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[/] [open8_urisc/] [trunk/] [gnu/] [binutils/] [gas/] [config/] [tc-mips.c] - Blame information for rev 196

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1 16 khays
/* tc-mips.c -- assemble code for a MIPS chip.
2
   Copyright 1993, 1994, 1995, 1996, 1997, 1998, 1999, 2000, 2001, 2002,
3 163 khays
   2003, 2004, 2005, 2006, 2007, 2008, 2009, 2010, 2011
4 16 khays
   Free Software Foundation, Inc.
5
   Contributed by the OSF and Ralph Campbell.
6
   Written by Keith Knowles and Ralph Campbell, working independently.
7
   Modified for ECOFF and R4000 support by Ian Lance Taylor of Cygnus
8
   Support.
9
 
10
   This file is part of GAS.
11
 
12
   GAS is free software; you can redistribute it and/or modify
13
   it under the terms of the GNU General Public License as published by
14
   the Free Software Foundation; either version 3, or (at your option)
15
   any later version.
16
 
17
   GAS is distributed in the hope that it will be useful,
18
   but WITHOUT ANY WARRANTY; without even the implied warranty of
19
   MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
20
   GNU General Public License for more details.
21
 
22
   You should have received a copy of the GNU General Public License
23
   along with GAS; see the file COPYING.  If not, write to the Free
24
   Software Foundation, 51 Franklin Street - Fifth Floor, Boston, MA
25
   02110-1301, USA.  */
26
 
27
#include "as.h"
28
#include "config.h"
29
#include "subsegs.h"
30
#include "safe-ctype.h"
31
 
32
#include "opcode/mips.h"
33
#include "itbl-ops.h"
34
#include "dwarf2dbg.h"
35
#include "dw2gencfi.h"
36
 
37
#ifdef DEBUG
38
#define DBG(x) printf x
39
#else
40
#define DBG(x)
41
#endif
42
 
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
59
 
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
65
 
66
#if defined (OBJ_ELF)
67
#include "elf/mips.h"
68
#endif
69
 
70
#ifndef ECOFF_DEBUGGING
71
#define NO_ECOFF_DEBUGGING
72
#define ECOFF_DEBUGGING 0
73
#endif
74
 
75
int mips_flag_mdebug = -1;
76
 
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
85
 
86
#include "ecoff.h"
87
 
88
#if defined (OBJ_ELF) || defined (OBJ_MAYBE_ELF)
89
static char *mips_regmask_frag;
90
#endif
91
 
92
#define ZERO 0
93
#define ATREG 1
94 160 khays
#define S0  16
95
#define S7  23
96 16 khays
#define TREG 24
97
#define PIC_CALL_REG 25
98
#define KT0 26
99
#define KT1 27
100
#define GP  28
101
#define SP  29
102
#define FP  30
103
#define RA  31
104
 
105
#define ILLEGAL_REG (32)
106
 
107
#define AT  mips_opts.at
108
 
109
/* Allow override of standard little-endian ECOFF format.  */
110
 
111
#ifndef ECOFF_LITTLE_FORMAT
112
#define ECOFF_LITTLE_FORMAT "ecoff-littlemips"
113
#endif
114
 
115
extern int target_big_endian;
116
 
117
/* The name of the readonly data section.  */
118
#define RDATA_SECTION_NAME (OUTPUT_FLAVOR == bfd_target_ecoff_flavour \
119
                            ? ".rdata" \
120
                            : OUTPUT_FLAVOR == bfd_target_coff_flavour \
121
                            ? ".rdata" \
122
                            : OUTPUT_FLAVOR == bfd_target_elf_flavour \
123
                            ? ".rodata" \
124
                            : (abort (), ""))
125
 
126 160 khays
/* Ways in which an instruction can be "appended" to the output.  */
127
enum append_method {
128
  /* Just add it normally.  */
129
  APPEND_ADD,
130
 
131
  /* Add it normally and then add a nop.  */
132
  APPEND_ADD_WITH_NOP,
133
 
134
  /* Turn an instruction with a delay slot into a "compact" version.  */
135
  APPEND_ADD_COMPACT,
136
 
137
  /* Insert the instruction before the last one.  */
138
  APPEND_SWAP
139
};
140
 
141 16 khays
/* Information about an instruction, including its format, operands
142
   and fixups.  */
143
struct mips_cl_insn
144
{
145
  /* The opcode's entry in mips_opcodes or mips16_opcodes.  */
146
  const struct mips_opcode *insn_mo;
147
 
148
  /* True if this is a mips16 instruction and if we want the extended
149
     form of INSN_MO.  */
150
  bfd_boolean use_extend;
151
 
152
  /* The 16-bit extension instruction to use when USE_EXTEND is true.  */
153
  unsigned short extend;
154
 
155
  /* The 16-bit or 32-bit bitstring of the instruction itself.  This is
156
     a copy of INSN_MO->match with the operands filled in.  */
157
  unsigned long insn_opcode;
158
 
159
  /* The frag that contains the instruction.  */
160
  struct frag *frag;
161
 
162
  /* The offset into FRAG of the first instruction byte.  */
163
  long where;
164
 
165
  /* The relocs associated with the instruction, if any.  */
166
  fixS *fixp[3];
167
 
168
  /* True if this entry cannot be moved from its current position.  */
169
  unsigned int fixed_p : 1;
170
 
171
  /* True if this instruction occurred in a .set noreorder block.  */
172
  unsigned int noreorder_p : 1;
173
 
174
  /* True for mips16 instructions that jump to an absolute address.  */
175
  unsigned int mips16_absolute_jump_p : 1;
176
 
177
  /* True if this instruction is complete.  */
178
  unsigned int complete_p : 1;
179
};
180
 
181
/* The ABI to use.  */
182
enum mips_abi_level
183
{
184
  NO_ABI = 0,
185
  O32_ABI,
186
  O64_ABI,
187
  N32_ABI,
188
  N64_ABI,
189
  EABI_ABI
190
};
191
 
192
/* MIPS ABI we are using for this output file.  */
193
static enum mips_abi_level mips_abi = NO_ABI;
194
 
195
/* Whether or not we have code that can call pic code.  */
196
int mips_abicalls = FALSE;
197
 
198
/* Whether or not we have code which can be put into a shared
199
   library.  */
200
static bfd_boolean mips_in_shared = TRUE;
201
 
202
/* This is the set of options which may be modified by the .set
203
   pseudo-op.  We use a struct so that .set push and .set pop are more
204
   reliable.  */
205
 
206
struct mips_set_options
207
{
208
  /* MIPS ISA (Instruction Set Architecture) level.  This is set to -1
209
     if it has not been initialized.  Changed by `.set mipsN', and the
210
     -mipsN command line option, and the default CPU.  */
211
  int isa;
212
  /* Enabled Application Specific Extensions (ASEs).  These are set to -1
213
     if they have not been initialized.  Changed by `.set <asename>', by
214
     command line options, and based on the default architecture.  */
215
  int ase_mips3d;
216
  int ase_mdmx;
217
  int ase_smartmips;
218
  int ase_dsp;
219
  int ase_dspr2;
220
  int ase_mt;
221 160 khays
  int ase_mcu;
222 16 khays
  /* Whether we are assembling for the mips16 processor.  0 if we are
223
     not, 1 if we are, and -1 if the value has not been initialized.
224
     Changed by `.set mips16' and `.set nomips16', and the -mips16 and
225
     -nomips16 command line options, and the default CPU.  */
226
  int mips16;
227 160 khays
  /* Whether we are assembling for the mipsMIPS ASE.  0 if we are not,
228
     1 if we are, and -1 if the value has not been initialized.  Changed
229
     by `.set micromips' and `.set nomicromips', and the -mmicromips
230
     and -mno-micromips command line options, and the default CPU.  */
231
  int micromips;
232 16 khays
  /* Non-zero if we should not reorder instructions.  Changed by `.set
233
     reorder' and `.set noreorder'.  */
234
  int noreorder;
235
  /* Non-zero if we should not permit the register designated "assembler
236
     temporary" to be used in instructions.  The value is the register
237
     number, normally $at ($1).  Changed by `.set at=REG', `.set noat'
238
     (same as `.set at=$0') and `.set at' (same as `.set at=$1').  */
239
  unsigned int at;
240
  /* Non-zero if we should warn when a macro instruction expands into
241
     more than one machine instruction.  Changed by `.set nomacro' and
242
     `.set macro'.  */
243
  int warn_about_macros;
244
  /* Non-zero if we should not move instructions.  Changed by `.set
245
     move', `.set volatile', `.set nomove', and `.set novolatile'.  */
246
  int nomove;
247
  /* Non-zero if we should not optimize branches by moving the target
248
     of the branch into the delay slot.  Actually, we don't perform
249
     this optimization anyhow.  Changed by `.set bopt' and `.set
250
     nobopt'.  */
251
  int nobopt;
252
  /* Non-zero if we should not autoextend mips16 instructions.
253
     Changed by `.set autoextend' and `.set noautoextend'.  */
254
  int noautoextend;
255
  /* Restrict general purpose registers and floating point registers
256
     to 32 bit.  This is initially determined when -mgp32 or -mfp32
257
     is passed but can changed if the assembler code uses .set mipsN.  */
258
  int gp32;
259
  int fp32;
260
  /* MIPS architecture (CPU) type.  Changed by .set arch=FOO, the -march
261
     command line option, and the default CPU.  */
262
  int arch;
263
  /* True if ".set sym32" is in effect.  */
264
  bfd_boolean sym32;
265
  /* True if floating-point operations are not allowed.  Changed by .set
266
     softfloat or .set hardfloat, by command line options -msoft-float or
267
     -mhard-float.  The default is false.  */
268
  bfd_boolean soft_float;
269
 
270
  /* True if only single-precision floating-point operations are allowed.
271
     Changed by .set singlefloat or .set doublefloat, command-line options
272
     -msingle-float or -mdouble-float.  The default is false.  */
273
  bfd_boolean single_float;
274
};
275
 
276
/* This is the struct we use to hold the current set of options.  Note
277
   that we must set the isa field to ISA_UNKNOWN and the ASE fields to
278
   -1 to indicate that they have not been initialized.  */
279
 
280
/* True if -mgp32 was passed.  */
281
static int file_mips_gp32 = -1;
282
 
283
/* True if -mfp32 was passed.  */
284
static int file_mips_fp32 = -1;
285
 
286
/* 1 if -msoft-float, 0 if -mhard-float.  The default is 0.  */
287
static int file_mips_soft_float = 0;
288
 
289
/* 1 if -msingle-float, 0 if -mdouble-float.  The default is 0.   */
290
static int file_mips_single_float = 0;
291
 
292
static struct mips_set_options mips_opts =
293
{
294
  /* isa */ ISA_UNKNOWN, /* ase_mips3d */ -1, /* ase_mdmx */ -1,
295
  /* ase_smartmips */ 0, /* ase_dsp */ -1, /* ase_dspr2 */ -1, /* ase_mt */ -1,
296 160 khays
  /* ase_mcu */ -1, /* mips16 */ -1, /* micromips */ -1, /* noreorder */ 0,
297
  /* at */ ATREG, /* warn_about_macros */ 0, /* nomove */ 0, /* nobopt */ 0,
298 16 khays
  /* noautoextend */ 0, /* gp32 */ 0, /* fp32 */ 0, /* arch */ CPU_UNKNOWN,
299
  /* sym32 */ FALSE, /* soft_float */ FALSE, /* single_float */ FALSE
300
};
301
 
302
/* These variables are filled in with the masks of registers used.
303
   The object format code reads them and puts them in the appropriate
304
   place.  */
305
unsigned long mips_gprmask;
306
unsigned long mips_cprmask[4];
307
 
308
/* MIPS ISA we are using for this output file.  */
309
static int file_mips_isa = ISA_UNKNOWN;
310
 
311
/* True if any MIPS16 code was produced.  */
312
static int file_ase_mips16;
313
 
314
#define ISA_SUPPORTS_MIPS16E (mips_opts.isa == ISA_MIPS32               \
315
                              || mips_opts.isa == ISA_MIPS32R2          \
316
                              || mips_opts.isa == ISA_MIPS64            \
317
                              || mips_opts.isa == ISA_MIPS64R2)
318
 
319 160 khays
/* True if any microMIPS code was produced.  */
320
static int file_ase_micromips;
321
 
322 16 khays
/* True if we want to create R_MIPS_JALR for jalr $25.  */
323
#ifdef TE_IRIX
324
#define MIPS_JALR_HINT_P(EXPR) HAVE_NEWABI
325
#else
326
/* As a GNU extension, we use R_MIPS_JALR for o32 too.  However,
327
   because there's no place for any addend, the only acceptable
328
   expression is a bare symbol.  */
329
#define MIPS_JALR_HINT_P(EXPR) \
330
  (!HAVE_IN_PLACE_ADDENDS \
331
   || ((EXPR)->X_op == O_symbol && (EXPR)->X_add_number == 0))
332
#endif
333
 
334
/* True if -mips3d was passed or implied by arguments passed on the
335
   command line (e.g., by -march).  */
336
static int file_ase_mips3d;
337
 
338
/* True if -mdmx was passed or implied by arguments passed on the
339
   command line (e.g., by -march).  */
340
static int file_ase_mdmx;
341
 
342
/* True if -msmartmips was passed or implied by arguments passed on the
343
   command line (e.g., by -march).  */
344
static int file_ase_smartmips;
345
 
346
#define ISA_SUPPORTS_SMARTMIPS (mips_opts.isa == ISA_MIPS32             \
347
                                || mips_opts.isa == ISA_MIPS32R2)
348
 
349
/* True if -mdsp was passed or implied by arguments passed on the
350
   command line (e.g., by -march).  */
351
static int file_ase_dsp;
352
 
353
#define ISA_SUPPORTS_DSP_ASE (mips_opts.isa == ISA_MIPS32R2             \
354
                              || mips_opts.isa == ISA_MIPS64R2)
355
 
356
#define ISA_SUPPORTS_DSP64_ASE (mips_opts.isa == ISA_MIPS64R2)
357
 
358
/* True if -mdspr2 was passed or implied by arguments passed on the
359
   command line (e.g., by -march).  */
360
static int file_ase_dspr2;
361
 
362
#define ISA_SUPPORTS_DSPR2_ASE (mips_opts.isa == ISA_MIPS32R2           \
363
                                || mips_opts.isa == ISA_MIPS64R2)
364
 
365
/* True if -mmt was passed or implied by arguments passed on the
366
   command line (e.g., by -march).  */
367
static int file_ase_mt;
368
 
369
#define ISA_SUPPORTS_MT_ASE (mips_opts.isa == ISA_MIPS32R2              \
370
                             || mips_opts.isa == ISA_MIPS64R2)
371
 
372 160 khays
#define ISA_SUPPORTS_MCU_ASE (mips_opts.isa == ISA_MIPS32R2             \
373 166 khays
                              || mips_opts.isa == ISA_MIPS64R2          \
374
                              || mips_opts.micromips)
375 160 khays
 
376 16 khays
/* The argument of the -march= flag.  The architecture we are assembling.  */
377
static int file_mips_arch = CPU_UNKNOWN;
378
static const char *mips_arch_string;
379
 
380
/* The argument of the -mtune= flag.  The architecture for which we
381
   are optimizing.  */
382
static int mips_tune = CPU_UNKNOWN;
383
static const char *mips_tune_string;
384
 
385
/* True when generating 32-bit code for a 64-bit processor.  */
386
static int mips_32bitmode = 0;
387
 
388
/* True if the given ABI requires 32-bit registers.  */
389
#define ABI_NEEDS_32BIT_REGS(ABI) ((ABI) == O32_ABI)
390
 
391
/* Likewise 64-bit registers.  */
392
#define ABI_NEEDS_64BIT_REGS(ABI)       \
393
  ((ABI) == N32_ABI                     \
394
   || (ABI) == N64_ABI                  \
395
   || (ABI) == O64_ABI)
396
 
397
/*  Return true if ISA supports 64 bit wide gp registers.  */
398
#define ISA_HAS_64BIT_REGS(ISA)         \
399
  ((ISA) == ISA_MIPS3                   \
400
   || (ISA) == ISA_MIPS4                \
401
   || (ISA) == ISA_MIPS5                \
402
   || (ISA) == ISA_MIPS64               \
403
   || (ISA) == ISA_MIPS64R2)
404
 
405
/*  Return true if ISA supports 64 bit wide float registers.  */
406
#define ISA_HAS_64BIT_FPRS(ISA)         \
407
  ((ISA) == ISA_MIPS3                   \
408
   || (ISA) == ISA_MIPS4                \
409
   || (ISA) == ISA_MIPS5                \
410
   || (ISA) == ISA_MIPS32R2             \
411
   || (ISA) == ISA_MIPS64               \
412
   || (ISA) == ISA_MIPS64R2)
413
 
414
/* Return true if ISA supports 64-bit right rotate (dror et al.)
415
   instructions.  */
416
#define ISA_HAS_DROR(ISA)               \
417 160 khays
  ((ISA) == ISA_MIPS64R2                \
418
   || (mips_opts.micromips              \
419
       && ISA_HAS_64BIT_REGS (ISA))     \
420
   )
421 16 khays
 
422
/* Return true if ISA supports 32-bit right rotate (ror et al.)
423
   instructions.  */
424
#define ISA_HAS_ROR(ISA)                \
425
  ((ISA) == ISA_MIPS32R2                \
426
   || (ISA) == ISA_MIPS64R2             \
427 160 khays
   || mips_opts.ase_smartmips           \
428
   || mips_opts.micromips               \
429
   )
430 16 khays
 
431
/* Return true if ISA supports single-precision floats in odd registers.  */
432
#define ISA_HAS_ODD_SINGLE_FPR(ISA)     \
433
  ((ISA) == ISA_MIPS32                  \
434
   || (ISA) == ISA_MIPS32R2             \
435
   || (ISA) == ISA_MIPS64               \
436
   || (ISA) == ISA_MIPS64R2)
437
 
438
/* Return true if ISA supports move to/from high part of a 64-bit
439
   floating-point register. */
440
#define ISA_HAS_MXHC1(ISA)              \
441
  ((ISA) == ISA_MIPS32R2                \
442
   || (ISA) == ISA_MIPS64R2)
443
 
444
#define HAVE_32BIT_GPRS                            \
445
    (mips_opts.gp32 || !ISA_HAS_64BIT_REGS (mips_opts.isa))
446
 
447
#define HAVE_32BIT_FPRS                            \
448
    (mips_opts.fp32 || !ISA_HAS_64BIT_FPRS (mips_opts.isa))
449
 
450
#define HAVE_64BIT_GPRS (!HAVE_32BIT_GPRS)
451
#define HAVE_64BIT_FPRS (!HAVE_32BIT_FPRS)
452
 
453
#define HAVE_NEWABI (mips_abi == N32_ABI || mips_abi == N64_ABI)
454
 
455
#define HAVE_64BIT_OBJECTS (mips_abi == N64_ABI)
456
 
457
/* True if relocations are stored in-place.  */
458
#define HAVE_IN_PLACE_ADDENDS (!HAVE_NEWABI)
459
 
460
/* The ABI-derived address size.  */
461
#define HAVE_64BIT_ADDRESSES \
462
  (HAVE_64BIT_GPRS && (mips_abi == EABI_ABI || mips_abi == N64_ABI))
463
#define HAVE_32BIT_ADDRESSES (!HAVE_64BIT_ADDRESSES)
464
 
465
/* The size of symbolic constants (i.e., expressions of the form
466
   "SYMBOL" or "SYMBOL + OFFSET").  */
467
#define HAVE_32BIT_SYMBOLS \
468
  (HAVE_32BIT_ADDRESSES || !HAVE_64BIT_OBJECTS || mips_opts.sym32)
469
#define HAVE_64BIT_SYMBOLS (!HAVE_32BIT_SYMBOLS)
470
 
471
/* Addresses are loaded in different ways, depending on the address size
472
   in use.  The n32 ABI Documentation also mandates the use of additions
473
   with overflow checking, but existing implementations don't follow it.  */
474
#define ADDRESS_ADD_INSN                                                \
475
   (HAVE_32BIT_ADDRESSES ? "addu" : "daddu")
476
 
477
#define ADDRESS_ADDI_INSN                                               \
478
   (HAVE_32BIT_ADDRESSES ? "addiu" : "daddiu")
479
 
480
#define ADDRESS_LOAD_INSN                                               \
481
   (HAVE_32BIT_ADDRESSES ? "lw" : "ld")
482
 
483
#define ADDRESS_STORE_INSN                                              \
484
   (HAVE_32BIT_ADDRESSES ? "sw" : "sd")
485
 
486
/* Return true if the given CPU supports the MIPS16 ASE.  */
487
#define CPU_HAS_MIPS16(cpu)                                             \
488
   (strncmp (TARGET_CPU, "mips16", sizeof ("mips16") - 1) == 0           \
489
    || strncmp (TARGET_CANONICAL, "mips-lsi-elf", sizeof ("mips-lsi-elf") - 1) == 0)
490
 
491 160 khays
/* Return true if the given CPU supports the microMIPS ASE.  */
492
#define CPU_HAS_MICROMIPS(cpu)  0
493
 
494 16 khays
/* True if CPU has a dror instruction.  */
495
#define CPU_HAS_DROR(CPU)       ((CPU) == CPU_VR5400 || (CPU) == CPU_VR5500)
496
 
497
/* True if CPU has a ror instruction.  */
498
#define CPU_HAS_ROR(CPU)        CPU_HAS_DROR (CPU)
499
 
500 166 khays
/* True if CPU is in the Octeon family */
501
#define CPU_IS_OCTEON(CPU) ((CPU) == CPU_OCTEON || (CPU) == CPU_OCTEONP || (CPU) == CPU_OCTEON2)
502
 
503 16 khays
/* True if CPU has seq/sne and seqi/snei instructions.  */
504 166 khays
#define CPU_HAS_SEQ(CPU)        (CPU_IS_OCTEON (CPU))
505 16 khays
 
506
/* True if CPU does not implement the all the coprocessor insns.  For these
507
   CPUs only those COP insns are accepted that are explicitly marked to be
508
   available on the CPU.  ISA membership for COP insns is ignored.  */
509 166 khays
#define NO_ISA_COP(CPU)         (CPU_IS_OCTEON (CPU))
510 16 khays
 
511
/* True if mflo and mfhi can be immediately followed by instructions
512
   which write to the HI and LO registers.
513
 
514
   According to MIPS specifications, MIPS ISAs I, II, and III need
515
   (at least) two instructions between the reads of HI/LO and
516
   instructions which write them, and later ISAs do not.  Contradicting
517
   the MIPS specifications, some MIPS IV processor user manuals (e.g.
518
   the UM for the NEC Vr5000) document needing the instructions between
519
   HI/LO reads and writes, as well.  Therefore, we declare only MIPS32,
520
   MIPS64 and later ISAs to have the interlocks, plus any specific
521
   earlier-ISA CPUs for which CPU documentation declares that the
522
   instructions are really interlocked.  */
523
#define hilo_interlocks \
524
  (mips_opts.isa == ISA_MIPS32                        \
525
   || mips_opts.isa == ISA_MIPS32R2                   \
526
   || mips_opts.isa == ISA_MIPS64                     \
527
   || mips_opts.isa == ISA_MIPS64R2                   \
528
   || mips_opts.arch == CPU_R4010                     \
529
   || mips_opts.arch == CPU_R10000                    \
530
   || mips_opts.arch == CPU_R12000                    \
531
   || mips_opts.arch == CPU_R14000                    \
532
   || mips_opts.arch == CPU_R16000                    \
533
   || mips_opts.arch == CPU_RM7000                    \
534
   || mips_opts.arch == CPU_VR5500                    \
535 160 khays
   || mips_opts.micromips                             \
536 16 khays
   )
537
 
538
/* Whether the processor uses hardware interlocks to protect reads
539
   from the GPRs after they are loaded from memory, and thus does not
540
   require nops to be inserted.  This applies to instructions marked
541
   INSN_LOAD_MEMORY_DELAY.  These nops are only required at MIPS ISA
542 160 khays
   level I and microMIPS mode instructions are always interlocked.  */
543
#define gpr_interlocks                                \
544
  (mips_opts.isa != ISA_MIPS1                         \
545
   || mips_opts.arch == CPU_R3900                     \
546
   || mips_opts.micromips                             \
547
   )
548 16 khays
 
549
/* Whether the processor uses hardware interlocks to avoid delays
550
   required by coprocessor instructions, and thus does not require
551
   nops to be inserted.  This applies to instructions marked
552
   INSN_LOAD_COPROC_DELAY, INSN_COPROC_MOVE_DELAY, and to delays
553
   between instructions marked INSN_WRITE_COND_CODE and ones marked
554
   INSN_READ_COND_CODE.  These nops are only required at MIPS ISA
555 160 khays
   levels I, II, and III and microMIPS mode instructions are always
556
   interlocked.  */
557 16 khays
/* Itbl support may require additional care here.  */
558
#define cop_interlocks                                \
559
  ((mips_opts.isa != ISA_MIPS1                        \
560
    && mips_opts.isa != ISA_MIPS2                     \
561
    && mips_opts.isa != ISA_MIPS3)                    \
562
   || mips_opts.arch == CPU_R4300                     \
563 160 khays
   || mips_opts.micromips                             \
564 16 khays
   )
565
 
566
/* Whether the processor uses hardware interlocks to protect reads
567
   from coprocessor registers after they are loaded from memory, and
568
   thus does not require nops to be inserted.  This applies to
569
   instructions marked INSN_COPROC_MEMORY_DELAY.  These nops are only
570 160 khays
   requires at MIPS ISA level I and microMIPS mode instructions are
571
   always interlocked.  */
572
#define cop_mem_interlocks                            \
573
  (mips_opts.isa != ISA_MIPS1                         \
574
   || mips_opts.micromips                             \
575
   )
576 16 khays
 
577
/* Is this a mfhi or mflo instruction?  */
578
#define MF_HILO_INSN(PINFO) \
579
  ((PINFO & INSN_READ_HI) || (PINFO & INSN_READ_LO))
580
 
581
/* Returns true for a (non floating-point) coprocessor instruction.  Reading
582
   or writing the condition code is only possible on the coprocessors and
583
   these insns are not marked with INSN_COP.  Thus for these insns use the
584
   condition-code flags.  */
585
#define COP_INSN(PINFO)                                                 \
586
  (PINFO != INSN_MACRO                                                  \
587
   && ((PINFO) & (FP_S | FP_D)) == 0                                     \
588
   && ((PINFO) & (INSN_COP | INSN_READ_COND_CODE | INSN_WRITE_COND_CODE)))
589
 
590 160 khays
/* Whether code compression (either of the MIPS16 or the microMIPS ASEs)
591
   has been selected.  This implies, in particular, that addresses of text
592
   labels have their LSB set.  */
593
#define HAVE_CODE_COMPRESSION                                           \
594
  ((mips_opts.mips16 | mips_opts.micromips) != 0)
595
 
596 16 khays
/* MIPS PIC level.  */
597
 
598
enum mips_pic_level mips_pic;
599
 
600
/* 1 if we should generate 32 bit offsets from the $gp register in
601
   SVR4_PIC mode.  Currently has no meaning in other modes.  */
602
static int mips_big_got = 0;
603
 
604
/* 1 if trap instructions should used for overflow rather than break
605
   instructions.  */
606
static int mips_trap = 0;
607
 
608
/* 1 if double width floating point constants should not be constructed
609
   by assembling two single width halves into two single width floating
610
   point registers which just happen to alias the double width destination
611
   register.  On some architectures this aliasing can be disabled by a bit
612
   in the status register, and the setting of this bit cannot be determined
613
   automatically at assemble time.  */
614
static int mips_disable_float_construction;
615
 
616
/* Non-zero if any .set noreorder directives were used.  */
617
 
618
static int mips_any_noreorder;
619
 
620
/* Non-zero if nops should be inserted when the register referenced in
621
   an mfhi/mflo instruction is read in the next two instructions.  */
622
static int mips_7000_hilo_fix;
623
 
624
/* The size of objects in the small data section.  */
625
static unsigned int g_switch_value = 8;
626
/* Whether the -G option was used.  */
627
static int g_switch_seen = 0;
628
 
629
#define N_RMASK 0xc4
630
#define N_VFP   0xd4
631
 
632
/* If we can determine in advance that GP optimization won't be
633
   possible, we can skip the relaxation stuff that tries to produce
634
   GP-relative references.  This makes delay slot optimization work
635
   better.
636
 
637
   This function can only provide a guess, but it seems to work for
638
   gcc output.  It needs to guess right for gcc, otherwise gcc
639
   will put what it thinks is a GP-relative instruction in a branch
640
   delay slot.
641
 
642
   I don't know if a fix is needed for the SVR4_PIC mode.  I've only
643
   fixed it for the non-PIC mode.  KR 95/04/07  */
644
static int nopic_need_relax (symbolS *, int);
645
 
646
/* handle of the OPCODE hash table */
647
static struct hash_control *op_hash = NULL;
648
 
649
/* The opcode hash table we use for the mips16.  */
650
static struct hash_control *mips16_op_hash = NULL;
651
 
652 160 khays
/* The opcode hash table we use for the microMIPS ASE.  */
653
static struct hash_control *micromips_op_hash = NULL;
654
 
655 16 khays
/* This array holds the chars that always start a comment.  If the
656
    pre-processor is disabled, these aren't very useful */
657
const char comment_chars[] = "#";
658
 
659
/* This array holds the chars that only start a comment at the beginning of
660
   a line.  If the line seems to have the form '# 123 filename'
661
   .line and .file directives will appear in the pre-processed output */
662
/* Note that input_file.c hand checks for '#' at the beginning of the
663
   first line of the input file.  This is because the compiler outputs
664
   #NO_APP at the beginning of its output.  */
665
/* Also note that C style comments are always supported.  */
666
const char line_comment_chars[] = "#";
667
 
668
/* This array holds machine specific line separator characters.  */
669
const char line_separator_chars[] = ";";
670
 
671
/* Chars that can be used to separate mant from exp in floating point nums */
672
const char EXP_CHARS[] = "eE";
673
 
674
/* Chars that mean this number is a floating point constant */
675
/* As in 0f12.456 */
676
/* or    0d1.2345e12 */
677
const char FLT_CHARS[] = "rRsSfFdDxXpP";
678
 
679
/* Also be aware that MAXIMUM_NUMBER_OF_CHARS_FOR_FLOAT may have to be
680
   changed in read.c .  Ideally it shouldn't have to know about it at all,
681
   but nothing is ideal around here.
682
 */
683
 
684
static char *insn_error;
685
 
686
static int auto_align = 1;
687
 
688
/* When outputting SVR4 PIC code, the assembler needs to know the
689
   offset in the stack frame from which to restore the $gp register.
690
   This is set by the .cprestore pseudo-op, and saved in this
691
   variable.  */
692
static offsetT mips_cprestore_offset = -1;
693
 
694
/* Similar for NewABI PIC code, where $gp is callee-saved.  NewABI has some
695
   more optimizations, it can use a register value instead of a memory-saved
696
   offset and even an other register than $gp as global pointer.  */
697
static offsetT mips_cpreturn_offset = -1;
698
static int mips_cpreturn_register = -1;
699
static int mips_gp_register = GP;
700
static int mips_gprel_offset = 0;
701
 
702
/* Whether mips_cprestore_offset has been set in the current function
703
   (or whether it has already been warned about, if not).  */
704
static int mips_cprestore_valid = 0;
705
 
706
/* This is the register which holds the stack frame, as set by the
707
   .frame pseudo-op.  This is needed to implement .cprestore.  */
708
static int mips_frame_reg = SP;
709
 
710
/* Whether mips_frame_reg has been set in the current function
711
   (or whether it has already been warned about, if not).  */
712
static int mips_frame_reg_valid = 0;
713
 
714
/* To output NOP instructions correctly, we need to keep information
715
   about the previous two instructions.  */
716
 
717
/* Whether we are optimizing.  The default value of 2 means to remove
718
   unneeded NOPs and swap branch instructions when possible.  A value
719
   of 1 means to not swap branches.  A value of 0 means to always
720
   insert NOPs.  */
721
static int mips_optimize = 2;
722
 
723
/* Debugging level.  -g sets this to 2.  -gN sets this to N.  -g0 is
724
   equivalent to seeing no -g option at all.  */
725
static int mips_debug = 0;
726
 
727
/* The maximum number of NOPs needed to avoid the VR4130 mflo/mfhi errata.  */
728
#define MAX_VR4130_NOPS 4
729
 
730
/* The maximum number of NOPs needed to fill delay slots.  */
731
#define MAX_DELAY_NOPS 2
732
 
733
/* The maximum number of NOPs needed for any purpose.  */
734
#define MAX_NOPS 4
735
 
736
/* A list of previous instructions, with index 0 being the most recent.
737
   We need to look back MAX_NOPS instructions when filling delay slots
738
   or working around processor errata.  We need to look back one
739
   instruction further if we're thinking about using history[0] to
740
   fill a branch delay slot.  */
741
static struct mips_cl_insn history[1 + MAX_NOPS];
742
 
743
/* Nop instructions used by emit_nop.  */
744 160 khays
static struct mips_cl_insn nop_insn;
745
static struct mips_cl_insn mips16_nop_insn;
746
static struct mips_cl_insn micromips_nop16_insn;
747
static struct mips_cl_insn micromips_nop32_insn;
748 16 khays
 
749
/* The appropriate nop for the current mode.  */
750 160 khays
#define NOP_INSN (mips_opts.mips16 ? &mips16_nop_insn \
751
                  : (mips_opts.micromips ? &micromips_nop16_insn : &nop_insn))
752 16 khays
 
753 160 khays
/* The size of NOP_INSN in bytes.  */
754
#define NOP_INSN_SIZE (HAVE_CODE_COMPRESSION ? 2 : 4)
755
 
756 16 khays
/* If this is set, it points to a frag holding nop instructions which
757
   were inserted before the start of a noreorder section.  If those
758
   nops turn out to be unnecessary, the size of the frag can be
759
   decreased.  */
760
static fragS *prev_nop_frag;
761
 
762
/* The number of nop instructions we created in prev_nop_frag.  */
763
static int prev_nop_frag_holds;
764
 
765
/* The number of nop instructions that we know we need in
766
   prev_nop_frag.  */
767
static int prev_nop_frag_required;
768
 
769
/* The number of instructions we've seen since prev_nop_frag.  */
770
static int prev_nop_frag_since;
771
 
772
/* For ECOFF and ELF, relocations against symbols are done in two
773
   parts, with a HI relocation and a LO relocation.  Each relocation
774
   has only 16 bits of space to store an addend.  This means that in
775
   order for the linker to handle carries correctly, it must be able
776
   to locate both the HI and the LO relocation.  This means that the
777
   relocations must appear in order in the relocation table.
778
 
779
   In order to implement this, we keep track of each unmatched HI
780
   relocation.  We then sort them so that they immediately precede the
781
   corresponding LO relocation.  */
782
 
783
struct mips_hi_fixup
784
{
785
  /* Next HI fixup.  */
786
  struct mips_hi_fixup *next;
787
  /* This fixup.  */
788
  fixS *fixp;
789
  /* The section this fixup is in.  */
790
  segT seg;
791
};
792
 
793
/* The list of unmatched HI relocs.  */
794
 
795
static struct mips_hi_fixup *mips_hi_fixup_list;
796
 
797
/* The frag containing the last explicit relocation operator.
798
   Null if explicit relocations have not been used.  */
799
 
800
static fragS *prev_reloc_op_frag;
801
 
802
/* Map normal MIPS register numbers to mips16 register numbers.  */
803
 
804
#define X ILLEGAL_REG
805
static const int mips32_to_16_reg_map[] =
806
{
807
  X, X, 2, 3, 4, 5, 6, 7,
808
  X, X, X, X, X, X, X, X,
809
  0, 1, X, X, X, X, X, X,
810
  X, X, X, X, X, X, X, X
811
};
812
#undef X
813
 
814
/* Map mips16 register numbers to normal MIPS register numbers.  */
815
 
816
static const unsigned int mips16_to_32_reg_map[] =
817
{
818
  16, 17, 2, 3, 4, 5, 6, 7
819
};
820
 
821 160 khays
/* Map normal MIPS register numbers to microMIPS register numbers.  */
822
 
823
#define mips32_to_micromips_reg_b_map   mips32_to_16_reg_map
824
#define mips32_to_micromips_reg_c_map   mips32_to_16_reg_map
825
#define mips32_to_micromips_reg_d_map   mips32_to_16_reg_map
826
#define mips32_to_micromips_reg_e_map   mips32_to_16_reg_map
827
#define mips32_to_micromips_reg_f_map   mips32_to_16_reg_map
828
#define mips32_to_micromips_reg_g_map   mips32_to_16_reg_map
829
#define mips32_to_micromips_reg_l_map   mips32_to_16_reg_map
830
 
831
#define X ILLEGAL_REG
832
/* reg type h: 4, 5, 6.  */
833
static const int mips32_to_micromips_reg_h_map[] =
834
{
835
  X, X, X, X, 4, 5, 6, X,
836
  X, X, X, X, X, X, X, X,
837
  X, X, X, X, X, X, X, X,
838
  X, X, X, X, X, X, X, X
839
};
840
 
841
/* reg type m: 0, 17, 2, 3, 16, 18, 19, 20.  */
842
static const int mips32_to_micromips_reg_m_map[] =
843
{
844
  0, X, 2, 3, X, X, X, X,
845
  X, X, X, X, X, X, X, X,
846
  4, 1, 5, 6, 7, X, X, X,
847
  X, X, X, X, X, X, X, X
848
};
849
 
850
/* reg type q: 0, 2-7. 17.  */
851
static const int mips32_to_micromips_reg_q_map[] =
852
{
853
  0, X, 2, 3, 4, 5, 6, 7,
854
  X, X, X, X, X, X, X, X,
855
  X, 1, X, X, X, X, X, X,
856
  X, X, X, X, X, X, X, X
857
};
858
 
859
#define mips32_to_micromips_reg_n_map  mips32_to_micromips_reg_m_map
860
#undef X
861
 
862
/* Map microMIPS register numbers to normal MIPS register numbers.  */
863
 
864
#define micromips_to_32_reg_b_map       mips16_to_32_reg_map
865
#define micromips_to_32_reg_c_map       mips16_to_32_reg_map
866
#define micromips_to_32_reg_d_map       mips16_to_32_reg_map
867
#define micromips_to_32_reg_e_map       mips16_to_32_reg_map
868
#define micromips_to_32_reg_f_map       mips16_to_32_reg_map
869
#define micromips_to_32_reg_g_map       mips16_to_32_reg_map
870
 
871
/* The microMIPS registers with type h.  */
872
static const unsigned int micromips_to_32_reg_h_map[] =
873
{
874
  5, 5, 6, 4, 4, 4, 4, 4
875
};
876
 
877
/* The microMIPS registers with type i.  */
878
static const unsigned int micromips_to_32_reg_i_map[] =
879
{
880
  6, 7, 7, 21, 22, 5, 6, 7
881
};
882
 
883
#define micromips_to_32_reg_l_map       mips16_to_32_reg_map
884
 
885
/* The microMIPS registers with type m.  */
886
static const unsigned int micromips_to_32_reg_m_map[] =
887
{
888
  0, 17, 2, 3, 16, 18, 19, 20
889
};
890
 
891
#define micromips_to_32_reg_n_map      micromips_to_32_reg_m_map
892
 
893
/* The microMIPS registers with type q.  */
894
static const unsigned int micromips_to_32_reg_q_map[] =
895
{
896
  0, 17, 2, 3, 4, 5, 6, 7
897
};
898
 
899
/* microMIPS imm type B.  */
900
static const int micromips_imm_b_map[] =
901
{
902
  1, 4, 8, 12, 16, 20, 24, -1
903
};
904
 
905
/* microMIPS imm type C.  */
906
static const int micromips_imm_c_map[] =
907
{
908
  128, 1, 2, 3, 4, 7, 8, 15, 16, 31, 32, 63, 64, 255, 32768, 65535
909
};
910
 
911 16 khays
/* Classifies the kind of instructions we're interested in when
912
   implementing -mfix-vr4120.  */
913
enum fix_vr4120_class
914
{
915
  FIX_VR4120_MACC,
916
  FIX_VR4120_DMACC,
917
  FIX_VR4120_MULT,
918
  FIX_VR4120_DMULT,
919
  FIX_VR4120_DIV,
920
  FIX_VR4120_MTHILO,
921
  NUM_FIX_VR4120_CLASSES
922
};
923
 
924
/* ...likewise -mfix-loongson2f-jump.  */
925
static bfd_boolean mips_fix_loongson2f_jump;
926
 
927
/* ...likewise -mfix-loongson2f-nop.  */
928
static bfd_boolean mips_fix_loongson2f_nop;
929
 
930
/* True if -mfix-loongson2f-nop or -mfix-loongson2f-jump passed.  */
931
static bfd_boolean mips_fix_loongson2f;
932
 
933
/* Given two FIX_VR4120_* values X and Y, bit Y of element X is set if
934
   there must be at least one other instruction between an instruction
935
   of type X and an instruction of type Y.  */
936
static unsigned int vr4120_conflicts[NUM_FIX_VR4120_CLASSES];
937
 
938
/* True if -mfix-vr4120 is in force.  */
939
static int mips_fix_vr4120;
940
 
941
/* ...likewise -mfix-vr4130.  */
942
static int mips_fix_vr4130;
943
 
944
/* ...likewise -mfix-24k.  */
945
static int mips_fix_24k;
946
 
947
/* ...likewise -mfix-cn63xxp1 */
948
static bfd_boolean mips_fix_cn63xxp1;
949
 
950
/* We don't relax branches by default, since this causes us to expand
951
   `la .l2 - .l1' if there's a branch between .l1 and .l2, because we
952
   fail to compute the offset before expanding the macro to the most
953
   efficient expansion.  */
954
 
955
static int mips_relax_branch;
956
 
957
/* The expansion of many macros depends on the type of symbol that
958
   they refer to.  For example, when generating position-dependent code,
959
   a macro that refers to a symbol may have two different expansions,
960
   one which uses GP-relative addresses and one which uses absolute
961
   addresses.  When generating SVR4-style PIC, a macro may have
962
   different expansions for local and global symbols.
963
 
964
   We handle these situations by generating both sequences and putting
965
   them in variant frags.  In position-dependent code, the first sequence
966
   will be the GP-relative one and the second sequence will be the
967
   absolute one.  In SVR4 PIC, the first sequence will be for global
968
   symbols and the second will be for local symbols.
969
 
970
   The frag's "subtype" is RELAX_ENCODE (FIRST, SECOND), where FIRST and
971
   SECOND are the lengths of the two sequences in bytes.  These fields
972
   can be extracted using RELAX_FIRST() and RELAX_SECOND().  In addition,
973
   the subtype has the following flags:
974
 
975
   RELAX_USE_SECOND
976
        Set if it has been decided that we should use the second
977
        sequence instead of the first.
978
 
979
   RELAX_SECOND_LONGER
980
        Set in the first variant frag if the macro's second implementation
981
        is longer than its first.  This refers to the macro as a whole,
982
        not an individual relaxation.
983
 
984
   RELAX_NOMACRO
985
        Set in the first variant frag if the macro appeared in a .set nomacro
986
        block and if one alternative requires a warning but the other does not.
987
 
988
   RELAX_DELAY_SLOT
989
        Like RELAX_NOMACRO, but indicates that the macro appears in a branch
990
        delay slot.
991
 
992 160 khays
   RELAX_DELAY_SLOT_16BIT
993
        Like RELAX_DELAY_SLOT, but indicates that the delay slot requires a
994
        16-bit instruction.
995
 
996
   RELAX_DELAY_SLOT_SIZE_FIRST
997
        Like RELAX_DELAY_SLOT, but indicates that the first implementation of
998
        the macro is of the wrong size for the branch delay slot.
999
 
1000
   RELAX_DELAY_SLOT_SIZE_SECOND
1001
        Like RELAX_DELAY_SLOT, but indicates that the second implementation of
1002
        the macro is of the wrong size for the branch delay slot.
1003
 
1004 16 khays
   The frag's "opcode" points to the first fixup for relaxable code.
1005
 
1006
   Relaxable macros are generated using a sequence such as:
1007
 
1008
      relax_start (SYMBOL);
1009
      ... generate first expansion ...
1010
      relax_switch ();
1011
      ... generate second expansion ...
1012
      relax_end ();
1013
 
1014
   The code and fixups for the unwanted alternative are discarded
1015
   by md_convert_frag.  */
1016
#define RELAX_ENCODE(FIRST, SECOND) (((FIRST) << 8) | (SECOND))
1017
 
1018
#define RELAX_FIRST(X) (((X) >> 8) & 0xff)
1019
#define RELAX_SECOND(X) ((X) & 0xff)
1020
#define RELAX_USE_SECOND 0x10000
1021
#define RELAX_SECOND_LONGER 0x20000
1022
#define RELAX_NOMACRO 0x40000
1023
#define RELAX_DELAY_SLOT 0x80000
1024 160 khays
#define RELAX_DELAY_SLOT_16BIT 0x100000
1025
#define RELAX_DELAY_SLOT_SIZE_FIRST 0x200000
1026
#define RELAX_DELAY_SLOT_SIZE_SECOND 0x400000
1027 16 khays
 
