (tempreg, &offset_expr);
5046 else
5048 expr1.X_add_number = offset_expr.X_add_number;
5049 offset_expr.X_add_number =
5050 ((offset_expr.X_add_number + 0x8000) & 0xffff) - 0x8000;
5051 load_got_offset (tempreg, &offset_expr);
5052 offset_expr.X_add_number = expr1.X_add_number;
5053 /* If we are going to add in a base register, and the
5054 target register and the base register are the same,
5055 then we are using AT as a temporary register. Since
5056 we want to load the constant into AT, we add our
5057 current AT (from the global offset table) and the
5058 register into the register now, and pretend we were
5059 not using a base register. */
5060 if (breg == treg)
5062 load_delay_nop ();
5063 macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t",
5064 treg, AT, breg);
5065 breg = 0;
5066 tempreg = treg;
5068 add_got_offset_hilo (tempreg, &offset_expr, AT);
5069 used_at = 1;
5072 else if (mips_pic == SVR4_PIC && ! mips_big_got && HAVE_NEWABI)
5074 int add_breg_early = 0;
5076 /* If this is a reference to an external, and there is no
5077 constant, or local symbol (*), with or without a
5078 constant, we want
5079 lw $tempreg,<sym>($gp) (BFD_RELOC_MIPS_GOT_DISP)
5080 or for lca or if tempreg is PIC_CALL_REG
5081 lw $tempreg,<sym>($gp) (BFD_RELOC_MIPS_CALL16)
5083 If we have a small constant, and this is a reference to
5084 an external symbol, we want
5085 lw $tempreg,<sym>($gp) (BFD_RELOC_MIPS_GOT_DISP)
5086 addiu $tempreg,$tempreg,<constant>
5088 If we have a large constant, and this is a reference to
5089 an external symbol, we want
5090 lw $tempreg,<sym>($gp) (BFD_RELOC_MIPS_GOT_DISP)
5091 lui $at,<hiconstant>
5092 addiu $at,$at,<loconstant>
5093 addu $tempreg,$tempreg,$at
5095 (*) Other assemblers seem to prefer GOT_PAGE/GOT_OFST for
5096 local symbols, even though it introduces an additional
5097 instruction. */
5099 if (offset_expr.X_add_number)
5101 expr1.X_add_number = offset_expr.X_add_number;
5102 offset_expr.X_add_number = 0;
5104 relax_start (offset_expr.X_add_symbol);
5105 macro_build (&offset_expr, ADDRESS_LOAD_INSN, "t,o(b)", tempreg,
5106 BFD_RELOC_MIPS_GOT_DISP, mips_gp_register);
5108 if (expr1.X_add_number >= -0x8000
5109 && expr1.X_add_number < 0x8000)
5111 macro_build (&expr1, ADDRESS_ADDI_INSN, "t,r,j",
5112 tempreg, tempreg, BFD_RELOC_LO16);
5114 else if (IS_SEXT_32BIT_NUM (expr1.X_add_number + 0x8000))
5116 int dreg;
5118 /* If we are going to add in a base register, and the
5119 target register and the base register are the same,
5120 then we are using AT as a temporary register. Since
5121 we want to load the constant into AT, we add our
5122 current AT (from the global offset table) and the
5123 register into the register now, and pretend we were
5124 not using a base register. */
5125 if (breg != treg)
5126 dreg = tempreg;
5127 else
5129 assert (tempreg == AT);
5130 macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t",
5131 treg, AT, breg);
5132 dreg = treg;
5133 add_breg_early = 1;
5136 load_register (AT, &expr1, HAVE_64BIT_ADDRESSES);
5137 macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t",
5138 dreg, dreg, AT);
5140 used_at = 1;
5142 else
5143 as_bad (_("PIC code offset overflow (max 32 signed bits)"));
5145 relax_switch ();
5146 offset_expr.X_add_number = expr1.X_add_number;
5148 macro_build (&offset_expr, ADDRESS_LOAD_INSN, "t,o(b)", tempreg,
5149 BFD_RELOC_MIPS_GOT_DISP, mips_gp_register);
5150 if (add_breg_early)
5152 macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t",
5153 treg, tempreg, breg);
5154 breg = 0;
5155 tempreg = treg;
5157 relax_end ();
5159 else if (breg == 0 && (call || tempreg == PIC_CALL_REG))
5161 relax_start (offset_expr.X_add_symbol);
5162 macro_build (&offset_expr, ADDRESS_LOAD_INSN, "t,o(b)", tempreg,
5163 BFD_RELOC_MIPS_CALL16, mips_gp_register);
5164 relax_switch ();
5165 macro_build (&offset_expr, ADDRESS_LOAD_INSN, "t,o(b)", tempreg,
5166 BFD_RELOC_MIPS_GOT_DISP, mips_gp_register);
5167 relax_end ();
5169 else
5171 macro_build (&offset_expr, ADDRESS_LOAD_INSN, "t,o(b)", tempreg,
5172 BFD_RELOC_MIPS_GOT_DISP, mips_gp_register);
5175 else if (mips_pic == SVR4_PIC && ! HAVE_NEWABI)
5177 int gpdelay;
5178 int lui_reloc_type = (int) BFD_RELOC_MIPS_GOT_HI16;
5179 int lw_reloc_type = (int) BFD_RELOC_MIPS_GOT_LO16;
5180 int local_reloc_type = (int) BFD_RELOC_MIPS_GOT16;
5182 /* This is the large GOT case. If this is a reference to an
5183 external symbol, and there is no constant, we want
5184 lui $tempreg,<sym> (BFD_RELOC_MIPS_GOT_HI16)
5185 addu $tempreg,$tempreg,$gp
5186 lw $tempreg,<sym>($tempreg) (BFD_RELOC_MIPS_GOT_LO16)
5187 or for lca or if tempreg is PIC_CALL_REG
5188 lui $tempreg,<sym> (BFD_RELOC_MIPS_CALL_HI16)
5189 addu $tempreg,$tempreg,$gp
5190 lw $tempreg,<sym>($tempreg) (BFD_RELOC_MIPS_CALL_LO16)
5191 For a local symbol, we want
5192 lw $tempreg,<sym>($gp) (BFD_RELOC_MIPS_GOT16)
5194 addiu $tempreg,$tempreg,<sym> (BFD_RELOC_LO16)
5196 If we have a small constant, and this is a reference to
5197 an external symbol, we want
5198 lui $tempreg,<sym> (BFD_RELOC_MIPS_GOT_HI16)
5199 addu $tempreg,$tempreg,$gp
5200 lw $tempreg,<sym>($tempreg) (BFD_RELOC_MIPS_GOT_LO16)
5202 addiu $tempreg,$tempreg,<constant>
5203 For a local symbol, we want
5204 lw $tempreg,<sym>($gp) (BFD_RELOC_MIPS_GOT16)
5206 addiu $tempreg,$tempreg,<constant> (BFD_RELOC_LO16)
5208 If we have a large constant, and this is a reference to
5209 an external symbol, we want
5210 lui $tempreg,<sym> (BFD_RELOC_MIPS_GOT_HI16)
5211 addu $tempreg,$tempreg,$gp
5212 lw $tempreg,<sym>($tempreg) (BFD_RELOC_MIPS_GOT_LO16)
5213 lui $at,<hiconstant>
5214 addiu $at,$at,<loconstant>
5215 addu $tempreg,$tempreg,$at
5216 For a local symbol, we want
5217 lw $tempreg,<sym>($gp) (BFD_RELOC_MIPS_GOT16)
5218 lui $at,<hiconstant>
5219 addiu $at,$at,<loconstant> (BFD_RELOC_LO16)
5220 addu $tempreg,$tempreg,$at
5223 expr1.X_add_number = offset_expr.X_add_number;
5224 offset_expr.X_add_number = 0;
5225 relax_start (offset_expr.X_add_symbol);
5226 gpdelay = reg_needs_delay (mips_gp_register);
5227 if (expr1.X_add_number == 0 && breg == 0
5228 && (call || tempreg == PIC_CALL_REG))
5230 lui_reloc_type = (int) BFD_RELOC_MIPS_CALL_HI16;
5231 lw_reloc_type = (int) BFD_RELOC_MIPS_CALL_LO16;
5233 macro_build (&offset_expr, "lui", "t,u", tempreg, lui_reloc_type);
5234 macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t",
5235 tempreg, tempreg, mips_gp_register);
5236 macro_build (&offset_expr, ADDRESS_LOAD_INSN, "t,o(b)",
5237 tempreg, lw_reloc_type, tempreg);
5238 if (expr1.X_add_number == 0)
5240 if (breg != 0)
5242 /* We're going to put in an addu instruction using
5243 tempreg, so we may as well insert the nop right
5244 now. */
5245 load_delay_nop ();
5248 else if (expr1.X_add_number >= -0x8000
5249 && expr1.X_add_number < 0x8000)
5251 load_delay_nop ();
5252 macro_build (&expr1, ADDRESS_ADDI_INSN, "t,r,j",
5253 tempreg, tempreg, BFD_RELOC_LO16);
5255 else
5257 int dreg;
5259 /* If we are going to add in a base register, and the
5260 target register and the base register are the same,
5261 then we are using AT as a temporary register. Since
5262 we want to load the constant into AT, we add our
5263 current AT (from the global offset table) and the
5264 register into the register now, and pretend we were
5265 not using a base register. */
5266 if (breg != treg)
5267 dreg = tempreg;
5268 else
5270 assert (tempreg == AT);
5271 load_delay_nop ();
5272 macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t",
5273 treg, AT, breg);
5274 dreg = treg;
5277 load_register (AT, &expr1, HAVE_64BIT_ADDRESSES);
5278 macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t", dreg, dreg, AT);
5280 used_at = 1;
5282 offset_expr.X_add_number =
5283 ((expr1.X_add_number + 0x8000) & 0xffff) - 0x8000;
5284 relax_switch ();
5286 if (gpdelay)
5288 /* This is needed because this instruction uses $gp, but
5289 the first instruction on the main stream does not. */
5290 macro_build (NULL, "nop", "");
5293 macro_build (&offset_expr, ADDRESS_LOAD_INSN, "t,o(b)", tempreg,
5294 local_reloc_type, mips_gp_register);
5295 if (expr1.X_add_number >= -0x8000
5296 && expr1.X_add_number < 0x8000)
5298 load_delay_nop ();
5299 macro_build (&offset_expr, ADDRESS_ADDI_INSN, "t,r,j",
5300 tempreg, tempreg, BFD_RELOC_LO16);
5301 /* FIXME: If add_number is 0, and there was no base
5302 register, the external symbol case ended with a load,
5303 so if the symbol turns out to not be external, and
5304 the next instruction uses tempreg, an unnecessary nop
5305 will be inserted. */
5307 else
5309 if (breg == treg)
5311 /* We must add in the base register now, as in the
5312 external symbol case. */
5313 assert (tempreg == AT);
5314 load_delay_nop ();
5315 macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t",
5316 treg, AT, breg);
5317 tempreg = treg;
5318 /* We set breg to 0 because we have arranged to add
5319 it in in both cases. */
5320 breg = 0;
5323 macro_build_lui (&expr1, AT);
5324 macro_build (&offset_expr, ADDRESS_ADDI_INSN, "t,r,j",
5325 AT, AT, BFD_RELOC_LO16);
5326 macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t",
5327 tempreg, tempreg, AT);
5329 relax_end ();
5331 else if (mips_pic == SVR4_PIC && HAVE_NEWABI)
5333 int lui_reloc_type = (int) BFD_RELOC_MIPS_GOT_HI16;
5334 int lw_reloc_type = (int) BFD_RELOC_MIPS_GOT_LO16;
5335 int add_breg_early = 0;
5337 /* This is the large GOT case. If this is a reference to an
5338 external symbol, and there is no constant, we want
5339 lui $tempreg,<sym> (BFD_RELOC_MIPS_GOT_HI16)
5340 add $tempreg,$tempreg,$gp
5341 lw $tempreg,<sym>($tempreg) (BFD_RELOC_MIPS_GOT_LO16)
5342 or for lca or if tempreg is PIC_CALL_REG
5343 lui $tempreg,<sym> (BFD_RELOC_MIPS_CALL_HI16)
5344 add $tempreg,$tempreg,$gp
5345 lw $tempreg,<sym>($tempreg) (BFD_RELOC_MIPS_CALL_LO16)
5347 If we have a small constant, and this is a reference to
5348 an external symbol, we want
5349 lui $tempreg,<sym> (BFD_RELOC_MIPS_GOT_HI16)
5350 add $tempreg,$tempreg,$gp
5351 lw $tempreg,<sym>($tempreg) (BFD_RELOC_MIPS_GOT_LO16)
5352 addi $tempreg,$tempreg,<constant>
5354 If we have a large constant, and this is a reference to
5355 an external symbol, we want
5356 lui $tempreg,<sym> (BFD_RELOC_MIPS_GOT_HI16)
5357 addu $tempreg,$tempreg,$gp
5358 lw $tempreg,<sym>($tempreg) (BFD_RELOC_MIPS_GOT_LO16)
5359 lui $at,<hiconstant>
5360 addi $at,$at,<loconstant>
5361 add $tempreg,$tempreg,$at
5363 If we have NewABI, and we know it's a local symbol, we want
5364 lw $reg,<sym>($gp) (BFD_RELOC_MIPS_GOT_PAGE)
5365 addiu $reg,$reg,<sym> (BFD_RELOC_MIPS_GOT_OFST)
5366 otherwise we have to resort to GOT_HI16/GOT_LO16. */
5368 relax_start (offset_expr.X_add_symbol);
5370 expr1.X_add_number = offset_expr.X_add_number;
5371 offset_expr.X_add_number = 0;
5373 if (expr1.X_add_number == 0 && breg == 0
5374 && (call || tempreg == PIC_CALL_REG))
5376 lui_reloc_type = (int) BFD_RELOC_MIPS_CALL_HI16;
5377 lw_reloc_type = (int) BFD_RELOC_MIPS_CALL_LO16;
5379 macro_build (&offset_expr, "lui", "t,u", tempreg, lui_reloc_type);
5380 macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t",
5381 tempreg, tempreg, mips_gp_register);
5382 macro_build (&offset_expr, ADDRESS_LOAD_INSN, "t,o(b)",
5383 tempreg, lw_reloc_type, tempreg);
5385 if (expr1.X_add_number == 0)
5387 else if (expr1.X_add_number >= -0x8000
5388 && expr1.X_add_number < 0x8000)
5390 macro_build (&expr1, ADDRESS_ADDI_INSN, "t,r,j",
5391 tempreg, tempreg, BFD_RELOC_LO16);
5393 else if (IS_SEXT_32BIT_NUM (expr1.X_add_number + 0x8000))
5395 int dreg;
5397 /* If we are going to add in a base register, and the
5398 target register and the base register are the same,
5399 then we are using AT as a temporary register. Since
5400 we want to load the constant into AT, we add our
5401 current AT (from the global offset table) and the
5402 register into the register now, and pretend we were
5403 not using a base register. */
5404 if (breg != treg)
5405 dreg = tempreg;
5406 else
5408 assert (tempreg == AT);
5409 macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t",
5410 treg, AT, breg);
5411 dreg = treg;
5412 add_breg_early = 1;
5415 load_register (AT, &expr1, HAVE_64BIT_ADDRESSES);
5416 macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t", dreg, dreg, AT);
5418 used_at = 1;
5420 else
5421 as_bad (_("PIC code offset overflow (max 32 signed bits)"));
5423 relax_switch ();
5424 offset_expr.X_add_number = expr1.X_add_number;
5425 macro_build (&offset_expr, ADDRESS_LOAD_INSN, "t,o(b)", tempreg,
5426 BFD_RELOC_MIPS_GOT_PAGE, mips_gp_register);
5427 macro_build (&offset_expr, ADDRESS_ADDI_INSN, "t,r,j", tempreg,
5428 tempreg, BFD_RELOC_MIPS_GOT_OFST);
5429 if (add_breg_early)
5431 macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t",
5432 treg, tempreg, breg);
5433 breg = 0;
5434 tempreg = treg;
5436 relax_end ();
5438 else
5439 abort ();
5441 if (breg != 0)
5443 char *s;
5445 if (mips_pic == NO_PIC)
5446 s = (dbl || HAVE_64BIT_ADDRESSES) ? "daddu" : "addu";
5447 else
5448 s = ADDRESS_ADD_INSN;
5450 macro_build (NULL, s, "d,v,t", treg, tempreg, breg);
5453 if (! used_at)
5454 return;
5456 break;
5458 case M_J_A:
5459 /* The j instruction may not be used in PIC code, since it
5460 requires an absolute address. We convert it to a b
5461 instruction. */
5462 if (mips_pic == NO_PIC)
5463 macro_build (&offset_expr, "j", "a");
5464 else
5465 macro_build (&offset_expr, "b", "p");
5466 return;
5468 /* The jal instructions must be handled as macros because when
5469 generating PIC code they expand to multi-instruction
5470 sequences. Normally they are simple instructions. */
5471 case M_JAL_1:
5472 dreg = RA;
5473 /* Fall through. */
5474 case M_JAL_2:
5475 if (mips_pic == NO_PIC)
5476 macro_build (NULL, "jalr", "d,s", dreg, sreg);
5477 else if (mips_pic == SVR4_PIC)
5479 if (sreg != PIC_CALL_REG)
5480 as_warn (_("MIPS PIC call to register other than $25"));
5482 macro_build (NULL, "jalr", "d,s", dreg, sreg);
5483 if (! HAVE_NEWABI)
5485 if (mips_cprestore_offset < 0)
5486 as_warn (_("No .cprestore pseudo-op used in PIC code"));
5487 else
5489 if (! mips_frame_reg_valid)
5491 as_warn (_("No .frame pseudo-op used in PIC code"));
5492 /* Quiet this warning. */
5493 mips_frame_reg_valid = 1;
5495 if (! mips_cprestore_valid)
5497 as_warn (_("No .cprestore pseudo-op used in PIC code"));
5498 /* Quiet this warning. */
5499 mips_cprestore_valid = 1;
5501 expr1.X_add_number = mips_cprestore_offset;
5502 macro_build_ldst_constoffset (&expr1, ADDRESS_LOAD_INSN,
5503 mips_gp_register,
5504 mips_frame_reg,
5505 HAVE_64BIT_ADDRESSES);
5509 else
5510 abort ();
5512 return;
5514 case M_JAL_A:
5515 if (mips_pic == NO_PIC)
5516 macro_build (&offset_expr, "jal", "a");
5517 else if (mips_pic == SVR4_PIC)
5519 /* If this is a reference to an external symbol, and we are
5520 using a small GOT, we want
5521 lw $25,<sym>($gp) (BFD_RELOC_MIPS_CALL16)
5523 jalr $ra,$25
5525 lw $gp,cprestore($sp)
5526 The cprestore value is set using the .cprestore
5527 pseudo-op. If we are using a big GOT, we want
5528 lui $25,<sym> (BFD_RELOC_MIPS_CALL_HI16)
5529 addu $25,$25,$gp
5530 lw $25,<sym>($25) (BFD_RELOC_MIPS_CALL_LO16)
5532 jalr $ra,$25
5534 lw $gp,cprestore($sp)
5535 If the symbol is not external, we want
5536 lw $25,<sym>($gp) (BFD_RELOC_MIPS_GOT16)
5538 addiu $25,$25,<sym> (BFD_RELOC_LO16)
5539 jalr $ra,$25
5541 lw $gp,cprestore($sp)
5543 For NewABI, we use the same CALL16 or CALL_HI16/CALL_LO16
5544 sequences above, minus nops, unless the symbol is local,
5545 which enables us to use GOT_PAGE/GOT_OFST (big got) or
5546 GOT_DISP. */
5547 if (HAVE_NEWABI)
5549 if (! mips_big_got)
5551 relax_start (offset_expr.X_add_symbol);
5552 macro_build (&offset_expr, ADDRESS_LOAD_INSN, "t,o(b)",
5553 PIC_CALL_REG, BFD_RELOC_MIPS_CALL16,
5554 mips_gp_register);
5555 relax_switch ();
5556 macro_build (&offset_expr, ADDRESS_LOAD_INSN, "t,o(b)",
5557 PIC_CALL_REG, BFD_RELOC_MIPS_GOT_DISP,
5558 mips_gp_register);
5559 relax_end ();
5561 else
5563 relax_start (offset_expr.X_add_symbol);
5564 macro_build (&offset_expr, "lui", "t,u", PIC_CALL_REG,
5565 BFD_RELOC_MIPS_CALL_HI16);
5566 macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t", PIC_CALL_REG,
5567 PIC_CALL_REG, mips_gp_register);
5568 macro_build (&offset_expr, ADDRESS_LOAD_INSN, "t,o(b)",
5569 PIC_CALL_REG, BFD_RELOC_MIPS_CALL_LO16,
5570 PIC_CALL_REG);
5571 relax_switch ();
5572 macro_build (&offset_expr, ADDRESS_LOAD_INSN, "t,o(b)",
5573 PIC_CALL_REG, BFD_RELOC_MIPS_GOT_PAGE,
5574 mips_gp_register);
5575 macro_build (&offset_expr, ADDRESS_ADDI_INSN, "t,r,j",
5576 PIC_CALL_REG, PIC_CALL_REG,
5577 BFD_RELOC_MIPS_GOT_OFST);
5578 relax_end ();
5581 macro_build_jalr (&offset_expr);
5583 else
5585 relax_start (offset_expr.X_add_symbol);
5586 if (! mips_big_got)
5588 macro_build (&offset_expr, ADDRESS_LOAD_INSN, "t,o(b)",
5589 PIC_CALL_REG, BFD_RELOC_MIPS_CALL16,
5590 mips_gp_register);
5591 load_delay_nop ();
5592 relax_switch ();
5594 else
5596 int gpdelay;
5598 gpdelay = reg_needs_delay (mips_gp_register);
5599 macro_build (&offset_expr, "lui", "t,u", PIC_CALL_REG,
5600 BFD_RELOC_MIPS_CALL_HI16);
5601 macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t", PIC_CALL_REG,
5602 PIC_CALL_REG, mips_gp_register);
5603 macro_build (&offset_expr, ADDRESS_LOAD_INSN, "t,o(b)",
5604 PIC_CALL_REG, BFD_RELOC_MIPS_CALL_LO16,
5605 PIC_CALL_REG);
5606 load_delay_nop ();
5607 relax_switch ();
5608 if (gpdelay)
5609 macro_build (NULL, "nop", "");
5611 macro_build (&offset_expr, ADDRESS_LOAD_INSN, "t,o(b)",
5612 PIC_CALL_REG, BFD_RELOC_MIPS_GOT16,
5613 mips_gp_register);
5614 load_delay_nop ();
5615 macro_build (&offset_expr, ADDRESS_ADDI_INSN, "t,r,j",
5616 PIC_CALL_REG, PIC_CALL_REG, BFD_RELOC_LO16);
5617 relax_end ();
5618 macro_build_jalr (&offset_expr);
5620 if (mips_cprestore_offset < 0)
5621 as_warn (_("No .cprestore pseudo-op used in PIC code"));
5622 else
5624 if (! mips_frame_reg_valid)
5626 as_warn (_("No .frame pseudo-op used in PIC code"));
5627 /* Quiet this warning. */
5628 mips_frame_reg_valid = 1;
5630 if (! mips_cprestore_valid)
5632 as_warn (_("No .cprestore pseudo-op used in PIC code"));
5633 /* Quiet this warning. */
5634 mips_cprestore_valid = 1;
5636 if (mips_opts.noreorder)
5637 macro_build (NULL, "nop", "");
5638 expr1.X_add_number = mips_cprestore_offset;
5639 macro_build_ldst_constoffset (&expr1, ADDRESS_LOAD_INSN,
5640 mips_gp_register,
5641 mips_frame_reg,
5642 HAVE_64BIT_ADDRESSES);
5646 else
5647 abort ();
5649 return;
5651 case M_LB_AB:
5652 s = "lb";
5653 goto ld;
5654 case M_LBU_AB:
5655 s = "lbu";
5656 goto ld;
5657 case M_LH_AB:
5658 s = "lh";
5659 goto ld;
5660 case M_LHU_AB:
5661 s = "lhu";
5662 goto ld;
5663 case M_LW_AB:
5664 s = "lw";
5665 goto ld;
5666 case M_LWC0_AB:
5667 s = "lwc0";
5668 /* Itbl support may require additional care here. */
5669 coproc = 1;
5670 goto ld;
5671 case M_LWC1_AB:
5672 s = "lwc1";
5673 /* Itbl support may require additional care here. */
5674 coproc = 1;
5675 goto ld;
5676 case M_LWC2_AB:
5677 s = "lwc2";
5678 /* Itbl support may require additional care here. */
5679 coproc = 1;
5680 goto ld;
5681 case M_LWC3_AB:
5682 s = "lwc3";
5683 /* Itbl support may require additional care here. */
5684 coproc = 1;
5685 goto ld;
5686 case M_LWL_AB:
5687 s = "lwl";
5688 lr = 1;
5689 goto ld;
5690 case M_LWR_AB:
5691 s = "lwr";
5692 lr = 1;
5693 goto ld;
5694 case M_LDC1_AB:
5695 if (mips_opts.arch == CPU_R4650)
5697 as_bad (_("opcode not supported on this processor"));
5698 return;
5700 s = "ldc1";
5701 /* Itbl support may require additional care here. */
5702 coproc = 1;
5703 goto ld;
5704 case M_LDC2_AB:
5705 s = "ldc2";
5706 /* Itbl support may require additional care here. */
5707 coproc = 1;
5708 goto ld;
5709 case M_LDC3_AB:
5710 s = "ldc3";
5711 /* Itbl support may require additional care here. */
5712 coproc = 1;
5713 goto ld;
5714 case M_LDL_AB:
5715 s = "ldl";
5716 lr = 1;
5717 goto ld;
5718 case M_LDR_AB:
5719 s = "ldr";
5720 lr = 1;
5721 goto ld;
5722 case M_LL_AB:
5723 s = "ll";
5724 goto ld;
5725 case M_LLD_AB:
5726 s = "lld";
5727 goto ld;
5728 case M_LWU_AB:
5729 s = "lwu";
5731 if (breg == treg || coproc || lr)
5733 tempreg = AT;
5734 used_at = 1;
5736 else
5738 tempreg = treg;
5739 used_at = 0;
5741 goto ld_st;
5742 case M_SB_AB:
5743 s = "sb";
5744 goto st;
5745 case M_SH_AB:
5746 s = "sh";
5747 goto st;
5748 case M_SW_AB:
5749 s = "sw";
5750 goto st;
5751 case M_SWC0_AB:
5752 s = "swc0";
5753 /* Itbl support may require additional care here. */
5754 coproc = 1;
5755 goto st;
5756 case M_SWC1_AB:
5757 s = "swc1";
5758 /* Itbl support may require additional care here. */
5759 coproc = 1;
5760 goto st;
5761 case M_SWC2_AB:
5762 s = "swc2";
5763 /* Itbl support may require additional care here. */
5764 coproc = 1;
5765 goto st;
5766 case M_SWC3_AB:
5767 s = "swc3";
5768 /* Itbl support may require additional care here. */
5769 coproc = 1;
5770 goto st;
5771 case M_SWL_AB:
5772 s = "swl";
5773 goto st;
5774 case M_SWR_AB:
5775 s = "swr";
5776 goto st;
5777 case M_SC_AB:
5778 s = "sc";
5779 goto st;
5780 case M_SCD_AB:
5781 s = "scd";
5782 goto st;
5783 case M_SDC1_AB:
5784 if (mips_opts.arch == CPU_R4650)
5786 as_bad (_("opcode not supported on this processor"));
5787 return;
5789 s = "sdc1";
5790 coproc = 1;
5791 /* Itbl support may require additional care here. */
5792 goto st;
5793 case M_SDC2_AB:
5794 s = "sdc2";
5795 /* Itbl support may require additional care here. */
5796 coproc = 1;
5797 goto st;
5798 case M_SDC3_AB:
5799 s = "sdc3";
5800 /* Itbl support may require additional care here. */
5801 coproc = 1;
5802 goto st;
5803 case M_SDL_AB:
5804 s = "sdl";
5805 goto st;
5806 case M_SDR_AB:
5807 s = "sdr";
5809 tempreg = AT;
5810 used_at = 1;
5811 ld_st:
5812 /* Itbl support may require additional care here. */
5813 if (mask == M_LWC1_AB
5814 || mask == M_SWC1_AB
5815 || mask == M_LDC1_AB
5816 || mask == M_SDC1_AB
5817 || mask == M_L_DAB
5818 || mask == M_S_DAB)
5819 fmt = "T,o(b)";
5820 else if (coproc)
5821 fmt = "E,o(b)";
5822 else
5823 fmt = "t,o(b)";
5825 /* Sign-extending 32-bit constants makes their handling easier.
5826 The HAVE_64BIT_GPRS... part is due to the linux kernel hack
5827 described below. */
5828 if ((! HAVE_64BIT_ADDRESSES
5829 && (! HAVE_64BIT_GPRS && offset_expr.X_op == O_constant))
5830 && (offset_expr.X_op == O_constant)
5831 && ! ((offset_expr.X_add_number & ~((bfd_vma) 0x7fffffff))
5832 == ~((bfd_vma) 0x7fffffff)))
5834 if (offset_expr.X_add_number & ~((bfd_vma) 0xffffffff))
5835 as_bad (_("constant too large"));
5837 offset_expr.X_add_number = (((offset_expr.X_add_number & 0xffffffff)
5838 ^ 0x80000000) - 0x80000000);
5841 if (offset_expr.X_op != O_constant
5842 && offset_expr.X_op != O_symbol)
5844 as_bad (_("expression too complex"));
5845 offset_expr.X_op = O_constant;
5848 /* A constant expression in PIC code can be handled just as it
5849 is in non PIC code. */
5850 if (mips_pic == NO_PIC
5851 || offset_expr.X_op == O_constant)
5853 /* If this is a reference to a GP relative symbol, and there
5854 is no base register, we want
5855 <op> $treg,<sym>($gp) (BFD_RELOC_GPREL16)
5856 Otherwise, if there is no base register, we want
5857 lui $tempreg,<sym> (BFD_RELOC_HI16_S)
5858 <op> $treg,<sym>($tempreg) (BFD_RELOC_LO16)
5859 If we have a constant, we need two instructions anyhow,
5860 so we always use the latter form.
5862 If we have a base register, and this is a reference to a
5863 GP relative symbol, we want
5864 addu $tempreg,$breg,$gp
5865 <op> $treg,<sym>($tempreg) (BFD_RELOC_GPREL16)
5866 Otherwise we want
5867 lui $tempreg,<sym> (BFD_RELOC_HI16_S)
5868 addu $tempreg,$tempreg,$breg
5869 <op> $treg,<sym>($tempreg) (BFD_RELOC_LO16)
5870 With a constant we always use the latter case.
5872 With 64bit address space and no base register and $at usable,
5873 we want
5874 lui $tempreg,<sym> (BFD_RELOC_MIPS_HIGHEST)
5875 lui $at,<sym> (BFD_RELOC_HI16_S)
5876 daddiu $tempreg,<sym> (BFD_RELOC_MIPS_HIGHER)
5877 dsll32 $tempreg,0
5878 daddu $tempreg,$at
5879 <op> $treg,<sym>($tempreg) (BFD_RELOC_LO16)
5880 If we have a base register, we want
5881 lui $tempreg,<sym> (BFD_RELOC_MIPS_HIGHEST)
5882 lui $at,<sym> (BFD_RELOC_HI16_S)
5883 daddiu $tempreg,<sym> (BFD_RELOC_MIPS_HIGHER)
5884 daddu $at,$breg
5885 dsll32 $tempreg,0
5886 daddu $tempreg,$at
5887 <op> $treg,<sym>($tempreg) (BFD_RELOC_LO16)
5889 Without $at we can't generate the optimal path for superscalar
5890 processors here since this would require two temporary registers.
5891 lui $tempreg,<sym> (BFD_RELOC_MIPS_HIGHEST)
5892 daddiu $tempreg,<sym> (BFD_RELOC_MIPS_HIGHER)
5893 dsll $tempreg,16
5894 daddiu $tempreg,<sym> (BFD_RELOC_HI16_S)
5895 dsll $tempreg,16
5896 <op> $treg,<sym>($tempreg) (BFD_RELOC_LO16)
5897 If we have a base register, we want
5898 lui $tempreg,<sym> (BFD_RELOC_MIPS_HIGHEST)
5899 daddiu $tempreg,<sym> (BFD_RELOC_MIPS_HIGHER)
5900 dsll $tempreg,16
5901 daddiu $tempreg,<sym> (BFD_RELOC_HI16_S)
5902 dsll $tempreg,16
5903 daddu $tempreg,$tempreg,$breg
5904 <op> $treg,<sym>($tempreg) (BFD_RELOC_LO16)
5906 If we have 64-bit addresses, as an optimization, for
5907 addresses which are 32-bit constants (e.g. kseg0/kseg1
5908 addresses) we fall back to the 32-bit address generation
5909 mechanism since it is more efficient. Note that due to
5910 the signed offset used by memory operations, the 32-bit
5911 range is shifted down by 32768 here. This code should
5912 probably attempt to generate 64-bit constants more
5913 efficiently in general.
5915 As an extension for architectures with 64-bit registers,
5916 we don't truncate 64-bit addresses given as literal
5917 constants down to 32 bits, to support existing practice
5918 in the mips64 Linux (the kernel), that compiles source
5919 files with -mabi=64, assembling them as o32 or n32 (with
5920 -Wa,-32 or -Wa,-n32). This is not beautiful, but since
5921 the whole kernel is loaded into a memory region that is
5922 addressable with sign-extended 32-bit addresses, it is
5923 wasteful to compute the upper 32 bits of every
5924 non-literal address, that takes more space and time.
5925 Some day this should probably be implemented as an
5926 assembler option, such that the kernel doesn't have to
5927 use such ugly hacks, even though it will still have to
5928 end up converting the binary to ELF32 for a number of
5929 platforms whose boot loaders don't support ELF64
5930 binaries. */
5931 if ((HAVE_64BIT_ADDRESSES
5932 && ! (offset_expr.X_op == O_constant
5933 && IS_SEXT_32BIT_NUM (offset_expr.X_add_number + 0x8000)))
5934 || (HAVE_64BIT_GPRS
5935 && offset_expr.X_op == O_constant
5936 && ! IS_SEXT_32BIT_NUM (offset_expr.X_add_number + 0x8000)))
5938 /* ??? We don't provide a GP-relative alternative for
5939 these macros. It used not to be possible with the
5940 original relaxation code, but it could be done now. */
5942 if (used_at == 0 && ! mips_opts.noat)
5944 macro_build (&offset_expr, "lui", "t,u", tempreg,
5945 BFD_RELOC_MIPS_HIGHEST);
5946 macro_build (&offset_expr, "lui", "t,u", AT,
5947 BFD_RELOC_HI16_S);
5948 macro_build (&offset_expr, "daddiu", "t,r,j", tempreg,
5949 tempreg, BFD_RELOC_MIPS_HIGHER);
5950 if (breg != 0)
5951 macro_build (NULL, "daddu", "d,v,t", AT, AT, breg);
5952 macro_build (NULL, "dsll32", "d,w,<", tempreg, tempreg, 0);
5953 macro_build (NULL, "daddu", "d,v,t", tempreg, tempreg, AT);
5954 macro_build (&offset_expr, s, fmt, treg, BFD_RELOC_LO16,
5955 tempreg);
5956 used_at = 1;
5958 else
5960 macro_build (&offset_expr, "lui", "t,u", tempreg,
5961 BFD_RELOC_MIPS_HIGHEST);
5962 macro_build (&offset_expr, "daddiu", "t,r,j", tempreg,
5963 tempreg, BFD_RELOC_MIPS_HIGHER);
5964 macro_build (NULL, "dsll", "d,w,<", tempreg, tempreg, 16);
5965 macro_build (&offset_expr, "daddiu", "t,r,j", tempreg,
5966 tempreg, BFD_RELOC_HI16_S);
5967 macro_build (NULL, "dsll", "d,w,<", tempreg, tempreg, 16);
5968 if (breg != 0)
5969 macro_build (NULL, "daddu", "d,v,t",
5970 tempreg, tempreg, breg);
5971 macro_build (&offset_expr, s, fmt, treg,
5972 BFD_RELOC_LO16, tempreg);
5975 return;
5978 if (offset_expr.X_op == O_constant
5979 && ! IS_SEXT_32BIT_NUM (offset_expr.X_add_number + 0x8000))
5980 as_bad (_("load/store address overflow (max 32 bits)"));
5982 if (breg == 0)
5984 if ((valueT) offset_expr.X_add_number <= MAX_GPREL_OFFSET
5985 && ! nopic_need_relax (offset_expr.X_add_symbol, 1))
5987 relax_start (offset_expr.X_add_symbol);
5988 macro_build (&offset_expr, s, fmt, treg, BFD_RELOC_GPREL16,
5989 mips_gp_register);
5990 relax_switch ();
5991 used_at = 0;
5993 macro_build_lui (&offset_expr, tempreg);
5994 macro_build (&offset_expr, s, fmt, treg,
5995 BFD_RELOC_LO16, tempreg);
5996 if (mips_relax.sequence)
5997 relax_end ();
5999 else
6001 if ((valueT) offset_expr.X_add_number <= MAX_GPREL_OFFSET
6002 && ! nopic_need_relax (offset_expr.X_add_symbol, 1))
6004 relax_start (offset_expr.X_add_symbol);
6005 macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t",
6006 tempreg, breg, mips_gp_register);
6007 macro_build (&offset_expr, s, fmt, treg,
6008 BFD_RELOC_GPREL16, tempreg);
6009 relax_switch ();
6011 macro_build_lui (&offset_expr, tempreg);
6012 macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t",
6013 tempreg, tempreg, breg);
6014 macro_build (&offset_expr, s, fmt, treg,
6015 BFD_RELOC_LO16, tempreg);
6016 if (mips_relax.sequence)
6017 relax_end ();
6020 else if (mips_pic == SVR4_PIC && ! mips_big_got)
6022 int lw_reloc_type = (int) BFD_RELOC_MIPS_GOT16;
6024 /* If this is a reference to an external symbol, we want
6025 lw $tempreg,<sym>($gp) (BFD_RELOC_MIPS_GOT16)
6027 <op> $treg,0($tempreg)
6028 Otherwise we want
6029 lw $tempreg,<sym>($gp) (BFD_RELOC_MIPS_GOT16)
6031 addiu $tempreg,$tempreg,<sym> (BFD_RELOC_LO16)
6032 <op> $treg,0($tempreg)
6034 For NewABI, we want
6035 lw $tempreg,<sym>($gp) (BFD_RELOC_MIPS_GOT_PAGE)
6036 <op> $treg,<sym>($tempreg) (BFD_RELOC_MIPS_GOT_OFST)
6038 If there is a base register, we add it to $tempreg before
6039 the <op>. If there is a constant, we stick it in the
6040 <op> instruction. We don't handle constants larger than
6041 16 bits, because we have no way to load the upper 16 bits
6042 (actually, we could handle them for the subset of cases
6043 in which we are not using $at). */
6044 assert (offset_expr.X_op == O_symbol);
6045 if (HAVE_NEWABI)
6047 macro_build (&offset_expr, ADDRESS_LOAD_INSN, "t,o(b)", tempreg,
6048 BFD_RELOC_MIPS_GOT_PAGE, mips_gp_register);
6049 if (breg != 0)
6050 macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t",
6051 tempreg, tempreg, breg);
6052 macro_build (&offset_expr, s, fmt, treg,
6053 BFD_RELOC_MIPS_GOT_OFST, tempreg);
6055 if (! used_at)
6056 return;
6058 break;
6060 expr1.X_add_number = offset_expr.X_add_number;
6061 offset_expr.X_add_number = 0;
6062 if (expr1.X_add_number < -0x8000
6063 || expr1.X_add_number >= 0x8000)
6064 as_bad (_("PIC code offset overflow (max 16 signed bits)"));
6065 macro_build (&offset_expr, ADDRESS_LOAD_INSN, "t,o(b)", tempreg,
6066 lw_reloc_type, mips_gp_register);
6067 load_delay_nop ();
6068 relax_start (offset_expr.X_add_symbol);
6069 relax_switch ();
6070 macro_build (&offset_expr, ADDRESS_ADDI_INSN, "t,r,j", tempreg,
6071 tempreg, BFD_RELOC_LO16);
6072 relax_end ();
6073 if (breg != 0)
6074 macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t",
6075 tempreg, tempreg, breg);
6076 macro_build (&expr1, s, fmt, treg, BFD_RELOC_LO16, tempreg);
6078 else if (mips_pic == SVR4_PIC && ! HAVE_NEWABI)
6080 int gpdelay;
6082 /* If this is a reference to an external symbol, we want
6083 lui $tempreg,<sym> (BFD_RELOC_MIPS_GOT_HI16)
6084 addu $tempreg,$tempreg,$gp
6085 lw $tempreg,<sym>($tempreg) (BFD_RELOC_MIPS_GOT_LO16)
6086 <op> $treg,0($tempreg)
6087 Otherwise we want
6088 lw $tempreg,<sym>($gp) (BFD_RELOC_MIPS_GOT16)
6090 addiu $tempreg,$tempreg,<sym> (BFD_RELOC_LO16)
6091 <op> $treg,0($tempreg)
6092 If there is a base register, we add it to $tempreg before
6093 the <op>. If there is a constant, we stick it in the
6094 <op> instruction. We don't handle constants larger than
6095 16 bits, because we have no way to load the upper 16 bits
6096 (actually, we could handle them for the subset of cases
6097 in which we are not using $at). */
6098 assert (offset_expr.X_op == O_symbol);
6099 expr1.X_add_number = offset_expr.X_add_number;
6100 offset_expr.X_add_number = 0;
6101 if (expr1.X_add_number < -0x8000
6102 || expr1.X_add_number >= 0x8000)
6103 as_bad (_("PIC code offset overflow (max 16 signed bits)"));
6104 gpdelay = reg_needs_delay (mips_gp_register);
6105 relax_start (offset_expr.X_add_symbol);
6106 macro_build (&offset_expr, "lui", "t,u", tempreg,
6107 BFD_RELOC_MIPS_GOT_HI16);
6108 macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t", tempreg, tempreg,
6109 mips_gp_register);
6110 macro_build (&offset_expr, ADDRESS_LOAD_INSN, "t,o(b)", tempreg,
6111 BFD_RELOC_MIPS_GOT_LO16, tempreg);
6112 relax_switch ();
6113 if (gpdelay)
6114 macro_build (NULL, "nop", "");
6115 macro_build (&offset_expr, ADDRESS_LOAD_INSN, "t,o(b)", tempreg,
6116 BFD_RELOC_MIPS_GOT16, mips_gp_register);
6117 load_delay_nop ();
6118 macro_build (&offset_expr, ADDRESS_ADDI_INSN, "t,r,j", tempreg,
6119 tempreg, BFD_RELOC_LO16);
6120 relax_end ();
6122 if (breg != 0)
6123 macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t",
6124 tempreg, tempreg, breg);
6125 macro_build (&expr1, s, fmt, treg, BFD_RELOC_LO16, tempreg);
6127 else if (mips_pic == SVR4_PIC && HAVE_NEWABI)
6129 /* If this is a reference to an external symbol, we want
6130 lui $tempreg,<sym> (BFD_RELOC_MIPS_GOT_HI16)
6131 add $tempreg,$tempreg,$gp
6132 lw $tempreg,<sym>($tempreg) (BFD_RELOC_MIPS_GOT_LO16)
6133 <op> $treg,<ofst>($tempreg)
6134 Otherwise, for local symbols, we want:
6135 lw $tempreg,<sym>($gp) (BFD_RELOC_MIPS_GOT_PAGE)
6136 <op> $treg,<sym>($tempreg) (BFD_RELOC_MIPS_GOT_OFST) */
6137 assert (offset_expr.X_op == O_symbol);
6138 expr1.X_add_number = offset_expr.X_add_number;
6139 offset_expr.X_add_number = 0;
6140 if (expr1.X_add_number < -0x8000
6141 || expr1.X_add_number >= 0x8000)
6142 as_bad (_("PIC code offset overflow (max 16 signed bits)"));
6143 relax_start (offset_expr.X_add_symbol);
6144 macro_build (&offset_expr, "lui", "t,u", tempreg,
6145 BFD_RELOC_MIPS_GOT_HI16);
6146 macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t", tempreg, tempreg,
6147 mips_gp_register);
6148 macro_build (&offset_expr, ADDRESS_LOAD_INSN, "t,o(b)", tempreg,
6149 BFD_RELOC_MIPS_GOT_LO16, tempreg);
6150 if (breg != 0)
6151 macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t",
6152 tempreg, tempreg, breg);
6153 macro_build (&expr1, s, fmt, treg, BFD_RELOC_LO16, tempreg);
6155 relax_switch ();
6156 offset_expr.X_add_number = expr1.X_add_number;
6157 macro_build (&offset_expr, ADDRESS_LOAD_INSN, "t,o(b)", tempreg,
6158 BFD_RELOC_MIPS_GOT_PAGE, mips_gp_register);
6159 if (breg != 0)
6160 macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t",
6161 tempreg, tempreg, breg);
6162 macro_build (&offset_expr, s, fmt, treg,
6163 BFD_RELOC_MIPS_GOT_OFST, tempreg);
6164 relax_end ();
6166 else
6167 abort ();
6169 if (! used_at)
6170 return;
6172 break;
6174 case M_LI:
6175 case M_LI_S:
6176 load_register (treg, &imm_expr, 0);
6177 return;
6179 case M_DLI:
6180 load_register (treg, &imm_expr, 1);
6181 return;
6183 case M_LI_SS:
6184 if (imm_expr.X_op == O_constant)
6186 load_register (AT, &imm_expr, 0);
6187 macro_build (NULL, "mtc1", "t,G", AT, treg);
6188 break;
6190 else
6192 assert (offset_expr.X_op == O_symbol
6193 && strcmp (segment_name (S_GET_SEGMENT
6194 (offset_expr.X_add_symbol)),
6195 ".lit4") == 0
6196 && offset_expr.X_add_number == 0);
6197 macro_build (&offset_expr, "lwc1", "T,o(b)", treg,
6198 BFD_RELOC_MIPS_LITERAL, mips_gp_register);
6199 return;
6202 case M_LI_D:
6203 /* Check if we have a constant in IMM_EXPR. If the GPRs are 64 bits
6204 wide, IMM_EXPR is the entire value. Otherwise IMM_EXPR is the high
6205 order 32 bits of the value and the low order 32 bits are either
6206 zero or in OFFSET_EXPR. */
6207 if (imm_expr.X_op == O_constant || imm_expr.X_op == O_big)
6209 if (HAVE_64BIT_GPRS)
6210 load_register (treg, &imm_expr, 1);
6211 else
6213 int hreg, lreg;
6215 if (target_big_endian)
6217 hreg = treg;
6218 lreg = treg + 1;
6220 else
6222 hreg = treg + 1;
6223 lreg = treg;
6226 if (hreg <= 31)
6227 load_register (hreg, &imm_expr, 0);
6228 if (lreg <= 31)
6230 if (offset_expr.X_op == O_absent)
6231 move_register (lreg, 0);
6232 else
6234 assert (offset_expr.X_op == O_constant);
6235 load_register (lreg, &offset_expr, 0);
6239 return;
6242 /* We know that sym is in the .rdata section. First we get the
6243 upper 16 bits of the address. */
6244 if (mips_pic == NO_PIC)
6246 macro_build_lui (&offset_expr, AT);
6248 else if (mips_pic == SVR4_PIC)
6250 macro_build (&offset_expr, ADDRESS_LOAD_INSN, "t,o(b)", AT,
6251 BFD_RELOC_MIPS_GOT16, mips_gp_register);
6253 else
6254 abort ();
6256 /* Now we load the register(s). */
6257 if (HAVE_64BIT_GPRS)
6258 macro_build (&offset_expr, "ld", "t,o(b)", treg, BFD_RELOC_LO16, AT);
6259 else
6261 macro_build (&offset_expr, "lw", "t,o(b)", treg, BFD_RELOC_LO16, AT);
6262 if (treg != RA)
6264 /* FIXME: How in the world do we deal with the possible
6265 overflow here? */
6266 offset_expr.X_add_number += 4;
6267 macro_build (&offset_expr, "lw", "t,o(b)",
6268 treg + 1, BFD_RELOC_LO16, AT);
6271 break;
6273 case M_LI_DD:
6274 /* Check if we have a constant in IMM_EXPR. If the FPRs are 64 bits
6275 wide, IMM_EXPR is the entire value and the GPRs are known to be 64
6276 bits wide as well. Otherwise IMM_EXPR is the high order 32 bits of
6277 the value and the low order 32 bits are either zero or in
6278 OFFSET_EXPR. */
6279 if (imm_expr.X_op == O_constant || imm_expr.X_op == O_big)
6281 load_register (AT, &imm_expr, HAVE_64BIT_FPRS);
6282 if (HAVE_64BIT_FPRS)
6284 assert (HAVE_64BIT_GPRS);
6285 macro_build (NULL, "dmtc1", "t,S", AT, treg);
6287 else
6289 macro_build (NULL, "mtc1", "t,G", AT, treg + 1);
6290 if (offset_expr.X_op == O_absent)
6291 macro_build (NULL, "mtc1", "t,G", 0, treg);
6292 else
6294 assert (offset_expr.X_op == O_constant);
6295 load_register (AT, &offset_expr, 0);
6296 macro_build (NULL, "mtc1", "t,G", AT, treg);
6299 break;
6302 assert (offset_expr.X_op == O_symbol
6303 && offset_expr.X_add_number == 0);
6304 s = segment_name (S_GET_SEGMENT (offset_expr.X_add_symbol));
6305 if (strcmp (s, ".lit8") == 0)
6307 if (mips_opts.isa != ISA_MIPS1)
6309 macro_build (&offset_expr, "ldc1", "T,o(b)", treg,
6310 BFD_RELOC_MIPS_LITERAL, mips_gp_register);
6311 return;
6313 breg = mips_gp_register;
6314 r = BFD_RELOC_MIPS_LITERAL;
6315 goto dob;
6317 else
6319 assert (strcmp (s, RDATA_SECTION_NAME) == 0);
6320 if (mips_pic == SVR4_PIC)
6321 macro_build (&offset_expr, ADDRESS_LOAD_INSN, "t,o(b)", AT,
6322 BFD_RELOC_MIPS_GOT16, mips_gp_register);
6323 else
6325 /* FIXME: This won't work for a 64 bit address. */
6326 macro_build_lui (&offset_expr, AT);
6329 if (mips_opts.isa != ISA_MIPS1)
6331 macro_build (&offset_expr, "ldc1", "T,o(b)",
6332 treg, BFD_RELOC_LO16, AT);
6333 break;
6335 breg = AT;
6336 r = BFD_RELOC_LO16;
6337 goto dob;
6340 case M_L_DOB:
6341 if (mips_opts.arch == CPU_R4650)
6343 as_bad (_("opcode not supported on this processor"));
6344 return;
6346 /* Even on a big endian machine $fn comes before $fn+1. We have
6347 to adjust when loading from memory. */
6348 r = BFD_RELOC_LO16;
6349 dob:
6350 assert (mips_opts.isa == ISA_MIPS1);
6351 macro_build (&offset_expr, "lwc1", "T,o(b)",
6352 target_big_endian ? treg + 1 : treg, r, breg);
6353 /* FIXME: A possible overflow which I don't know how to deal
6354 with. */
6355 offset_expr.X_add_number += 4;
6356 macro_build (&offset_expr, "lwc1", "T,o(b)",
6357 target_big_endian ? treg : treg + 1, r, breg);
6359 if (breg != AT)
6360 return;
6361 break;
6363 case M_L_DAB:
6365 * The MIPS assembler seems to check for X_add_number not
6366 * being double aligned and generating:
6367 * lui at,%hi(foo+1)
6368 * addu at,at,v1
6369 * addiu at,at,%lo(foo+1)
6370 * lwc1 f2,0(at)
6371 * lwc1 f3,4(at)
6372 * But, the resulting address is the same after relocation so why
6373 * generate the extra instruction?
6375 if (mips_opts.arch == CPU_R4650)
6377 as_bad (_("opcode not supported on this processor"));
6378 return;
6380 /* Itbl support may require additional care here. */
6381 coproc = 1;
6382 if (mips_opts.isa != ISA_MIPS1)
6384 s = "ldc1";
6385 goto ld;
6388 s = "lwc1";
6389 fmt = "T,o(b)";
6390 goto ldd_std;
6392 case M_S_DAB:
6393 if (mips_opts.arch == CPU_R4650)
6395 as_bad (_("opcode not supported on this processor"));
6396 return;
6399 if (mips_opts.isa != ISA_MIPS1)
6401 s = "sdc1";
6402 goto st;
6405 s = "swc1";
6406 fmt = "T,o(b)";
6407 /* Itbl support may require additional care here. */
6408 coproc = 1;
6409 goto ldd_std;
6411 case M_LD_AB:
6412 if (HAVE_64BIT_GPRS)
6414 s = "ld";
6415 goto ld;
6418 s = "lw";
6419 fmt = "t,o(b)";
6420 goto ldd_std;
6422 case M_SD_AB:
6423 if (HAVE_64BIT_GPRS)
6425 s = "sd";
6426 goto st;
6429 s = "sw";
6430 fmt = "t,o(b)";
6432 ldd_std:
6433 if (offset_expr.X_op != O_symbol
6434 && offset_expr.X_op != O_constant)
6436 as_bad (_("expression too complex"));
6437 offset_expr.X_op = O_constant;
6440 /* Even on a big endian machine $fn comes before $fn+1. We have
6441 to adjust when loading from memory. We set coproc if we must
6442 load $fn+1 first. */
6443 /* Itbl support may require additional care here. */
6444 if (! target_big_endian)
6445 coproc = 0;
6447 if (mips_pic == NO_PIC
6448 || offset_expr.X_op == O_constant)
6450 /* If this is a reference to a GP relative symbol, we want
6451 <op> $treg,<sym>($gp) (BFD_RELOC_GPREL16)
6452 <op> $treg+1,<sym>+4($gp) (BFD_RELOC_GPREL16)
6453 If we have a base register, we use this
6454 addu $at,$breg,$gp
6455 <op> $treg,<sym>($at) (BFD_RELOC_GPREL16)
6456 <op> $treg+1,<sym>+4($at) (BFD_RELOC_GPREL16)
6457 If this is not a GP relative symbol, we want
6458 lui $at,<sym> (BFD_RELOC_HI16_S)
6459 <op> $treg,<sym>($at) (BFD_RELOC_LO16)
6460 <op> $treg+1,<sym>+4($at) (BFD_RELOC_LO16)
6461 If there is a base register, we add it to $at after the
6462 lui instruction. If there is a constant, we always use
6463 the last case. */
6464 if ((valueT) offset_expr.X_add_number > MAX_GPREL_OFFSET
6465 || nopic_need_relax (offset_expr.X_add_symbol, 1))
6466 used_at = 1;
6467 else
6469 relax_start (offset_expr.X_add_symbol);
6470 if (breg == 0)
6472 tempreg = mips_gp_register;
6473 used_at = 0;
6475 else
6477 macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t",
6478 AT, breg, mips_gp_register);
6479 tempreg = AT;
6480 used_at = 1;
6483 /* Itbl support may require additional care here. */
6484 macro_build (&offset_expr, s, fmt, coproc ? treg + 1 : treg,
6485 BFD_RELOC_GPREL16, tempreg);
6486 offset_expr.X_add_number += 4;
6488 /* Set mips_optimize to 2 to avoid inserting an
6489 undesired nop. */
6490 hold_mips_optimize = mips_optimize;
6491 mips_optimize = 2;
6492 /* Itbl support may require additional care here. */
6493 macro_build (&offset_expr, s, fmt, coproc ? treg : treg + 1,
6494 BFD_RELOC_GPREL16, tempreg);
6495 mips_optimize = hold_mips_optimize;
6497 relax_switch ();
6499 /* We just generated two relocs. When tc_gen_reloc
6500 handles this case, it will skip the first reloc and
6501 handle the second. The second reloc already has an
6502 extra addend of 4, which we added above. We must
6503 subtract it out, and then subtract another 4 to make
6504 the first reloc come out right. The second reloc
6505 will come out right because we are going to add 4 to
6506 offset_expr when we build its instruction below.
6508 If we have a symbol, then we don't want to include
6509 the offset, because it will wind up being included
6510 when we generate the reloc. */
6512 if (offset_expr.X_op == O_constant)
6513 offset_expr.X_add_number -= 8;
6514 else
6516 offset_expr.X_add_number = -4;
6517 offset_expr.X_op = O_constant;
6520 macro_build_lui (&offset_expr, AT);
6521 if (breg != 0)
6522 macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t", AT, breg, AT);
6523 /* Itbl support may require additional care here. */
6524 macro_build (&offset_expr, s, fmt, coproc ? treg + 1 : treg,
6525 BFD_RELOC_LO16, AT);
6526 /* FIXME: How do we handle overflow here? */
6527 offset_expr.X_add_number += 4;
6528 /* Itbl support may require additional care here. */
6529 macro_build (&offset_expr, s, fmt, coproc ? treg : treg + 1,
6530 BFD_RELOC_LO16, AT);
6531 if (mips_relax.sequence)
6532 relax_end ();
6534 else if (mips_pic == SVR4_PIC && ! mips_big_got)
6536 /* If this is a reference to an external symbol, we want
6537 lw $at,<sym>($gp) (BFD_RELOC_MIPS_GOT16)
6539 <op> $treg,0($at)
6540 <op> $treg+1,4($at)
6541 Otherwise we want
6542 lw $at,<sym>($gp) (BFD_RELOC_MIPS_GOT16)
6544 <op> $treg,<sym>($at) (BFD_RELOC_LO16)
6545 <op> $treg+1,<sym>+4($at) (BFD_RELOC_LO16)
6546 If there is a base register we add it to $at before the
6547 lwc1 instructions. If there is a constant we include it
6548 in the lwc1 instructions. */
6549 used_at = 1;
6550 expr1.X_add_number = offset_expr.X_add_number;
6551 if (expr1.X_add_number < -0x8000
6552 || expr1.X_add_number >= 0x8000 - 4)
6553 as_bad (_("PIC code offset overflow (max 16 signed bits)"));
6554 load_got_offset (AT, &offset_expr);
6555 load_delay_nop ();
6556 if (breg != 0)
6557 macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t", AT, breg, AT);
6559 /* Set mips_optimize to 2 to avoid inserting an undesired
6560 nop. */
6561 hold_mips_optimize = mips_optimize;
6562 mips_optimize = 2;
6564 /* Itbl support may require additional care here. */
6565 relax_start (offset_expr.X_add_symbol);
6566 macro_build (&expr1, s, fmt, coproc ? treg + 1 : treg,
6567 BFD_RELOC_LO16, AT);
6568 expr1.X_add_number += 4;
6569 macro_build (&expr1, s, fmt, coproc ? treg : treg + 1,
6570 BFD_RELOC_LO16, AT);
6571 relax_switch ();
6572 macro_build (&offset_expr, s, fmt, coproc ? treg + 1 : treg,
6573 BFD_RELOC_LO16, AT);
6574 offset_expr.X_add_number += 4;
6575 macro_build (&offset_expr, s, fmt, coproc ? treg : treg + 1,
6576 BFD_RELOC_LO16, AT);
6577 relax_end ();
6579 mips_optimize = hold_mips_optimize;
6581 else if (mips_pic == SVR4_PIC)
6583 int gpdelay;
6585 /* If this is a reference to an external symbol, we want
6586 lui $at,<sym> (BFD_RELOC_MIPS_GOT_HI16)
6587 addu $at,$at,$gp
6588 lw $at,<sym>($at) (BFD_RELOC_MIPS_GOT_LO16)
6590 <op> $treg,0($at)
6591 <op> $treg+1,4($at)
6592 Otherwise we want
6593 lw $at,<sym>($gp) (BFD_RELOC_MIPS_GOT16)
6595 <op> $treg,<sym>($at) (BFD_RELOC_LO16)
6596 <op> $treg+1,<sym>+4($at) (BFD_RELOC_LO16)
6597 If there is a base register we add it to $at before the
6598 lwc1 instructions. If there is a constant we include it
6599 in the lwc1 instructions. */
6600 used_at = 1;
6601 expr1.X_add_number = offset_expr.X_add_number;
6602 offset_expr.X_add_number = 0;
6603 if (expr1.X_add_number < -0x8000
6604 || expr1.X_add_number >= 0x8000 - 4)
6605 as_bad (_("PIC code offset overflow (max 16 signed bits)"));
6606 gpdelay = reg_needs_delay (mips_gp_register);
6607 relax_start (offset_expr.X_add_symbol);
6608 macro_build (&offset_expr, "lui", "t,u",
6609 AT, BFD_RELOC_MIPS_GOT_HI16);
6610 macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t",
6611 AT, AT, mips_gp_register);
6612 macro_build (&offset_expr, ADDRESS_LOAD_INSN, "t,o(b)",
6613 AT, BFD_RELOC_MIPS_GOT_LO16, AT);
6614 load_delay_nop ();
6615 if (breg != 0)
6616 macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t", AT, breg, AT);
6617 /* Itbl support may require additional care here. */
6618 macro_build (&expr1, s, fmt, coproc ? treg + 1 : treg,
6619 BFD_RELOC_LO16, AT);
6620 expr1.X_add_number += 4;
6622 /* Set mips_optimize to 2 to avoid inserting an undesired
6623 nop. */
6624 hold_mips_optimize = mips_optimize;
6625 mips_optimize = 2;
6626 /* Itbl support may require additional care here. */
6627 macro_build (&expr1, s, fmt, coproc ? treg : treg + 1,
6628 BFD_RELOC_LO16, AT);
6629 mips_optimize = hold_mips_optimize;
6630 expr1.X_add_number -= 4;
6632 relax_switch ();
6633 offset_expr.X_add_number = expr1.X_add_number;
6634 if (gpdelay)
6635 macro_build (NULL, "nop", "");
6636 macro_build (&offset_expr, ADDRESS_LOAD_INSN, "t,o(b)", AT,
6637 BFD_RELOC_MIPS_GOT16, mips_gp_register);
6638 load_delay_nop ();
6639 if (breg != 0)
6640 macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t", AT, breg, AT);
6641 /* Itbl support may require additional care here. */
6642 macro_build (&offset_expr, s, fmt, coproc ? treg + 1 : treg,
6643 BFD_RELOC_LO16, AT);
6644 offset_expr.X_add_number += 4;
6646 /* Set mips_optimize to 2 to avoid inserting an undesired
6647 nop. */
6648 hold_mips_optimize = mips_optimize;
6649 mips_optimize = 2;
6650 /* Itbl support may require additional care here. */
6651 macro_build (&offset_expr, s, fmt, coproc ? treg : treg + 1,
6652 BFD_RELOC_LO16, AT);
6653 mips_optimize = hold_mips_optimize;
6654 relax_end ();
6656 else
6657 abort ();
6659 if (! used_at)
6660 return;
6662 break;
6664 case M_LD_OB:
6665 s = "lw";
6666 goto sd_ob;
6667 case M_SD_OB:
6668 s = "sw";
6669 sd_ob:
6670 assert (HAVE_32BIT_ADDRESSES);
6671 macro_build (&offset_expr, s, "t,o(b)", treg, BFD_RELOC_LO16, breg);
6672 offset_expr.X_add_number += 4;
6673 macro_build (&offset_expr, s, "t,o(b)", treg + 1, BFD_RELOC_LO16, breg);
6674 return;
6676 /* New code added to support COPZ instructions.
6677 This code builds table entries out of the macros in mip_opcodes.
6678 R4000 uses interlocks to handle coproc delays.
6679 Other chips (like the R3000) require nops to be inserted for delays.
6681 FIXME: Currently, we require that the user handle delays.
6682 In order to fill delay slots for non-interlocked chips,
6683 we must have a way to specify delays based on the coprocessor.
6684 Eg. 4 cycles if load coproc reg from memory, 1 if in cache, etc.
6685 What are the side-effects of the cop instruction?
6686 What cache support might we have and what are its effects?
6687 Both coprocessor & memory require delays. how long???
6688 What registers are read/set/modified?
6690 If an itbl is provided to interpret cop instructions,
6691 this knowledge can be encoded in the itbl spec. */
6693 case M_COP0:
6694 s = "c0";
6695 goto copz;
6696 case M_COP1:
6697 s = "c1";
6698 goto copz;
6699 case M_COP2:
6700 s = "c2";
6701 goto copz;
6702 case M_COP3:
6703 s = "c3";
6704 copz:
6705 /* For now we just do C (same as Cz). The parameter will be
6706 stored in insn_opcode by mips_ip. */
6707 macro_build (NULL, s, "C", ip->insn_opcode);
6708 return;
6710 case M_MOVE:
6711 move_register (dreg, sreg);
6712 return;
6714 #ifdef LOSING_COMPILER
6715 default:
6716 /* Try and see if this is a new itbl instruction.
6717 This code builds table entries out of the macros in mip_opcodes.
6718 FIXME: For now we just assemble the expression and pass it's
6719 value along as a 32-bit immediate.
6720 We may want to have the assembler assemble this value,
6721 so that we gain the assembler's knowledge of delay slots,
6722 symbols, etc.
6723 Would it be more efficient to use mask (id) here? */
6724 if (itbl_have_entries
6725 && (immed_expr = itbl_assemble (ip->insn_mo->name, "")))
6727 s = ip->insn_mo->name;
6728 s2 = "cop3";
6729 coproc = ITBL_DECODE_PNUM (immed_expr);;
6730 macro_build (&immed_expr, s, "C");
6731 return;
6733 macro2 (ip);
6734 return;
6736 if (mips_opts.noat)
6737 as_warn (_("Macro used $at after \".set noat\""));
6740 static void
6741 macro2 (struct mips_cl_insn *ip)
6743 register int treg, sreg, dreg, breg;
6744 int tempreg;
6745 int mask;
6746 int used_at;
6747 expressionS expr1;
6748 const char *s;
6749 const char *s2;
6750 const char *fmt;
6751 int likely = 0;
6752 int dbl = 0;
6753 int coproc = 0;
6754 int lr = 0;
6755 int imm = 0;
6756 int off;
6757 offsetT maxnum;
6758 bfd_reloc_code_real_type r;
6760 treg = (ip->insn_opcode >> 16) & 0x1f;
6761 dreg = (ip->insn_opcode >> 11) & 0x1f;
6762 sreg = breg = (ip->insn_opcode >> 21) & 0x1f;
6763 mask = ip->insn_mo->mask;
6765 expr1.X_op = O_constant;
6766 expr1.X_op_symbol = NULL;
6767 expr1.X_add_symbol = NULL;
6768 expr1.X_add_number = 1;
6770 switch (mask)
6772 #endif /* LOSING_COMPILER */
6774 case M_DMUL:
6775 dbl = 1;
6776 case M_MUL:
6777 macro_build (NULL, dbl ? "dmultu" : "multu", "s,t", sreg, treg);
6778 macro_build (NULL, "mflo", "d", dreg);
6779 return;
6781 case M_DMUL_I:
6782 dbl = 1;
6783 case M_MUL_I:
6784 /* The MIPS assembler some times generates shifts and adds. I'm
6785 not trying to be that fancy. GCC should do this for us
6786 anyway. */
6787 load_register (AT, &imm_expr, dbl);
6788 macro_build (NULL, dbl ? "dmult" : "mult", "s,t", sreg, AT);
6789 macro_build (NULL, "mflo", "d", dreg);
6790 break;
6792 case M_DMULO_I:
6793 dbl = 1;
6794 case M_MULO_I:
6795 imm = 1;
6796 goto do_mulo;
6798 case M_DMULO:
6799 dbl = 1;
6800 case M_MULO:
6801 do_mulo:
6802 mips_emit_delays (TRUE);
6803 ++mips_opts.noreorder;
6804 mips_any_noreorder = 1;
6805 if (imm)
6806 load_register (AT, &imm_expr, dbl);
6807 macro_build (NULL, dbl ? "dmult" : "mult", "s,t", sreg, imm ? AT : treg);
6808 macro_build (NULL, "mflo", "d", dreg);
6809 macro_build (NULL, dbl ? "dsra32" : "sra", "d,w,<", dreg, dreg, RA);
6810 macro_build (NULL, "mfhi", "d", AT);
6811 if (mips_trap)
6812 macro_build (NULL, "tne", "s,t,q", dreg, AT, 6);
6813 else
6815 expr1.X_add_number = 8;
6816 macro_build (&expr1, "beq", "s,t,p", dreg, AT);
6817 macro_build (NULL, "nop", "", 0);
6818 macro_build (NULL, "break", "c", 6);
6820 --mips_opts.noreorder;
6821 macro_build (NULL, "mflo", "d", dreg);
6822 break;
6824 case M_DMULOU_I:
6825 dbl = 1;
6826 case M_MULOU_I:
6827 imm = 1;
6828 goto do_mulou;
6830 case M_DMULOU:
6831 dbl = 1;
6832 case M_MULOU:
6833 do_mulou:
6834 mips_emit_delays (TRUE);
6835 ++mips_opts.noreorder;
6836 mips_any_noreorder = 1;
6837 if (imm)
6838 load_register (AT, &imm_expr, dbl);
6839 macro_build (NULL, dbl ? "dmultu" : "multu", "s,t",
6840 sreg, imm ? AT : treg);
6841 macro_build (NULL, "mfhi", "d", AT);
6842 macro_build (NULL, "mflo", "d", dreg);
6843 if (mips_trap)
6844 macro_build (NULL, "tne", "s,t,q", AT, 0, 6);
6845 else
6847 expr1.X_add_number = 8;
6848 macro_build (&expr1, "beq", "s,t,p", AT, 0);
6849 macro_build (NULL, "nop", "", 0);
6850 macro_build (NULL, "break", "c", 6);
6852 --mips_opts.noreorder;
6853 break;
6855 case M_DROL:
6856 if (ISA_HAS_DROR (mips_opts.isa) || CPU_HAS_DROR (mips_opts.arch))
6858 if (dreg == sreg)
6860 tempreg = AT;
6861 used_at = 1;
6863 else
6865 tempreg = dreg;
6866 used_at = 0;
6868 macro_build (NULL, "dnegu", "d,w", tempreg, treg);
6869 macro_build (NULL, "drorv", "d,t,s", dreg, sreg, tempreg);
6870 if (used_at)
6871 break;
6872 return;
6874 macro_build (NULL, "dsubu", "d,v,t", AT, 0, treg);
6875 macro_build (NULL, "dsrlv", "d,t,s", AT, sreg, AT);
6876 macro_build (NULL, "dsllv", "d,t,s", dreg, sreg, treg);
6877 macro_build (NULL, "or", "d,v,t", dreg, dreg, AT);
6878 break;
6880 case M_ROL:
6881 if (ISA_HAS_ROR (mips_opts.isa) || CPU_HAS_ROR (mips_opts.arch))
6883 if (dreg == sreg)
6885 tempreg = AT;
6886 used_at = 1;
6888 else
6890 tempreg = dreg;
6891 used_at = 0;
6893 macro_build (NULL, "negu", "d,w", tempreg, treg);
6894 macro_build (NULL, "rorv", "d,t,s", dreg, sreg, tempreg);
6895 if (used_at)
6896 break;
6897 return;
6899 macro_build (NULL, "subu", "d,v,t", AT, 0, treg);
6900 macro_build (NULL, "srlv", "d,t,s", AT, sreg, AT);
6901 macro_build (NULL, "sllv", "d,t,s", dreg, sreg, treg);
6902 macro_build (NULL, "or", "d,v,t", dreg, dreg, AT);
6903 break;
6905 case M_DROL_I:
6907 unsigned int rot;
6908 char *l, *r;
6910 if (imm_expr.X_op != O_constant)
6911 as_bad (_("Improper rotate count"));
6912 rot = imm_expr.X_add_number & 0x3f;
6913 if (ISA_HAS_DROR (mips_opts.isa) || CPU_HAS_DROR (mips_opts.arch))
6915 rot = (64 - rot) & 0x3f;
6916 if (rot >= 32)
6917 macro_build (NULL, "dror32", "d,w,<", dreg, sreg, rot - 32);
6918 else
6919 macro_build (NULL, "dror", "d,w,<", dreg, sreg, rot);
6920 return;
6922 if (rot == 0)
6924 macro_build (NULL, "dsrl", "d,w,<", dreg, sreg, 0);
6925 return;
6927 l = (rot < 0x20) ? "dsll" : "dsll32";
6928 r = ((0x40 - rot) < 0x20) ? "dsrl" : "dsrl32";
6929 rot &= 0x1f;
6930 macro_build (NULL, l, "d,w,<", AT, sreg, rot);
6931 macro_build (NULL, r, "d,w,<", dreg, sreg, (0x20 - rot) & 0x1f);
6932 macro_build (NULL, "or", "d,v,t", dreg, dreg, AT);
6934 break;
6936 case M_ROL_I:
6938 unsigned int rot;
6940 if (imm_expr.X_op != O_constant)
6941 as_bad (_("Improper rotate count"));
6942 rot = imm_expr.X_add_number & 0x1f;
6943 if (ISA_HAS_ROR (mips_opts.isa) || CPU_HAS_ROR (mips_opts.arch))
6945 macro_build (NULL, "ror", "d,w,<", dreg, sreg, (32 - rot) & 0x1f);
6946 return;
6948 if (rot == 0)
6950 macro_build (NULL, "srl", "d,w,<", dreg, sreg, 0);
6951 return;
6953 macro_build (NULL, "sll", "d,w,<", AT, sreg, rot);
6954 macro_build (NULL, "srl", "d,w,<", dreg, sreg, (0x20 - rot) & 0x1f);
6955 macro_build (NULL, "or", "d,v,t", dreg, dreg, AT);
6957 break;
6959 case M_DROR:
6960 if (ISA_HAS_DROR (mips_opts.isa) || CPU_HAS_DROR (mips_opts.arch))
6962 macro_build (NULL, "drorv", "d,t,s", dreg, sreg, treg);
6963 return;
6965 macro_build (NULL, "dsubu", "d,v,t", AT, 0, treg);
6966 macro_build (NULL, "dsllv", "d,t,s", AT, sreg, AT);
6967 macro_build (NULL, "dsrlv", "d,t,s", dreg, sreg, treg);
6968 macro_build (NULL, "or", "d,v,t", dreg, dreg, AT);
6969 break;
6971 case M_ROR:
6972 if (ISA_HAS_ROR (mips_opts.isa) || CPU_HAS_ROR (mips_opts.arch))
6974 macro_build (NULL, "rorv", "d,t,s", dreg, sreg, treg);
6975 return;
6977 macro_build (NULL, "subu", "d,v,t", AT, 0, treg);
6978 macro_build (NULL, "sllv", "d,t,s", AT, sreg, AT);
6979 macro_build (NULL, "srlv", "d,t,s", dreg, sreg, treg);
6980 macro_build (NULL, "or", "d,v,t", dreg, dreg, AT);
6981 break;
6983 case M_DROR_I:
6985 unsigned int rot;
6986 char *l, *r;
6988 if (imm_expr.X_op != O_constant)
6989 as_bad (_("Improper rotate count"));
6990 rot = imm_expr.X_add_number & 0x3f;
6991 if (ISA_HAS_DROR (mips_opts.isa) || CPU_HAS_DROR (mips_opts.arch))
6993 if (rot >= 32)
6994 macro_build (NULL, "dror32", "d,w,<", dreg, sreg, rot - 32);
6995 else
6996 macro_build (NULL, "dror", "d,w,<", dreg, sreg, rot);
6997 return;
6999 if (rot == 0)
7001 macro_build (NULL, "dsrl", "d,w,<", dreg, sreg, 0);
7002 return;
7004 r = (rot < 0x20) ? "dsrl" : "dsrl32";
7005 l = ((0x40 - rot) < 0x20) ? "dsll" : "dsll32";
7006 rot &= 0x1f;
7007 macro_build (NULL, r, "d,w,<", AT, sreg, rot);
7008 macro_build (NULL, l, "d,w,<", dreg, sreg, (0x20 - rot) & 0x1f);
7009 macro_build (NULL, "or", "d,v,t", dreg, dreg, AT);
7011 break;
7013 case M_ROR_I:
7015 unsigned int rot;
7017 if (imm_expr.X_op != O_constant)
7018 as_bad (_("Improper rotate count"));
7019 rot = imm_expr.X_add_number & 0x1f;
7020 if (ISA_HAS_ROR (mips_opts.isa) || CPU_HAS_ROR (mips_opts.arch))
7022 macro_build (NULL, "ror", "d,w,<", dreg, sreg, rot);
7023 return;
7025 if (rot == 0)
7027 macro_build (NULL, "srl", "d,w,<", dreg, sreg, 0);
7028 return;
7030 macro_build (NULL, "srl", "d,w,<", AT, sreg, rot);
7031 macro_build (NULL, "sll", "d,w,<", dreg, sreg, (0x20 - rot) & 0x1f);
7032 macro_build (NULL, "or", "d,v,t", dreg, dreg, AT);
7034 break;
7036 case M_S_DOB:
7037 if (mips_opts.arch == CPU_R4650)
7039 as_bad (_("opcode not supported on this processor"));
7040 return;
7042 assert (mips_opts.isa == ISA_MIPS1);
7043 /* Even on a big endian machine $fn comes before $fn+1. We have
7044 to adjust when storing to memory. */
7045 macro_build (&offset_expr, "swc1", "T,o(b)",
7046 target_big_endian ? treg + 1 : treg, BFD_RELOC_LO16, breg);
7047 offset_expr.X_add_number += 4;
7048 macro_build (&offset_expr, "swc1", "T,o(b)",
7049 target_big_endian ? treg : treg + 1, BFD_RELOC_LO16, breg);
7050 return;
7052 case M_SEQ:
7053 if (sreg == 0)
7054 macro_build (&expr1, "sltiu", "t,r,j", dreg, treg, BFD_RELOC_LO16);
7055 else if (treg == 0)
7056 macro_build (&expr1, "sltiu", "t,r,j", dreg, sreg, BFD_RELOC_LO16);
7057 else
7059 macro_build (NULL, "xor", "d,v,t", dreg, sreg, treg);
7060 macro_build (&expr1, "sltiu", "t,r,j", dreg, dreg, BFD_RELOC_LO16);
7062 return;
7064 case M_SEQ_I:
7065 if (imm_expr.X_op == O_constant && imm_expr.X_add_number == 0)
7067 macro_build (&expr1, "sltiu", "t,r,j", dreg, sreg, BFD_RELOC_LO16);
7068 return;
7070 if (sreg == 0)
7072 as_warn (_("Instruction %s: result is always false"),
7073 ip->insn_mo->name);
7074 move_register (dreg, 0);
7075 return;
7077 if (imm_expr.X_op == O_constant
7078 && imm_expr.X_add_number >= 0
7079 && imm_expr.X_add_number < 0x10000)
7081 macro_build (&imm_expr, "xori", "t,r,i", dreg, sreg, BFD_RELOC_LO16);
7082 used_at = 0;
7084 else if (imm_expr.X_op == O_constant
7085 && imm_expr.X_add_number > -0x8000
7086 && imm_expr.X_add_number < 0)
7088 imm_expr.X_add_number = -imm_expr.X_add_number;
7089 macro_build (&imm_expr, HAVE_32BIT_GPRS ? "addiu" : "daddiu",
7090 "t,r,j", dreg, sreg, BFD_RELOC_LO16);
7091 used_at = 0;
7093 else
7095 load_register (AT, &imm_expr, HAVE_64BIT_GPRS);
7096 macro_build (NULL, "xor", "d,v,t", dreg, sreg, AT);
7097 used_at = 1;
7099 macro_build (&expr1, "sltiu", "t,r,j", dreg, dreg, BFD_RELOC_LO16);
7100 if (used_at)
7101 break;
7102 return;
7104 case M_SGE: /* sreg >= treg <==> not (sreg < treg) */
7105 s = "slt";
7106 goto sge;
7107 case M_SGEU:
7108 s = "sltu";
7109 sge:
7110 macro_build (NULL, s, "d,v,t", dreg, sreg, treg);
7111 macro_build (&expr1, "xori", "t,r,i", dreg, dreg, BFD_RELOC_LO16);
7112 return;
7114 case M_SGE_I: /* sreg >= I <==> not (sreg < I) */
7115 case M_SGEU_I:
7116 if (imm_expr.X_op == O_constant
7117 && imm_expr.X_add_number >= -0x8000
7118 && imm_expr.X_add_number < 0x8000)
7120 macro_build (&imm_expr, mask == M_SGE_I ? "slti" : "sltiu", "t,r,j",
7121 dreg, sreg, BFD_RELOC_LO16);
7122 used_at = 0;
7124 else
7126 load_register (AT, &imm_expr, HAVE_64BIT_GPRS);
7127 macro_build (NULL, mask == M_SGE_I ? "slt" : "sltu", "d,v,t",
7128 dreg, sreg, AT);
7129 used_at = 1;
7131 macro_build (&expr1, "xori", "t,r,i", dreg, dreg, BFD_RELOC_LO16);
7132 if (used_at)
7133 break;
7134 return;
7136 case M_SGT: /* sreg > treg <==> treg < sreg */
7137 s = "slt";
7138 goto sgt;
7139 case M_SGTU:
7140 s = "sltu";
7141 sgt:
7142 macro_build (NULL, s, "d,v,t", dreg, treg, sreg);
7143 return;
7145 case M_SGT_I: /* sreg > I <==> I < sreg */
7146 s = "slt";
7147 goto sgti;
7148 case M_SGTU_I:
7149 s = "sltu";
7150 sgti:
7151 load_register (AT, &imm_expr, HAVE_64BIT_GPRS);
7152 macro_build (NULL, s, "d,v,t", dreg, AT, sreg);
7153 break;
7155 case M_SLE: /* sreg <= treg <==> treg >= sreg <==> not (treg < sreg) */
7156 s = "slt";
7157 goto sle;
7158 case M_SLEU:
7159 s = "sltu";
7160 sle:
7161 macro_build (NULL, s, "d,v,t", dreg, treg, sreg);
7162 macro_build (&expr1, "xori", "t,r,i", dreg, dreg, BFD_RELOC_LO16);
7163 return;
7165 case M_SLE_I: /* sreg <= I <==> I >= sreg <==> not (I < sreg) */
7166 s = "slt";
7167 goto slei;
7168 case M_SLEU_I:
7169 s = "sltu";
7170 slei:
7171 load_register (AT, &imm_expr, HAVE_64BIT_GPRS);
7172 macro_build (NULL, s, "d,v,t", dreg, AT, sreg);
7173 macro_build (&expr1, "xori", "t,r,i", dreg, dreg, BFD_RELOC_LO16);
7174 break;
7176 case M_SLT_I:
7177 if (imm_expr.X_op == O_constant
7178 && imm_expr.X_add_number >= -0x8000
7179 && imm_expr.X_add_number < 0x8000)
7181 macro_build (&imm_expr, "slti", "t,r,j", dreg, sreg, BFD_RELOC_LO16);
7182 return;
7184 load_register (AT, &imm_expr, HAVE_64BIT_GPRS);
7185 macro_build (NULL, "slt", "d,v,t", dreg, sreg, AT);
7186 break;
7188 case M_SLTU_I:
7189 if (imm_expr.X_op == O_constant
7190 && imm_expr.X_add_number >= -0x8000
7191 && imm_expr.X_add_number < 0x8000)
7193 macro_build (&imm_expr, "sltiu", "t,r,j", dreg, sreg,
7194 BFD_RELOC_LO16);
7195 return;
7197 load_register (AT, &imm_expr, HAVE_64BIT_GPRS);
7198 macro_build (NULL, "sltu", "d,v,t", dreg, sreg, AT);
7199 break;
7201 case M_SNE:
7202 if (sreg == 0)
7203 macro_build (NULL, "sltu", "d,v,t", dreg, 0, treg);
7204 else if (treg == 0)
7205 macro_build (NULL, "sltu", "d,v,t", dreg, 0, sreg);
7206 else
7208 macro_build (NULL, "xor", "d,v,t", dreg, sreg, treg);
7209 macro_build (NULL, "sltu", "d,v,t", dreg, 0, dreg);
7211 return;
7213 case M_SNE_I:
7214 if (imm_expr.X_op == O_constant && imm_expr.X_add_number == 0)
7216 macro_build (NULL, "sltu", "d,v,t", dreg, 0, sreg);
7217 return;
7219 if (sreg == 0)
7221 as_warn (_("Instruction %s: result is always true"),
7222 ip->insn_mo->name);
7223 macro_build (&expr1, HAVE_32BIT_GPRS ? "addiu" : "daddiu", "t,r,j",
7224 dreg, 0, BFD_RELOC_LO16);
7225 return;
7227 if (imm_expr.X_op == O_constant
7228 && imm_expr.X_add_number >= 0
7229 && imm_expr.X_add_number < 0x10000)
7231 macro_build (&imm_expr, "xori", "t,r,i", dreg, sreg, BFD_RELOC_LO16);
7232 used_at = 0;
7234 else if (imm_expr.X_op == O_constant
7235 && imm_expr.X_add_number > -0x8000
7236 && imm_expr.X_add_number < 0)
7238 imm_expr.X_add_number = -imm_expr.X_add_number;
7239 macro_build (&imm_expr, HAVE_32BIT_GPRS ? "addiu" : "daddiu",
7240 "t,r,j", dreg, sreg, BFD_RELOC_LO16);
7241 used_at = 0;
7243 else
7245 load_register (AT, &imm_expr, HAVE_64BIT_GPRS);
7246 macro_build (NULL, "xor", "d,v,t", dreg, sreg, AT);
7247 used_at = 1;
7249 macro_build (NULL, "sltu", "d,v,t", dreg, 0, dreg);
7250 if (used_at)
7251 break;
7252 return;
7254 case M_DSUB_I:
7255 dbl = 1;
7256 case M_SUB_I:
7257 if (imm_expr.X_op == O_constant
7258 && imm_expr.X_add_number > -0x8000
7259 && imm_expr.X_add_number <= 0x8000)
7261 imm_expr.X_add_number = -imm_expr.X_add_number;
7262 macro_build (&imm_expr, dbl ? "daddi" : "addi", "t,r,j",
7263 dreg, sreg, BFD_RELOC_LO16);
7264 return;
7266 load_register (AT, &imm_expr, dbl);
7267 macro_build (NULL, dbl ? "dsub" : "sub", "d,v,t", dreg, sreg, AT);
7268 break;
7270 case M_DSUBU_I:
7271 dbl = 1;
7272 case M_SUBU_I:
7273 if (imm_expr.X_op == O_constant
7274 && imm_expr.X_add_number > -0x8000
7275 && imm_expr.X_add_number <= 0x8000)
7277 imm_expr.X_add_number = -imm_expr.X_add_number;
7278 macro_build (&imm_expr, dbl ? "daddiu" : "addiu", "t,r,j",
7279 dreg, sreg, BFD_RELOC_LO16);
7280 return;
7282 load_register (AT, &imm_expr, dbl);
7283 macro_build (NULL, dbl ? "dsubu" : "subu", "d,v,t", dreg, sreg, AT);
7284 break;
7286 case M_TEQ_I:
7287 s = "teq";
7288 goto trap;
7289 case M_TGE_I:
7290 s = "tge";
7291 goto trap;
7292 case M_TGEU_I:
7293 s = "tgeu";
7294 goto trap;
7295 case M_TLT_I:
7296 s = "tlt";
7297 goto trap;
7298 case M_TLTU_I:
7299 s = "tltu";
7300 goto trap;
7301 case M_TNE_I:
7302 s = "tne";
7303 trap:
7304 load_register (AT, &imm_expr, HAVE_64BIT_GPRS);
7305 macro_build (NULL, s, "s,t", sreg, AT);
7306 break;
7308 case M_TRUNCWS:
7309 case M_TRUNCWD:
7310 assert (mips_opts.isa == ISA_MIPS1);
7311 sreg = (ip->insn_opcode >> 11) & 0x1f; /* floating reg */
7312 dreg = (ip->insn_opcode >> 06) & 0x1f; /* floating reg */
7315 * Is the double cfc1 instruction a bug in the mips assembler;
7316 * or is there a reason for it?