1028
/* Branch without likely bit.  If label is out of range, we turn:
1029
 
1030
        beq reg1, reg2, label
1031
        delay slot
1032
 
1033
   into
1034
 
1035
        bne reg1, reg2, 0f
1036
        nop
1037
        j label
1038
     0: delay slot
1039
 
1040
   with the following opcode replacements:
1041
 
1042
        beq <-> bne
1043
        blez <-> bgtz
1044
        bltz <-> bgez
1045
        bc1f <-> bc1t
1046
 
1047
        bltzal <-> bgezal  (with jal label instead of j label)
1048
 
1049
   Even though keeping the delay slot instruction in the delay slot of
1050
   the branch would be more efficient, it would be very tricky to do
1051
   correctly, because we'd have to introduce a variable frag *after*
1052
   the delay slot instruction, and expand that instead.  Let's do it
1053
   the easy way for now, even if the branch-not-taken case now costs
1054
   one additional instruction.  Out-of-range branches are not supposed
1055
   to be common, anyway.
1056
 
1057
   Branch likely.  If label is out of range, we turn:
1058
 
1059
        beql reg1, reg2, label
1060
        delay slot (annulled if branch not taken)
1061
 
1062
   into
1063
 
1064
        beql reg1, reg2, 1f
1065
        nop
1066
        beql $0, $0, 2f
1067
        nop
1068
     1: j[al] label
1069
        delay slot (executed only if branch taken)
1070
     2:
1071
 
1072
   It would be possible to generate a shorter sequence by losing the
1073
   likely bit, generating something like:
1074
 
1075
        bne reg1, reg2, 0f
1076
        nop
1077
        j[al] label
1078
        delay slot (executed only if branch taken)
1079
     0:
1080
 
1081
        beql -> bne
1082
        bnel -> beq
1083
        blezl -> bgtz
1084
        bgtzl -> blez
1085
        bltzl -> bgez
1086
        bgezl -> bltz
1087
        bc1fl -> bc1t
1088
        bc1tl -> bc1f
1089
 
1090
        bltzall -> bgezal  (with jal label instead of j label)
1091
        bgezall -> bltzal  (ditto)
1092
 
1093
 
1094
   but it's not clear that it would actually improve performance.  */
1095
#define RELAX_BRANCH_ENCODE(at, uncond, likely, link, toofar)   \
1096
  ((relax_substateT)                                            \
1097
   (0xc0000000                                                  \
1098
    | ((at) & 0x1f)                                             \
1099
    | ((toofar) ? 0x20 : 0)                                      \
1100
    | ((link) ? 0x40 : 0)                                        \
1101
    | ((likely) ? 0x80 : 0)                                      \
1102
    | ((uncond) ? 0x100 : 0)))
1103
#define RELAX_BRANCH_P(i) (((i) & 0xf0000000) == 0xc0000000)
1104
#define RELAX_BRANCH_UNCOND(i) (((i) & 0x100) != 0)
1105
#define RELAX_BRANCH_LIKELY(i) (((i) & 0x80) != 0)
1106
#define RELAX_BRANCH_LINK(i) (((i) & 0x40) != 0)
1107
#define RELAX_BRANCH_TOOFAR(i) (((i) & 0x20) != 0)
1108
#define RELAX_BRANCH_AT(i) ((i) & 0x1f)
1109
 
1110
/* For mips16 code, we use an entirely different form of relaxation.
1111
   mips16 supports two versions of most instructions which take
1112
   immediate values: a small one which takes some small value, and a
1113
   larger one which takes a 16 bit value.  Since branches also follow
1114
   this pattern, relaxing these values is required.
1115
 
1116
   We can assemble both mips16 and normal MIPS code in a single
1117
   object.  Therefore, we need to support this type of relaxation at
1118
   the same time that we support the relaxation described above.  We
1119
   use the high bit of the subtype field to distinguish these cases.
1120
 
1121
   The information we store for this type of relaxation is the
1122
   argument code found in the opcode file for this relocation, whether
1123
   the user explicitly requested a small or extended form, and whether
1124
   the relocation is in a jump or jal delay slot.  That tells us the
1125
   size of the value, and how it should be stored.  We also store
1126
   whether the fragment is considered to be extended or not.  We also
1127
   store whether this is known to be a branch to a different section,
1128
   whether we have tried to relax this frag yet, and whether we have
1129
   ever extended a PC relative fragment because of a shift count.  */
1130
#define RELAX_MIPS16_ENCODE(type, small, ext, dslot, jal_dslot) \
1131
  (0x80000000                                                   \
1132
   | ((type) & 0xff)                                            \
1133
   | ((small) ? 0x100 : 0)                                       \
1134
   | ((ext) ? 0x200 : 0)                                 \
1135
   | ((dslot) ? 0x400 : 0)                                       \
1136
   | ((jal_dslot) ? 0x800 : 0))
1137
#define RELAX_MIPS16_P(i) (((i) & 0xc0000000) == 0x80000000)
1138
#define RELAX_MIPS16_TYPE(i) ((i) & 0xff)
1139
#define RELAX_MIPS16_USER_SMALL(i) (((i) & 0x100) != 0)
1140
#define RELAX_MIPS16_USER_EXT(i) (((i) & 0x200) != 0)
1141
#define RELAX_MIPS16_DSLOT(i) (((i) & 0x400) != 0)
1142
#define RELAX_MIPS16_JAL_DSLOT(i) (((i) & 0x800) != 0)
1143
#define RELAX_MIPS16_EXTENDED(i) (((i) & 0x1000) != 0)
1144
#define RELAX_MIPS16_MARK_EXTENDED(i) ((i) | 0x1000)
1145
#define RELAX_MIPS16_CLEAR_EXTENDED(i) ((i) &~ 0x1000)
1146
#define RELAX_MIPS16_LONG_BRANCH(i) (((i) & 0x2000) != 0)
1147
#define RELAX_MIPS16_MARK_LONG_BRANCH(i) ((i) | 0x2000)
1148
#define RELAX_MIPS16_CLEAR_LONG_BRANCH(i) ((i) &~ 0x2000)
1149
 
1150 160 khays
/* For microMIPS code, we use relaxation similar to one we use for
1151
   MIPS16 code.  Some instructions that take immediate values support
1152
   two encodings: a small one which takes some small value, and a
1153
   larger one which takes a 16 bit value.  As some branches also follow
1154
   this pattern, relaxing these values is required.
1155
 
1156
   We can assemble both microMIPS and normal MIPS code in a single
1157
   object.  Therefore, we need to support this type of relaxation at
1158
   the same time that we support the relaxation described above.  We
1159
   use one of the high bits of the subtype field to distinguish these
1160
   cases.
1161
 
1162
   The information we store for this type of relaxation is the argument
1163
   code found in the opcode file for this relocation, the register
1164
   selected as the assembler temporary, whether the branch is
1165
   unconditional, whether it is compact, whether it stores the link
1166
   address implicitly in $ra, whether relaxation of out-of-range 32-bit
1167
   branches to a sequence of instructions is enabled, and whether the
1168
   displacement of a branch is too large to fit as an immediate argument
1169
   of a 16-bit and a 32-bit branch, respectively.  */
1170
#define RELAX_MICROMIPS_ENCODE(type, at, uncond, compact, link, \
1171
                               relax32, toofar16, toofar32)     \
1172
  (0x40000000                                                   \
1173
   | ((type) & 0xff)                                            \
1174
   | (((at) & 0x1f) << 8)                                       \
1175
   | ((uncond) ? 0x2000 : 0)                                     \
1176
   | ((compact) ? 0x4000 : 0)                                    \
1177
   | ((link) ? 0x8000 : 0)                                       \
1178
   | ((relax32) ? 0x10000 : 0)                                   \
1179
   | ((toofar16) ? 0x20000 : 0)                                  \
1180
   | ((toofar32) ? 0x40000 : 0))
1181
#define RELAX_MICROMIPS_P(i) (((i) & 0xc0000000) == 0x40000000)
1182
#define RELAX_MICROMIPS_TYPE(i) ((i) & 0xff)
1183
#define RELAX_MICROMIPS_AT(i) (((i) >> 8) & 0x1f)
1184
#define RELAX_MICROMIPS_UNCOND(i) (((i) & 0x2000) != 0)
1185
#define RELAX_MICROMIPS_COMPACT(i) (((i) & 0x4000) != 0)
1186
#define RELAX_MICROMIPS_LINK(i) (((i) & 0x8000) != 0)
1187
#define RELAX_MICROMIPS_RELAX32(i) (((i) & 0x10000) != 0)
1188
 
1189
#define RELAX_MICROMIPS_TOOFAR16(i) (((i) & 0x20000) != 0)
1190
#define RELAX_MICROMIPS_MARK_TOOFAR16(i) ((i) | 0x20000)
1191
#define RELAX_MICROMIPS_CLEAR_TOOFAR16(i) ((i) & ~0x20000)
1192
#define RELAX_MICROMIPS_TOOFAR32(i) (((i) & 0x40000) != 0)
1193
#define RELAX_MICROMIPS_MARK_TOOFAR32(i) ((i) | 0x40000)
1194
#define RELAX_MICROMIPS_CLEAR_TOOFAR32(i) ((i) & ~0x40000)
1195
 
1196 16 khays
/* Is the given value a sign-extended 32-bit value?  */
1197
#define IS_SEXT_32BIT_NUM(x)                                            \
1198
  (((x) &~ (offsetT) 0x7fffffff) == 0                                    \
1199
   || (((x) &~ (offsetT) 0x7fffffff) == ~ (offsetT) 0x7fffffff))
1200
 
1201
/* Is the given value a sign-extended 16-bit value?  */
1202
#define IS_SEXT_16BIT_NUM(x)                                            \
1203
  (((x) &~ (offsetT) 0x7fff) == 0                                        \
1204
   || (((x) &~ (offsetT) 0x7fff) == ~ (offsetT) 0x7fff))
1205
 
1206 160 khays
/* Is the given value a sign-extended 12-bit value?  */
1207
#define IS_SEXT_12BIT_NUM(x)                                            \
1208
  (((((x) & 0xfff) ^ 0x800LL) - 0x800LL) == (x))
1209
 
1210 16 khays
/* Is the given value a zero-extended 32-bit value?  Or a negated one?  */
1211
#define IS_ZEXT_32BIT_NUM(x)                                            \
1212
  (((x) &~ (offsetT) 0xffffffff) == 0                                    \
1213
   || (((x) &~ (offsetT) 0xffffffff) == ~ (offsetT) 0xffffffff))
1214
 
1215
/* Replace bits MASK << SHIFT of STRUCT with the equivalent bits in
1216
   VALUE << SHIFT.  VALUE is evaluated exactly once.  */
1217
#define INSERT_BITS(STRUCT, VALUE, MASK, SHIFT) \
1218
  (STRUCT) = (((STRUCT) & ~((MASK) << (SHIFT))) \
1219
              | (((VALUE) & (MASK)) << (SHIFT)))
1220
 
1221
/* Extract bits MASK << SHIFT from STRUCT and shift them right
1222
   SHIFT places.  */
1223
#define EXTRACT_BITS(STRUCT, MASK, SHIFT) \
1224
  (((STRUCT) >> (SHIFT)) & (MASK))
1225
 
1226
/* Change INSN's opcode so that the operand given by FIELD has value VALUE.
1227
   INSN is a mips_cl_insn structure and VALUE is evaluated exactly once.
1228
 
1229
   include/opcode/mips.h specifies operand fields using the macros
1230
   OP_MASK_<FIELD> and OP_SH_<FIELD>.  The MIPS16 equivalents start
1231
   with "MIPS16OP" instead of "OP".  */
1232 160 khays
#define INSERT_OPERAND(MICROMIPS, FIELD, INSN, VALUE) \
1233
  do \
1234
    if (!(MICROMIPS)) \
1235
      INSERT_BITS ((INSN).insn_opcode, VALUE, \
1236
                   OP_MASK_##FIELD, OP_SH_##FIELD); \
1237
    else \
1238
      INSERT_BITS ((INSN).insn_opcode, VALUE, \
1239
                   MICROMIPSOP_MASK_##FIELD, MICROMIPSOP_SH_##FIELD); \
1240
  while (0)
1241 16 khays
#define MIPS16_INSERT_OPERAND(FIELD, INSN, VALUE) \
1242
  INSERT_BITS ((INSN).insn_opcode, VALUE, \
1243
                MIPS16OP_MASK_##FIELD, MIPS16OP_SH_##FIELD)
1244
 
1245
/* Extract the operand given by FIELD from mips_cl_insn INSN.  */
1246 160 khays
#define EXTRACT_OPERAND(MICROMIPS, FIELD, INSN) \
1247
  (!(MICROMIPS) \
1248
   ? EXTRACT_BITS ((INSN).insn_opcode, OP_MASK_##FIELD, OP_SH_##FIELD) \
1249
   : EXTRACT_BITS ((INSN).insn_opcode, \
1250
                   MICROMIPSOP_MASK_##FIELD, MICROMIPSOP_SH_##FIELD))
1251 16 khays
#define MIPS16_EXTRACT_OPERAND(FIELD, INSN) \
1252
  EXTRACT_BITS ((INSN).insn_opcode, \
1253
                MIPS16OP_MASK_##FIELD, \
1254
                MIPS16OP_SH_##FIELD)
1255
 
1256 160 khays
/* Whether or not we are emitting a branch-likely macro.  */
1257
static bfd_boolean emit_branch_likely_macro = FALSE;
1258
 
1259 16 khays
/* Global variables used when generating relaxable macros.  See the
1260
   comment above RELAX_ENCODE for more details about how relaxation
1261
   is used.  */
1262
static struct {
1263
  /* 0 if we're not emitting a relaxable macro.
1264
     1 if we're emitting the first of the two relaxation alternatives.
1265
     2 if we're emitting the second alternative.  */
1266
  int sequence;
1267
 
1268
  /* The first relaxable fixup in the current frag.  (In other words,
1269
     the first fixup that refers to relaxable code.)  */
1270
  fixS *first_fixup;
1271
 
1272
  /* sizes[0] says how many bytes of the first alternative are stored in
1273
     the current frag.  Likewise sizes[1] for the second alternative.  */
1274
  unsigned int sizes[2];
1275
 
1276
  /* The symbol on which the choice of sequence depends.  */
1277
  symbolS *symbol;
1278
} mips_relax;
1279
 
1280
/* Global variables used to decide whether a macro needs a warning.  */
1281
static struct {
1282
  /* True if the macro is in a branch delay slot.  */
1283
  bfd_boolean delay_slot_p;
1284
 
1285 160 khays
  /* Set to the length in bytes required if the macro is in a delay slot
1286
     that requires a specific length of instruction, otherwise zero.  */
1287
  unsigned int delay_slot_length;
1288
 
1289 16 khays
  /* For relaxable macros, sizes[0] is the length of the first alternative
1290
     in bytes and sizes[1] is the length of the second alternative.
1291
     For non-relaxable macros, both elements give the length of the
1292
     macro in bytes.  */
1293
  unsigned int sizes[2];
1294
 
1295 160 khays
  /* For relaxable macros, first_insn_sizes[0] is the length of the first
1296
     instruction of the first alternative in bytes and first_insn_sizes[1]
1297
     is the length of the first instruction of the second alternative.
1298
     For non-relaxable macros, both elements give the length of the first
1299
     instruction in bytes.
1300
 
1301
     Set to zero if we haven't yet seen the first instruction.  */
1302
  unsigned int first_insn_sizes[2];
1303
 
1304
  /* For relaxable macros, insns[0] is the number of instructions for the
1305
     first alternative and insns[1] is the number of instructions for the
1306
     second alternative.
1307
 
1308
     For non-relaxable macros, both elements give the number of
1309
     instructions for the macro.  */
1310
  unsigned int insns[2];
1311
 
1312 16 khays
  /* The first variant frag for this macro.  */
1313
  fragS *first_frag;
1314
} mips_macro_warning;
1315
 
1316
/* Prototypes for static functions.  */
1317
 
1318
#define internalError()                                                 \
1319
    as_fatal (_("internal Error, line %d, %s"), __LINE__, __FILE__)
1320
 
1321
enum mips_regclass { MIPS_GR_REG, MIPS_FP_REG, MIPS16_REG };
1322
 
1323
static void append_insn
1324 160 khays
  (struct mips_cl_insn *, expressionS *, bfd_reloc_code_real_type *,
1325
   bfd_boolean expansionp);
1326 16 khays
static void mips_no_prev_insn (void);
1327
static void macro_build (expressionS *, const char *, const char *, ...);
1328
static void mips16_macro_build
1329
  (expressionS *, const char *, const char *, va_list *);
1330
static void load_register (int, expressionS *, int);
1331
static void macro_start (void);
1332
static void macro_end (void);
1333
static void macro (struct mips_cl_insn * ip);
1334
static void mips16_macro (struct mips_cl_insn * ip);
1335
static void mips_ip (char *str, struct mips_cl_insn * ip);
1336
static void mips16_ip (char *str, struct mips_cl_insn * ip);
1337
static void mips16_immed
1338
  (char *, unsigned int, int, offsetT, bfd_boolean, bfd_boolean, bfd_boolean,
1339
   unsigned long *, bfd_boolean *, unsigned short *);
1340
static size_t my_getSmallExpression
1341
  (expressionS *, bfd_reloc_code_real_type *, char *);
1342
static void my_getExpression (expressionS *, char *);
1343
static void s_align (int);
1344
static void s_change_sec (int);
1345
static void s_change_section (int);
1346
static void s_cons (int);
1347
static void s_float_cons (int);
1348
static void s_mips_globl (int);
1349
static void s_option (int);
1350
static void s_mipsset (int);
1351
static void s_abicalls (int);
1352
static void s_cpload (int);
1353
static void s_cpsetup (int);
1354
static void s_cplocal (int);
1355
static void s_cprestore (int);
1356
static void s_cpreturn (int);
1357
static void s_dtprelword (int);
1358
static void s_dtpreldword (int);
1359 166 khays
static void s_tprelword (int);
1360
static void s_tpreldword (int);
1361 16 khays
static void s_gpvalue (int);
1362
static void s_gpword (int);
1363
static void s_gpdword (int);
1364
static void s_cpadd (int);
1365
static void s_insn (int);
1366
static void md_obj_begin (void);
1367
static void md_obj_end (void);
1368
static void s_mips_ent (int);
1369
static void s_mips_end (int);
1370
static void s_mips_frame (int);
1371
static void s_mips_mask (int reg_type);
1372
static void s_mips_stab (int);
1373
static void s_mips_weakext (int);
1374
static void s_mips_file (int);
1375
static void s_mips_loc (int);
1376
static bfd_boolean pic_need_relax (symbolS *, asection *);
1377
static int relaxed_branch_length (fragS *, asection *, int);
1378
static int validate_mips_insn (const struct mips_opcode *);
1379 160 khays
static int validate_micromips_insn (const struct mips_opcode *);
1380
static int relaxed_micromips_16bit_branch_length (fragS *, asection *, int);
1381
static int relaxed_micromips_32bit_branch_length (fragS *, asection *, int);
1382 16 khays
 
1383
/* Table and functions used to map between CPU/ISA names, and
1384
   ISA levels, and CPU numbers.  */
1385
 
1386
struct mips_cpu_info
1387
{
1388
  const char *name;           /* CPU or ISA name.  */
1389
  int flags;                  /* ASEs available, or ISA flag.  */
1390
  int isa;                    /* ISA level.  */
1391
  int cpu;                    /* CPU number (default CPU if ISA).  */
1392
};
1393
 
1394
#define MIPS_CPU_IS_ISA         0x0001  /* Is this an ISA?  (If 0, a CPU.) */
1395
#define MIPS_CPU_ASE_SMARTMIPS  0x0002  /* CPU implements SmartMIPS ASE */
1396
#define MIPS_CPU_ASE_DSP        0x0004  /* CPU implements DSP ASE */
1397
#define MIPS_CPU_ASE_MT         0x0008  /* CPU implements MT ASE */
1398
#define MIPS_CPU_ASE_MIPS3D     0x0010  /* CPU implements MIPS-3D ASE */
1399
#define MIPS_CPU_ASE_MDMX       0x0020  /* CPU implements MDMX ASE */
1400
#define MIPS_CPU_ASE_DSPR2      0x0040  /* CPU implements DSP R2 ASE */
1401 160 khays
#define MIPS_CPU_ASE_MCU        0x0080  /* CPU implements MCU ASE */
1402 16 khays
 
1403
static const struct mips_cpu_info *mips_parse_cpu (const char *, const char *);
1404
static const struct mips_cpu_info *mips_cpu_info_from_isa (int);
1405
static const struct mips_cpu_info *mips_cpu_info_from_arch (int);
1406
 
1407
/* Pseudo-op table.
1408
 
1409
   The following pseudo-ops from the Kane and Heinrich MIPS book
1410
   should be defined here, but are currently unsupported: .alias,
1411
   .galive, .gjaldef, .gjrlive, .livereg, .noalias.
1412
 
1413
   The following pseudo-ops from the Kane and Heinrich MIPS book are
1414
   specific to the type of debugging information being generated, and
1415
   should be defined by the object format: .aent, .begin, .bend,
1416
   .bgnb, .end, .endb, .ent, .fmask, .frame, .loc, .mask, .verstamp,
1417
   .vreg.
1418
 
1419
   The following pseudo-ops from the Kane and Heinrich MIPS book are
1420
   not MIPS CPU specific, but are also not specific to the object file
1421
   format.  This file is probably the best place to define them, but
1422
   they are not currently supported: .asm0, .endr, .lab, .struct.  */
1423
 
1424
static const pseudo_typeS mips_pseudo_table[] =
1425
{
1426
  /* MIPS specific pseudo-ops.  */
1427
  {"option", s_option, 0},
1428
  {"set", s_mipsset, 0},
1429
  {"rdata", s_change_sec, 'r'},
1430
  {"sdata", s_change_sec, 's'},
1431
  {"livereg", s_ignore, 0},
1432
  {"abicalls", s_abicalls, 0},
1433
  {"cpload", s_cpload, 0},
1434
  {"cpsetup", s_cpsetup, 0},
1435
  {"cplocal", s_cplocal, 0},
1436
  {"cprestore", s_cprestore, 0},
1437
  {"cpreturn", s_cpreturn, 0},
1438
  {"dtprelword", s_dtprelword, 0},
1439
  {"dtpreldword", s_dtpreldword, 0},
1440 166 khays
  {"tprelword", s_tprelword, 0},
1441
  {"tpreldword", s_tpreldword, 0},
1442 16 khays
  {"gpvalue", s_gpvalue, 0},
1443
  {"gpword", s_gpword, 0},
1444
  {"gpdword", s_gpdword, 0},
1445
  {"cpadd", s_cpadd, 0},
1446
  {"insn", s_insn, 0},
1447
 
1448
  /* Relatively generic pseudo-ops that happen to be used on MIPS
1449
     chips.  */
1450
  {"asciiz", stringer, 8 + 1},
1451
  {"bss", s_change_sec, 'b'},
1452
  {"err", s_err, 0},
1453
  {"half", s_cons, 1},
1454
  {"dword", s_cons, 3},
1455
  {"weakext", s_mips_weakext, 0},
1456
  {"origin", s_org, 0},
1457
  {"repeat", s_rept, 0},
1458
 
1459
  /* For MIPS this is non-standard, but we define it for consistency.  */
1460
  {"sbss", s_change_sec, 'B'},
1461
 
1462
  /* These pseudo-ops are defined in read.c, but must be overridden
1463
     here for one reason or another.  */
1464
  {"align", s_align, 0},
1465
  {"byte", s_cons, 0},
1466
  {"data", s_change_sec, 'd'},
1467
  {"double", s_float_cons, 'd'},
1468
  {"float", s_float_cons, 'f'},
1469
  {"globl", s_mips_globl, 0},
1470
  {"global", s_mips_globl, 0},
1471
  {"hword", s_cons, 1},
1472
  {"int", s_cons, 2},
1473
  {"long", s_cons, 2},
1474
  {"octa", s_cons, 4},
1475
  {"quad", s_cons, 3},
1476
  {"section", s_change_section, 0},
1477
  {"short", s_cons, 1},
1478
  {"single", s_float_cons, 'f'},
1479
  {"stabn", s_mips_stab, 'n'},
1480
  {"text", s_change_sec, 't'},
1481
  {"word", s_cons, 2},
1482
 
1483
  { "extern", ecoff_directive_extern, 0},
1484
 
1485
  { NULL, NULL, 0 },
1486
};
1487
 
1488
static const pseudo_typeS mips_nonecoff_pseudo_table[] =
1489
{
1490
  /* These pseudo-ops should be defined by the object file format.
1491
     However, a.out doesn't support them, so we have versions here.  */
1492
  {"aent", s_mips_ent, 1},
1493
  {"bgnb", s_ignore, 0},
1494
  {"end", s_mips_end, 0},
1495
  {"endb", s_ignore, 0},
1496
  {"ent", s_mips_ent, 0},
1497
  {"file", s_mips_file, 0},
1498
  {"fmask", s_mips_mask, 'F'},
1499
  {"frame", s_mips_frame, 0},
1500
  {"loc", s_mips_loc, 0},
1501
  {"mask", s_mips_mask, 'R'},
1502
  {"verstamp", s_ignore, 0},
1503
  { NULL, NULL, 0 },
1504
};
1505
 
1506
/* Export the ABI address size for use by TC_ADDRESS_BYTES for the
1507
   purpose of the `.dc.a' internal pseudo-op.  */
1508
 
1509
int
1510
mips_address_bytes (void)
1511
{
1512
  return HAVE_64BIT_ADDRESSES ? 8 : 4;
1513
}
1514
 
1515
extern void pop_insert (const pseudo_typeS *);
1516
 
1517
void
1518
mips_pop_insert (void)
1519
{
1520
  pop_insert (mips_pseudo_table);
1521
  if (! ECOFF_DEBUGGING)
1522
    pop_insert (mips_nonecoff_pseudo_table);
1523
}
1524
 
1525
/* Symbols labelling the current insn.  */
1526
 
1527
struct insn_label_list
1528
{
1529
  struct insn_label_list *next;
1530
  symbolS *label;
1531
};
1532
 
1533
static struct insn_label_list *free_insn_labels;
1534
#define label_list tc_segment_info_data.labels
1535
 
1536
static void mips_clear_insn_labels (void);
1537 160 khays
static void mips_mark_labels (void);
1538
static void mips_compressed_mark_labels (void);
1539 16 khays
 
1540
static inline void
1541
mips_clear_insn_labels (void)
1542
{
1543
  register struct insn_label_list **pl;
1544
  segment_info_type *si;
1545
 
1546
  if (now_seg)
1547
    {
1548
      for (pl = &free_insn_labels; *pl != NULL; pl = &(*pl)->next)
1549
        ;
1550
 
1551
      si = seg_info (now_seg);
1552
      *pl = si->label_list;
1553
      si->label_list = NULL;
1554
    }
1555
}
1556
 
1557 160 khays
/* Mark instruction labels in MIPS16/microMIPS mode.  */
1558
 
1559
static inline void
1560
mips_mark_labels (void)
1561
{
1562
  if (HAVE_CODE_COMPRESSION)
1563
    mips_compressed_mark_labels ();
1564
}
1565 16 khays
 
1566
static char *expr_end;
1567
 
1568
/* Expressions which appear in instructions.  These are set by
1569
   mips_ip.  */
1570
 
1571
static expressionS imm_expr;
1572
static expressionS imm2_expr;
1573
static expressionS offset_expr;
1574
 
1575
/* Relocs associated with imm_expr and offset_expr.  */
1576
 
1577
static bfd_reloc_code_real_type imm_reloc[3]
1578
  = {BFD_RELOC_UNUSED, BFD_RELOC_UNUSED, BFD_RELOC_UNUSED};
1579
static bfd_reloc_code_real_type offset_reloc[3]
1580
  = {BFD_RELOC_UNUSED, BFD_RELOC_UNUSED, BFD_RELOC_UNUSED};
1581
 
1582 160 khays
/* This is set to the resulting size of the instruction to be produced
1583
   by mips16_ip if an explicit extension is used or by mips_ip if an
1584
   explicit size is supplied.  */
1585 16 khays
 
1586 160 khays
static unsigned int forced_insn_length;
1587 16 khays
 
1588
#ifdef OBJ_ELF
1589
/* The pdr segment for per procedure frame/regmask info.  Not used for
1590
   ECOFF debugging.  */
1591
 
1592
static segT pdr_seg;
1593
#endif
1594
 
1595
/* The default target format to use.  */
1596
 
1597
#if defined (TE_FreeBSD)
1598
#define ELF_TARGET(PREFIX, ENDIAN) PREFIX "trad" ENDIAN "mips-freebsd"
1599
#elif defined (TE_TMIPS)
1600
#define ELF_TARGET(PREFIX, ENDIAN) PREFIX "trad" ENDIAN "mips"
1601
#else
1602
#define ELF_TARGET(PREFIX, ENDIAN) PREFIX ENDIAN "mips"
1603
#endif
1604
 
1605
const char *
1606
mips_target_format (void)
1607
{
1608
  switch (OUTPUT_FLAVOR)
1609
    {
1610
    case bfd_target_ecoff_flavour:
1611
      return target_big_endian ? "ecoff-bigmips" : ECOFF_LITTLE_FORMAT;
1612
    case bfd_target_coff_flavour:
1613
      return "pe-mips";
1614
    case bfd_target_elf_flavour:
1615
#ifdef TE_VXWORKS
1616
      if (!HAVE_64BIT_OBJECTS && !HAVE_NEWABI)
1617
        return (target_big_endian
1618
                ? "elf32-bigmips-vxworks"
1619
                : "elf32-littlemips-vxworks");
1620
#endif
1621
      return (target_big_endian
1622
              ? (HAVE_64BIT_OBJECTS
1623
                 ? ELF_TARGET ("elf64-", "big")
1624
                 : (HAVE_NEWABI
1625
                    ? ELF_TARGET ("elf32-n", "big")
1626
                    : ELF_TARGET ("elf32-", "big")))
1627
              : (HAVE_64BIT_OBJECTS
1628
                 ? ELF_TARGET ("elf64-", "little")
1629
                 : (HAVE_NEWABI
1630
                    ? ELF_TARGET ("elf32-n", "little")
1631
                    : ELF_TARGET ("elf32-", "little"))));
1632
    default:
1633
      abort ();
1634
      return NULL;
1635
    }
1636
}
1637
 
1638 160 khays
/* Return the length of a microMIPS instruction in bytes.  If bits of
1639
   the mask beyond the low 16 are 0, then it is a 16-bit instruction.
1640
   Otherwise assume a 32-bit instruction; 48-bit instructions (0x1f
1641
   major opcode) will require further modifications to the opcode
1642
   table.  */
1643
 
1644
static inline unsigned int
1645
micromips_insn_length (const struct mips_opcode *mo)
1646
{
1647
  return (mo->mask >> 16) == 0 ? 2 : 4;
1648
}
1649
 
1650 16 khays
/* Return the length of instruction INSN.  */
1651
 
1652
static inline unsigned int
1653
insn_length (const struct mips_cl_insn *insn)
1654
{
1655 160 khays
  if (mips_opts.micromips)
1656
    return micromips_insn_length (insn->insn_mo);
1657
  else if (mips_opts.mips16)
1658
    return insn->mips16_absolute_jump_p || insn->use_extend ? 4 : 2;
1659
  else
1660 16 khays
    return 4;
1661
}
1662
 
1663
/* Initialise INSN from opcode entry MO.  Leave its position unspecified.  */
1664
 
1665
static void
1666
create_insn (struct mips_cl_insn *insn, const struct mips_opcode *mo)
1667
{
1668
  size_t i;
1669
 
1670
  insn->insn_mo = mo;
1671
  insn->use_extend = FALSE;
1672
  insn->extend = 0;
1673
  insn->insn_opcode = mo->match;
1674
  insn->frag = NULL;
1675
  insn->where = 0;
1676
  for (i = 0; i < ARRAY_SIZE (insn->fixp); i++)
1677
    insn->fixp[i] = NULL;
1678
  insn->fixed_p = (mips_opts.noreorder > 0);
1679
  insn->noreorder_p = (mips_opts.noreorder > 0);
1680
  insn->mips16_absolute_jump_p = 0;
1681
  insn->complete_p = 0;
1682
}
1683
 
1684 160 khays
/* Record the current MIPS16/microMIPS mode in now_seg.  */
1685 16 khays
 
1686
static void
1687 160 khays
mips_record_compressed_mode (void)
1688 16 khays
{
1689
  segment_info_type *si;
1690
 
1691
  si = seg_info (now_seg);
1692
  if (si->tc_segment_info_data.mips16 != mips_opts.mips16)
1693
    si->tc_segment_info_data.mips16 = mips_opts.mips16;
1694 160 khays
  if (si->tc_segment_info_data.micromips != mips_opts.micromips)
1695
    si->tc_segment_info_data.micromips = mips_opts.micromips;
1696 16 khays
}
1697
 
1698
/* Install INSN at the location specified by its "frag" and "where" fields.  */
1699
 
1700
static void
1701
install_insn (const struct mips_cl_insn *insn)
1702
{
1703
  char *f = insn->frag->fr_literal + insn->where;
1704 160 khays
  if (!HAVE_CODE_COMPRESSION)
1705 16 khays
    md_number_to_chars (f, insn->insn_opcode, 4);
1706 160 khays
  else if (mips_opts.micromips)
1707
    {
1708
      unsigned int length = insn_length (insn);
1709
      if (length == 2)
1710
        md_number_to_chars (f, insn->insn_opcode, 2);
1711
      else if (length == 4)
1712
        {
1713
          md_number_to_chars (f, insn->insn_opcode >> 16, 2);
1714
          f += 2;
1715
          md_number_to_chars (f, insn->insn_opcode & 0xffff, 2);
1716
        }
1717
      else
1718
        as_bad (_("48-bit microMIPS instructions are not supported"));
1719
    }
1720 16 khays
  else if (insn->mips16_absolute_jump_p)
1721
    {
1722
      md_number_to_chars (f, insn->insn_opcode >> 16, 2);
1723
      md_number_to_chars (f + 2, insn->insn_opcode & 0xffff, 2);
1724
    }
1725
  else
1726
    {
1727
      if (insn->use_extend)
1728
        {
1729
          md_number_to_chars (f, 0xf000 | insn->extend, 2);
1730
          f += 2;
1731
        }
1732
      md_number_to_chars (f, insn->insn_opcode, 2);
1733
    }
1734 160 khays
  mips_record_compressed_mode ();
1735 16 khays
}
1736
 
1737
/* Move INSN to offset WHERE in FRAG.  Adjust the fixups accordingly
1738
   and install the opcode in the new location.  */
1739
 
1740
static void
1741
move_insn (struct mips_cl_insn *insn, fragS *frag, long where)
1742
{
1743
  size_t i;
1744
 
1745
  insn->frag = frag;
1746
  insn->where = where;
1747
  for (i = 0; i < ARRAY_SIZE (insn->fixp); i++)
1748
    if (insn->fixp[i] != NULL)
1749
      {
1750
        insn->fixp[i]->fx_frag = frag;
1751
        insn->fixp[i]->fx_where = where;
1752
      }
1753
  install_insn (insn);
1754
}
1755
 
1756
/* Add INSN to the end of the output.  */
1757
 
1758
static void
1759
add_fixed_insn (struct mips_cl_insn *insn)
1760
{
1761
  char *f = frag_more (insn_length (insn));
1762
  move_insn (insn, frag_now, f - frag_now->fr_literal);
1763
}
1764
 
1765
/* Start a variant frag and move INSN to the start of the variant part,
1766
   marking it as fixed.  The other arguments are as for frag_var.  */
1767
 
1768
static void
1769
add_relaxed_insn (struct mips_cl_insn *insn, int max_chars, int var,
1770
                  relax_substateT subtype, symbolS *symbol, offsetT offset)
1771
{
1772
  frag_grow (max_chars);
1773
  move_insn (insn, frag_now, frag_more (0) - frag_now->fr_literal);
1774
  insn->fixed_p = 1;
1775
  frag_var (rs_machine_dependent, max_chars, var,
1776
            subtype, symbol, offset, NULL);
1777
}
1778
 
1779
/* Insert N copies of INSN into the history buffer, starting at
1780
   position FIRST.  Neither FIRST nor N need to be clipped.  */
1781
 
1782
static void
1783
insert_into_history (unsigned int first, unsigned int n,
1784
                     const struct mips_cl_insn *insn)
1785
{
1786
  if (mips_relax.sequence != 2)
1787
    {
1788
      unsigned int i;
1789
 
1790
      for (i = ARRAY_SIZE (history); i-- > first;)
1791
        if (i >= first + n)
1792
          history[i] = history[i - n];
1793
        else
1794
          history[i] = *insn;
1795
    }
1796
}
1797
 
1798
/* Initialize vr4120_conflicts.  There is a bit of duplication here:
1799
   the idea is to make it obvious at a glance that each errata is
1800
   included.  */
1801
 
1802
static void
1803
init_vr4120_conflicts (void)
1804
{
1805
#define CONFLICT(FIRST, SECOND) \
1806
    vr4120_conflicts[FIX_VR4120_##FIRST] |= 1 << FIX_VR4120_##SECOND
1807
 
1808
  /* Errata 21 - [D]DIV[U] after [D]MACC */
1809
  CONFLICT (MACC, DIV);
1810
  CONFLICT (DMACC, DIV);
1811
 
1812
  /* Errata 23 - Continuous DMULT[U]/DMACC instructions.  */
1813
  CONFLICT (DMULT, DMULT);
1814
  CONFLICT (DMULT, DMACC);
1815
  CONFLICT (DMACC, DMULT);
1816
  CONFLICT (DMACC, DMACC);
1817
 
1818
  /* Errata 24 - MT{LO,HI} after [D]MACC */
1819
  CONFLICT (MACC, MTHILO);
1820
  CONFLICT (DMACC, MTHILO);
1821
 
1822
  /* VR4181A errata MD(1): "If a MULT, MULTU, DMULT or DMULTU
1823
     instruction is executed immediately after a MACC or DMACC
1824
     instruction, the result of [either instruction] is incorrect."  */
1825
  CONFLICT (MACC, MULT);
1826
  CONFLICT (MACC, DMULT);
1827
  CONFLICT (DMACC, MULT);
1828
  CONFLICT (DMACC, DMULT);
1829
 
1830
  /* VR4181A errata MD(4): "If a MACC or DMACC instruction is
1831
     executed immediately after a DMULT, DMULTU, DIV, DIVU,
1832
     DDIV or DDIVU instruction, the result of the MACC or
1833
     DMACC instruction is incorrect.".  */
1834
  CONFLICT (DMULT, MACC);
1835
  CONFLICT (DMULT, DMACC);
1836
  CONFLICT (DIV, MACC);
1837
  CONFLICT (DIV, DMACC);
1838
 
1839
#undef CONFLICT
1840
}
1841
 
1842
struct regname {
1843
  const char *name;
1844
  unsigned int num;
1845
};
1846
 
1847
#define RTYPE_MASK      0x1ff00
1848
#define RTYPE_NUM       0x00100
1849
#define RTYPE_FPU       0x00200
1850
#define RTYPE_FCC       0x00400
1851
#define RTYPE_VEC       0x00800
1852
#define RTYPE_GP        0x01000
1853
#define RTYPE_CP0       0x02000
1854
#define RTYPE_PC        0x04000
1855
#define RTYPE_ACC       0x08000
1856
#define RTYPE_CCC       0x10000
1857
#define RNUM_MASK       0x000ff
1858
#define RWARN           0x80000
1859
 
1860
#define GENERIC_REGISTER_NUMBERS \
1861
    {"$0",      RTYPE_NUM | 0},  \
1862
    {"$1",      RTYPE_NUM | 1},  \
1863
    {"$2",      RTYPE_NUM | 2},  \
1864
    {"$3",      RTYPE_NUM | 3},  \
1865
    {"$4",      RTYPE_NUM | 4},  \
1866
    {"$5",      RTYPE_NUM | 5},  \
1867
    {"$6",      RTYPE_NUM | 6},  \
1868
    {"$7",      RTYPE_NUM | 7},  \
1869
    {"$8",      RTYPE_NUM | 8},  \
1870
    {"$9",      RTYPE_NUM | 9},  \
1871
    {"$10",     RTYPE_NUM | 10}, \
1872
    {"$11",     RTYPE_NUM | 11}, \
1873
    {"$12",     RTYPE_NUM | 12}, \
1874
    {"$13",     RTYPE_NUM | 13}, \
1875
    {"$14",     RTYPE_NUM | 14}, \
1876
    {"$15",     RTYPE_NUM | 15}, \
1877
    {"$16",     RTYPE_NUM | 16}, \
1878
    {"$17",     RTYPE_NUM | 17}, \
1879
    {"$18",     RTYPE_NUM | 18}, \
1880
    {"$19",     RTYPE_NUM | 19}, \
1881
    {"$20",     RTYPE_NUM | 20}, \
1882
    {"$21",     RTYPE_NUM | 21}, \
1883
    {"$22",     RTYPE_NUM | 22}, \
1884
    {"$23",     RTYPE_NUM | 23}, \
1885
    {"$24",     RTYPE_NUM | 24}, \
1886
    {"$25",     RTYPE_NUM | 25}, \
1887
    {"$26",     RTYPE_NUM | 26}, \
1888
    {"$27",     RTYPE_NUM | 27}, \
1889
    {"$28",     RTYPE_NUM | 28}, \
1890
    {"$29",     RTYPE_NUM | 29}, \
1891
    {"$30",     RTYPE_NUM | 30}, \
1892
    {"$31",     RTYPE_NUM | 31}
1893
 
1894
#define FPU_REGISTER_NAMES       \
1895
    {"$f0",     RTYPE_FPU | 0},  \
1896
    {"$f1",     RTYPE_FPU | 1},  \
1897
    {"$f2",     RTYPE_FPU | 2},  \
1898
    {"$f3",     RTYPE_FPU | 3},  \
1899
    {"$f4",     RTYPE_FPU | 4},  \
1900
    {"$f5",     RTYPE_FPU | 5},  \
1901
    {"$f6",     RTYPE_FPU | 6},  \
1902
    {"$f7",     RTYPE_FPU | 7},  \
1903
    {"$f8",     RTYPE_FPU | 8},  \
1904
    {"$f9",     RTYPE_FPU | 9},  \
1905
    {"$f10",    RTYPE_FPU | 10}, \
1906
    {"$f11",    RTYPE_FPU | 11}, \
1907
    {"$f12",    RTYPE_FPU | 12}, \
1908
    {"$f13",    RTYPE_FPU | 13}, \
1909
    {"$f14",    RTYPE_FPU | 14}, \
1910
    {"$f15",    RTYPE_FPU | 15}, \
1911
    {"$f16",    RTYPE_FPU | 16}, \
1912
    {"$f17",    RTYPE_FPU | 17}, \
1913
    {"$f18",    RTYPE_FPU | 18}, \
1914
    {"$f19",    RTYPE_FPU | 19}, \
1915
    {"$f20",    RTYPE_FPU | 20}, \
1916
    {"$f21",    RTYPE_FPU | 21}, \
1917
    {"$f22",    RTYPE_FPU | 22}, \
1918
    {"$f23",    RTYPE_FPU | 23}, \
1919
    {"$f24",    RTYPE_FPU | 24}, \
1920
    {"$f25",    RTYPE_FPU | 25}, \
1921
    {"$f26",    RTYPE_FPU | 26}, \
1922
    {"$f27",    RTYPE_FPU | 27}, \
1923
    {"$f28",    RTYPE_FPU | 28}, \
1924
    {"$f29",    RTYPE_FPU | 29}, \
1925
    {"$f30",    RTYPE_FPU | 30}, \
1926
    {"$f31",    RTYPE_FPU | 31}
1927
 
1928
#define FPU_CONDITION_CODE_NAMES \
1929
    {"$fcc0",   RTYPE_FCC | 0},  \
1930
    {"$fcc1",   RTYPE_FCC | 1},  \
1931
    {"$fcc2",   RTYPE_FCC | 2},  \
1932
    {"$fcc3",   RTYPE_FCC | 3},  \
1933
    {"$fcc4",   RTYPE_FCC | 4},  \
1934
    {"$fcc5",   RTYPE_FCC | 5},  \
1935
    {"$fcc6",   RTYPE_FCC | 6},  \
1936
    {"$fcc7",   RTYPE_FCC | 7}
1937
 