7318 mips_emit_delays (TRUE);
7319 ++mips_opts.noreorder;
7320 mips_any_noreorder = 1;
7321 macro_build (NULL, "cfc1", "t,G", treg, RA);
7322 macro_build (NULL, "cfc1", "t,G", treg, RA);
7323 macro_build (NULL, "nop", "");
7324 expr1.X_add_number = 3;
7325 macro_build (&expr1, "ori", "t,r,i", AT, treg, BFD_RELOC_LO16);
7326 expr1.X_add_number = 2;
7327 macro_build (&expr1, "xori", "t,r,i", AT, AT, BFD_RELOC_LO16);
7328 macro_build (NULL, "ctc1", "t,G", AT, RA);
7329 macro_build (NULL, "nop", "");
7330 macro_build (NULL, mask == M_TRUNCWD ? "cvt.w.d" : "cvt.w.s", "D,S",
7331 dreg, sreg);
7332 macro_build (NULL, "ctc1", "t,G", treg, RA);
7333 macro_build (NULL, "nop", "");
7334 --mips_opts.noreorder;
7335 break;
7337 case M_ULH:
7338 s = "lb";
7339 goto ulh;
7340 case M_ULHU:
7341 s = "lbu";
7342 ulh:
7343 if (offset_expr.X_add_number >= 0x7fff)
7344 as_bad (_("operand overflow"));
7345 if (! target_big_endian)
7346 ++offset_expr.X_add_number;
7347 macro_build (&offset_expr, s, "t,o(b)", AT, BFD_RELOC_LO16, breg);
7348 if (! target_big_endian)
7349 --offset_expr.X_add_number;
7350 else
7351 ++offset_expr.X_add_number;
7352 macro_build (&offset_expr, "lbu", "t,o(b)", treg, BFD_RELOC_LO16, breg);
7353 macro_build (NULL, "sll", "d,w,<", AT, AT, 8);
7354 macro_build (NULL, "or", "d,v,t", treg, treg, AT);
7355 break;
7357 case M_ULD:
7358 s = "ldl";
7359 s2 = "ldr";
7360 off = 7;
7361 goto ulw;
7362 case M_ULW:
7363 s = "lwl";
7364 s2 = "lwr";
7365 off = 3;
7366 ulw:
7367 if (offset_expr.X_add_number >= 0x8000 - off)
7368 as_bad (_("operand overflow"));
7369 if (treg != breg)
7370 tempreg = treg;
7371 else
7372 tempreg = AT;
7373 if (! target_big_endian)
7374 offset_expr.X_add_number += off;
7375 macro_build (&offset_expr, s, "t,o(b)", tempreg, BFD_RELOC_LO16, breg);
7376 if (! target_big_endian)
7377 offset_expr.X_add_number -= off;
7378 else
7379 offset_expr.X_add_number += off;
7380 macro_build (&offset_expr, s2, "t,o(b)", tempreg, BFD_RELOC_LO16, breg);
7382 /* If necessary, move the result in tempreg the final destination. */
7383 if (treg == tempreg)
7384 return;
7385 /* Protect second load's delay slot. */
7386 load_delay_nop ();
7387 move_register (treg, tempreg);
7388 break;
7390 case M_ULD_A:
7391 s = "ldl";
7392 s2 = "ldr";
7393 off = 7;
7394 goto ulwa;
7395 case M_ULW_A:
7396 s = "lwl";
7397 s2 = "lwr";
7398 off = 3;
7399 ulwa:
7400 used_at = 1;
7401 load_address (AT, &offset_expr, &used_at);
7402 if (breg != 0)
7403 macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t", AT, AT, breg);
7404 if (! target_big_endian)
7405 expr1.X_add_number = off;
7406 else
7407 expr1.X_add_number = 0;
7408 macro_build (&expr1, s, "t,o(b)", treg, BFD_RELOC_LO16, AT);
7409 if (! target_big_endian)
7410 expr1.X_add_number = 0;
7411 else
7412 expr1.X_add_number = off;
7413 macro_build (&expr1, s2, "t,o(b)", treg, BFD_RELOC_LO16, AT);
7414 break;
7416 case M_ULH_A:
7417 case M_ULHU_A:
7418 used_at = 1;
7419 load_address (AT, &offset_expr, &used_at);
7420 if (breg != 0)
7421 macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t", AT, AT, breg);
7422 if (target_big_endian)
7423 expr1.X_add_number = 0;
7424 macro_build (&expr1, mask == M_ULH_A ? "lb" : "lbu", "t,o(b)",
7425 treg, BFD_RELOC_LO16, AT);
7426 if (target_big_endian)
7427 expr1.X_add_number = 1;
7428 else
7429 expr1.X_add_number = 0;
7430 macro_build (&expr1, "lbu", "t,o(b)", AT, BFD_RELOC_LO16, AT);
7431 macro_build (NULL, "sll", "d,w,<", treg, treg, 8);
7432 macro_build (NULL, "or", "d,v,t", treg, treg, AT);
7433 break;
7435 case M_USH:
7436 if (offset_expr.X_add_number >= 0x7fff)
7437 as_bad (_("operand overflow"));
7438 if (target_big_endian)
7439 ++offset_expr.X_add_number;
7440 macro_build (&offset_expr, "sb", "t,o(b)", treg, BFD_RELOC_LO16, breg);
7441 macro_build (NULL, "srl", "d,w,<", AT, treg, 8);
7442 if (target_big_endian)
7443 --offset_expr.X_add_number;
7444 else
7445 ++offset_expr.X_add_number;
7446 macro_build (&offset_expr, "sb", "t,o(b)", AT, BFD_RELOC_LO16, breg);
7447 break;
7449 case M_USD:
7450 s = "sdl";
7451 s2 = "sdr";
7452 off = 7;
7453 goto usw;
7454 case M_USW:
7455 s = "swl";
7456 s2 = "swr";
7457 off = 3;
7458 usw:
7459 if (offset_expr.X_add_number >= 0x8000 - off)
7460 as_bad (_("operand overflow"));
7461 if (! target_big_endian)
7462 offset_expr.X_add_number += off;
7463 macro_build (&offset_expr, s, "t,o(b)", treg, BFD_RELOC_LO16, breg);
7464 if (! target_big_endian)
7465 offset_expr.X_add_number -= off;
7466 else
7467 offset_expr.X_add_number += off;
7468 macro_build (&offset_expr, s2, "t,o(b)", treg, BFD_RELOC_LO16, breg);
7469 return;
7471 case M_USD_A:
7472 s = "sdl";
7473 s2 = "sdr";
7474 off = 7;
7475 goto uswa;
7476 case M_USW_A:
7477 s = "swl";
7478 s2 = "swr";
7479 off = 3;
7480 uswa:
7481 used_at = 1;
7482 load_address (AT, &offset_expr, &used_at);
7483 if (breg != 0)
7484 macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t", AT, AT, breg);
7485 if (! target_big_endian)
7486 expr1.X_add_number = off;
7487 else
7488 expr1.X_add_number = 0;
7489 macro_build (&expr1, s, "t,o(b)", treg, BFD_RELOC_LO16, AT);
7490 if (! target_big_endian)
7491 expr1.X_add_number = 0;
7492 else
7493 expr1.X_add_number = off;
7494 macro_build (&expr1, s2, "t,o(b)", treg, BFD_RELOC_LO16, AT);
7495 break;
7497 case M_USH_A:
7498 used_at = 1;
7499 load_address (AT, &offset_expr, &used_at);
7500 if (breg != 0)
7501 macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t", AT, AT, breg);
7502 if (! target_big_endian)
7503 expr1.X_add_number = 0;
7504 macro_build (&expr1, "sb", "t,o(b)", treg, BFD_RELOC_LO16, AT);
7505 macro_build (NULL, "srl", "d,w,<", treg, treg, 8);
7506 if (! target_big_endian)
7507 expr1.X_add_number = 1;
7508 else
7509 expr1.X_add_number = 0;
7510 macro_build (&expr1, "sb", "t,o(b)", treg, BFD_RELOC_LO16, AT);
7511 if (! target_big_endian)
7512 expr1.X_add_number = 0;
7513 else
7514 expr1.X_add_number = 1;
7515 macro_build (&expr1, "lbu", "t,o(b)", AT, BFD_RELOC_LO16, AT);
7516 macro_build (NULL, "sll", "d,w,<", treg, treg, 8);
7517 macro_build (NULL, "or", "d,v,t", treg, treg, AT);
7518 break;
7520 default:
7521 /* FIXME: Check if this is one of the itbl macros, since they
7522 are added dynamically. */
7523 as_bad (_("Macro %s not implemented yet"), ip->insn_mo->name);
7524 break;
7526 if (mips_opts.noat)
7527 as_warn (_("Macro used $at after \".set noat\""));
7530 /* Implement macros in mips16 mode. */
7532 static void
7533 mips16_macro (struct mips_cl_insn *ip)
7535 int mask;
7536 int xreg, yreg, zreg, tmp;
7537 expressionS expr1;
7538 int dbl;
7539 const char *s, *s2, *s3;
7541 mask = ip->insn_mo->mask;
7543 xreg = (ip->insn_opcode >> MIPS16OP_SH_RX) & MIPS16OP_MASK_RX;
7544 yreg = (ip->insn_opcode >> MIPS16OP_SH_RY) & MIPS16OP_MASK_RY;
7545 zreg = (ip->insn_opcode >> MIPS16OP_SH_RZ) & MIPS16OP_MASK_RZ;
7547 expr1.X_op = O_constant;
7548 expr1.X_op_symbol = NULL;
7549 expr1.X_add_symbol = NULL;
7550 expr1.X_add_number = 1;
7552 dbl = 0;
7554 switch (mask)
7556 default:
7557 internalError ();
7559 case M_DDIV_3:
7560 dbl = 1;
7561 case M_DIV_3:
7562 s = "mflo";
7563 goto do_div3;
7564 case M_DREM_3:
7565 dbl = 1;
7566 case M_REM_3:
7567 s = "mfhi";
7568 do_div3:
7569 mips_emit_delays (TRUE);
7570 ++mips_opts.noreorder;
7571 mips_any_noreorder = 1;
7572 macro_build (NULL, dbl ? "ddiv" : "div", "0,x,y", xreg, yreg);
7573 expr1.X_add_number = 2;
7574 macro_build (&expr1, "bnez", "x,p", yreg);
7575 macro_build (NULL, "break", "6", 7);
7577 /* FIXME: The normal code checks for of -1 / -0x80000000 here,
7578 since that causes an overflow. We should do that as well,
7579 but I don't see how to do the comparisons without a temporary
7580 register. */
7581 --mips_opts.noreorder;
7582 macro_build (NULL, s, "x", zreg);
7583 break;
7585 case M_DIVU_3:
7586 s = "divu";
7587 s2 = "mflo";
7588 goto do_divu3;
7589 case M_REMU_3:
7590 s = "divu";
7591 s2 = "mfhi";
7592 goto do_divu3;
7593 case M_DDIVU_3:
7594 s = "ddivu";
7595 s2 = "mflo";
7596 goto do_divu3;
7597 case M_DREMU_3:
7598 s = "ddivu";
7599 s2 = "mfhi";
7600 do_divu3:
7601 mips_emit_delays (TRUE);
7602 ++mips_opts.noreorder;
7603 mips_any_noreorder = 1;
7604 macro_build (NULL, s, "0,x,y", xreg, yreg);
7605 expr1.X_add_number = 2;
7606 macro_build (&expr1, "bnez", "x,p", yreg);
7607 macro_build (NULL, "break", "6", 7);
7608 --mips_opts.noreorder;
7609 macro_build (NULL, s2, "x", zreg);
7610 break;
7612 case M_DMUL:
7613 dbl = 1;
7614 case M_MUL:
7615 macro_build (NULL, dbl ? "dmultu" : "multu", "x,y", xreg, yreg);
7616 macro_build (NULL, "mflo", "x", zreg);
7617 return;
7619 case M_DSUBU_I:
7620 dbl = 1;
7621 goto do_subu;
7622 case M_SUBU_I:
7623 do_subu:
7624 if (imm_expr.X_op != O_constant)
7625 as_bad (_("Unsupported large constant"));
7626 imm_expr.X_add_number = -imm_expr.X_add_number;
7627 macro_build (&imm_expr, dbl ? "daddiu" : "addiu", "y,x,4", yreg, xreg);
7628 break;
7630 case M_SUBU_I_2:
7631 if (imm_expr.X_op != O_constant)
7632 as_bad (_("Unsupported large constant"));
7633 imm_expr.X_add_number = -imm_expr.X_add_number;
7634 macro_build (&imm_expr, "addiu", "x,k", xreg);
7635 break;
7637 case M_DSUBU_I_2:
7638 if (imm_expr.X_op != O_constant)
7639 as_bad (_("Unsupported large constant"));
7640 imm_expr.X_add_number = -imm_expr.X_add_number;
7641 macro_build (&imm_expr, "daddiu", "y,j", yreg);
7642 break;
7644 case M_BEQ:
7645 s = "cmp";
7646 s2 = "bteqz";
7647 goto do_branch;
7648 case M_BNE:
7649 s = "cmp";
7650 s2 = "btnez";
7651 goto do_branch;
7652 case M_BLT:
7653 s = "slt";
7654 s2 = "btnez";
7655 goto do_branch;
7656 case M_BLTU:
7657 s = "sltu";
7658 s2 = "btnez";
7659 goto do_branch;
7660 case M_BLE:
7661 s = "slt";
7662 s2 = "bteqz";
7663 goto do_reverse_branch;
7664 case M_BLEU:
7665 s = "sltu";
7666 s2 = "bteqz";
7667 goto do_reverse_branch;
7668 case M_BGE:
7669 s = "slt";
7670 s2 = "bteqz";
7671 goto do_branch;
7672 case M_BGEU:
7673 s = "sltu";
7674 s2 = "bteqz";
7675 goto do_branch;
7676 case M_BGT:
7677 s = "slt";
7678 s2 = "btnez";
7679 goto do_reverse_branch;
7680 case M_BGTU:
7681 s = "sltu";
7682 s2 = "btnez";
7684 do_reverse_branch:
7685 tmp = xreg;
7686 xreg = yreg;
7687 yreg = tmp;
7689 do_branch:
7690 macro_build (NULL, s, "x,y", xreg, yreg);
7691 macro_build (&offset_expr, s2, "p");
7692 break;
7694 case M_BEQ_I:
7695 s = "cmpi";
7696 s2 = "bteqz";
7697 s3 = "x,U";
7698 goto do_branch_i;
7699 case M_BNE_I:
7700 s = "cmpi";
7701 s2 = "btnez";
7702 s3 = "x,U";
7703 goto do_branch_i;
7704 case M_BLT_I:
7705 s = "slti";
7706 s2 = "btnez";
7707 s3 = "x,8";
7708 goto do_branch_i;
7709 case M_BLTU_I:
7710 s = "sltiu";
7711 s2 = "btnez";
7712 s3 = "x,8";
7713 goto do_branch_i;
7714 case M_BLE_I:
7715 s = "slti";
7716 s2 = "btnez";
7717 s3 = "x,8";
7718 goto do_addone_branch_i;
7719 case M_BLEU_I:
7720 s = "sltiu";
7721 s2 = "btnez";
7722 s3 = "x,8";
7723 goto do_addone_branch_i;
7724 case M_BGE_I:
7725 s = "slti";
7726 s2 = "bteqz";
7727 s3 = "x,8";
7728 goto do_branch_i;
7729 case M_BGEU_I:
7730 s = "sltiu";
7731 s2 = "bteqz";
7732 s3 = "x,8";
7733 goto do_branch_i;
7734 case M_BGT_I:
7735 s = "slti";
7736 s2 = "bteqz";
7737 s3 = "x,8";
7738 goto do_addone_branch_i;
7739 case M_BGTU_I:
7740 s = "sltiu";
7741 s2 = "bteqz";
7742 s3 = "x,8";
7744 do_addone_branch_i:
7745 if (imm_expr.X_op != O_constant)
7746 as_bad (_("Unsupported large constant"));
7747 ++imm_expr.X_add_number;
7749 do_branch_i:
7750 macro_build (&imm_expr, s, s3, xreg);
7751 macro_build (&offset_expr, s2, "p");
7752 break;
7754 case M_ABS:
7755 expr1.X_add_number = 0;
7756 macro_build (&expr1, "slti", "x,8", yreg);
7757 if (xreg != yreg)
7758 move_register (xreg, yreg);
7759 expr1.X_add_number = 2;
7760 macro_build (&expr1, "bteqz", "p");
7761 macro_build (NULL, "neg", "x,w", xreg, xreg);
7765 /* For consistency checking, verify that all bits are specified either
7766 by the match/mask part of the instruction definition, or by the
7767 operand list. */
7768 static int
7769 validate_mips_insn (const struct mips_opcode *opc)
7771 const char *p = opc->args;
7772 char c;
7773 unsigned long used_bits = opc->mask;
7775 if ((used_bits & opc->match) != opc->match)
7777 as_bad (_("internal: bad mips opcode (mask error): %s %s"),
7778 opc->name, opc->args);
7779 return 0;
7781 #define USE_BITS(mask,shift) (used_bits |= ((mask) << (shift)))
7782 while (*p)
7783 switch (c = *p++)
7785 case ',': break;
7786 case '(': break;
7787 case ')': break;
7788 case '+':
7789 switch (c = *p++)
7791 case 'A': USE_BITS (OP_MASK_SHAMT, OP_SH_SHAMT); break;
7792 case 'B': USE_BITS (OP_MASK_INSMSB, OP_SH_INSMSB); break;
7793 case 'C': USE_BITS (OP_MASK_EXTMSBD, OP_SH_EXTMSBD); break;
7794 case 'D': USE_BITS (OP_MASK_RD, OP_SH_RD);
7795 USE_BITS (OP_MASK_SEL, OP_SH_SEL); break;
7796 case 'E': USE_BITS (OP_MASK_SHAMT, OP_SH_SHAMT); break;
7797 case 'F': USE_BITS (OP_MASK_INSMSB, OP_SH_INSMSB); break;
7798 case 'G': USE_BITS (OP_MASK_EXTMSBD, OP_SH_EXTMSBD); break;
7799 case 'H': USE_BITS (OP_MASK_EXTMSBD, OP_SH_EXTMSBD); break;
7800 case 'I': break;
7801 default:
7802 as_bad (_("internal: bad mips opcode (unknown extension operand type `+%c'): %s %s"),
7803 c, opc->name, opc->args);
7804 return 0;
7806 break;
7807 case '<': USE_BITS (OP_MASK_SHAMT, OP_SH_SHAMT); break;
7808 case '>': USE_BITS (OP_MASK_SHAMT, OP_SH_SHAMT); break;
7809 case 'A': break;
7810 case 'B': USE_BITS (OP_MASK_CODE20, OP_SH_CODE20); break;
7811 case 'C': USE_BITS (OP_MASK_COPZ, OP_SH_COPZ); break;
7812 case 'D': USE_BITS (OP_MASK_FD, OP_SH_FD); break;
7813 case 'E': USE_BITS (OP_MASK_RT, OP_SH_RT); break;
7814 case 'F': break;
7815 case 'G': USE_BITS (OP_MASK_RD, OP_SH_RD); break;
7816 case 'H': USE_BITS (OP_MASK_SEL, OP_SH_SEL); break;
7817 case 'I': break;
7818 case 'J': USE_BITS (OP_MASK_CODE19, OP_SH_CODE19); break;
7819 case 'K': USE_BITS (OP_MASK_RD, OP_SH_RD); break;
7820 case 'L': break;
7821 case 'M': USE_BITS (OP_MASK_CCC, OP_SH_CCC); break;
7822 case 'N': USE_BITS (OP_MASK_BCC, OP_SH_BCC); break;
7823 case 'O': USE_BITS (OP_MASK_ALN, OP_SH_ALN); break;
7824 case 'Q': USE_BITS (OP_MASK_VSEL, OP_SH_VSEL);
7825 USE_BITS (OP_MASK_FT, OP_SH_FT); break;
7826 case 'R': USE_BITS (OP_MASK_FR, OP_SH_FR); break;
7827 case 'S': USE_BITS (OP_MASK_FS, OP_SH_FS); break;
7828 case 'T': USE_BITS (OP_MASK_FT, OP_SH_FT); break;
7829 case 'V': USE_BITS (OP_MASK_FS, OP_SH_FS); break;
7830 case 'W': USE_BITS (OP_MASK_FT, OP_SH_FT); break;
7831 case 'X': USE_BITS (OP_MASK_FD, OP_SH_FD); break;
7832 case 'Y': USE_BITS (OP_MASK_FS, OP_SH_FS); break;
7833 case 'Z': USE_BITS (OP_MASK_FT, OP_SH_FT); break;
7834 case 'a': USE_BITS (OP_MASK_TARGET, OP_SH_TARGET); break;
7835 case 'b': USE_BITS (OP_MASK_RS, OP_SH_RS); break;
7836 case 'c': USE_BITS (OP_MASK_CODE, OP_SH_CODE); break;
7837 case 'd': USE_BITS (OP_MASK_RD, OP_SH_RD); break;
7838 case 'f': break;
7839 case 'h': USE_BITS (OP_MASK_PREFX, OP_SH_PREFX); break;
7840 case 'i': USE_BITS (OP_MASK_IMMEDIATE, OP_SH_IMMEDIATE); break;
7841 case 'j': USE_BITS (OP_MASK_DELTA, OP_SH_DELTA); break;
7842 case 'k': USE_BITS (OP_MASK_CACHE, OP_SH_CACHE); break;
7843 case 'l': break;
7844 case 'o': USE_BITS (OP_MASK_DELTA, OP_SH_DELTA); break;
7845 case 'p': USE_BITS (OP_MASK_DELTA, OP_SH_DELTA); break;
7846 case 'q': USE_BITS (OP_MASK_CODE2, OP_SH_CODE2); break;
7847 case 'r': USE_BITS (OP_MASK_RS, OP_SH_RS); break;
7848 case 's': USE_BITS (OP_MASK_RS, OP_SH_RS); break;
7849 case 't': USE_BITS (OP_MASK_RT, OP_SH_RT); break;
7850 case 'u': USE_BITS (OP_MASK_IMMEDIATE, OP_SH_IMMEDIATE); break;
7851 case 'v': USE_BITS (OP_MASK_RS, OP_SH_RS); break;
7852 case 'w': USE_BITS (OP_MASK_RT, OP_SH_RT); break;
7853 case 'x': break;
7854 case 'z': break;
7855 case 'P': USE_BITS (OP_MASK_PERFREG, OP_SH_PERFREG); break;
7856 case 'U': USE_BITS (OP_MASK_RD, OP_SH_RD);
7857 USE_BITS (OP_MASK_RT, OP_SH_RT); break;
7858 case 'e': USE_BITS (OP_MASK_VECBYTE, OP_SH_VECBYTE); break;
7859 case '%': USE_BITS (OP_MASK_VECALIGN, OP_SH_VECALIGN); break;
7860 case '[': break;
7861 case ']': break;
7862 default:
7863 as_bad (_("internal: bad mips opcode (unknown operand type `%c'): %s %s"),
7864 c, opc->name, opc->args);
7865 return 0;
7867 #undef USE_BITS
7868 if (used_bits != 0xffffffff)
7870 as_bad (_("internal: bad mips opcode (bits 0x%lx undefined): %s %s"),
7871 ~used_bits & 0xffffffff, opc->name, opc->args);
7872 return 0;
7874 return 1;
7877 /* This routine assembles an instruction into its binary format. As a
7878 side effect, it sets one of the global variables imm_reloc or
7879 offset_reloc to the type of relocation to do if one of the operands
7880 is an address expression. */
7882 static void
7883 mips_ip (char *str, struct mips_cl_insn *ip)
7885 char *s;
7886 const char *args;
7887 char c = 0;
7888 struct mips_opcode *insn;
7889 char *argsStart;
7890 unsigned int regno;
7891 unsigned int lastregno = 0;
7892 unsigned int lastpos = 0;
7893 unsigned int limlo, limhi;
7894 char *s_reset;
7895 char save_c = 0;
7897 insn_error = NULL;
7899 /* If the instruction contains a '.', we first try to match an instruction
7900 including the '.'. Then we try again without the '.'. */
7901 insn = NULL;
7902 for (s = str; *s != '\0' && !ISSPACE (*s); ++s)
7903 continue;
7905 /* If we stopped on whitespace, then replace the whitespace with null for
7906 the call to hash_find. Save the character we replaced just in case we
7907 have to re-parse the instruction. */
7908 if (ISSPACE (*s))
7910 save_c = *s;
7911 *s++ = '\0';
7914 insn = (struct mips_opcode *) hash_find (op_hash, str);
7916 /* If we didn't find the instruction in the opcode table, try again, but
7917 this time with just the instruction up to, but not including the
7918 first '.'. */
7919 if (insn == NULL)
7921 /* Restore the character we overwrite above (if any). */
7922 if (save_c)
7923 *(--s) = save_c;
7925 /* Scan up to the first '.' or whitespace. */
7926 for (s = str;
7927 *s != '\0' && *s != '.' && !ISSPACE (*s);
7928 ++s)
7929 continue;
7931 /* If we did not find a '.', then we can quit now. */
7932 if (*s != '.')
7934 insn_error = "unrecognized opcode";
7935 return;
7938 /* Lookup the instruction in the hash table. */
7939 *s++ = '\0';
7940 if ((insn = (struct mips_opcode *) hash_find (op_hash, str)) == NULL)
7942 insn_error = "unrecognized opcode";
7943 return;
7947 argsStart = s;
7948 for (;;)
7950 bfd_boolean ok;
7952 assert (strcmp (insn->name, str) == 0);
7954 if (OPCODE_IS_MEMBER (insn,
7955 (mips_opts.isa
7956 | (file_ase_mips16 ? INSN_MIPS16 : 0)
7957 | (mips_opts.ase_mdmx ? INSN_MDMX : 0)
7958 | (mips_opts.ase_mips3d ? INSN_MIPS3D : 0)),
7959 mips_opts.arch))
7960 ok = TRUE;
7961 else
7962 ok = FALSE;
7964 if (insn->pinfo != INSN_MACRO)
7966 if (mips_opts.arch == CPU_R4650 && (insn->pinfo & FP_D) != 0)
7967 ok = FALSE;
7970 if (! ok)
7972 if (insn + 1 < &mips_opcodes[NUMOPCODES]
7973 && strcmp (insn->name, insn[1].name) == 0)
7975 ++insn;
7976 continue;
7978 else
7980 if (!insn_error)
7982 static char buf[100];
7983 sprintf (buf,
7984 _("opcode not supported on this processor: %s (%s)"),
7985 mips_cpu_info_from_arch (mips_opts.arch)->name,
7986 mips_cpu_info_from_isa (mips_opts.isa)->name);
7987 insn_error = buf;
7989 if (save_c)
7990 *(--s) = save_c;
7991 return;
7995 ip->insn_mo = insn;
7996 ip->insn_opcode = insn->match;
7997 insn_error = NULL;
7998 for (args = insn->args;; ++args)
8000 int is_mdmx;
8002 s += strspn (s, " \t");
8003 is_mdmx = 0;
8004 switch (*args)
8006 case '\0': /* end of args */
8007 if (*s == '\0')
8008 return;
8009 break;
8011 case ',':
8012 if (*s++ == *args)
8013 continue;
8014 s--;
8015 switch (*++args)
8017 case 'r':
8018 case 'v':
8019 ip->insn_opcode |= lastregno << OP_SH_RS;
8020 continue;
8022 case 'w':
8023 ip->insn_opcode |= lastregno << OP_SH_RT;
8024 continue;
8026 case 'W':
8027 ip->insn_opcode |= lastregno << OP_SH_FT;
8028 continue;
8030 case 'V':
8031 ip->insn_opcode |= lastregno << OP_SH_FS;
8032 continue;
8034 break;
8036 case '(':
8037 /* Handle optional base register.
8038 Either the base register is omitted or
8039 we must have a left paren. */
8040 /* This is dependent on the next operand specifier
8041 is a base register specification. */
8042 assert (args[1] == 'b' || args[1] == '5'
8043 || args[1] == '-' || args[1] == '4');
8044 if (*s == '\0')
8045 return;
8047 case ')': /* these must match exactly */
8048 case '[':
8049 case ']':
8050 if (*s++ == *args)
8051 continue;
8052 break;
8054 case '+': /* Opcode extension character. */
8055 switch (*++args)
8057 case 'A': /* ins/ext position, becomes LSB. */
8058 limlo = 0;
8059 limhi = 31;
8060 goto do_lsb;
8061 case 'E':
8062 limlo = 32;
8063 limhi = 63;
8064 goto do_lsb;
8065 do_lsb:
8066 my_getExpression (&imm_expr, s);
8067 check_absolute_expr (ip, &imm_expr);
8068 if ((unsigned long) imm_expr.X_add_number < limlo
8069 || (unsigned long) imm_expr.X_add_number > limhi)
8071 as_bad (_("Improper position (%lu)"),
8072 (unsigned long) imm_expr.X_add_number);
8073 imm_expr.X_add_number = limlo;
8075 lastpos = imm_expr.X_add_number;
8076 ip->insn_opcode |= (imm_expr.X_add_number
8077 & OP_MASK_SHAMT) << OP_SH_SHAMT;
8078 imm_expr.X_op = O_absent;
8079 s = expr_end;
8080 continue;
8082 case 'B': /* ins size, becomes MSB. */
8083 limlo = 1;
8084 limhi = 32;
8085 goto do_msb;
8086 case 'F':
8087 limlo = 33;
8088 limhi = 64;
8089 goto do_msb;
8090 do_msb:
8091 my_getExpression (&imm_expr, s);
8092 check_absolute_expr (ip, &imm_expr);
8093 /* Check for negative input so that small negative numbers
8094 will not succeed incorrectly. The checks against
8095 (pos+size) transitively check "size" itself,
8096 assuming that "pos" is reasonable. */
8097 if ((long) imm_expr.X_add_number < 0
8098 || ((unsigned long) imm_expr.X_add_number
8099 + lastpos) < limlo
8100 || ((unsigned long) imm_expr.X_add_number
8101 + lastpos) > limhi)
8103 as_bad (_("Improper insert size (%lu, position %lu)"),
8104 (unsigned long) imm_expr.X_add_number,
8105 (unsigned long) lastpos);
8106 imm_expr.X_add_number = limlo - lastpos;
8108 ip->insn_opcode |= ((lastpos + imm_expr.X_add_number - 1)
8109 & OP_MASK_INSMSB) << OP_SH_INSMSB;
8110 imm_expr.X_op = O_absent;
8111 s = expr_end;
8112 continue;
8114 case 'C': /* ext size, becomes MSBD. */
8115 limlo = 1;
8116 limhi = 32;
8117 goto do_msbd;
8118 case 'G':
8119 limlo = 33;
8120 limhi = 64;
8121 goto do_msbd;
8122 case 'H':
8123 limlo = 33;
8124 limhi = 64;
8125 goto do_msbd;
8126 do_msbd:
8127 my_getExpression (&imm_expr, s);
8128 check_absolute_expr (ip, &imm_expr);
8129 /* Check for negative input so that small negative numbers
8130 will not succeed incorrectly. The checks against
8131 (pos+size) transitively check "size" itself,
8132 assuming that "pos" is reasonable. */
8133 if ((long) imm_expr.X_add_number < 0
8134 || ((unsigned long) imm_expr.X_add_number
8135 + lastpos) < limlo
8136 || ((unsigned long) imm_expr.X_add_number
8137 + lastpos) > limhi)
8139 as_bad (_("Improper extract size (%lu, position %lu)"),
8140 (unsigned long) imm_expr.X_add_number,
8141 (unsigned long) lastpos);
8142 imm_expr.X_add_number = limlo - lastpos;
8144 ip->insn_opcode |= ((imm_expr.X_add_number - 1)
8145 & OP_MASK_EXTMSBD) << OP_SH_EXTMSBD;
8146 imm_expr.X_op = O_absent;
8147 s = expr_end;
8148 continue;
8150 case 'D':
8151 /* +D is for disassembly only; never match. */
8152 break;
8154 case 'I':
8155 /* "+I" is like "I", except that imm2_expr is used. */
8156 my_getExpression (&imm2_expr, s);
8157 if (imm2_expr.X_op != O_big
8158 && imm2_expr.X_op != O_constant)
8159 insn_error = _("absolute expression required");
8160 normalize_constant_expr (&imm2_expr);
8161 s = expr_end;
8162 continue;
8164 default:
8165 as_bad (_("internal: bad mips opcode (unknown extension operand type `+%c'): %s %s"),
8166 *args, insn->name, insn->args);
8167 /* Further processing is fruitless. */
8168 return;
8170 break;
8172 case '<': /* must be at least one digit */
8174 * According to the manual, if the shift amount is greater
8175 * than 31 or less than 0, then the shift amount should be
8176 * mod 32. In reality the mips assembler issues an error.