1938
#define COPROC_CONDITION_CODE_NAMES         \
1939
    {"$cc0",    RTYPE_FCC | RTYPE_CCC | 0}, \
1940
    {"$cc1",    RTYPE_FCC | RTYPE_CCC | 1}, \
1941
    {"$cc2",    RTYPE_FCC | RTYPE_CCC | 2}, \
1942
    {"$cc3",    RTYPE_FCC | RTYPE_CCC | 3}, \
1943
    {"$cc4",    RTYPE_FCC | RTYPE_CCC | 4}, \
1944
    {"$cc5",    RTYPE_FCC | RTYPE_CCC | 5}, \
1945
    {"$cc6",    RTYPE_FCC | RTYPE_CCC | 6}, \
1946
    {"$cc7",    RTYPE_FCC | RTYPE_CCC | 7}
1947
 
1948
#define N32N64_SYMBOLIC_REGISTER_NAMES \
1949
    {"$a4",     RTYPE_GP | 8},  \
1950
    {"$a5",     RTYPE_GP | 9},  \
1951
    {"$a6",     RTYPE_GP | 10}, \
1952
    {"$a7",     RTYPE_GP | 11}, \
1953
    {"$ta0",    RTYPE_GP | 8},  /* alias for $a4 */ \
1954
    {"$ta1",    RTYPE_GP | 9},  /* alias for $a5 */ \
1955
    {"$ta2",    RTYPE_GP | 10}, /* alias for $a6 */ \
1956
    {"$ta3",    RTYPE_GP | 11}, /* alias for $a7 */ \
1957
    {"$t0",     RTYPE_GP | 12}, \
1958
    {"$t1",     RTYPE_GP | 13}, \
1959
    {"$t2",     RTYPE_GP | 14}, \
1960
    {"$t3",     RTYPE_GP | 15}
1961
 
1962
#define O32_SYMBOLIC_REGISTER_NAMES \
1963
    {"$t0",     RTYPE_GP | 8},  \
1964
    {"$t1",     RTYPE_GP | 9},  \
1965
    {"$t2",     RTYPE_GP | 10}, \
1966
    {"$t3",     RTYPE_GP | 11}, \
1967
    {"$t4",     RTYPE_GP | 12}, \
1968
    {"$t5",     RTYPE_GP | 13}, \
1969
    {"$t6",     RTYPE_GP | 14}, \
1970
    {"$t7",     RTYPE_GP | 15}, \
1971
    {"$ta0",    RTYPE_GP | 12}, /* alias for $t4 */ \
1972
    {"$ta1",    RTYPE_GP | 13}, /* alias for $t5 */ \
1973
    {"$ta2",    RTYPE_GP | 14}, /* alias for $t6 */ \
1974
    {"$ta3",    RTYPE_GP | 15}  /* alias for $t7 */
1975
 
1976
/* Remaining symbolic register names */
1977
#define SYMBOLIC_REGISTER_NAMES \
1978
    {"$zero",   RTYPE_GP | 0},  \
1979
    {"$at",     RTYPE_GP | 1},  \
1980
    {"$AT",     RTYPE_GP | 1},  \
1981
    {"$v0",     RTYPE_GP | 2},  \
1982
    {"$v1",     RTYPE_GP | 3},  \
1983
    {"$a0",     RTYPE_GP | 4},  \
1984
    {"$a1",     RTYPE_GP | 5},  \
1985
    {"$a2",     RTYPE_GP | 6},  \
1986
    {"$a3",     RTYPE_GP | 7},  \
1987
    {"$s0",     RTYPE_GP | 16}, \
1988
    {"$s1",     RTYPE_GP | 17}, \
1989
    {"$s2",     RTYPE_GP | 18}, \
1990
    {"$s3",     RTYPE_GP | 19}, \
1991
    {"$s4",     RTYPE_GP | 20}, \
1992
    {"$s5",     RTYPE_GP | 21}, \
1993
    {"$s6",     RTYPE_GP | 22}, \
1994
    {"$s7",     RTYPE_GP | 23}, \
1995
    {"$t8",     RTYPE_GP | 24}, \
1996
    {"$t9",     RTYPE_GP | 25}, \
1997
    {"$k0",     RTYPE_GP | 26}, \
1998
    {"$kt0",    RTYPE_GP | 26}, \
1999
    {"$k1",     RTYPE_GP | 27}, \
2000
    {"$kt1",    RTYPE_GP | 27}, \
2001
    {"$gp",     RTYPE_GP | 28}, \
2002
    {"$sp",     RTYPE_GP | 29}, \
2003
    {"$s8",     RTYPE_GP | 30}, \
2004
    {"$fp",     RTYPE_GP | 30}, \
2005
    {"$ra",     RTYPE_GP | 31}
2006
 
2007
#define MIPS16_SPECIAL_REGISTER_NAMES \
2008
    {"$pc",     RTYPE_PC | 0}
2009
 
2010
#define MDMX_VECTOR_REGISTER_NAMES \
2011
    /* {"$v0",  RTYPE_VEC | 0},  clash with REG 2 above */ \
2012
    /* {"$v1",  RTYPE_VEC | 1},  clash with REG 3 above */ \
2013
    {"$v2",     RTYPE_VEC | 2},  \
2014
    {"$v3",     RTYPE_VEC | 3},  \
2015
    {"$v4",     RTYPE_VEC | 4},  \
2016
    {"$v5",     RTYPE_VEC | 5},  \
2017
    {"$v6",     RTYPE_VEC | 6},  \
2018
    {"$v7",     RTYPE_VEC | 7},  \
2019
    {"$v8",     RTYPE_VEC | 8},  \
2020
    {"$v9",     RTYPE_VEC | 9},  \
2021
    {"$v10",    RTYPE_VEC | 10}, \
2022
    {"$v11",    RTYPE_VEC | 11}, \
2023
    {"$v12",    RTYPE_VEC | 12}, \
2024
    {"$v13",    RTYPE_VEC | 13}, \
2025
    {"$v14",    RTYPE_VEC | 14}, \
2026
    {"$v15",    RTYPE_VEC | 15}, \
2027
    {"$v16",    RTYPE_VEC | 16}, \
2028
    {"$v17",    RTYPE_VEC | 17}, \
2029
    {"$v18",    RTYPE_VEC | 18}, \
2030
    {"$v19",    RTYPE_VEC | 19}, \
2031
    {"$v20",    RTYPE_VEC | 20}, \
2032
    {"$v21",    RTYPE_VEC | 21}, \
2033
    {"$v22",    RTYPE_VEC | 22}, \
2034
    {"$v23",    RTYPE_VEC | 23}, \
2035
    {"$v24",    RTYPE_VEC | 24}, \
2036
    {"$v25",    RTYPE_VEC | 25}, \
2037
    {"$v26",    RTYPE_VEC | 26}, \
2038
    {"$v27",    RTYPE_VEC | 27}, \
2039
    {"$v28",    RTYPE_VEC | 28}, \
2040
    {"$v29",    RTYPE_VEC | 29}, \
2041
    {"$v30",    RTYPE_VEC | 30}, \
2042
    {"$v31",    RTYPE_VEC | 31}
2043
 
2044
#define MIPS_DSP_ACCUMULATOR_NAMES \
2045
    {"$ac0",    RTYPE_ACC | 0}, \
2046
    {"$ac1",    RTYPE_ACC | 1}, \
2047
    {"$ac2",    RTYPE_ACC | 2}, \
2048
    {"$ac3",    RTYPE_ACC | 3}
2049
 
2050
static const struct regname reg_names[] = {
2051
  GENERIC_REGISTER_NUMBERS,
2052
  FPU_REGISTER_NAMES,
2053
  FPU_CONDITION_CODE_NAMES,
2054
  COPROC_CONDITION_CODE_NAMES,
2055
 
2056
  /* The $txx registers depends on the abi,
2057
     these will be added later into the symbol table from
2058
     one of the tables below once mips_abi is set after
2059
     parsing of arguments from the command line. */
2060
  SYMBOLIC_REGISTER_NAMES,
2061
 
2062
  MIPS16_SPECIAL_REGISTER_NAMES,
2063
  MDMX_VECTOR_REGISTER_NAMES,
2064
  MIPS_DSP_ACCUMULATOR_NAMES,
2065
  {0, 0}
2066
};
2067
 
2068
static const struct regname reg_names_o32[] = {
2069
  O32_SYMBOLIC_REGISTER_NAMES,
2070
  {0, 0}
2071
};
2072
 
2073
static const struct regname reg_names_n32n64[] = {
2074
  N32N64_SYMBOLIC_REGISTER_NAMES,
2075
  {0, 0}
2076
};
2077
 
2078 160 khays
/* Check if S points at a valid register specifier according to TYPES.
2079
   If so, then return 1, advance S to consume the specifier and store
2080
   the register's number in REGNOP, otherwise return 0.  */
2081
 
2082 16 khays
static int
2083
reg_lookup (char **s, unsigned int types, unsigned int *regnop)
2084
{
2085
  symbolS *symbolP;
2086
  char *e;
2087
  char save_c;
2088
  int reg = -1;
2089
 
2090
  /* Find end of name.  */
2091
  e = *s;
2092
  if (is_name_beginner (*e))
2093
    ++e;
2094
  while (is_part_of_name (*e))
2095
    ++e;
2096
 
2097
  /* Terminate name.  */
2098
  save_c = *e;
2099
  *e = '\0';
2100
 
2101
  /* Look for a register symbol.  */
2102
  if ((symbolP = symbol_find (*s)) && S_GET_SEGMENT (symbolP) == reg_section)
2103
    {
2104
      int r = S_GET_VALUE (symbolP);
2105
      if (r & types)
2106
        reg = r & RNUM_MASK;
2107
      else if ((types & RTYPE_VEC) && (r & ~1) == (RTYPE_GP | 2))
2108
        /* Convert GP reg $v0/1 to MDMX reg $v0/1!  */
2109
        reg = (r & RNUM_MASK) - 2;
2110
    }
2111
  /* Else see if this is a register defined in an itbl entry.  */
2112
  else if ((types & RTYPE_GP) && itbl_have_entries)
2113
    {
2114
      char *n = *s;
2115
      unsigned long r;
2116
 
2117
      if (*n == '$')
2118
        ++n;
2119
      if (itbl_get_reg_val (n, &r))
2120
        reg = r & RNUM_MASK;
2121
    }
2122
 
2123
  /* Advance to next token if a register was recognised.  */
2124
  if (reg >= 0)
2125
    *s = e;
2126
  else if (types & RWARN)
2127
    as_warn (_("Unrecognized register name `%s'"), *s);
2128
 
2129
  *e = save_c;
2130
  if (regnop)
2131
    *regnop = reg;
2132
  return reg >= 0;
2133
}
2134
 
2135 160 khays
/* Check if S points at a valid register list according to TYPES.
2136
   If so, then return 1, advance S to consume the list and store
2137
   the registers present on the list as a bitmask of ones in REGLISTP,
2138
   otherwise return 0.  A valid list comprises a comma-separated
2139
   enumeration of valid single registers and/or dash-separated
2140
   contiguous register ranges as determined by their numbers.
2141
 
2142
   As a special exception if one of s0-s7 registers is specified as
2143
   the range's lower delimiter and s8 (fp) is its upper one, then no
2144
   registers whose numbers place them between s7 and s8 (i.e. $24-$29)
2145
   are selected; they have to be listed separately if needed.  */
2146
 
2147
static int
2148
reglist_lookup (char **s, unsigned int types, unsigned int *reglistp)
2149
{
2150
  unsigned int reglist = 0;
2151
  unsigned int lastregno;
2152
  bfd_boolean ok = TRUE;
2153
  unsigned int regmask;
2154
  char *s_endlist = *s;
2155
  char *s_reset = *s;
2156
  unsigned int regno;
2157
 
2158
  while (reg_lookup (s, types, &regno))
2159
    {
2160
      lastregno = regno;
2161
      if (**s == '-')
2162
        {
2163
          (*s)++;
2164
          ok = reg_lookup (s, types, &lastregno);
2165
          if (ok && lastregno < regno)
2166
            ok = FALSE;
2167
          if (!ok)
2168
            break;
2169
        }
2170
 
2171
      if (lastregno == FP && regno >= S0 && regno <= S7)
2172
        {
2173
          lastregno = S7;
2174
          reglist |= 1 << FP;
2175
        }
2176
      regmask = 1 << lastregno;
2177
      regmask = (regmask << 1) - 1;
2178
      regmask ^= (1 << regno) - 1;
2179
      reglist |= regmask;
2180
 
2181
      s_endlist = *s;
2182
      if (**s != ',')
2183
        break;
2184
      (*s)++;
2185
    }
2186
 
2187
  if (ok)
2188
    *s = s_endlist;
2189
  else
2190
    *s = s_reset;
2191
  if (reglistp)
2192
    *reglistp = reglist;
2193
  return ok && reglist != 0;
2194
}
2195
 
2196 16 khays
/* Return TRUE if opcode MO is valid on the currently selected ISA and
2197
   architecture.  Use is_opcode_valid_16 for MIPS16 opcodes.  */
2198
 
2199
static bfd_boolean
2200
is_opcode_valid (const struct mips_opcode *mo)
2201
{
2202
  int isa = mips_opts.isa;
2203
  int fp_s, fp_d;
2204
 
2205
  if (mips_opts.ase_mdmx)
2206
    isa |= INSN_MDMX;
2207
  if (mips_opts.ase_dsp)
2208
    isa |= INSN_DSP;
2209
  if (mips_opts.ase_dsp && ISA_SUPPORTS_DSP64_ASE)
2210
    isa |= INSN_DSP64;
2211
  if (mips_opts.ase_dspr2)
2212
    isa |= INSN_DSPR2;
2213
  if (mips_opts.ase_mt)
2214
    isa |= INSN_MT;
2215
  if (mips_opts.ase_mips3d)
2216
    isa |= INSN_MIPS3D;
2217
  if (mips_opts.ase_smartmips)
2218
    isa |= INSN_SMARTMIPS;
2219 160 khays
  if (mips_opts.ase_mcu)
2220
    isa |= INSN_MCU;
2221 16 khays
 
2222
  /* Don't accept instructions based on the ISA if the CPU does not implement
2223
     all the coprocessor insns. */
2224
  if (NO_ISA_COP (mips_opts.arch)
2225
      && COP_INSN (mo->pinfo))
2226
    isa = 0;
2227
 
2228
  if (!OPCODE_IS_MEMBER (mo, isa, mips_opts.arch))
2229
    return FALSE;
2230
 
2231
  /* Check whether the instruction or macro requires single-precision or
2232
     double-precision floating-point support.  Note that this information is
2233
     stored differently in the opcode table for insns and macros.  */
2234
  if (mo->pinfo == INSN_MACRO)
2235
    {
2236
      fp_s = mo->pinfo2 & INSN2_M_FP_S;
2237
      fp_d = mo->pinfo2 & INSN2_M_FP_D;
2238
    }
2239
  else
2240
    {
2241
      fp_s = mo->pinfo & FP_S;
2242
      fp_d = mo->pinfo & FP_D;
2243
    }
2244
 
2245
  if (fp_d && (mips_opts.soft_float || mips_opts.single_float))
2246
    return FALSE;
2247
 
2248
  if (fp_s && mips_opts.soft_float)
2249
    return FALSE;
2250
 
2251
  return TRUE;
2252
}
2253
 
2254
/* Return TRUE if the MIPS16 opcode MO is valid on the currently
2255
   selected ISA and architecture.  */
2256
 
2257
static bfd_boolean
2258
is_opcode_valid_16 (const struct mips_opcode *mo)
2259
{
2260
  return OPCODE_IS_MEMBER (mo, mips_opts.isa, mips_opts.arch) ? TRUE : FALSE;
2261
}
2262
 
2263 160 khays
/* Return TRUE if the size of the microMIPS opcode MO matches one
2264
   explicitly requested.  Always TRUE in the standard MIPS mode.  */
2265
 
2266
static bfd_boolean
2267
is_size_valid (const struct mips_opcode *mo)
2268
{
2269
  if (!mips_opts.micromips)
2270
    return TRUE;
2271
 
2272
  if (!forced_insn_length)
2273
    return TRUE;
2274
  if (mo->pinfo == INSN_MACRO)
2275
    return FALSE;
2276
  return forced_insn_length == micromips_insn_length (mo);
2277
}
2278
 
2279
/* Return TRUE if the microMIPS opcode MO is valid for the delay slot
2280
   of the preceding instruction.  Always TRUE in the standard MIPS mode.  */
2281
 
2282
static bfd_boolean
2283
is_delay_slot_valid (const struct mips_opcode *mo)
2284
{
2285
  if (!mips_opts.micromips)
2286
    return TRUE;
2287
 
2288
  if (mo->pinfo == INSN_MACRO)
2289
    return TRUE;
2290
  if ((history[0].insn_mo->pinfo2 & INSN2_BRANCH_DELAY_32BIT) != 0
2291
      && micromips_insn_length (mo) != 4)
2292
    return FALSE;
2293
  if ((history[0].insn_mo->pinfo2 & INSN2_BRANCH_DELAY_16BIT) != 0
2294
      && micromips_insn_length (mo) != 2)
2295
    return FALSE;
2296
 
2297
  return TRUE;
2298
}
2299
 
2300 16 khays
/* This function is called once, at assembler startup time.  It should set up
2301
   all the tables, etc. that the MD part of the assembler will need.  */
2302
 
2303
void
2304
md_begin (void)
2305
{
2306
  const char *retval = NULL;
2307
  int i = 0;
2308
  int broken = 0;
2309
 
2310
  if (mips_pic != NO_PIC)
2311
    {
2312
      if (g_switch_seen && g_switch_value != 0)
2313
        as_bad (_("-G may not be used in position-independent code"));
2314
      g_switch_value = 0;
2315
    }
2316
 
2317
  if (! bfd_set_arch_mach (stdoutput, bfd_arch_mips, file_mips_arch))
2318
    as_warn (_("Could not set architecture and machine"));
2319
 
2320
  op_hash = hash_new ();
2321
 
2322
  for (i = 0; i < NUMOPCODES;)
2323
    {
2324
      const char *name = mips_opcodes[i].name;
2325
 
2326
      retval = hash_insert (op_hash, name, (void *) &mips_opcodes[i]);
2327
      if (retval != NULL)
2328
        {
2329
          fprintf (stderr, _("internal error: can't hash `%s': %s\n"),
2330
                   mips_opcodes[i].name, retval);
2331
          /* Probably a memory allocation problem?  Give up now.  */
2332
          as_fatal (_("Broken assembler.  No assembly attempted."));
2333
        }
2334
      do
2335
        {
2336
          if (mips_opcodes[i].pinfo != INSN_MACRO)
2337
            {
2338
              if (!validate_mips_insn (&mips_opcodes[i]))
2339
                broken = 1;
2340
              if (nop_insn.insn_mo == NULL && strcmp (name, "nop") == 0)
2341
                {
2342
                  create_insn (&nop_insn, mips_opcodes + i);
2343
                  if (mips_fix_loongson2f_nop)
2344
                    nop_insn.insn_opcode = LOONGSON2F_NOP_INSN;
2345
                  nop_insn.fixed_p = 1;
2346
                }
2347
            }
2348
          ++i;
2349
        }
2350
      while ((i < NUMOPCODES) && !strcmp (mips_opcodes[i].name, name));
2351
    }
2352
 
2353
  mips16_op_hash = hash_new ();
2354
 
2355
  i = 0;
2356
  while (i < bfd_mips16_num_opcodes)
2357
    {
2358
      const char *name = mips16_opcodes[i].name;
2359
 
2360
      retval = hash_insert (mips16_op_hash, name, (void *) &mips16_opcodes[i]);
2361
      if (retval != NULL)
2362
        as_fatal (_("internal: can't hash `%s': %s"),
2363
                  mips16_opcodes[i].name, retval);
2364
      do
2365
        {
2366
          if (mips16_opcodes[i].pinfo != INSN_MACRO
2367
              && ((mips16_opcodes[i].match & mips16_opcodes[i].mask)
2368
                  != mips16_opcodes[i].match))
2369
            {
2370
              fprintf (stderr, _("internal error: bad mips16 opcode: %s %s\n"),
2371
                       mips16_opcodes[i].name, mips16_opcodes[i].args);
2372
              broken = 1;
2373
            }
2374
          if (mips16_nop_insn.insn_mo == NULL && strcmp (name, "nop") == 0)
2375
            {
2376
              create_insn (&mips16_nop_insn, mips16_opcodes + i);
2377
              mips16_nop_insn.fixed_p = 1;
2378
            }
2379
          ++i;
2380
        }
2381
      while (i < bfd_mips16_num_opcodes
2382
             && strcmp (mips16_opcodes[i].name, name) == 0);
2383
    }
2384
 
2385 160 khays
  micromips_op_hash = hash_new ();
2386
 
2387
  i = 0;
2388
  while (i < bfd_micromips_num_opcodes)
2389
    {
2390
      const char *name = micromips_opcodes[i].name;
2391
 
2392
      retval = hash_insert (micromips_op_hash, name,
2393
                            (void *) &micromips_opcodes[i]);
2394
      if (retval != NULL)
2395
        as_fatal (_("internal: can't hash `%s': %s"),
2396
                  micromips_opcodes[i].name, retval);
2397
      do
2398
        if (micromips_opcodes[i].pinfo != INSN_MACRO)
2399
          {
2400
            struct mips_cl_insn *micromips_nop_insn;
2401
 
2402
            if (!validate_micromips_insn (&micromips_opcodes[i]))
2403
              broken = 1;
2404
 
2405
            if (micromips_insn_length (micromips_opcodes + i) == 2)
2406
              micromips_nop_insn = &micromips_nop16_insn;
2407
            else if (micromips_insn_length (micromips_opcodes + i) == 4)
2408
              micromips_nop_insn = &micromips_nop32_insn;
2409
            else
2410
              continue;
2411
 
2412
            if (micromips_nop_insn->insn_mo == NULL
2413
                && strcmp (name, "nop") == 0)
2414
              {
2415
                create_insn (micromips_nop_insn, micromips_opcodes + i);
2416
                micromips_nop_insn->fixed_p = 1;
2417
              }
2418
          }
2419
      while (++i < bfd_micromips_num_opcodes
2420
             && strcmp (micromips_opcodes[i].name, name) == 0);
2421
    }
2422
 
2423 16 khays
  if (broken)
2424
    as_fatal (_("Broken assembler.  No assembly attempted."));
2425
 
2426
  /* We add all the general register names to the symbol table.  This
2427
     helps us detect invalid uses of them.  */
2428
  for (i = 0; reg_names[i].name; i++)
2429
    symbol_table_insert (symbol_new (reg_names[i].name, reg_section,
2430
                                     reg_names[i].num, /* & RNUM_MASK, */
2431
                                     &zero_address_frag));
2432
  if (HAVE_NEWABI)
2433
    for (i = 0; reg_names_n32n64[i].name; i++)
2434
      symbol_table_insert (symbol_new (reg_names_n32n64[i].name, reg_section,
2435
                                       reg_names_n32n64[i].num, /* & RNUM_MASK, */
2436
                                       &zero_address_frag));
2437
  else
2438
    for (i = 0; reg_names_o32[i].name; i++)
2439
      symbol_table_insert (symbol_new (reg_names_o32[i].name, reg_section,
2440
                                       reg_names_o32[i].num, /* & RNUM_MASK, */
2441
                                       &zero_address_frag));
2442
 
2443
  mips_no_prev_insn ();
2444
 
2445
  mips_gprmask = 0;
2446
  mips_cprmask[0] = 0;
2447
  mips_cprmask[1] = 0;
2448
  mips_cprmask[2] = 0;
2449
  mips_cprmask[3] = 0;
2450
 
2451
  /* set the default alignment for the text section (2**2) */
2452
  record_alignment (text_section, 2);
2453
 
2454
  bfd_set_gp_size (stdoutput, g_switch_value);
2455
 
2456
#ifdef OBJ_ELF
2457
  if (IS_ELF)
2458
    {
2459
      /* On a native system other than VxWorks, sections must be aligned
2460
         to 16 byte boundaries.  When configured for an embedded ELF
2461
         target, we don't bother.  */
2462
      if (strncmp (TARGET_OS, "elf", 3) != 0
2463
          && strncmp (TARGET_OS, "vxworks", 7) != 0)
2464
        {
2465
          (void) bfd_set_section_alignment (stdoutput, text_section, 4);
2466
          (void) bfd_set_section_alignment (stdoutput, data_section, 4);
2467
          (void) bfd_set_section_alignment (stdoutput, bss_section, 4);
2468
        }
2469
 
2470
      /* Create a .reginfo section for register masks and a .mdebug
2471
         section for debugging information.  */
2472
      {
2473
        segT seg;
2474
        subsegT subseg;
2475
        flagword flags;
2476
        segT sec;
2477
 
2478
        seg = now_seg;
2479
        subseg = now_subseg;
2480
 
2481
        /* The ABI says this section should be loaded so that the
2482
           running program can access it.  However, we don't load it
2483
           if we are configured for an embedded target */
2484
        flags = SEC_READONLY | SEC_DATA;
2485
        if (strncmp (TARGET_OS, "elf", 3) != 0)
2486
          flags |= SEC_ALLOC | SEC_LOAD;
2487
 
2488
        if (mips_abi != N64_ABI)
2489
          {
2490
            sec = subseg_new (".reginfo", (subsegT) 0);
2491
 
2492
            bfd_set_section_flags (stdoutput, sec, flags);
2493
            bfd_set_section_alignment (stdoutput, sec, HAVE_NEWABI ? 3 : 2);
2494
 
2495
            mips_regmask_frag = frag_more (sizeof (Elf32_External_RegInfo));
2496
          }
2497
        else
2498
          {
2499
            /* The 64-bit ABI uses a .MIPS.options section rather than
2500
               .reginfo section.  */
2501
            sec = subseg_new (".MIPS.options", (subsegT) 0);
2502
            bfd_set_section_flags (stdoutput, sec, flags);
2503
            bfd_set_section_alignment (stdoutput, sec, 3);
2504
 
2505
            /* Set up the option header.  */
2506
            {
2507
              Elf_Internal_Options opthdr;
2508
              char *f;
2509
 
2510
              opthdr.kind = ODK_REGINFO;
2511
              opthdr.size = (sizeof (Elf_External_Options)
2512
                             + sizeof (Elf64_External_RegInfo));
2513
              opthdr.section = 0;
2514
              opthdr.info = 0;
2515
              f = frag_more (sizeof (Elf_External_Options));
2516
              bfd_mips_elf_swap_options_out (stdoutput, &opthdr,
2517
                                             (Elf_External_Options *) f);
2518
 
2519
              mips_regmask_frag = frag_more (sizeof (Elf64_External_RegInfo));
2520
            }
2521
          }
2522
 
2523
        if (ECOFF_DEBUGGING)
2524
          {
2525
            sec = subseg_new (".mdebug", (subsegT) 0);
2526
            (void) bfd_set_section_flags (stdoutput, sec,
2527
                                          SEC_HAS_CONTENTS | SEC_READONLY);
2528
            (void) bfd_set_section_alignment (stdoutput, sec, 2);
2529
          }
2530
        else if (mips_flag_pdr)
2531
          {
2532
            pdr_seg = subseg_new (".pdr", (subsegT) 0);
2533
            (void) bfd_set_section_flags (stdoutput, pdr_seg,
2534
                                          SEC_READONLY | SEC_RELOC
2535
                                          | SEC_DEBUGGING);
2536
            (void) bfd_set_section_alignment (stdoutput, pdr_seg, 2);
2537
          }
2538
 
2539
        subseg_set (seg, subseg);
2540
      }
2541
    }
2542
#endif /* OBJ_ELF */
2543
 
2544
  if (! ECOFF_DEBUGGING)
2545
    md_obj_begin ();
2546
 
2547
  if (mips_fix_vr4120)
2548
    init_vr4120_conflicts ();
2549
}
2550
 
2551
void
2552
md_mips_end (void)
2553
{
2554 160 khays
  mips_emit_delays ();
2555 16 khays
  if (! ECOFF_DEBUGGING)
2556
    md_obj_end ();
2557
}
2558
 
2559
void
2560
md_assemble (char *str)
2561
{
2562
  struct mips_cl_insn insn;
2563
  bfd_reloc_code_real_type unused_reloc[3]
2564
    = {BFD_RELOC_UNUSED, BFD_RELOC_UNUSED, BFD_RELOC_UNUSED};
2565
 
2566
  imm_expr.X_op = O_absent;
2567
  imm2_expr.X_op = O_absent;
2568
  offset_expr.X_op = O_absent;
2569
  imm_reloc[0] = BFD_RELOC_UNUSED;
2570
  imm_reloc[1] = BFD_RELOC_UNUSED;
2571
  imm_reloc[2] = BFD_RELOC_UNUSED;
2572
  offset_reloc[0] = BFD_RELOC_UNUSED;
2573
  offset_reloc[1] = BFD_RELOC_UNUSED;
2574
  offset_reloc[2] = BFD_RELOC_UNUSED;
2575
 
2576
  if (mips_opts.mips16)
2577
    mips16_ip (str, &insn);
2578
  else
2579
    {
2580
      mips_ip (str, &insn);
2581
      DBG ((_("returned from mips_ip(%s) insn_opcode = 0x%x\n"),
2582
            str, insn.insn_opcode));
2583
    }
2584
 
2585
  if (insn_error)
2586
    {
2587
      as_bad ("%s `%s'", insn_error, str);
2588
      return;
2589
    }
2590
 
2591
  if (insn.insn_mo->pinfo == INSN_MACRO)
2592
    {
2593
      macro_start ();
2594
      if (mips_opts.mips16)
2595
        mips16_macro (&insn);
2596
      else
2597
        macro (&insn);
2598
      macro_end ();
2599
    }
2600
  else
2601
    {
2602
      if (imm_expr.X_op != O_absent)
2603 160 khays
        append_insn (&insn, &imm_expr, imm_reloc, FALSE);
2604 16 khays
      else if (offset_expr.X_op != O_absent)
2605 160 khays
        append_insn (&insn, &offset_expr, offset_reloc, FALSE);
2606 16 khays
      else
2607 160 khays
        append_insn (&insn, NULL, unused_reloc, FALSE);
2608 16 khays
    }
2609
}
2610
 
2611
/* Convenience functions for abstracting away the differences between
2612
   MIPS16 and non-MIPS16 relocations.  */
2613
 
2614
static inline bfd_boolean
2615
mips16_reloc_p (bfd_reloc_code_real_type reloc)
2616
{
2617
  switch (reloc)
2618
    {
2619
    case BFD_RELOC_MIPS16_JMP:
2620
    case BFD_RELOC_MIPS16_GPREL:
2621
    case BFD_RELOC_MIPS16_GOT16:
2622
    case BFD_RELOC_MIPS16_CALL16:
2623
    case BFD_RELOC_MIPS16_HI16_S:
2624
    case BFD_RELOC_MIPS16_HI16:
2625
    case BFD_RELOC_MIPS16_LO16:
2626
      return TRUE;
2627
 
2628
    default:
2629
      return FALSE;
2630
    }
2631
}
2632
 
2633
static inline bfd_boolean
2634 160 khays
micromips_reloc_p (bfd_reloc_code_real_type reloc)
2635
{
2636
  switch (reloc)
2637
    {
2638
    case BFD_RELOC_MICROMIPS_7_PCREL_S1:
2639
    case BFD_RELOC_MICROMIPS_10_PCREL_S1:
2640
    case BFD_RELOC_MICROMIPS_16_PCREL_S1:
2641
    case BFD_RELOC_MICROMIPS_GPREL16:
2642
    case BFD_RELOC_MICROMIPS_JMP:
2643
    case BFD_RELOC_MICROMIPS_HI16:
2644
    case BFD_RELOC_MICROMIPS_HI16_S:
2645
    case BFD_RELOC_MICROMIPS_LO16:
2646
    case BFD_RELOC_MICROMIPS_LITERAL:
2647
    case BFD_RELOC_MICROMIPS_GOT16:
2648
    case BFD_RELOC_MICROMIPS_CALL16:
2649
    case BFD_RELOC_MICROMIPS_GOT_HI16:
2650
    case BFD_RELOC_MICROMIPS_GOT_LO16:
2651
    case BFD_RELOC_MICROMIPS_CALL_HI16:
2652
    case BFD_RELOC_MICROMIPS_CALL_LO16:
2653
    case BFD_RELOC_MICROMIPS_SUB:
2654
    case BFD_RELOC_MICROMIPS_GOT_PAGE:
2655
    case BFD_RELOC_MICROMIPS_GOT_OFST:
2656
    case BFD_RELOC_MICROMIPS_GOT_DISP:
2657
    case BFD_RELOC_MICROMIPS_HIGHEST:
2658
    case BFD_RELOC_MICROMIPS_HIGHER:
2659
    case BFD_RELOC_MICROMIPS_SCN_DISP:
2660
    case BFD_RELOC_MICROMIPS_JALR:
2661
      return TRUE;
2662
 
2663
    default:
2664
      return FALSE;
2665
    }
2666
}
2667
 
2668
static inline bfd_boolean
2669
jmp_reloc_p (bfd_reloc_code_real_type reloc)
2670
{
2671
  return reloc == BFD_RELOC_MIPS_JMP || reloc == BFD_RELOC_MICROMIPS_JMP;
2672
}
2673
 
2674
static inline bfd_boolean
2675 16 khays
got16_reloc_p (bfd_reloc_code_real_type reloc)
2676
{
2677 160 khays
  return (reloc == BFD_RELOC_MIPS_GOT16 || reloc == BFD_RELOC_MIPS16_GOT16
2678
          || reloc == BFD_RELOC_MICROMIPS_GOT16);
2679 16 khays
}
2680
 
2681
static inline bfd_boolean
2682
hi16_reloc_p (bfd_reloc_code_real_type reloc)
2683
{
2684 160 khays
  return (reloc == BFD_RELOC_HI16_S || reloc == BFD_RELOC_MIPS16_HI16_S
2685
          || reloc == BFD_RELOC_MICROMIPS_HI16_S);
2686 16 khays
}
2687
 
2688
static inline bfd_boolean
2689
lo16_reloc_p (bfd_reloc_code_real_type reloc)
2690
{
2691 160 khays
  return (reloc == BFD_RELOC_LO16 || reloc == BFD_RELOC_MIPS16_LO16
2692
          || reloc == BFD_RELOC_MICROMIPS_LO16);
2693 16 khays
}
2694
 
2695 160 khays
static inline bfd_boolean
2696
jalr_reloc_p (bfd_reloc_code_real_type reloc)
2697
{
2698
  return reloc == BFD_RELOC_MIPS_JALR || reloc == BFD_RELOC_MICROMIPS_JALR;
2699
}
2700
 
2701 16 khays
/* Return true if the given relocation might need a matching %lo().
2702
   This is only "might" because SVR4 R_MIPS_GOT16 relocations only
2703
   need a matching %lo() when applied to local symbols.  */
2704
 
2705
static inline bfd_boolean
2706
reloc_needs_lo_p (bfd_reloc_code_real_type reloc)
2707
{
2708
  return (HAVE_IN_PLACE_ADDENDS
2709
          && (hi16_reloc_p (reloc)
2710
              /* VxWorks R_MIPS_GOT16 relocs never need a matching %lo();
2711
                 all GOT16 relocations evaluate to "G".  */
2712
              || (got16_reloc_p (reloc) && mips_pic != VXWORKS_PIC)));
2713
}
2714
 
2715
/* Return the type of %lo() reloc needed by RELOC, given that
2716
   reloc_needs_lo_p.  */
2717
 
2718
static inline bfd_reloc_code_real_type
2719
matching_lo_reloc (bfd_reloc_code_real_type reloc)
2720
{
2721 160 khays
  return (mips16_reloc_p (reloc) ? BFD_RELOC_MIPS16_LO16
2722
          : (micromips_reloc_p (reloc) ? BFD_RELOC_MICROMIPS_LO16
2723
             : BFD_RELOC_LO16));
2724 16 khays
}
2725
 
2726
/* Return true if the given fixup is followed by a matching R_MIPS_LO16
2727
   relocation.  */
2728
 
2729
static inline bfd_boolean
2730
fixup_has_matching_lo_p (fixS *fixp)
2731
{
2732
  return (fixp->fx_next != NULL
2733
          && fixp->fx_next->fx_r_type == matching_lo_reloc (fixp->fx_r_type)
2734
          && fixp->fx_addsy == fixp->fx_next->fx_addsy
2735
          && fixp->fx_offset == fixp->fx_next->fx_offset);
2736
}
2737
 
2738
/* This function returns true if modifying a register requires a
2739
   delay.  */
2740
 
2741
static int
2742
reg_needs_delay (unsigned int reg)
2743
{
2744
  unsigned long prev_pinfo;
2745
 
2746
  prev_pinfo = history[0].insn_mo->pinfo;
2747
  if (! mips_opts.noreorder
2748
      && (((prev_pinfo & INSN_LOAD_MEMORY_DELAY)
2749
           && ! gpr_interlocks)
2750
          || ((prev_pinfo & INSN_LOAD_COPROC_DELAY)
2751
              && ! cop_interlocks)))
2752
    {
2753
      /* A load from a coprocessor or from memory.  All load delays
2754
         delay the use of general register rt for one instruction.  */
2755
      /* Itbl support may require additional care here.  */
2756
      know (prev_pinfo & INSN_WRITE_GPR_T);
2757 160 khays
      if (reg == EXTRACT_OPERAND (mips_opts.micromips, RT, history[0]))
2758 16 khays
        return 1;
2759
    }
2760
 
2761
  return 0;
2762
}
2763
 
2764 166 khays
/* Move all labels in LABELS to the current insertion point.  TEXT_P
2765
   says whether the labels refer to text or data.  */
2766 16 khays
 
2767
static void
2768 166 khays
mips_move_labels (struct insn_label_list *labels, bfd_boolean text_p)
2769 16 khays
{
2770
  struct insn_label_list *l;
2771
  valueT val;
2772
 
2773 166 khays
  for (l = labels; l != NULL; l = l->next)
2774 16 khays
    {
2775
      gas_assert (S_GET_SEGMENT (l->label) == now_seg);
2776
      symbol_set_frag (l->label, frag_now);
2777
      val = (valueT) frag_now_fix ();
2778 160 khays
      /* MIPS16/microMIPS text labels are stored as odd.  */
2779 166 khays
      if (text_p && HAVE_CODE_COMPRESSION)
2780 16 khays
        ++val;
2781
      S_SET_VALUE (l->label, val);
2782
    }
2783
}
2784
 
2785 166 khays
/* Move all labels in insn_labels to the current insertion point
2786
   and treat them as text labels.  */
2787
 
2788
static void
2789
mips_move_text_labels (void)
2790
{
2791
  mips_move_labels (seg_info (now_seg)->label_list, TRUE);
2792
}
2793
 
2794 16 khays
static bfd_boolean
2795
s_is_linkonce (symbolS *sym, segT from_seg)
2796
{
2797
  bfd_boolean linkonce = FALSE;
2798
  segT symseg = S_GET_SEGMENT (sym);
2799
 
2800
  if (symseg != from_seg && !S_IS_LOCAL (sym))
2801
    {
2802
      if ((bfd_get_section_flags (stdoutput, symseg) & SEC_LINK_ONCE))
2803
        linkonce = TRUE;
2804
#ifdef OBJ_ELF
2805
      /* The GNU toolchain uses an extension for ELF: a section
2806
         beginning with the magic string .gnu.linkonce is a
2807
         linkonce section.  */
2808
      if (strncmp (segment_name (symseg), ".gnu.linkonce",
2809
                   sizeof ".gnu.linkonce" - 1) == 0)
2810
        linkonce = TRUE;
2811
#endif
2812
    }
2813
  return linkonce;
2814
}
2815
 
2816 160 khays
/* Mark instruction labels in MIPS16/microMIPS mode.  This permits the
2817
   linker to handle them specially, such as generating jalx instructions
2818
   when needed.  We also make them odd for the duration of the assembly,
2819
   in order to generate the right sort of code.  We will make them even
2820 16 khays
   in the adjust_symtab routine, while leaving them marked.  This is
2821
   convenient for the debugger and the disassembler.  The linker knows
2822
   to make them odd again.  */
2823
 
2824
static void
2825 160 khays
mips_compressed_mark_labels (void)
2826 16 khays
{
2827
  segment_info_type *si = seg_info (now_seg);
2828
  struct insn_label_list *l;
2829
 
2830 160 khays
  gas_assert (HAVE_CODE_COMPRESSION);
2831 16 khays
 
2832
  for (l = si->label_list; l != NULL; l = l->next)
2833
   {
2834
      symbolS *label = l->label;
2835
 
2836
#if defined(OBJ_ELF) || defined(OBJ_MAYBE_ELF)
2837
      if (IS_ELF)
2838 160 khays
        {
2839
          if (mips_opts.mips16)
2840
            S_SET_OTHER (label, ELF_ST_SET_MIPS16 (S_GET_OTHER (label)));
2841
          else
2842
            S_SET_OTHER (label, ELF_ST_SET_MICROMIPS (S_GET_OTHER (label)));
2843
        }
2844 16 khays
#endif
2845
      if ((S_GET_VALUE (label) & 1) == 0
2846
        /* Don't adjust the address if the label is global or weak, or
2847
           in a link-once section, since we'll be emitting symbol reloc
2848
           references to it which will be patched up by the linker, and
2849 160 khays
           the final value of the symbol may or may not be MIPS16/microMIPS.  */
2850 16 khays
          && ! S_IS_WEAK (label)
2851
          && ! S_IS_EXTERNAL (label)
2852
          && ! s_is_linkonce (label, now_seg))
2853
        S_SET_VALUE (label, S_GET_VALUE (label) | 1);
2854
    }
2855
}
2856
 
2857
/* End the current frag.  Make it a variant frag and record the
2858
   relaxation info.  */
2859
 
2860
static void
2861
relax_close_frag (void)
2862
{
2863
  mips_macro_warning.first_frag = frag_now;
2864
  frag_var (rs_machine_dependent, 0, 0,
2865
            RELAX_ENCODE (mips_relax.sizes[0], mips_relax.sizes[1]),
2866
            mips_relax.symbol, 0, (char *) mips_relax.first_fixup);
2867
 
2868
  memset (&mips_relax.sizes, 0, sizeof (mips_relax.sizes));
2869
  mips_relax.first_fixup = 0;
2870
}
2871
 
2872
/* Start a new relaxation sequence whose expansion depends on SYMBOL.
2873
   See the comment above RELAX_ENCODE for more details.  */
2874
 
2875
static void
2876
relax_start (symbolS *symbol)
2877
{
2878
  gas_assert (mips_relax.sequence == 0);
2879
  mips_relax.sequence = 1;
2880
  mips_relax.symbol = symbol;
2881
}
2882
 
2883
/* Start generating the second version of a relaxable sequence.
2884
   See the comment above RELAX_ENCODE for more details.  */
2885
 
2886
static void
2887
relax_switch (void)
2888
{
2889
  gas_assert (mips_relax.sequence == 1);
2890
  mips_relax.sequence = 2;
2891
}
2892
 
2893
/* End the current relaxable sequence.  */
2894
 
2895
static void
2896
relax_end (void)
2897
{
2898
  gas_assert (mips_relax.sequence == 2);
2899
  relax_close_frag ();
2900
  mips_relax.sequence = 0;
2901
}
2902
 
2903 160 khays
/* Return true if IP is a delayed branch or jump.  */
2904
 
2905
static inline bfd_boolean
2906
delayed_branch_p (const struct mips_cl_insn *ip)
2907
{
2908
  return (ip->insn_mo->pinfo & (INSN_UNCOND_BRANCH_DELAY
2909
                                | INSN_COND_BRANCH_DELAY
2910
                                | INSN_COND_BRANCH_LIKELY)) != 0;
2911
}
2912
 
2913
/* Return true if IP is a compact branch or jump.  */
2914
 
2915
static inline bfd_boolean
2916
compact_branch_p (const struct mips_cl_insn *ip)
2917
{
2918
  if (mips_opts.mips16)
2919
    return (ip->insn_mo->pinfo & (MIPS16_INSN_UNCOND_BRANCH
2920
                                  | MIPS16_INSN_COND_BRANCH)) != 0;
2921
  else
2922
    return (ip->insn_mo->pinfo2 & (INSN2_UNCOND_BRANCH
2923
                                   | INSN2_COND_BRANCH)) != 0;
2924
}
2925
 
2926
/* Return true if IP is an unconditional branch or jump.  */
2927
 
2928
static inline bfd_boolean
2929
uncond_branch_p (const struct mips_cl_insn *ip)
2930
{
2931
  return ((ip->insn_mo->pinfo & INSN_UNCOND_BRANCH_DELAY) != 0
2932
          || (mips_opts.mips16
2933
              ? (ip->insn_mo->pinfo & MIPS16_INSN_UNCOND_BRANCH) != 0
2934
              : (ip->insn_mo->pinfo2 & INSN2_UNCOND_BRANCH) != 0));
2935
}
2936
 
2937
/* Return true if IP is a branch-likely instruction.  */
2938
 
2939
static inline bfd_boolean
2940
branch_likely_p (const struct mips_cl_insn *ip)
2941
{
2942
  return (ip->insn_mo->pinfo & INSN_COND_BRANCH_LIKELY) != 0;
2943
}
2944
 