8177 * We issue a warning and mask out all but the low 5 bits.
8179 my_getExpression (&imm_expr, s);
8180 check_absolute_expr (ip, &imm_expr);
8181 if ((unsigned long) imm_expr.X_add_number > 31)
8183 as_warn (_("Improper shift amount (%lu)"),
8184 (unsigned long) imm_expr.X_add_number);
8185 imm_expr.X_add_number &= OP_MASK_SHAMT;
8187 ip->insn_opcode |= imm_expr.X_add_number << OP_SH_SHAMT;
8188 imm_expr.X_op = O_absent;
8189 s = expr_end;
8190 continue;
8192 case '>': /* shift amount minus 32 */
8193 my_getExpression (&imm_expr, s);
8194 check_absolute_expr (ip, &imm_expr);
8195 if ((unsigned long) imm_expr.X_add_number < 32
8196 || (unsigned long) imm_expr.X_add_number > 63)
8197 break;
8198 ip->insn_opcode |= (imm_expr.X_add_number - 32) << OP_SH_SHAMT;
8199 imm_expr.X_op = O_absent;
8200 s = expr_end;
8201 continue;
8203 case 'k': /* cache code */
8204 case 'h': /* prefx code */
8205 my_getExpression (&imm_expr, s);
8206 check_absolute_expr (ip, &imm_expr);
8207 if ((unsigned long) imm_expr.X_add_number > 31)
8209 as_warn (_("Invalid value for `%s' (%lu)"),
8210 ip->insn_mo->name,
8211 (unsigned long) imm_expr.X_add_number);
8212 imm_expr.X_add_number &= 0x1f;
8214 if (*args == 'k')
8215 ip->insn_opcode |= imm_expr.X_add_number << OP_SH_CACHE;
8216 else
8217 ip->insn_opcode |= imm_expr.X_add_number << OP_SH_PREFX;
8218 imm_expr.X_op = O_absent;
8219 s = expr_end;
8220 continue;
8222 case 'c': /* break code */
8223 my_getExpression (&imm_expr, s);
8224 check_absolute_expr (ip, &imm_expr);
8225 if ((unsigned long) imm_expr.X_add_number > 1023)
8227 as_warn (_("Illegal break code (%lu)"),
8228 (unsigned long) imm_expr.X_add_number);
8229 imm_expr.X_add_number &= OP_MASK_CODE;
8231 ip->insn_opcode |= imm_expr.X_add_number << OP_SH_CODE;
8232 imm_expr.X_op = O_absent;
8233 s = expr_end;
8234 continue;
8236 case 'q': /* lower break code */
8237 my_getExpression (&imm_expr, s);
8238 check_absolute_expr (ip, &imm_expr);
8239 if ((unsigned long) imm_expr.X_add_number > 1023)
8241 as_warn (_("Illegal lower break code (%lu)"),
8242 (unsigned long) imm_expr.X_add_number);
8243 imm_expr.X_add_number &= OP_MASK_CODE2;
8245 ip->insn_opcode |= imm_expr.X_add_number << OP_SH_CODE2;
8246 imm_expr.X_op = O_absent;
8247 s = expr_end;
8248 continue;
8250 case 'B': /* 20-bit syscall/break code. */
8251 my_getExpression (&imm_expr, s);
8252 check_absolute_expr (ip, &imm_expr);
8253 if ((unsigned long) imm_expr.X_add_number > OP_MASK_CODE20)
8254 as_warn (_("Illegal 20-bit code (%lu)"),
8255 (unsigned long) imm_expr.X_add_number);
8256 ip->insn_opcode |= imm_expr.X_add_number << OP_SH_CODE20;
8257 imm_expr.X_op = O_absent;
8258 s = expr_end;
8259 continue;
8261 case 'C': /* Coprocessor code */
8262 my_getExpression (&imm_expr, s);
8263 check_absolute_expr (ip, &imm_expr);
8264 if ((unsigned long) imm_expr.X_add_number >= (1 << 25))
8266 as_warn (_("Coproccesor code > 25 bits (%lu)"),
8267 (unsigned long) imm_expr.X_add_number);
8268 imm_expr.X_add_number &= ((1 << 25) - 1);
8270 ip->insn_opcode |= imm_expr.X_add_number;
8271 imm_expr.X_op = O_absent;
8272 s = expr_end;
8273 continue;
8275 case 'J': /* 19-bit wait code. */
8276 my_getExpression (&imm_expr, s);
8277 check_absolute_expr (ip, &imm_expr);
8278 if ((unsigned long) imm_expr.X_add_number > OP_MASK_CODE19)
8279 as_warn (_("Illegal 19-bit code (%lu)"),
8280 (unsigned long) imm_expr.X_add_number);
8281 ip->insn_opcode |= imm_expr.X_add_number << OP_SH_CODE19;
8282 imm_expr.X_op = O_absent;
8283 s = expr_end;
8284 continue;
8286 case 'P': /* Performance register */
8287 my_getExpression (&imm_expr, s);
8288 check_absolute_expr (ip, &imm_expr);
8289 if (imm_expr.X_add_number != 0 && imm_expr.X_add_number != 1)
8291 as_warn (_("Invalid performance register (%lu)"),
8292 (unsigned long) imm_expr.X_add_number);
8293 imm_expr.X_add_number &= OP_MASK_PERFREG;
8295 ip->insn_opcode |= (imm_expr.X_add_number << OP_SH_PERFREG);
8296 imm_expr.X_op = O_absent;
8297 s = expr_end;
8298 continue;
8300 case 'b': /* base register */
8301 case 'd': /* destination register */
8302 case 's': /* source register */
8303 case 't': /* target register */
8304 case 'r': /* both target and source */
8305 case 'v': /* both dest and source */
8306 case 'w': /* both dest and target */
8307 case 'E': /* coprocessor target register */
8308 case 'G': /* coprocessor destination register */
8309 case 'K': /* 'rdhwr' destination register */
8310 case 'x': /* ignore register name */
8311 case 'z': /* must be zero register */
8312 case 'U': /* destination register (clo/clz). */
8313 s_reset = s;
8314 if (s[0] == '$')
8317 if (ISDIGIT (s[1]))
8319 ++s;
8320 regno = 0;
8323 regno *= 10;
8324 regno += *s - '0';
8325 ++s;
8327 while (ISDIGIT (*s));
8328 if (regno > 31)
8329 as_bad (_("Invalid register number (%d)"), regno);
8331 else if (*args == 'E' || *args == 'G' || *args == 'K')
8332 goto notreg;
8333 else
8335 if (s[1] == 'r' && s[2] == 'a')
8337 s += 3;
8338 regno = RA;
8340 else if (s[1] == 'f' && s[2] == 'p')
8342 s += 3;
8343 regno = FP;
8345 else if (s[1] == 's' && s[2] == 'p')
8347 s += 3;
8348 regno = SP;
8350 else if (s[1] == 'g' && s[2] == 'p')
8352 s += 3;
8353 regno = GP;
8355 else if (s[1] == 'a' && s[2] == 't')
8357 s += 3;
8358 regno = AT;
8360 else if (s[1] == 'k' && s[2] == 't' && s[3] == '0')
8362 s += 4;
8363 regno = KT0;
8365 else if (s[1] == 'k' && s[2] == 't' && s[3] == '1')
8367 s += 4;
8368 regno = KT1;
8370 else if (s[1] == 'z' && s[2] == 'e' && s[3] == 'r' && s[4] == 'o')
8372 s += 5;
8373 regno = ZERO;
8375 else if (itbl_have_entries)
8377 char *p, *n;
8378 unsigned long r;
8380 p = s + 1; /* advance past '$' */
8381 n = itbl_get_field (&p); /* n is name */
8383 /* See if this is a register defined in an
8384 itbl entry. */
8385 if (itbl_get_reg_val (n, &r))
8387 /* Get_field advances to the start of
8388 the next field, so we need to back
8389 rack to the end of the last field. */
8390 if (p)
8391 s = p - 1;
8392 else
8393 s = strchr (s, '\0');
8394 regno = r;
8396 else
8397 goto notreg;
8399 else
8400 goto notreg;
8402 if (regno == AT
8403 && ! mips_opts.noat
8404 && *args != 'E'
8405 && *args != 'G'
8406 && *args != 'K')
8407 as_warn (_("Used $at without \".set noat\""));
8408 c = *args;
8409 if (*s == ' ')
8410 ++s;
8411 if (args[1] != *s)
8413 if (c == 'r' || c == 'v' || c == 'w')
8415 regno = lastregno;
8416 s = s_reset;
8417 ++args;
8420 /* 'z' only matches $0. */
8421 if (c == 'z' && regno != 0)
8422 break;
8424 /* Now that we have assembled one operand, we use the args string
8425 * to figure out where it goes in the instruction. */
8426 switch (c)
8428 case 'r':
8429 case 's':
8430 case 'v':
8431 case 'b':
8432 ip->insn_opcode |= regno << OP_SH_RS;
8433 break;
8434 case 'd':
8435 case 'G':
8436 case 'K':
8437 ip->insn_opcode |= regno << OP_SH_RD;
8438 break;
8439 case 'U':
8440 ip->insn_opcode |= regno << OP_SH_RD;
8441 ip->insn_opcode |= regno << OP_SH_RT;
8442 break;
8443 case 'w':
8444 case 't':
8445 case 'E':
8446 ip->insn_opcode |= regno << OP_SH_RT;
8447 break;
8448 case 'x':
8449 /* This case exists because on the r3000 trunc
8450 expands into a macro which requires a gp
8451 register. On the r6000 or r4000 it is
8452 assembled into a single instruction which
8453 ignores the register. Thus the insn version
8454 is MIPS_ISA2 and uses 'x', and the macro
8455 version is MIPS_ISA1 and uses 't'. */
8456 break;
8457 case 'z':
8458 /* This case is for the div instruction, which
8459 acts differently if the destination argument
8460 is $0. This only matches $0, and is checked
8461 outside the switch. */
8462 break;
8463 case 'D':
8464 /* Itbl operand; not yet implemented. FIXME ?? */
8465 break;
8466 /* What about all other operands like 'i', which
8467 can be specified in the opcode table? */
8469 lastregno = regno;
8470 continue;
8472 notreg:
8473 switch (*args++)
8475 case 'r':
8476 case 'v':
8477 ip->insn_opcode |= lastregno << OP_SH_RS;
8478 continue;
8479 case 'w':
8480 ip->insn_opcode |= lastregno << OP_SH_RT;
8481 continue;
8483 break;
8485 case 'O': /* MDMX alignment immediate constant. */
8486 my_getExpression (&imm_expr, s);
8487 check_absolute_expr (ip, &imm_expr);
8488 if ((unsigned long) imm_expr.X_add_number > OP_MASK_ALN)
8490 as_warn ("Improper align amount (%ld), using low bits",
8491 (long) imm_expr.X_add_number);
8492 imm_expr.X_add_number &= OP_MASK_ALN;
8494 ip->insn_opcode |= imm_expr.X_add_number << OP_SH_ALN;
8495 imm_expr.X_op = O_absent;
8496 s = expr_end;
8497 continue;
8499 case 'Q': /* MDMX vector, element sel, or const. */
8500 if (s[0] != '$')
8502 /* MDMX Immediate. */
8503 my_getExpression (&imm_expr, s);
8504 check_absolute_expr (ip, &imm_expr);
8505 if ((unsigned long) imm_expr.X_add_number > OP_MASK_FT)
8507 as_warn (_("Invalid MDMX Immediate (%ld)"),
8508 (long) imm_expr.X_add_number);
8509 imm_expr.X_add_number &= OP_MASK_FT;
8511 imm_expr.X_add_number &= OP_MASK_FT;
8512 if (ip->insn_opcode & (OP_MASK_VSEL << OP_SH_VSEL))
8513 ip->insn_opcode |= MDMX_FMTSEL_IMM_QH << OP_SH_VSEL;
8514 else
8515 ip->insn_opcode |= MDMX_FMTSEL_IMM_OB << OP_SH_VSEL;
8516 ip->insn_opcode |= imm_expr.X_add_number << OP_SH_FT;
8517 imm_expr.X_op = O_absent;
8518 s = expr_end;
8519 continue;
8521 /* Not MDMX Immediate. Fall through. */
8522 case 'X': /* MDMX destination register. */
8523 case 'Y': /* MDMX source register. */
8524 case 'Z': /* MDMX target register. */
8525 is_mdmx = 1;
8526 case 'D': /* floating point destination register */
8527 case 'S': /* floating point source register */
8528 case 'T': /* floating point target register */
8529 case 'R': /* floating point source register */
8530 case 'V':
8531 case 'W':
8532 s_reset = s;
8533 /* Accept $fN for FP and MDMX register numbers, and in
8534 addition accept $vN for MDMX register numbers. */
8535 if ((s[0] == '$' && s[1] == 'f' && ISDIGIT (s[2]))
8536 || (is_mdmx != 0 && s[0] == '$' && s[1] == 'v'
8537 && ISDIGIT (s[2])))
8539 s += 2;
8540 regno = 0;
8543 regno *= 10;
8544 regno += *s - '0';
8545 ++s;
8547 while (ISDIGIT (*s));
8549 if (regno > 31)
8550 as_bad (_("Invalid float register number (%d)"), regno);
8552 if ((regno & 1) != 0
8553 && HAVE_32BIT_FPRS
8554 && ! (strcmp (str, "mtc1") == 0
8555 || strcmp (str, "mfc1") == 0
8556 || strcmp (str, "lwc1") == 0
8557 || strcmp (str, "swc1") == 0
8558 || strcmp (str, "l.s") == 0
8559 || strcmp (str, "s.s") == 0))
8560 as_warn (_("Float register should be even, was %d"),
8561 regno);
8563 c = *args;
8564 if (*s == ' ')
8565 ++s;
8566 if (args[1] != *s)
8568 if (c == 'V' || c == 'W')
8570 regno = lastregno;
8571 s = s_reset;
8572 ++args;
8575 switch (c)
8577 case 'D':
8578 case 'X':
8579 ip->insn_opcode |= regno << OP_SH_FD;
8580 break;
8581 case 'V':
8582 case 'S':
8583 case 'Y':
8584 ip->insn_opcode |= regno << OP_SH_FS;
8585 break;
8586 case 'Q':
8587 /* This is like 'Z', but also needs to fix the MDMX
8588 vector/scalar select bits. Note that the
8589 scalar immediate case is handled above. */
8590 if (*s == '[')
8592 int is_qh = (ip->insn_opcode & (1 << OP_SH_VSEL));
8593 int max_el = (is_qh ? 3 : 7);
8594 s++;
8595 my_getExpression(&imm_expr, s);
8596 check_absolute_expr (ip, &imm_expr);
8597 s = expr_end;
8598 if (imm_expr.X_add_number > max_el)
8599 as_bad(_("Bad element selector %ld"),
8600 (long) imm_expr.X_add_number);
8601 imm_expr.X_add_number &= max_el;
8602 ip->insn_opcode |= (imm_expr.X_add_number
8603 << (OP_SH_VSEL +
8604 (is_qh ? 2 : 1)));
8605 imm_expr.X_op = O_absent;
8606 if (*s != ']')
8607 as_warn(_("Expecting ']' found '%s'"), s);
8608 else
8609 s++;
8611 else
8613 if (ip->insn_opcode & (OP_MASK_VSEL << OP_SH_VSEL))
8614 ip->insn_opcode |= (MDMX_FMTSEL_VEC_QH
8615 << OP_SH_VSEL);
8616 else
8617 ip->insn_opcode |= (MDMX_FMTSEL_VEC_OB <<
8618 OP_SH_VSEL);
8620 /* Fall through */
8621 case 'W':
8622 case 'T':
8623 case 'Z':
8624 ip->insn_opcode |= regno << OP_SH_FT;
8625 break;
8626 case 'R':
8627 ip->insn_opcode |= regno << OP_SH_FR;
8628 break;
8630 lastregno = regno;
8631 continue;
8634 switch (*args++)
8636 case 'V':
8637 ip->insn_opcode |= lastregno << OP_SH_FS;
8638 continue;
8639 case 'W':
8640 ip->insn_opcode |= lastregno << OP_SH_FT;
8641 continue;
8643 break;
8645 case 'I':
8646 my_getExpression (&imm_expr, s);
8647 if (imm_expr.X_op != O_big
8648 && imm_expr.X_op != O_constant)
8649 insn_error = _("absolute expression required");
8650 normalize_constant_expr (&imm_expr);
8651 s = expr_end;
8652 continue;
8654 case 'A':
8655 my_getExpression (&offset_expr, s);
8656 *imm_reloc = BFD_RELOC_32;
8657 s = expr_end;
8658 continue;
8660 case 'F':
8661 case 'L':
8662 case 'f':
8663 case 'l':
8665 int f64;
8666 int using_gprs;
8667 char *save_in;
8668 char *err;
8669 unsigned char temp[8];
8670 int len;
8671 unsigned int length;
8672 segT seg;
8673 subsegT subseg;
8674 char *p;
8676 /* These only appear as the last operand in an
8677 instruction, and every instruction that accepts
8678 them in any variant accepts them in all variants.
8679 This means we don't have to worry about backing out
8680 any changes if the instruction does not match.
8682 The difference between them is the size of the
8683 floating point constant and where it goes. For 'F'
8684 and 'L' the constant is 64 bits; for 'f' and 'l' it
8685 is 32 bits. Where the constant is placed is based
8686 on how the MIPS assembler does things:
8687 F -- .rdata
8688 L -- .lit8
8689 f -- immediate value
8690 l -- .lit4
8692 The .lit4 and .lit8 sections are only used if
8693 permitted by the -G argument.
8695 The code below needs to know whether the target register
8696 is 32 or 64 bits wide. It relies on the fact 'f' and
8697 'F' are used with GPR-based instructions and 'l' and
8698 'L' are used with FPR-based instructions. */
8700 f64 = *args == 'F' || *args == 'L';
8701 using_gprs = *args == 'F' || *args == 'f';
8703 save_in = input_line_pointer;
8704 input_line_pointer = s;
8705 err = md_atof (f64 ? 'd' : 'f', (char *) temp, &len);
8706 length = len;
8707 s = input_line_pointer;
8708 input_line_pointer = save_in;
8709 if (err != NULL && *err != '\0')
8711 as_bad (_("Bad floating point constant: %s"), err);
8712 memset (temp, '\0', sizeof temp);
8713 length = f64 ? 8 : 4;
8716 assert (length == (unsigned) (f64 ? 8 : 4));
8718 if (*args == 'f'
8719 || (*args == 'l'
8720 && (g_switch_value < 4
8721 || (temp[0] == 0 && temp[1] == 0)
8722 || (temp[2] == 0 && temp[3] == 0))))
8724 imm_expr.X_op = O_constant;
8725 if (! target_big_endian)
8726 imm_expr.X_add_number = bfd_getl32 (temp);
8727 else
8728 imm_expr.X_add_number = bfd_getb32 (temp);
8730 else if (length > 4
8731 && ! mips_disable_float_construction
8732 /* Constants can only be constructed in GPRs and
8733 copied to FPRs if the GPRs are at least as wide
8734 as the FPRs. Force the constant into memory if
8735 we are using 64-bit FPRs but the GPRs are only
8736 32 bits wide. */
8737 && (using_gprs
8738 || ! (HAVE_64BIT_FPRS && HAVE_32BIT_GPRS))
8739 && ((temp[0] == 0 && temp[1] == 0)
8740 || (temp[2] == 0 && temp[3] == 0))
8741 && ((temp[4] == 0 && temp[5] == 0)
8742 || (temp[6] == 0 && temp[7] == 0)))
8744 /* The value is simple enough to load with a couple of
8745 instructions. If using 32-bit registers, set
8746 imm_expr to the high order 32 bits and offset_expr to
8747 the low order 32 bits. Otherwise, set imm_expr to
8748 the entire 64 bit constant. */
8749 if (using_gprs ? HAVE_32BIT_GPRS : HAVE_32BIT_FPRS)
8751 imm_expr.X_op = O_constant;
8752 offset_expr.X_op = O_constant;
8753 if (! target_big_endian)
8755 imm_expr.X_add_number = bfd_getl32 (temp + 4);
8756 offset_expr.X_add_number = bfd_getl32 (temp);
8758 else
8760 imm_expr.X_add_number = bfd_getb32 (temp);
8761 offset_expr.X_add_number = bfd_getb32 (temp + 4);
8763 if (offset_expr.X_add_number == 0)
8764 offset_expr.X_op = O_absent;
8766 else if (sizeof (imm_expr.X_add_number) > 4)
8768 imm_expr.X_op = O_constant;
8769 if (! target_big_endian)
8770 imm_expr.X_add_number = bfd_getl64 (temp);
8771 else
8772 imm_expr.X_add_number = bfd_getb64 (temp);
8774 else
8776 imm_expr.X_op = O_big;
8777 imm_expr.X_add_number = 4;
8778 if (! target_big_endian)
8780 generic_bignum[0] = bfd_getl16 (temp);
8781 generic_bignum[1] = bfd_getl16 (temp + 2);
8782 generic_bignum[2] = bfd_getl16 (temp + 4);
8783 generic_bignum[3] = bfd_getl16 (temp + 6);
8785 else
8787 generic_bignum[0] = bfd_getb16 (temp + 6);
8788 generic_bignum[1] = bfd_getb16 (temp + 4);
8789 generic_bignum[2] = bfd_getb16 (temp + 2);
8790 generic_bignum[3] = bfd_getb16 (temp);
8794 else
8796 const char *newname;
8797 segT new_seg;
8799 /* Switch to the right section. */
8800 seg = now_seg;
8801 subseg = now_subseg;
8802 switch (*args)
8804 default: /* unused default case avoids warnings. */
8805 case 'L':
8806 newname = RDATA_SECTION_NAME;
8807 if (g_switch_value >= 8)
8808 newname = ".lit8";
8809 break;
8810 case 'F':
8811 newname = RDATA_SECTION_NAME;
8812 break;
8813 case 'l':
8814 assert (g_switch_value >= 4);
8815 newname = ".lit4";
8816 break;
8818 new_seg = subseg_new (newname, (subsegT) 0);
8819 if (OUTPUT_FLAVOR == bfd_target_elf_flavour)
8820 bfd_set_section_flags (stdoutput, new_seg,
8821 (SEC_ALLOC
8822 | SEC_LOAD
8823 | SEC_READONLY
8824 | SEC_DATA));
8825 frag_align (*args == 'l' ? 2 : 3, 0, 0);
8826 if (OUTPUT_FLAVOR == bfd_target_elf_flavour
8827 && strcmp (TARGET_OS, "elf") != 0)
8828 record_alignment (new_seg, 4);
8829 else
8830 record_alignment (new_seg, *args == 'l' ? 2 : 3);
8831 if (seg == now_seg)
8832 as_bad (_("Can't use floating point insn in this section"));
8834 /* Set the argument to the current address in the
8835 section. */
8836 offset_expr.X_op = O_symbol;
8837 offset_expr.X_add_symbol =
8838 symbol_new ("L0\001", now_seg,
8839 (valueT) frag_now_fix (), frag_now);
8840 offset_expr.X_add_number = 0;
8842 /* Put the floating point number into the section. */
8843 p = frag_more ((int) length);
8844 memcpy (p, temp, length);
8846 /* Switch back to the original section. */
8847 subseg_set (seg, subseg);
8850 continue;
8852 case 'i': /* 16 bit unsigned immediate */
8853 case 'j': /* 16 bit signed immediate */
8854 *imm_reloc = BFD_RELOC_LO16;
8855 if (my_getSmallExpression (&imm_expr, imm_reloc, s) == 0)
8857 int more;
8858 offsetT minval, maxval;
8860 more = (insn + 1 < &mips_opcodes[NUMOPCODES]
8861 && strcmp (insn->name, insn[1].name) == 0);
8863 /* If the expression was written as an unsigned number,
8864 only treat it as signed if there are no more
8865 alternatives. */
8866 if (more
8867 && *args == 'j'
8868 && sizeof (imm_expr.X_add_number) <= 4
8869 && imm_expr.X_op == O_constant
8870 && imm_expr.X_add_number < 0
8871 && imm_expr.X_unsigned
8872 && HAVE_64BIT_GPRS)
8873 break;
8875 /* For compatibility with older assemblers, we accept
8876 0x8000-0xffff as signed 16-bit numbers when only
8877 signed numbers are allowed. */
8878 if (*args == 'i')
8879 minval = 0, maxval = 0xffff;
8880 else if (more)
8881 minval = -0x8000, maxval = 0x7fff;
8882 else
8883 minval = -0x8000, maxval = 0xffff;
8885 if (imm_expr.X_op != O_constant
8886 || imm_expr.X_add_number < minval
8887 || imm_expr.X_add_number > maxval)
8889 if (more)
8890 break;
8891 if (imm_expr.X_op == O_constant
8892 || imm_expr.X_op == O_big)
8893 as_bad (_("expression out of range"));
8896 s = expr_end;
8897 continue;
8899 case 'o': /* 16 bit offset */
8900 /* Check whether there is only a single bracketed expression
8901 left. If so, it must be the base register and the
8902 constant must be zero. */
8903 if (*s == '(' && strchr (s + 1, '(') == 0)
8905 offset_expr.X_op = O_constant;
8906 offset_expr.X_add_number = 0;
8907 continue;
8910 /* If this value won't fit into a 16 bit offset, then go
8911 find a macro that will generate the 32 bit offset
8912 code pattern. */
8913 if (my_getSmallExpression (&offset_expr, offset_reloc, s) == 0
8914 && (offset_expr.X_op != O_constant
8915 || offset_expr.X_add_number >= 0x8000
8916 || offset_expr.X_add_number < -0x8000))
8917 break;
8919 s = expr_end;
8920 continue;
8922 case 'p': /* pc relative offset */
8923 *offset_reloc = BFD_RELOC_16_PCREL_S2;
8924 my_getExpression (&offset_expr, s);
8925 s = expr_end;
8926 continue;
8928 case 'u': /* upper 16 bits */
8929 if (my_getSmallExpression (&imm_expr, imm_reloc, s) == 0
8930 && imm_expr.X_op == O_constant
8931 && (imm_expr.X_add_number < 0
8932 || imm_expr.X_add_number >= 0x10000))
8933 as_bad (_("lui expression not in range 0..65535"));
8934 s = expr_end;
8935 continue;
8937 case 'a': /* 26 bit address */
8938 my_getExpression (&offset_expr, s);
8939 s = expr_end;
8940 *offset_reloc = BFD_RELOC_MIPS_JMP;
8941 continue;
8943 case 'N': /* 3 bit branch condition code */
8944 case 'M': /* 3 bit compare condition code */
8945 if (strncmp (s, "$fcc", 4) != 0)
8946 break;
8947 s += 4;
8948 regno = 0;
8951 regno *= 10;
8952 regno += *s - '0';
8953 ++s;
8955 while (ISDIGIT (*s));
8956 if (regno > 7)
8957 as_bad (_("Invalid condition code register $fcc%d"), regno);
8958 if ((strcmp(str + strlen(str) - 3, ".ps") == 0
8959 || strcmp(str + strlen(str) - 5, "any2f") == 0
8960 || strcmp(str + strlen(str) - 5, "any2t") == 0)
8961 && (regno & 1) != 0)
8962 as_warn(_("Condition code register should be even for %s, was %d"),
8963 str, regno);
8964 if ((strcmp(str + strlen(str) - 5, "any4f") == 0
8965 || strcmp(str + strlen(str) - 5, "any4t") == 0)
8966 && (regno & 3) != 0)
8967 as_warn(_("Condition code register should be 0 or 4 for %s, was %d"),
8968 str, regno);
8969 if (*args == 'N')
8970 ip->insn_opcode |= regno << OP_SH_BCC;
8971 else
8972 ip->insn_opcode |= regno << OP_SH_CCC;
8973 continue;
8975 case 'H':
8976 if (s[0] == '0' && (s[1] == 'x' || s[1] == 'X'))
8977 s += 2;
8978 if (ISDIGIT (*s))
8980 c = 0;
8983 c *= 10;
8984 c += *s - '0';
8985 ++s;
8987 while (ISDIGIT (*s));
8989 else
8990 c = 8; /* Invalid sel value. */
8992 if (c > 7)
8993 as_bad (_("invalid coprocessor sub-selection value (0-7)"));
8994 ip->insn_opcode |= c;
8995 continue;
8997 case 'e':
8998 /* Must be at least one digit. */
8999 my_getExpression (&imm_expr, s);
9000 check_absolute_expr (ip, &imm_expr);
9002 if ((unsigned long) imm_expr.X_add_number
9003 > (unsigned long) OP_MASK_VECBYTE)
9005 as_bad (_("bad byte vector index (%ld)"),
9006 (long) imm_expr.X_add_number);
9007 imm_expr.X_add_number = 0;
9010 ip->insn_opcode |= imm_expr.X_add_number << OP_SH_VECBYTE;
9011 imm_expr.X_op = O_absent;
9012 s = expr_end;
9013 continue;
9015 case '%':
9016 my_getExpression (&imm_expr, s);
9017 check_absolute_expr (ip, &imm_expr);
9019 if ((unsigned long) imm_expr.X_add_number
9020 > (unsigned long) OP_MASK_VECALIGN)
9022 as_bad (_("bad byte vector index (%ld)"),
9023 (long) imm_expr.X_add_number);
9024 imm_expr.X_add_number = 0;
9027 ip->insn_opcode |= imm_expr.X_add_number << OP_SH_VECALIGN;
9028 imm_expr.X_op = O_absent;
9029 s = expr_end;
9030 continue;
9032 default:
9033 as_bad (_("bad char = '%c'\n"), *args);
9034 internalError ();
9036 break;
9038 /* Args don't match. */
9039 if (insn + 1 < &mips_opcodes[NUMOPCODES] &&
9040 !strcmp (insn->name, insn[1].name))
9042 ++insn;
9043 s = argsStart;
9044 insn_error = _("illegal operands");
9045 continue;
9047 if (save_c)
9048 *(--s) = save_c;
9049 insn_error = _("illegal operands");
9050 return;
9054 /* This routine assembles an instruction into its binary format when
9055 assembling for the mips16. As a side effect, it sets one of the
9056 global variables imm_reloc or offset_reloc to the type of
9057 relocation to do if one of the operands is an address expression.
9058 It also sets mips16_small and mips16_ext if the user explicitly
9059 requested a small or extended instruction. */
9061 static void
9062 mips16_ip (char *str, struct mips_cl_insn *ip)
9064 char *s;
9065 const char *args;
9066 struct mips_opcode *insn;
9067 char *argsstart;
9068 unsigned int regno;
9069 unsigned int lastregno = 0;
9070 char *s_reset;
9072 insn_error = NULL;
9074 mips16_small = FALSE;
9075 mips16_ext = FALSE;
9077 for (s = str; ISLOWER (*s); ++s)
9079 switch (*s)
9081 case '\0':
9082 break;
9084 case ' ':
9085 *s++ = '\0';
9086 break;
9088 case '.':
9089 if (s[1] == 't' && s[2] == ' ')
9091 *s = '\0';
9092 mips16_small = TRUE;
9093 s += 3;
9094 break;
9096 else if (s[1] == 'e' && s[2] == ' ')
9098 *s = '\0';
9099 mips16_ext = TRUE;
9100 s += 3;
9101 break;
9103 /* Fall through. */
9104 default:
9105 insn_error = _("unknown opcode");
9106 return;
9109 if (mips_opts.noautoextend && ! mips16_ext)
9110 mips16_small = TRUE;
9112 if ((insn = (struct mips_opcode *) hash_find (mips16_op_hash, str)) == NULL)
9114 insn_error = _("unrecognized opcode");
9115 return;
9118 argsstart = s;
9119 for (;;)
9121 assert (strcmp (insn->name, str) == 0);
9123 ip->insn_mo = insn;
9124 ip->insn_opcode = insn->match;
9125 ip->use_extend = FALSE;
9126 imm_expr.X_op = O_absent;
9127 imm_reloc[0] = BFD_RELOC_UNUSED;
9128 imm_reloc[1] = BFD_RELOC_UNUSED;
9129 imm_reloc[2] = BFD_RELOC_UNUSED;
9130 imm2_expr.X_op = O_absent;
9131 offset_expr.X_op = O_absent;
9132 offset_reloc[0] = BFD_RELOC_UNUSED;
9133 offset_reloc[1] = BFD_RELOC_UNUSED;
9134 offset_reloc[2] = BFD_RELOC_UNUSED;
9135 for (args = insn->args; 1; ++args)
9137 int c;
9139 if (*s == ' ')
9140 ++s;
9142 /* In this switch statement we call break if we did not find
9143 a match, continue if we did find a match, or return if we
9144 are done. */
9146 c = *args;
9147 switch (c)
9149 case '\0':
9150 if (*s == '\0')
9152 /* Stuff the immediate value in now, if we can. */
9153 if (imm_expr.X_op == O_constant
9154 && *imm_reloc > BFD_RELOC_UNUSED
9155 && insn->pinfo != INSN_MACRO)
9157 mips16_immed (NULL, 0, *imm_reloc - BFD_RELOC_UNUSED,
9158 imm_expr.X_add_number, TRUE, mips16_small,
9159 mips16_ext, &ip->insn_opcode,
9160 &ip->use_extend, &ip->extend);
9161 imm_expr.X_op = O_absent;
9162 *imm_reloc = BFD_RELOC_UNUSED;
9165 return;
9167 break;
9169 case ',':
9170 if (*s++ == c)
9171 continue;
9172 s--;
9173 switch (*++args)
9175 case 'v':
9176 ip->insn_opcode |= lastregno << MIPS16OP_SH_RX;
9177 continue;
9178 case 'w':
9179 ip->insn_opcode |= lastregno << MIPS16OP_SH_RY;
9180 continue;
9182 break;
9184 case '(':
9185 case ')':
9186 if (*s++ == c)
9187 continue;
9188 break;
9190 case 'v':
9191 case 'w':
9192 if (s[0] != '$')
9194 if (c == 'v')
9195 ip->insn_opcode |= lastregno << MIPS16OP_SH_RX;
9196 else
9197 ip->insn_opcode |= lastregno << MIPS16OP_SH_RY;
9198 ++args;
9199 continue;
9201 /* Fall through. */
9202 case 'x':
9203 case 'y':
9204 case 'z':
9205 case 'Z':
9206 case '0':
9207 case 'S':
9208 case 'R':
9209 case 'X':
9210 case 'Y':
9211 if (s[0] != '$')
9212 break;
9213 s_reset = s;
9214 if (ISDIGIT (s[1]))
9216 ++s;
9217 regno = 0;
9220 regno *= 10;
9221 regno += *s - '0';
9222 ++s;
9224 while (ISDIGIT (*s));
9225 if (regno > 31)
9227 as_bad (_("invalid register number (%d)"), regno);
9228 regno = 2;
9231 else
9233 if (s[1] == 'r' && s[2] == 'a')
9235 s += 3;
9236 regno = RA;
9238 else if (s[1] == 'f' && s[2] == 'p')
9240 s += 3;
9241 regno = FP;
9243 else if (s[1] == 's' && s[2] == 'p')
9245 s += 3;
9246 regno = SP;
9248 else if (s[1] == 'g' && s[2] == 'p')
9250 s += 3;
9251 regno = GP;
9253 else if (s[1] == 'a' && s[2] == 't')
9255 s += 3;
9256 regno = AT;
9258 else if (s[1] == 'k' && s[2] == 't' && s[3] == '0')
9260 s += 4;
9261 regno = KT0;
9263 else if (s[1] == 'k' && s[2] == 't' && s[3] == '1')
9265 s += 4;
9266 regno = KT1;
9268 else if (s[1] == 'z' && s[2] == 'e' && s[3] == 'r' && s[4] == 'o')
9270 s += 5;
9271 regno = ZERO;
9273 else
9274 break;
9277 if (*s == ' ')
9278 ++s;
9279 if (args[1] != *s)
9281 if (c == 'v' || c == 'w')
9283 regno = mips16_to_32_reg_map[lastregno];
9284 s = s_reset;
9285 ++args;
9289 switch (c)
9291 case 'x':
9292 case 'y':
9293 case 'z':
9294 case 'v':
9295 case 'w':
9296 case 'Z':
9297 regno = mips32_to_16_reg_map[regno];
9298 break;
9300 case '0':
9301 if (regno != 0)
9302 regno = ILLEGAL_REG;
9303 break;
9305 case 'S':
9306 if (regno != SP)
9307 regno = ILLEGAL_REG;
9308 break;
9310 case 'R':
9311 if (regno != RA)
9312 regno = ILLEGAL_REG;
9313 break;
9315 case 'X':
9316 case 'Y':
9317 if (regno == AT && ! mips_opts.noat)
9318 as_warn (_("used $at without \".set noat\""));
9319 break;
9321 default:
9322 internalError ();
9325 if (regno == ILLEGAL_REG)
9326 break;
9328 switch (c)
9330 case 'x':
9331 case 'v':
9332 ip->insn_opcode |= regno << MIPS16OP_SH_RX;
9333 break;
9334 case 'y':
9335 case 'w':
9336 ip->insn_opcode |= regno << MIPS16OP_SH_RY;
9337 break;
9338 case 'z':
9339 ip->insn_opcode |= regno << MIPS16OP_SH_RZ;
9340 break;
9341 case 'Z':
9342 ip->insn_opcode |= regno << MIPS16OP_SH_MOVE32Z;
9343 case '0':
9344 case 'S':
9345 case 'R':
9346 break;
9347 case 'X':
9348 ip->insn_opcode |= regno << MIPS16OP_SH_REGR32;
9349 break;
9350 case 'Y':
9351 regno = ((regno & 7) << 2) | ((regno & 0x18) >> 3);
9352 ip->insn_opcode |= regno << MIPS16OP_SH_REG32R;
9353 break;
9354 default:
9355 internalError ();
9358 lastregno = regno;
9359 continue;
9361 case 'P':
9362 if (strncmp (s, "$pc", 3) == 0)
9364 s += 3;
9365 continue;
9367 break;
9369 case '<':
9370 case '>':
9371 case '[':
9372 case ']':
9373 case '4':
9374 case '5':
9375 case 'H':
9376 case 'W':
9377 case 'D':
9378 case 'j':
9379 case '8':
9380 case 'V':
9381 case 'C':
9382 case 'U':
9383 case 'k':
9384 case 'K':
9385 if (s[0] == '%'
9386 && strncmp (s + 1, "gprel(", sizeof "gprel(" - 1) == 0)
9388 /* This is %gprel(SYMBOL). We need to read SYMBOL,
9389 and generate the appropriate reloc. If the text
9390 inside %gprel is not a symbol name with an
9391 optional offset, then we generate a normal reloc
9392 and will probably fail later. */
9393 my_getExpression (&imm_expr, s + sizeof "%gprel" - 1);
9394 if (imm_expr.X_op == O_symbol)
9396 mips16_ext = TRUE;
9397 *imm_reloc = BFD_RELOC_MIPS16_GPREL;
9398 s = expr_end;
9399 ip->use_extend = TRUE;
9400 ip->extend = 0;
9401 continue;
9404 else
9406 /* Just pick up a normal expression. */
9407 my_getExpression (&imm_expr, s);
9410 if (imm_expr.X_op == O_register)
9412 /* What we thought was an expression turned out to
9413 be a register. */
9415 if (s[0] == '(' && args[1] == '(')
9417 /* It looks like the expression was omitted
9418 before a register indirection, which means
9419 that the expression is implicitly zero. We
9420 still set up imm_expr, so that we handle
9421 explicit extensions correctly. */
9422 imm_expr.X_op = O_constant;
9423 imm_expr.X_add_number = 0;
9424 *imm_reloc = (int) BFD_RELOC_UNUSED + c;
9425 continue;
9428 break;
9431 /* We need to relax this instruction. */
9432 *imm_reloc = (int) BFD_RELOC_UNUSED + c;
9433 s = expr_end;
9434 continue;
9436 case 'p':
9437 case 'q':
9438 case 'A':
9439 case 'B':
9440 case 'E':
9441 /* We use offset_reloc rather than imm_reloc for the PC
9442 relative operands. This lets macros with both
9443 immediate and address operands work correctly. */
9444 my_getExpression (&offset_expr, s);
9446 if (offset_expr.X_op == O_register)
9447 break;
9449 /* We need to relax this instruction. */
9450 *offset_reloc = (int) BFD_RELOC_UNUSED + c;
9451 s = expr_end;
9452 continue;
9454 case '6': /* break code */
9455 my_getExpression (&imm_expr, s);
9456 check_absolute_expr (ip, &imm_expr);
9457 if ((unsigned long) imm_expr.X_add_number > 63)
9459 as_warn (_("Invalid value for `%s' (%lu)"),
9460 ip->insn_mo->name,
9461 (unsigned long) imm_expr.X_add_number);
9462 imm_expr.X_add_number &= 0x3f;
9464 ip->insn_opcode |= imm_expr.X_add_number << MIPS16OP_SH_IMM6;
9465 imm_expr.X_op = O_absent;
9466 s = expr_end;
9467 continue;
9469 case 'a': /* 26 bit address */
9470 my_getExpression (&offset_expr, s);
9471 s = expr_end;
9472 *offset_reloc = BFD_RELOC_MIPS16_JMP;
9473 ip->insn_opcode <<= 16;
9474 continue;
9476 case 'l': /* register list for entry macro */
9477 case 'L': /* register list for exit macro */
9479 int mask;
9481 if (c == 'l')
9482 mask = 0;
9483 else
9484 mask = 7 << 3;
9485 while (*s != '\0')
9487 int freg, reg1, reg2;
9489 while (*s == ' ' || *s == ',')
9490 ++s;
9491 if (*s != '$')
9493 as_bad (_("can't parse register list"));
9494 break;
9496 ++s;
9497 if (*s != 'f')
9498 freg = 0;
9499 else
9501 freg = 1;
9502 ++s;
9504 reg1 = 0;
9505 while (ISDIGIT (*s))
9507 reg1 *= 10;
9508 reg1 += *s - '0';
9509 ++s;
9511 if (*s == ' ')
9512 ++s;
9513 if (*s != '-')
9514 reg2 = reg1;
9515 else
9517 ++s;
9518 if (*s != '$')
9519 break;
9520 ++s;
9521 if (freg)
9523 if (*s == 'f')
9524 ++s;
9525 else
9527 as_bad (_("invalid register list"));
9528 break;
9531 reg2 = 0;
9532 while (ISDIGIT (*s))
9534 reg2 *= 10;
9535 reg2 += *s - '0';
9536 ++s;
9539 if (freg && reg1 == 0 && reg2 == 0 && c == 'L')
9541 mask &= ~ (7 << 3);
9542 mask |= 5 << 3;
9544 else if (freg && reg1 == 0 && reg2 == 1 && c == 'L')
9546 mask &= ~ (7 << 3);
9547 mask |= 6 << 3;
9549 else if (reg1 == 4 && reg2 >= 4 && reg2 <= 7 && c != 'L')
9550 mask |= (reg2 - 3) << 3;
9551 else if (reg1 == 16 && reg2 >= 16 && reg2 <= 17)
9552 mask |= (reg2 - 15) << 1;
9553 else if (reg1 == RA && reg2 == RA)
9554 mask |= 1;
9555 else
9557 as_bad (_("invalid register list"));
9558 break;
9561 /* The mask is filled in in the opcode table for the
9562 benefit of the disassembler. We remove it before
9563 applying the actual mask. */
9564 ip->insn_opcode &= ~ ((7 << 3) << MIPS16OP_SH_IMM6);
9565 ip->insn_opcode |= mask << MIPS16OP_SH_IMM6;
9567 continue;
9569 case 'e': /* extend code */
9570 my_getExpression (&imm_expr, s);
9571 check_absolute_expr (ip, &imm_expr);
9572 if ((unsigned long) imm_expr.X_add_number > 0x7ff)
9574 as_warn (_("Invalid value for `%s' (%lu)"),
9575 ip->insn_mo->name,
9576 (unsigned long) imm_expr.X_add_number);
9577 imm_expr.X_add_number &= 0x7ff;
9579 ip->insn_opcode |= imm_expr.X_add_number;
9580 imm_expr.X_op = O_absent;
9581 s = expr_end;
9582 continue;
9584 default:
9585 internalError ();
9587 break;
9590 /* Args don't match. */
9591 if (insn + 1 < &mips16_opcodes[bfd_mips16_num_opcodes] &&
9592 strcmp (insn->name, insn[1].name) == 0)
9594 ++insn;
9595 s = argsstart;
9596 continue;
9599 insn_error = _("illegal operands");
9601 return;
9605 /* This structure holds information we know about a mips16 immediate
9606 argument type. */
9608 struct mips16_immed_operand
9610 /* The type code used in the argument string in the opcode table. */
9611 int type;
9612 /* The number of bits in the short form of the opcode. */
9613 int nbits;
9614 /* The number of bits in the extended form of the opcode. */
9615 int extbits;
9616 /* The amount by which the short form is shifted when it is used;
9617 for example, the sw instruction has a shift count of 2. */
9618 int shift;
9619 /* The amount by which the short form is shifted when it is stored
9620 into the instruction code. */
9621 int op_shift;
9622 /* Non-zero if the short form is unsigned. */
9623 int unsp;
9624 /* Non-zero if the extended form is unsigned. */
9625 int extu;
9626 /* Non-zero if the value is PC relative. */
9627 int pcrel;
9630 /* The mips16 immediate operand types. */
9632 static const struct mips16_immed_operand mips16_immed_operands[] =
9634 { '<', 3, 5, 0, MIPS16OP_SH_RZ, 1, 1, 0 },
9635 { '>', 3, 5, 0, MIPS16OP_SH_RX, 1, 1, 0 },
9636 { '[', 3, 6, 0, MIPS16OP_SH_RZ, 1, 1, 0 },
9637 { ']', 3, 6, 0, MIPS16OP_SH_RX, 1, 1, 0 },
9638 { '4', 4, 15, 0, MIPS16OP_SH_IMM4, 0, 0, 0 },
9639 { '5', 5, 16, 0, MIPS16OP_SH_IMM5, 1, 0, 0 },
9640 { 'H', 5, 16, 1, MIPS16OP_SH_IMM5, 1, 0, 0 },
9641 { 'W', 5, 16, 2, MIPS16OP_SH_IMM5, 1, 0, 0 },
9642 { 'D', 5, 16, 3, MIPS16OP_SH_IMM5, 1, 0, 0 },
9643 { 'j', 5, 16, 0, MIPS16OP_SH_IMM5, 0, 0, 0 },
9644 { '8', 8, 16, 0, MIPS16OP_SH_IMM8, 1, 0, 0 },
9645 { 'V', 8, 16, 2, MIPS16OP_SH_IMM8, 1, 0, 0 },
9646 { 'C', 8, 16, 3, MIPS16OP_SH_IMM8, 1, 0, 0 },
9647 { 'U', 8, 16, 0, MIPS16OP_SH_IMM8, 1, 1, 0 },
9648 { 'k', 8, 16, 0, MIPS16OP_SH_IMM8, 0, 0, 0 },
9649 { 'K', 8, 16, 3, MIPS16OP_SH_IMM8, 0, 0, 0 },
9650 { 'p', 8, 16, 0, MIPS16OP_SH_IMM8, 0, 0, 1 },
9651 { 'q', 11, 16, 0, MIPS16OP_SH_IMM8, 0, 0, 1 },
9652 { 'A', 8, 16, 2, MIPS16OP_SH_IMM8, 1, 0, 1 },
9653 { 'B', 5, 16, 3, MIPS16OP_SH_IMM5, 1, 0, 1 },
9654 { 'E', 5, 16, 2, MIPS16OP_SH_IMM5, 1, 0, 1 }
9657 #define MIPS16_NUM_IMMED \
9658 (sizeof mips16_immed_operands / sizeof mips16_immed_operands[0])
9660 /* Handle a mips16 instruction with an immediate value. This or's the
9661 small immediate value into *INSN. It sets *USE_EXTEND to indicate
9662 whether an extended value is needed; if one is needed, it sets
9663 *EXTEND to the value. The argument type is TYPE. The value is VAL.
9664 If SMALL is true, an unextended opcode was explicitly requested.
9665 If EXT is true, an extended opcode was explicitly requested. If
9666 WARN is true, warn if EXT does not match reality. */
9668 static void
9669 mips16_immed (char *file, unsigned int line, int type, offsetT val,
9670 bfd_boolean warn, bfd_boolean small, bfd_boolean ext,
9671 unsigned long *insn, bfd_boolean *use_extend,
9672 unsigned short *extend)
9674 register const struct mips16_immed_operand *op;
9675 int mintiny, maxtiny;
9676 bfd_boolean needext;
9678 op = mips16_immed_operands;
9679 while (op->type != type)
9681 ++op;
9682 assert (op < mips16_immed_operands + MIPS16_NUM_IMMED);
9685 if (op->unsp)
9687 if (type == '<' || type == '>' || type == '[' || type == ']')
9689 mintiny = 1;
9690 maxtiny = 1 << op->nbits;
9692 else
9694 mintiny = 0;
9695 maxtiny = (1 << op->nbits) - 1;
9698 else
9700 mintiny = - (1 << (op->nbits - 1));
9701 maxtiny = (1 << (op->nbits - 1)) - 1;
9704 /* Branch offsets have an implicit 0 in the lowest bit. */
9705 if (type == 'p' || type == 'q')
9706 val /= 2;
9708 if ((val & ((1 << op->shift) - 1)) != 0
9709 || val < (mintiny << op->shift)
9710 || val > (maxtiny << op->shift))
9711 needext = TRUE;
9712 else
9713 needext = FALSE;
9715 if (warn && ext && ! needext)
9716 as_warn_where (file, line,
9717 _("extended operand requested but not required"));
9718 if (small && needext)
9719 as_bad_where (file, line, _("invalid unextended operand value"));
9721 if (small || (! ext && ! needext))
9723 int insnval;
9725 *use_extend = FALSE;
9726 insnval = ((val >> op->shift) & ((1 << op->nbits) - 1));
9727 insnval <<= op->op_shift;
9728 *insn |= insnval;
9730 else
9732 long minext, maxext;
9733 int extval;
9735 if (op->extu)
9737 minext = 0;
9738 maxext = (1 << op->extbits) - 1;
9740 else
9742 minext = - (1 << (op->extbits - 1));
9743 maxext = (1 << (op->extbits - 1)) - 1;
9745 if (val < minext || val > maxext)
9746 as_bad_where (file, line,
9747 _("operand value out of range for instruction"));
9749 *use_extend = TRUE;
9750 if (op->extbits == 16)
9752 extval = ((val >> 11) & 0x1f) | (val & 0x7e0);
9753 val &= 0x1f;
9755 else if (op->extbits == 15)
9757 extval = ((val >> 11) & 0xf) | (val & 0x7f0);
9758 val &= 0xf;
9760 else
9762 extval = ((val & 0x1f) << 6) | (val & 0x20);
9763 val = 0;
9766 *extend = (unsigned short) extval;
9767 *insn |= val;
9771 static const struct percent_op_match
9773 const char *str;
9774 bfd_reloc_code_real_type reloc;
9775 } percent_op[] =
9777 {"%lo", BFD_RELOC_LO16},
9778 #ifdef OBJ_ELF
9779 {"%call_hi", BFD_RELOC_MIPS_CALL_HI16},
9780 {"%call_lo", BFD_RELOC_MIPS_CALL_LO16},
9781 {"%call16", BFD_RELOC_MIPS_CALL16},
9782 {"%got_disp", BFD_RELOC_MIPS_GOT_DISP},
9783 {"%got_page", BFD_RELOC_MIPS_GOT_PAGE},
9784 {"%got_ofst", BFD_RELOC_MIPS_GOT_OFST},
9785 {"%got_hi", BFD_RELOC_MIPS_GOT_HI16},
9786 {"%got_lo", BFD_RELOC_MIPS_GOT_LO16},
9787 {"%got", BFD_RELOC_MIPS_GOT16},
9788 {"%gp_rel", BFD_RELOC_GPREL16},
9789 {"%half", BFD_RELOC_16},
9790 {"%highest", BFD_RELOC_MIPS_HIGHEST},
9791 {"%higher", BFD_RELOC_MIPS_HIGHER},
9792 {"%neg", BFD_RELOC_MIPS_SUB},
9793 #endif
9794 {"%hi", BFD_RELOC_HI16_S}
9798 /* Return true if *STR points to a relocation operator. When returning true,
9799 move *STR over the operator and store its relocation code in *RELOC.
9800 Leave both *STR and *RELOC alone when returning false. */
9802 static bfd_boolean
9803 parse_relocation (char **str, bfd_reloc_code_real_type *reloc)
9805 size_t i;
9807 for (i = 0; i < ARRAY_SIZE (percent_op); i++)
9808 if (strncasecmp (*str, percent_op[i].str, strlen (percent_op[i].str)) == 0)
9810 *str += strlen (percent_op[i].str);
9811 *reloc = percent_op[i].reloc;
9813 /* Check whether the output BFD supports this relocation.
9814 If not, issue an error and fall back on something safe. */
9815 if (!bfd_reloc_type_lookup (stdoutput, percent_op[i].reloc))
9817 as_bad ("relocation %s isn't supported by the current ABI",
9818 percent_op[i].str);
9819 *reloc = BFD_RELOC_UNUSED;
9821 return TRUE;
9823 return FALSE;
9827 /* Parse string STR as a 16-bit relocatable operand. Store the
9828 expression in *EP and the relocations in the array starting
9829 at RELOC. Return the number of relocation operators used.
9831 On exit, EXPR_END points to the first character after the expression. */
9833 static size_t
9834 my_getSmallExpression (expressionS *ep, bfd_reloc_code_real_type *reloc,
9835 char *str)
9837 bfd_reloc_code_real_type reversed_reloc[3];
9838 size_t reloc_index, i;
9839 int crux_depth, str_depth;
9840 char *crux;
9842 /* Search for the start of the main expression, recoding relocations
9843 in REVERSED_RELOC. End the loop with CRUX pointing to the start
9844 of the main expression and with CRUX_DEPTH containing the number
9845 of open brackets at that point. */
9846 reloc_index = -1;
9847 str_depth = 0;
9850 reloc_index++;
9851 crux = str;
9852 crux_depth = str_depth;
9854 /* Skip over whitespace and brackets, keeping count of the number
9855 of brackets. */
9856 while (*str == ' ' || *str == '\t' || *str == '(')
9857 if (*str++ == '(')
9858 str_depth++;
9860 while (*str == '%'
9861 && reloc_index < (HAVE_NEWABI ? 3 : 1)
9862 && parse_relocation (&str, &reversed_reloc[reloc_index]));
9864 my_getExpression (ep, crux);
9865 str = expr_end;
9867 /* Match every open bracket. */
9868 while (crux_depth > 0 && (*str == ')' || *str == ' ' || *str == '\t'))
9869 if (*str++ == ')')
9870 crux_depth--;
9872 if (crux_depth > 0)
9873 as_bad ("unclosed '('");
9875 expr_end = str;
9877 if (reloc_index != 0)
9879 prev_reloc_op_frag = frag_now;
9880 for (i = 0; i < reloc_index; i++)
9881 reloc[i] = reversed_reloc[reloc_index - 1 - i];
9884 return reloc_index;
9887 static void
9888 my_getExpression (expressionS *ep, char *str)
9890 char *save_in;
9891 valueT val;
9893 save_in = input_line_pointer;
9894 input_line_pointer = str;
9895 expression (ep);
9896 expr_end = input_line_pointer;
9897 input_line_pointer = save_in;
9899 /* If we are in mips16 mode, and this is an expression based on `.',
9900 then we bump the value of the symbol by 1 since that is how other
9901 text symbols are handled. We don't bother to handle complex
9902 expressions, just `.' plus or minus a constant. */
9903 if (mips_opts.mips16
9904 && ep->X_op == O_symbol
9905 && strcmp (S_GET_NAME (ep->X_add_symbol), FAKE_LABEL_NAME) == 0
9906 && S_GET_SEGMENT (ep->X_add_symbol) == now_seg
9907 && symbol_get_frag (ep->X_add_symbol) == frag_now
9908 && symbol_constant_p (ep->X_add_symbol)
9909 && (val = S_GET_VALUE (ep->X_add_symbol)) == frag_now_fix ())
9910 S_SET_VALUE (ep->X_add_symbol, val + 1);
9913 /* Turn a string in input_line_pointer into a floating point constant
9914 of type TYPE, and store the appropriate bytes in *LITP. The number
9915 of LITTLENUMS emitted is stored in *SIZEP. An error message is
9916 returned, or NULL on OK. */
9918 char *
9919 md_atof (int type, char *litP, int *sizeP)
9921 int prec;
9922 LITTLENUM_TYPE words[4];
9923 char *t;
9924 int i;
9926 switch (type)
9928 case 'f':
9929 prec = 2;
9930 break;
9932 case 'd':
9933 prec = 4;
9934 break;
9936 default:
9937 *sizeP = 0;
9938 return _("bad call to md_atof");
9941 t = atof_ieee (input_line_pointer, type, words);
9942 if (t)
9943 input_line_pointer = t;
9945 *sizeP = prec * 2;
9947 if (! target_big_endian)
9949 for (i = prec - 1; i >= 0; i--)
9951 md_number_to_chars (litP, words[i], 2);
9952 litP += 2;
9955 else
9957 for (i = 0; i < prec; i++)
9959 md_number_to_chars (litP, words[i], 2);
9960 litP += 2;
9964 return NULL;
9967 void
9968 md_number_to_chars (char *buf, valueT val, int n)
9970 if (target_big_endian)
9971 number_to_chars_bigendian (buf, val, n);
9972 else
9973 number_to_chars_littleendian (buf, val, n);
9976 #ifdef OBJ_ELF
9977 static int support_64bit_objects(void)
9979 const char **list, **l;
9980 int yes;
9982 list = bfd_target_list ();
9983 for (l = list; *l != NULL; l++)
9984 #ifdef TE_TMIPS
9985 /* This is traditional mips */
9986 if (strcmp (*l, "elf64-tradbigmips") == 0
9987 || strcmp (*l, "elf64-tradlittlemips") == 0)
9988 #else
9989 if (strcmp (*l, "elf64-bigmips") == 0
9990 || strcmp (*l, "elf64-littlemips") == 0)
9991 #endif
9992 break;
9993 yes = (*l != NULL);
9994 free (list);
9995 return yes;
9997 #endif /* OBJ_ELF */
9999 const char *md_shortopts = "O::g::G:";
10001 struct option md_longopts[] =
10003 /* Options which specify architecture. */
10004 #define OPTION_ARCH_BASE (OPTION_MD_BASE)
10005 #define OPTION_MARCH (OPTION_ARCH_BASE + 0)
10006 {"march", required_argument, NULL, OPTION_MARCH},
10007 #define OPTION_MTUNE (OPTION_ARCH_BASE + 1)
10008 {"mtune", required_argument, NULL, OPTION_MTUNE},
10009 #define OPTION_MIPS1 (OPTION_ARCH_BASE + 2)
10010 {"mips0", no_argument, NULL, OPTION_MIPS1},
10011 {"mips1", no_argument, NULL, OPTION_MIPS1},
10012 #define OPTION_MIPS2 (OPTION_ARCH_BASE + 3)
10013 {"mips2", no_argument, NULL, OPTION_MIPS2},
10014 #define OPTION_MIPS3 (OPTION_ARCH_BASE + 4)
10015 {"mips3", no_argument, NULL, OPTION_MIPS3},
10016 #define OPTION_MIPS4 (OPTION_ARCH_BASE + 5)
10017 {"mips4", no_argument, NULL, OPTION_MIPS4},
10018 #define OPTION_MIPS5 (OPTION_ARCH_BASE + 6)
10019 {"mips5", no_argument, NULL, OPTION_MIPS5},
10020 #define OPTION_MIPS32 (OPTION_ARCH_BASE + 7)
10021 {"mips32", no_argument, NULL, OPTION_MIPS32},
10022 #define OPTION_MIPS64 (OPTION_ARCH_BASE + 8)
10023 {"mips64", no_argument, NULL, OPTION_MIPS64},
10024 #define OPTION_MIPS32R2 (OPTION_ARCH_BASE + 9)
10025 {"mips32r2", no_argument, NULL, OPTION_MIPS32R2},
10026 #define OPTION_MIPS64R2 (OPTION_ARCH_BASE + 10)
10027 {"mips64r2", no_argument, NULL, OPTION_MIPS64R2},
10029 /* Options which specify Application Specific Extensions (ASEs). */
10030 #define OPTION_ASE_BASE (OPTION_ARCH_BASE + 11)
10031 #define OPTION_MIPS16 (OPTION_ASE_BASE + 0)
10032 {"mips16", no_argument, NULL, OPTION_MIPS16},
10033 #define OPTION_NO_MIPS16 (OPTION_ASE_BASE + 1)
10034 {"no-mips16", no_argument, NULL, OPTION_NO_MIPS16},
10035 #define OPTION_MIPS3D (OPTION_ASE_BASE + 2)
10036 {"mips3d", no_argument, NULL, OPTION_MIPS3D},
10037 #define OPTION_NO_MIPS3D (OPTION_ASE_BASE + 3)
10038 {"no-mips3d", no_argument, NULL, OPTION_NO_MIPS3D},
10039 #define OPTION_MDMX (OPTION_ASE_BASE + 4)
10040 {"mdmx", no_argument, NULL, OPTION_MDMX},
10041 #define OPTION_NO_MDMX (OPTION_ASE_BASE + 5)
10042 {"no-mdmx", no_argument, NULL, OPTION_NO_MDMX},
10044 /* Old-style architecture options. Don't add more of these. */
10045 #define OPTION_COMPAT_ARCH_BASE (OPTION_ASE_BASE + 6)
10046 #define OPTION_M4650 (OPTION_COMPAT_ARCH_BASE + 0)
10047 {"m4650", no_argument, NULL, OPTION_M4650},
10048 #define OPTION_NO_M4650 (OPTION_COMPAT_ARCH_BASE + 1)
10049 {"no-m4650", no_argument, NULL, OPTION_NO_M4650},
10050 #define OPTION_M4010 (OPTION_COMPAT_ARCH_BASE + 2)
10051 {"m4010", no_argument, NULL, OPTION_M4010},
10052 #define OPTION_NO_M4010 (OPTION_COMPAT_ARCH_BASE + 3)
10053 {"no-m4010", no_argument, NULL, OPTION_NO_M4010},
10054 #define OPTION_M4100 (OPTION_COMPAT_ARCH_BASE + 4)
10055 {"m4100", no_argument, NULL, OPTION_M4100},
10056 #define OPTION_NO_M4100 (OPTION_COMPAT_ARCH_BASE + 5)
10057 {"no-m4100", no_argument, NULL, OPTION_NO_M4100},
10058 #define OPTION_M3900 (OPTION_COMPAT_ARCH_BASE + 6)
10059 {"m3900", no_argument, NULL, OPTION_M3900},
10060 #define OPTION_NO_M3900 (OPTION_COMPAT_ARCH_BASE + 7)
10061 {"no-m3900", no_argument, NULL, OPTION_NO_M3900},
10063 /* Options which enable bug fixes. */
10064 #define OPTION_FIX_BASE (OPTION_COMPAT_ARCH_BASE + 8)
10065 #define OPTION_M7000_HILO_FIX (OPTION_FIX_BASE + 0)
10066 {"mfix7000", no_argument, NULL, OPTION_M7000_HILO_FIX},
10067 #define OPTION_MNO_7000_HILO_FIX (OPTION_FIX_BASE + 1)
10068 {"no-fix-7000", no_argument, NULL, OPTION_MNO_7000_HILO_FIX},
10069 {"mno-fix7000", no_argument, NULL, OPTION_MNO_7000_HILO_FIX},
10070 #define OPTION_FIX_VR4120 (OPTION_FIX_BASE + 2)
10071 #define OPTION_NO_FIX_VR4120 (OPTION_FIX_BASE + 3)
10072 {"mfix-vr4120", no_argument, NULL, OPTION_FIX_VR4120},
10073 {"mno-fix-vr4120", no_argument, NULL, OPTION_NO_FIX_VR4120},
10075 /* Miscellaneous options. */
10076 #define OPTION_MISC_BASE (OPTION_FIX_BASE + 4)
10077 #define OPTION_TRAP (OPTION_MISC_BASE + 0)
10078 {"trap", no_argument, NULL, OPTION_TRAP},
10079 {"no-break", no_argument, NULL, OPTION_TRAP},
10080 #define OPTION_BREAK (OPTION_MISC_BASE + 1)
10081 {"break", no_argument, NULL, OPTION_BREAK},
10082 {"no-trap", no_argument, NULL, OPTION_BREAK},
10083 #define OPTION_EB (OPTION_MISC_BASE + 2)
10084 {"EB", no_argument, NULL, OPTION_EB},
10085 #define OPTION_EL (OPTION_MISC_BASE + 3)
10086 {"EL", no_argument, NULL, OPTION_EL},
10087 #define OPTION_FP32 (OPTION_MISC_BASE + 4)
10088 {"mfp32", no_argument, NULL, OPTION_FP32},
10089 #define OPTION_GP32 (OPTION_MISC_BASE + 5)
10090 {"mgp32", no_argument, NULL, OPTION_GP32},
10091 #define OPTION_CONSTRUCT_FLOATS (OPTION_MISC_BASE + 6)
10092 {"construct-floats", no_argument, NULL, OPTION_CONSTRUCT_FLOATS},
10093 #define OPTION_NO_CONSTRUCT_FLOATS (OPTION_MISC_BASE + 7)
10094 {"no-construct-floats", no_argument, NULL, OPTION_NO_CONSTRUCT_FLOATS},
10095 #define OPTION_FP64 (OPTION_MISC_BASE + 8)
10096 {"mfp64", no_argument, NULL, OPTION_FP64},
10097 #define OPTION_GP64 (OPTION_MISC_BASE + 9)
10098 {"mgp64", no_argument, NULL, OPTION_GP64},
10099 #define OPTION_RELAX_BRANCH (OPTION_MISC_BASE + 10)
10100 #define OPTION_NO_RELAX_BRANCH (OPTION_MISC_BASE + 11)
10101 {"relax-branch", no_argument, NULL, OPTION_RELAX_BRANCH},
10102 {"no-relax-branch", no_argument, NULL, OPTION_NO_RELAX_BRANCH},
10104 /* ELF-specific options. */
10105 #ifdef OBJ_ELF
10106 #define OPTION_ELF_BASE (OPTION_MISC_BASE + 12)
10107 #define OPTION_CALL_SHARED (OPTION_ELF_BASE + 0)
10108 {"KPIC", no_argument, NULL, OPTION_CALL_SHARED},
10109 {"call_shared", no_argument, NULL, OPTION_CALL_SHARED},
10110 #define OPTION_NON_SHARED (OPTION_ELF_BASE + 1)
10111 {"non_shared", no_argument, NULL, OPTION_NON_SHARED},
10112 #define OPTION_XGOT (OPTION_ELF_BASE + 2)
10113 {"xgot", no_argument, NULL, OPTION_XGOT},
10114 #define OPTION_MABI (OPTION_ELF_BASE + 3)
10115 {"mabi", required_argument, NULL, OPTION_MABI},
10116 #define OPTION_32 (OPTION_ELF_BASE + 4)
10117 {"32", no_argument, NULL, OPTION_32},
10118 #define OPTION_N32 (OPTION_ELF_BASE + 5)
10119 {"n32", no_argument, NULL, OPTION_N32},
10120 #define OPTION_64 (OPTION_ELF_BASE + 6)
10121 {"64", no_argument, NULL, OPTION_64},
10122 #define OPTION_MDEBUG (OPTION_ELF_BASE + 7)
10123 {"mdebug", no_argument, NULL, OPTION_MDEBUG},
10124 #define OPTION_NO_MDEBUG (OPTION_ELF_BASE + 8)
10125 {"no-mdebug", no_argument, NULL, OPTION_NO_MDEBUG},
10126 #define OPTION_PDR (OPTION_ELF_BASE + 9)
10127 {"mpdr", no_argument, NULL, OPTION_PDR},
10128 #define OPTION_NO_PDR (OPTION_ELF_BASE + 10)
10129 {"mno-pdr", no_argument, NULL, OPTION_NO_PDR},
10130 #endif /* OBJ_ELF */
10132 {NULL, no_argument, NULL, 0}
10134 size_t md_longopts_size = sizeof (md_longopts);
10136 /* Set STRING_PTR (either &mips_arch_string or &mips_tune_string) to
10137 NEW_VALUE. Warn if another value was already specified. Note:
10138 we have to defer parsing the -march and -mtune arguments in order
10139 to handle 'from-abi' correctly, since the ABI might be specified
10140 in a later argument. */
10142 static void
10143 mips_set_option_string (const char **string_ptr, const char *new_value)
10145 if (*string_ptr != 0 && strcasecmp (*string_ptr, new_value) != 0)
10146 as_warn (_("A different %s was already specified, is now %s"),
10147 string_ptr == &mips_arch_string ? "-march" : "-mtune",
10148 new_value);
10150 *string_ptr = new_value;
10154 md_parse_option (int c, char *arg)
10156 switch (c)
10158 case OPTION_CONSTRUCT_FLOATS:
10159 mips_disable_float_construction = 0;
10160 break;
10162 case OPTION_NO_CONSTRUCT_FLOATS:
10163 mips_disable_float_construction = 1;
10164 break;
10166 case OPTION_TRAP:
10167 mips_trap = 1;
10168 break;
10170 case OPTION_BREAK:
10171 mips_trap = 0;
10172 break;
10174 case OPTION_EB:
10175 target_big_endian = 1;
10176 break;
10178 case OPTION_EL:
10179 target_big_endian = 0;
10180 break;
10182 case 'O':
10183 if (arg && arg[1] == '0')
10184 mips_optimize = 1;
10185 else
10186 mips_optimize = 2;
10187 break;
10189 case 'g':
10190 if (arg == NULL)
10191 mips_debug = 2;
10192 else
10193 mips_debug = atoi (arg);
10194 /* When the MIPS assembler sees -g or -g2, it does not do
10195 optimizations which limit full symbolic debugging. We take
10196 that to be equivalent to -O0. */
10197 if (mips_debug == 2)
10198 mips_optimize = 1;
10199 break;
10201 case OPTION_MIPS1:
10202 file_mips_isa = ISA_MIPS1;
10203 break;
10205 case OPTION_MIPS2:
10206 file_mips_isa = ISA_MIPS2;
10207 break;
10209 case OPTION_MIPS3:
10210 file_mips_isa = ISA_MIPS3;
10211 break;
10213 case OPTION_MIPS4:
10214 file_mips_isa = ISA_MIPS4;
10215 break;
10217 case OPTION_MIPS5:
10218 file_mips_isa = ISA_MIPS5;
10219 break;
10221 case OPTION_MIPS32:
10222 file_mips_isa = ISA_MIPS32;
10223 break;
10225 case OPTION_MIPS32R2:
10226 file_mips_isa = ISA_MIPS32R2;
10227 break;
10229 case OPTION_MIPS64R2:
10230 file_mips_isa = ISA_MIPS64R2;
10231 break;
10233 case OPTION_MIPS64:
10234 file_mips_isa = ISA_MIPS64;
10235 break;
10237 case OPTION_MTUNE:
10238 mips_set_option_string (&mips_tune_string, arg);
10239 break;
10241 case OPTION_MARCH:
10242 mips_set_option_string (&mips_arch_string, arg);
10243 break;
10245 case OPTION_M4650:
10246 mips_set_option_string (&mips_arch_string, "4650");
10247 mips_set_option_string (&mips_tune_string, "4650");
10248 break;
10250 case OPTION_NO_M4650:
10251 break;
10253 case OPTION_M4010:
10254 mips_set_option_string (&mips_arch_string, "4010");
10255 mips_set_option_string (&mips_tune_string, "4010");
10256 break;
10258 case OPTION_NO_M4010:
10259 break;
10261 case OPTION_M4100:
10262 mips_set_option_string (&mips_arch_string, "4100");
10263 mips_set_option_string (&mips_tune_string, "4100");
10264 break;
10266 case OPTION_NO_M4100:
10267 break;
10269 case OPTION_M3900:
10270 mips_set_option_string (&mips_arch_string, "3900");
10271 mips_set_option_string (&mips_tune_string, "3900");
10272 break;
10274 case OPTION_NO_M3900:
10275 break;
10277 case OPTION_MDMX:
10278 mips_opts.ase_mdmx = 1;
10279 break;
10281 case OPTION_NO_MDMX:
10282 mips_opts.ase_mdmx = 0;
10283 break;
10285 case OPTION_MIPS16:
10286 mips_opts.mips16 = 1;
10287 mips_no_prev_insn (FALSE);
10288 break;
10290 case OPTION_NO_MIPS16:
10291 mips_opts.mips16 = 0;
10292 mips_no_prev_insn (FALSE);
10293 break;
10295 case OPTION_MIPS3D:
10296 mips_opts.ase_mips3d = 1;
10297 break;
10299 case OPTION_NO_MIPS3D:
10300 mips_opts.ase_mips3d = 0;
10301 break;
10303 case OPTION_FIX_VR4120:
10304 mips_fix_vr4120 = 1;
10305 break;
10307 case OPTION_NO_FIX_VR4120:
10308 mips_fix_vr4120 = 0;
10309 break;
10311 case OPTION_RELAX_BRANCH:
10312 mips_relax_branch = 1;
10313 break;
10315 case OPTION_NO_RELAX_BRANCH:
10316 mips_relax_branch = 0;
10317 break;
10319 #ifdef OBJ_ELF
10320 /* When generating ELF code, we permit -KPIC and -call_shared to
10321 select SVR4_PIC, and -non_shared to select no PIC. This is
10322 intended to be compatible with Irix 5. */
10323 case OPTION_CALL_SHARED:
10324 if (OUTPUT_FLAVOR != bfd_target_elf_flavour)
10326 as_bad (_("-call_shared is supported only for ELF format"));
10327 return 0;
10329 mips_pic = SVR4_PIC;
10330 mips_abicalls = TRUE;
10331 if (g_switch_seen && g_switch_value != 0)
10333 as_bad (_("-G may not be used with SVR4 PIC code"));
10334 return 0;
10336 g_switch_value = 0;
10337 break;
10339 case OPTION_NON_SHARED:
10340 if (OUTPUT_FLAVOR != bfd_target_elf_flavour)
10342 as_bad (_("-non_shared is supported only for ELF format"));
10343 return 0;
10345 mips_pic = NO_PIC;
10346 mips_abicalls = FALSE;
10347 break;
10349 /* The -xgot option tells the assembler to use 32 offsets when
10350 accessing the got in SVR4_PIC mode. It is for Irix
10351 compatibility. */
10352 case OPTION_XGOT:
10353 mips_big_got = 1;
10354 break;
10355 #endif /* OBJ_ELF */
10357 case 'G':
10358 if (mips_pic == SVR4_PIC)
10360 as_bad (_("-G may not be used with SVR4 PIC code"));
10361 return 0;
10363 else
10364 g_switch_value = atoi (arg);
10365 g_switch_seen = 1;
10366 break;
10368 #ifdef OBJ_ELF
10369 /* The -32, -n32 and -64 options are shortcuts for -mabi=32, -mabi=n32
10370 and -mabi=64. */
10371 case OPTION_32:
10372 if (OUTPUT_FLAVOR != bfd_target_elf_flavour)
10374 as_bad (_("-32 is supported for ELF format only"));
10375 return 0;
10377 mips_abi = O32_ABI;
10378 break;
10380 case OPTION_N32:
10381 if (OUTPUT_FLAVOR != bfd_target_elf_flavour)
10383 as_bad (_("-n32 is supported for ELF format only"));
10384 return 0;
10386 mips_abi = N32_ABI;
10387 break;
10389 case OPTION_64:
10390 if (OUTPUT_FLAVOR != bfd_target_elf_flavour)
10392 as_bad (_("-64 is supported for ELF format only"));
10393 return 0;
10395 mips_abi = N64_ABI;
10396 if (! support_64bit_objects())
10397 as_fatal (_("No compiled in support for 64 bit object file format"));
10398 break;
10399 #endif /* OBJ_ELF */
10401 case OPTION_GP32:
10402 file_mips_gp32 = 1;
10403 break;
10405 case OPTION_GP64:
10406 file_mips_gp32 = 0;
10407 break;
10409 case OPTION_FP32:
10410 file_mips_fp32 = 1;
10411 break;
10413 case OPTION_FP64:
10414 file_mips_fp32 = 0;
10415 break;
10417 #ifdef OBJ_ELF
10418 case OPTION_MABI:
10419 if (OUTPUT_FLAVOR != bfd_target_elf_flavour)
10421 as_bad (_("-mabi is supported for ELF format only"));
10422 return 0;
10424 if (strcmp (arg, "32") == 0)
10425 mips_abi = O32_ABI;
10426 else if (strcmp (arg, "o64") == 0)
10427 mips_abi = O64_ABI;
10428 else if (strcmp (arg, "n32") == 0)
10429 mips_abi = N32_ABI;
10430 else if (strcmp (arg, "64") == 0)
10432 mips_abi = N64_ABI;
10433 if (! support_64bit_objects())
10434 as_fatal (_("No compiled in support for 64 bit object file "
10435 "format"));
10437 else if (strcmp (arg, "eabi") == 0)
10438 mips_abi = EABI_ABI;
10439 else
10441 as_fatal (_("invalid abi -mabi=%s"), arg);
10442 return 0;
10444 break;
10445 #endif /* OBJ_ELF */
10447 case OPTION_M7000_HILO_FIX:
10448 mips_7000_hilo_fix = TRUE;
10449 break;
10451 case OPTION_MNO_7000_HILO_FIX:
10452 mips_7000_hilo_fix = FALSE;
10453 break;
10455 #ifdef OBJ_ELF
10456 case OPTION_MDEBUG:
10457 mips_flag_mdebug = TRUE;
10458 break;
10460 case OPTION_NO_MDEBUG:
10461 mips_flag_mdebug = FALSE;
10462 break;
10464 case OPTION_PDR:
10465 mips_flag_pdr = TRUE;
10466 break;
10468 case OPTION_NO_PDR:
10469 mips_flag_pdr = FALSE;
10470 break;
10471 #endif /* OBJ_ELF */
10473 default:
10474 return 0;
10477 return 1;
10480 /* Set up globals to generate code for the ISA or processor
10481 described by INFO. */
10483 static void
10484 mips_set_architecture (const struct mips_cpu_info *info)
10486 if (info != 0)
10488 file_mips_arch = info->cpu;
10489 mips_opts.arch = info->cpu;
10490 mips_opts.isa = info->isa;
10495 /* Likewise for tuning. */
10497 static void
10498 mips_set_tune (const struct mips_cpu_info *info)
10500 if (info != 0)
10501 mips_tune = info->cpu;
10505 void
10506 mips_after_parse_args (void)
10508 const struct mips_cpu_info *arch_info = 0;
10509 const struct mips_cpu_info *tune_info = 0;
10511 /* GP relative stuff not working for PE */
10512 if (strncmp (TARGET_OS, "pe", 2) == 0
10513 && g_switch_value != 0)
10515 if (g_switch_seen)
10516 as_bad (_("-G not supported in this configuration."));
10517 g_switch_value = 0;
10520 if (mips_abi == NO_ABI)
10521 mips_abi = MIPS_DEFAULT_ABI;
10523 /* The following code determines the architecture and register size.
10524 Similar code was added to GCC 3.3 (see override_options() in
10525 config/mips/mips.c). The GAS and GCC code should be kept in sync
10526 as much as possible. */
10528 if (mips_arch_string != 0)
10529 arch_info = mips_parse_cpu ("-march", mips_arch_string);
10531 if (file_mips_isa != ISA_UNKNOWN)
10533 /* Handle -mipsN. At this point, file_mips_isa contains the
10534 ISA level specified by -mipsN, while arch_info->isa contains
10535 the -march selection (if any). */
10536 if (arch_info != 0)
10538 /* -march takes precedence over -mipsN, since it is more descriptive.