2945
/* Return the type of nop that should be used to fill the delay slot
2946
   of delayed branch IP.  */
2947
 
2948
static struct mips_cl_insn *
2949
get_delay_slot_nop (const struct mips_cl_insn *ip)
2950
{
2951
  if (mips_opts.micromips
2952
      && (ip->insn_mo->pinfo2 & INSN2_BRANCH_DELAY_32BIT))
2953
    return &micromips_nop32_insn;
2954
  return NOP_INSN;
2955
}
2956
 
2957
/* Return the mask of core registers that IP reads or writes.  */
2958
 
2959
static unsigned int
2960
gpr_mod_mask (const struct mips_cl_insn *ip)
2961
{
2962
  unsigned long pinfo2;
2963
  unsigned int mask;
2964
 
2965
  mask = 0;
2966
  pinfo2 = ip->insn_mo->pinfo2;
2967
  if (mips_opts.micromips)
2968
    {
2969
      if (pinfo2 & INSN2_MOD_GPR_MD)
2970
        mask |= 1 << micromips_to_32_reg_d_map[EXTRACT_OPERAND (1, MD, *ip)];
2971
      if (pinfo2 & INSN2_MOD_GPR_MF)
2972
        mask |= 1 << micromips_to_32_reg_f_map[EXTRACT_OPERAND (1, MF, *ip)];
2973
      if (pinfo2 & INSN2_MOD_SP)
2974
        mask |= 1 << SP;
2975
    }
2976
  return mask;
2977
}
2978
 
2979
/* Return the mask of core registers that IP reads.  */
2980
 
2981
static unsigned int
2982
gpr_read_mask (const struct mips_cl_insn *ip)
2983
{
2984
  unsigned long pinfo, pinfo2;
2985
  unsigned int mask;
2986
 
2987
  mask = gpr_mod_mask (ip);
2988
  pinfo = ip->insn_mo->pinfo;
2989
  pinfo2 = ip->insn_mo->pinfo2;
2990
  if (mips_opts.mips16)
2991
    {
2992
      if (pinfo & MIPS16_INSN_READ_X)
2993
        mask |= 1 << mips16_to_32_reg_map[MIPS16_EXTRACT_OPERAND (RX, *ip)];
2994
      if (pinfo & MIPS16_INSN_READ_Y)
2995
        mask |= 1 << mips16_to_32_reg_map[MIPS16_EXTRACT_OPERAND (RY, *ip)];
2996
      if (pinfo & MIPS16_INSN_READ_T)
2997
        mask |= 1 << TREG;
2998
      if (pinfo & MIPS16_INSN_READ_SP)
2999
        mask |= 1 << SP;
3000
      if (pinfo & MIPS16_INSN_READ_31)
3001
        mask |= 1 << RA;
3002
      if (pinfo & MIPS16_INSN_READ_Z)
3003
        mask |= 1 << (mips16_to_32_reg_map
3004
                      [MIPS16_EXTRACT_OPERAND (MOVE32Z, *ip)]);
3005
      if (pinfo & MIPS16_INSN_READ_GPR_X)
3006
        mask |= 1 << MIPS16_EXTRACT_OPERAND (REGR32, *ip);
3007
    }
3008
  else
3009
    {
3010
      if (pinfo2 & INSN2_READ_GPR_D)
3011
        mask |= 1 << EXTRACT_OPERAND (mips_opts.micromips, RD, *ip);
3012
      if (pinfo & INSN_READ_GPR_T)
3013
        mask |= 1 << EXTRACT_OPERAND (mips_opts.micromips, RT, *ip);
3014
      if (pinfo & INSN_READ_GPR_S)
3015
        mask |= 1 << EXTRACT_OPERAND (mips_opts.micromips, RS, *ip);
3016
      if (pinfo2 & INSN2_READ_GP)
3017
        mask |= 1 << GP;
3018
      if (pinfo2 & INSN2_READ_GPR_31)
3019
        mask |= 1 << RA;
3020
      if (pinfo2 & INSN2_READ_GPR_Z)
3021
        mask |= 1 << EXTRACT_OPERAND (mips_opts.micromips, RZ, *ip);
3022
    }
3023
  if (mips_opts.micromips)
3024
    {
3025
      if (pinfo2 & INSN2_READ_GPR_MC)
3026
        mask |= 1 << micromips_to_32_reg_c_map[EXTRACT_OPERAND (1, MC, *ip)];
3027
      if (pinfo2 & INSN2_READ_GPR_ME)
3028
        mask |= 1 << micromips_to_32_reg_e_map[EXTRACT_OPERAND (1, ME, *ip)];
3029
      if (pinfo2 & INSN2_READ_GPR_MG)
3030
        mask |= 1 << micromips_to_32_reg_g_map[EXTRACT_OPERAND (1, MG, *ip)];
3031
      if (pinfo2 & INSN2_READ_GPR_MJ)
3032
        mask |= 1 << EXTRACT_OPERAND (1, MJ, *ip);
3033
      if (pinfo2 & INSN2_READ_GPR_MMN)
3034
        {
3035
          mask |= 1 << micromips_to_32_reg_m_map[EXTRACT_OPERAND (1, MM, *ip)];
3036
          mask |= 1 << micromips_to_32_reg_n_map[EXTRACT_OPERAND (1, MN, *ip)];
3037
        }
3038
      if (pinfo2 & INSN2_READ_GPR_MP)
3039
        mask |= 1 << EXTRACT_OPERAND (1, MP, *ip);
3040
      if (pinfo2 & INSN2_READ_GPR_MQ)
3041
        mask |= 1 << micromips_to_32_reg_q_map[EXTRACT_OPERAND (1, MQ, *ip)];
3042
    }
3043
  /* Don't include register 0.  */
3044
  return mask & ~1;
3045
}
3046
 
3047
/* Return the mask of core registers that IP writes.  */
3048
 
3049
static unsigned int
3050
gpr_write_mask (const struct mips_cl_insn *ip)
3051
{
3052
  unsigned long pinfo, pinfo2;
3053
  unsigned int mask;
3054
 
3055
  mask = gpr_mod_mask (ip);
3056
  pinfo = ip->insn_mo->pinfo;
3057
  pinfo2 = ip->insn_mo->pinfo2;
3058
  if (mips_opts.mips16)
3059
    {
3060
      if (pinfo & MIPS16_INSN_WRITE_X)
3061
        mask |= 1 << mips16_to_32_reg_map[MIPS16_EXTRACT_OPERAND (RX, *ip)];
3062
      if (pinfo & MIPS16_INSN_WRITE_Y)
3063
        mask |= 1 << mips16_to_32_reg_map[MIPS16_EXTRACT_OPERAND (RY, *ip)];
3064
      if (pinfo & MIPS16_INSN_WRITE_Z)
3065
        mask |= 1 << mips16_to_32_reg_map[MIPS16_EXTRACT_OPERAND (RZ, *ip)];
3066
      if (pinfo & MIPS16_INSN_WRITE_T)
3067
        mask |= 1 << TREG;
3068
      if (pinfo & MIPS16_INSN_WRITE_SP)
3069
        mask |= 1 << SP;
3070
      if (pinfo & MIPS16_INSN_WRITE_31)
3071
        mask |= 1 << RA;
3072
      if (pinfo & MIPS16_INSN_WRITE_GPR_Y)
3073
        mask |= 1 << MIPS16OP_EXTRACT_REG32R (ip->insn_opcode);
3074
    }
3075
  else
3076
    {
3077
      if (pinfo & INSN_WRITE_GPR_D)
3078
        mask |= 1 << EXTRACT_OPERAND (mips_opts.micromips, RD, *ip);
3079
      if (pinfo & INSN_WRITE_GPR_T)
3080
        mask |= 1 << EXTRACT_OPERAND (mips_opts.micromips, RT, *ip);
3081
      if (pinfo & INSN_WRITE_GPR_S)
3082
        mask |= 1 << EXTRACT_OPERAND (mips_opts.micromips, RS, *ip);
3083
      if (pinfo & INSN_WRITE_GPR_31)
3084
        mask |= 1 << RA;
3085
      if (pinfo2 & INSN2_WRITE_GPR_Z)
3086
        mask |= 1 << EXTRACT_OPERAND (mips_opts.micromips, RZ, *ip);
3087
    }
3088
  if (mips_opts.micromips)
3089
    {
3090
      if (pinfo2 & INSN2_WRITE_GPR_MB)
3091
        mask |= 1 << micromips_to_32_reg_b_map[EXTRACT_OPERAND (1, MB, *ip)];
3092
      if (pinfo2 & INSN2_WRITE_GPR_MHI)
3093
        {
3094
          mask |= 1 << micromips_to_32_reg_h_map[EXTRACT_OPERAND (1, MH, *ip)];
3095
          mask |= 1 << micromips_to_32_reg_i_map[EXTRACT_OPERAND (1, MI, *ip)];
3096
        }
3097
      if (pinfo2 & INSN2_WRITE_GPR_MJ)
3098
        mask |= 1 << EXTRACT_OPERAND (1, MJ, *ip);
3099
      if (pinfo2 & INSN2_WRITE_GPR_MP)
3100
        mask |= 1 << EXTRACT_OPERAND (1, MP, *ip);
3101
    }
3102
  /* Don't include register 0.  */
3103
  return mask & ~1;
3104
}
3105
 
3106
/* Return the mask of floating-point registers that IP reads.  */
3107
 
3108
static unsigned int
3109
fpr_read_mask (const struct mips_cl_insn *ip)
3110
{
3111
  unsigned long pinfo, pinfo2;
3112
  unsigned int mask;
3113
 
3114
  mask = 0;
3115
  pinfo = ip->insn_mo->pinfo;
3116
  pinfo2 = ip->insn_mo->pinfo2;
3117
  if (!mips_opts.mips16)
3118
    {
3119
      if (pinfo2 & INSN2_READ_FPR_D)
3120
        mask |= 1 << EXTRACT_OPERAND (mips_opts.micromips, FD, *ip);
3121
      if (pinfo & INSN_READ_FPR_S)
3122
        mask |= 1 << EXTRACT_OPERAND (mips_opts.micromips, FS, *ip);
3123
      if (pinfo & INSN_READ_FPR_T)
3124
        mask |= 1 << EXTRACT_OPERAND (mips_opts.micromips, FT, *ip);
3125
      if (pinfo & INSN_READ_FPR_R)
3126
        mask |= 1 << EXTRACT_OPERAND (mips_opts.micromips, FR, *ip);
3127
      if (pinfo2 & INSN2_READ_FPR_Z)
3128
        mask |= 1 << EXTRACT_OPERAND (mips_opts.micromips, FZ, *ip);
3129
    }
3130
  /* Conservatively treat all operands to an FP_D instruction are doubles.
3131
     (This is overly pessimistic for things like cvt.d.s.)  */
3132
  if (HAVE_32BIT_FPRS && (pinfo & FP_D))
3133
    mask |= mask << 1;
3134
  return mask;
3135
}
3136
 
3137
/* Return the mask of floating-point registers that IP writes.  */
3138
 
3139
static unsigned int
3140
fpr_write_mask (const struct mips_cl_insn *ip)
3141
{
3142
  unsigned long pinfo, pinfo2;
3143
  unsigned int mask;
3144
 
3145
  mask = 0;
3146
  pinfo = ip->insn_mo->pinfo;
3147
  pinfo2 = ip->insn_mo->pinfo2;
3148
  if (!mips_opts.mips16)
3149
    {
3150
      if (pinfo & INSN_WRITE_FPR_D)
3151
        mask |= 1 << EXTRACT_OPERAND (mips_opts.micromips, FD, *ip);
3152
      if (pinfo & INSN_WRITE_FPR_S)
3153
        mask |= 1 << EXTRACT_OPERAND (mips_opts.micromips, FS, *ip);
3154
      if (pinfo & INSN_WRITE_FPR_T)
3155
        mask |= 1 << EXTRACT_OPERAND (mips_opts.micromips, FT, *ip);
3156
      if (pinfo2 & INSN2_WRITE_FPR_Z)
3157
        mask |= 1 << EXTRACT_OPERAND (mips_opts.micromips, FZ, *ip);
3158
    }
3159
  /* Conservatively treat all operands to an FP_D instruction are doubles.
3160
     (This is overly pessimistic for things like cvt.s.d.)  */
3161
  if (HAVE_32BIT_FPRS && (pinfo & FP_D))
3162
    mask |= mask << 1;
3163
  return mask;
3164
}
3165
 
3166 16 khays
/* Classify an instruction according to the FIX_VR4120_* enumeration.
3167
   Return NUM_FIX_VR4120_CLASSES if the instruction isn't affected
3168
   by VR4120 errata.  */
3169
 
3170
static unsigned int
3171
classify_vr4120_insn (const char *name)
3172
{
3173
  if (strncmp (name, "macc", 4) == 0)
3174
    return FIX_VR4120_MACC;
3175
  if (strncmp (name, "dmacc", 5) == 0)
3176
    return FIX_VR4120_DMACC;
3177
  if (strncmp (name, "mult", 4) == 0)
3178
    return FIX_VR4120_MULT;
3179
  if (strncmp (name, "dmult", 5) == 0)
3180
    return FIX_VR4120_DMULT;
3181
  if (strstr (name, "div"))
3182
    return FIX_VR4120_DIV;
3183
  if (strcmp (name, "mtlo") == 0 || strcmp (name, "mthi") == 0)
3184
    return FIX_VR4120_MTHILO;
3185
  return NUM_FIX_VR4120_CLASSES;
3186
}
3187
 
3188
#define INSN_ERET  0x42000018
3189
#define INSN_DERET 0x4200001f
3190
 
3191
/* Return the number of instructions that must separate INSN1 and INSN2,
3192
   where INSN1 is the earlier instruction.  Return the worst-case value
3193
   for any INSN2 if INSN2 is null.  */
3194
 
3195
static unsigned int
3196
insns_between (const struct mips_cl_insn *insn1,
3197
               const struct mips_cl_insn *insn2)
3198
{
3199
  unsigned long pinfo1, pinfo2;
3200 160 khays
  unsigned int mask;
3201 16 khays
 
3202
  /* This function needs to know which pinfo flags are set for INSN2
3203
     and which registers INSN2 uses.  The former is stored in PINFO2 and
3204 160 khays
     the latter is tested via INSN2_USES_GPR.  If INSN2 is null, PINFO2
3205
     will have every flag set and INSN2_USES_GPR will always return true.  */
3206 16 khays
  pinfo1 = insn1->insn_mo->pinfo;
3207
  pinfo2 = insn2 ? insn2->insn_mo->pinfo : ~0U;
3208
 
3209 160 khays
#define INSN2_USES_GPR(REG) \
3210
  (insn2 == NULL || (gpr_read_mask (insn2) & (1U << (REG))) != 0)
3211 16 khays
 
3212
  /* For most targets, write-after-read dependencies on the HI and LO
3213
     registers must be separated by at least two instructions.  */
3214
  if (!hilo_interlocks)
3215
    {
3216
      if ((pinfo1 & INSN_READ_LO) && (pinfo2 & INSN_WRITE_LO))
3217
        return 2;
3218
      if ((pinfo1 & INSN_READ_HI) && (pinfo2 & INSN_WRITE_HI))
3219
        return 2;
3220
    }
3221
 
3222
  /* If we're working around r7000 errata, there must be two instructions
3223
     between an mfhi or mflo and any instruction that uses the result.  */
3224
  if (mips_7000_hilo_fix
3225 160 khays
      && !mips_opts.micromips
3226 16 khays
      && MF_HILO_INSN (pinfo1)
3227 160 khays
      && INSN2_USES_GPR (EXTRACT_OPERAND (0, RD, *insn1)))
3228 16 khays
    return 2;
3229
 
3230
  /* If we're working around 24K errata, one instruction is required
3231
     if an ERET or DERET is followed by a branch instruction.  */
3232 160 khays
  if (mips_fix_24k && !mips_opts.micromips)
3233 16 khays
    {
3234
      if (insn1->insn_opcode == INSN_ERET
3235
          || insn1->insn_opcode == INSN_DERET)
3236
        {
3237
          if (insn2 == NULL
3238
              || insn2->insn_opcode == INSN_ERET
3239
              || insn2->insn_opcode == INSN_DERET
3240 160 khays
              || delayed_branch_p (insn2))
3241 16 khays
            return 1;
3242
        }
3243
    }
3244
 
3245
  /* If working around VR4120 errata, check for combinations that need
3246
     a single intervening instruction.  */
3247 160 khays
  if (mips_fix_vr4120 && !mips_opts.micromips)
3248 16 khays
    {
3249
      unsigned int class1, class2;
3250
 
3251
      class1 = classify_vr4120_insn (insn1->insn_mo->name);
3252
      if (class1 != NUM_FIX_VR4120_CLASSES && vr4120_conflicts[class1] != 0)
3253
        {
3254
          if (insn2 == NULL)
3255
            return 1;
3256
          class2 = classify_vr4120_insn (insn2->insn_mo->name);
3257
          if (vr4120_conflicts[class1] & (1 << class2))
3258
            return 1;
3259
        }
3260
    }
3261
 
3262 160 khays
  if (!HAVE_CODE_COMPRESSION)
3263 16 khays
    {
3264
      /* Check for GPR or coprocessor load delays.  All such delays
3265
         are on the RT register.  */
3266
      /* Itbl support may require additional care here.  */
3267
      if ((!gpr_interlocks && (pinfo1 & INSN_LOAD_MEMORY_DELAY))
3268
          || (!cop_interlocks && (pinfo1 & INSN_LOAD_COPROC_DELAY)))
3269
        {
3270
          know (pinfo1 & INSN_WRITE_GPR_T);
3271 160 khays
          if (INSN2_USES_GPR (EXTRACT_OPERAND (0, RT, *insn1)))
3272 16 khays
            return 1;
3273
        }
3274
 
3275
      /* Check for generic coprocessor hazards.
3276
 
3277
         This case is not handled very well.  There is no special
3278
         knowledge of CP0 handling, and the coprocessors other than
3279
         the floating point unit are not distinguished at all.  */
3280
      /* Itbl support may require additional care here. FIXME!
3281
         Need to modify this to include knowledge about
3282
         user specified delays!  */
3283
      else if ((!cop_interlocks && (pinfo1 & INSN_COPROC_MOVE_DELAY))
3284
               || (!cop_mem_interlocks && (pinfo1 & INSN_COPROC_MEMORY_DELAY)))
3285
        {
3286
          /* Handle cases where INSN1 writes to a known general coprocessor
3287
             register.  There must be a one instruction delay before INSN2
3288
             if INSN2 reads that register, otherwise no delay is needed.  */
3289 160 khays
          mask = fpr_write_mask (insn1);
3290
          if (mask != 0)
3291 16 khays
            {
3292 160 khays
              if (!insn2 || (mask & fpr_read_mask (insn2)) != 0)
3293 16 khays
                return 1;
3294
            }
3295
          else
3296
            {
3297
              /* Read-after-write dependencies on the control registers
3298
                 require a two-instruction gap.  */
3299
              if ((pinfo1 & INSN_WRITE_COND_CODE)
3300
                  && (pinfo2 & INSN_READ_COND_CODE))
3301
                return 2;
3302
 
3303
              /* We don't know exactly what INSN1 does.  If INSN2 is
3304
                 also a coprocessor instruction, assume there must be
3305
                 a one instruction gap.  */
3306
              if (pinfo2 & INSN_COP)
3307
                return 1;
3308
            }
3309
        }
3310
 
3311
      /* Check for read-after-write dependencies on the coprocessor
3312
         control registers in cases where INSN1 does not need a general
3313
         coprocessor delay.  This means that INSN1 is a floating point
3314
         comparison instruction.  */
3315
      /* Itbl support may require additional care here.  */
3316
      else if (!cop_interlocks
3317
               && (pinfo1 & INSN_WRITE_COND_CODE)
3318
               && (pinfo2 & INSN_READ_COND_CODE))
3319
        return 1;
3320
    }
3321
 
3322 160 khays
#undef INSN2_USES_GPR
3323 16 khays
 
3324
  return 0;
3325
}
3326
 
3327
/* Return the number of nops that would be needed to work around the
3328
   VR4130 mflo/mfhi errata if instruction INSN immediately followed
3329 160 khays
   the MAX_VR4130_NOPS instructions described by HIST.  Ignore hazards
3330
   that are contained within the first IGNORE instructions of HIST.  */
3331 16 khays
 
3332
static int
3333 160 khays
nops_for_vr4130 (int ignore, const struct mips_cl_insn *hist,
3334 16 khays
                 const struct mips_cl_insn *insn)
3335
{
3336 160 khays
  int i, j;
3337
  unsigned int mask;
3338 16 khays
 
3339
  /* Check if the instruction writes to HI or LO.  MTHI and MTLO
3340
     are not affected by the errata.  */
3341
  if (insn != 0
3342
      && ((insn->insn_mo->pinfo & (INSN_WRITE_HI | INSN_WRITE_LO)) == 0
3343
          || strcmp (insn->insn_mo->name, "mtlo") == 0
3344
          || strcmp (insn->insn_mo->name, "mthi") == 0))
3345
    return 0;
3346
 
3347
  /* Search for the first MFLO or MFHI.  */
3348
  for (i = 0; i < MAX_VR4130_NOPS; i++)
3349
    if (MF_HILO_INSN (hist[i].insn_mo->pinfo))
3350
      {
3351
        /* Extract the destination register.  */
3352 160 khays
        mask = gpr_write_mask (&hist[i]);
3353 16 khays
 
3354
        /* No nops are needed if INSN reads that register.  */
3355 160 khays
        if (insn != NULL && (gpr_read_mask (insn) & mask) != 0)
3356 16 khays
          return 0;
3357
 
3358
        /* ...or if any of the intervening instructions do.  */
3359
        for (j = 0; j < i; j++)
3360 160 khays
          if (gpr_read_mask (&hist[j]) & mask)
3361 16 khays
            return 0;
3362
 
3363 160 khays
        if (i >= ignore)
3364
          return MAX_VR4130_NOPS - i;
3365 16 khays
      }
3366
  return 0;
3367
}
3368
 
3369
#define BASE_REG_EQ(INSN1, INSN2)       \
3370
  ((((INSN1) >> OP_SH_RS) & OP_MASK_RS) \
3371
      == (((INSN2) >> OP_SH_RS) & OP_MASK_RS))
3372
 
3373
/* Return the minimum alignment for this store instruction.  */
3374
 
3375
static int
3376
fix_24k_align_to (const struct mips_opcode *mo)
3377
{
3378
  if (strcmp (mo->name, "sh") == 0)
3379
    return 2;
3380
 
3381
  if (strcmp (mo->name, "swc1") == 0
3382
      || strcmp (mo->name, "swc2") == 0
3383
      || strcmp (mo->name, "sw") == 0
3384
      || strcmp (mo->name, "sc") == 0
3385
      || strcmp (mo->name, "s.s") == 0)
3386
    return 4;
3387
 
3388
  if (strcmp (mo->name, "sdc1") == 0
3389
      || strcmp (mo->name, "sdc2") == 0
3390
      || strcmp (mo->name, "s.d") == 0)
3391
    return 8;
3392
 
3393
  /* sb, swl, swr */
3394
  return 1;
3395
}
3396
 
3397
struct fix_24k_store_info
3398
  {
3399
    /* Immediate offset, if any, for this store instruction.  */
3400
    short off;
3401
    /* Alignment required by this store instruction.  */
3402
    int align_to;
3403
    /* True for register offsets.  */
3404
    int register_offset;
3405
  };
3406
 
3407
/* Comparison function used by qsort.  */
3408
 
3409
static int
3410
fix_24k_sort (const void *a, const void *b)
3411
{
3412
  const struct fix_24k_store_info *pos1 = a;
3413
  const struct fix_24k_store_info *pos2 = b;
3414
 
3415
  return (pos1->off - pos2->off);
3416
}
3417
 
3418
/* INSN is a store instruction.  Try to record the store information
3419
   in STINFO.  Return false if the information isn't known.  */
3420
 
3421
static bfd_boolean
3422
fix_24k_record_store_info (struct fix_24k_store_info *stinfo,
3423 160 khays
                           const struct mips_cl_insn *insn)
3424 16 khays
{
3425
  /* The instruction must have a known offset.  */
3426
  if (!insn->complete_p || !strstr (insn->insn_mo->args, "o("))
3427
    return FALSE;
3428
 
3429
  stinfo->off = (insn->insn_opcode >> OP_SH_IMMEDIATE) & OP_MASK_IMMEDIATE;
3430
  stinfo->align_to = fix_24k_align_to (insn->insn_mo);
3431
  return TRUE;
3432
}
3433
 
3434 160 khays
/* Return the number of nops that would be needed to work around the 24k
3435
   "lost data on stores during refill" errata if instruction INSN
3436
   immediately followed the 2 instructions described by HIST.
3437
   Ignore hazards that are contained within the first IGNORE
3438
   instructions of HIST.
3439 16 khays
 
3440 160 khays
   Problem: The FSB (fetch store buffer) acts as an intermediate buffer
3441
   for the data cache refills and store data. The following describes
3442
   the scenario where the store data could be lost.
3443
 
3444
   * A data cache miss, due to either a load or a store, causing fill
3445
     data to be supplied by the memory subsystem
3446
   * The first three doublewords of fill data are returned and written
3447
     into the cache
3448
   * A sequence of four stores occurs in consecutive cycles around the
3449
     final doubleword of the fill:
3450
   * Store A
3451
   * Store B
3452
   * Store C
3453
   * Zero, One or more instructions
3454
   * Store D
3455
 
3456
   The four stores A-D must be to different doublewords of the line that
3457
   is being filled. The fourth instruction in the sequence above permits
3458
   the fill of the final doubleword to be transferred from the FSB into
3459
   the cache. In the sequence above, the stores may be either integer
3460
   (sb, sh, sw, swr, swl, sc) or coprocessor (swc1/swc2, sdc1/sdc2,
3461
   swxc1, sdxc1, suxc1) stores, as long as the four stores are to
3462
   different doublewords on the line. If the floating point unit is
3463
   running in 1:2 mode, it is not possible to create the sequence above
3464
   using only floating point store instructions.
3465
 
3466 16 khays
   In this case, the cache line being filled is incorrectly marked
3467
   invalid, thereby losing the data from any store to the line that
3468
   occurs between the original miss and the completion of the five
3469
   cycle sequence shown above.
3470
 
3471 160 khays
   The workarounds are:
3472 16 khays
 
3473 160 khays
   * Run the data cache in write-through mode.
3474
   * Insert a non-store instruction between
3475
     Store A and Store B or Store B and Store C.  */
3476 16 khays
 
3477
static int
3478 160 khays
nops_for_24k (int ignore, const struct mips_cl_insn *hist,
3479 16 khays
              const struct mips_cl_insn *insn)
3480
{
3481
  struct fix_24k_store_info pos[3];
3482
  int align, i, base_offset;
3483
 
3484 160 khays
  if (ignore >= 2)
3485 16 khays
    return 0;
3486
 
3487 160 khays
  /* If the previous instruction wasn't a store, there's nothing to
3488
     worry about.  */
3489 16 khays
  if ((hist[0].insn_mo->pinfo & INSN_STORE_MEMORY) == 0)
3490
    return 0;
3491
 
3492 160 khays
  /* If the instructions after the previous one are unknown, we have
3493
     to assume the worst.  */
3494
  if (!insn)
3495 16 khays
    return 1;
3496
 
3497 160 khays
  /* Check whether we are dealing with three consecutive stores.  */
3498
  if ((insn->insn_mo->pinfo & INSN_STORE_MEMORY) == 0
3499
      || (hist[1].insn_mo->pinfo & INSN_STORE_MEMORY) == 0)
3500 16 khays
    return 0;
3501
 
3502
  /* If we don't know the relationship between the store addresses,
3503
     assume the worst.  */
3504 160 khays
  if (!BASE_REG_EQ (insn->insn_opcode, hist[0].insn_opcode)
3505 16 khays
      || !BASE_REG_EQ (insn->insn_opcode, hist[1].insn_opcode))
3506
    return 1;
3507
 
3508
  if (!fix_24k_record_store_info (&pos[0], insn)
3509
      || !fix_24k_record_store_info (&pos[1], &hist[0])
3510
      || !fix_24k_record_store_info (&pos[2], &hist[1]))
3511
    return 1;
3512
 
3513
  qsort (&pos, 3, sizeof (struct fix_24k_store_info), fix_24k_sort);
3514
 
3515
  /* Pick a value of ALIGN and X such that all offsets are adjusted by
3516
     X bytes and such that the base register + X is known to be aligned
3517
     to align bytes.  */
3518
 
3519
  if (((insn->insn_opcode >> OP_SH_RS) & OP_MASK_RS) == SP)
3520
    align = 8;
3521
  else
3522
    {
3523
      align = pos[0].align_to;
3524
      base_offset = pos[0].off;
3525
      for (i = 1; i < 3; i++)
3526
        if (align < pos[i].align_to)
3527
          {
3528
            align = pos[i].align_to;
3529
            base_offset = pos[i].off;
3530
          }
3531
      for (i = 0; i < 3; i++)
3532
        pos[i].off -= base_offset;
3533
    }
3534
 
3535
  pos[0].off &= ~align + 1;
3536
  pos[1].off &= ~align + 1;
3537
  pos[2].off &= ~align + 1;
3538
 
3539
  /* If any two stores write to the same chunk, they also write to the
3540
     same doubleword.  The offsets are still sorted at this point.  */
3541
  if (pos[0].off == pos[1].off || pos[1].off == pos[2].off)
3542
    return 0;
3543
 
3544
  /* A range of at least 9 bytes is needed for the stores to be in
3545
     non-overlapping doublewords.  */
3546
  if (pos[2].off - pos[0].off <= 8)
3547
    return 0;
3548
 
3549
  if (pos[2].off - pos[1].off >= 24
3550
      || pos[1].off - pos[0].off >= 24
3551
      || pos[2].off - pos[0].off >= 32)
3552
    return 0;
3553
 
3554
  return 1;
3555
}
3556
 
3557
/* Return the number of nops that would be needed if instruction INSN
3558
   immediately followed the MAX_NOPS instructions given by HIST,
3559 160 khays
   where HIST[0] is the most recent instruction.  Ignore hazards
3560
   between INSN and the first IGNORE instructions in HIST.
3561 16 khays
 
3562 160 khays
   If INSN is null, return the worse-case number of nops for any
3563
   instruction.  */
3564
 
3565 16 khays
static int
3566 160 khays
nops_for_insn (int ignore, const struct mips_cl_insn *hist,
3567 16 khays
               const struct mips_cl_insn *insn)
3568
{
3569
  int i, nops, tmp_nops;
3570
 
3571
  nops = 0;
3572 160 khays
  for (i = ignore; i < MAX_DELAY_NOPS; i++)
3573 16 khays
    {
3574
      tmp_nops = insns_between (hist + i, insn) - i;
3575
      if (tmp_nops > nops)
3576
        nops = tmp_nops;
3577
    }
3578
 
3579 160 khays
  if (mips_fix_vr4130 && !mips_opts.micromips)
3580 16 khays
    {
3581 160 khays
      tmp_nops = nops_for_vr4130 (ignore, hist, insn);
3582 16 khays
      if (tmp_nops > nops)
3583
        nops = tmp_nops;
3584
    }
3585
 
3586 160 khays
  if (mips_fix_24k && !mips_opts.micromips)
3587 16 khays
    {
3588 160 khays
      tmp_nops = nops_for_24k (ignore, hist, insn);
3589 16 khays
      if (tmp_nops > nops)
3590
        nops = tmp_nops;
3591
    }
3592
 
3593
  return nops;
3594
}
3595
 
3596
/* The variable arguments provide NUM_INSNS extra instructions that
3597
   might be added to HIST.  Return the largest number of nops that
3598 160 khays
   would be needed after the extended sequence, ignoring hazards
3599
   in the first IGNORE instructions.  */
3600 16 khays
 
3601
static int
3602 160 khays
nops_for_sequence (int num_insns, int ignore,
3603
                   const struct mips_cl_insn *hist, ...)
3604 16 khays
{
3605
  va_list args;
3606
  struct mips_cl_insn buffer[MAX_NOPS];
3607
  struct mips_cl_insn *cursor;
3608
  int nops;
3609
 
3610
  va_start (args, hist);
3611
  cursor = buffer + num_insns;
3612
  memcpy (cursor, hist, (MAX_NOPS - num_insns) * sizeof (*cursor));
3613
  while (cursor > buffer)
3614
    *--cursor = *va_arg (args, const struct mips_cl_insn *);
3615
 
3616 160 khays
  nops = nops_for_insn (ignore, buffer, NULL);
3617 16 khays
  va_end (args);
3618
  return nops;
3619
}
3620
 
3621
/* Like nops_for_insn, but if INSN is a branch, take into account the
3622
   worst-case delay for the branch target.  */
3623
 
3624
static int
3625 160 khays
nops_for_insn_or_target (int ignore, const struct mips_cl_insn *hist,
3626 16 khays
                         const struct mips_cl_insn *insn)
3627
{
3628
  int nops, tmp_nops;
3629
 
3630 160 khays
  nops = nops_for_insn (ignore, hist, insn);
3631
  if (delayed_branch_p (insn))
3632 16 khays
    {
3633 160 khays
      tmp_nops = nops_for_sequence (2, ignore ? ignore + 2 : 0,
3634
                                    hist, insn, get_delay_slot_nop (insn));
3635 16 khays
      if (tmp_nops > nops)
3636
        nops = tmp_nops;
3637
    }
3638 160 khays
  else if (compact_branch_p (insn))
3639 16 khays
    {
3640 160 khays
      tmp_nops = nops_for_sequence (1, ignore ? ignore + 1 : 0, hist, insn);
3641 16 khays
      if (tmp_nops > nops)
3642
        nops = tmp_nops;
3643
    }
3644
  return nops;
3645
}
3646
 
3647
/* Fix NOP issue: Replace nops by "or at,at,zero".  */
3648
 
3649
static void
3650
fix_loongson2f_nop (struct mips_cl_insn * ip)
3651
{
3652 160 khays
  gas_assert (!HAVE_CODE_COMPRESSION);
3653 16 khays
  if (strcmp (ip->insn_mo->name, "nop") == 0)
3654
    ip->insn_opcode = LOONGSON2F_NOP_INSN;
3655
}
3656
 
3657
/* Fix Jump Issue: Eliminate instruction fetch from outside 256M region
3658
                   jr target pc &= 'hffff_ffff_cfff_ffff.  */
3659
 
3660
static void
3661
fix_loongson2f_jump (struct mips_cl_insn * ip)
3662
{
3663 160 khays
  gas_assert (!HAVE_CODE_COMPRESSION);
3664 16 khays
  if (strcmp (ip->insn_mo->name, "j") == 0
3665
      || strcmp (ip->insn_mo->name, "jr") == 0
3666
      || strcmp (ip->insn_mo->name, "jalr") == 0)
3667
    {
3668
      int sreg;
3669
      expressionS ep;
3670
 
3671
      if (! mips_opts.at)
3672
        return;
3673
 
3674 160 khays
      sreg = EXTRACT_OPERAND (0, RS, *ip);
3675 16 khays
      if (sreg == ZERO || sreg == KT0 || sreg == KT1 || sreg == ATREG)
3676
        return;
3677
 
3678
      ep.X_op = O_constant;
3679
      ep.X_add_number = 0xcfff0000;
3680
      macro_build (&ep, "lui", "t,u", ATREG, BFD_RELOC_HI16);
3681
      ep.X_add_number = 0xffff;
3682
      macro_build (&ep, "ori", "t,r,i", ATREG, ATREG, BFD_RELOC_LO16);
3683
      macro_build (NULL, "and", "d,v,t", sreg, sreg, ATREG);
3684
    }
3685
}
3686
 
3687
static void
3688
fix_loongson2f (struct mips_cl_insn * ip)
3689
{
3690
  if (mips_fix_loongson2f_nop)
3691
    fix_loongson2f_nop (ip);
3692
 
3693
  if (mips_fix_loongson2f_jump)
3694
    fix_loongson2f_jump (ip);
3695
}
3696
 
3697 160 khays
/* IP is a branch that has a delay slot, and we need to fill it
3698
   automatically.   Return true if we can do that by swapping IP
3699
   with the previous instruction.  */
3700
 
3701
static bfd_boolean
3702
can_swap_branch_p (struct mips_cl_insn *ip)
3703
{
3704
  unsigned long pinfo, pinfo2, prev_pinfo, prev_pinfo2;
3705
  unsigned int gpr_read, gpr_write, prev_gpr_read, prev_gpr_write;
3706
 
3707
  /* -O2 and above is required for this optimization.  */
3708
  if (mips_optimize < 2)
3709
    return FALSE;
3710
 
3711
  /* If we have seen .set volatile or .set nomove, don't optimize.  */
3712
  if (mips_opts.nomove)
3713
    return FALSE;
3714
 
3715
  /* We can't swap if the previous instruction's position is fixed.  */
3716
  if (history[0].fixed_p)
3717
    return FALSE;
3718
 
3719
  /* If the previous previous insn was in a .set noreorder, we can't
3720
     swap.  Actually, the MIPS assembler will swap in this situation.
3721
     However, gcc configured -with-gnu-as will generate code like
3722
 
3723
        .set    noreorder
3724
        lw      $4,XXX
3725
        .set    reorder
3726
        INSN
3727
        bne     $4,$0,foo
3728
 
3729
     in which we can not swap the bne and INSN.  If gcc is not configured
3730
     -with-gnu-as, it does not output the .set pseudo-ops.  */
3731
  if (history[1].noreorder_p)
3732
    return FALSE;
3733
 
3734
  /* If the previous instruction had a fixup in mips16 mode, we can not swap.
3735
     This means that the previous instruction was a 4-byte one anyhow.  */
3736
  if (mips_opts.mips16 && history[0].fixp[0])
3737
    return FALSE;
3738
 
3739
  /* If the branch is itself the target of a branch, we can not swap.
3740
     We cheat on this; all we check for is whether there is a label on
3741
     this instruction.  If there are any branches to anything other than
3742
     a label, users must use .set noreorder.  */
3743
  if (seg_info (now_seg)->label_list)
3744
    return FALSE;
3745
 
3746
  /* If the previous instruction is in a variant frag other than this
3747
     branch's one, we cannot do the swap.  This does not apply to
3748 163 khays
     MIPS16 code, which uses variant frags for different purposes.  */
3749
  if (!mips_opts.mips16
3750 160 khays
      && history[0].frag
3751
      && history[0].frag->fr_type == rs_machine_dependent)
3752
    return FALSE;
3753
 
3754
  /* We do not swap with instructions that cannot architecturally
3755
     be placed in a branch delay slot, such as SYNC or ERET.  We
3756
     also refrain from swapping with a trap instruction, since it
3757
     complicates trap handlers to have the trap instruction be in
3758
     a delay slot.  */
3759
  prev_pinfo = history[0].insn_mo->pinfo;
3760
  if (prev_pinfo & INSN_NO_DELAY_SLOT)
3761
    return FALSE;
3762
 
3763
  /* Check for conflicts between the branch and the instructions
3764
     before the candidate delay slot.  */
3765
  if (nops_for_insn (0, history + 1, ip) > 0)
3766
    return FALSE;
3767
 
3768
  /* Check for conflicts between the swapped sequence and the
3769
     target of the branch.  */
3770
  if (nops_for_sequence (2, 0, history + 1, ip, history) > 0)
3771
    return FALSE;
3772
 
3773
  /* If the branch reads a register that the previous
3774
     instruction sets, we can not swap.  */
3775
  gpr_read = gpr_read_mask (ip);
3776
  prev_gpr_write = gpr_write_mask (&history[0]);
3777
  if (gpr_read & prev_gpr_write)
3778
    return FALSE;
3779
 
3780
  /* If the branch writes a register that the previous
3781
     instruction sets, we can not swap.  */
3782
  gpr_write = gpr_write_mask (ip);
3783
  if (gpr_write & prev_gpr_write)
3784
    return FALSE;
3785
 
3786
  /* If the branch writes a register that the previous
3787
     instruction reads, we can not swap.  */
3788
  prev_gpr_read = gpr_read_mask (&history[0]);
3789
  if (gpr_write & prev_gpr_read)
3790
    return FALSE;
3791
 
3792
  /* If one instruction sets a condition code and the
3793
     other one uses a condition code, we can not swap.  */
3794
  pinfo = ip->insn_mo->pinfo;
3795
  if ((pinfo & INSN_READ_COND_CODE)
3796
      && (prev_pinfo & INSN_WRITE_COND_CODE))
3797
    return FALSE;
3798
  if ((pinfo & INSN_WRITE_COND_CODE)
3799
      && (prev_pinfo & INSN_READ_COND_CODE))
3800
    return FALSE;
3801
 
3802
  /* If the previous instruction uses the PC, we can not swap.  */
3803
  prev_pinfo2 = history[0].insn_mo->pinfo2;
3804
  if (mips_opts.mips16 && (prev_pinfo & MIPS16_INSN_READ_PC))
3805
    return FALSE;
3806
  if (mips_opts.micromips && (prev_pinfo2 & INSN2_READ_PC))
3807
    return FALSE;
3808
 
3809
  /* If the previous instruction has an incorrect size for a fixed
3810
     branch delay slot in microMIPS mode, we cannot swap.  */
3811
  pinfo2 = ip->insn_mo->pinfo2;
3812
  if (mips_opts.micromips
3813
      && (pinfo2 & INSN2_BRANCH_DELAY_16BIT)
3814
      && insn_length (history) != 2)
3815
    return FALSE;
3816
  if (mips_opts.micromips
3817
      && (pinfo2 & INSN2_BRANCH_DELAY_32BIT)
3818
      && insn_length (history) != 4)
3819
    return FALSE;
3820
 
3821
  return TRUE;
3822
}
3823
 
3824
/* Decide how we should add IP to the instruction stream.  */
3825
 
3826
static enum append_method
3827
get_append_method (struct mips_cl_insn *ip)
3828
{
3829
  unsigned long pinfo;
3830
 
3831
  /* The relaxed version of a macro sequence must be inherently
3832
     hazard-free.  */
3833
  if (mips_relax.sequence == 2)
3834
    return APPEND_ADD;
3835
 
3836
  /* We must not dabble with instructions in a ".set norerorder" block.  */
3837
  if (mips_opts.noreorder)
3838
    return APPEND_ADD;
3839
 
3840
  /* Otherwise, it's our responsibility to fill branch delay slots.  */
3841
  if (delayed_branch_p (ip))
3842
    {
3843
      if (!branch_likely_p (ip) && can_swap_branch_p (ip))
3844
        return APPEND_SWAP;
3845
 
3846
      pinfo = ip->insn_mo->pinfo;
3847
      if (mips_opts.mips16
3848
          && ISA_SUPPORTS_MIPS16E
3849
          && (pinfo & (MIPS16_INSN_READ_X | MIPS16_INSN_READ_31)))
3850
        return APPEND_ADD_COMPACT;
3851
 
3852
      return APPEND_ADD_WITH_NOP;
3853
    }
3854
 
3855
  return APPEND_ADD;
3856
}
3857
 
3858
/* IP is a MIPS16 instruction whose opcode we have just changed.
3859
   Point IP->insn_mo to the new opcode's definition.  */
3860
 
3861
static void
3862
find_altered_mips16_opcode (struct mips_cl_insn *ip)
3863
{
3864
  const struct mips_opcode *mo, *end;
3865
 
3866
  end = &mips16_opcodes[bfd_mips16_num_opcodes];
3867
  for (mo = ip->insn_mo; mo < end; mo++)
3868
    if ((ip->insn_opcode & mo->mask) == mo->match)
3869
      {
3870
        ip->insn_mo = mo;
3871
        return;
3872
      }
3873
  abort ();
3874
}
3875
 
3876
/* For microMIPS macros, we need to generate a local number label
3877
   as the target of branches.  */
3878
#define MICROMIPS_LABEL_CHAR            '\037'
3879
static unsigned long micromips_target_label;
3880
static char micromips_target_name[32];
3881
 
3882
static char *
3883
micromips_label_name (void)
3884
{
3885
  char *p = micromips_target_name;
3886
  char symbol_name_temporary[24];
3887
  unsigned long l;
3888
  int i;
3889
 
3890
  if (*p)
3891
    return p;
3892
 
3893
  i = 0;
3894
  l = micromips_target_label;
3895
#ifdef LOCAL_LABEL_PREFIX
3896
  *p++ = LOCAL_LABEL_PREFIX;
3897
#endif
3898
  *p++ = 'L';
3899
  *p++ = MICROMIPS_LABEL_CHAR;
3900
  do
3901
    {
3902
      symbol_name_temporary[i++] = l % 10 + '0';
3903
      l /= 10;
3904
    }
3905
  while (l != 0);
3906
  while (i > 0)
3907
    *p++ = symbol_name_temporary[--i];
3908
  *p = '\0';
3909
 
3910
  return micromips_target_name;
3911
}
3912
 
3913
static void
3914
micromips_label_expr (expressionS *label_expr)
3915
{
3916
  label_expr->X_op = O_symbol;
3917
  label_expr->X_add_symbol = symbol_find_or_make (micromips_label_name ());
3918
  label_expr->X_add_number = 0;
3919
}
3920
 
3921
static void
3922
micromips_label_inc (void)
3923
{
3924
  micromips_target_label++;
3925
  *micromips_target_name = '\0';
3926
}
3927
 
3928
static void
3929
micromips_add_label (void)
3930
{
3931
  symbolS *s;
3932
 
3933
  s = colon (micromips_label_name ());
3934
  micromips_label_inc ();
3935
#if defined(OBJ_ELF) || defined(OBJ_MAYBE_ELF)
3936
  if (IS_ELF)
3937
    S_SET_OTHER (s, ELF_ST_SET_MICROMIPS (S_GET_OTHER (s)));
3938 163 khays
#else
3939
  (void) s;
3940 160 khays
#endif
3941
}
3942
 
3943
/* If assembling microMIPS code, then return the microMIPS reloc
3944
   corresponding to the requested one if any.  Otherwise return
3945
   the reloc unchanged.  */
3946
 
3947
static bfd_reloc_code_real_type
3948
micromips_map_reloc (bfd_reloc_code_real_type reloc)
3949
{
3950
  static const bfd_reloc_code_real_type relocs[][2] =
3951
    {
3952
      /* Keep sorted incrementally by the left-hand key.  */
3953
      { BFD_RELOC_16_PCREL_S2, BFD_RELOC_MICROMIPS_16_PCREL_S1 },
3954
      { BFD_RELOC_GPREL16, BFD_RELOC_MICROMIPS_GPREL16 },
3955
      { BFD_RELOC_MIPS_JMP, BFD_RELOC_MICROMIPS_JMP },
3956
      { BFD_RELOC_HI16, BFD_RELOC_MICROMIPS_HI16 },
3957
      { BFD_RELOC_HI16_S, BFD_RELOC_MICROMIPS_HI16_S },
3958
      { BFD_RELOC_LO16, BFD_RELOC_MICROMIPS_LO16 },
3959
      { BFD_RELOC_MIPS_LITERAL, BFD_RELOC_MICROMIPS_LITERAL },
3960
      { BFD_RELOC_MIPS_GOT16, BFD_RELOC_MICROMIPS_GOT16 },
3961
      { BFD_RELOC_MIPS_CALL16, BFD_RELOC_MICROMIPS_CALL16 },
3962
      { BFD_RELOC_MIPS_GOT_HI16, BFD_RELOC_MICROMIPS_GOT_HI16 },
3963
      { BFD_RELOC_MIPS_GOT_LO16, BFD_RELOC_MICROMIPS_GOT_LO16 },
3964
      { BFD_RELOC_MIPS_CALL_HI16, BFD_RELOC_MICROMIPS_CALL_HI16 },
3965
      { BFD_RELOC_MIPS_CALL_LO16, BFD_RELOC_MICROMIPS_CALL_LO16 },
3966
      { BFD_RELOC_MIPS_SUB, BFD_RELOC_MICROMIPS_SUB },
3967
      { BFD_RELOC_MIPS_GOT_PAGE, BFD_RELOC_MICROMIPS_GOT_PAGE },
3968
      { BFD_RELOC_MIPS_GOT_OFST, BFD_RELOC_MICROMIPS_GOT_OFST },
3969
      { BFD_RELOC_MIPS_GOT_DISP, BFD_RELOC_MICROMIPS_GOT_DISP },
3970
      { BFD_RELOC_MIPS_HIGHEST, BFD_RELOC_MICROMIPS_HIGHEST },
3971
      { BFD_RELOC_MIPS_HIGHER, BFD_RELOC_MICROMIPS_HIGHER },
3972
      { BFD_RELOC_MIPS_SCN_DISP, BFD_RELOC_MICROMIPS_SCN_DISP },
3973
      { BFD_RELOC_MIPS_TLS_GD, BFD_RELOC_MICROMIPS_TLS_GD },
3974
      { BFD_RELOC_MIPS_TLS_LDM, BFD_RELOC_MICROMIPS_TLS_LDM },
3975
      { BFD_RELOC_MIPS_TLS_DTPREL_HI16, BFD_RELOC_MICROMIPS_TLS_DTPREL_HI16 },
3976
      { BFD_RELOC_MIPS_TLS_DTPREL_LO16, BFD_RELOC_MICROMIPS_TLS_DTPREL_LO16 },
3977
      { BFD_RELOC_MIPS_TLS_GOTTPREL, BFD_RELOC_MICROMIPS_TLS_GOTTPREL },
3978
      { BFD_RELOC_MIPS_TLS_TPREL_HI16, BFD_RELOC_MICROMIPS_TLS_TPREL_HI16 },
3979
      { BFD_RELOC_MIPS_TLS_TPREL_LO16, BFD_RELOC_MICROMIPS_TLS_TPREL_LO16 }
3980
    };
3981
  bfd_reloc_code_real_type r;
3982
  size_t i;
3983
 
3984
  if (!mips_opts.micromips)
3985
    return reloc;
3986
  for (i = 0; i < ARRAY_SIZE (relocs); i++)
3987
    {
3988
      r = relocs[i][0];
3989
      if (r > reloc)
3990
        return reloc;
3991
      if (r == reloc)
3992
        return relocs[i][1];
3993
    }
3994
  return reloc;
3995
}
3996
 
3997 16 khays
/* Output an instruction.  IP is the instruction information.
3998
   ADDRESS_EXPR is an operand of the instruction to be used with
3999 160 khays
   RELOC_TYPE.  EXPANSIONP is true if the instruction is part of
4000
   a macro expansion.  */
4001 16 khays
 
4002
static void
4003
append_insn (struct mips_cl_insn *ip, expressionS *address_expr,
4004 160 khays
             bfd_reloc_code_real_type *reloc_type, bfd_boolean expansionp)
4005 16 khays
{
4006 160 khays
  unsigned long prev_pinfo2, pinfo;
4007 16 khays
  bfd_boolean relaxed_branch = FALSE;
4008 160 khays
  enum append_method method;
4009
  bfd_boolean relax32;
4010
  int branch_disp;
4011 16 khays
 
4012 160 khays
  if (mips_fix_loongson2f && !HAVE_CODE_COMPRESSION)
4013 16 khays
    fix_loongson2f (ip);
4014
 
4015 160 khays
  mips_mark_labels ();
4016 16 khays
 
4017
  file_ase_mips16 |= mips_opts.mips16;
4018 160 khays
  file_ase_micromips |= mips_opts.micromips;
4019 16 khays
 
4020
  prev_pinfo2 = history[0].insn_mo->pinfo2;
4021
  pinfo = ip->insn_mo->pinfo;
4022
 
4023 160 khays
  if (mips_opts.micromips
4024
      && !expansionp
4025
      && (((prev_pinfo2 & INSN2_BRANCH_DELAY_16BIT) != 0
4026
           && micromips_insn_length (ip->insn_mo) != 2)
4027
          || ((prev_pinfo2 & INSN2_BRANCH_DELAY_32BIT) != 0
4028
              && micromips_insn_length (ip->insn_mo) != 4)))
4029
    as_warn (_("Wrong size instruction in a %u-bit branch delay slot"),
4030
             (prev_pinfo2 & INSN2_BRANCH_DELAY_16BIT) != 0 ? 16 : 32);
4031
 
4032 16 khays
  if (address_expr == NULL)
4033
    ip->complete_p = 1;
4034
  else if (*reloc_type <= BFD_RELOC_UNUSED
4035
           && address_expr->X_op == O_constant)
4036
    {
4037
      unsigned int tmp;
4038
 
4039
      ip->complete_p = 1;
4040
      switch (*reloc_type)
4041
        {
4042
        case BFD_RELOC_32:
4043
          ip->insn_opcode |= address_expr->X_add_number;
4044
          break;
4045
 
4046
        case BFD_RELOC_MIPS_HIGHEST:
4047
          tmp = (address_expr->X_add_number + 0x800080008000ull) >> 48;
4048
          ip->insn_opcode |= tmp & 0xffff;
4049
          break;
4050
 
4051
        case BFD_RELOC_MIPS_HIGHER:
4052
          tmp = (address_expr->X_add_number + 0x80008000ull) >> 32;
4053
          ip->insn_opcode |= tmp & 0xffff;
4054
          break;
4055
 
4056
        case BFD_RELOC_HI16_S:
4057
          tmp = (address_expr->X_add_number + 0x8000) >> 16;
4058
          ip->insn_opcode |= tmp & 0xffff;
4059
          break;
4060
 
4061
        case BFD_RELOC_HI16:
4062
          ip->insn_opcode |= (address_expr->X_add_number >> 16) & 0xffff;
4063
          break;
4064
 
4065
        case BFD_RELOC_UNUSED:
4066
        case BFD_RELOC_LO16:
4067
        case BFD_RELOC_MIPS_GOT_DISP:
4068
          ip->insn_opcode |= address_expr->X_add_number & 0xffff;
4069
          break;
4070
 
4071
        case BFD_RELOC_MIPS_JMP:
4072 160 khays
          {
4073
            int shift;
4074
 
4075
            shift = mips_opts.micromips ? 1 : 2;
4076
            if ((address_expr->X_add_number & ((1 << shift) - 1)) != 0)
4077
              as_bad (_("jump to misaligned address (0x%lx)"),
4078
                      (unsigned long) address_expr->X_add_number);
4079
            ip->insn_opcode |= ((address_expr->X_add_number >> shift)
4080
                                & 0x3ffffff);
4081
            ip->complete_p = 0;
4082
          }
4083 16 khays
          break;
4084
 
4085
        case BFD_RELOC_MIPS16_JMP:
4086
          if ((address_expr->X_add_number & 3) != 0)
4087
            as_bad (_("jump to misaligned address (0x%lx)"),
4088
                    (unsigned long) address_expr->X_add_number);
4089
          ip->insn_opcode |=
4090
            (((address_expr->X_add_number & 0x7c0000) << 3)
4091
               | ((address_expr->X_add_number & 0xf800000) >> 7)
4092
               | ((address_expr->X_add_number & 0x3fffc) >> 2));
4093
          ip->complete_p = 0;
4094
          break;
4095
 
4096
        case BFD_RELOC_16_PCREL_S2:
4097 160 khays
          {
4098
            int shift;
4099
 
4100
            shift = mips_opts.micromips ? 1 : 2;
4101
            if ((address_expr->X_add_number & ((1 << shift) - 1)) != 0)
4102
              as_bad (_("branch to misaligned address (0x%lx)"),
4103
                      (unsigned long) address_expr->X_add_number);
4104
            if (!mips_relax_branch)
4105
              {
4106
                if ((address_expr->X_add_number + (1 << (shift + 15)))
4107
                    & ~((1 << (shift + 16)) - 1))
4108
                  as_bad (_("branch address range overflow (0x%lx)"),
4109
                          (unsigned long) address_expr->X_add_number);
4110
                ip->insn_opcode |= ((address_expr->X_add_number >> shift)
4111
                                    & 0xffff);
4112
              }
4113
            ip->complete_p = 0;
4114
          }
4115 16 khays
          break;
4116
 
4117
        default:
4118
          internalError ();
4119
        }
4120
    }
4121
 
4122
  if (mips_relax.sequence != 2 && !mips_opts.noreorder)
4123
    {
4124
      /* There are a lot of optimizations we could do that we don't.
4125
         In particular, we do not, in general, reorder instructions.
4126
         If you use gcc with optimization, it will reorder
4127
         instructions and generally do much more optimization then we
4128
         do here; repeating all that work in the assembler would only
4129
         benefit hand written assembly code, and does not seem worth
4130
         it.  */
4131
      int nops = (mips_optimize == 0
4132 160 khays
                  ? nops_for_insn (0, history, NULL)
4133
                  : nops_for_insn_or_target (0, history, ip));
4134 16 khays
      if (nops > 0)
4135
        {
4136
          fragS *old_frag;
4137
          unsigned long old_frag_offset;
4138
          int i;
4139
 
4140
          old_frag = frag_now;
4141
          old_frag_offset = frag_now_fix ();
4142
 
4143
          for (i = 0; i < nops; i++)
4144 160 khays
            add_fixed_insn (NOP_INSN);
4145
          insert_into_history (0, nops, NOP_INSN);
4146 16 khays
 
4147
          if (listing)
4148
            {
4149
              listing_prev_line ();
4150
              /* We may be at the start of a variant frag.  In case we
4151
                 are, make sure there is enough space for the frag
4152
                 after the frags created by listing_prev_line.  The
4153
                 argument to frag_grow here must be at least as large
4154
                 as the argument to all other calls to frag_grow in
4155
                 this file.  We don't have to worry about being in the
4156
                 middle of a variant frag, because the variants insert
4157
                 all needed nop instructions themselves.  */
4158
              frag_grow (40);
4159
            }
4160
 
4161 166 khays
          mips_move_text_labels ();
4162 16 khays
 
4163
#ifndef NO_ECOFF_DEBUGGING
4164
          if (ECOFF_DEBUGGING)
4165
            ecoff_fix_loc (old_frag, old_frag_offset);
4166
#endif
4167
        }
4168
    }
4169
  else if (mips_relax.sequence != 2 && prev_nop_frag != NULL)
4170
    {
4171 160 khays
      int nops;
4172
 
4173
      /* Work out how many nops in prev_nop_frag are needed by IP,
4174
         ignoring hazards generated by the first prev_nop_frag_since
4175
         instructions.  */
4176
      nops = nops_for_insn_or_target (prev_nop_frag_since, history, ip);
4177 16 khays
      gas_assert (nops <= prev_nop_frag_holds);
4178
 
4179
      /* Enforce NOPS as a minimum.  */
4180
      if (nops > prev_nop_frag_required)
4181
        prev_nop_frag_required = nops;
4182
 
4183
      if (prev_nop_frag_holds == prev_nop_frag_required)
4184
        {
4185
          /* Settle for the current number of nops.  Update the history
4186
             accordingly (for the benefit of any future .set reorder code).  */
4187
          prev_nop_frag = NULL;
4188
          insert_into_history (prev_nop_frag_since,
4189
                               prev_nop_frag_holds, NOP_INSN);
4190
        }
4191
      else
4192
        {
4193
          /* Allow this instruction to replace one of the nops that was
4194
             tentatively added to prev_nop_frag.  */
4195 160 khays
          prev_nop_frag->fr_fix -= NOP_INSN_SIZE;
4196 16 khays
          prev_nop_frag_holds--;
4197
          prev_nop_frag_since++;
4198
        }
4199
    }
4200
 
4201 160 khays
  method = get_append_method (ip);
4202
  branch_disp = method == APPEND_SWAP ? insn_length (history) : 0;
4203
 
4204 16 khays
#ifdef OBJ_ELF
4205
  /* The value passed to dwarf2_emit_insn is the distance between
4206
     the beginning of the current instruction and the address that
4207 160 khays
     should be recorded in the debug tables.  This is normally the
4208
     current address.
4209
 
4210
     For MIPS16/microMIPS debug info we want to use ISA-encoded
4211
     addresses, so we use -1 for an address higher by one than the
4212
     current one.
4213
 
4214
     If the instruction produced is a branch that we will swap with
4215
     the preceding instruction, then we add the displacement by which
4216
     the branch will be moved backwards.  This is more appropriate
4217
     and for MIPS16/microMIPS code also prevents a debugger from
4218
     placing a breakpoint in the middle of the branch (and corrupting
4219
     code if software breakpoints are used).  */
4220
  dwarf2_emit_insn ((HAVE_CODE_COMPRESSION ? -1 : 0) + branch_disp);
4221 16 khays
#endif
4222
 
4223 160 khays
  relax32 = (mips_relax_branch
4224
             /* Don't try branch relaxation within .set nomacro, or within
4225
                .set noat if we use $at for PIC computations.  If it turns
4226
                out that the branch was out-of-range, we'll get an error.  */
4227
             && !mips_opts.warn_about_macros
4228
             && (mips_opts.at || mips_pic == NO_PIC)
4229
             /* Don't relax BPOSGE32/64 as they have no complementing
4230
                branches.  */
4231
             && !(ip->insn_mo->membership & (INSN_DSP64 | INSN_DSP)));
4232 16 khays
 
4233 160 khays
  if (!HAVE_CODE_COMPRESSION
4234
      && address_expr
4235
      && relax32
4236 16 khays
      && *reloc_type == BFD_RELOC_16_PCREL_S2
4237 160 khays
      && delayed_branch_p (ip))
4238 16 khays
    {
4239
      relaxed_branch = TRUE;
4240
      add_relaxed_insn (ip, (relaxed_branch_length
4241
                             (NULL, NULL,
4242 160 khays
                              uncond_branch_p (ip) ? -1
4243
                              : branch_likely_p (ip) ? 1
4244 16 khays
                              : 0)), 4,
4245
                        RELAX_BRANCH_ENCODE
4246
                        (AT,
4247 160 khays
                         uncond_branch_p (ip),
4248
                         branch_likely_p (ip),
4249 16 khays
                         pinfo & INSN_WRITE_GPR_31,
4250
                         0),
4251
                        address_expr->X_add_symbol,
4252
                        address_expr->X_add_number);
4253
      *reloc_type = BFD_RELOC_UNUSED;
4254
    }
4255 160 khays
  else if (mips_opts.micromips
4256
           && address_expr
4257
           && ((relax32 && *reloc_type == BFD_RELOC_16_PCREL_S2)
4258
               || *reloc_type > BFD_RELOC_UNUSED)
4259
           && (delayed_branch_p (ip) || compact_branch_p (ip))
4260
           /* Don't try branch relaxation when users specify
4261
              16-bit/32-bit instructions.  */
4262
           && !forced_insn_length)
4263 16 khays
    {
4264 160 khays
      bfd_boolean relax16 = *reloc_type > BFD_RELOC_UNUSED;
4265
      int type = relax16 ? *reloc_type - BFD_RELOC_UNUSED : 0;
4266
      int uncond = uncond_branch_p (ip) ? -1 : 0;
4267
      int compact = compact_branch_p (ip);
4268
      int al = pinfo & INSN_WRITE_GPR_31;
4269
      int length32;
4270
 
4271
      gas_assert (address_expr != NULL);
4272
      gas_assert (!mips_relax.sequence);
4273
 
4274
      relaxed_branch = TRUE;
4275
      length32 = relaxed_micromips_32bit_branch_length (NULL, NULL, uncond);
4276
      add_relaxed_insn (ip, relax32 ? length32 : 4, relax16 ? 2 : 4,
4277
                        RELAX_MICROMIPS_ENCODE (type, AT, uncond, compact, al,
4278
                                                relax32, 0, 0),
4279
                        address_expr->X_add_symbol,
4280
                        address_expr->X_add_number);
4281
      *reloc_type = BFD_RELOC_UNUSED;
4282
    }
4283
  else if (mips_opts.mips16 && *reloc_type > BFD_RELOC_UNUSED)
4284
    {
4285 16 khays
      /* We need to set up a variant frag.  */
4286 160 khays
      gas_assert (address_expr != NULL);
4287 16 khays
      add_relaxed_insn (ip, 4, 0,
4288
                        RELAX_MIPS16_ENCODE
4289
                        (*reloc_type - BFD_RELOC_UNUSED,
4290 160 khays
                         forced_insn_length == 2, forced_insn_length == 4,
4291
                         delayed_branch_p (&history[0]),
4292 16 khays
                         history[0].mips16_absolute_jump_p),
4293
                        make_expr_symbol (address_expr), 0);
4294
    }
4295
  else if (mips_opts.mips16
4296
           && ! ip->use_extend
4297
           && *reloc_type != BFD_RELOC_MIPS16_JMP)
4298
    {
4299 160 khays
      if (!delayed_branch_p (ip))
4300 16 khays
        /* Make sure there is enough room to swap this instruction with
4301
           a following jump instruction.  */
4302
        frag_grow (6);
4303
      add_fixed_insn (ip);
4304
    }
4305
  else
4306
    {
4307
      if (mips_opts.mips16
4308
          && mips_opts.noreorder
4309 160 khays
          && delayed_branch_p (&history[0]))
4310 16 khays
        as_warn (_("extended instruction in delay slot"));
4311
 
4312
      if (mips_relax.sequence)
4313
        {
4314
          /* If we've reached the end of this frag, turn it into a variant
4315
             frag and record the information for the instructions we've
4316
             written so far.  */
4317
          if (frag_room () < 4)
4318
            relax_close_frag ();
4319 160 khays
          mips_relax.sizes[mips_relax.sequence - 1] += insn_length (ip);
4320 16 khays
        }
4321
 
4322
      if (mips_relax.sequence != 2)
4323 160 khays
        {
4324
          if (mips_macro_warning.first_insn_sizes[0] == 0)
4325
            mips_macro_warning.first_insn_sizes[0] = insn_length (ip);
4326
          mips_macro_warning.sizes[0] += insn_length (ip);
4327
          mips_macro_warning.insns[0]++;
4328
        }
4329 16 khays
      if (mips_relax.sequence != 1)
4330 160 khays
        {
4331
          if (mips_macro_warning.first_insn_sizes[1] == 0)
4332
            mips_macro_warning.first_insn_sizes[1] = insn_length (ip);
4333
          mips_macro_warning.sizes[1] += insn_length (ip);
4334
          mips_macro_warning.insns[1]++;
4335
        }
4336 16 khays
 
4337
      if (mips_opts.mips16)
4338
        {
4339
          ip->fixed_p = 1;
4340
          ip->mips16_absolute_jump_p = (*reloc_type == BFD_RELOC_MIPS16_JMP);
4341
        }
4342
      add_fixed_insn (ip);
4343
    }
4344
 
4345 160 khays
  if (!ip->complete_p && *reloc_type < BFD_RELOC_UNUSED)
4346 16 khays
    {
4347 160 khays
      bfd_reloc_code_real_type final_type[3];
4348
      reloc_howto_type *howto0;
4349
      reloc_howto_type *howto;
4350
      int i;
4351
 
4352
      /* Perform any necessary conversion to microMIPS relocations
4353
         and find out how many relocations there actually are.  */
4354
      for (i = 0; i < 3 && reloc_type[i] != BFD_RELOC_UNUSED; i++)
4355
        final_type[i] = micromips_map_reloc (reloc_type[i]);
4356
 
4357
      /* In a compound relocation, it is the final (outermost)
4358
         operator that determines the relocated field.  */
4359
      howto = howto0 = bfd_reloc_type_lookup (stdoutput, final_type[i - 1]);
4360
 
4361
      if (howto == NULL)
4362 16 khays
        {
4363 160 khays
          /* To reproduce this failure try assembling gas/testsuites/
4364
             gas/mips/mips16-intermix.s with a mips-ecoff targeted
4365
             assembler.  */
4366
          as_bad (_("Unsupported MIPS relocation number %d"),
4367
                  final_type[i - 1]);
4368
          howto = bfd_reloc_type_lookup (stdoutput, BFD_RELOC_16);
4369
        }
4370 16 khays
 
4371 160 khays
      if (i > 1)
4372
        howto0 = bfd_reloc_type_lookup (stdoutput, final_type[0]);
4373
      ip->fixp[0] = fix_new_exp (ip->frag, ip->where,
4374
                                 bfd_get_reloc_size (howto),
4375
                                 address_expr,
4376
                                 howto0 && howto0->pc_relative,
4377
                                 final_type[0]);
4378 16 khays
 
4379 160 khays
      /* Tag symbols that have a R_MIPS16_26 relocation against them.  */
4380
      if (final_type[0] == BFD_RELOC_MIPS16_JMP && ip->fixp[0]->fx_addsy)
4381
        *symbol_get_tc (ip->fixp[0]->fx_addsy) = 1;
4382 16 khays
 
4383 160 khays
      /* These relocations can have an addend that won't fit in
4384
         4 octets for 64bit assembly.  */
4385
      if (HAVE_64BIT_GPRS
4386
          && ! howto->partial_inplace
4387
          && (reloc_type[0] == BFD_RELOC_16
4388
              || reloc_type[0] == BFD_RELOC_32
4389
              || reloc_type[0] == BFD_RELOC_MIPS_JMP
4390
              || reloc_type[0] == BFD_RELOC_GPREL16
4391
              || reloc_type[0] == BFD_RELOC_MIPS_LITERAL
4392
              || reloc_type[0] == BFD_RELOC_GPREL32
4393
              || reloc_type[0] == BFD_RELOC_64
4394
              || reloc_type[0] == BFD_RELOC_CTOR
4395
              || reloc_type[0] == BFD_RELOC_MIPS_SUB
4396
              || reloc_type[0] == BFD_RELOC_MIPS_HIGHEST
4397
              || reloc_type[0] == BFD_RELOC_MIPS_HIGHER
4398
              || reloc_type[0] == BFD_RELOC_MIPS_SCN_DISP
4399
              || reloc_type[0] == BFD_RELOC_MIPS_REL16
4400
              || reloc_type[0] == BFD_RELOC_MIPS_RELGOT
4401
              || reloc_type[0] == BFD_RELOC_MIPS16_GPREL
4402
              || hi16_reloc_p (reloc_type[0])
4403
              || lo16_reloc_p (reloc_type[0])))
4404
        ip->fixp[0]->fx_no_overflow = 1;
4405 16 khays
 
4406 160 khays
      if (mips_relax.sequence)
4407
        {
4408
          if (mips_relax.first_fixup == 0)
4409
            mips_relax.first_fixup = ip->fixp[0];
4410
        }
4411
      else if (reloc_needs_lo_p (*reloc_type))
4412
        {
4413
          struct mips_hi_fixup *hi_fixup;
4414 16 khays
 
4415 160 khays
          /* Reuse the last entry if it already has a matching %lo.  */
4416
          hi_fixup = mips_hi_fixup_list;
4417
          if (hi_fixup == 0
4418
              || !fixup_has_matching_lo_p (hi_fixup->fixp))
4419 16 khays
            {
4420 160 khays
              hi_fixup = ((struct mips_hi_fixup *)
4421
                          xmalloc (sizeof (struct mips_hi_fixup)));
4422
              hi_fixup->next = mips_hi_fixup_list;
4423
              mips_hi_fixup_list = hi_fixup;
4424 16 khays
            }
4425 160 khays
          hi_fixup->fixp = ip->fixp[0];
4426
          hi_fixup->seg = now_seg;
4427
        }
4428 16 khays
 
4429 160 khays
      /* Add fixups for the second and third relocations, if given.
4430
         Note that the ABI allows the second relocation to be
4431
         against RSS_UNDEF, RSS_GP, RSS_GP0 or RSS_LOC.  At the
4432
         moment we only use RSS_UNDEF, but we could add support
4433
         for the others if it ever becomes necessary.  */
4434
      for (i = 1; i < 3; i++)
4435
        if (reloc_type[i] != BFD_RELOC_UNUSED)
4436
          {
4437
            ip->fixp[i] = fix_new (ip->frag, ip->where,
4438
                                   ip->fixp[0]->fx_size, NULL, 0,
4439
                                   FALSE, final_type[i]);
4440 16 khays
 
4441 160 khays
            /* Use fx_tcbit to mark compound relocs.  */
4442
            ip->fixp[0]->fx_tcbit = 1;
4443
            ip->fixp[i]->fx_tcbit = 1;
4444
          }
4445 16 khays
    }
4446
  install_insn (ip);
4447
 
4448
  /* Update the register mask information.  */
4449 160 khays
  mips_gprmask |= gpr_read_mask (ip) | gpr_write_mask (ip);
4450
  mips_cprmask[1] |= fpr_read_mask (ip) | fpr_write_mask (ip);
4451 16 khays
 
4452 160 khays
  switch (method)
4453 16 khays
    {
4454 160 khays
    case APPEND_ADD:
4455
      insert_into_history (0, 1, ip);
4456
      break;
4457 16 khays
 
4458 160 khays
    case APPEND_ADD_WITH_NOP:
4459
      {
4460
        struct mips_cl_insn *nop;
4461
 
4462 16 khays
        insert_into_history (0, 1, ip);
4463 160 khays
        nop = get_delay_slot_nop (ip);
4464
        add_fixed_insn (nop);
4465
        insert_into_history (0, 1, nop);
4466
        if (mips_relax.sequence)
4467
          mips_relax.sizes[mips_relax.sequence - 1] += insn_length (nop);
4468
      }
4469
      break;
4470
 
4471
    case APPEND_ADD_COMPACT:
4472
      /* Convert MIPS16 jr/jalr into a "compact" jump.  */
4473
      gas_assert (mips_opts.mips16);
4474
      ip->insn_opcode |= 0x0080;
4475
      find_altered_mips16_opcode (ip);
4476
      install_insn (ip);
4477
      insert_into_history (0, 1, ip);
4478
      break;
4479
 
4480
    case APPEND_SWAP:
4481
      {
4482
        struct mips_cl_insn delay = history[0];
4483
        if (mips_opts.mips16)
4484
          {
4485
            know (delay.frag == ip->frag);
4486
            move_insn (ip, delay.frag, delay.where);
4487
            move_insn (&delay, ip->frag, ip->where + insn_length (ip));
4488
          }
4489
        else if (relaxed_branch)
4490
          {
4491
            /* Add the delay slot instruction to the end of the
4492
               current frag and shrink the fixed part of the
4493
               original frag.  If the branch occupies the tail of
4494
               the latter, move it backwards to cover the gap.  */
4495
            delay.frag->fr_fix -= branch_disp;
4496
            if (delay.frag == ip->frag)
4497
              move_insn (ip, ip->frag, ip->where - branch_disp);
4498
            add_fixed_insn (&delay);
4499
          }
4500
        else
4501
          {
4502
            move_insn (&delay, ip->frag,
4503
                       ip->where - branch_disp + insn_length (ip));
4504
            move_insn (ip, history[0].frag, history[0].where);
4505
          }
4506
        history[0] = *ip;
4507
        delay.fixed_p = 1;
4508
        insert_into_history (0, 1, &delay);
4509
      }
4510
      break;
4511 16 khays
    }
4512
 
4513 160 khays
  /* If we have just completed an unconditional branch, clear the history.  */
4514
  if ((delayed_branch_p (&history[1]) && uncond_branch_p (&history[1]))
4515
      || (compact_branch_p (&history[0]) && uncond_branch_p (&history[0])))
4516
    mips_no_prev_insn ();
4517
 
4518
  /* We need to emit a label at the end of branch-likely macros.  */
4519
  if (emit_branch_likely_macro)
4520
    {
4521
      emit_branch_likely_macro = FALSE;
4522
      micromips_add_label ();
4523
    }
4524
 
4525 16 khays
  /* We just output an insn, so the next one doesn't have a label.  */
4526
  mips_clear_insn_labels ();
4527
}
4528
 
4529
/* Forget that there was any previous instruction or label.  */
4530
 
4531
static void
4532
mips_no_prev_insn (void)
4533
{
4534
  prev_nop_frag = NULL;
4535
  insert_into_history (0, ARRAY_SIZE (history), NOP_INSN);
4536
  mips_clear_insn_labels ();
4537
}
4538
 
4539
/* This function must be called before we emit something other than
4540
   instructions.  It is like mips_no_prev_insn except that it inserts
4541
   any NOPS that might be needed by previous instructions.  */
4542
 
4543
void
4544
mips_emit_delays (void)
4545
{
4546
  if (! mips_opts.noreorder)
4547
    {
4548 160 khays
      int nops = nops_for_insn (0, history, NULL);
4549 16 khays
      if (nops > 0)
4550
        {
4551
          while (nops-- > 0)
4552
            add_fixed_insn (NOP_INSN);
4553 166 khays
          mips_move_text_labels ();
4554 16 khays
        }
4555
    }
4556
  mips_no_prev_insn ();
4557
}
4558
 
4559
/* Start a (possibly nested) noreorder block.  */
4560
 
4561
static void
4562
start_noreorder (void)
4563
{
4564
  if (mips_opts.noreorder == 0)
4565
    {
4566
      unsigned int i;
4567
      int nops;
4568
 
4569
      /* None of the instructions before the .set noreorder can be moved.  */
4570
      for (i = 0; i < ARRAY_SIZE (history); i++)
4571
        history[i].fixed_p = 1;
4572
 
4573
      /* Insert any nops that might be needed between the .set noreorder
4574
         block and the previous instructions.  We will later remove any
4575
         nops that turn out not to be needed.  */
4576 160 khays
      nops = nops_for_insn (0, history, NULL);
4577 16 khays
      if (nops > 0)
4578
        {
4579
          if (mips_optimize != 0)
4580
            {
4581
              /* Record the frag which holds the nop instructions, so
4582
                 that we can remove them if we don't need them.  */
4583 160 khays
              frag_grow (nops * NOP_INSN_SIZE);
4584 16 khays
              prev_nop_frag = frag_now;
4585
              prev_nop_frag_holds = nops;
4586
              prev_nop_frag_required = 0;
4587
              prev_nop_frag_since = 0;
4588
            }
4589
 
4590
          for (; nops > 0; --nops)
4591
            add_fixed_insn (NOP_INSN);
4592
 
4593
          /* Move on to a new frag, so that it is safe to simply
4594
             decrease the size of prev_nop_frag.  */
4595
          frag_wane (frag_now);
4596
          frag_new (0);
4597 166 khays
          mips_move_text_labels ();
4598 16 khays
        }
4599 160 khays
      mips_mark_labels ();
4600 16 khays
      mips_clear_insn_labels ();
4601
    }
4602
  mips_opts.noreorder++;
4603
  mips_any_noreorder = 1;
4604
}
4605
 
4606
/* End a nested noreorder block.  */
4607
 
4608
static void
4609
end_noreorder (void)
4610
{
4611
  mips_opts.noreorder--;
4612
  if (mips_opts.noreorder == 0 && prev_nop_frag != NULL)
4613
    {
4614
      /* Commit to inserting prev_nop_frag_required nops and go back to
4615
         handling nop insertion the .set reorder way.  */
4616
      prev_nop_frag->fr_fix -= ((prev_nop_frag_holds - prev_nop_frag_required)
4617 160 khays
                                * NOP_INSN_SIZE);
4618 16 khays
      insert_into_history (prev_nop_frag_since,
4619
                           prev_nop_frag_required, NOP_INSN);
4620
      prev_nop_frag = NULL;
4621
    }
4622
}
4623
 
4624
/* Set up global variables for the start of a new macro.  */
4625
 
4626
static void
4627
macro_start (void)
4628
{
4629
  memset (&mips_macro_warning.sizes, 0, sizeof (mips_macro_warning.sizes));
4630 160 khays
  memset (&mips_macro_warning.first_insn_sizes, 0,
4631
          sizeof (mips_macro_warning.first_insn_sizes));
4632
  memset (&mips_macro_warning.insns, 0, sizeof (mips_macro_warning.insns));
4633 16 khays
  mips_macro_warning.delay_slot_p = (mips_opts.noreorder
4634 160 khays
                                     && delayed_branch_p (&history[0]));
4635
  switch (history[0].insn_mo->pinfo2
4636
          & (INSN2_BRANCH_DELAY_32BIT | INSN2_BRANCH_DELAY_16BIT))
4637
    {
4638
    case INSN2_BRANCH_DELAY_32BIT:
4639
      mips_macro_warning.delay_slot_length = 4;
4640
      break;
4641
    case INSN2_BRANCH_DELAY_16BIT:
4642
      mips_macro_warning.delay_slot_length = 2;
4643
      break;
4644
    default:
4645
      mips_macro_warning.delay_slot_length = 0;
4646
      break;
4647
    }
4648
  mips_macro_warning.first_frag = NULL;
4649 16 khays
}
4650
 
4651 160 khays
/* Given that a macro is longer than one instruction or of the wrong size,
4652
   return the appropriate warning for it.  Return null if no warning is
4653
   needed.  SUBTYPE is a bitmask of RELAX_DELAY_SLOT, RELAX_DELAY_SLOT_16BIT,
4654
   RELAX_DELAY_SLOT_SIZE_FIRST, RELAX_DELAY_SLOT_SIZE_SECOND,
4655
   and RELAX_NOMACRO.  */
4656 16 khays
 
4657
static const char *
4658
macro_warning (relax_substateT subtype)
4659
{
4660
  if (subtype & RELAX_DELAY_SLOT)
4661
    return _("Macro instruction expanded into multiple instructions"
4662
             " in a branch delay slot");
4663
  else if (subtype & RELAX_NOMACRO)
4664
    return _("Macro instruction expanded into multiple instructions");
4665 160 khays
  else if (subtype & (RELAX_DELAY_SLOT_SIZE_FIRST
4666
                      | RELAX_DELAY_SLOT_SIZE_SECOND))
4667
    return ((subtype & RELAX_DELAY_SLOT_16BIT)
4668
            ? _("Macro instruction expanded into a wrong size instruction"
4669
                " in a 16-bit branch delay slot")
4670
            : _("Macro instruction expanded into a wrong size instruction"
4671
                " in a 32-bit branch delay slot"));
4672 16 khays
  else
4673
    return 0;
4674
}
4675
 
4676
/* Finish up a macro.  Emit warnings as appropriate.  */
4677
 
4678
static void
4679
macro_end (void)
4680
{
4681 160 khays
  /* Relaxation warning flags.  */
4682
  relax_substateT subtype = 0;
4683
 
4684
  /* Check delay slot size requirements.  */
4685
  if (mips_macro_warning.delay_slot_length == 2)
4686
    subtype |= RELAX_DELAY_SLOT_16BIT;
4687
  if (mips_macro_warning.delay_slot_length != 0)
4688 16 khays
    {
4689 160 khays
      if (mips_macro_warning.delay_slot_length
4690
          != mips_macro_warning.first_insn_sizes[0])
4691
        subtype |= RELAX_DELAY_SLOT_SIZE_FIRST;
4692
      if (mips_macro_warning.delay_slot_length
4693
          != mips_macro_warning.first_insn_sizes[1])
4694
        subtype |= RELAX_DELAY_SLOT_SIZE_SECOND;
4695
    }
4696 16 khays
 
4697 160 khays
  /* Check instruction count requirements.  */
4698
  if (mips_macro_warning.insns[0] > 1 || mips_macro_warning.insns[1] > 1)
4699
    {
4700
      if (mips_macro_warning.insns[1] > mips_macro_warning.insns[0])
4701 16 khays
        subtype |= RELAX_SECOND_LONGER;
4702
      if (mips_opts.warn_about_macros)
4703
        subtype |= RELAX_NOMACRO;
4704
      if (mips_macro_warning.delay_slot_p)
4705
        subtype |= RELAX_DELAY_SLOT;
4706 160 khays
    }
4707 16 khays
 
4708 160 khays
  /* If both alternatives fail to fill a delay slot correctly,
4709
     emit the warning now.  */
4710
  if ((subtype & RELAX_DELAY_SLOT_SIZE_FIRST) != 0
4711
      && (subtype & RELAX_DELAY_SLOT_SIZE_SECOND) != 0)
4712
    {
4713
      relax_substateT s;
4714
      const char *msg;
4715
 
4716
      s = subtype & (RELAX_DELAY_SLOT_16BIT
4717
                     | RELAX_DELAY_SLOT_SIZE_FIRST
4718
                     | RELAX_DELAY_SLOT_SIZE_SECOND);
4719
      msg = macro_warning (s);
4720
      if (msg != NULL)
4721
        as_warn ("%s", msg);
4722
      subtype &= ~s;
4723 16 khays
    }
4724 160 khays
 
4725
  /* If both implementations are longer than 1 instruction, then emit the
4726
     warning now.  */
4727
  if (mips_macro_warning.insns[0] > 1 && mips_macro_warning.insns[1] > 1)
4728
    {
4729
      relax_substateT s;
4730
      const char *msg;
4731
 
4732
      s = subtype & (RELAX_SECOND_LONGER | RELAX_NOMACRO | RELAX_DELAY_SLOT);
4733
      msg = macro_warning (s);
4734
      if (msg != NULL)
4735
        as_warn ("%s", msg);
4736
      subtype &= ~s;
4737
    }
4738
 
4739
  /* If any flags still set, then one implementation might need a warning
4740
     and the other either will need one of a different kind or none at all.
4741
     Pass any remaining flags over to relaxation.  */
4742
  if (mips_macro_warning.first_frag != NULL)
4743
    mips_macro_warning.first_frag->fr_subtype |= subtype;
4744 16 khays
}
4745
 
4746 160 khays
/* Instruction operand formats used in macros that vary between
4747
   standard MIPS and microMIPS code.  */
4748
 
4749
static const char * const brk_fmt[2] = { "c", "mF" };
4750
static const char * const cop12_fmt[2] = { "E,o(b)", "E,~(b)" };
4751
static const char * const jalr_fmt[2] = { "d,s", "t,s" };
4752
static const char * const lui_fmt[2] = { "t,u", "s,u" };
4753
static const char * const mem12_fmt[2] = { "t,o(b)", "t,~(b)" };
4754
static const char * const mfhl_fmt[2] = { "d", "mj" };
4755
static const char * const shft_fmt[2] = { "d,w,<", "t,r,<" };
4756
static const char * const trap_fmt[2] = { "s,t,q", "s,t,|" };
4757
 
4758
#define BRK_FMT (brk_fmt[mips_opts.micromips])
4759
#define COP12_FMT (cop12_fmt[mips_opts.micromips])
4760
#define JALR_FMT (jalr_fmt[mips_opts.micromips])
4761
#define LUI_FMT (lui_fmt[mips_opts.micromips])
4762
#define MEM12_FMT (mem12_fmt[mips_opts.micromips])
4763
#define MFHL_FMT (mfhl_fmt[mips_opts.micromips])
4764
#define SHFT_FMT (shft_fmt[mips_opts.micromips])
4765
#define TRAP_FMT (trap_fmt[mips_opts.micromips])
4766
 
4767 16 khays
/* Read a macro's relocation codes from *ARGS and store them in *R.
4768
   The first argument in *ARGS will be either the code for a single
4769
   relocation or -1 followed by the three codes that make up a
4770
   composite relocation.  */
4771
 
4772
static void
4773
macro_read_relocs (va_list *args, bfd_reloc_code_real_type *r)
4774
{
4775
  int i, next;
4776
 
4777
  next = va_arg (*args, int);
4778
  if (next >= 0)
4779
    r[0] = (bfd_reloc_code_real_type) next;
4780
  else
4781
    for (i = 0; i < 3; i++)
4782
      r[i] = (bfd_reloc_code_real_type) va_arg (*args, int);
4783
}
4784
 
4785
/* Build an instruction created by a macro expansion.  This is passed
4786
   a pointer to the count of instructions created so far, an
4787
   expression, the name of the instruction to build, an operand format
4788
   string, and corresponding arguments.  */
4789
 
4790
static void
4791
macro_build (expressionS *ep, const char *name, const char *fmt, ...)
4792
{
4793 160 khays
  const struct mips_opcode *mo = NULL;
4794
  bfd_reloc_code_real_type r[3];
4795
  const struct mips_opcode *amo;
4796
  struct hash_control *hash;
4797 16 khays
  struct mips_cl_insn insn;
4798
  va_list args;
4799
 
4800
  va_start (args, fmt);
4801
 
4802
  if (mips_opts.mips16)
4803
    {
4804
      mips16_macro_build (ep, name, fmt, &args);
4805
      va_end (args);
4806
      return;
4807
    }
4808
 
4809
  r[0] = BFD_RELOC_UNUSED;
4810
  r[1] = BFD_RELOC_UNUSED;
4811
  r[2] = BFD_RELOC_UNUSED;
4812 160 khays
  hash = mips_opts.micromips ? micromips_op_hash : op_hash;
4813
  amo = (struct mips_opcode *) hash_find (hash, name);
4814
  gas_assert (amo);
4815
  gas_assert (strcmp (name, amo->name) == 0);
4816 16 khays
 
4817 160 khays
  do
4818 16 khays
    {
4819
      /* Search until we get a match for NAME.  It is assumed here that
4820 160 khays
         macros will never generate MDMX, MIPS-3D, or MT instructions.
4821
         We try to match an instruction that fulfils the branch delay
4822
         slot instruction length requirement (if any) of the previous
4823
         instruction.  While doing this we record the first instruction
4824
         seen that matches all the other conditions and use it anyway
4825
         if the requirement cannot be met; we will issue an appropriate
4826
         warning later on.  */
4827
      if (strcmp (fmt, amo->args) == 0
4828
          && amo->pinfo != INSN_MACRO
4829
          && is_opcode_valid (amo)
4830
          && is_size_valid (amo))
4831
        {
4832
          if (is_delay_slot_valid (amo))
4833
            {
4834
              mo = amo;
4835
              break;
4836
            }
4837
          else if (!mo)
4838
            mo = amo;
4839
        }
4840 16 khays
 
4841 160 khays
      ++amo;
4842
      gas_assert (amo->name);
4843 16 khays
    }
4844 160 khays
  while (strcmp (name, amo->name) == 0);
4845 16 khays
 
4846 160 khays
  gas_assert (mo);
4847 16 khays
  create_insn (&insn, mo);
4848
  for (;;)
4849
    {
4850
      switch (*fmt++)
4851
        {
4852
        case '\0':
4853
          break;
4854
 