10539 There's no harm in specifying both as long as the ISA levels
10540 are the same. */
10541 if (file_mips_isa != arch_info->isa)
10542 as_bad (_("-%s conflicts with the other architecture options, which imply -%s"),
10543 mips_cpu_info_from_isa (file_mips_isa)->name,
10544 mips_cpu_info_from_isa (arch_info->isa)->name);
10546 else
10547 arch_info = mips_cpu_info_from_isa (file_mips_isa);
10550 if (arch_info == 0)
10551 arch_info = mips_parse_cpu ("default CPU", MIPS_CPU_STRING_DEFAULT);
10553 if (ABI_NEEDS_64BIT_REGS (mips_abi) && !ISA_HAS_64BIT_REGS (arch_info->isa))
10554 as_bad ("-march=%s is not compatible with the selected ABI",
10555 arch_info->name);
10557 mips_set_architecture (arch_info);
10559 /* Optimize for file_mips_arch, unless -mtune selects a different processor. */
10560 if (mips_tune_string != 0)
10561 tune_info = mips_parse_cpu ("-mtune", mips_tune_string);
10563 if (tune_info == 0)
10564 mips_set_tune (arch_info);
10565 else
10566 mips_set_tune (tune_info);
10568 if (file_mips_gp32 >= 0)
10570 /* The user specified the size of the integer registers. Make sure
10571 it agrees with the ABI and ISA. */
10572 if (file_mips_gp32 == 0 && !ISA_HAS_64BIT_REGS (mips_opts.isa))
10573 as_bad (_("-mgp64 used with a 32-bit processor"));
10574 else if (file_mips_gp32 == 1 && ABI_NEEDS_64BIT_REGS (mips_abi))
10575 as_bad (_("-mgp32 used with a 64-bit ABI"));
10576 else if (file_mips_gp32 == 0 && ABI_NEEDS_32BIT_REGS (mips_abi))
10577 as_bad (_("-mgp64 used with a 32-bit ABI"));
10579 else
10581 /* Infer the integer register size from the ABI and processor.
10582 Restrict ourselves to 32-bit registers if that's all the
10583 processor has, or if the ABI cannot handle 64-bit registers. */
10584 file_mips_gp32 = (ABI_NEEDS_32BIT_REGS (mips_abi)
10585 || !ISA_HAS_64BIT_REGS (mips_opts.isa));
10588 /* ??? GAS treats single-float processors as though they had 64-bit
10589 float registers (although it complains when double-precision
10590 instructions are used). As things stand, saying they have 32-bit
10591 registers would lead to spurious "register must be even" messages.
10592 So here we assume float registers are always the same size as
10593 integer ones, unless the user says otherwise. */
10594 if (file_mips_fp32 < 0)
10595 file_mips_fp32 = file_mips_gp32;
10597 /* End of GCC-shared inference code. */
10599 /* This flag is set when we have a 64-bit capable CPU but use only
10600 32-bit wide registers. Note that EABI does not use it. */
10601 if (ISA_HAS_64BIT_REGS (mips_opts.isa)
10602 && ((mips_abi == NO_ABI && file_mips_gp32 == 1)
10603 || mips_abi == O32_ABI))
10604 mips_32bitmode = 1;
10606 if (mips_opts.isa == ISA_MIPS1 && mips_trap)
10607 as_bad (_("trap exception not supported at ISA 1"));
10609 /* If the selected architecture includes support for ASEs, enable
10610 generation of code for them. */
10611 if (mips_opts.mips16 == -1)
10612 mips_opts.mips16 = (CPU_HAS_MIPS16 (file_mips_arch)) ? 1 : 0;
10613 if (mips_opts.ase_mips3d == -1)
10614 mips_opts.ase_mips3d = (CPU_HAS_MIPS3D (file_mips_arch)) ? 1 : 0;
10615 if (mips_opts.ase_mdmx == -1)
10616 mips_opts.ase_mdmx = (CPU_HAS_MDMX (file_mips_arch)) ? 1 : 0;
10618 file_mips_isa = mips_opts.isa;
10619 file_ase_mips16 = mips_opts.mips16;
10620 file_ase_mips3d = mips_opts.ase_mips3d;
10621 file_ase_mdmx = mips_opts.ase_mdmx;
10622 mips_opts.gp32 = file_mips_gp32;
10623 mips_opts.fp32 = file_mips_fp32;
10625 if (mips_flag_mdebug < 0)
10627 #ifdef OBJ_MAYBE_ECOFF
10628 if (OUTPUT_FLAVOR == bfd_target_ecoff_flavour)
10629 mips_flag_mdebug = 1;
10630 else
10631 #endif /* OBJ_MAYBE_ECOFF */
10632 mips_flag_mdebug = 0;
10636 void
10637 mips_init_after_args (void)
10639 /* initialize opcodes */
10640 bfd_mips_num_opcodes = bfd_mips_num_builtin_opcodes;
10641 mips_opcodes = (struct mips_opcode *) mips_builtin_opcodes;
10644 long
10645 md_pcrel_from (fixS *fixP)
10647 valueT addr = fixP->fx_where + fixP->fx_frag->fr_address;
10648 switch (fixP->fx_r_type)
10650 case BFD_RELOC_16_PCREL_S2:
10651 case BFD_RELOC_MIPS_JMP:
10652 /* Return the address of the delay slot. */
10653 return addr + 4;
10654 default:
10655 return addr;
10659 /* This is called before the symbol table is processed. In order to
10660 work with gcc when using mips-tfile, we must keep all local labels.
10661 However, in other cases, we want to discard them. If we were
10662 called with -g, but we didn't see any debugging information, it may
10663 mean that gcc is smuggling debugging information through to
10664 mips-tfile, in which case we must generate all local labels. */
10666 void
10667 mips_frob_file_before_adjust (void)
10669 #ifndef NO_ECOFF_DEBUGGING
10670 if (ECOFF_DEBUGGING
10671 && mips_debug != 0
10672 && ! ecoff_debugging_seen)
10673 flag_keep_locals = 1;
10674 #endif
10677 /* Sort any unmatched HI16 and GOT16 relocs so that they immediately precede
10678 the corresponding LO16 reloc. This is called before md_apply_fix3 and
10679 tc_gen_reloc. Unmatched relocs can only be generated by use of explicit
10680 relocation operators.
10682 For our purposes, a %lo() expression matches a %got() or %hi()
10683 expression if:
10685 (a) it refers to the same symbol; and
10686 (b) the offset applied in the %lo() expression is no lower than
10687 the offset applied in the %got() or %hi().
10689 (b) allows us to cope with code like:
10691 lui $4,%hi(foo)
10692 lh $4,%lo(foo+2)($4)
10694 ...which is legal on RELA targets, and has a well-defined behaviour
10695 if the user knows that adding 2 to "foo" will not induce a carry to
10696 the high 16 bits.
10698 When several %lo()s match a particular %got() or %hi(), we use the
10699 following rules to distinguish them:
10701 (1) %lo()s with smaller offsets are a better match than %lo()s with
10702 higher offsets.
10704 (2) %lo()s with no matching %got() or %hi() are better than those
10705 that already have a matching %got() or %hi().
10707 (3) later %lo()s are better than earlier %lo()s.
10709 These rules are applied in order.
10711 (1) means, among other things, that %lo()s with identical offsets are
10712 chosen if they exist.
10714 (2) means that we won't associate several high-part relocations with
10715 the same low-part relocation unless there's no alternative. Having
10716 several high parts for the same low part is a GNU extension; this rule
10717 allows careful users to avoid it.
10719 (3) is purely cosmetic. mips_hi_fixup_list is is in reverse order,
10720 with the last high-part relocation being at the front of the list.
10721 It therefore makes sense to choose the last matching low-part
10722 relocation, all other things being equal. It's also easier
10723 to code that way. */
10725 void
10726 mips_frob_file (void)
10728 struct mips_hi_fixup *l;
10730 for (l = mips_hi_fixup_list; l != NULL; l = l->next)
10732 segment_info_type *seginfo;
10733 bfd_boolean matched_lo_p;
10734 fixS **hi_pos, **lo_pos, **pos;
10736 assert (reloc_needs_lo_p (l->fixp->fx_r_type));
10738 /* If a GOT16 relocation turns out to be against a global symbol,
10739 there isn't supposed to be a matching LO. */
10740 if (l->fixp->fx_r_type == BFD_RELOC_MIPS_GOT16
10741 && !pic_need_relax (l->fixp->fx_addsy, l->seg))
10742 continue;
10744 /* Check quickly whether the next fixup happens to be a matching %lo. */
10745 if (fixup_has_matching_lo_p (l->fixp))
10746 continue;
10748 seginfo = seg_info (l->seg);
10750 /* Set HI_POS to the position of this relocation in the chain.
10751 Set LO_POS to the position of the chosen low-part relocation.
10752 MATCHED_LO_P is true on entry to the loop if *POS is a low-part
10753 relocation that matches an immediately-preceding high-part
10754 relocation. */
10755 hi_pos = NULL;
10756 lo_pos = NULL;
10757 matched_lo_p = FALSE;
10758 for (pos = &seginfo->fix_root; *pos != NULL; pos = &(*pos)->fx_next)
10760 if (*pos == l->fixp)
10761 hi_pos = pos;
10763 if ((*pos)->fx_r_type == BFD_RELOC_LO16
10764 && (*pos)->fx_addsy == l->fixp->fx_addsy
10765 && (*pos)->fx_offset >= l->fixp->fx_offset
10766 && (lo_pos == NULL
10767 || (*pos)->fx_offset < (*lo_pos)->fx_offset
10768 || (!matched_lo_p
10769 && (*pos)->fx_offset == (*lo_pos)->fx_offset)))
10770 lo_pos = pos;
10772 matched_lo_p = (reloc_needs_lo_p ((*pos)->fx_r_type)
10773 && fixup_has_matching_lo_p (*pos));
10776 /* If we found a match, remove the high-part relocation from its
10777 current position and insert it before the low-part relocation.
10778 Make the offsets match so that fixup_has_matching_lo_p()
10779 will return true.
10781 We don't warn about unmatched high-part relocations since some
10782 versions of gcc have been known to emit dead "lui ...%hi(...)"
10783 instructions. */
10784 if (lo_pos != NULL)
10786 l->fixp->fx_offset = (*lo_pos)->fx_offset;
10787 if (l->fixp->fx_next != *lo_pos)
10789 *hi_pos = l->fixp->fx_next;
10790 l->fixp->fx_next = *lo_pos;
10791 *lo_pos = l->fixp;
10797 /* We may have combined relocations without symbols in the N32/N64 ABI.
10798 We have to prevent gas from dropping them. */
10801 mips_force_relocation (fixS *fixp)
10803 if (generic_force_reloc (fixp))
10804 return 1;
10806 if (HAVE_NEWABI
10807 && S_GET_SEGMENT (fixp->fx_addsy) == bfd_abs_section_ptr
10808 && (fixp->fx_r_type == BFD_RELOC_MIPS_SUB
10809 || fixp->fx_r_type == BFD_RELOC_HI16_S
10810 || fixp->fx_r_type == BFD_RELOC_LO16))
10811 return 1;
10813 return 0;
10816 /* This hook is called before a fix is simplified. We don't really
10817 decide whether to skip a fix here. Rather, we turn global symbols
10818 used as branch targets into local symbols, such that they undergo
10819 simplification. We can only do this if the symbol is defined and
10820 it is in the same section as the branch. If this doesn't hold, we
10821 emit a better error message than just saying the relocation is not
10822 valid for the selected object format.
10824 FIXP is the fix-up we're going to try to simplify, SEG is the
10825 segment in which the fix up occurs. The return value should be
10826 non-zero to indicate the fix-up is valid for further
10827 simplifications. */
10830 mips_validate_fix (struct fix *fixP, asection *seg)
10832 /* There's a lot of discussion on whether it should be possible to
10833 use R_MIPS_PC16 to represent branch relocations. The outcome
10834 seems to be that it can, but gas/bfd are very broken in creating
10835 RELA relocations for this, so for now we only accept branches to
10836 symbols in the same section. Anything else is of dubious value,
10837 since there's no guarantee that at link time the symbol would be
10838 in range. Even for branches to local symbols this is arguably
10839 wrong, since it we assume the symbol is not going to be
10840 overridden, which should be possible per ELF library semantics,
10841 but then, there isn't a dynamic relocation that could be used to
10842 this effect, and the target would likely be out of range as well.
10844 Unfortunately, it seems that there is too much code out there
10845 that relies on branches to symbols that are global to be resolved
10846 as if they were local, like the IRIX tools do, so we do it as
10847 well, but with a warning so that people are reminded to fix their
10848 code. If we ever get back to using R_MIPS_PC16 for branch
10849 targets, this entire block should go away (and probably the
10850 whole function). */
10852 if (fixP->fx_r_type == BFD_RELOC_16_PCREL_S2
10853 && ((OUTPUT_FLAVOR == bfd_target_ecoff_flavour
10854 || OUTPUT_FLAVOR == bfd_target_elf_flavour)
10855 || bfd_reloc_type_lookup (stdoutput, BFD_RELOC_16_PCREL_S2) == NULL)
10856 && fixP->fx_addsy)
10858 if (! S_IS_DEFINED (fixP->fx_addsy))
10860 as_bad_where (fixP->fx_file, fixP->fx_line,
10861 _("Cannot branch to undefined symbol."));
10862 /* Avoid any further errors about this fixup. */
10863 fixP->fx_done = 1;
10865 else if (S_GET_SEGMENT (fixP->fx_addsy) != seg)
10867 as_bad_where (fixP->fx_file, fixP->fx_line,
10868 _("Cannot branch to symbol in another section."));
10869 fixP->fx_done = 1;
10871 else if (S_IS_EXTERNAL (fixP->fx_addsy))
10873 symbolS *sym = fixP->fx_addsy;
10875 if (mips_pic == SVR4_PIC)
10876 as_warn_where (fixP->fx_file, fixP->fx_line,
10877 _("Pretending global symbol used as branch target is local."));
10879 fixP->fx_addsy = symbol_create (S_GET_NAME (sym),
10880 S_GET_SEGMENT (sym),
10881 S_GET_VALUE (sym),
10882 symbol_get_frag (sym));
10883 copy_symbol_attributes (fixP->fx_addsy, sym);
10884 S_CLEAR_EXTERNAL (fixP->fx_addsy);
10885 assert (symbol_resolved_p (sym));
10886 symbol_mark_resolved (fixP->fx_addsy);
10890 return 1;
10893 /* Apply a fixup to the object file. */
10895 void
10896 md_apply_fix3 (fixS *fixP, valueT *valP, segT seg ATTRIBUTE_UNUSED)
10898 bfd_byte *buf;
10899 long insn;
10900 static int previous_fx_r_type = 0;
10901 reloc_howto_type *howto;
10903 /* We ignore generic BFD relocations we don't know about. */
10904 howto = bfd_reloc_type_lookup (stdoutput, fixP->fx_r_type);
10905 if (! howto)
10906 return;
10908 assert (fixP->fx_size == 4
10909 || fixP->fx_r_type == BFD_RELOC_16
10910 || fixP->fx_r_type == BFD_RELOC_64
10911 || fixP->fx_r_type == BFD_RELOC_CTOR
10912 || fixP->fx_r_type == BFD_RELOC_MIPS_SUB
10913 || fixP->fx_r_type == BFD_RELOC_VTABLE_INHERIT
10914 || fixP->fx_r_type == BFD_RELOC_VTABLE_ENTRY);
10916 buf = (bfd_byte *) (fixP->fx_frag->fr_literal + fixP->fx_where);
10918 /* We are not done if this is a composite relocation to set up gp. */
10919 assert (! fixP->fx_pcrel);
10920 if (fixP->fx_addsy == NULL
10921 && !(fixP->fx_r_type == BFD_RELOC_MIPS_SUB
10922 || (fixP->fx_r_type == BFD_RELOC_64
10923 && (previous_fx_r_type == BFD_RELOC_GPREL32
10924 || previous_fx_r_type == BFD_RELOC_GPREL16))
10925 || (previous_fx_r_type == BFD_RELOC_MIPS_SUB
10926 && (fixP->fx_r_type == BFD_RELOC_HI16_S
10927 || fixP->fx_r_type == BFD_RELOC_LO16))))
10928 fixP->fx_done = 1;
10929 previous_fx_r_type = fixP->fx_r_type;
10931 switch (fixP->fx_r_type)
10933 case BFD_RELOC_MIPS_JMP:
10934 case BFD_RELOC_MIPS_SHIFT5:
10935 case BFD_RELOC_MIPS_SHIFT6:
10936 case BFD_RELOC_MIPS_GOT_DISP:
10937 case BFD_RELOC_MIPS_GOT_PAGE:
10938 case BFD_RELOC_MIPS_GOT_OFST:
10939 case BFD_RELOC_MIPS_SUB:
10940 case BFD_RELOC_MIPS_INSERT_A:
10941 case BFD_RELOC_MIPS_INSERT_B:
10942 case BFD_RELOC_MIPS_DELETE:
10943 case BFD_RELOC_MIPS_HIGHEST:
10944 case BFD_RELOC_MIPS_HIGHER:
10945 case BFD_RELOC_MIPS_SCN_DISP:
10946 case BFD_RELOC_MIPS_REL16:
10947 case BFD_RELOC_MIPS_RELGOT:
10948 case BFD_RELOC_MIPS_JALR:
10949 case BFD_RELOC_HI16:
10950 case BFD_RELOC_HI16_S:
10951 case BFD_RELOC_GPREL16:
10952 case BFD_RELOC_MIPS_LITERAL:
10953 case BFD_RELOC_MIPS_CALL16:
10954 case BFD_RELOC_MIPS_GOT16:
10955 case BFD_RELOC_GPREL32:
10956 case BFD_RELOC_MIPS_GOT_HI16:
10957 case BFD_RELOC_MIPS_GOT_LO16:
10958 case BFD_RELOC_MIPS_CALL_HI16:
10959 case BFD_RELOC_MIPS_CALL_LO16:
10960 case BFD_RELOC_MIPS16_GPREL:
10961 assert (! fixP->fx_pcrel);
10962 /* Nothing needed to do. The value comes from the reloc entry */
10963 break;
10965 case BFD_RELOC_MIPS16_JMP:
10966 /* We currently always generate a reloc against a symbol, which
10967 means that we don't want an addend even if the symbol is
10968 defined. */
10969 *valP = 0;
10970 break;
10972 case BFD_RELOC_64:
10973 /* This is handled like BFD_RELOC_32, but we output a sign
10974 extended value if we are only 32 bits. */
10975 if (fixP->fx_done)
10977 if (8 <= sizeof (valueT))
10978 md_number_to_chars (buf, *valP, 8);
10979 else
10981 valueT hiv;
10983 if ((*valP & 0x80000000) != 0)
10984 hiv = 0xffffffff;
10985 else
10986 hiv = 0;
10987 md_number_to_chars ((char *)(buf + target_big_endian ? 4 : 0),
10988 *valP, 4);
10989 md_number_to_chars ((char *)(buf + target_big_endian ? 0 : 4),
10990 hiv, 4);
10993 break;
10995 case BFD_RELOC_RVA:
10996 case BFD_RELOC_32:
10997 /* If we are deleting this reloc entry, we must fill in the
10998 value now. This can happen if we have a .word which is not
10999 resolved when it appears but is later defined. */
11000 if (fixP->fx_done)
11001 md_number_to_chars (buf, *valP, 4);
11002 break;
11004 case BFD_RELOC_16:
11005 /* If we are deleting this reloc entry, we must fill in the
11006 value now. */
11007 assert (fixP->fx_size == 2);
11008 if (fixP->fx_done)
11009 md_number_to_chars (buf, *valP, 2);
11010 break;
11012 case BFD_RELOC_LO16:
11013 /* FIXME: Now that embedded-PIC is gone, some of this code/comment
11014 may be safe to remove, but if so it's not obvious. */
11015 /* When handling an embedded PIC switch statement, we can wind
11016 up deleting a LO16 reloc. See the 'o' case in mips_ip. */
11017 if (fixP->fx_done)
11019 if (*valP + 0x8000 > 0xffff)
11020 as_bad_where (fixP->fx_file, fixP->fx_line,
11021 _("relocation overflow"));
11022 if (target_big_endian)
11023 buf += 2;
11024 md_number_to_chars (buf, *valP, 2);
11026 break;
11028 case BFD_RELOC_16_PCREL_S2:
11029 if ((*valP & 0x3) != 0)
11030 as_bad_where (fixP->fx_file, fixP->fx_line,
11031 _("Branch to odd address (%lx)"), (long) *valP);
11034 * We need to save the bits in the instruction since fixup_segment()
11035 * might be deleting the relocation entry (i.e., a branch within
11036 * the current segment).
11038 if (! fixP->fx_done)
11039 break;
11041 /* update old instruction data */
11042 if (target_big_endian)
11043 insn = (buf[0] << 24) | (buf[1] << 16) | (buf[2] << 8) | buf[3];
11044 else
11045 insn = (buf[3] << 24) | (buf[2] << 16) | (buf[1] << 8) | buf[0];
11047 if (*valP + 0x20000 <= 0x3ffff)
11049 insn |= (*valP >> 2) & 0xffff;
11050 md_number_to_chars (buf, insn, 4);
11052 else if (mips_pic == NO_PIC
11053 && fixP->fx_done
11054 && fixP->fx_frag->fr_address >= text_section->vma
11055 && (fixP->fx_frag->fr_address
11056 < text_section->vma + bfd_get_section_size (text_section))
11057 && ((insn & 0xffff0000) == 0x10000000 /* beq $0,$0 */
11058 || (insn & 0xffff0000) == 0x04010000 /* bgez $0 */
11059 || (insn & 0xffff0000) == 0x04110000)) /* bgezal $0 */
11061 /* The branch offset is too large. If this is an
11062 unconditional branch, and we are not generating PIC code,
11063 we can convert it to an absolute jump instruction. */
11064 if ((insn & 0xffff0000) == 0x04110000) /* bgezal $0 */
11065 insn = 0x0c000000; /* jal */
11066 else
11067 insn = 0x08000000; /* j */
11068 fixP->fx_r_type = BFD_RELOC_MIPS_JMP;
11069 fixP->fx_done = 0;
11070 fixP->fx_addsy = section_symbol (text_section);
11071 *valP += md_pcrel_from (fixP);
11072 md_number_to_chars (buf, insn, 4);
11074 else
11076 /* If we got here, we have branch-relaxation disabled,
11077 and there's nothing we can do to fix this instruction
11078 without turning it into a longer sequence. */
11079 as_bad_where (fixP->fx_file, fixP->fx_line,
11080 _("Branch out of range"));
11082 break;
11084 case BFD_RELOC_VTABLE_INHERIT:
11085 fixP->fx_done = 0;
11086 if (fixP->fx_addsy
11087 && !S_IS_DEFINED (fixP->fx_addsy)
11088 && !S_IS_WEAK (fixP->fx_addsy))
11089 S_SET_WEAK (fixP->fx_addsy);
11090 break;
11092 case BFD_RELOC_VTABLE_ENTRY:
11093 fixP->fx_done = 0;
11094 break;
11096 default:
11097 internalError ();
11100 /* Remember value for tc_gen_reloc. */
11101 fixP->fx_addnumber = *valP;
11104 #if 0
11105 void
11106 printInsn (unsigned long oc)
11108 const struct mips_opcode *p;
11109 int treg, sreg, dreg, shamt;
11110 short imm;
11111 const char *args;
11112 int i;
11114 for (i = 0; i < NUMOPCODES; ++i)
11116 p = &mips_opcodes[i];
11117 if (((oc & p->mask) == p->match) && (p->pinfo != INSN_MACRO))
11119 printf ("%08lx %s\t", oc, p->name);
11120 treg = (oc >> 16) & 0x1f;
11121 sreg = (oc >> 21) & 0x1f;
11122 dreg = (oc >> 11) & 0x1f;
11123 shamt = (oc >> 6) & 0x1f;
11124 imm = oc;
11125 for (args = p->args;; ++args)
11127 switch (*args)
11129 case '\0':
11130 printf ("\n");
11131 break;
11133 case ',':
11134 case '(':
11135 case ')':
11136 printf ("%c", *args);
11137 continue;
11139 case 'r':
11140 assert (treg == sreg);
11141 printf ("$%d,$%d", treg, sreg);
11142 continue;
11144 case 'd':
11145 case 'G':
11146 printf ("$%d", dreg);
11147 continue;
11149 case 't':
11150 case 'E':
11151 printf ("$%d", treg);
11152 continue;
11154 case 'k':
11155 printf ("0x%x", treg);
11156 continue;
11158 case 'b':
11159 case 's':
11160 printf ("$%d", sreg);
11161 continue;
11163 case 'a':
11164 printf ("0x%08lx", oc & 0x1ffffff);
11165 continue;
11167 case 'i':
11168 case 'j':
11169 case 'o':
11170 case 'u':
11171 printf ("%d", imm);
11172 continue;
11174 case '<':
11175 case '>':
11176 printf ("$%d", shamt);
11177 continue;
11179 default:
11180 internalError ();
11182 break;
11184 return;
11187 printf (_("%08lx UNDEFINED\n"), oc);
11189 #endif
11191 static symbolS *
11192 get_symbol (void)
11194 int c;
11195 char *name;
11196 symbolS *p;
11198 name = input_line_pointer;
11199 c = get_symbol_end ();
11200 p = (symbolS *) symbol_find_or_make (name);
11201 *input_line_pointer = c;
11202 return p;
11205 /* Align the current frag to a given power of two. The MIPS assembler
11206 also automatically adjusts any preceding label. */
11208 static void
11209 mips_align (int to, int fill, symbolS *label)
11211 mips_emit_delays (FALSE);
11212 frag_align (to, fill, 0);
11213 record_alignment (now_seg, to);
11214 if (label != NULL)
11216 assert (S_GET_SEGMENT (label) == now_seg);
11217 symbol_set_frag (label, frag_now);
11218 S_SET_VALUE (label, (valueT) frag_now_fix ());
11222 /* Align to a given power of two. .align 0 turns off the automatic
11223 alignment used by the data creating pseudo-ops. */
11225 static void
11226 s_align (int x ATTRIBUTE_UNUSED)
11228 register int temp;
11229 register long temp_fill;
11230 long max_alignment = 15;
11234 o Note that the assembler pulls down any immediately preceding label
11235 to the aligned address.
11236 o It's not documented but auto alignment is reinstated by
11237 a .align pseudo instruction.
11238 o Note also that after auto alignment is turned off the mips assembler
11239 issues an error on attempt to assemble an improperly aligned data item.
11240 We don't.
11244 temp = get_absolute_expression ();
11245 if (temp > max_alignment)
11246 as_bad (_("Alignment too large: %d. assumed."), temp = max_alignment);
11247 else if (temp < 0)
11249 as_warn (_("Alignment negative: 0 assumed."));
11250 temp = 0;
11252 if (*input_line_pointer == ',')
11254 ++input_line_pointer;
11255 temp_fill = get_absolute_expression ();
11257 else
11258 temp_fill = 0;
11259 if (temp)
11261 auto_align = 1;
11262 mips_align (temp, (int) temp_fill,
11263 insn_labels != NULL ? insn_labels->label : NULL);
11265 else
11267 auto_align = 0;
11270 demand_empty_rest_of_line ();
11273 void
11274 mips_flush_pending_output (void)
11276 mips_emit_delays (FALSE);
11277 mips_clear_insn_labels ();
11280 static void
11281 s_change_sec (int sec)
11283 segT seg;
11285 #ifdef OBJ_ELF
11286 /* The ELF backend needs to know that we are changing sections, so
11287 that .previous works correctly. We could do something like check
11288 for an obj_section_change_hook macro, but that might be confusing
11289 as it would not be appropriate to use it in the section changing
11290 functions in read.c, since obj-elf.c intercepts those. FIXME:
11291 This should be cleaner, somehow. */
11292 obj_elf_section_change_hook ();
11293 #endif
11295 mips_emit_delays (FALSE);
11296 switch (sec)
11298 case 't':
11299 s_text (0);
11300 break;
11301 case 'd':
11302 s_data (0);
11303 break;
11304 case 'b':
11305 subseg_set (bss_section, (subsegT) get_absolute_expression ());
11306 demand_empty_rest_of_line ();
11307 break;
11309 case 'r':
11310 seg = subseg_new (RDATA_SECTION_NAME,
11311 (subsegT) get_absolute_expression ());
11312 if (OUTPUT_FLAVOR == bfd_target_elf_flavour)
11314 bfd_set_section_flags (stdoutput, seg, (SEC_ALLOC | SEC_LOAD
11315 | SEC_READONLY | SEC_RELOC
11316 | SEC_DATA));
11317 if (strcmp (TARGET_OS, "elf") != 0)
11318 record_alignment (seg, 4);
11320 demand_empty_rest_of_line ();
11321 break;
11323 case 's':
11324 seg = subseg_new (".sdata", (subsegT) get_absolute_expression ());
11325 if (OUTPUT_FLAVOR == bfd_target_elf_flavour)
11327 bfd_set_section_flags (stdoutput, seg,
11328 SEC_ALLOC | SEC_LOAD | SEC_RELOC | SEC_DATA);
11329 if (strcmp (TARGET_OS, "elf") != 0)
11330 record_alignment (seg, 4);
11332 demand_empty_rest_of_line ();
11333 break;
11336 auto_align = 1;
11339 void
11340 s_change_section (int ignore ATTRIBUTE_UNUSED)
11342 #ifdef OBJ_ELF
11343 char *section_name;
11344 char c;
11345 char next_c = 0;
11346 int section_type;
11347 int section_flag;
11348 int section_entry_size;
11349 int section_alignment;
11351 if (OUTPUT_FLAVOR != bfd_target_elf_flavour)
11352 return;
11354 section_name = input_line_pointer;
11355 c = get_symbol_end ();
11356 if (c)
11357 next_c = *(input_line_pointer + 1);
11359 /* Do we have .section Name<,"flags">? */
11360 if (c != ',' || (c == ',' && next_c == '"'))
11362 /* just after name is now '\0'. */
11363 *input_line_pointer = c;
11364 input_line_pointer = section_name;
11365 obj_elf_section (ignore);
11366 return;
11368 input_line_pointer++;
11370 /* Do we have .section Name<,type><,flag><,entry_size><,alignment> */
11371 if (c == ',')
11372 section_type = get_absolute_expression ();
11373 else
11374 section_type = 0;
11375 if (*input_line_pointer++ == ',')
11376 section_flag = get_absolute_expression ();
11377 else
11378 section_flag = 0;
11379 if (*input_line_pointer++ == ',')
11380 section_entry_size = get_absolute_expression ();
11381 else
11382 section_entry_size = 0;
11383 if (*input_line_pointer++ == ',')
11384 section_alignment = get_absolute_expression ();
11385 else
11386 section_alignment = 0;
11388 section_name = xstrdup (section_name);
11390 /* When using the generic form of .section (as implemented by obj-elf.c),
11391 there's no way to set the section type to SHT_MIPS_DWARF. Users have
11392 traditionally had to fall back on the more common @progbits instead.
11394 There's nothing really harmful in this, since bfd will correct
11395 SHT_PROGBITS to SHT_MIPS_DWARF before writing out the file. But it
11396 means that, for backwards compatibiltiy, the special_section entries
11397 for dwarf sections must use SHT_PROGBITS rather than SHT_MIPS_DWARF.
11399 Even so, we shouldn't force users of the MIPS .section syntax to
11400 incorrectly label the sections as SHT_PROGBITS. The best compromise
11401 seems to be to map SHT_MIPS_DWARF to SHT_PROGBITS before calling the
11402 generic type-checking code. */
11403 if (section_type == SHT_MIPS_DWARF)
11404 section_type = SHT_PROGBITS;
11406 obj_elf_change_section (section_name, section_type, section_flag,
11407 section_entry_size, 0, 0, 0);
11409 if (now_seg->name != section_name)
11410 free (section_name);
11411 #endif /* OBJ_ELF */
11414 void
11415 mips_enable_auto_align (void)
11417 auto_align = 1;
11420 static void
11421 s_cons (int log_size)
11423 symbolS *label;
11425 label = insn_labels != NULL ? insn_labels->label : NULL;
11426 mips_emit_delays (FALSE);
11427 if (log_size > 0 && auto_align)
11428 mips_align (log_size, 0, label);
11429 mips_clear_insn_labels ();
11430 cons (1 << log_size);
11433 static void
11434 s_float_cons (int type)
11436 symbolS *label;
11438 label = insn_labels != NULL ? insn_labels->label : NULL;
11440 mips_emit_delays (FALSE);
11442 if (auto_align)
11444 if (type == 'd')
11445 mips_align (3, 0, label);
11446 else
11447 mips_align (2, 0, label);
11450 mips_clear_insn_labels ();
11452 float_cons (type);
11455 /* Handle .globl. We need to override it because on Irix 5 you are
11456 permitted to say
11457 .globl foo .text
11458 where foo is an undefined symbol, to mean that foo should be
11459 considered to be the address of a function. */
11461 static void
11462 s_mips_globl (int x ATTRIBUTE_UNUSED)
11464 char *name;
11465 int c;
11466 symbolS *symbolP;
11467 flagword flag;
11469 name = input_line_pointer;
11470 c = get_symbol_end ();
11471 symbolP = symbol_find_or_make (name);
11472 *input_line_pointer = c;
11473 SKIP_WHITESPACE ();
11475 /* On Irix 5, every global symbol that is not explicitly labelled as
11476 being a function is apparently labelled as being an object. */
11477 flag = BSF_OBJECT;
11479 if (! is_end_of_line[(unsigned char) *input_line_pointer])
11481 char *secname;
11482 asection *sec;
11484 secname = input_line_pointer;
11485 c = get_symbol_end ();
11486 sec = bfd_get_section_by_name (stdoutput, secname);
11487 if (sec == NULL)
11488 as_bad (_("%s: no such section"), secname);
11489 *input_line_pointer = c;
11491 if (sec != NULL && (sec->flags & SEC_CODE) != 0)
11492 flag = BSF_FUNCTION;
11495 symbol_get_bfdsym (symbolP)->flags |= flag;
11497 S_SET_EXTERNAL (symbolP);
11498 demand_empty_rest_of_line ();
11501 static void
11502 s_option (int x ATTRIBUTE_UNUSED)
11504 char *opt;
11505 char c;
11507 opt = input_line_pointer;
11508 c = get_symbol_end ();
11510 if (*opt == 'O')
11512 /* FIXME: What does this mean? */
11514 else if (strncmp (opt, "pic", 3) == 0)
11516 int i;
11518 i = atoi (opt + 3);
11519 if (i == 0)
11520 mips_pic = NO_PIC;
11521 else if (i == 2)
11523 mips_pic = SVR4_PIC;
11524 mips_abicalls = TRUE;
11526 else
11527 as_bad (_(".option pic%d not supported"), i);
11529 if (mips_pic == SVR4_PIC)
11531 if (g_switch_seen && g_switch_value != 0)
11532 as_warn (_("-G may not be used with SVR4 PIC code"));
11533 g_switch_value = 0;
11534 bfd_set_gp_size (stdoutput, 0);
11537 else
11538 as_warn (_("Unrecognized option \"%s\""), opt);
11540 *input_line_pointer = c;
11541 demand_empty_rest_of_line ();
11544 /* This structure is used to hold a stack of .set values. */
11546 struct mips_option_stack
11548 struct mips_option_stack *next;
11549 struct mips_set_options options;
11552 static struct mips_option_stack *mips_opts_stack;
11554 /* Handle the .set pseudo-op. */
11556 static void
11557 s_mipsset (int x ATTRIBUTE_UNUSED)
11559 char *name = input_line_pointer, ch;
11561 while (!is_end_of_line[(unsigned char) *input_line_pointer])
11562 ++input_line_pointer;
11563 ch = *input_line_pointer;
11564 *input_line_pointer = '\0';
11566 if (strcmp (name, "reorder") == 0)
11568 if (mips_opts.noreorder && prev_nop_frag != NULL)
11570 /* If we still have pending nops, we can discard them. The
11571 usual nop handling will insert any that are still
11572 needed. */
11573 prev_nop_frag->fr_fix -= (prev_nop_frag_holds
11574 * (mips_opts.mips16 ? 2 : 4));
11575 prev_nop_frag = NULL;
11577 mips_opts.noreorder = 0;
11579 else if (strcmp (name, "noreorder") == 0)
11581 mips_emit_delays (TRUE);
11582 mips_opts.noreorder = 1;
11583 mips_any_noreorder = 1;
11585 else if (strcmp (name, "at") == 0)
11587 mips_opts.noat = 0;
11589 else if (strcmp (name, "noat") == 0)
11591 mips_opts.noat = 1;
11593 else if (strcmp (name, "macro") == 0)
11595 mips_opts.warn_about_macros = 0;
11597 else if (strcmp (name, "nomacro") == 0)
11599 if (mips_opts.noreorder == 0)
11600 as_bad (_("`noreorder' must be set before `nomacro'"));
11601 mips_opts.warn_about_macros = 1;
11603 else if (strcmp (name, "move") == 0 || strcmp (name, "novolatile") == 0)
11605 mips_opts.nomove = 0;
11607 else if (strcmp (name, "nomove") == 0 || strcmp (name, "volatile") == 0)
11609 mips_opts.nomove = 1;
11611 else if (strcmp (name, "bopt") == 0)
11613 mips_opts.nobopt = 0;
11615 else if (strcmp (name, "nobopt") == 0)
11617 mips_opts.nobopt = 1;
11619 else if (strcmp (name, "mips16") == 0
11620 || strcmp (name, "MIPS-16") == 0)
11621 mips_opts.mips16 = 1;
11622 else if (strcmp (name, "nomips16") == 0
11623 || strcmp (name, "noMIPS-16") == 0)
11624 mips_opts.mips16 = 0;
11625 else if (strcmp (name, "mips3d") == 0)
11626 mips_opts.ase_mips3d = 1;
11627 else if (strcmp (name, "nomips3d") == 0)
11628 mips_opts.ase_mips3d = 0;
11629 else if (strcmp (name, "mdmx") == 0)
11630 mips_opts.ase_mdmx = 1;
11631 else if (strcmp (name, "nomdmx") == 0)
11632 mips_opts.ase_mdmx = 0;
11633 else if (strncmp (name, "mips", 4) == 0 || strncmp (name, "arch=", 5) == 0)
11635 int reset = 0;
11637 /* Permit the user to change the ISA and architecture on the fly.
11638 Needless to say, misuse can cause serious problems. */
11639 if (strcmp (name, "mips0") == 0 || strcmp (name, "arch=default") == 0)
11641 reset = 1;
11642 mips_opts.isa = file_mips_isa;
11643 mips_opts.arch = file_mips_arch;
11645 else if (strncmp (name, "arch=", 5) == 0)
11647 const struct mips_cpu_info *p;
11649 p = mips_parse_cpu("internal use", name + 5);
11650 if (!p)
11651 as_bad (_("unknown architecture %s"), name + 5);
11652 else
11654 mips_opts.arch = p->cpu;
11655 mips_opts.isa = p->isa;
11658 else if (strncmp (name, "mips", 4) == 0)
11660 const struct mips_cpu_info *p;
11662 p = mips_parse_cpu("internal use", name);
11663 if (!p)
11664 as_bad (_("unknown ISA level %s"), name + 4);
11665 else
11667 mips_opts.arch = p->cpu;
11668 mips_opts.isa = p->isa;
11671 else
11672 as_bad (_("unknown ISA or architecture %s"), name);
11674 switch (mips_opts.isa)
11676 case 0:
11677 break;
11678 case ISA_MIPS1:
11679 case ISA_MIPS2:
11680 case ISA_MIPS32:
11681 case ISA_MIPS32R2:
11682 mips_opts.gp32 = 1;
11683 mips_opts.fp32 = 1;
11684 break;
11685 case ISA_MIPS3:
11686 case ISA_MIPS4:
11687 case ISA_MIPS5:
11688 case ISA_MIPS64:
11689 case ISA_MIPS64R2:
11690 mips_opts.gp32 = 0;
11691 mips_opts.fp32 = 0;
11692 break;
11693 default:
11694 as_bad (_("unknown ISA level %s"), name + 4);
11695 break;
11697 if (reset)
11699 mips_opts.gp32 = file_mips_gp32;
11700 mips_opts.fp32 = file_mips_fp32;
11703 else if (strcmp (name, "autoextend") == 0)
11704 mips_opts.noautoextend = 0;
11705 else if (strcmp (name, "noautoextend") == 0)
11706 mips_opts.noautoextend = 1;
11707 else if (strcmp (name, "push") == 0)
11709 struct mips_option_stack *s;
11711 s = (struct mips_option_stack *) xmalloc (sizeof *s);
11712 s->next = mips_opts_stack;
11713 s->options = mips_opts;
11714 mips_opts_stack = s;
11716 else if (strcmp (name, "pop") == 0)
11718 struct mips_option_stack *s;
11720 s = mips_opts_stack;
11721 if (s == NULL)
11722 as_bad (_(".set pop with no .set push"));
11723 else
11725 /* If we're changing the reorder mode we need to handle
11726 delay slots correctly. */
11727 if (s->options.noreorder && ! mips_opts.noreorder)
11728 mips_emit_delays (TRUE);
11729 else if (! s->options.noreorder && mips_opts.noreorder)
11731 if (prev_nop_frag != NULL)
11733 prev_nop_frag->fr_fix -= (prev_nop_frag_holds
11734 * (mips_opts.mips16 ? 2 : 4));
11735 prev_nop_frag = NULL;
11739 mips_opts = s->options;
11740 mips_opts_stack = s->next;
11741 free (s);
11744 else
11746 as_warn (_("Tried to set unrecognized symbol: %s\n"), name);
11748 *input_line_pointer = ch;
11749 demand_empty_rest_of_line ();
11752 /* Handle the .abicalls pseudo-op. I believe this is equivalent to
11753 .option pic2. It means to generate SVR4 PIC calls. */
11755 static void
11756 s_abicalls (int ignore ATTRIBUTE_UNUSED)
11758 mips_pic = SVR4_PIC;
11759 mips_abicalls = TRUE;
11761 if (g_switch_seen && g_switch_value != 0)
11762 as_warn (_("-G may not be used with SVR4 PIC code"));
11763 g_switch_value = 0;
11765 bfd_set_gp_size (stdoutput, 0);
11766 demand_empty_rest_of_line ();
11769 /* Handle the .cpload pseudo-op. This is used when generating SVR4
11770 PIC code. It sets the $gp register for the function based on the
11771 function address, which is in the register named in the argument.