4855
        case ',':
4856
        case '(':
4857
        case ')':
4858
          continue;
4859
 
4860
        case '+':
4861
          switch (*fmt++)
4862
            {
4863
            case 'A':
4864
            case 'E':
4865 160 khays
              INSERT_OPERAND (mips_opts.micromips,
4866
                              EXTLSB, insn, va_arg (args, int));
4867 16 khays
              continue;
4868
 
4869
            case 'B':
4870
            case 'F':
4871
              /* Note that in the macro case, these arguments are already
4872
                 in MSB form.  (When handling the instruction in the
4873
                 non-macro case, these arguments are sizes from which
4874
                 MSB values must be calculated.)  */
4875 160 khays
              INSERT_OPERAND (mips_opts.micromips,
4876
                              INSMSB, insn, va_arg (args, int));
4877 16 khays
              continue;
4878
 
4879
            case 'C':
4880
            case 'G':
4881
            case 'H':
4882
              /* Note that in the macro case, these arguments are already
4883
                 in MSBD form.  (When handling the instruction in the
4884
                 non-macro case, these arguments are sizes from which
4885
                 MSBD values must be calculated.)  */
4886 160 khays
              INSERT_OPERAND (mips_opts.micromips,
4887
                              EXTMSBD, insn, va_arg (args, int));
4888 16 khays
              continue;
4889
 
4890
            case 'Q':
4891 160 khays
              gas_assert (!mips_opts.micromips);
4892
              INSERT_OPERAND (0, SEQI, insn, va_arg (args, int));
4893 16 khays
              continue;
4894
 
4895
            default:
4896
              internalError ();
4897
            }
4898
          continue;
4899
 
4900
        case '2':
4901 160 khays
          gas_assert (!mips_opts.micromips);
4902
          INSERT_OPERAND (0, BP, insn, va_arg (args, int));
4903 16 khays
          continue;
4904
 
4905 160 khays
        case 'n':
4906
          gas_assert (mips_opts.micromips);
4907 16 khays
        case 't':
4908
        case 'w':
4909
        case 'E':
4910 160 khays
          INSERT_OPERAND (mips_opts.micromips, RT, insn, va_arg (args, int));
4911 16 khays
          continue;
4912
 
4913
        case 'c':
4914 160 khays
          gas_assert (!mips_opts.micromips);
4915
          INSERT_OPERAND (0, CODE, insn, va_arg (args, int));
4916 16 khays
          continue;
4917
 
4918 160 khays
        case 'W':
4919
          gas_assert (!mips_opts.micromips);
4920 16 khays
        case 'T':
4921 160 khays
          INSERT_OPERAND (mips_opts.micromips, FT, insn, va_arg (args, int));
4922 16 khays
          continue;
4923
 
4924
        case 'G':
4925 160 khays
          if (mips_opts.micromips)
4926
            INSERT_OPERAND (1, RS, insn, va_arg (args, int));
4927
          else
4928
            INSERT_OPERAND (0, RD, insn, va_arg (args, int));
4929
          continue;
4930
 
4931 16 khays
        case 'K':
4932 160 khays
          gas_assert (!mips_opts.micromips);
4933
        case 'd':
4934
          INSERT_OPERAND (mips_opts.micromips, RD, insn, va_arg (args, int));
4935 16 khays
          continue;
4936
 
4937
        case 'U':
4938 160 khays
          gas_assert (!mips_opts.micromips);
4939 16 khays
          {
4940
            int tmp = va_arg (args, int);
4941
 
4942 160 khays
            INSERT_OPERAND (0, RT, insn, tmp);
4943
            INSERT_OPERAND (0, RD, insn, tmp);
4944 16 khays
          }
4945 160 khays
          continue;
4946 16 khays
 
4947
        case 'V':
4948
        case 'S':
4949 160 khays
          gas_assert (!mips_opts.micromips);
4950
          INSERT_OPERAND (0, FS, insn, va_arg (args, int));
4951 16 khays
          continue;
4952
 
4953
        case 'z':
4954
          continue;
4955
 
4956
        case '<':
4957 160 khays
          INSERT_OPERAND (mips_opts.micromips,
4958
                          SHAMT, insn, va_arg (args, int));
4959 16 khays
          continue;
4960
 
4961
        case 'D':
4962 160 khays
          gas_assert (!mips_opts.micromips);
4963
          INSERT_OPERAND (0, FD, insn, va_arg (args, int));
4964 16 khays
          continue;
4965
 
4966
        case 'B':
4967 160 khays
          gas_assert (!mips_opts.micromips);
4968
          INSERT_OPERAND (0, CODE20, insn, va_arg (args, int));
4969 16 khays
          continue;
4970
 
4971
        case 'J':
4972 160 khays
          gas_assert (!mips_opts.micromips);
4973
          INSERT_OPERAND (0, CODE19, insn, va_arg (args, int));
4974 16 khays
          continue;
4975
 
4976
        case 'q':
4977 160 khays
          gas_assert (!mips_opts.micromips);
4978
          INSERT_OPERAND (0, CODE2, insn, va_arg (args, int));
4979 16 khays
          continue;
4980
 
4981
        case 'b':
4982
        case 's':
4983
        case 'r':
4984
        case 'v':
4985 160 khays
          INSERT_OPERAND (mips_opts.micromips, RS, insn, va_arg (args, int));
4986 16 khays
          continue;
4987
 
4988
        case 'i':
4989
        case 'j':
4990
          macro_read_relocs (&args, r);
4991
          gas_assert (*r == BFD_RELOC_GPREL16
4992
                      || *r == BFD_RELOC_MIPS_HIGHER
4993
                      || *r == BFD_RELOC_HI16_S
4994
                      || *r == BFD_RELOC_LO16
4995
                      || *r == BFD_RELOC_MIPS_GOT_OFST);
4996
          continue;
4997
 
4998
        case 'o':
4999
          macro_read_relocs (&args, r);
5000
          continue;
5001
 
5002
        case 'u':
5003
          macro_read_relocs (&args, r);
5004
          gas_assert (ep != NULL
5005
                      && (ep->X_op == O_constant
5006
                          || (ep->X_op == O_symbol
5007
                              && (*r == BFD_RELOC_MIPS_HIGHEST
5008
                                  || *r == BFD_RELOC_HI16_S
5009
                                  || *r == BFD_RELOC_HI16
5010
                                  || *r == BFD_RELOC_GPREL16
5011
                                  || *r == BFD_RELOC_MIPS_GOT_HI16
5012
                                  || *r == BFD_RELOC_MIPS_CALL_HI16))));
5013
          continue;
5014
 
5015
        case 'p':
5016
          gas_assert (ep != NULL);
5017
 
5018
          /*
5019
           * This allows macro() to pass an immediate expression for
5020
           * creating short branches without creating a symbol.
5021
           *
5022
           * We don't allow branch relaxation for these branches, as
5023
           * they should only appear in ".set nomacro" anyway.
5024
           */
5025
          if (ep->X_op == O_constant)
5026
            {
5027 160 khays
              /* For microMIPS we always use relocations for branches.
5028
                 So we should not resolve immediate values.  */
5029
              gas_assert (!mips_opts.micromips);
5030
 
5031 16 khays
              if ((ep->X_add_number & 3) != 0)
5032
                as_bad (_("branch to misaligned address (0x%lx)"),
5033
                        (unsigned long) ep->X_add_number);
5034
              if ((ep->X_add_number + 0x20000) & ~0x3ffff)
5035
                as_bad (_("branch address range overflow (0x%lx)"),
5036
                        (unsigned long) ep->X_add_number);
5037
              insn.insn_opcode |= (ep->X_add_number >> 2) & 0xffff;
5038
              ep = NULL;
5039
            }
5040
          else
5041
            *r = BFD_RELOC_16_PCREL_S2;
5042
          continue;
5043
 
5044
        case 'a':
5045
          gas_assert (ep != NULL);
5046
          *r = BFD_RELOC_MIPS_JMP;
5047
          continue;
5048
 
5049
        case 'C':
5050 160 khays
          gas_assert (!mips_opts.micromips);
5051
          INSERT_OPERAND (0, COPZ, insn, va_arg (args, unsigned long));
5052 16 khays
          continue;
5053
 
5054
        case 'k':
5055 160 khays
          INSERT_OPERAND (mips_opts.micromips,
5056
                          CACHE, insn, va_arg (args, unsigned long));
5057 16 khays
          continue;
5058
 
5059 160 khays
        case '|':
5060
          gas_assert (mips_opts.micromips);
5061
          INSERT_OPERAND (1, TRAP, insn, va_arg (args, int));
5062
          continue;
5063
 
5064
        case '.':
5065
          gas_assert (mips_opts.micromips);
5066
          INSERT_OPERAND (1, OFFSET10, insn, va_arg (args, int));
5067
          continue;
5068
 
5069
        case '\\':
5070
          INSERT_OPERAND (mips_opts.micromips,
5071
                          3BITPOS, insn, va_arg (args, unsigned int));
5072
          continue;
5073
 
5074
        case '~':
5075
          INSERT_OPERAND (mips_opts.micromips,
5076
                          OFFSET12, insn, va_arg (args, unsigned long));
5077
          continue;
5078
 
5079
        case 'N':
5080
          gas_assert (mips_opts.micromips);
5081
          INSERT_OPERAND (1, BCC, insn, va_arg (args, int));
5082
          continue;
5083
 
5084
        case 'm':       /* Opcode extension character.  */
5085
          gas_assert (mips_opts.micromips);
5086
          switch (*fmt++)
5087
            {
5088
            case 'j':
5089
              INSERT_OPERAND (1, MJ, insn, va_arg (args, int));
5090
              break;
5091
 
5092
            case 'p':
5093
              INSERT_OPERAND (1, MP, insn, va_arg (args, int));
5094
              break;
5095
 
5096
            case 'F':
5097
              INSERT_OPERAND (1, IMMF, insn, va_arg (args, int));
5098
              break;
5099
 
5100
            default:
5101
              internalError ();
5102
            }
5103
          continue;
5104
 
5105 16 khays
        default:
5106
          internalError ();
5107
        }
5108
      break;
5109
    }
5110
  va_end (args);
5111
  gas_assert (*r == BFD_RELOC_UNUSED ? ep == NULL : ep != NULL);
5112
 
5113 160 khays
  append_insn (&insn, ep, r, TRUE);
5114 16 khays
}
5115
 
5116
static void
5117
mips16_macro_build (expressionS *ep, const char *name, const char *fmt,
5118
                    va_list *args)
5119
{
5120
  struct mips_opcode *mo;
5121
  struct mips_cl_insn insn;
5122
  bfd_reloc_code_real_type r[3]
5123
    = {BFD_RELOC_UNUSED, BFD_RELOC_UNUSED, BFD_RELOC_UNUSED};
5124
 
5125
  mo = (struct mips_opcode *) hash_find (mips16_op_hash, name);
5126
  gas_assert (mo);
5127
  gas_assert (strcmp (name, mo->name) == 0);
5128
 
5129
  while (strcmp (fmt, mo->args) != 0 || mo->pinfo == INSN_MACRO)
5130
    {
5131
      ++mo;
5132
      gas_assert (mo->name);
5133
      gas_assert (strcmp (name, mo->name) == 0);
5134
    }
5135
 
5136
  create_insn (&insn, mo);
5137
  for (;;)
5138
    {
5139
      int c;
5140
 
5141
      c = *fmt++;
5142
      switch (c)
5143
        {
5144
        case '\0':
5145
          break;
5146
 
5147
        case ',':
5148
        case '(':
5149
        case ')':
5150
          continue;
5151
 
5152
        case 'y':
5153
        case 'w':
5154
          MIPS16_INSERT_OPERAND (RY, insn, va_arg (*args, int));
5155
          continue;
5156
 
5157
        case 'x':
5158
        case 'v':
5159
          MIPS16_INSERT_OPERAND (RX, insn, va_arg (*args, int));
5160
          continue;
5161
 
5162
        case 'z':
5163
          MIPS16_INSERT_OPERAND (RZ, insn, va_arg (*args, int));
5164
          continue;
5165
 
5166
        case 'Z':
5167
          MIPS16_INSERT_OPERAND (MOVE32Z, insn, va_arg (*args, int));
5168
          continue;
5169
 
5170
        case '0':
5171
        case 'S':
5172
        case 'P':
5173
        case 'R':
5174
          continue;
5175
 
5176
        case 'X':
5177
          MIPS16_INSERT_OPERAND (REGR32, insn, va_arg (*args, int));
5178
          continue;
5179
 
5180
        case 'Y':
5181
          {
5182
            int regno;
5183
 
5184
            regno = va_arg (*args, int);
5185
            regno = ((regno & 7) << 2) | ((regno & 0x18) >> 3);
5186
            MIPS16_INSERT_OPERAND (REG32R, insn, regno);
5187
          }
5188
          continue;
5189
 
5190
        case '<':
5191
        case '>':
5192
        case '4':
5193
        case '5':
5194
        case 'H':
5195
        case 'W':
5196
        case 'D':
5197
        case 'j':
5198
        case '8':
5199
        case 'V':
5200
        case 'C':
5201
        case 'U':
5202
        case 'k':
5203
        case 'K':
5204
        case 'p':
5205
        case 'q':
5206
          {
5207
            gas_assert (ep != NULL);
5208
 
5209
            if (ep->X_op != O_constant)
5210
              *r = (int) BFD_RELOC_UNUSED + c;
5211
            else
5212
              {
5213
                mips16_immed (NULL, 0, c, ep->X_add_number, FALSE, FALSE,
5214
                              FALSE, &insn.insn_opcode, &insn.use_extend,
5215
                              &insn.extend);
5216
                ep = NULL;
5217
                *r = BFD_RELOC_UNUSED;
5218
              }
5219
          }
5220
          continue;
5221
 
5222
        case '6':
5223
          MIPS16_INSERT_OPERAND (IMM6, insn, va_arg (*args, int));
5224
          continue;
5225
        }
5226
 
5227
      break;
5228
    }
5229
 
5230
  gas_assert (*r == BFD_RELOC_UNUSED ? ep == NULL : ep != NULL);
5231
 
5232 160 khays
  append_insn (&insn, ep, r, TRUE);
5233 16 khays
}
5234
 
5235
/*
5236
 * Sign-extend 32-bit mode constants that have bit 31 set and all
5237
 * higher bits unset.
5238
 */
5239
static void
5240
normalize_constant_expr (expressionS *ex)
5241
{
5242
  if (ex->X_op == O_constant
5243
      && IS_ZEXT_32BIT_NUM (ex->X_add_number))
5244
    ex->X_add_number = (((ex->X_add_number & 0xffffffff) ^ 0x80000000)
5245
                        - 0x80000000);
5246
}
5247
 
5248
/*
5249
 * Sign-extend 32-bit mode address offsets that have bit 31 set and
5250
 * all higher bits unset.
5251
 */
5252
static void
5253
normalize_address_expr (expressionS *ex)
5254
{
5255
  if (((ex->X_op == O_constant && HAVE_32BIT_ADDRESSES)
5256
        || (ex->X_op == O_symbol && HAVE_32BIT_SYMBOLS))
5257
      && IS_ZEXT_32BIT_NUM (ex->X_add_number))
5258
    ex->X_add_number = (((ex->X_add_number & 0xffffffff) ^ 0x80000000)
5259
                        - 0x80000000);
5260
}
5261
 
5262
/*
5263
 * Generate a "jalr" instruction with a relocation hint to the called
5264
 * function.  This occurs in NewABI PIC code.
5265
 */
5266
static void
5267 160 khays
macro_build_jalr (expressionS *ep, int cprestore)
5268 16 khays
{
5269 160 khays
  static const bfd_reloc_code_real_type jalr_relocs[2]
5270
    = { BFD_RELOC_MIPS_JALR, BFD_RELOC_MICROMIPS_JALR };
5271
  bfd_reloc_code_real_type jalr_reloc = jalr_relocs[mips_opts.micromips];
5272
  const char *jalr;
5273 16 khays
  char *f = NULL;
5274
 
5275
  if (MIPS_JALR_HINT_P (ep))
5276
    {
5277
      frag_grow (8);
5278
      f = frag_more (0);
5279
    }
5280 166 khays
  if (mips_opts.micromips)
5281 160 khays
    {
5282
      jalr = mips_opts.noreorder && !cprestore ? "jalr" : "jalrs";
5283
      if (MIPS_JALR_HINT_P (ep))
5284
        macro_build (NULL, jalr, "t,s", RA, PIC_CALL_REG);
5285
      else
5286
        macro_build (NULL, jalr, "mj", PIC_CALL_REG);
5287
    }
5288 166 khays
  else
5289
    macro_build (NULL, "jalr", "d,s", RA, PIC_CALL_REG);
5290 16 khays
  if (MIPS_JALR_HINT_P (ep))
5291 160 khays
    fix_new_exp (frag_now, f - frag_now->fr_literal, 4, ep, FALSE, jalr_reloc);
5292 16 khays
}
5293
 
5294
/*
5295
 * Generate a "lui" instruction.
5296
 */
5297
static void
5298
macro_build_lui (expressionS *ep, int regnum)
5299
{
5300
  gas_assert (! mips_opts.mips16);
5301
 
5302 160 khays
  if (ep->X_op != O_constant)
5303 16 khays
    {
5304
      gas_assert (ep->X_op == O_symbol);
5305
      /* _gp_disp is a special case, used from s_cpload.
5306
         __gnu_local_gp is used if mips_no_shared.  */
5307
      gas_assert (mips_pic == NO_PIC
5308
              || (! HAVE_NEWABI
5309
                  && strcmp (S_GET_NAME (ep->X_add_symbol), "_gp_disp") == 0)
5310
              || (! mips_in_shared
5311
                  && strcmp (S_GET_NAME (ep->X_add_symbol),
5312
                             "__gnu_local_gp") == 0));
5313
    }
5314
 
5315 160 khays
  macro_build (ep, "lui", LUI_FMT, regnum, BFD_RELOC_HI16_S);
5316 16 khays
}
5317
 
5318
/* Generate a sequence of instructions to do a load or store from a constant
5319
   offset off of a base register (breg) into/from a target register (treg),
5320
   using AT if necessary.  */
5321
static void
5322
macro_build_ldst_constoffset (expressionS *ep, const char *op,
5323
                              int treg, int breg, int dbl)
5324
{
5325
  gas_assert (ep->X_op == O_constant);
5326
 
5327
  /* Sign-extending 32-bit constants makes their handling easier.  */
5328
  if (!dbl)
5329
    normalize_constant_expr (ep);
5330
 
5331
  /* Right now, this routine can only handle signed 32-bit constants.  */
5332
  if (! IS_SEXT_32BIT_NUM(ep->X_add_number + 0x8000))
5333
    as_warn (_("operand overflow"));
5334
 
5335
  if (IS_SEXT_16BIT_NUM(ep->X_add_number))
5336
    {
5337
      /* Signed 16-bit offset will fit in the op.  Easy!  */
5338
      macro_build (ep, op, "t,o(b)", treg, BFD_RELOC_LO16, breg);
5339
    }
5340
  else
5341
    {
5342
      /* 32-bit offset, need multiple instructions and AT, like:
5343
           lui      $tempreg,const_hi       (BFD_RELOC_HI16_S)
5344
           addu     $tempreg,$tempreg,$breg
5345
           <op>     $treg,const_lo($tempreg)   (BFD_RELOC_LO16)
5346
         to handle the complete offset.  */
5347
      macro_build_lui (ep, AT);
5348
      macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t", AT, AT, breg);
5349
      macro_build (ep, op, "t,o(b)", treg, BFD_RELOC_LO16, AT);
5350
 
5351
      if (!mips_opts.at)
5352
        as_bad (_("Macro used $at after \".set noat\""));
5353
    }
5354
}
5355
 
5356
/*                      set_at()
5357
 * Generates code to set the $at register to true (one)
5358
 * if reg is less than the immediate expression.
5359
 */
5360
static void
5361
set_at (int reg, int unsignedp)
5362
{
5363
  if (imm_expr.X_op == O_constant
5364
      && imm_expr.X_add_number >= -0x8000
5365
      && imm_expr.X_add_number < 0x8000)
5366
    macro_build (&imm_expr, unsignedp ? "sltiu" : "slti", "t,r,j",
5367
                 AT, reg, BFD_RELOC_LO16);
5368
  else
5369
    {
5370
      load_register (AT, &imm_expr, HAVE_64BIT_GPRS);
5371
      macro_build (NULL, unsignedp ? "sltu" : "slt", "d,v,t", AT, reg, AT);
5372
    }
5373
}
5374
 
5375
/* Warn if an expression is not a constant.  */
5376
 
5377
static void
5378
check_absolute_expr (struct mips_cl_insn *ip, expressionS *ex)
5379
{
5380
  if (ex->X_op == O_big)
5381
    as_bad (_("unsupported large constant"));
5382
  else if (ex->X_op != O_constant)
5383
    as_bad (_("Instruction %s requires absolute expression"),
5384
            ip->insn_mo->name);
5385
 
5386
  if (HAVE_32BIT_GPRS)
5387
    normalize_constant_expr (ex);
5388
}
5389
 
5390
/* Count the leading zeroes by performing a binary chop. This is a
5391
   bulky bit of source, but performance is a LOT better for the
5392
   majority of values than a simple loop to count the bits:
5393
       for (lcnt = 0; (lcnt < 32); lcnt++)
5394
         if ((v) & (1 << (31 - lcnt)))
5395
           break;
5396
  However it is not code size friendly, and the gain will drop a bit
5397
  on certain cached systems.
5398
*/
5399
#define COUNT_TOP_ZEROES(v)             \
5400
  (((v) & ~0xffff) == 0                 \
5401
   ? ((v) & ~0xff) == 0                 \
5402
     ? ((v) & ~0xf) == 0                \
5403
       ? ((v) & ~0x3) == 0              \
5404
         ? ((v) & ~0x1) == 0            \
5405
           ? !(v)                       \
5406
             ? 32                       \
5407
             : 31                       \
5408
           : 30                         \
5409
         : ((v) & ~0x7) == 0            \
5410
           ? 29                         \
5411
           : 28                         \
5412
       : ((v) & ~0x3f) == 0             \
5413
         ? ((v) & ~0x1f) == 0           \
5414
           ? 27                         \
5415
           : 26                         \
5416
         : ((v) & ~0x7f) == 0           \
5417
           ? 25                         \
5418
           : 24                         \
5419
     : ((v) & ~0xfff) == 0              \
5420
       ? ((v) & ~0x3ff) == 0            \
5421
         ? ((v) & ~0x1ff) == 0          \
5422
           ? 23                         \
5423
           : 22                         \
5424
         : ((v) & ~0x7ff) == 0          \
5425
           ? 21                         \
5426
           : 20                         \
5427
       : ((v) & ~0x3fff) == 0           \
5428
         ? ((v) & ~0x1fff) == 0         \
5429
           ? 19                         \
5430
           : 18                         \
5431
         : ((v) & ~0x7fff) == 0         \
5432
           ? 17                         \
5433
           : 16                         \
5434
   : ((v) & ~0xffffff) == 0             \
5435
     ? ((v) & ~0xfffff) == 0            \
5436
       ? ((v) & ~0x3ffff) == 0          \
5437
         ? ((v) & ~0x1ffff) == 0        \
5438
           ? 15                         \
5439
           : 14                         \
5440
         : ((v) & ~0x7ffff) == 0        \
5441
           ? 13                         \
5442
           : 12                         \
5443
       : ((v) & ~0x3fffff) == 0         \
5444
         ? ((v) & ~0x1fffff) == 0       \
5445
           ? 11                         \
5446
           : 10                         \
5447
         : ((v) & ~0x7fffff) == 0       \
5448
           ? 9                          \
5449
           : 8                          \
5450
     : ((v) & ~0xfffffff) == 0          \
5451
       ? ((v) & ~0x3ffffff) == 0        \
5452
         ? ((v) & ~0x1ffffff) == 0      \
5453
           ? 7                          \
5454
           : 6                          \
5455
         : ((v) & ~0x7ffffff) == 0      \
5456
           ? 5                          \
5457
           : 4                          \
5458
       : ((v) & ~0x3fffffff) == 0       \
5459
         ? ((v) & ~0x1fffffff) == 0     \
5460
           ? 3                          \
5461
           : 2                          \
5462
         : ((v) & ~0x7fffffff) == 0     \
5463
           ? 1                          \
5464
           : 0)
5465
 
5466
/*                      load_register()
5467
 *  This routine generates the least number of instructions necessary to load
5468
 *  an absolute expression value into a register.
5469
 */
5470
static void
5471
load_register (int reg, expressionS *ep, int dbl)
5472
{
5473
  int freg;
5474
  expressionS hi32, lo32;
5475
 
5476
  if (ep->X_op != O_big)
5477
    {
5478
      gas_assert (ep->X_op == O_constant);
5479
 
5480
      /* Sign-extending 32-bit constants makes their handling easier.  */
5481
      if (!dbl)
5482
        normalize_constant_expr (ep);
5483
 
5484
      if (IS_SEXT_16BIT_NUM (ep->X_add_number))
5485
        {
5486
          /* We can handle 16 bit signed values with an addiu to
5487
             $zero.  No need to ever use daddiu here, since $zero and
5488
             the result are always correct in 32 bit mode.  */
5489
          macro_build (ep, "addiu", "t,r,j", reg, 0, BFD_RELOC_LO16);
5490
          return;
5491
        }
5492
      else if (ep->X_add_number >= 0 && ep->X_add_number < 0x10000)
5493
        {
5494
          /* We can handle 16 bit unsigned values with an ori to
5495
             $zero.  */
5496
          macro_build (ep, "ori", "t,r,i", reg, 0, BFD_RELOC_LO16);
5497
          return;
5498
        }
5499
      else if ((IS_SEXT_32BIT_NUM (ep->X_add_number)))
5500
        {
5501
          /* 32 bit values require an lui.  */
5502 160 khays
          macro_build (ep, "lui", LUI_FMT, reg, BFD_RELOC_HI16);
5503 16 khays
          if ((ep->X_add_number & 0xffff) != 0)
5504
            macro_build (ep, "ori", "t,r,i", reg, reg, BFD_RELOC_LO16);
5505
          return;
5506
        }
5507
    }
5508
 
5509
  /* The value is larger than 32 bits.  */
5510
 
5511
  if (!dbl || HAVE_32BIT_GPRS)
5512
    {
5513
      char value[32];
5514
 
5515
      sprintf_vma (value, ep->X_add_number);
5516
      as_bad (_("Number (0x%s) larger than 32 bits"), value);
5517
      macro_build (ep, "addiu", "t,r,j", reg, 0, BFD_RELOC_LO16);
5518
      return;
5519
    }
5520
 
5521
  if (ep->X_op != O_big)
5522
    {
5523
      hi32 = *ep;
5524
      hi32.X_add_number = (valueT) hi32.X_add_number >> 16;
5525
      hi32.X_add_number = (valueT) hi32.X_add_number >> 16;
5526
      hi32.X_add_number &= 0xffffffff;
5527
      lo32 = *ep;
5528
      lo32.X_add_number &= 0xffffffff;
5529
    }
5530
  else
5531
    {
5532
      gas_assert (ep->X_add_number > 2);
5533
      if (ep->X_add_number == 3)
5534
        generic_bignum[3] = 0;
5535
      else if (ep->X_add_number > 4)
5536
        as_bad (_("Number larger than 64 bits"));
5537
      lo32.X_op = O_constant;
5538
      lo32.X_add_number = generic_bignum[0] + (generic_bignum[1] << 16);
5539
      hi32.X_op = O_constant;
5540
      hi32.X_add_number = generic_bignum[2] + (generic_bignum[3] << 16);
5541
    }
5542
 
5543
  if (hi32.X_add_number == 0)
5544
    freg = 0;
5545
  else
5546
    {
5547
      int shift, bit;
5548
      unsigned long hi, lo;
5549
 
5550
      if (hi32.X_add_number == (offsetT) 0xffffffff)
5551
        {
5552
          if ((lo32.X_add_number & 0xffff8000) == 0xffff8000)
5553
            {
5554
              macro_build (&lo32, "addiu", "t,r,j", reg, 0, BFD_RELOC_LO16);
5555
              return;
5556
            }
5557
          if (lo32.X_add_number & 0x80000000)
5558
            {
5559 160 khays
              macro_build (&lo32, "lui", LUI_FMT, reg, BFD_RELOC_HI16);
5560 16 khays
              if (lo32.X_add_number & 0xffff)
5561
                macro_build (&lo32, "ori", "t,r,i", reg, reg, BFD_RELOC_LO16);
5562
              return;
5563
            }
5564
        }
5565
 
5566
      /* Check for 16bit shifted constant.  We know that hi32 is
5567
         non-zero, so start the mask on the first bit of the hi32
5568
         value.  */
5569
      shift = 17;
5570
      do
5571
        {
5572
          unsigned long himask, lomask;
5573
 
5574
          if (shift < 32)
5575
            {
5576
              himask = 0xffff >> (32 - shift);
5577
              lomask = (0xffff << shift) & 0xffffffff;
5578
            }
5579
          else
5580
            {
5581
              himask = 0xffff << (shift - 32);
5582
              lomask = 0;
5583
            }
5584
          if ((hi32.X_add_number & ~(offsetT) himask) == 0
5585
              && (lo32.X_add_number & ~(offsetT) lomask) == 0)
5586
            {
5587
              expressionS tmp;
5588
 
5589
              tmp.X_op = O_constant;
5590
              if (shift < 32)
5591
                tmp.X_add_number = ((hi32.X_add_number << (32 - shift))
5592
                                    | (lo32.X_add_number >> shift));
5593
              else
5594
                tmp.X_add_number = hi32.X_add_number >> (shift - 32);
5595
              macro_build (&tmp, "ori", "t,r,i", reg, 0, BFD_RELOC_LO16);
5596 160 khays
              macro_build (NULL, (shift >= 32) ? "dsll32" : "dsll", SHFT_FMT,
5597 16 khays
                           reg, reg, (shift >= 32) ? shift - 32 : shift);
5598
              return;
5599
            }
5600
          ++shift;
5601
        }
5602
      while (shift <= (64 - 16));
5603
 
5604
      /* Find the bit number of the lowest one bit, and store the
5605
         shifted value in hi/lo.  */
5606
      hi = (unsigned long) (hi32.X_add_number & 0xffffffff);
5607
      lo = (unsigned long) (lo32.X_add_number & 0xffffffff);
5608
      if (lo != 0)
5609
        {
5610
          bit = 0;
5611
          while ((lo & 1) == 0)
5612
            {
5613
              lo >>= 1;
5614
              ++bit;
5615
            }
5616
          lo |= (hi & (((unsigned long) 1 << bit) - 1)) << (32 - bit);
5617
          hi >>= bit;
5618
        }
5619
      else
5620
        {
5621
          bit = 32;
5622
          while ((hi & 1) == 0)
5623
            {
5624
              hi >>= 1;
5625
              ++bit;
5626
            }
5627
          lo = hi;
5628
          hi = 0;
5629
        }
5630
 
5631
      /* Optimize if the shifted value is a (power of 2) - 1.  */
5632
      if ((hi == 0 && ((lo + 1) & lo) == 0)
5633
          || (lo == 0xffffffff && ((hi + 1) & hi) == 0))
5634
        {
5635
          shift = COUNT_TOP_ZEROES ((unsigned int) hi32.X_add_number);
5636
          if (shift != 0)
5637
            {
5638
              expressionS tmp;
5639
 
5640
              /* This instruction will set the register to be all
5641
                 ones.  */
5642
              tmp.X_op = O_constant;
5643
              tmp.X_add_number = (offsetT) -1;
5644
              macro_build (&tmp, "addiu", "t,r,j", reg, 0, BFD_RELOC_LO16);
5645
              if (bit != 0)
5646
                {
5647
                  bit += shift;
5648 160 khays
                  macro_build (NULL, (bit >= 32) ? "dsll32" : "dsll", SHFT_FMT,
5649 16 khays
                               reg, reg, (bit >= 32) ? bit - 32 : bit);
5650
                }
5651 160 khays
              macro_build (NULL, (shift >= 32) ? "dsrl32" : "dsrl", SHFT_FMT,
5652 16 khays
                           reg, reg, (shift >= 32) ? shift - 32 : shift);
5653
              return;
5654
            }
5655
        }
5656
 
5657
      /* Sign extend hi32 before calling load_register, because we can
5658
         generally get better code when we load a sign extended value.  */
5659
      if ((hi32.X_add_number & 0x80000000) != 0)
5660
        hi32.X_add_number |= ~(offsetT) 0xffffffff;
5661
      load_register (reg, &hi32, 0);
5662
      freg = reg;
5663
    }
5664
  if ((lo32.X_add_number & 0xffff0000) == 0)
5665
    {
5666
      if (freg != 0)
5667
        {
5668 160 khays
          macro_build (NULL, "dsll32", SHFT_FMT, reg, freg, 0);
5669 16 khays
          freg = reg;
5670
        }
5671
    }
5672
  else
5673
    {
5674
      expressionS mid16;
5675
 
5676
      if ((freg == 0) && (lo32.X_add_number == (offsetT) 0xffffffff))
5677
        {
5678 160 khays
          macro_build (&lo32, "lui", LUI_FMT, reg, BFD_RELOC_HI16);
5679
          macro_build (NULL, "dsrl32", SHFT_FMT, reg, reg, 0);
5680 16 khays
          return;
5681
        }
5682
 
5683
      if (freg != 0)
5684
        {
5685 160 khays
          macro_build (NULL, "dsll", SHFT_FMT, reg, freg, 16);
5686 16 khays
          freg = reg;
5687
        }
5688
      mid16 = lo32;
5689
      mid16.X_add_number >>= 16;
5690
      macro_build (&mid16, "ori", "t,r,i", reg, freg, BFD_RELOC_LO16);
5691 160 khays
      macro_build (NULL, "dsll", SHFT_FMT, reg, reg, 16);
5692 16 khays
      freg = reg;
5693
    }
5694
  if ((lo32.X_add_number & 0xffff) != 0)
5695
    macro_build (&lo32, "ori", "t,r,i", reg, freg, BFD_RELOC_LO16);
5696
}
5697
 
5698
static inline void
5699
load_delay_nop (void)
5700
{
5701
  if (!gpr_interlocks)
5702
    macro_build (NULL, "nop", "");
5703
}
5704
 
5705
/* Load an address into a register.  */
5706
 
5707
static void
5708
load_address (int reg, expressionS *ep, int *used_at)
5709
{
5710
  if (ep->X_op != O_constant
5711
      && ep->X_op != O_symbol)
5712
    {
5713
      as_bad (_("expression too complex"));
5714
      ep->X_op = O_constant;
5715
    }
5716
 
5717
  if (ep->X_op == O_constant)
5718
    {
5719
      load_register (reg, ep, HAVE_64BIT_ADDRESSES);
5720
      return;
5721
    }
5722
 
5723
  if (mips_pic == NO_PIC)
5724
    {
5725
      /* If this is a reference to a GP relative symbol, we want
5726
           addiu        $reg,$gp,<sym>          (BFD_RELOC_GPREL16)
5727
         Otherwise we want
5728
           lui          $reg,<sym>              (BFD_RELOC_HI16_S)
5729
           addiu        $reg,$reg,<sym>         (BFD_RELOC_LO16)
5730
         If we have an addend, we always use the latter form.
5731
 
5732
         With 64bit address space and a usable $at we want
5733
           lui          $reg,<sym>              (BFD_RELOC_MIPS_HIGHEST)
5734
           lui          $at,<sym>               (BFD_RELOC_HI16_S)
5735
           daddiu       $reg,<sym>              (BFD_RELOC_MIPS_HIGHER)
5736
           daddiu       $at,<sym>               (BFD_RELOC_LO16)
5737
           dsll32       $reg,0
5738
           daddu        $reg,$reg,$at
5739
 
5740
         If $at is already in use, we use a path which is suboptimal
5741
         on superscalar processors.
5742
           lui          $reg,<sym>              (BFD_RELOC_MIPS_HIGHEST)
5743
           daddiu       $reg,<sym>              (BFD_RELOC_MIPS_HIGHER)
5744
           dsll         $reg,16
5745
           daddiu       $reg,<sym>              (BFD_RELOC_HI16_S)
5746
           dsll         $reg,16
5747
           daddiu       $reg,<sym>              (BFD_RELOC_LO16)
5748
 
5749
         For GP relative symbols in 64bit address space we can use
5750
         the same sequence as in 32bit address space.  */
5751
      if (HAVE_64BIT_SYMBOLS)
5752
        {
5753
          if ((valueT) ep->X_add_number <= MAX_GPREL_OFFSET
5754
              && !nopic_need_relax (ep->X_add_symbol, 1))
5755
            {
5756
              relax_start (ep->X_add_symbol);
5757
              macro_build (ep, ADDRESS_ADDI_INSN, "t,r,j", reg,
5758
                           mips_gp_register, BFD_RELOC_GPREL16);
5759
              relax_switch ();
5760
            }
5761
 
5762
          if (*used_at == 0 && mips_opts.at)
5763
            {
5764 160 khays
              macro_build (ep, "lui", LUI_FMT, reg, BFD_RELOC_MIPS_HIGHEST);
5765
              macro_build (ep, "lui", LUI_FMT, AT, BFD_RELOC_HI16_S);
5766 16 khays
              macro_build (ep, "daddiu", "t,r,j", reg, reg,
5767
                           BFD_RELOC_MIPS_HIGHER);
5768
              macro_build (ep, "daddiu", "t,r,j", AT, AT, BFD_RELOC_LO16);
5769 160 khays
              macro_build (NULL, "dsll32", SHFT_FMT, reg, reg, 0);
5770 16 khays
              macro_build (NULL, "daddu", "d,v,t", reg, reg, AT);
5771
              *used_at = 1;
5772
            }
5773
          else
5774
            {
5775 160 khays
              macro_build (ep, "lui", LUI_FMT, reg, BFD_RELOC_MIPS_HIGHEST);
5776 16 khays
              macro_build (ep, "daddiu", "t,r,j", reg, reg,
5777
                           BFD_RELOC_MIPS_HIGHER);
5778 160 khays
              macro_build (NULL, "dsll", SHFT_FMT, reg, reg, 16);
5779 16 khays
              macro_build (ep, "daddiu", "t,r,j", reg, reg, BFD_RELOC_HI16_S);
5780 160 khays
              macro_build (NULL, "dsll", SHFT_FMT, reg, reg, 16);
5781 16 khays
              macro_build (ep, "daddiu", "t,r,j", reg, reg, BFD_RELOC_LO16);
5782
            }
5783
 
5784
          if (mips_relax.sequence)
5785
            relax_end ();
5786
        }
5787
      else
5788
        {
5789
          if ((valueT) ep->X_add_number <= MAX_GPREL_OFFSET
5790
              && !nopic_need_relax (ep->X_add_symbol, 1))
5791
            {
5792
              relax_start (ep->X_add_symbol);
5793
              macro_build (ep, ADDRESS_ADDI_INSN, "t,r,j", reg,
5794
                           mips_gp_register, BFD_RELOC_GPREL16);
5795
              relax_switch ();
5796
            }
5797
          macro_build_lui (ep, reg);
5798
          macro_build (ep, ADDRESS_ADDI_INSN, "t,r,j",
5799
                       reg, reg, BFD_RELOC_LO16);
5800
          if (mips_relax.sequence)
5801
            relax_end ();
5802
        }
5803
    }
5804
  else if (!mips_big_got)
5805
    {
5806
      expressionS ex;
5807
 
5808
      /* If this is a reference to an external symbol, we want
5809
           lw           $reg,<sym>($gp)         (BFD_RELOC_MIPS_GOT16)
5810
         Otherwise we want
5811
           lw           $reg,<sym>($gp)         (BFD_RELOC_MIPS_GOT16)
5812
           nop
5813
           addiu        $reg,$reg,<sym>         (BFD_RELOC_LO16)
5814
         If there is a constant, it must be added in after.
5815
 
5816
         If we have NewABI, we want
5817
           lw           $reg,<sym+cst>($gp)     (BFD_RELOC_MIPS_GOT_DISP)
5818
         unless we're referencing a global symbol with a non-zero
5819
         offset, in which case cst must be added separately.  */
5820
      if (HAVE_NEWABI)
5821
        {
5822
          if (ep->X_add_number)
5823
            {
5824
              ex.X_add_number = ep->X_add_number;
5825
              ep->X_add_number = 0;
5826
              relax_start (ep->X_add_symbol);
5827
              macro_build (ep, ADDRESS_LOAD_INSN, "t,o(b)", reg,
5828
                           BFD_RELOC_MIPS_GOT_DISP, mips_gp_register);
5829
              if (ex.X_add_number < -0x8000 || ex.X_add_number >= 0x8000)
5830
                as_bad (_("PIC code offset overflow (max 16 signed bits)"));
5831
              ex.X_op = O_constant;
5832
              macro_build (&ex, ADDRESS_ADDI_INSN, "t,r,j",
5833
                           reg, reg, BFD_RELOC_LO16);
5834
              ep->X_add_number = ex.X_add_number;
5835
              relax_switch ();
5836
            }
5837
          macro_build (ep, ADDRESS_LOAD_INSN, "t,o(b)", reg,
5838
                       BFD_RELOC_MIPS_GOT_DISP, mips_gp_register);
5839
          if (mips_relax.sequence)
5840
            relax_end ();
5841
        }
5842
      else
5843
        {
5844
          ex.X_add_number = ep->X_add_number;
5845
          ep->X_add_number = 0;
5846
          macro_build (ep, ADDRESS_LOAD_INSN, "t,o(b)", reg,
5847
                       BFD_RELOC_MIPS_GOT16, mips_gp_register);
5848
          load_delay_nop ();
5849
          relax_start (ep->X_add_symbol);
5850
          relax_switch ();
5851
          macro_build (ep, ADDRESS_ADDI_INSN, "t,r,j", reg, reg,
5852
                       BFD_RELOC_LO16);
5853
          relax_end ();
5854
 
5855
          if (ex.X_add_number != 0)
5856
            {
5857
              if (ex.X_add_number < -0x8000 || ex.X_add_number >= 0x8000)
5858
                as_bad (_("PIC code offset overflow (max 16 signed bits)"));
5859
              ex.X_op = O_constant;
5860
              macro_build (&ex, ADDRESS_ADDI_INSN, "t,r,j",
5861
                           reg, reg, BFD_RELOC_LO16);
5862
            }
5863
        }
5864
    }
5865
  else if (mips_big_got)
5866
    {
5867
      expressionS ex;
5868
 
5869
      /* This is the large GOT case.  If this is a reference to an
5870
         external symbol, we want
5871
           lui          $reg,<sym>              (BFD_RELOC_MIPS_GOT_HI16)
5872
           addu         $reg,$reg,$gp
5873
           lw           $reg,<sym>($reg)        (BFD_RELOC_MIPS_GOT_LO16)
5874
 
5875
         Otherwise, for a reference to a local symbol in old ABI, we want
5876
           lw           $reg,<sym>($gp)         (BFD_RELOC_MIPS_GOT16)
5877
           nop
5878
           addiu        $reg,$reg,<sym>         (BFD_RELOC_LO16)
5879
         If there is a constant, it must be added in after.
5880
 
5881
         In the NewABI, for local symbols, with or without offsets, we want:
5882
           lw           $reg,<sym>($gp)         (BFD_RELOC_MIPS_GOT_PAGE)
5883
           addiu        $reg,$reg,<sym>         (BFD_RELOC_MIPS_GOT_OFST)
5884
      */
5885
      if (HAVE_NEWABI)
5886
        {
5887
          ex.X_add_number = ep->X_add_number;
5888
          ep->X_add_number = 0;
5889
          relax_start (ep->X_add_symbol);
5890 160 khays
          macro_build (ep, "lui", LUI_FMT, reg, BFD_RELOC_MIPS_GOT_HI16);
5891 16 khays
          macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t",
5892
                       reg, reg, mips_gp_register);
5893
          macro_build (ep, ADDRESS_LOAD_INSN, "t,o(b)",
5894
                       reg, BFD_RELOC_MIPS_GOT_LO16, reg);
5895
          if (ex.X_add_number < -0x8000 || ex.X_add_number >= 0x8000)
5896
            as_bad (_("PIC code offset overflow (max 16 signed bits)"));
5897
          else if (ex.X_add_number)
5898
            {
5899
              ex.X_op = O_constant;
5900
              macro_build (&ex, ADDRESS_ADDI_INSN, "t,r,j", reg, reg,
5901
                           BFD_RELOC_LO16);
5902
            }
5903
 
5904
          ep->X_add_number = ex.X_add_number;
5905
          relax_switch ();
5906
          macro_build (ep, ADDRESS_LOAD_INSN, "t,o(b)", reg,
5907
                       BFD_RELOC_MIPS_GOT_PAGE, mips_gp_register);
5908
          macro_build (ep, ADDRESS_ADDI_INSN, "t,r,j", reg, reg,
5909
                       BFD_RELOC_MIPS_GOT_OFST);
5910
          relax_end ();
5911
        }
5912
      else
5913
        {
5914
          ex.X_add_number = ep->X_add_number;
5915
          ep->X_add_number = 0;
5916
          relax_start (ep->X_add_symbol);
5917 160 khays
          macro_build (ep, "lui", LUI_FMT, reg, BFD_RELOC_MIPS_GOT_HI16);
5918 16 khays
          macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t",
5919
                       reg, reg, mips_gp_register);
5920
          macro_build (ep, ADDRESS_LOAD_INSN, "t,o(b)",
5921
                       reg, BFD_RELOC_MIPS_GOT_LO16, reg);
5922
          relax_switch ();
5923
          if (reg_needs_delay (mips_gp_register))
5924
            {
5925
              /* We need a nop before loading from $gp.  This special
5926
                 check is required because the lui which starts the main
5927
                 instruction stream does not refer to $gp, and so will not
5928
                 insert the nop which may be required.  */
5929
              macro_build (NULL, "nop", "");
5930
            }
5931
          macro_build (ep, ADDRESS_LOAD_INSN, "t,o(b)", reg,
5932
                       BFD_RELOC_MIPS_GOT16, mips_gp_register);
5933
          load_delay_nop ();
5934
          macro_build (ep, ADDRESS_ADDI_INSN, "t,r,j", reg, reg,
5935
                       BFD_RELOC_LO16);
5936
          relax_end ();
5937
 
5938
          if (ex.X_add_number != 0)
5939
            {
5940
              if (ex.X_add_number < -0x8000 || ex.X_add_number >= 0x8000)
5941
                as_bad (_("PIC code offset overflow (max 16 signed bits)"));
5942
              ex.X_op = O_constant;
5943
              macro_build (&ex, ADDRESS_ADDI_INSN, "t,r,j", reg, reg,
5944
                           BFD_RELOC_LO16);
5945
            }
5946
        }
5947
    }
5948
  else
5949
    abort ();
5950
 
5951
  if (!mips_opts.at && *used_at == 1)
5952
    as_bad (_("Macro used $at after \".set noat\""));
5953
}
5954
 
5955
/* Move the contents of register SOURCE into register DEST.  */
5956
 
5957
static void
5958
move_register (int dest, int source)
5959
{
5960 160 khays
  /* Prefer to use a 16-bit microMIPS instruction unless the previous
5961
     instruction specifically requires a 32-bit one.  */
5962
  if (mips_opts.micromips
5963
      && !(history[0].insn_mo->pinfo2 & INSN2_BRANCH_DELAY_32BIT))
5964 163 khays
    macro_build (NULL, "move", "mp,mj", dest, source);
5965 160 khays
  else
5966
    macro_build (NULL, HAVE_32BIT_GPRS ? "addu" : "daddu", "d,v,t",
5967
                 dest, source, 0);
5968 16 khays
}
5969
 
5970
/* Emit an SVR4 PIC sequence to load address LOCAL into DEST, where
5971
   LOCAL is the sum of a symbol and a 16-bit or 32-bit displacement.
5972
   The two alternatives are:
5973
 
5974
   Global symbol                Local sybmol
5975
   -------------                ------------
5976
   lw DEST,%got(SYMBOL)         lw DEST,%got(SYMBOL + OFFSET)
5977
   ...                          ...
5978
   addiu DEST,DEST,OFFSET       addiu DEST,DEST,%lo(SYMBOL + OFFSET)
5979
 
5980
   load_got_offset emits the first instruction and add_got_offset
5981
   emits the second for a 16-bit offset or add_got_offset_hilo emits
5982
   a sequence to add a 32-bit offset using a scratch register.  */
5983
 
5984
static void
5985
load_got_offset (int dest, expressionS *local)
5986
{
5987
  expressionS global;
5988
 
5989
  global = *local;
5990
  global.X_add_number = 0;
5991
 
5992
  relax_start (local->X_add_symbol);
5993
  macro_build (&global, ADDRESS_LOAD_INSN, "t,o(b)", dest,
5994
               BFD_RELOC_MIPS_GOT16, mips_gp_register);
5995
  relax_switch ();
5996
  macro_build (local, ADDRESS_LOAD_INSN, "t,o(b)", dest,
5997
               BFD_RELOC_MIPS_GOT16, mips_gp_register);
5998
  relax_end ();
5999
}
6000
 
6001
static void
6002
add_got_offset (int dest, expressionS *local)
6003
{
6004
  expressionS global;
6005
 
6006
  global.X_op = O_constant;
6007
  global.X_op_symbol = NULL;
6008
  global.X_add_symbol = NULL;
6009
  global.X_add_number = local->X_add_number;
6010
 
6011
  relax_start (local->X_add_symbol);
6012
  macro_build (&global, ADDRESS_ADDI_INSN, "t,r,j",
6013
               dest, dest, BFD_RELOC_LO16);
6014
  relax_switch ();
6015
  macro_build (local, ADDRESS_ADDI_INSN, "t,r,j", dest, dest, BFD_RELOC_LO16);
6016
  relax_end ();
6017
}
6018
 
6019
static void
6020
add_got_offset_hilo (int dest, expressionS *local, int tmp)
6021
{
6022
  expressionS global;
6023
  int hold_mips_optimize;
6024
 
6025
  global.X_op = O_constant;
6026
  global.X_op_symbol = NULL;
6027
  global.X_add_symbol = NULL;
6028
  global.X_add_number = local->X_add_number;
6029
 
6030
  relax_start (local->X_add_symbol);
6031
  load_register (tmp, &global, HAVE_64BIT_ADDRESSES);
6032
  relax_switch ();
6033
  /* Set mips_optimize around the lui instruction to avoid
6034
     inserting an unnecessary nop after the lw.  */
6035
  hold_mips_optimize = mips_optimize;
6036
  mips_optimize = 2;
6037
  macro_build_lui (&global, tmp);
6038
  mips_optimize = hold_mips_optimize;
6039
  macro_build (local, ADDRESS_ADDI_INSN, "t,r,j", tmp, tmp, BFD_RELOC_LO16);
6040
  relax_end ();
6041
 
6042
  macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t", dest, dest, tmp);
6043
}
6044
 
6045 160 khays
/* Emit a sequence of instructions to emulate a branch likely operation.
6046
   BR is an ordinary branch corresponding to one to be emulated.  BRNEG
6047
   is its complementing branch with the original condition negated.
6048
   CALL is set if the original branch specified the link operation.
6049
   EP, FMT, SREG and TREG specify the usual macro_build() parameters.
6050
 
6051
   Code like this is produced in the noreorder mode:
6052
 
6053
        BRNEG   <args>, 1f
6054
         nop
6055
        b       <sym>
6056
         delay slot (executed only if branch taken)
6057
    1:
6058
 
6059
   or, if CALL is set:
6060
 
6061
        BRNEG   <args>, 1f
6062
         nop
6063
        bal     <sym>
6064
         delay slot (executed only if branch taken)
6065
    1:
6066
 
6067
   In the reorder mode the delay slot would be filled with a nop anyway,
6068
   so code produced is simply:
6069
 
6070
        BR      <args>, <sym>
6071
         nop
6072
 
6073
   This function is used when producing code for the microMIPS ASE that
6074
   does not implement branch likely instructions in hardware.  */
6075
 
6076
static void
6077
macro_build_branch_likely (const char *br, const char *brneg,
6078
                           int call, expressionS *ep, const char *fmt,
6079
                           unsigned int sreg, unsigned int treg)
6080
{
6081
  int noreorder = mips_opts.noreorder;
6082
  expressionS expr1;
6083
 
6084
  gas_assert (mips_opts.micromips);
6085
  start_noreorder ();
6086
  if (noreorder)
6087
    {
6088
      micromips_label_expr (&expr1);
6089
      macro_build (&expr1, brneg, fmt, sreg, treg);
6090
      macro_build (NULL, "nop", "");
6091
      macro_build (ep, call ? "bal" : "b", "p");
6092
 
6093
      /* Set to true so that append_insn adds a label.  */
6094
      emit_branch_likely_macro = TRUE;
6095
    }
6096
  else
6097
    {
6098
      macro_build (ep, br, fmt, sreg, treg);
6099
      macro_build (NULL, "nop", "");
6100
    }
6101
  end_noreorder ();
6102
}
6103
 
6104
/* Emit a coprocessor branch-likely macro specified by TYPE, using CC as
6105
   the condition code tested.  EP specifies the branch target.  */
6106
 
6107
static void
6108
macro_build_branch_ccl (int type, expressionS *ep, unsigned int cc)
6109
{
6110
  const int call = 0;
6111
  const char *brneg;
6112
  const char *br;
6113
 
6114
  switch (type)
6115
    {
6116
    case M_BC1FL:
6117
      br = "bc1f";
6118
      brneg = "bc1t";
6119
      break;
6120
    case M_BC1TL:
6121
      br = "bc1t";
6122
      brneg = "bc1f";
6123
      break;
6124
    case M_BC2FL:
6125
      br = "bc2f";
6126
      brneg = "bc2t";
6127
      break;
6128
    case M_BC2TL:
6129
      br = "bc2t";
6130
      brneg = "bc2f";
6131
      break;
6132
    default:
6133
      abort ();
6134
    }
6135
  macro_build_branch_likely (br, brneg, call, ep, "N,p", cc, ZERO);
6136
}
6137
 
6138
/* Emit a two-argument branch macro specified by TYPE, using SREG as
6139
   the register tested.  EP specifies the branch target.  */
6140
 
6141
static void
6142
macro_build_branch_rs (int type, expressionS *ep, unsigned int sreg)
6143
{
6144
  const char *brneg = NULL;
6145
  const char *br;
6146
  int call = 0;
6147
 
6148
  switch (type)
6149
    {
6150
    case M_BGEZ:
6151
      br = "bgez";
6152
      break;
6153
    case M_BGEZL:
6154
      br = mips_opts.micromips ? "bgez" : "bgezl";
6155
      brneg = "bltz";
6156
      break;
6157
    case M_BGEZALL:
6158
      gas_assert (mips_opts.micromips);
6159
      br = "bgezals";
6160
      brneg = "bltz";
6161
      call = 1;
6162
      break;
6163
    case M_BGTZ:
6164
      br = "bgtz";
6165
      break;
6166
    case M_BGTZL:
6167
      br = mips_opts.micromips ? "bgtz" : "bgtzl";
6168
      brneg = "blez";
6169
      break;
6170
    case M_BLEZ:
6171
      br = "blez";
6172
      break;
6173
    case M_BLEZL:
6174
      br = mips_opts.micromips ? "blez" : "blezl";
6175
      brneg = "bgtz";
6176
      break;
6177
    case M_BLTZ:
6178
      br = "bltz";
6179
      break;
6180
    case M_BLTZL:
6181
      br = mips_opts.micromips ? "bltz" : "bltzl";
6182
      brneg = "bgez";
6183
      break;
6184
    case M_BLTZALL:
6185
      gas_assert (mips_opts.micromips);
6186
      br = "bltzals";
6187
      brneg = "bgez";
6188
      call = 1;
6189
      break;
6190
    default:
6191
      abort ();
6192
    }
6193
  if (mips_opts.micromips && brneg)
6194
    macro_build_branch_likely (br, brneg, call, ep, "s,p", sreg, ZERO);
6195
  else
6196
    macro_build (ep, br, "s,p", sreg);
6197
}
6198
 
6199
/* Emit a three-argument branch macro specified by TYPE, using SREG and
6200
   TREG as the registers tested.  EP specifies the branch target.  */
6201
 
6202
static void
6203
macro_build_branch_rsrt (int type, expressionS *ep,
6204
                         unsigned int sreg, unsigned int treg)
6205
{
6206
  const char *brneg = NULL;
6207
  const int call = 0;
6208
  const char *br;
6209
 
6210
  switch (type)
6211
    {
6212
    case M_BEQ:
6213
    case M_BEQ_I:
6214
      br = "beq";
6215
      break;
6216
    case M_BEQL:
6217
    case M_BEQL_I:
6218
      br = mips_opts.micromips ? "beq" : "beql";
6219
      brneg = "bne";
6220
      break;
6221
    case M_BNE:
6222
    case M_BNE_I:
6223
      br = "bne";
6224
      break;
6225
    case M_BNEL:
6226
    case M_BNEL_I:
6227
      br = mips_opts.micromips ? "bne" : "bnel";
6228
      brneg = "beq";
6229
      break;
6230
    default:
6231
      abort ();
6232
    }
6233
  if (mips_opts.micromips && brneg)
6234
    macro_build_branch_likely (br, brneg, call, ep, "s,t,p", sreg, treg);
6235
  else
6236
    macro_build (ep, br, "s,t,p", sreg, treg);
6237
}
6238
 
6239 16 khays
/*
6240
 *                      Build macros
6241
 *   This routine implements the seemingly endless macro or synthesized
6242
 * instructions and addressing modes in the mips assembly language. Many
6243
 * of these macros are simple and are similar to each other. These could
6244
 * probably be handled by some kind of table or grammar approach instead of
6245
 * this verbose method. Others are not simple macros but are more like
6246
 * optimizing code generation.
6247
 *   One interesting optimization is when several store macros appear
6248
 * consecutively that would load AT with the upper half of the same address.
6249
 * The ensuing load upper instructions are ommited. This implies some kind
6250
 * of global optimization. We currently only optimize within a single macro.
6251
 *   For many of the load and store macros if the address is specified as a
6252
 * constant expression in the first 64k of memory (ie ld $2,0x4000c) we
6253
 * first load register 'at' with zero and use it as the base register. The
6254
 * mips assembler simply uses register $zero. Just one tiny optimization
6255
 * we're missing.
6256
 */
6257
static void
6258
macro (struct mips_cl_insn *ip)
6259
{
6260
  unsigned int treg, sreg, dreg, breg;
6261
  unsigned int tempreg;
6262
  int mask;
6263
  int used_at = 0;
6264 160 khays
  expressionS label_expr;
6265 16 khays
  expressionS expr1;
6266 160 khays
  expressionS *ep;
6267 16 khays
  const char *s;
6268
  const char *s2;
6269
  const char *fmt;
6270
  int likely = 0;
6271 160 khays
  int coproc = 0;
6272
  int off12 = 0;
6273
  int call = 0;
6274
  int jals = 0;
6275 16 khays
  int dbl = 0;
6276
  int imm = 0;
6277 160 khays
  int ust = 0;
6278
  int lp = 0;
6279
  int ab = 0;
6280 166 khays
  int off0 = 0;
6281 16 khays
  int off;
6282
  offsetT maxnum;
6283
  bfd_reloc_code_real_type r;
6284
  int hold_mips_optimize;
6285
 
6286
  gas_assert (! mips_opts.mips16);
6287
 
6288 160 khays
  treg = EXTRACT_OPERAND (mips_opts.micromips, RT, *ip);
6289
  dreg = EXTRACT_OPERAND (mips_opts.micromips, RD, *ip);
6290
  sreg = breg = EXTRACT_OPERAND (mips_opts.micromips, RS, *ip);
6291 16 khays
  mask = ip->insn_mo->mask;
6292
 
6293 160 khays
  label_expr.X_op = O_constant;
6294
  label_expr.X_op_symbol = NULL;
6295
  label_expr.X_add_symbol = NULL;
6296
  label_expr.X_add_number = 0;
6297
 
6298 16 khays
  expr1.X_op = O_constant;
6299
  expr1.X_op_symbol = NULL;
6300
  expr1.X_add_symbol = NULL;
6301
  expr1.X_add_number = 1;
6302
 
6303
  switch (mask)
6304
    {
6305
    case M_DABS:
6306
      dbl = 1;
6307
    case M_ABS:
6308 160 khays
      /*    bgez    $a0,1f
6309
            move    v0,$a0
6310
            sub     v0,$zero,$a0
6311
         1:
6312
       */
6313 16 khays
 
6314
      start_noreorder ();
6315
 
6316 160 khays
      if (mips_opts.micromips)
6317
        micromips_label_expr (&label_expr);
6318
      else
6319
        label_expr.X_add_number = 8;
6320
      macro_build (&label_expr, "bgez", "s,p", sreg);
6321 16 khays
      if (dreg == sreg)
6322
        macro_build (NULL, "nop", "");
6323
      else
6324
        move_register (dreg, sreg);
6325
      macro_build (NULL, dbl ? "dsub" : "sub", "d,v,t", dreg, 0, sreg);
6326 160 khays
      if (mips_opts.micromips)
6327
        micromips_add_label ();
6328 16 khays
 
6329
      end_noreorder ();
6330
      break;
6331
 
6332
    case M_ADD_I:
6333
      s = "addi";
6334
      s2 = "add";
6335
      goto do_addi;
6336
    case M_ADDU_I:
6337
      s = "addiu";
6338
      s2 = "addu";
6339
      goto do_addi;
6340
    case M_DADD_I:
6341
      dbl = 1;
6342
      s = "daddi";
6343
      s2 = "dadd";
6344 160 khays
      if (!mips_opts.micromips)
6345
        goto do_addi;
6346
      if (imm_expr.X_op == O_constant
6347
          && imm_expr.X_add_number >= -0x200
6348
          && imm_expr.X_add_number < 0x200)
6349
        {
6350
          macro_build (NULL, s, "t,r,.", treg, sreg, imm_expr.X_add_number);
6351
          break;
6352
        }
6353
      goto do_addi_i;
6354 16 khays
    case M_DADDU_I:
6355
      dbl = 1;
6356
      s = "daddiu";
6357
      s2 = "daddu";
6358
    do_addi:
6359
      if (imm_expr.X_op == O_constant
6360
          && imm_expr.X_add_number >= -0x8000
6361
          && imm_expr.X_add_number < 0x8000)
6362
        {
6363
          macro_build (&imm_expr, s, "t,r,j", treg, sreg, BFD_RELOC_LO16);
6364
          break;
6365
        }
6366 160 khays
    do_addi_i:
6367 16 khays
      used_at = 1;
6368
      load_register (AT, &imm_expr, dbl);
6369
      macro_build (NULL, s2, "d,v,t", treg, sreg, AT);
6370
      break;
6371
 
6372
    case M_AND_I:
6373
      s = "andi";
6374
      s2 = "and";
6375
      goto do_bit;
6376
    case M_OR_I:
6377
      s = "ori";
6378
      s2 = "or";
6379
      goto do_bit;
6380
    case M_NOR_I:
6381
      s = "";
6382
      s2 = "nor";
6383
      goto do_bit;
6384
    case M_XOR_I:
6385
      s = "xori";
6386
      s2 = "xor";
6387
    do_bit:
6388
      if (imm_expr.X_op == O_constant
6389
          && imm_expr.X_add_number >= 0
6390
          && imm_expr.X_add_number < 0x10000)
6391
        {
6392
          if (mask != M_NOR_I)
6393
            macro_build (&imm_expr, s, "t,r,i", treg, sreg, BFD_RELOC_LO16);
6394
          else
6395
            {
6396
              macro_build (&imm_expr, "ori", "t,r,i",
6397
                           treg, sreg, BFD_RELOC_LO16);
6398
              macro_build (NULL, "nor", "d,v,t", treg, treg, 0);
6399
            }
6400
          break;
6401
        }
6402
 
6403
      used_at = 1;
6404
      load_register (AT, &imm_expr, HAVE_64BIT_GPRS);
6405
      macro_build (NULL, s2, "d,v,t", treg, sreg, AT);
6406
      break;
6407
 
6408
    case M_BALIGN:
6409
      switch (imm_expr.X_add_number)
6410
        {
6411
        case 0:
6412
          macro_build (NULL, "nop", "");
6413
          break;
6414
        case 2:
6415
          macro_build (NULL, "packrl.ph", "d,s,t", treg, treg, sreg);
6416
          break;
6417
        default:
6418
          macro_build (NULL, "balign", "t,s,2", treg, sreg,
6419
                       (int) imm_expr.X_add_number);
6420
          break;
6421
        }
6422
      break;
6423
 
6424 160 khays
    case M_BC1FL:
6425
    case M_BC1TL:
6426
    case M_BC2FL:
6427
    case M_BC2TL:
6428
      gas_assert (mips_opts.micromips);
6429
      macro_build_branch_ccl (mask, &offset_expr,
6430
                              EXTRACT_OPERAND (1, BCC, *ip));
6431
      break;
6432
 
6433 16 khays
    case M_BEQ_I:
6434
    case M_BEQL_I:
6435
    case M_BNE_I:
6436
    case M_BNEL_I:
6437
      if (imm_expr.X_op == O_constant && imm_expr.X_add_number == 0)
6438 160 khays
        treg = 0;
6439
      else
6440 16 khays
        {
6441 160 khays
          treg = AT;
6442
          used_at = 1;
6443
          load_register (treg, &imm_expr, HAVE_64BIT_GPRS);
6444 16 khays
        }
6445 160 khays
      /* Fall through.  */
6446
    case M_BEQL:
6447
    case M_BNEL:
6448
      macro_build_branch_rsrt (mask, &offset_expr, sreg, treg);
6449 16 khays
      break;
6450
 
6451
    case M_BGEL:
6452
      likely = 1;
6453
    case M_BGE:
6454
      if (treg == 0)
6455 160 khays
        macro_build_branch_rs (likely ? M_BGEZL : M_BGEZ, &offset_expr, sreg);
6456
      else if (sreg == 0)
6457
        macro_build_branch_rs (likely ? M_BLEZL : M_BLEZ, &offset_expr, treg);
6458
      else
6459 16 khays
        {
6460 160 khays
          used_at = 1;
6461
          macro_build (NULL, "slt", "d,v,t", AT, sreg, treg);
6462
          macro_build_branch_rsrt (likely ? M_BEQL : M_BEQ,
6463
                                   &offset_expr, AT, ZERO);
6464 16 khays
        }
6465
      break;
6466
 
6467 160 khays
    case M_BGEZL:
6468
    case M_BGEZALL:
6469
    case M_BGTZL:
6470
    case M_BLEZL:
6471
    case M_BLTZL:
6472
    case M_BLTZALL:
6473
      macro_build_branch_rs (mask, &offset_expr, sreg);
6474
      break;
6475
 
6476 16 khays
    case M_BGTL_I:
6477
      likely = 1;
6478
    case M_BGT_I:
6479
      /* Check for > max integer.  */
6480
      maxnum = 0x7fffffff;
6481
      if (HAVE_64BIT_GPRS && sizeof (maxnum) > 4)
6482
        {
6483
          maxnum <<= 16;
6484
          maxnum |= 0xffff;
6485
          maxnum <<= 16;
6486
          maxnum |= 0xffff;
6487
        }
6488
      if (imm_expr.X_op == O_constant
6489
          && imm_expr.X_add_number >= maxnum
6490
          && (HAVE_32BIT_GPRS || sizeof (maxnum) > 4))
6491
        {
6492
        do_false:
6493
          /* Result is always false.  */
6494
          if (! likely)
6495
            macro_build (NULL, "nop", "");
6496
          else
6497 160 khays
            macro_build_branch_rsrt (M_BNEL, &offset_expr, ZERO, ZERO);
6498 16 khays
          break;
6499
        }
6500
      if (imm_expr.X_op != O_constant)
6501
        as_bad (_("Unsupported large constant"));
6502
      ++imm_expr.X_add_number;
6503
      /* FALLTHROUGH */
6504
    case M_BGE_I:
6505
    case M_BGEL_I:
6506
      if (mask == M_BGEL_I)
6507
        likely = 1;
6508
      if (imm_expr.X_op == O_constant && imm_expr.X_add_number == 0)
6509
        {
6510 160 khays
          macro_build_branch_rs (likely ? M_BGEZL : M_BGEZ,
6511
                                 &offset_expr, sreg);
6512 16 khays
          break;
6513
        }
6514
      if (imm_expr.X_op == O_constant && imm_expr.X_add_number == 1)
6515
        {
6516 160 khays
          macro_build_branch_rs (likely ? M_BGTZL : M_BGTZ,
6517
                                 &offset_expr, sreg);
6518 16 khays
          break;
6519
        }
6520
      maxnum = 0x7fffffff;
6521
      if (HAVE_64BIT_GPRS && sizeof (maxnum) > 4)
6522
        {
6523
          maxnum <<= 16;
6524
          maxnum |= 0xffff;
6525
          maxnum <<= 16;
6526
          maxnum |= 0xffff;
6527
        }
6528
      maxnum = - maxnum - 1;
6529
      if (imm_expr.X_op == O_constant
6530
          && imm_expr.X_add_number <= maxnum
6531
          && (HAVE_32BIT_GPRS || sizeof (maxnum) > 4))
6532
        {
6533
        do_true:
6534
          /* result is always true */
6535
          as_warn (_("Branch %s is always true"), ip->insn_mo->name);
6536
          macro_build (&offset_expr, "b", "p");
6537
          break;
6538
        }
6539
      used_at = 1;
6540
      set_at (sreg, 0);
6541 160 khays
      macro_build_branch_rsrt (likely ? M_BEQL : M_BEQ,
6542
                               &offset_expr, AT, ZERO);
6543 16 khays
      break;
6544
 
6545
    case M_BGEUL:
6546
      likely = 1;
6547
    case M_BGEU:
6548
      if (treg == 0)
6549
        goto do_true;
6550 160 khays
      else if (sreg == 0)
6551
        macro_build_branch_rsrt (likely ? M_BEQL : M_BEQ,
6552
                                 &offset_expr, ZERO, treg);
6553
      else
6554 16 khays
        {
6555 160 khays
          used_at = 1;
6556
          macro_build (NULL, "sltu", "d,v,t", AT, sreg, treg);
6557
          macro_build_branch_rsrt (likely ? M_BEQL : M_BEQ,
6558
                                   &offset_expr, AT, ZERO);
6559 16 khays
        }
6560
      break;
6561
 
6562
    case M_BGTUL_I:
6563
      likely = 1;
6564
    case M_BGTU_I:
6565
      if (sreg == 0
6566
          || (HAVE_32BIT_GPRS
6567
              && imm_expr.X_op == O_constant
6568
              && imm_expr.X_add_number == -1))
6569
        goto do_false;
6570
      if (imm_expr.X_op != O_constant)
6571
        as_bad (_("Unsupported large constant"));
6572
      ++imm_expr.X_add_number;
6573
      /* FALLTHROUGH */
6574
    case M_BGEU_I:
6575
    case M_BGEUL_I:
6576
      if (mask == M_BGEUL_I)
6577
        likely = 1;
6578
      if (imm_expr.X_op == O_constant && imm_expr.X_add_number == 0)
6579
        goto do_true;
6580 160 khays
      else if (imm_expr.X_op == O_constant && imm_expr.X_add_number == 1)
6581
        macro_build_branch_rsrt (likely ? M_BNEL : M_BNE,
6582
                                 &offset_expr, sreg, ZERO);
6583
      else
6584 16 khays
        {
6585 160 khays
          used_at = 1;
6586
          set_at (sreg, 1);
6587
          macro_build_branch_rsrt (likely ? M_BEQL : M_BEQ,
6588
                                   &offset_expr, AT, ZERO);
6589 16 khays
        }
6590
      break;
6591
 
6592
    case M_BGTL:
6593
      likely = 1;
6594
    case M_BGT:
6595
      if (treg == 0)
6596 160 khays
        macro_build_branch_rs (likely ? M_BGTZL : M_BGTZ, &offset_expr, sreg);
6597
      else if (sreg == 0)
6598
        macro_build_branch_rs (likely ? M_BLTZL : M_BLTZ, &offset_expr, treg);
6599
      else
6600 16 khays
        {
6601 160 khays
          used_at = 1;
6602
          macro_build (NULL, "slt", "d,v,t", AT, treg, sreg);
6603
          macro_build_branch_rsrt (likely ? M_BNEL : M_BNE,
6604
                                   &offset_expr, AT, ZERO);
6605 16 khays
        }
6606
      break;
6607
 
6608
    case M_BGTUL:
6609
      likely = 1;
6610
    case M_BGTU:
6611
      if (treg == 0)
6612 160 khays
        macro_build_branch_rsrt (likely ? M_BNEL : M_BNE,
6613
                                 &offset_expr, sreg, ZERO);
6614
      else if (sreg == 0)
6615
        goto do_false;
6616
      else
6617 16 khays
        {
6618 160 khays
          used_at = 1;
6619
          macro_build (NULL, "sltu", "d,v,t", AT, treg, sreg);
6620
          macro_build_branch_rsrt (likely ? M_BNEL : M_BNE,
6621
                                   &offset_expr, AT, ZERO);
6622 16 khays
        }
6623
      break;
6624
 
6625
    case M_BLEL:
6626
      likely = 1;
6627
    case M_BLE:
6628
      if (treg == 0)
6629 160 khays
        macro_build_branch_rs (likely ? M_BLEZL : M_BLEZ, &offset_expr, sreg);
6630
      else if (sreg == 0)
6631
        macro_build_branch_rs (likely ? M_BGEZL : M_BGEZ, &offset_expr, treg);
6632
      else
6633 16 khays
        {
6634 160 khays
          used_at = 1;
6635
          macro_build (NULL, "slt", "d,v,t", AT, treg, sreg);
6636
          macro_build_branch_rsrt (likely ? M_BEQL : M_BEQ,
6637
                                   &offset_expr, AT, ZERO);
6638 16 khays
        }
6639
      break;
6640
 
6641
    case M_BLEL_I:
6642
      likely = 1;
6643
    case M_BLE_I:
6644
      maxnum = 0x7fffffff;
6645
      if (HAVE_64BIT_GPRS && sizeof (maxnum) > 4)
6646
        {
6647
          maxnum <<= 16;
6648
          maxnum |= 0xffff;
6649
          maxnum <<= 16;
6650
          maxnum |= 0xffff;
6651
        }
6652
      if (imm_expr.X_op == O_constant
6653
          && imm_expr.X_add_number >= maxnum
6654
          && (HAVE_32BIT_GPRS || sizeof (maxnum) > 4))
6655
        goto do_true;
6656
      if (imm_expr.X_op != O_constant)
6657
        as_bad (_("Unsupported large constant"));
6658
      ++imm_expr.X_add_number;
6659
      /* FALLTHROUGH */
6660
    case M_BLT_I:
6661
    case M_BLTL_I:
6662
      if (mask == M_BLTL_I)
6663
        likely = 1;
6664
      if (imm_expr.X_op == O_constant && imm_expr.X_add_number == 0)
6665 160 khays
        macro_build_branch_rs (likely ? M_BLTZL : M_BLTZ, &offset_expr, sreg);
6666
      else if (imm_expr.X_op == O_constant && imm_expr.X_add_number == 1)
6667
        macro_build_branch_rs (likely ? M_BLEZL : M_BLEZ, &offset_expr, sreg);
6668
      else
6669 16 khays
        {
6670 160 khays
          used_at = 1;
6671
          set_at (sreg, 0);
6672
          macro_build_branch_rsrt (likely ? M_BNEL : M_BNE,
6673
                                   &offset_expr, AT, ZERO);
6674 16 khays
        }
6675
      break;
6676
 
6677
    case M_BLEUL:
6678
      likely = 1;
6679
    case M_BLEU:
6680
      if (treg == 0)
6681 160 khays
        macro_build_branch_rsrt (likely ? M_BEQL : M_BEQ,
6682
                                 &offset_expr, sreg, ZERO);
6683
      else if (sreg == 0)
6684
        goto do_true;
6685
      else
6686 16 khays
        {
6687 160 khays
          used_at = 1;
6688
          macro_build (NULL, "sltu", "d,v,t", AT, treg, sreg);
6689
          macro_build_branch_rsrt (likely ? M_BEQL : M_BEQ,
6690
                                   &offset_expr, AT, ZERO);
6691 16 khays
        }
6692
      break;
6693
 
6694
    case M_BLEUL_I:
6695
      likely = 1;
6696
    case M_BLEU_I:
6697
      if (sreg == 0
6698
          || (HAVE_32BIT_GPRS
6699
              && imm_expr.X_op == O_constant
6700
              && imm_expr.X_add_number == -1))
6701
        goto do_true;
6702
      if (imm_expr.X_op != O_constant)
6703
        as_bad (_("Unsupported large constant"));
6704
      ++imm_expr.X_add_number;
6705
      /* FALLTHROUGH */
6706
    case M_BLTU_I:
6707
    case M_BLTUL_I:
6708
      if (mask == M_BLTUL_I)
6709
        likely = 1;
6710
      if (imm_expr.X_op == O_constant && imm_expr.X_add_number == 0)
6711
        goto do_false;
6712 160 khays
      else if (imm_expr.X_op == O_constant && imm_expr.X_add_number == 1)
6713
        macro_build_branch_rsrt (likely ? M_BEQL : M_BEQ,
6714
                                 &offset_expr, sreg, ZERO);
6715
      else
6716 16 khays
        {
6717 160 khays
          used_at = 1;
6718
          set_at (sreg, 1);
6719
          macro_build_branch_rsrt (likely ? M_BNEL : M_BNE,
6720
                                   &offset_expr, AT, ZERO);
6721 16 khays
        }
6722
      break;
6723
 
6724
    case M_BLTL:
6725
      likely = 1;
6726
    case M_BLT:
6727
      if (treg == 0)
6728 160 khays
        macro_build_branch_rs (likely ? M_BLTZL : M_BLTZ, &offset_expr, sreg);
6729
      else if (sreg == 0)
6730
        macro_build_branch_rs (likely ? M_BGTZL : M_BGTZ, &offset_expr, treg);
6731
      else
6732 16 khays
        {
6733 160 khays
          used_at = 1;
6734
          macro_build (NULL, "slt", "d,v,t", AT, sreg, treg);
6735
          macro_build_branch_rsrt (likely ? M_BNEL : M_BNE,
6736
                                   &offset_expr, AT, ZERO);
6737 16 khays
        }
6738
      break;
6739
 
6740
    case M_BLTUL:
6741
      likely = 1;
6742
    case M_BLTU:
6743
      if (treg == 0)
6744
        goto do_false;
6745 160 khays
      else if (sreg == 0)
6746
        macro_build_branch_rsrt (likely ? M_BNEL : M_BNE,
6747
                                 &offset_expr, ZERO, treg);
6748
      else
6749 16 khays
        {
6750 160 khays
          used_at = 1;
6751
          macro_build (NULL, "sltu", "d,v,t", AT, sreg, treg);
6752
          macro_build_branch_rsrt (likely ? M_BNEL : M_BNE,
6753
                                   &offset_expr, AT, ZERO);
6754 16 khays
        }
6755
      break;
6756
 
6757
    case M_DEXT:
6758
      {
6759
        /* Use unsigned arithmetic.  */
6760
        addressT pos;
6761
        addressT size;
6762
 
6763
        if (imm_expr.X_op != O_constant || imm2_expr.X_op != O_constant)
6764
          {
6765
            as_bad (_("Unsupported large constant"));
6766
            pos = size = 1;
6767
          }
6768
        else
6769
          {
6770
            pos = imm_expr.X_add_number;
6771
            size = imm2_expr.X_add_number;
6772
          }
6773
 
6774
        if (pos > 63)
6775
          {
6776
            as_bad (_("Improper position (%lu)"), (unsigned long) pos);
6777
            pos = 1;
6778
          }
6779
        if (size == 0 || size > 64 || (pos + size - 1) > 63)
6780
          {
6781
            as_bad (_("Improper extract size (%lu, position %lu)"),
6782
                    (unsigned long) size, (unsigned long) pos);
6783
            size = 1;
6784
          }
6785
 
6786
        if (size <= 32 && pos < 32)
6787
          {
6788
            s = "dext";
6789
            fmt = "t,r,+A,+C";
6790
          }
6791
        else if (size <= 32)
6792
          {
6793
            s = "dextu";
6794
            fmt = "t,r,+E,+H";
6795
          }
6796
        else
6797
          {
6798
            s = "dextm";
6799
            fmt = "t,r,+A,+G";
6800
          }
6801
        macro_build ((expressionS *) NULL, s, fmt, treg, sreg, (int) pos,
6802
                     (int) (size - 1));
6803
      }
6804
      break;
6805
 
6806
    case M_DINS:
6807
      {
6808
        /* Use unsigned arithmetic.  */
6809
        addressT pos;
6810
        addressT size;
6811
 
6812
        if (imm_expr.X_op != O_constant || imm2_expr.X_op != O_constant)
6813
          {
6814
            as_bad (_("Unsupported large constant"));
6815
            pos = size = 1;
6816
          }
6817
        else
6818
          {
6819
            pos = imm_expr.X_add_number;
6820
            size = imm2_expr.X_add_number;
6821
          }
6822
 
6823
        if (pos > 63)
6824
          {
6825
            as_bad (_("Improper position (%lu)"), (unsigned long) pos);
6826
            pos = 1;
6827
          }
6828
        if (size == 0 || size > 64 || (pos + size - 1) > 63)
6829
          {
6830
            as_bad (_("Improper insert size (%lu, position %lu)"),
6831
                    (unsigned long) size, (unsigned long) pos);
6832
            size = 1;
6833
          }
6834
 
6835
        if (pos < 32 && (pos + size - 1) < 32)
6836
          {
6837
            s = "dins";
6838
            fmt = "t,r,+A,+B";
6839
          }
6840
        else if (pos >= 32)
6841
          {
6842
            s = "dinsu";
6843
            fmt = "t,r,+E,+F";
6844
          }
6845
        else
6846
          {
6847
            s = "dinsm";
6848
            fmt = "t,r,+A,+F";
6849
          }
6850
        macro_build ((expressionS *) NULL, s, fmt, treg, sreg, (int) pos,
6851
                     (int) (pos + size - 1));
6852
      }
6853
      break;
6854
 
6855
    case M_DDIV_3:
6856
      dbl = 1;
6857
    case M_DIV_3:
6858
      s = "mflo";
6859
      goto do_div3;
6860
    case M_DREM_3:
6861
      dbl = 1;
6862
    case M_REM_3:
6863
      s = "mfhi";
6864
    do_div3:
6865
      if (treg == 0)
6866
        {
6867
          as_warn (_("Divide by zero."));
6868
          if (mips_trap)
6869 160 khays
            macro_build (NULL, "teq", TRAP_FMT, ZERO, ZERO, 7);
6870 16 khays
          else
6871 160 khays
            macro_build (NULL, "break", BRK_FMT, 7);
6872 16 khays
          break;
6873
        }
6874
 
6875
      start_noreorder ();
6876
      if (mips_trap)
6877
        {
6878 160 khays
          macro_build (NULL, "teq", TRAP_FMT, treg, ZERO, 7);
6879 16 khays
          macro_build (NULL, dbl ? "ddiv" : "div", "z,s,t", sreg, treg);
6880
        }
6881
      else
6882
        {
6883 160 khays
          if (mips_opts.micromips)
6884
            micromips_label_expr (&label_expr);
6885
          else
6886
            label_expr.X_add_number = 8;
6887
          macro_build (&label_expr, "bne", "s,t,p", treg, ZERO);
6888 16 khays
          macro_build (NULL, dbl ? "ddiv" : "div", "z,s,t", sreg, treg);
6889 160 khays
          macro_build (NULL, "break", BRK_FMT, 7);
6890
          if (mips_opts.micromips)
6891
            micromips_add_label ();
6892 16 khays
        }
6893
      expr1.X_add_number = -1;
6894
      used_at = 1;
6895
      load_register (AT, &expr1, dbl);
6896 160 khays
      if (mips_opts.micromips)
6897
        micromips_label_expr (&label_expr);
6898
      else
6899
        label_expr.X_add_number = mips_trap ? (dbl ? 12 : 8) : (dbl ? 20 : 16);
6900
      macro_build (&label_expr, "bne", "s,t,p", treg, AT);
6901 16 khays
      if (dbl)
6902
        {
6903
          expr1.X_add_number = 1;
6904
          load_register (AT, &expr1, dbl);
6905 160 khays
          macro_build (NULL, "dsll32", SHFT_FMT, AT, AT, 31);
6906 16 khays
        }
6907
      else
6908
        {
6909
          expr1.X_add_number = 0x80000000;
6910 160 khays
          macro_build (&expr1, "lui", LUI_FMT, AT, BFD_RELOC_HI16);
6911 16 khays
        }
6912
      if (mips_trap)
6913
        {
6914 160 khays
          macro_build (NULL, "teq", TRAP_FMT, sreg, AT, 6);
6915 16 khays
          /* We want to close the noreorder block as soon as possible, so
6916
             that later insns are available for delay slot filling.  */
6917
          end_noreorder ();
6918
        }
6919
      else
6920
        {
6921 160 khays
          if (mips_opts.micromips)
6922
            micromips_label_expr (&label_expr);
6923
          else
6924
            label_expr.X_add_number = 8;
6925
          macro_build (&label_expr, "bne", "s,t,p", sreg, AT);
6926 16 khays
          macro_build (NULL, "nop", "");
6927
 
6928
          /* We want to close the noreorder block as soon as possible, so
6929
             that later insns are available for delay slot filling.  */
6930
          end_noreorder ();
6931
 
6932 160 khays
          macro_build (NULL, "break", BRK_FMT, 6);
6933 16 khays
        }
6934 160 khays
      if (mips_opts.micromips)
6935
        micromips_add_label ();
6936
      macro_build (NULL, s, MFHL_FMT, dreg);
6937 16 khays
      break;
6938
 
6939
    case M_DIV_3I:
6940
      s = "div";
6941
      s2 = "mflo";
6942
      goto do_divi;
6943
    case M_DIVU_3I:
6944
      s = "divu";
6945
      s2 = "mflo";
6946
      goto do_divi;
6947
    case M_REM_3I:
6948
      s = "div";
6949
      s2 = "mfhi";
6950
      goto do_divi;
6951
    case M_REMU_3I:
6952
      s = "divu";
6953
      s2 = "mfhi";
6954
      goto do_divi;
6955
    case M_DDIV_3I:
6956
      dbl = 1;
6957
      s = "ddiv";
6958
      s2 = "mflo";
6959
      goto do_divi;
6960
    case M_DDIVU_3I:
6961
      dbl = 1;
6962
      s = "ddivu";
6963
      s2 = "mflo";
6964
      goto do_divi;
6965
    case M_DREM_3I:
6966
      dbl = 1;
6967
      s = "ddiv";
6968
      s2 = "mfhi";
6969
      goto do_divi;
6970
    case M_DREMU_3I:
6971
      dbl = 1;
6972
      s = "ddivu";
6973
      s2 = "mfhi";
6974
    do_divi:
6975
      if (imm_expr.X_op == O_constant && imm_expr.X_add_number == 0)
6976
        {
6977
          as_warn (_("Divide by zero."));
6978
          if (mips_trap)
6979 160 khays
            macro_build (NULL, "teq", TRAP_FMT, ZERO, ZERO, 7);
6980 16 khays
          else
6981 160 khays
            macro_build (NULL, "break", BRK_FMT, 7);
6982 16 khays
          break;
6983
        }
6984
      if (imm_expr.X_op == O_constant && imm_expr.X_add_number == 1)
6985
        {
6986
          if (strcmp (s2, "mflo") == 0)
6987
            move_register (dreg, sreg);
6988
          else
6989
            move_register (dreg, ZERO);
6990
          break;
6991
        }
6992
      if (imm_expr.X_op == O_constant
6993
          && imm_expr.X_add_number == -1
6994
          && s[strlen (s) - 1] != 'u')
6995
        {
6996
          if (strcmp (s2, "mflo") == 0)
6997
            {
6998
              macro_build (NULL, dbl ? "dneg" : "neg", "d,w", dreg, sreg);
6999
            }
7000
          else
7001
            move_register (dreg, ZERO);
7002
          break;
7003
        }
7004
 
7005
      used_at = 1;
7006
      load_register (AT, &imm_expr, dbl);
7007
      macro_build (NULL, s, "z,s,t", sreg, AT);
7008 160 khays
      macro_build (NULL, s2, MFHL_FMT, dreg);
7009 16 khays
      break;
7010
 
7011
    case M_DIVU_3:
7012
      s = "divu";
7013
      s2 = "mflo";
7014
      goto do_divu3;
7015
    case M_REMU_3:
7016
      s = "divu";
7017
      s2 = "mfhi";
7018
      goto do_divu3;
7019
    case M_DDIVU_3:
7020
      s = "ddivu";
7021
      s2 = "mflo";
7022
      goto do_divu3;
7023
    case M_DREMU_3:
7024
      s = "ddivu";
7025
      s2 = "mfhi";
7026
    do_divu3:
7027
      start_noreorder ();
7028
      if (mips_trap)
7029
        {
7030 160 khays
          macro_build (NULL, "teq", TRAP_FMT, treg, ZERO, 7);
7031 16 khays
          macro_build (NULL, s, "z,s,t", sreg, treg);
7032
          /* We want to close the noreorder block as soon as possible, so
7033
             that later insns are available for delay slot filling.  */
7034
          end_noreorder ();
7035
        }
7036
      else
7037
        {
7038 160 khays
          if (mips_opts.micromips)
7039
            micromips_label_expr (&label_expr);
7040
          else
7041
            label_expr.X_add_number = 8;
7042
          macro_build (&label_expr, "bne", "s,t,p", treg, ZERO);
7043 16 khays
          macro_build (NULL, s, "z,s,t", sreg, treg);
7044
 