11772 This uses a relocation against _gp_disp, which is handled specially
11773 by the linker. The result is:
11774 lui $gp,%hi(_gp_disp)
11775 addiu $gp,$gp,%lo(_gp_disp)
11776 addu $gp,$gp,.cpload argument
11777 The .cpload argument is normally $25 == $t9. */
11779 static void
11780 s_cpload (int ignore ATTRIBUTE_UNUSED)
11782 expressionS ex;
11784 /* If we are not generating SVR4 PIC code, or if this is NewABI code,
11785 .cpload is ignored. */
11786 if (mips_pic != SVR4_PIC || HAVE_NEWABI)
11788 s_ignore (0);
11789 return;
11792 /* .cpload should be in a .set noreorder section. */
11793 if (mips_opts.noreorder == 0)
11794 as_warn (_(".cpload not in noreorder section"));
11796 ex.X_op = O_symbol;
11797 ex.X_add_symbol = symbol_find_or_make ("_gp_disp");
11798 ex.X_op_symbol = NULL;
11799 ex.X_add_number = 0;
11801 /* In ELF, this symbol is implicitly an STT_OBJECT symbol. */
11802 symbol_get_bfdsym (ex.X_add_symbol)->flags |= BSF_OBJECT;
11804 macro_start ();
11805 macro_build_lui (&ex, mips_gp_register);
11806 macro_build (&ex, "addiu", "t,r,j", mips_gp_register,
11807 mips_gp_register, BFD_RELOC_LO16);
11808 macro_build (NULL, "addu", "d,v,t", mips_gp_register,
11809 mips_gp_register, tc_get_register (0));
11810 macro_end ();
11812 demand_empty_rest_of_line ();
11815 /* Handle the .cpsetup pseudo-op defined for NewABI PIC code. The syntax is:
11816 .cpsetup $reg1, offset|$reg2, label
11818 If offset is given, this results in:
11819 sd $gp, offset($sp)
11820 lui $gp, %hi(%neg(%gp_rel(label)))
11821 addiu $gp, $gp, %lo(%neg(%gp_rel(label)))
11822 daddu $gp, $gp, $reg1
11824 If $reg2 is given, this results in:
11825 daddu $reg2, $gp, $0
11826 lui $gp, %hi(%neg(%gp_rel(label)))
11827 addiu $gp, $gp, %lo(%neg(%gp_rel(label)))
11828 daddu $gp, $gp, $reg1
11829 $reg1 is normally $25 == $t9. */
11830 static void
11831 s_cpsetup (int ignore ATTRIBUTE_UNUSED)
11833 expressionS ex_off;
11834 expressionS ex_sym;
11835 int reg1;
11836 char *f;
11838 /* If we are not generating SVR4 PIC code, .cpsetup is ignored.
11839 We also need NewABI support. */
11840 if (mips_pic != SVR4_PIC || ! HAVE_NEWABI)
11842 s_ignore (0);
11843 return;
11846 reg1 = tc_get_register (0);
11847 SKIP_WHITESPACE ();
11848 if (*input_line_pointer != ',')
11850 as_bad (_("missing argument separator ',' for .cpsetup"));
11851 return;
11853 else
11854 ++input_line_pointer;
11855 SKIP_WHITESPACE ();
11856 if (*input_line_pointer == '$')
11858 mips_cpreturn_register = tc_get_register (0);
11859 mips_cpreturn_offset = -1;
11861 else
11863 mips_cpreturn_offset = get_absolute_expression ();
11864 mips_cpreturn_register = -1;
11866 SKIP_WHITESPACE ();
11867 if (*input_line_pointer != ',')
11869 as_bad (_("missing argument separator ',' for .cpsetup"));
11870 return;
11872 else
11873 ++input_line_pointer;
11874 SKIP_WHITESPACE ();
11875 expression (&ex_sym);
11877 macro_start ();
11878 if (mips_cpreturn_register == -1)
11880 ex_off.X_op = O_constant;
11881 ex_off.X_add_symbol = NULL;
11882 ex_off.X_op_symbol = NULL;
11883 ex_off.X_add_number = mips_cpreturn_offset;
11885 macro_build (&ex_off, "sd", "t,o(b)", mips_gp_register,
11886 BFD_RELOC_LO16, SP);
11888 else
11889 macro_build (NULL, "daddu", "d,v,t", mips_cpreturn_register,
11890 mips_gp_register, 0);
11892 /* Ensure there's room for the next two instructions, so that `f'
11893 doesn't end up with an address in the wrong frag. */
11894 frag_grow (8);
11895 f = frag_more (0);
11896 macro_build (&ex_sym, "lui", "t,u", mips_gp_register, BFD_RELOC_GPREL16);
11897 fix_new (frag_now, f - frag_now->fr_literal,
11898 8, NULL, 0, 0, BFD_RELOC_MIPS_SUB);
11899 fix_new (frag_now, f - frag_now->fr_literal,
11900 4, NULL, 0, 0, BFD_RELOC_HI16_S);
11902 f = frag_more (0);
11903 macro_build (&ex_sym, "addiu", "t,r,j", mips_gp_register,
11904 mips_gp_register, BFD_RELOC_GPREL16);
11905 fix_new (frag_now, f - frag_now->fr_literal,
11906 8, NULL, 0, 0, BFD_RELOC_MIPS_SUB);
11907 fix_new (frag_now, f - frag_now->fr_literal,
11908 4, NULL, 0, 0, BFD_RELOC_LO16);
11910 macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t", mips_gp_register,
11911 mips_gp_register, reg1);
11912 macro_end ();
11914 demand_empty_rest_of_line ();
11917 static void
11918 s_cplocal (int ignore ATTRIBUTE_UNUSED)
11920 /* If we are not generating SVR4 PIC code, or if this is not NewABI code,
11921 .cplocal is ignored. */
11922 if (mips_pic != SVR4_PIC || ! HAVE_NEWABI)
11924 s_ignore (0);
11925 return;
11928 mips_gp_register = tc_get_register (0);
11929 demand_empty_rest_of_line ();
11932 /* Handle the .cprestore pseudo-op. This stores $gp into a given
11933 offset from $sp. The offset is remembered, and after making a PIC
11934 call $gp is restored from that location. */
11936 static void
11937 s_cprestore (int ignore ATTRIBUTE_UNUSED)
11939 expressionS ex;
11941 /* If we are not generating SVR4 PIC code, or if this is NewABI code,
11942 .cprestore is ignored. */
11943 if (mips_pic != SVR4_PIC || HAVE_NEWABI)
11945 s_ignore (0);
11946 return;
11949 mips_cprestore_offset = get_absolute_expression ();
11950 mips_cprestore_valid = 1;
11952 ex.X_op = O_constant;
11953 ex.X_add_symbol = NULL;
11954 ex.X_op_symbol = NULL;
11955 ex.X_add_number = mips_cprestore_offset;
11957 macro_start ();
11958 macro_build_ldst_constoffset (&ex, ADDRESS_STORE_INSN, mips_gp_register,
11959 SP, HAVE_64BIT_ADDRESSES);
11960 macro_end ();
11962 demand_empty_rest_of_line ();
11965 /* Handle the .cpreturn pseudo-op defined for NewABI PIC code. If an offset
11966 was given in the preceding .cpsetup, it results in:
11967 ld $gp, offset($sp)
11969 If a register $reg2 was given there, it results in:
11970 daddu $gp, $reg2, $0
11972 static void
11973 s_cpreturn (int ignore ATTRIBUTE_UNUSED)
11975 expressionS ex;
11977 /* If we are not generating SVR4 PIC code, .cpreturn is ignored.
11978 We also need NewABI support. */
11979 if (mips_pic != SVR4_PIC || ! HAVE_NEWABI)
11981 s_ignore (0);
11982 return;
11985 macro_start ();
11986 if (mips_cpreturn_register == -1)
11988 ex.X_op = O_constant;
11989 ex.X_add_symbol = NULL;
11990 ex.X_op_symbol = NULL;
11991 ex.X_add_number = mips_cpreturn_offset;
11993 macro_build (&ex, "ld", "t,o(b)", mips_gp_register, BFD_RELOC_LO16, SP);
11995 else
11996 macro_build (NULL, "daddu", "d,v,t", mips_gp_register,
11997 mips_cpreturn_register, 0);
11998 macro_end ();
12000 demand_empty_rest_of_line ();
12003 /* Handle the .gpvalue pseudo-op. This is used when generating NewABI PIC
12004 code. It sets the offset to use in gp_rel relocations. */
12006 static void
12007 s_gpvalue (int ignore ATTRIBUTE_UNUSED)
12009 /* If we are not generating SVR4 PIC code, .gpvalue is ignored.
12010 We also need NewABI support. */
12011 if (mips_pic != SVR4_PIC || ! HAVE_NEWABI)
12013 s_ignore (0);
12014 return;
12017 mips_gprel_offset = get_absolute_expression ();
12019 demand_empty_rest_of_line ();
12022 /* Handle the .gpword pseudo-op. This is used when generating PIC
12023 code. It generates a 32 bit GP relative reloc. */
12025 static void
12026 s_gpword (int ignore ATTRIBUTE_UNUSED)
12028 symbolS *label;
12029 expressionS ex;
12030 char *p;
12032 /* When not generating PIC code, this is treated as .word. */
12033 if (mips_pic != SVR4_PIC)
12035 s_cons (2);
12036 return;
12039 label = insn_labels != NULL ? insn_labels->label : NULL;
12040 mips_emit_delays (TRUE);
12041 if (auto_align)
12042 mips_align (2, 0, label);
12043 mips_clear_insn_labels ();
12045 expression (&ex);
12047 if (ex.X_op != O_symbol || ex.X_add_number != 0)
12049 as_bad (_("Unsupported use of .gpword"));
12050 ignore_rest_of_line ();
12053 p = frag_more (4);
12054 md_number_to_chars (p, 0, 4);
12055 fix_new_exp (frag_now, p - frag_now->fr_literal, 4, &ex, FALSE,
12056 BFD_RELOC_GPREL32);
12058 demand_empty_rest_of_line ();
12061 static void
12062 s_gpdword (int ignore ATTRIBUTE_UNUSED)
12064 symbolS *label;
12065 expressionS ex;
12066 char *p;
12068 /* When not generating PIC code, this is treated as .dword. */
12069 if (mips_pic != SVR4_PIC)
12071 s_cons (3);
12072 return;
12075 label = insn_labels != NULL ? insn_labels->label : NULL;
12076 mips_emit_delays (TRUE);
12077 if (auto_align)
12078 mips_align (3, 0, label);
12079 mips_clear_insn_labels ();
12081 expression (&ex);
12083 if (ex.X_op != O_symbol || ex.X_add_number != 0)
12085 as_bad (_("Unsupported use of .gpdword"));
12086 ignore_rest_of_line ();
12089 p = frag_more (8);
12090 md_number_to_chars (p, 0, 8);
12091 fix_new_exp (frag_now, p - frag_now->fr_literal, 4, &ex, FALSE,
12092 BFD_RELOC_GPREL32);
12094 /* GPREL32 composed with 64 gives a 64-bit GP offset. */
12095 ex.X_op = O_absent;
12096 ex.X_add_symbol = 0;
12097 ex.X_add_number = 0;
12098 fix_new_exp (frag_now, p - frag_now->fr_literal, 8, &ex, FALSE,
12099 BFD_RELOC_64);
12101 demand_empty_rest_of_line ();
12104 /* Handle the .cpadd pseudo-op. This is used when dealing with switch
12105 tables in SVR4 PIC code. */
12107 static void
12108 s_cpadd (int ignore ATTRIBUTE_UNUSED)
12110 int reg;
12112 /* This is ignored when not generating SVR4 PIC code. */
12113 if (mips_pic != SVR4_PIC)
12115 s_ignore (0);
12116 return;
12119 /* Add $gp to the register named as an argument. */
12120 macro_start ();
12121 reg = tc_get_register (0);
12122 macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t", reg, reg, mips_gp_register);
12123 macro_end ();
12125 demand_empty_rest_of_line ();
12128 /* Handle the .insn pseudo-op. This marks instruction labels in
12129 mips16 mode. This permits the linker to handle them specially,
12130 such as generating jalx instructions when needed. We also make
12131 them odd for the duration of the assembly, in order to generate the
12132 right sort of code. We will make them even in the adjust_symtab
12133 routine, while leaving them marked. This is convenient for the
12134 debugger and the disassembler. The linker knows to make them odd
12135 again. */
12137 static void
12138 s_insn (int ignore ATTRIBUTE_UNUSED)
12140 mips16_mark_labels ();
12142 demand_empty_rest_of_line ();
12145 /* Handle a .stabn directive. We need these in order to mark a label
12146 as being a mips16 text label correctly. Sometimes the compiler
12147 will emit a label, followed by a .stabn, and then switch sections.
12148 If the label and .stabn are in mips16 mode, then the label is
12149 really a mips16 text label. */
12151 static void
12152 s_mips_stab (int type)
12154 if (type == 'n')
12155 mips16_mark_labels ();
12157 s_stab (type);
12160 /* Handle the .weakext pseudo-op as defined in Kane and Heinrich.
12163 static void
12164 s_mips_weakext (int ignore ATTRIBUTE_UNUSED)
12166 char *name;
12167 int c;
12168 symbolS *symbolP;
12169 expressionS exp;
12171 name = input_line_pointer;
12172 c = get_symbol_end ();
12173 symbolP = symbol_find_or_make (name);
12174 S_SET_WEAK (symbolP);
12175 *input_line_pointer = c;
12177 SKIP_WHITESPACE ();
12179 if (! is_end_of_line[(unsigned char) *input_line_pointer])
12181 if (S_IS_DEFINED (symbolP))
12183 as_bad ("ignoring attempt to redefine symbol %s",
12184 S_GET_NAME (symbolP));
12185 ignore_rest_of_line ();
12186 return;
12189 if (*input_line_pointer == ',')
12191 ++input_line_pointer;
12192 SKIP_WHITESPACE ();
12195 expression (&exp);
12196 if (exp.X_op != O_symbol)
12198 as_bad ("bad .weakext directive");
12199 ignore_rest_of_line ();
12200 return;
12202 symbol_set_value_expression (symbolP, &exp);
12205 demand_empty_rest_of_line ();
12208 /* Parse a register string into a number. Called from the ECOFF code
12209 to parse .frame. The argument is non-zero if this is the frame
12210 register, so that we can record it in mips_frame_reg. */
12213 tc_get_register (int frame)
12215 int reg;
12217 SKIP_WHITESPACE ();
12218 if (*input_line_pointer++ != '$')
12220 as_warn (_("expected `$'"));
12221 reg = ZERO;
12223 else if (ISDIGIT (*input_line_pointer))
12225 reg = get_absolute_expression ();
12226 if (reg < 0 || reg >= 32)
12228 as_warn (_("Bad register number"));
12229 reg = ZERO;
12232 else
12234 if (strncmp (input_line_pointer, "ra", 2) == 0)
12236 reg = RA;
12237 input_line_pointer += 2;
12239 else if (strncmp (input_line_pointer, "fp", 2) == 0)
12241 reg = FP;
12242 input_line_pointer += 2;
12244 else if (strncmp (input_line_pointer, "sp", 2) == 0)
12246 reg = SP;
12247 input_line_pointer += 2;
12249 else if (strncmp (input_line_pointer, "gp", 2) == 0)
12251 reg = GP;
12252 input_line_pointer += 2;
12254 else if (strncmp (input_line_pointer, "at", 2) == 0)
12256 reg = AT;
12257 input_line_pointer += 2;
12259 else if (strncmp (input_line_pointer, "kt0", 3) == 0)
12261 reg = KT0;
12262 input_line_pointer += 3;
12264 else if (strncmp (input_line_pointer, "kt1", 3) == 0)
12266 reg = KT1;
12267 input_line_pointer += 3;
12269 else if (strncmp (input_line_pointer, "zero", 4) == 0)
12271 reg = ZERO;
12272 input_line_pointer += 4;
12274 else
12276 as_warn (_("Unrecognized register name"));
12277 reg = ZERO;
12278 while (ISALNUM(*input_line_pointer))
12279 input_line_pointer++;
12282 if (frame)
12284 mips_frame_reg = reg != 0 ? reg : SP;
12285 mips_frame_reg_valid = 1;
12286 mips_cprestore_valid = 0;
12288 return reg;
12291 valueT
12292 md_section_align (asection *seg, valueT addr)
12294 int align = bfd_get_section_alignment (stdoutput, seg);
12296 #ifdef OBJ_ELF
12297 /* We don't need to align ELF sections to the full alignment.
12298 However, Irix 5 may prefer that we align them at least to a 16
12299 byte boundary. We don't bother to align the sections if we are
12300 targeted for an embedded system. */
12301 if (strcmp (TARGET_OS, "elf") == 0)
12302 return addr;
12303 if (align > 4)
12304 align = 4;
12305 #endif
12307 return ((addr + (1 << align) - 1) & (-1 << align));
12310 /* Utility routine, called from above as well. If called while the
12311 input file is still being read, it's only an approximation. (For
12312 example, a symbol may later become defined which appeared to be
12313 undefined earlier.) */
12315 static int
12316 nopic_need_relax (symbolS *sym, int before_relaxing)
12318 if (sym == 0)
12319 return 0;
12321 if (g_switch_value > 0)
12323 const char *symname;
12324 int change;
12326 /* Find out whether this symbol can be referenced off the $gp
12327 register. It can be if it is smaller than the -G size or if
12328 it is in the .sdata or .sbss section. Certain symbols can
12329 not be referenced off the $gp, although it appears as though
12330 they can. */
12331 symname = S_GET_NAME (sym);
12332 if (symname != (const char *) NULL
12333 && (strcmp (symname, "eprol") == 0
12334 || strcmp (symname, "etext") == 0
12335 || strcmp (symname, "_gp") == 0
12336 || strcmp (symname, "edata") == 0
12337 || strcmp (symname, "_fbss") == 0
12338 || strcmp (symname, "_fdata") == 0
12339 || strcmp (symname, "_ftext") == 0
12340 || strcmp (symname, "end") == 0
12341 || strcmp (symname, "_gp_disp") == 0))
12342 change = 1;
12343 else if ((! S_IS_DEFINED (sym) || S_IS_COMMON (sym))
12344 && (0
12345 #ifndef NO_ECOFF_DEBUGGING
12346 || (symbol_get_obj (sym)->ecoff_extern_size != 0
12347 && (symbol_get_obj (sym)->ecoff_extern_size
12348 <= g_switch_value))
12349 #endif
12350 /* We must defer this decision until after the whole
12351 file has been read, since there might be a .extern
12352 after the first use of this symbol. */
12353 || (before_relaxing
12354 #ifndef NO_ECOFF_DEBUGGING
12355 && symbol_get_obj (sym)->ecoff_extern_size == 0
12356 #endif
12357 && S_GET_VALUE (sym) == 0)
12358 || (S_GET_VALUE (sym) != 0
12359 && S_GET_VALUE (sym) <= g_switch_value)))
12360 change = 0;
12361 else
12363 const char *segname;
12365 segname = segment_name (S_GET_SEGMENT (sym));
12366 assert (strcmp (segname, ".lit8") != 0
12367 && strcmp (segname, ".lit4") != 0);
12368 change = (strcmp (segname, ".sdata") != 0
12369 && strcmp (segname, ".sbss") != 0
12370 && strncmp (segname, ".sdata.", 7) != 0
12371 && strncmp (segname, ".gnu.linkonce.s.", 16) != 0);
12373 return change;
12375 else
12376 /* We are not optimizing for the $gp register. */
12377 return 1;
12381 /* Return true if the given symbol should be considered local for SVR4 PIC. */
12383 static bfd_boolean
12384 pic_need_relax (symbolS *sym, asection *segtype)
12386 asection *symsec;
12387 bfd_boolean linkonce;
12389 /* Handle the case of a symbol equated to another symbol. */
12390 while (symbol_equated_reloc_p (sym))
12392 symbolS *n;
12394 /* It's possible to get a loop here in a badly written
12395 program. */
12396 n = symbol_get_value_expression (sym)->X_add_symbol;
12397 if (n == sym)
12398 break;
12399 sym = n;
12402 symsec = S_GET_SEGMENT (sym);
12404 /* duplicate the test for LINK_ONCE sections as in adjust_reloc_syms */
12405 linkonce = FALSE;
12406 if (symsec != segtype && ! S_IS_LOCAL (sym))
12408 if ((bfd_get_section_flags (stdoutput, symsec) & SEC_LINK_ONCE)
12409 != 0)
12410 linkonce = TRUE;
12412 /* The GNU toolchain uses an extension for ELF: a section
12413 beginning with the magic string .gnu.linkonce is a linkonce
12414 section. */
12415 if (strncmp (segment_name (symsec), ".gnu.linkonce",
12416 sizeof ".gnu.linkonce" - 1) == 0)
12417 linkonce = TRUE;
12420 /* This must duplicate the test in adjust_reloc_syms. */
12421 return (symsec != &bfd_und_section
12422 && symsec != &bfd_abs_section
12423 && ! bfd_is_com_section (symsec)
12424 && !linkonce
12425 #ifdef OBJ_ELF
12426 /* A global or weak symbol is treated as external. */
12427 && (OUTPUT_FLAVOR != bfd_target_elf_flavour
12428 || (! S_IS_WEAK (sym) && ! S_IS_EXTERNAL (sym)))
12429 #endif
12434 /* Given a mips16 variant frag FRAGP, return non-zero if it needs an
12435 extended opcode. SEC is the section the frag is in. */
12437 static int
12438 mips16_extended_frag (fragS *fragp, asection *sec, long stretch)
12440 int type;
12441 register const struct mips16_immed_operand *op;
12442 offsetT val;
12443 int mintiny, maxtiny;
12444 segT symsec;
12445 fragS *sym_frag;
12447 if (RELAX_MIPS16_USER_SMALL (fragp->fr_subtype))
12448 return 0;
12449 if (RELAX_MIPS16_USER_EXT (fragp->fr_subtype))
12450 return 1;
12452 type = RELAX_MIPS16_TYPE (fragp->fr_subtype);
12453 op = mips16_immed_operands;
12454 while (op->type != type)
12456 ++op;
12457 assert (op < mips16_immed_operands + MIPS16_NUM_IMMED);
12460 if (op->unsp)
12462 if (type == '<' || type == '>' || type == '[' || type == ']')
12464 mintiny = 1;
12465 maxtiny = 1 << op->nbits;
12467 else
12469 mintiny = 0;
12470 maxtiny = (1 << op->nbits) - 1;
12473 else
12475 mintiny = - (1 << (op->nbits - 1));
12476 maxtiny = (1 << (op->nbits - 1)) - 1;
12479 sym_frag = symbol_get_frag (fragp->fr_symbol);
12480 val = S_GET_VALUE (fragp->fr_symbol);
12481 symsec = S_GET_SEGMENT (fragp->fr_symbol);
12483 if (op->pcrel)
12485 addressT addr;
12487 /* We won't have the section when we are called from
12488 mips_relax_frag. However, we will always have been called
12489 from md_estimate_size_before_relax first. If this is a
12490 branch to a different section, we mark it as such. If SEC is
12491 NULL, and the frag is not marked, then it must be a branch to
12492 the same section. */
12493 if (sec == NULL)
12495 if (RELAX_MIPS16_LONG_BRANCH (fragp->fr_subtype))
12496 return 1;
12498 else
12500 /* Must have been called from md_estimate_size_before_relax. */
12501 if (symsec != sec)
12503 fragp->fr_subtype =
12504 RELAX_MIPS16_MARK_LONG_BRANCH (fragp->fr_subtype);
12506 /* FIXME: We should support this, and let the linker
12507 catch branches and loads that are out of range. */
12508 as_bad_where (fragp->fr_file, fragp->fr_line,
12509 _("unsupported PC relative reference to different section"));
12511 return 1;
12513 if (fragp != sym_frag && sym_frag->fr_address == 0)
12514 /* Assume non-extended on the first relaxation pass.
12515 The address we have calculated will be bogus if this is
12516 a forward branch to another frag, as the forward frag
12517 will have fr_address == 0. */
12518 return 0;
12521 /* In this case, we know for sure that the symbol fragment is in
12522 the same section. If the relax_marker of the symbol fragment
12523 differs from the relax_marker of this fragment, we have not
12524 yet adjusted the symbol fragment fr_address. We want to add
12525 in STRETCH in order to get a better estimate of the address.
12526 This particularly matters because of the shift bits. */
12527 if (stretch != 0
12528 && sym_frag->relax_marker != fragp->relax_marker)
12530 fragS *f;
12532 /* Adjust stretch for any alignment frag. Note that if have
12533 been expanding the earlier code, the symbol may be
12534 defined in what appears to be an earlier frag. FIXME:
12535 This doesn't handle the fr_subtype field, which specifies
12536 a maximum number of bytes to skip when doing an
12537 alignment. */
12538 for (f = fragp; f != NULL && f != sym_frag; f = f->fr_next)
12540 if (f->fr_type == rs_align || f->fr_type == rs_align_code)
12542 if (stretch < 0)
12543 stretch = - ((- stretch)
12544 & ~ ((1 << (int) f->fr_offset) - 1));
12545 else
12546 stretch &= ~ ((1 << (int) f->fr_offset) - 1);
12547 if (stretch == 0)
12548 break;
12551 if (f != NULL)
12552 val += stretch;
12555 addr = fragp->fr_address + fragp->fr_fix;
12557 /* The base address rules are complicated. The base address of
12558 a branch is the following instruction. The base address of a
12559 PC relative load or add is the instruction itself, but if it
12560 is in a delay slot (in which case it can not be extended) use
12561 the address of the instruction whose delay slot it is in. */
12562 if (type == 'p' || type == 'q')
12564 addr += 2;
12566 /* If we are currently assuming that this frag should be
12567 extended, then, the current address is two bytes
12568 higher. */
12569 if (RELAX_MIPS16_EXTENDED (fragp->fr_subtype))
12570 addr += 2;
12572 /* Ignore the low bit in the target, since it will be set
12573 for a text label. */
12574 if ((val & 1) != 0)
12575 --val;
12577 else if (RELAX_MIPS16_JAL_DSLOT (fragp->fr_subtype))
12578 addr -= 4;
12579 else if (RELAX_MIPS16_DSLOT (fragp->fr_subtype))
12580 addr -= 2;
12582 val -= addr & ~ ((1 << op->shift) - 1);
12584 /* Branch offsets have an implicit 0 in the lowest bit. */
12585 if (type == 'p' || type == 'q')
12586 val /= 2;
12588 /* If any of the shifted bits are set, we must use an extended
12589 opcode. If the address depends on the size of this
12590 instruction, this can lead to a loop, so we arrange to always
12591 use an extended opcode. We only check this when we are in
12592 the main relaxation loop, when SEC is NULL. */
12593 if ((val & ((1 << op->shift) - 1)) != 0 && sec == NULL)
12595 fragp->fr_subtype =
12596 RELAX_MIPS16_MARK_LONG_BRANCH (fragp->fr_subtype);
12597 return 1;
12600 /* If we are about to mark a frag as extended because the value
12601 is precisely maxtiny + 1, then there is a chance of an
12602 infinite loop as in the following code:
12603 la $4,foo
12604 .skip 1020
12605 .align 2
12606 foo:
12607 In this case when the la is extended, foo is 0x3fc bytes
12608 away, so the la can be shrunk, but then foo is 0x400 away, so
12609 the la must be extended. To avoid this loop, we mark the
12610 frag as extended if it was small, and is about to become
12611 extended with a value of maxtiny + 1. */
12612 if (val == ((maxtiny + 1) << op->shift)
12613 && ! RELAX_MIPS16_EXTENDED (fragp->fr_subtype)
12614 && sec == NULL)
12616 fragp->fr_subtype =
12617 RELAX_MIPS16_MARK_LONG_BRANCH (fragp->fr_subtype);
12618 return 1;
12621 else if (symsec != absolute_section && sec != NULL)
12622 as_bad_where (fragp->fr_file, fragp->fr_line, _("unsupported relocation"));
12624 if ((val & ((1 << op->shift) - 1)) != 0
12625 || val < (mintiny << op->shift)
12626 || val > (maxtiny << op->shift))
12627 return 1;
12628 else
12629 return 0;
12632 /* Compute the length of a branch sequence, and adjust the
12633 RELAX_BRANCH_TOOFAR bit accordingly. If FRAGP is NULL, the
12634 worst-case length is computed, with UPDATE being used to indicate
12635 whether an unconditional (-1), branch-likely (+1) or regular (0)
12636 branch is to be computed. */
12637 static int
12638 relaxed_branch_length (fragS *fragp, asection *sec, int update)
12640 bfd_boolean toofar;
12641 int length;
12643 if (fragp
12644 && S_IS_DEFINED (fragp->fr_symbol)
12645 && sec == S_GET_SEGMENT (fragp->fr_symbol))
12647 addressT addr;
12648 offsetT val;
12650 val = S_GET_VALUE (fragp->fr_symbol) + fragp->fr_offset;
12652 addr = fragp->fr_address + fragp->fr_fix + 4;
12654 val -= addr;
12656 toofar = val < - (0x8000 << 2) || val >= (0x8000 << 2);
12658 else if (fragp)
12659 /* If the symbol is not defined or it's in a different segment,
12660 assume the user knows what's going on and emit a short
12661 branch. */
12662 toofar = FALSE;
12663 else
12664 toofar = TRUE;
12666 if (fragp && update && toofar != RELAX_BRANCH_TOOFAR (fragp->fr_subtype))
12667 fragp->fr_subtype
12668 = RELAX_BRANCH_ENCODE (RELAX_BRANCH_UNCOND (fragp->fr_subtype),
12669 RELAX_BRANCH_LIKELY (fragp->fr_subtype),
12670 RELAX_BRANCH_LINK (fragp->fr_subtype),
12671 toofar);
12673 length = 4;
12674 if (toofar)
12676 if (fragp ? RELAX_BRANCH_LIKELY (fragp->fr_subtype) : (update > 0))
12677 length += 8;
12679 if (mips_pic != NO_PIC)
12681 /* Additional space for PIC loading of target address. */
12682 length += 8;
12683 if (mips_opts.isa == ISA_MIPS1)
12684 /* Additional space for $at-stabilizing nop. */
12685 length += 4;
12688 /* If branch is conditional. */
12689 if (fragp ? !RELAX_BRANCH_UNCOND (fragp->fr_subtype) : (update >= 0))
12690 length += 8;
12693 return length;
12696 /* Estimate the size of a frag before relaxing. Unless this is the
12697 mips16, we are not really relaxing here, and the final size is
12698 encoded in the subtype information. For the mips16, we have to
12699 decide whether we are using an extended opcode or not. */
12702 md_estimate_size_before_relax (fragS *fragp, asection *segtype)
12704 int change;
12706 if (RELAX_BRANCH_P (fragp->fr_subtype))
12709 fragp->fr_var = relaxed_branch_length (fragp, segtype, FALSE);
12711 return fragp->fr_var;
12714 if (RELAX_MIPS16_P (fragp->fr_subtype))
12715 /* We don't want to modify the EXTENDED bit here; it might get us
12716 into infinite loops. We change it only in mips_relax_frag(). */
12717 return (RELAX_MIPS16_EXTENDED (fragp->fr_subtype) ? 4 : 2);
12719 if (mips_pic == NO_PIC)
12720 change = nopic_need_relax (fragp->fr_symbol, 0);
12721 else if (mips_pic == SVR4_PIC)
12722 change = pic_need_relax (fragp->fr_symbol, segtype);
12723 else
12724 abort ();
12726 if (change)
12728 fragp->fr_subtype |= RELAX_USE_SECOND;
12729 return -RELAX_FIRST (fragp->fr_subtype);
12731 else
12732 return -RELAX_SECOND (fragp->fr_subtype);
12735 /* This is called to see whether a reloc against a defined symbol
12736 should be converted into a reloc against a section. */
12739 mips_fix_adjustable (fixS *fixp)
12741 /* Don't adjust MIPS16 jump relocations, so we don't have to worry
12742 about the format of the offset in the .o file. */
12743 if (fixp->fx_r_type == BFD_RELOC_MIPS16_JMP)
12744 return 0;
12746 if (fixp->fx_r_type == BFD_RELOC_VTABLE_INHERIT
12747 || fixp->fx_r_type == BFD_RELOC_VTABLE_ENTRY)
12748 return 0;
12750 if (fixp->fx_addsy == NULL)
12751 return 1;
12753 /* If symbol SYM is in a mergeable section, relocations of the form
12754 SYM + 0 can usually be made section-relative. The mergeable data
12755 is then identified by the section offset rather than by the symbol.
12757 However, if we're generating REL LO16 relocations, the offset is split
12758 between the LO16 and parterning high part relocation. The linker will
12759 need to recalculate the complete offset in order to correctly identify
12760 the merge data.
12762 The linker has traditionally not looked for the parterning high part
12763 relocation, and has thus allowed orphaned R_MIPS_LO16 relocations to be
12764 placed anywhere. Rather than break backwards compatibility by changing
12765 this, it seems better not to force the issue, and instead keep the
12766 original symbol. This will work with either linker behavior. */
12767 if ((fixp->fx_r_type == BFD_RELOC_LO16 || reloc_needs_lo_p (fixp->fx_r_type))
12768 && HAVE_IN_PLACE_ADDENDS
12769 && (S_GET_SEGMENT (fixp->fx_addsy)->flags & SEC_MERGE) != 0)
12770 return 0;
12772 #ifdef OBJ_ELF
12773 /* Don't adjust relocations against mips16 symbols, so that the linker
12774 can find them if it needs to set up a stub. */
12775 if (OUTPUT_FLAVOR == bfd_target_elf_flavour
12776 && S_GET_OTHER (fixp->fx_addsy) == STO_MIPS16
12777 && fixp->fx_subsy == NULL)
12778 return 0;
12779 #endif
12781 return 1;
12784 /* Translate internal representation of relocation info to BFD target
12785 format. */
12787 arelent **
12788 tc_gen_reloc (asection *section ATTRIBUTE_UNUSED, fixS *fixp)
12790 static arelent *retval[4];
12791 arelent *reloc;
12792 bfd_reloc_code_real_type code;
12794 memset (retval, 0, sizeof(retval));
12795 reloc = retval[0] = (arelent *) xcalloc (1, sizeof (arelent));
12796 reloc->sym_ptr_ptr = (asymbol **) xmalloc (sizeof (asymbol *));
12797 *reloc->sym_ptr_ptr = symbol_get_bfdsym (fixp->fx_addsy);
12798 reloc->address = fixp->fx_frag->fr_address + fixp->fx_where;
12800 assert (! fixp->fx_pcrel);
12801 reloc->addend = fixp->fx_addnumber;
12803 /* Since the old MIPS ELF ABI uses Rel instead of Rela, encode the vtable
12804 entry to be used in the relocation's section offset. */
12805 if (! HAVE_NEWABI && fixp->fx_r_type == BFD_RELOC_VTABLE_ENTRY)
12807 reloc->address = reloc->addend;
12808 reloc->addend = 0;
12811 code = fixp->fx_r_type;
12813 /* To support a PC relative reloc, we used a Cygnus extension.
12814 We check for that here to make sure that we don't let such a
12815 reloc escape normally. (FIXME: This was formerly used by
12816 embedded-PIC support, but is now used by branch handling in
12817 general. That probably should be fixed.) */
12818 if ((OUTPUT_FLAVOR == bfd_target_ecoff_flavour
12819 || OUTPUT_FLAVOR == bfd_target_elf_flavour)
12820 && code == BFD_RELOC_16_PCREL_S2)
12821 reloc->howto = NULL;
12822 else
12823 reloc->howto = bfd_reloc_type_lookup (stdoutput, code);
12825 if (reloc->howto == NULL)
12827 as_bad_where (fixp->fx_file, fixp->fx_line,
12828 _("Can not represent %s relocation in this object file format"),
12829 bfd_get_reloc_code_name (code));
12830 retval[0] = NULL;
12833 return retval;
12836 /* Relax a machine dependent frag. This returns the amount by which
12837 the current size of the frag should change. */
12840 mips_relax_frag (asection *sec, fragS *fragp, long stretch)
12842 if (RELAX_BRANCH_P (fragp->fr_subtype))
12844 offsetT old_var = fragp->fr_var;
12846 fragp->fr_var = relaxed_branch_length (fragp, sec, TRUE);
12848 return fragp->fr_var - old_var;
12851 if (! RELAX_MIPS16_P (fragp->fr_subtype))
12852 return 0;
12854 if (mips16_extended_frag (fragp, NULL, stretch))
12856 if (RELAX_MIPS16_EXTENDED (fragp->fr_subtype))
12857 return 0;
12858 fragp->fr_subtype = RELAX_MIPS16_MARK_EXTENDED (fragp->fr_subtype);
12859 return 2;
12861 else
12863 if (! RELAX_MIPS16_EXTENDED (fragp->fr_subtype))
12864 return 0;
12865 fragp->fr_subtype = RELAX_MIPS16_CLEAR_EXTENDED (fragp->fr_subtype);
12866 return -2;
12869 return 0;
12872 /* Convert a machine dependent frag. */
12874 void
12875 md_convert_frag (bfd *abfd ATTRIBUTE_UNUSED, segT asec, fragS *fragp)
12877 if (RELAX_BRANCH_P (fragp->fr_subtype))
12879 bfd_byte *buf;
12880 unsigned long insn;
12881 expressionS exp;
12882 fixS *fixp;
12884 buf = (bfd_byte *)fragp->fr_literal + fragp->fr_fix;
12886 if (target_big_endian)
12887 insn = bfd_getb32 (buf);
12888 else
12889 insn = bfd_getl32 (buf);
12891 if (!RELAX_BRANCH_TOOFAR (fragp->fr_subtype))
12893 /* We generate a fixup instead of applying it right now
12894 because, if there are linker relaxations, we're going to
12895 need the relocations. */
12896 exp.X_op = O_symbol;
12897 exp.X_add_symbol = fragp->fr_symbol;
12898 exp.X_add_number = fragp->fr_offset;
12900 fixp = fix_new_exp (fragp, buf - (bfd_byte *)fragp->fr_literal,
12901 4, &exp, 1,
12902 BFD_RELOC_16_PCREL_S2);
12903 fixp->fx_file = fragp->fr_file;
12904 fixp->fx_line = fragp->fr_line;
12906 md_number_to_chars (buf, insn, 4);
12907 buf += 4;
12909 else
12911 int i;
12913 as_warn_where (fragp->fr_file, fragp->fr_line,
12914 _("relaxed out-of-range branch into a jump"));
12916 if (RELAX_BRANCH_UNCOND (fragp->fr_subtype))
12917 goto uncond;
12919 if (!RELAX_BRANCH_LIKELY (fragp->fr_subtype))
12921 /* Reverse the branch. */
12922 switch ((insn >> 28) & 0xf)
12924 case 4:
12925 /* bc[0-3][tf]l? and bc1any[24][ft] instructions can
12926 have the condition reversed by tweaking a single
12927 bit, and their opcodes all have 0x4???????. */
12928 assert ((insn & 0xf1000000) == 0x41000000);
12929 insn ^= 0x00010000;
12930 break;
12932 case 0:
12933 /* bltz 0x04000000 bgez 0x04010000
12934 bltzal 0x04100000 bgezal 0x04110000 */
12935 assert ((insn & 0xfc0e0000) == 0x04000000);
12936 insn ^= 0x00010000;
12937 break;
12939 case 1:
12940 /* beq 0x10000000 bne 0x14000000
12941 blez 0x18000000 bgtz 0x1c000000 */
12942 insn ^= 0x04000000;
12943 break;
12945 default:
12946 abort ();
12950 if (RELAX_BRANCH_LINK (fragp->fr_subtype))
12952 /* Clear the and-link bit. */
12953 assert ((insn & 0xfc1c0000) == 0x04100000);
12955 /* bltzal 0x04100000 bgezal 0x04110000
12956 bltzall 0x04120000 bgezall 0x04130000 */
12957 insn &= ~0x00100000;
12960 /* Branch over the branch (if the branch was likely) or the
12961 full jump (not likely case). Compute the offset from the
12962 current instruction to branch to. */
12963 if (RELAX_BRANCH_LIKELY (fragp->fr_subtype))
12964 i = 16;
12965 else
12967 /* How many bytes in instructions we've already emitted? */
12968 i = buf - (bfd_byte *)fragp->fr_literal - fragp->fr_fix;
12969 /* How many bytes in instructions from here to the end? */
12970 i = fragp->fr_var - i;
12972 /* Convert to instruction count. */
12973 i >>= 2;
12974 /* Branch counts from the next instruction. */
12975 i--;
12976 insn |= i;
12977 /* Branch over the jump. */
12978 md_number_to_chars (buf, insn, 4);
12979 buf += 4;
12981 /* Nop */
12982 md_number_to_chars (buf, 0, 4);
12983 buf += 4;
12985 if (RELAX_BRANCH_LIKELY (fragp->fr_subtype))
12987 /* beql $0, $0, 2f */
12988 insn = 0x50000000;
12989 /* Compute the PC offset from the current instruction to
12990 the end of the variable frag. */
12991 /* How many bytes in instructions we've already emitted? */
12992 i = buf - (bfd_byte *)fragp->fr_literal - fragp->fr_fix;
12993 /* How many bytes in instructions from here to the end? */
12994 i = fragp->fr_var - i;
12995 /* Convert to instruction count. */
12996 i >>= 2;
12997 /* Don't decrement i, because we want to branch over the
12998 delay slot. */
13000 insn |= i;
13001 md_number_to_chars (buf, insn, 4);
13002 buf += 4;
13004 md_number_to_chars (buf, 0, 4);
13005 buf += 4;
13008 uncond:
13009 if (mips_pic == NO_PIC)
13011 /* j or jal. */
13012 insn = (RELAX_BRANCH_LINK (fragp->fr_subtype)
13013 ? 0x0c000000 : 0x08000000);
13014 exp.X_op = O_symbol;
13015 exp.X_add_symbol = fragp->fr_symbol;
13016 exp.X_add_number = fragp->fr_offset;
13018 fixp = fix_new_exp (fragp, buf - (bfd_byte *)fragp->fr_literal,
13019 4, &exp, 0, BFD_RELOC_MIPS_JMP);
13020 fixp->fx_file = fragp->fr_file;
13021 fixp->fx_line = fragp->fr_line;
13023 md_number_to_chars (buf, insn, 4);
13024 buf += 4;
13026 else
13028 /* lw/ld $at, <sym>($gp) R_MIPS_GOT16 */
13029 insn = HAVE_64BIT_ADDRESSES ? 0xdf810000 : 0x8f810000;
13030 exp.X_op = O_symbol;
13031 exp.X_add_symbol = fragp->fr_symbol;
13032 exp.X_add_number = fragp->fr_offset;
13034 if (fragp->fr_offset)
13036 exp.X_add_symbol = make_expr_symbol (&exp);
13037 exp.X_add_number = 0;
13040 fixp = fix_new_exp (fragp, buf - (bfd_byte *)fragp->fr_literal,
13041 4, &exp, 0, BFD_RELOC_MIPS_GOT16);
13042 fixp->fx_file = fragp->fr_file;
13043 fixp->fx_line = fragp->fr_line;
13045 md_number_to_chars (buf, insn, 4);
13046 buf += 4;
13048 if (mips_opts.isa == ISA_MIPS1)
13050 /* nop */
13051 md_number_to_chars (buf, 0, 4);
13052 buf += 4;
13055 /* d/addiu $at, $at, <sym> R_MIPS_LO16 */
13056 insn = HAVE_64BIT_ADDRESSES ? 0x64210000 : 0x24210000;
13058 fixp = fix_new_exp (fragp, buf - (bfd_byte *)fragp->fr_literal,
13059 4, &exp, 0, BFD_RELOC_LO16);
13060 fixp->fx_file = fragp->fr_file;
13061 fixp->fx_line = fragp->fr_line;
13063 md_number_to_chars (buf, insn, 4);
13064 buf += 4;
13066 /* j(al)r $at. */
13067 if (RELAX_BRANCH_LINK (fragp->fr_subtype))
13068 insn = 0x0020f809;
13069 else
13070 insn = 0x00200008;
13072 md_number_to_chars (buf, insn, 4);
13073 buf += 4;
13077 assert (buf == (bfd_byte *)fragp->fr_literal
13078 + fragp->fr_fix + fragp->fr_var);
13080 fragp->fr_fix += fragp->fr_var;
13082 return;
13085 if (RELAX_MIPS16_P (fragp->fr_subtype))
13087 int type;
13088 register const struct mips16_immed_operand *op;
13089 bfd_boolean small, ext;
13090 offsetT val;
13091 bfd_byte *buf;
13092 unsigned long insn;
13093 bfd_boolean use_extend;
13094 unsigned short extend;
13096 type = RELAX_MIPS16_TYPE (fragp->fr_subtype);
13097 op = mips16_immed_operands;
13098 while (op->type != type)
13099 ++op;
13101 if (RELAX_MIPS16_EXTENDED (fragp->fr_subtype))
13103 small = FALSE;
13104 ext = TRUE;
13106 else
13108 small = TRUE;
13109 ext = FALSE;
13112 resolve_symbol_value (fragp->fr_symbol);
13113 val = S_GET_VALUE (fragp->fr_symbol);
13114 if (op->pcrel)
13116 addressT addr;
13118 addr = fragp->fr_address + fragp->fr_fix;
13120 /* The rules for the base address of a PC relative reloc are
13121 complicated; see mips16_extended_frag. */
13122 if (type == 'p' || type == 'q')
13124 addr += 2;
13125 if (ext)
13126 addr += 2;
13127 /* Ignore the low bit in the target, since it will be
13128 set for a text label. */
13129 if ((val & 1) != 0)
13130 --val;
13132 else if (RELAX_MIPS16_JAL_DSLOT (fragp->fr_subtype))
13133 addr -= 4;
13134 else if (RELAX_MIPS16_DSLOT (fragp->fr_subtype))
13135 addr -= 2;
13137 addr &= ~ (addressT) ((1 << op->shift) - 1);
13138 val -= addr;
13140 /* Make sure the section winds up with the alignment we have
13141 assumed. */
13142 if (op->shift > 0)
13143 record_alignment (asec, op->shift);
13146 if (ext
13147 && (RELAX_MIPS16_JAL_DSLOT (fragp->fr_subtype)
13148 || RELAX_MIPS16_DSLOT (fragp->fr_subtype)))
13149 as_warn_where (fragp->fr_file, fragp->fr_line,
13150 _("extended instruction in delay slot"));
13152 buf = (bfd_byte *) (fragp->fr_literal + fragp->fr_fix);
13154 if (target_big_endian)
13155 insn = bfd_getb16 (buf);
13156 else
13157 insn = bfd_getl16 (buf);
13159 mips16_immed (fragp->fr_file, fragp->fr_line, type, val,
13160 RELAX_MIPS16_USER_EXT (fragp->fr_subtype),
13161 small, ext, &insn, &use_extend, &extend);
13163 if (use_extend)
13165 md_number_to_chars (buf, 0xf000 | extend, 2);
13166 fragp->fr_fix += 2;
13167 buf += 2;
13170 md_number_to_chars (buf, insn, 2);
13171 fragp->fr_fix += 2;
13172 buf += 2;
13174 else
13176 int first, second;
13177 fixS *fixp;
13179 first = RELAX_FIRST (fragp->fr_subtype);
13180 second = RELAX_SECOND (fragp->fr_subtype);
13181 fixp = (fixS *) fragp->fr_opcode;
13183 /* Possibly emit a warning if we've chosen the longer option. */
13184 if (((fragp->fr_subtype & RELAX_USE_SECOND) != 0)
13185 == ((fragp->fr_subtype & RELAX_SECOND_LONGER) != 0))
13187 const char *msg = macro_warning (fragp->fr_subtype);
13188 if (msg != 0)
13189 as_warn_where (fragp->fr_file, fragp->fr_line, msg);
13192 /* Go through all the fixups for the first sequence. Disable them
13193 (by marking them as done) if we're going to use the second
13194 sequence instead. */
13195 while (fixp
13196 && fixp->fx_frag == fragp
13197 && fixp->fx_where < fragp->fr_fix - second)
13199 if (fragp->fr_subtype & RELAX_USE_SECOND)
13200 fixp->fx_done = 1;
13201 fixp = fixp->fx_next;
13204 /* Go through the fixups for the second sequence. Disable them if
13205 we're going to use the first sequence, otherwise adjust their
13206 addresses to account for the relaxation. */
13207 while (fixp && fixp->fx_frag == fragp)
13209 if (fragp->fr_subtype & RELAX_USE_SECOND)
13210 fixp->fx_where -= first;
13211 else
13212 fixp->fx_done = 1;
13213 fixp = fixp->fx_next;
13216 /* Now modify the frag contents. */
13217 if (fragp->fr_subtype & RELAX_USE_SECOND)
13219 char *start;
13221 start = fragp->fr_literal + fragp->fr_fix - first - second;
13222 memmove (start, start + first, second);
13223 fragp->fr_fix -= first;
13225 else
13226 fragp->fr_fix -= second;
13230 #ifdef OBJ_ELF
13232 /* This function is called after the relocs have been generated.
13233 We've been storing mips16 text labels as odd. Here we convert them
13234 back to even for the convenience of the debugger. */
13236 void
13237 mips_frob_file_after_relocs (void)
13239 asymbol **syms;
13240 unsigned int count, i;
13242 if (OUTPUT_FLAVOR != bfd_target_elf_flavour)
13243 return;
13245 syms = bfd_get_outsymbols (stdoutput);
13246 count = bfd_get_symcount (stdoutput);
13247 for (i = 0; i < count; i++, syms++)
13249 if (elf_symbol (*syms)->internal_elf_sym.st_other == STO_MIPS16
13250 && ((*syms)->value & 1) != 0)
13252 (*syms)->value &= ~1;
13253 /* If the symbol has an odd size, it was probably computed
13254 incorrectly, so adjust that as well. */
13255 if ((elf_symbol (*syms)->internal_elf_sym.st_size & 1) != 0)
13256 ++elf_symbol (*syms)->internal_elf_sym.st_size;
13261 #endif
13263 /* This function is called whenever a label is defined. It is used
13264 when handling branch delays; if a branch has a label, we assume we
13265 can not move it. */
13267 void
13268 mips_define_label (symbolS *sym)
13270 struct insn_label_list *l;
13272 if (free_insn_labels == NULL)
13273 l = (struct insn_label_list *) xmalloc (sizeof *l);
13274 else
13276 l = free_insn_labels;
13277 free_insn_labels = l->next;
13280 l->label = sym;
13281 l->next = insn_labels;
13282 insn_labels = l;
13285 #if defined (OBJ_ELF) || defined (OBJ_MAYBE_ELF)
13287 /* Some special processing for a MIPS ELF file. */
13289 void
13290 mips_elf_final_processing (void)
13292 /* Write out the register information. */
13293 if (mips_abi != N64_ABI)
13295 Elf32_RegInfo s;
13297 s.ri_gprmask = mips_gprmask;
13298 s.ri_cprmask[0] = mips_cprmask[0];
13299 s.ri_cprmask[1] = mips_cprmask[1];
13300 s.ri_cprmask[2] = mips_cprmask[2];
13301 s.ri_cprmask[3] = mips_cprmask[3];
13302 /* The gp_value field is set by the MIPS ELF backend. */
13304 bfd_mips_elf32_swap_reginfo_out (stdoutput, &s,
13305 ((Elf32_External_RegInfo *)
13306 mips_regmask_frag));
13308 else
13310 Elf64_Internal_RegInfo s;
13312 s.ri_gprmask = mips_gprmask;
13313 s.ri_pad = 0;
13314 s.ri_cprmask[0] = mips_cprmask[0];
13315 s.ri_cprmask[1] = mips_cprmask[1];
13316 s.ri_cprmask[2] = mips_cprmask[2];
13317 s.ri_cprmask[3] = mips_cprmask[3];
13318 /* The gp_value field is set by the MIPS ELF backend. */
13320 bfd_mips_elf64_swap_reginfo_out (stdoutput, &s,
13321 ((Elf64_External_RegInfo *)
13322 mips_regmask_frag));
13325 /* Set the MIPS ELF flag bits. FIXME: There should probably be some
13326 sort of BFD interface for this. */
13327 if (mips_any_noreorder)
13328 elf_elfheader (stdoutput)->e_flags |= EF_MIPS_NOREORDER;
13329 if (mips_pic != NO_PIC)
13331 elf_elfheader (stdoutput)->e_flags |= EF_MIPS_PIC;
13332 elf_elfheader (stdoutput)->e_flags |= EF_MIPS_CPIC;
13334 if (mips_abicalls)
13335 elf_elfheader (stdoutput)->e_flags |= EF_MIPS_CPIC;
13337 /* Set MIPS ELF flags for ASEs. */
13338 if (file_ase_mips16)
13339 elf_elfheader (stdoutput)->e_flags |= EF_MIPS_ARCH_ASE_M16;
13340 #if 0 /* XXX FIXME */
13341 if (file_ase_mips3d)
13342 elf_elfheader (stdoutput)->e_flags |= ???;
13343 #endif
13344 if (file_ase_mdmx)
13345 elf_elfheader (stdoutput)->e_flags |= EF_MIPS_ARCH_ASE_MDMX;
13347 /* Set the MIPS ELF ABI flags. */
13348 if (mips_abi == O32_ABI && USE_E_MIPS_ABI_O32)
13349 elf_elfheader (stdoutput)->e_flags |= E_MIPS_ABI_O32;
13350 else if (mips_abi == O64_ABI)
13351 elf_elfheader (stdoutput)->e_flags |= E_MIPS_ABI_O64;
13352 else if (mips_abi == EABI_ABI)
13354 if (!file_mips_gp32)
13355 elf_elfheader (stdoutput)->e_flags |= E_MIPS_ABI_EABI64;
13356 else
13357 elf_elfheader (stdoutput)->e_flags |= E_MIPS_ABI_EABI32;
13359 else if (mips_abi == N32_ABI)
13360 elf_elfheader (stdoutput)->e_flags |= EF_MIPS_ABI2;
13362 /* Nothing to do for N64_ABI. */
13364 if (mips_32bitmode)
13365 elf_elfheader (stdoutput)->e_flags |= EF_MIPS_32BITMODE;
13368 #endif /* OBJ_ELF || OBJ_MAYBE_ELF */
13370 typedef struct proc {
13371 symbolS *isym;
13372 unsigned long reg_mask;
13373 unsigned long reg_offset;
13374 unsigned long fpreg_mask;
13375 unsigned long fpreg_offset;
13376 unsigned long frame_offset;
13377 unsigned long frame_reg;
13378 unsigned long pc_reg;
13379 } procS;
13381 static procS cur_proc;
13382 static procS *cur_proc_ptr;
13383 static int numprocs;
13385 /* Fill in an rs_align_code fragment. */
13387 void
13388 mips_handle_align (fragS *fragp)
13390 if (fragp->fr_type != rs_align_code)
13391 return;
13393 if (mips_opts.mips16)
13395 static const unsigned char be_nop[] = { 0x65, 0x00 };
13396 static const unsigned char le_nop[] = { 0x00, 0x65 };
13398 int bytes;
13399 char *p;
13401 bytes = fragp->fr_next->fr_address - fragp->fr_address - fragp->fr_fix;
13402 p = fragp->fr_literal + fragp->fr_fix;
13404 if (bytes & 1)
13406 *p++ = 0;
13407 fragp->fr_fix++;
13410 memcpy (p, (target_big_endian ? be_nop : le_nop), 2);
13411 fragp->fr_var = 2;
13414 /* For mips32, a nop is a zero, which we trivially get by doing nothing. */
13417 static void
13418 md_obj_begin (void)
13422 static void
13423 md_obj_end (void)
13425 /* check for premature end, nesting errors, etc */
13426 if (cur_proc_ptr)
13427 as_warn (_("missing .end at end of assembly"));
13430 static long
13431 get_number (void)
13433 int negative = 0;
13434 long val = 0;
13436 if (*input_line_pointer == '-')
13438 ++input_line_pointer;
13439 negative = 1;
13441 if (!ISDIGIT (*input_line_pointer))
13442 as_bad (_("expected simple number"));
13443 if (input_line_pointer[0] == '0')
13445 if (input_line_pointer[1] == 'x')
13447 input_line_pointer += 2;
13448 while (ISXDIGIT (*input_line_pointer))
13450 val <<= 4;
13451 val |= hex_value (*input_line_pointer++);
13453 return negative ? -val : val;
13455 else
13457 ++input_line_pointer;
13458 while (ISDIGIT (*input_line_pointer))
13460 val <<= 3;
13461 val |= *input_line_pointer++ - '0';
13463 return negative ? -val : val;
13466 if (!ISDIGIT (*input_line_pointer))
13468 printf (_(" *input_line_pointer == '%c' 0x%02x\n"),
13469 *input_line_pointer, *input_line_pointer);
13470 as_warn (_("invalid number"));
13471 return -1;
13473 while (ISDIGIT (*input_line_pointer))
13475 val *= 10;
13476 val += *input_line_pointer++ - '0';
13478 return negative ? -val : val;
13481 /* The .file directive; just like the usual .file directive, but there
13482 is an initial number which is the ECOFF file index. In the non-ECOFF
13483 case .file implies DWARF-2. */
13485 static void
13486 s_mips_file (int x ATTRIBUTE_UNUSED)
13488 static int first_file_directive = 0;
13490 if (ECOFF_DEBUGGING)
13492 get_number ();
13493 s_app_file (0);
13495 else
13497 char *filename;
13499 filename = dwarf2_directive_file (0);
13501 /* Versions of GCC up to 3.1 start files with a ".file"
13502 directive even for stabs output. Make sure that this
13503 ".file" is handled. Note that you need a version of GCC
13504 after 3.1 in order to support DWARF-2 on MIPS. */
13505 if (filename != NULL && ! first_file_directive)
13507 (void) new_logical_line (filename, -1);
13508 s_app_file_string (filename);
13510 first_file_directive = 1;
13514 /* The .loc directive, implying DWARF-2. */
13516 static void
13517 s_mips_loc (int x ATTRIBUTE_UNUSED)
13519 if (!ECOFF_DEBUGGING)
13520 dwarf2_directive_loc (0);
13523 /* The .end directive. */
13525 static void
13526 s_mips_end (int x ATTRIBUTE_UNUSED)
13528 symbolS *p;
13530 /* Following functions need their own .frame and .cprestore directives. */
13531 mips_frame_reg_valid = 0;
13532 mips_cprestore_valid = 0;
13534 if (!is_end_of_line[(unsigned char) *input_line_pointer])
13536 p = get_symbol ();
13537 demand_empty_rest_of_line ();
13539 else
13540 p = NULL;
13542 if ((bfd_get_section_flags (stdoutput, now_seg) & SEC_CODE) == 0)
13543 as_warn (_(".end not in text section"));
13545 if (!cur_proc_ptr)
13547 as_warn (_(".end directive without a preceding .ent directive."));
13548 demand_empty_rest_of_line ();
13549 return;
13552 if (p != NULL)
13554 assert (S_GET_NAME (p));
13555 if (strcmp (S_GET_NAME (p), S_GET_NAME (cur_proc_ptr->isym)))
13556 as_warn (_(".end symbol does not match .ent symbol."));
13558 if (debug_type == DEBUG_STABS)
13559 stabs_generate_asm_endfunc (S_GET_NAME (p),
13560 S_GET_NAME (p));
13562 else
13563 as_warn (_(".end directive missing or unknown symbol"));
13565 #ifdef OBJ_ELF
13566 /* Generate a .pdr section. */
13567 if (OUTPUT_FLAVOR == bfd_target_elf_flavour && ! ECOFF_DEBUGGING
13568 && mips_flag_pdr)
13570 segT saved_seg = now_seg;
13571 subsegT saved_subseg = now_subseg;
13572 valueT dot;
13573 expressionS exp;
13574 char *fragp;
13576 dot = frag_now_fix ();
13578 #ifdef md_flush_pending_output
13579 md_flush_pending_output ();
13580 #endif
13582 assert (pdr_seg);
13583 subseg_set (pdr_seg, 0);
13585 /* Write the symbol. */
13586 exp.X_op = O_symbol;
13587 exp.X_add_symbol = p;
13588 exp.X_add_number = 0;
13589 emit_expr (&exp, 4);
13591 fragp = frag_more (7 * 4);
13593 md_number_to_chars (fragp, cur_proc_ptr->reg_mask, 4);
13594 md_number_to_chars (fragp + 4, cur_proc_ptr->reg_offset, 4);
13595 md_number_to_chars (fragp + 8, cur_proc_ptr->fpreg_mask, 4);
13596 md_number_to_chars (fragp + 12, cur_proc_ptr->fpreg_offset, 4);
13597 md_number_to_chars (fragp + 16, cur_proc_ptr->frame_offset, 4);
13598 md_number_to_chars (fragp + 20, cur_proc_ptr->frame_reg, 4);
13599 md_number_to_chars (fragp + 24, cur_proc_ptr->pc_reg, 4);
13601 subseg_set (saved_seg, saved_subseg);
13603 #endif /* OBJ_ELF */
13605 cur_proc_ptr = NULL;
13608 /* The .aent and .ent directives. */
13610 static void
13611 s_mips_ent (int aent)
13613 symbolS *symbolP;
13615 symbolP = get_symbol ();
13616 if (*input_line_pointer == ',')
13617 ++input_line_pointer;
13618 SKIP_WHITESPACE ();
13619 if (ISDIGIT (*input_line_pointer)
13620 || *input_line_pointer == '-')
13621 get_number ();
13623 if ((bfd_get_section_flags (stdoutput, now_seg) & SEC_CODE) == 0)
13624 as_warn (_(".ent or .aent not in text section."));
13626 if (!aent && cur_proc_ptr)
13627 as_warn (_("missing .end"));
13629 if (!aent)
13631 /* This function needs its own .frame and .cprestore directives. */
13632 mips_frame_reg_valid = 0;
13633 mips_cprestore_valid = 0;
13635 cur_proc_ptr = &cur_proc;
13636 memset (cur_proc_ptr, '\0', sizeof (procS));
13638 cur_proc_ptr->isym = symbolP;
13640 symbol_get_bfdsym (symbolP)->flags |= BSF_FUNCTION;
13642 ++numprocs;
13644 if (debug_type == DEBUG_STABS)
13645 stabs_generate_asm_func (S_GET_NAME (symbolP),
13646 S_GET_NAME (symbolP));
13649 demand_empty_rest_of_line ();
13652 /* The .frame directive. If the mdebug section is present (IRIX 5 native)
13653 then ecoff.c (ecoff_directive_frame) is used. For embedded targets,
13654 s_mips_frame is used so that we can set the PDR information correctly.
13655 We can't use the ecoff routines because they make reference to the ecoff
13656 symbol table (in the mdebug section). */
13658 static void
13659 s_mips_frame (int ignore ATTRIBUTE_UNUSED)
13661 #ifdef OBJ_ELF
13662 if (OUTPUT_FLAVOR == bfd_target_elf_flavour && ! ECOFF_DEBUGGING)
13664 long val;
13666 if (cur_proc_ptr == (procS *) NULL)
13668 as_warn (_(".frame outside of .ent"));
13669 demand_empty_rest_of_line ();
13670 return;
13673 cur_proc_ptr->frame_reg = tc_get_register (1);
13675 SKIP_WHITESPACE ();
13676 if (*input_line_pointer++ != ','
13677 || get_absolute_expression_and_terminator (&val) != ',')
13679 as_warn (_("Bad .frame directive"));
13680 --input_line_pointer;
13681 demand_empty_rest_of_line ();
13682 return;
13685 cur_proc_ptr->frame_offset = val;
13686 cur_proc_ptr->pc_reg = tc_get_register (0);
13688 demand_empty_rest_of_line ();
13690 else
13691 #endif /* OBJ_ELF */
13692 s_ignore (ignore);
13695 /* The .fmask and .mask directives. If the mdebug section is present
13696 (IRIX 5 native) then ecoff.c (ecoff_directive_mask) is used. For
13697 embedded targets, s_mips_mask is used so that we can set the PDR
13698 information correctly. We can't use the ecoff routines because they
13699 make reference to the ecoff symbol table (in the mdebug section). */
13701 static void
13702 s_mips_mask (int reg_type)
13704 #ifdef OBJ_ELF
13705 if (OUTPUT_FLAVOR == bfd_target_elf_flavour && ! ECOFF_DEBUGGING)
13707 long mask, off;
13709 if (cur_proc_ptr == (procS *) NULL)
13711 as_warn (_(".mask/.fmask outside of .ent"));
13712 demand_empty_rest_of_line ();
13713 return;
13716 if (get_absolute_expression_and_terminator (&mask) != ',')
13718 as_warn (_("Bad .mask/.fmask directive"));
13719 --input_line_pointer;
13720 demand_empty_rest_of_line ();
13721 return;
13724 off = get_absolute_expression ();
13726 if (reg_type == 'F')
13728 cur_proc_ptr->fpreg_mask = mask;
13729 cur_proc_ptr->fpreg_offset = off;
13731 else
13733 cur_proc_ptr->reg_mask = mask;
13734 cur_proc_ptr->reg_offset = off;
13737 demand_empty_rest_of_line ();
13739 else
13740 #endif /* OBJ_ELF */
13741 s_ignore (reg_type);
13744 /* The .loc directive. */
13746 #if 0
13747 static void
13748 s_loc (int x)
13750 symbolS *symbolP;
13751 int lineno;
13752 int addroff;
13754 assert (now_seg == text_section);
13756 lineno = get_number ();
13757 addroff = frag_now_fix ();
13759 symbolP = symbol_new ("", N_SLINE, addroff, frag_now);
13760 S_SET_TYPE (symbolP, N_SLINE);
13761 S_SET_OTHER (symbolP, 0);
13762 S_SET_DESC (symbolP, lineno);
13763 symbolP->sy_segment = now_seg;
13765 #endif
13767 /* A table describing all the processors gas knows about. Names are
13768 matched in the order listed.
13770 To ease comparison, please keep this table in the same order as
13771 gcc's mips_cpu_info_table[]. */
13772 static const struct mips_cpu_info mips_cpu_info_table[] =
13774 /* Entries for generic ISAs */
13775 { "mips1", 1, ISA_MIPS1, CPU_R3000 },
13776 { "mips2", 1, ISA_MIPS2, CPU_R6000 },
13777 { "mips3", 1, ISA_MIPS3, CPU_R4000 },
13778 { "mips4", 1, ISA_MIPS4, CPU_R8000 },
13779 { "mips5", 1, ISA_MIPS5, CPU_MIPS5 },
13780 { "mips32", 1, ISA_MIPS32, CPU_MIPS32 },
13781 { "mips32r2", 1, ISA_MIPS32R2, CPU_MIPS32R2 },
13782 { "mips64", 1, ISA_MIPS64, CPU_MIPS64 },
13783 { "mips64r2", 1, ISA_MIPS64R2, CPU_MIPS64R2 },
13785 /* MIPS I */
13786 { "r3000", 0, ISA_MIPS1, CPU_R3000 },
13787 { "r2000", 0, ISA_MIPS1, CPU_R3000 },
13788 { "r3900", 0, ISA_MIPS1, CPU_R3900 },
13790 /* MIPS II */
13791 { "r6000", 0, ISA_MIPS2, CPU_R6000 },
13793 /* MIPS III */
13794 { "r4000", 0, ISA_MIPS3, CPU_R4000 },
13795 { "r4010", 0, ISA_MIPS2, CPU_R4010 },
13796 { "vr4100", 0, ISA_MIPS3, CPU_VR4100 },
13797 { "vr4111", 0, ISA_MIPS3, CPU_R4111 },
13798 { "vr4120", 0, ISA_MIPS3, CPU_VR4120 },
13799 { "vr4130", 0, ISA_MIPS3, CPU_VR4120 },
13800 { "vr4181", 0, ISA_MIPS3, CPU_R4111 },
13801 { "vr4300", 0, ISA_MIPS3, CPU_R4300 },
13802 { "r4400", 0, ISA_MIPS3, CPU_R4400 },
13803 { "r4600", 0, ISA_MIPS3, CPU_R4600 },
13804 { "orion", 0, ISA_MIPS3, CPU_R4600 },
13805 { "r4650", 0, ISA_MIPS3, CPU_R4650 },
13807 /* MIPS IV */
13808 { "r8000", 0, ISA_MIPS4, CPU_R8000 },
13809 { "r10000", 0, ISA_MIPS4, CPU_R10000 },
13810 { "r12000", 0, ISA_MIPS4, CPU_R12000 },
13811 { "vr5000", 0, ISA_MIPS4, CPU_R5000 },
13812 { "vr5400", 0, ISA_MIPS4, CPU_VR5400 },
13813 { "vr5500", 0, ISA_MIPS4, CPU_VR5500 },
13814 { "rm5200", 0, ISA_MIPS4, CPU_R5000 },
13815 { "rm5230", 0, ISA_MIPS4, CPU_R5000 },
13816 { "rm5231", 0, ISA_MIPS4, CPU_R5000 },
13817 { "rm5261", 0, ISA_MIPS4, CPU_R5000 },
13818 { "rm5721", 0, ISA_MIPS4, CPU_R5000 },
13819 { "rm7000", 0, ISA_MIPS4, CPU_RM7000 },
13820 { "rm9000", 0, ISA_MIPS4, CPU_RM7000 },
13822 /* MIPS 32 */
13823 { "4kc", 0, ISA_MIPS32, CPU_MIPS32 },
13824 { "4km", 0, ISA_MIPS32, CPU_MIPS32 },
13825 { "4kp", 0, ISA_MIPS32, CPU_MIPS32 },
13827 /* MIPS 64 */
13828 { "5kc", 0, ISA_MIPS64, CPU_MIPS64 },
13829 { "20kc", 0, ISA_MIPS64, CPU_MIPS64 },
13831 /* Broadcom SB-1 CPU core */
13832 { "sb1", 0, ISA_MIPS64, CPU_SB1 },
13834 /* End marker */
13835 { NULL, 0, 0, 0 }
13839 /* Return true if GIVEN is the same as CANONICAL, or if it is CANONICAL
13840 with a final "000" replaced by "k". Ignore case.
13842 Note: this function is shared between GCC and GAS. */
13844 static bfd_boolean
13845 mips_strict_matching_cpu_name_p (const char *canonical, const char *given)
13847 while (*given != 0 && TOLOWER (*given) == TOLOWER (*canonical))
13848 given++, canonical++;
13850 return ((*given == 0 && *canonical == 0)
13851 || (strcmp (canonical, "000") == 0 && strcasecmp (given, "k") == 0));
13855 /* Return true if GIVEN matches CANONICAL, where GIVEN is a user-supplied
13856 CPU name. We've traditionally allowed a lot of variation here.
13858 Note: this function is shared between GCC and GAS. */
13860 static bfd_boolean
13861 mips_matching_cpu_name_p (const char *canonical, const char *given)
13863 /* First see if the name matches exactly, or with a final "000"
13864 turned into "k". */
13865 if (mips_strict_matching_cpu_name_p (canonical, given))
13866 return TRUE;
13868 /* If not, try comparing based on numerical designation alone.
13869 See if GIVEN is an unadorned number, or 'r' followed by a number. */
13870 if (TOLOWER (*given) == 'r')
13871 given++;
13872 if (!ISDIGIT (*given))
13873 return FALSE;
13875 /* Skip over some well-known prefixes in the canonical name,
13876 hoping to find a number there too. */
13877 if (TOLOWER (canonical[0]) == 'v' && TOLOWER (canonical[1]) == 'r')
13878 canonical += 2;
13879 else if (TOLOWER (canonical[0]) == 'r' && TOLOWER (canonical[1]) == 'm')
13880 canonical += 2;
13881 else if (TOLOWER (canonical[0]) == 'r')
13882 canonical += 1;
13884 return mips_strict_matching_cpu_name_p (canonical, given);
13888 /* Parse an option that takes the name of a processor as its argument.
13889 OPTION is the name of the option and CPU_STRING is the argument.
13890 Return the corresponding processor enumeration if the CPU_STRING is
13891 recognized, otherwise report an error and return null.
13893 A similar function exists in GCC. */
13895 static const struct mips_cpu_info *
13896 mips_parse_cpu (const char *option, const char *cpu_string)
13898 const struct mips_cpu_info *p;
13900 /* 'from-abi' selects the most compatible architecture for the given
13901 ABI: MIPS I for 32-bit ABIs and MIPS III for 64-bit ABIs. For the
13902 EABIs, we have to decide whether we're using the 32-bit or 64-bit
13903 version. Look first at the -mgp options, if given, otherwise base
13904 the choice on MIPS_DEFAULT_64BIT.
13906 Treat NO_ABI like the EABIs. One reason to do this is that the
13907 plain 'mips' and 'mips64' configs have 'from-abi' as their default
13908 architecture. This code picks MIPS I for 'mips' and MIPS III for
13909 'mips64', just as we did in the days before 'from-abi'. */
13910 if (strcasecmp (cpu_string, "from-abi") == 0)
13912 if (ABI_NEEDS_32BIT_REGS (mips_abi))
13913 return mips_cpu_info_from_isa (ISA_MIPS1);
13915 if (ABI_NEEDS_64BIT_REGS (mips_abi))
13916 return mips_cpu_info_from_isa (ISA_MIPS3);
13918 if (file_mips_gp32 >= 0)
13919 return mips_cpu_info_from_isa (file_mips_gp32 ? ISA_MIPS1 : ISA_MIPS3);
13921 return mips_cpu_info_from_isa (MIPS_DEFAULT_64BIT
13922 ? ISA_MIPS3
13923 : ISA_MIPS1);
13926 /* 'default' has traditionally been a no-op. Probably not very useful. */
13927 if (strcasecmp (cpu_string, "default") == 0)
13928 return 0;
13930 for (p = mips_cpu_info_table; p->name != 0; p++)
13931 if (mips_matching_cpu_name_p (p->name, cpu_string))
13932 return p;
13934 as_bad ("Bad value (%s) for %s", cpu_string, option);
13935 return 0;
13938 /* Return the canonical processor information for ISA (a member of the
13939 ISA_MIPS* enumeration). */
13941 static const struct mips_cpu_info *
13942 mips_cpu_info_from_isa (int isa)
13944 int i;
13946 for (i = 0; mips_cpu_info_table[i].name != NULL; i++)
13947 if (mips_cpu_info_table[i].is_isa
13948 && isa == mips_cpu_info_table[i].isa)
13949 return (&mips_cpu_info_table[i]);
13951 return NULL;
13954 static const struct mips_cpu_info *
13955 mips_cpu_info_from_arch (int arch)
13957 int i;
13959 for (i = 0; mips_cpu_info_table[i].name != NULL; i++)
13960 if (arch == mips_cpu_info_table[i].cpu)
13961 return (&mips_cpu_info_table[i]);
13963 return NULL;
13966 static void
13967 show (FILE *stream, const char *string, int *col_p, int *first_p)
13969 if (*first_p)
13971 fprintf (stream, "%24s", "");
13972 *col_p = 24;
13974 else
13976 fprintf (stream, ", ");
13977 *col_p += 2;
13980 if (*col_p + strlen (string) > 72)
13982 fprintf (stream, "\n%24s", "");
13983 *col_p = 24;
13986 fprintf (stream, "%s", string);
13987 *col_p += strlen (string);
13989 *first_p = 0;
13992 void
13993 md_show_usage (FILE *stream)
13995 int column, first;
13996 size_t i;
13998 fprintf (stream, _("\
13999 MIPS options:\n\
14000 -EB generate big endian output\n\
14001 -EL generate little endian output\n\
14002 -g, -g2 do not remove unneeded NOPs or swap branches\n\
14003 -G NUM allow referencing objects up to NUM bytes\n\
14004 implicitly with the gp register [default 8]\n"));
14005 fprintf (stream, _("\
14006 -mips1 generate MIPS ISA I instructions\n\
14007 -mips2 generate MIPS ISA II instructions\n\
14008 -mips3 generate MIPS ISA III instructions\n\
14009 -mips4 generate MIPS ISA IV instructions\n\
14010 -mips5 generate MIPS ISA V instructions\n\
14011 -mips32 generate MIPS32 ISA instructions\n\
14012 -mips32r2 generate MIPS32 release 2 ISA instructions\n\
14013 -mips64 generate MIPS64 ISA instructions\n\
14014 -mips64r2 generate MIPS64 release 2 ISA instructions\n\
14015 -march=CPU/-mtune=CPU generate code/schedule for CPU, where CPU is one of:\n"));
14017 first = 1;
14019 for (i = 0; mips_cpu_info_table[i].name != NULL; i++)
14020 show (stream, mips_cpu_info_table[i].name, &column, &first);
14021 show (stream, "from-abi", &column, &first);
14022 fputc ('\n', stream);
14024 fprintf (stream, _("\
14025 -mCPU equivalent to -march=CPU -mtune=CPU. Deprecated.\n\
14026 -no-mCPU don't generate code specific to CPU.\n\
14027 For -mCPU and -no-mCPU, CPU must be one of:\n"));
14029 first = 1;
14031 show (stream, "3900", &column, &first);
14032 show (stream, "4010", &column, &first);
14033 show (stream, "4100", &column, &first);
14034 show (stream, "4650", &column, &first);
14035 fputc ('\n', stream);
14037 fprintf (stream, _("\
14038 -mips16 generate mips16 instructions\n\
14039 -no-mips16 do not generate mips16 instructions\n"));
14040 fprintf (stream, _("\
14041 -mfix-vr4120 work around certain VR4120 errata\n\
14042 -mgp32 use 32-bit GPRs, regardless of the chosen ISA\n\
14043 -mfp32 use 32-bit FPRs, regardless of the chosen ISA\n\
14044 -O0 remove unneeded NOPs, do not swap branches\n\
14045 -O remove unneeded NOPs and swap branches\n\
14046 --[no-]construct-floats [dis]allow floating point values to be constructed\n\
14047 --trap, --no-break trap exception on div by 0 and mult overflow\n\
14048 --break, --no-trap break exception on div by 0 and mult overflow\n"));
14049 #ifdef OBJ_ELF
14050 fprintf (stream, _("\
14051 -KPIC, -call_shared generate SVR4 position independent code\n\
14052 -non_shared do not generate position independent code\n\
14053 -xgot assume a 32 bit GOT\n\
14054 -mpdr, -mno-pdr enable/disable creation of .pdr sections\n\
14055 -mabi=ABI create ABI conformant object file for:\n"));
14057 first = 1;
14059 show (stream, "32", &column, &first);
14060 show (stream, "o64", &column, &first);
14061 show (stream, "n32", &column, &first);
14062 show (stream, "64", &column, &first);
14063 show (stream, "eabi", &column, &first);
14065 fputc ('\n', stream);
14067 fprintf (stream, _("\
14068 -32 create o32 ABI object file (default)\n\
14069 -n32 create n32 ABI object file\n\
14070 -64 create 64 ABI object file\n"));
14071 #endif
14074 enum dwarf2_format
14075 mips_dwarf2_format (void)
14077 if (mips_abi == N64_ABI)
14079 #ifdef TE_IRIX
14080 return dwarf2_format_64bit_irix;
14081 #else
14082 return dwarf2_format_64bit;
14083 #endif
14085 else
14086 return dwarf2_format_32bit;
14090 mips_dwarf2_addr_size (void)
14092 if (mips_abi == N64_ABI)
14093 return 8;
14094 else
14095 return 4;