7045
          /* We want to close the noreorder block as soon as possible, so
7046
             that later insns are available for delay slot filling.  */
7047
          end_noreorder ();
7048 160 khays
          macro_build (NULL, "break", BRK_FMT, 7);
7049
          if (mips_opts.micromips)
7050
            micromips_add_label ();
7051 16 khays
        }
7052 160 khays
      macro_build (NULL, s2, MFHL_FMT, dreg);
7053 16 khays
      break;
7054
 
7055
    case M_DLCA_AB:
7056
      dbl = 1;
7057
    case M_LCA_AB:
7058
      call = 1;
7059
      goto do_la;
7060
    case M_DLA_AB:
7061
      dbl = 1;
7062
    case M_LA_AB:
7063
    do_la:
7064
      /* Load the address of a symbol into a register.  If breg is not
7065
         zero, we then add a base register to it.  */
7066
 
7067
      if (dbl && HAVE_32BIT_GPRS)
7068
        as_warn (_("dla used to load 32-bit register"));
7069
 
7070
      if (!dbl && HAVE_64BIT_OBJECTS)
7071
        as_warn (_("la used to load 64-bit address"));
7072
 
7073
      if (offset_expr.X_op == O_constant
7074
          && offset_expr.X_add_number >= -0x8000
7075
          && offset_expr.X_add_number < 0x8000)
7076
        {
7077
          macro_build (&offset_expr, ADDRESS_ADDI_INSN,
7078
                       "t,r,j", treg, sreg, BFD_RELOC_LO16);
7079
          break;
7080
        }
7081
 
7082
      if (mips_opts.at && (treg == breg))
7083
        {
7084
          tempreg = AT;
7085
          used_at = 1;
7086
        }
7087
      else
7088
        {
7089
          tempreg = treg;
7090
        }
7091
 
7092
      if (offset_expr.X_op != O_symbol
7093
          && offset_expr.X_op != O_constant)
7094
        {
7095
          as_bad (_("Expression too complex"));
7096
          offset_expr.X_op = O_constant;
7097
        }
7098
 
7099
      if (offset_expr.X_op == O_constant)
7100
        load_register (tempreg, &offset_expr, HAVE_64BIT_ADDRESSES);
7101
      else if (mips_pic == NO_PIC)
7102
        {
7103
          /* If this is a reference to a GP relative symbol, we want
7104
               addiu    $tempreg,$gp,<sym>      (BFD_RELOC_GPREL16)
7105
             Otherwise we want
7106
               lui      $tempreg,<sym>          (BFD_RELOC_HI16_S)
7107
               addiu    $tempreg,$tempreg,<sym> (BFD_RELOC_LO16)
7108
             If we have a constant, we need two instructions anyhow,
7109
             so we may as well always use the latter form.
7110
 
7111
             With 64bit address space and a usable $at we want
7112
               lui      $tempreg,<sym>          (BFD_RELOC_MIPS_HIGHEST)
7113
               lui      $at,<sym>               (BFD_RELOC_HI16_S)
7114
               daddiu   $tempreg,<sym>          (BFD_RELOC_MIPS_HIGHER)
7115
               daddiu   $at,<sym>               (BFD_RELOC_LO16)
7116
               dsll32   $tempreg,0
7117
               daddu    $tempreg,$tempreg,$at
7118
 
7119
             If $at is already in use, we use a path which is suboptimal
7120
             on superscalar processors.
7121
               lui      $tempreg,<sym>          (BFD_RELOC_MIPS_HIGHEST)
7122
               daddiu   $tempreg,<sym>          (BFD_RELOC_MIPS_HIGHER)
7123
               dsll     $tempreg,16
7124
               daddiu   $tempreg,<sym>          (BFD_RELOC_HI16_S)
7125
               dsll     $tempreg,16
7126
               daddiu   $tempreg,<sym>          (BFD_RELOC_LO16)
7127
 
7128
             For GP relative symbols in 64bit address space we can use
7129
             the same sequence as in 32bit address space.  */
7130
          if (HAVE_64BIT_SYMBOLS)
7131
            {
7132
              if ((valueT) offset_expr.X_add_number <= MAX_GPREL_OFFSET
7133
                  && !nopic_need_relax (offset_expr.X_add_symbol, 1))
7134
                {
7135
                  relax_start (offset_expr.X_add_symbol);
7136
                  macro_build (&offset_expr, ADDRESS_ADDI_INSN, "t,r,j",
7137
                               tempreg, mips_gp_register, BFD_RELOC_GPREL16);
7138
                  relax_switch ();
7139
                }
7140
 
7141
              if (used_at == 0 && mips_opts.at)
7142
                {
7143 160 khays
                  macro_build (&offset_expr, "lui", LUI_FMT,
7144 16 khays
                               tempreg, BFD_RELOC_MIPS_HIGHEST);
7145 160 khays
                  macro_build (&offset_expr, "lui", LUI_FMT,
7146 16 khays
                               AT, BFD_RELOC_HI16_S);
7147
                  macro_build (&offset_expr, "daddiu", "t,r,j",
7148
                               tempreg, tempreg, BFD_RELOC_MIPS_HIGHER);
7149
                  macro_build (&offset_expr, "daddiu", "t,r,j",
7150
                               AT, AT, BFD_RELOC_LO16);
7151 160 khays
                  macro_build (NULL, "dsll32", SHFT_FMT, tempreg, tempreg, 0);
7152 16 khays
                  macro_build (NULL, "daddu", "d,v,t", tempreg, tempreg, AT);
7153
                  used_at = 1;
7154
                }
7155
              else
7156
                {
7157 160 khays
                  macro_build (&offset_expr, "lui", LUI_FMT,
7158 16 khays
                               tempreg, BFD_RELOC_MIPS_HIGHEST);
7159
                  macro_build (&offset_expr, "daddiu", "t,r,j",
7160
                               tempreg, tempreg, BFD_RELOC_MIPS_HIGHER);
7161 160 khays
                  macro_build (NULL, "dsll", SHFT_FMT, tempreg, tempreg, 16);
7162 16 khays
                  macro_build (&offset_expr, "daddiu", "t,r,j",
7163
                               tempreg, tempreg, BFD_RELOC_HI16_S);
7164 160 khays
                  macro_build (NULL, "dsll", SHFT_FMT, tempreg, tempreg, 16);
7165 16 khays
                  macro_build (&offset_expr, "daddiu", "t,r,j",
7166
                               tempreg, tempreg, BFD_RELOC_LO16);
7167
                }
7168
 
7169
              if (mips_relax.sequence)
7170
                relax_end ();
7171
            }
7172
          else
7173
            {
7174
              if ((valueT) offset_expr.X_add_number <= MAX_GPREL_OFFSET
7175
                  && !nopic_need_relax (offset_expr.X_add_symbol, 1))
7176
                {
7177
                  relax_start (offset_expr.X_add_symbol);
7178
                  macro_build (&offset_expr, ADDRESS_ADDI_INSN, "t,r,j",
7179
                               tempreg, mips_gp_register, BFD_RELOC_GPREL16);
7180
                  relax_switch ();
7181
                }
7182
              if (!IS_SEXT_32BIT_NUM (offset_expr.X_add_number))
7183
                as_bad (_("Offset too large"));
7184
              macro_build_lui (&offset_expr, tempreg);
7185
              macro_build (&offset_expr, ADDRESS_ADDI_INSN, "t,r,j",
7186
                           tempreg, tempreg, BFD_RELOC_LO16);
7187
              if (mips_relax.sequence)
7188
                relax_end ();
7189
            }
7190
        }
7191
      else if (!mips_big_got && !HAVE_NEWABI)
7192
        {
7193
          int lw_reloc_type = (int) BFD_RELOC_MIPS_GOT16;
7194
 
7195
          /* If this is a reference to an external symbol, and there
7196
             is no constant, we want
7197
               lw       $tempreg,<sym>($gp)     (BFD_RELOC_MIPS_GOT16)
7198
             or for lca or if tempreg is PIC_CALL_REG
7199
               lw       $tempreg,<sym>($gp)     (BFD_RELOC_MIPS_CALL16)
7200
             For a local symbol, we want
7201
               lw       $tempreg,<sym>($gp)     (BFD_RELOC_MIPS_GOT16)
7202
               nop
7203
               addiu    $tempreg,$tempreg,<sym> (BFD_RELOC_LO16)
7204
 
7205
             If we have a small constant, and this is a reference to
7206
             an external symbol, we want
7207
               lw       $tempreg,<sym>($gp)     (BFD_RELOC_MIPS_GOT16)
7208
               nop
7209
               addiu    $tempreg,$tempreg,<constant>
7210
             For a local symbol, we want the same instruction
7211
             sequence, but we output a BFD_RELOC_LO16 reloc on the
7212
             addiu instruction.
7213
 
7214
             If we have a large constant, and this is a reference to
7215
             an external symbol, we want
7216
               lw       $tempreg,<sym>($gp)     (BFD_RELOC_MIPS_GOT16)
7217
               lui      $at,<hiconstant>
7218
               addiu    $at,$at,<loconstant>
7219
               addu     $tempreg,$tempreg,$at
7220
             For a local symbol, we want the same instruction
7221
             sequence, but we output a BFD_RELOC_LO16 reloc on the
7222
             addiu instruction.
7223
           */
7224
 
7225
          if (offset_expr.X_add_number == 0)
7226
            {
7227
              if (mips_pic == SVR4_PIC
7228
                  && breg == 0
7229
                  && (call || tempreg == PIC_CALL_REG))
7230
                lw_reloc_type = (int) BFD_RELOC_MIPS_CALL16;
7231
 
7232
              relax_start (offset_expr.X_add_symbol);
7233
              macro_build (&offset_expr, ADDRESS_LOAD_INSN, "t,o(b)", tempreg,
7234
                           lw_reloc_type, mips_gp_register);
7235
              if (breg != 0)
7236
                {
7237
                  /* We're going to put in an addu instruction using
7238
                     tempreg, so we may as well insert the nop right
7239
                     now.  */
7240
                  load_delay_nop ();
7241
                }
7242
              relax_switch ();
7243
              macro_build (&offset_expr, ADDRESS_LOAD_INSN, "t,o(b)",
7244
                           tempreg, BFD_RELOC_MIPS_GOT16, mips_gp_register);
7245
              load_delay_nop ();
7246
              macro_build (&offset_expr, ADDRESS_ADDI_INSN, "t,r,j",
7247
                           tempreg, tempreg, BFD_RELOC_LO16);
7248
              relax_end ();
7249
              /* FIXME: If breg == 0, and the next instruction uses
7250
                 $tempreg, then if this variant case is used an extra
7251
                 nop will be generated.  */
7252
            }
7253
          else if (offset_expr.X_add_number >= -0x8000
7254
                   && offset_expr.X_add_number < 0x8000)
7255
            {
7256
              load_got_offset (tempreg, &offset_expr);
7257
              load_delay_nop ();
7258
              add_got_offset (tempreg, &offset_expr);
7259
            }
7260
          else
7261
            {
7262
              expr1.X_add_number = offset_expr.X_add_number;
7263
              offset_expr.X_add_number =
7264
                ((offset_expr.X_add_number + 0x8000) & 0xffff) - 0x8000;
7265
              load_got_offset (tempreg, &offset_expr);
7266
              offset_expr.X_add_number = expr1.X_add_number;
7267
              /* If we are going to add in a base register, and the
7268
                 target register and the base register are the same,
7269
                 then we are using AT as a temporary register.  Since
7270
                 we want to load the constant into AT, we add our
7271
                 current AT (from the global offset table) and the
7272
                 register into the register now, and pretend we were
7273
                 not using a base register.  */
7274
              if (breg == treg)
7275
                {
7276
                  load_delay_nop ();
7277
                  macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t",
7278
                               treg, AT, breg);
7279
                  breg = 0;
7280
                  tempreg = treg;
7281
                }
7282
              add_got_offset_hilo (tempreg, &offset_expr, AT);
7283
              used_at = 1;
7284
            }
7285
        }
7286
      else if (!mips_big_got && HAVE_NEWABI)
7287
        {
7288
          int add_breg_early = 0;
7289
 
7290
          /* If this is a reference to an external, and there is no
7291
             constant, or local symbol (*), with or without a
7292
             constant, we want
7293
               lw       $tempreg,<sym>($gp)     (BFD_RELOC_MIPS_GOT_DISP)
7294
             or for lca or if tempreg is PIC_CALL_REG
7295
               lw       $tempreg,<sym>($gp)     (BFD_RELOC_MIPS_CALL16)
7296
 
7297
             If we have a small constant, and this is a reference to
7298
             an external symbol, we want
7299
               lw       $tempreg,<sym>($gp)     (BFD_RELOC_MIPS_GOT_DISP)
7300
               addiu    $tempreg,$tempreg,<constant>
7301
 
7302
             If we have a large constant, and this is a reference to
7303
             an external symbol, we want
7304
               lw       $tempreg,<sym>($gp)     (BFD_RELOC_MIPS_GOT_DISP)
7305
               lui      $at,<hiconstant>
7306
               addiu    $at,$at,<loconstant>
7307
               addu     $tempreg,$tempreg,$at
7308
 
7309
             (*) Other assemblers seem to prefer GOT_PAGE/GOT_OFST for
7310
             local symbols, even though it introduces an additional
7311
             instruction.  */
7312
 
7313
          if (offset_expr.X_add_number)
7314
            {
7315
              expr1.X_add_number = offset_expr.X_add_number;
7316
              offset_expr.X_add_number = 0;
7317
 
7318
              relax_start (offset_expr.X_add_symbol);
7319
              macro_build (&offset_expr, ADDRESS_LOAD_INSN, "t,o(b)", tempreg,
7320
                           BFD_RELOC_MIPS_GOT_DISP, mips_gp_register);
7321
 
7322
              if (expr1.X_add_number >= -0x8000
7323
                  && expr1.X_add_number < 0x8000)
7324
                {
7325
                  macro_build (&expr1, ADDRESS_ADDI_INSN, "t,r,j",
7326
                               tempreg, tempreg, BFD_RELOC_LO16);
7327
                }
7328
              else if (IS_SEXT_32BIT_NUM (expr1.X_add_number + 0x8000))
7329
                {
7330
                  /* If we are going to add in a base register, and the
7331
                     target register and the base register are the same,
7332
                     then we are using AT as a temporary register.  Since
7333
                     we want to load the constant into AT, we add our
7334
                     current AT (from the global offset table) and the
7335
                     register into the register now, and pretend we were
7336
                     not using a base register.  */
7337
                  if (breg != treg)
7338
                    dreg = tempreg;
7339
                  else
7340
                    {
7341
                      gas_assert (tempreg == AT);
7342
                      macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t",
7343
                                   treg, AT, breg);
7344
                      dreg = treg;
7345
                      add_breg_early = 1;
7346
                    }
7347
 
7348
                  load_register (AT, &expr1, HAVE_64BIT_ADDRESSES);
7349
                  macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t",
7350
                               dreg, dreg, AT);
7351
 
7352
                  used_at = 1;
7353
                }
7354
              else
7355
                as_bad (_("PIC code offset overflow (max 32 signed bits)"));
7356
 
7357
              relax_switch ();
7358
              offset_expr.X_add_number = expr1.X_add_number;
7359
 
7360
              macro_build (&offset_expr, ADDRESS_LOAD_INSN, "t,o(b)", tempreg,
7361
                           BFD_RELOC_MIPS_GOT_DISP, mips_gp_register);
7362
              if (add_breg_early)
7363
                {
7364
                  macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t",
7365
                               treg, tempreg, breg);
7366
                  breg = 0;
7367
                  tempreg = treg;
7368
                }
7369
              relax_end ();
7370
            }
7371
          else if (breg == 0 && (call || tempreg == PIC_CALL_REG))
7372
            {
7373
              relax_start (offset_expr.X_add_symbol);
7374
              macro_build (&offset_expr, ADDRESS_LOAD_INSN, "t,o(b)", tempreg,
7375
                           BFD_RELOC_MIPS_CALL16, mips_gp_register);
7376
              relax_switch ();
7377
              macro_build (&offset_expr, ADDRESS_LOAD_INSN, "t,o(b)", tempreg,
7378
                           BFD_RELOC_MIPS_GOT_DISP, mips_gp_register);
7379
              relax_end ();
7380
            }
7381
          else
7382
            {
7383
              macro_build (&offset_expr, ADDRESS_LOAD_INSN, "t,o(b)", tempreg,
7384
                           BFD_RELOC_MIPS_GOT_DISP, mips_gp_register);
7385
            }
7386
        }
7387
      else if (mips_big_got && !HAVE_NEWABI)
7388
        {
7389
          int gpdelay;
7390
          int lui_reloc_type = (int) BFD_RELOC_MIPS_GOT_HI16;
7391
          int lw_reloc_type = (int) BFD_RELOC_MIPS_GOT_LO16;
7392
          int local_reloc_type = (int) BFD_RELOC_MIPS_GOT16;
7393
 
7394
          /* This is the large GOT case.  If this is a reference to an
7395
             external symbol, and there is no constant, we want
7396
               lui      $tempreg,<sym>          (BFD_RELOC_MIPS_GOT_HI16)
7397
               addu     $tempreg,$tempreg,$gp
7398
               lw       $tempreg,<sym>($tempreg) (BFD_RELOC_MIPS_GOT_LO16)
7399
             or for lca or if tempreg is PIC_CALL_REG
7400
               lui      $tempreg,<sym>          (BFD_RELOC_MIPS_CALL_HI16)
7401
               addu     $tempreg,$tempreg,$gp
7402
               lw       $tempreg,<sym>($tempreg) (BFD_RELOC_MIPS_CALL_LO16)
7403
             For a local symbol, we want
7404
               lw       $tempreg,<sym>($gp)     (BFD_RELOC_MIPS_GOT16)
7405
               nop
7406
               addiu    $tempreg,$tempreg,<sym> (BFD_RELOC_LO16)
7407
 
7408
             If we have a small constant, and this is a reference to
7409
             an external symbol, we want
7410
               lui      $tempreg,<sym>          (BFD_RELOC_MIPS_GOT_HI16)
7411
               addu     $tempreg,$tempreg,$gp
7412
               lw       $tempreg,<sym>($tempreg) (BFD_RELOC_MIPS_GOT_LO16)
7413
               nop
7414
               addiu    $tempreg,$tempreg,<constant>
7415
             For a local symbol, we want
7416
               lw       $tempreg,<sym>($gp)     (BFD_RELOC_MIPS_GOT16)
7417
               nop
7418
               addiu    $tempreg,$tempreg,<constant> (BFD_RELOC_LO16)
7419
 
7420
             If we have a large constant, and this is a reference to
7421
             an external symbol, we want
7422
               lui      $tempreg,<sym>          (BFD_RELOC_MIPS_GOT_HI16)
7423
               addu     $tempreg,$tempreg,$gp
7424
               lw       $tempreg,<sym>($tempreg) (BFD_RELOC_MIPS_GOT_LO16)
7425
               lui      $at,<hiconstant>
7426
               addiu    $at,$at,<loconstant>
7427
               addu     $tempreg,$tempreg,$at
7428
             For a local symbol, we want
7429
               lw       $tempreg,<sym>($gp)     (BFD_RELOC_MIPS_GOT16)
7430
               lui      $at,<hiconstant>
7431
               addiu    $at,$at,<loconstant>    (BFD_RELOC_LO16)
7432
               addu     $tempreg,$tempreg,$at
7433
          */
7434
 
7435
          expr1.X_add_number = offset_expr.X_add_number;
7436
          offset_expr.X_add_number = 0;
7437
          relax_start (offset_expr.X_add_symbol);
7438
          gpdelay = reg_needs_delay (mips_gp_register);
7439
          if (expr1.X_add_number == 0 && breg == 0
7440
              && (call || tempreg == PIC_CALL_REG))
7441
            {
7442
              lui_reloc_type = (int) BFD_RELOC_MIPS_CALL_HI16;
7443
              lw_reloc_type = (int) BFD_RELOC_MIPS_CALL_LO16;
7444
            }
7445 160 khays
          macro_build (&offset_expr, "lui", LUI_FMT, tempreg, lui_reloc_type);
7446 16 khays
          macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t",
7447
                       tempreg, tempreg, mips_gp_register);
7448
          macro_build (&offset_expr, ADDRESS_LOAD_INSN, "t,o(b)",
7449
                       tempreg, lw_reloc_type, tempreg);
7450
          if (expr1.X_add_number == 0)
7451
            {
7452
              if (breg != 0)
7453
                {
7454
                  /* We're going to put in an addu instruction using
7455
                     tempreg, so we may as well insert the nop right
7456
                     now.  */
7457
                  load_delay_nop ();
7458
                }
7459
            }
7460
          else if (expr1.X_add_number >= -0x8000
7461
                   && expr1.X_add_number < 0x8000)
7462
            {
7463
              load_delay_nop ();
7464
              macro_build (&expr1, ADDRESS_ADDI_INSN, "t,r,j",
7465
                           tempreg, tempreg, BFD_RELOC_LO16);
7466
            }
7467
          else
7468
            {
7469
              /* If we are going to add in a base register, and the
7470
                 target register and the base register are the same,
7471
                 then we are using AT as a temporary register.  Since
7472
                 we want to load the constant into AT, we add our
7473
                 current AT (from the global offset table) and the
7474
                 register into the register now, and pretend we were
7475
                 not using a base register.  */
7476
              if (breg != treg)
7477
                dreg = tempreg;
7478
              else
7479
                {
7480
                  gas_assert (tempreg == AT);
7481
                  load_delay_nop ();
7482
                  macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t",
7483
                               treg, AT, breg);
7484
                  dreg = treg;
7485
                }
7486
 
7487
              load_register (AT, &expr1, HAVE_64BIT_ADDRESSES);
7488
              macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t", dreg, dreg, AT);
7489
 
7490
              used_at = 1;
7491
            }
7492
          offset_expr.X_add_number =
7493
            ((expr1.X_add_number + 0x8000) & 0xffff) - 0x8000;
7494
          relax_switch ();
7495
 
7496
          if (gpdelay)
7497
            {
7498
              /* This is needed because this instruction uses $gp, but
7499
                 the first instruction on the main stream does not.  */
7500
              macro_build (NULL, "nop", "");
7501
            }
7502
 
7503
          macro_build (&offset_expr, ADDRESS_LOAD_INSN, "t,o(b)", tempreg,
7504
                       local_reloc_type, mips_gp_register);
7505
          if (expr1.X_add_number >= -0x8000
7506
              && expr1.X_add_number < 0x8000)
7507
            {
7508
              load_delay_nop ();
7509
              macro_build (&offset_expr, ADDRESS_ADDI_INSN, "t,r,j",
7510
                           tempreg, tempreg, BFD_RELOC_LO16);
7511
              /* FIXME: If add_number is 0, and there was no base
7512
                 register, the external symbol case ended with a load,
7513
                 so if the symbol turns out to not be external, and
7514
                 the next instruction uses tempreg, an unnecessary nop
7515
                 will be inserted.  */
7516
            }
7517
          else
7518
            {
7519
              if (breg == treg)
7520
                {
7521
                  /* We must add in the base register now, as in the
7522
                     external symbol case.  */
7523
                  gas_assert (tempreg == AT);
7524
                  load_delay_nop ();
7525
                  macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t",
7526
                               treg, AT, breg);
7527
                  tempreg = treg;
7528
                  /* We set breg to 0 because we have arranged to add
7529
                     it in in both cases.  */
7530
                  breg = 0;
7531
                }
7532
 
7533
              macro_build_lui (&expr1, AT);
7534
              macro_build (&offset_expr, ADDRESS_ADDI_INSN, "t,r,j",
7535
                           AT, AT, BFD_RELOC_LO16);
7536
              macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t",
7537
                           tempreg, tempreg, AT);
7538
              used_at = 1;
7539
            }
7540
          relax_end ();
7541
        }
7542
      else if (mips_big_got && HAVE_NEWABI)
7543
        {
7544
          int lui_reloc_type = (int) BFD_RELOC_MIPS_GOT_HI16;
7545
          int lw_reloc_type = (int) BFD_RELOC_MIPS_GOT_LO16;
7546
          int add_breg_early = 0;
7547
 
7548
          /* This is the large GOT case.  If this is a reference to an
7549
             external symbol, and there is no constant, we want
7550
               lui      $tempreg,<sym>          (BFD_RELOC_MIPS_GOT_HI16)
7551
               add      $tempreg,$tempreg,$gp
7552
               lw       $tempreg,<sym>($tempreg) (BFD_RELOC_MIPS_GOT_LO16)
7553
             or for lca or if tempreg is PIC_CALL_REG
7554
               lui      $tempreg,<sym>          (BFD_RELOC_MIPS_CALL_HI16)
7555
               add      $tempreg,$tempreg,$gp
7556
               lw       $tempreg,<sym>($tempreg) (BFD_RELOC_MIPS_CALL_LO16)
7557
 
7558
             If we have a small constant, and this is a reference to
7559
             an external symbol, we want
7560
               lui      $tempreg,<sym>          (BFD_RELOC_MIPS_GOT_HI16)
7561
               add      $tempreg,$tempreg,$gp
7562
               lw       $tempreg,<sym>($tempreg) (BFD_RELOC_MIPS_GOT_LO16)
7563
               addi     $tempreg,$tempreg,<constant>
7564
 
7565
             If we have a large constant, and this is a reference to
7566
             an external symbol, we want
7567
               lui      $tempreg,<sym>          (BFD_RELOC_MIPS_GOT_HI16)
7568
               addu     $tempreg,$tempreg,$gp
7569
               lw       $tempreg,<sym>($tempreg) (BFD_RELOC_MIPS_GOT_LO16)
7570
               lui      $at,<hiconstant>
7571
               addi     $at,$at,<loconstant>
7572
               add      $tempreg,$tempreg,$at
7573
 
7574
             If we have NewABI, and we know it's a local symbol, we want
7575
               lw       $reg,<sym>($gp)         (BFD_RELOC_MIPS_GOT_PAGE)
7576
               addiu    $reg,$reg,<sym>         (BFD_RELOC_MIPS_GOT_OFST)
7577
             otherwise we have to resort to GOT_HI16/GOT_LO16.  */
7578
 
7579
          relax_start (offset_expr.X_add_symbol);
7580
 
7581
          expr1.X_add_number = offset_expr.X_add_number;
7582
          offset_expr.X_add_number = 0;
7583
 
7584
          if (expr1.X_add_number == 0 && breg == 0
7585
              && (call || tempreg == PIC_CALL_REG))
7586
            {
7587
              lui_reloc_type = (int) BFD_RELOC_MIPS_CALL_HI16;
7588
              lw_reloc_type = (int) BFD_RELOC_MIPS_CALL_LO16;
7589
            }
7590 160 khays
          macro_build (&offset_expr, "lui", LUI_FMT, tempreg, lui_reloc_type);
7591 16 khays
          macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t",
7592
                       tempreg, tempreg, mips_gp_register);
7593
          macro_build (&offset_expr, ADDRESS_LOAD_INSN, "t,o(b)",
7594
                       tempreg, lw_reloc_type, tempreg);
7595
 
7596
          if (expr1.X_add_number == 0)
7597
            ;
7598
          else if (expr1.X_add_number >= -0x8000
7599
                   && expr1.X_add_number < 0x8000)
7600
            {
7601
              macro_build (&expr1, ADDRESS_ADDI_INSN, "t,r,j",
7602
                           tempreg, tempreg, BFD_RELOC_LO16);
7603
            }
7604
          else if (IS_SEXT_32BIT_NUM (expr1.X_add_number + 0x8000))
7605
            {
7606
              /* If we are going to add in a base register, and the
7607
                 target register and the base register are the same,
7608
                 then we are using AT as a temporary register.  Since
7609
                 we want to load the constant into AT, we add our
7610
                 current AT (from the global offset table) and the
7611
                 register into the register now, and pretend we were
7612
                 not using a base register.  */
7613
              if (breg != treg)
7614
                dreg = tempreg;
7615
              else
7616
                {
7617
                  gas_assert (tempreg == AT);
7618
                  macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t",
7619
                               treg, AT, breg);
7620
                  dreg = treg;
7621
                  add_breg_early = 1;
7622
                }
7623
 
7624
              load_register (AT, &expr1, HAVE_64BIT_ADDRESSES);
7625
              macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t", dreg, dreg, AT);
7626
 
7627
              used_at = 1;
7628
            }
7629
          else
7630
            as_bad (_("PIC code offset overflow (max 32 signed bits)"));
7631
 
7632
          relax_switch ();
7633
          offset_expr.X_add_number = expr1.X_add_number;
7634
          macro_build (&offset_expr, ADDRESS_LOAD_INSN, "t,o(b)", tempreg,
7635
                       BFD_RELOC_MIPS_GOT_PAGE, mips_gp_register);
7636
          macro_build (&offset_expr, ADDRESS_ADDI_INSN, "t,r,j", tempreg,
7637
                       tempreg, BFD_RELOC_MIPS_GOT_OFST);
7638
          if (add_breg_early)
7639
            {
7640
              macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t",
7641
                           treg, tempreg, breg);
7642
              breg = 0;
7643
              tempreg = treg;
7644
            }
7645
          relax_end ();
7646
        }
7647
      else
7648
        abort ();
7649
 
7650
      if (breg != 0)
7651
        macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t", treg, tempreg, breg);
7652
      break;
7653
 
7654
    case M_MSGSND:
7655 160 khays
      gas_assert (!mips_opts.micromips);
7656 16 khays
      {
7657
        unsigned long temp = (treg << 16) | (0x01);
7658
        macro_build (NULL, "c2", "C", temp);
7659
      }
7660
      break;
7661
 
7662
    case M_MSGLD:
7663 160 khays
      gas_assert (!mips_opts.micromips);
7664 16 khays
      {
7665
        unsigned long temp = (0x02);
7666
        macro_build (NULL, "c2", "C", temp);
7667
      }
7668
      break;
7669
 
7670
    case M_MSGLD_T:
7671 160 khays
      gas_assert (!mips_opts.micromips);
7672 16 khays
      {
7673
        unsigned long temp = (treg << 16) | (0x02);
7674
        macro_build (NULL, "c2", "C", temp);
7675
      }
7676
      break;
7677
 
7678
    case M_MSGWAIT:
7679 160 khays
      gas_assert (!mips_opts.micromips);
7680 16 khays
      macro_build (NULL, "c2", "C", 3);
7681
      break;
7682
 
7683
    case M_MSGWAIT_T:
7684 160 khays
      gas_assert (!mips_opts.micromips);
7685 16 khays
      {
7686
        unsigned long temp = (treg << 16) | 0x03;
7687
        macro_build (NULL, "c2", "C", temp);
7688
      }
7689
      break;
7690
 
7691
    case M_J_A:
7692
      /* The j instruction may not be used in PIC code, since it
7693
         requires an absolute address.  We convert it to a b
7694
         instruction.  */
7695
      if (mips_pic == NO_PIC)
7696
        macro_build (&offset_expr, "j", "a");
7697
      else
7698
        macro_build (&offset_expr, "b", "p");
7699
      break;
7700
 
7701
      /* The jal instructions must be handled as macros because when
7702
         generating PIC code they expand to multi-instruction
7703
         sequences.  Normally they are simple instructions.  */
7704 160 khays
    case M_JALS_1:
7705
      dreg = RA;
7706
      /* Fall through.  */
7707
    case M_JALS_2:
7708
      gas_assert (mips_opts.micromips);
7709
      jals = 1;
7710
      goto jal;
7711 16 khays
    case M_JAL_1:
7712
      dreg = RA;
7713
      /* Fall through.  */
7714
    case M_JAL_2:
7715 160 khays
    jal:
7716 16 khays
      if (mips_pic == NO_PIC)
7717 160 khays
        {
7718
          s = jals ? "jalrs" : "jalr";
7719
          if (mips_opts.micromips && dreg == RA)
7720
            macro_build (NULL, s, "mj", sreg);
7721
          else
7722
            macro_build (NULL, s, JALR_FMT, dreg, sreg);
7723
        }
7724 16 khays
      else
7725
        {
7726 160 khays
          int cprestore = (mips_pic == SVR4_PIC && !HAVE_NEWABI
7727
                           && mips_cprestore_offset >= 0);
7728
 
7729 16 khays
          if (sreg != PIC_CALL_REG)
7730
            as_warn (_("MIPS PIC call to register other than $25"));
7731
 
7732 160 khays
          s = (mips_opts.micromips && (!mips_opts.noreorder || cprestore)
7733
               ? "jalrs" : "jalr");
7734
          if (mips_opts.micromips && dreg == RA)
7735
            macro_build (NULL, s, "mj", sreg);
7736
          else
7737
            macro_build (NULL, s, JALR_FMT, dreg, sreg);
7738 16 khays
          if (mips_pic == SVR4_PIC && !HAVE_NEWABI)
7739
            {
7740
              if (mips_cprestore_offset < 0)
7741
                as_warn (_("No .cprestore pseudo-op used in PIC code"));
7742
              else
7743
                {
7744
                  if (!mips_frame_reg_valid)
7745
                    {
7746
                      as_warn (_("No .frame pseudo-op used in PIC code"));
7747
                      /* Quiet this warning.  */
7748
                      mips_frame_reg_valid = 1;
7749
                    }
7750
                  if (!mips_cprestore_valid)
7751
                    {
7752
                      as_warn (_("No .cprestore pseudo-op used in PIC code"));
7753
                      /* Quiet this warning.  */
7754
                      mips_cprestore_valid = 1;
7755
                    }
7756
                  if (mips_opts.noreorder)
7757
                    macro_build (NULL, "nop", "");
7758
                  expr1.X_add_number = mips_cprestore_offset;
7759
                  macro_build_ldst_constoffset (&expr1, ADDRESS_LOAD_INSN,
7760
                                                mips_gp_register,
7761
                                                mips_frame_reg,
7762
                                                HAVE_64BIT_ADDRESSES);
7763
                }
7764
            }
7765
        }
7766
 
7767
      break;
7768
 
7769 160 khays
    case M_JALS_A:
7770
      gas_assert (mips_opts.micromips);
7771
      jals = 1;
7772
      /* Fall through.  */
7773 16 khays
    case M_JAL_A:
7774
      if (mips_pic == NO_PIC)
7775 160 khays
        macro_build (&offset_expr, jals ? "jals" : "jal", "a");
7776 16 khays
      else if (mips_pic == SVR4_PIC)
7777
        {
7778
          /* If this is a reference to an external symbol, and we are
7779
             using a small GOT, we want
7780
               lw       $25,<sym>($gp)          (BFD_RELOC_MIPS_CALL16)
7781
               nop
7782
               jalr     $ra,$25
7783
               nop
7784
               lw       $gp,cprestore($sp)
7785
             The cprestore value is set using the .cprestore
7786
             pseudo-op.  If we are using a big GOT, we want
7787
               lui      $25,<sym>               (BFD_RELOC_MIPS_CALL_HI16)
7788
               addu     $25,$25,$gp
7789
               lw       $25,<sym>($25)          (BFD_RELOC_MIPS_CALL_LO16)
7790
               nop
7791
               jalr     $ra,$25
7792
               nop
7793
               lw       $gp,cprestore($sp)
7794
             If the symbol is not external, we want
7795
               lw       $25,<sym>($gp)          (BFD_RELOC_MIPS_GOT16)
7796
               nop
7797
               addiu    $25,$25,<sym>           (BFD_RELOC_LO16)
7798
               jalr     $ra,$25
7799
               nop
7800
               lw $gp,cprestore($sp)
7801
 
7802
             For NewABI, we use the same CALL16 or CALL_HI16/CALL_LO16
7803
             sequences above, minus nops, unless the symbol is local,
7804
             which enables us to use GOT_PAGE/GOT_OFST (big got) or
7805
             GOT_DISP.  */
7806
          if (HAVE_NEWABI)
7807
            {
7808
              if (!mips_big_got)
7809
                {
7810
                  relax_start (offset_expr.X_add_symbol);
7811
                  macro_build (&offset_expr, ADDRESS_LOAD_INSN, "t,o(b)",
7812
                               PIC_CALL_REG, BFD_RELOC_MIPS_CALL16,
7813
                               mips_gp_register);
7814
                  relax_switch ();
7815
                  macro_build (&offset_expr, ADDRESS_LOAD_INSN, "t,o(b)",
7816
                               PIC_CALL_REG, BFD_RELOC_MIPS_GOT_DISP,
7817
                               mips_gp_register);
7818
                  relax_end ();
7819
                }
7820
              else
7821
                {
7822
                  relax_start (offset_expr.X_add_symbol);
7823 160 khays
                  macro_build (&offset_expr, "lui", LUI_FMT, PIC_CALL_REG,
7824 16 khays
                               BFD_RELOC_MIPS_CALL_HI16);
7825
                  macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t", PIC_CALL_REG,
7826
                               PIC_CALL_REG, mips_gp_register);
7827
                  macro_build (&offset_expr, ADDRESS_LOAD_INSN, "t,o(b)",
7828
                               PIC_CALL_REG, BFD_RELOC_MIPS_CALL_LO16,
7829
                               PIC_CALL_REG);
7830
                  relax_switch ();
7831
                  macro_build (&offset_expr, ADDRESS_LOAD_INSN, "t,o(b)",
7832
                               PIC_CALL_REG, BFD_RELOC_MIPS_GOT_PAGE,
7833
                               mips_gp_register);
7834
                  macro_build (&offset_expr, ADDRESS_ADDI_INSN, "t,r,j",
7835
                               PIC_CALL_REG, PIC_CALL_REG,
7836
                               BFD_RELOC_MIPS_GOT_OFST);
7837
                  relax_end ();
7838
                }
7839
 
7840 160 khays
              macro_build_jalr (&offset_expr, 0);
7841 16 khays
            }
7842
          else
7843
            {
7844
              relax_start (offset_expr.X_add_symbol);
7845
              if (!mips_big_got)
7846
                {
7847
                  macro_build (&offset_expr, ADDRESS_LOAD_INSN, "t,o(b)",
7848
                               PIC_CALL_REG, BFD_RELOC_MIPS_CALL16,
7849
                               mips_gp_register);
7850
                  load_delay_nop ();
7851
                  relax_switch ();
7852
                }
7853
              else
7854
                {
7855
                  int gpdelay;
7856
 
7857
                  gpdelay = reg_needs_delay (mips_gp_register);
7858 160 khays
                  macro_build (&offset_expr, "lui", LUI_FMT, PIC_CALL_REG,
7859 16 khays
                               BFD_RELOC_MIPS_CALL_HI16);
7860
                  macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t", PIC_CALL_REG,
7861
                               PIC_CALL_REG, mips_gp_register);
7862
                  macro_build (&offset_expr, ADDRESS_LOAD_INSN, "t,o(b)",
7863
                               PIC_CALL_REG, BFD_RELOC_MIPS_CALL_LO16,
7864
                               PIC_CALL_REG);
7865
                  load_delay_nop ();
7866
                  relax_switch ();
7867
                  if (gpdelay)
7868
                    macro_build (NULL, "nop", "");
7869
                }
7870
              macro_build (&offset_expr, ADDRESS_LOAD_INSN, "t,o(b)",
7871
                           PIC_CALL_REG, BFD_RELOC_MIPS_GOT16,
7872
                           mips_gp_register);
7873
              load_delay_nop ();
7874
              macro_build (&offset_expr, ADDRESS_ADDI_INSN, "t,r,j",
7875
                           PIC_CALL_REG, PIC_CALL_REG, BFD_RELOC_LO16);
7876
              relax_end ();
7877 160 khays
              macro_build_jalr (&offset_expr, mips_cprestore_offset >= 0);
7878 16 khays
 
7879
              if (mips_cprestore_offset < 0)
7880
                as_warn (_("No .cprestore pseudo-op used in PIC code"));
7881
              else
7882
                {
7883
                  if (!mips_frame_reg_valid)
7884
                    {
7885
                      as_warn (_("No .frame pseudo-op used in PIC code"));
7886
                      /* Quiet this warning.  */
7887
                      mips_frame_reg_valid = 1;
7888
                    }
7889
                  if (!mips_cprestore_valid)
7890
                    {
7891
                      as_warn (_("No .cprestore pseudo-op used in PIC code"));
7892
                      /* Quiet this warning.  */
7893
                      mips_cprestore_valid = 1;
7894
                    }
7895
                  if (mips_opts.noreorder)
7896
                    macro_build (NULL, "nop", "");
7897
                  expr1.X_add_number = mips_cprestore_offset;
7898
                  macro_build_ldst_constoffset (&expr1, ADDRESS_LOAD_INSN,
7899
                                                mips_gp_register,
7900
                                                mips_frame_reg,
7901
                                                HAVE_64BIT_ADDRESSES);
7902
                }
7903
            }
7904
        }
7905
      else if (mips_pic == VXWORKS_PIC)
7906
        as_bad (_("Non-PIC jump used in PIC library"));
7907
      else
7908
        abort ();
7909
 
7910
      break;
7911
 
7912 160 khays
    case M_ACLR_AB:
7913
      ab = 1;
7914
    case M_ACLR_OB:
7915
      s = "aclr";
7916
      treg = EXTRACT_OPERAND (mips_opts.micromips, 3BITPOS, *ip);
7917
      fmt = "\\,~(b)";
7918
      off12 = 1;
7919
      goto ld_st;
7920
    case M_ASET_AB:
7921
      ab = 1;
7922
    case M_ASET_OB:
7923
      s = "aset";
7924
      treg = EXTRACT_OPERAND (mips_opts.micromips, 3BITPOS, *ip);
7925
      fmt = "\\,~(b)";
7926
      off12 = 1;
7927
      goto ld_st;
7928 16 khays
    case M_LB_AB:
7929 160 khays
      ab = 1;
7930 16 khays
      s = "lb";
7931 160 khays
      fmt = "t,o(b)";
7932 16 khays
      goto ld;
7933
    case M_LBU_AB:
7934 160 khays
      ab = 1;
7935 16 khays
      s = "lbu";
7936 160 khays
      fmt = "t,o(b)";
7937 16 khays
      goto ld;
7938
    case M_LH_AB:
7939 160 khays
      ab = 1;
7940 16 khays
      s = "lh";
7941 160 khays
      fmt = "t,o(b)";
7942 16 khays
      goto ld;
7943
    case M_LHU_AB:
7944 160 khays
      ab = 1;
7945 16 khays
      s = "lhu";
7946 160 khays
      fmt = "t,o(b)";
7947 16 khays
      goto ld;
7948
    case M_LW_AB:
7949 160 khays
      ab = 1;
7950 16 khays
      s = "lw";
7951 160 khays
      fmt = "t,o(b)";
7952 16 khays
      goto ld;
7953
    case M_LWC0_AB:
7954 160 khays
      ab = 1;
7955
      gas_assert (!mips_opts.micromips);
7956 16 khays
      s = "lwc0";
7957 160 khays
      fmt = "E,o(b)";
7958 16 khays
      /* Itbl support may require additional care here.  */
7959
      coproc = 1;
7960 160 khays
      goto ld_st;
7961 16 khays
    case M_LWC1_AB:
7962 160 khays
      ab = 1;
7963 16 khays
      s = "lwc1";
7964 160 khays
      fmt = "T,o(b)";
7965 16 khays
      /* Itbl support may require additional care here.  */
7966
      coproc = 1;
7967 160 khays
      goto ld_st;
7968 16 khays
    case M_LWC2_AB:
7969 160 khays
      ab = 1;
7970
    case M_LWC2_OB:
7971 16 khays
      s = "lwc2";
7972 160 khays
      fmt = COP12_FMT;
7973
      off12 = mips_opts.micromips;
7974 16 khays
      /* Itbl support may require additional care here.  */
7975
      coproc = 1;
7976 160 khays
      goto ld_st;
7977 16 khays
    case M_LWC3_AB:
7978 160 khays
      ab = 1;
7979
      gas_assert (!mips_opts.micromips);
7980 16 khays
      s = "lwc3";
7981 160 khays
      fmt = "E,o(b)";
7982 16 khays
      /* Itbl support may require additional care here.  */
7983
      coproc = 1;
7984 160 khays
      goto ld_st;
7985 16 khays
    case M_LWL_AB:
7986 160 khays
      ab = 1;
7987
    case M_LWL_OB:
7988 16 khays
      s = "lwl";
7989 160 khays
      fmt = MEM12_FMT;
7990
      off12 = mips_opts.micromips;
7991
      goto ld_st;
7992 16 khays
    case M_LWR_AB:
7993 160 khays
      ab = 1;
7994
    case M_LWR_OB:
7995 16 khays
      s = "lwr";
7996 160 khays
      fmt = MEM12_FMT;
7997
      off12 = mips_opts.micromips;
7998
      goto ld_st;
7999 16 khays
    case M_LDC1_AB:
8000 160 khays
      ab = 1;
8001 16 khays
      s = "ldc1";
8002 160 khays
      fmt = "T,o(b)";
8003 16 khays
      /* Itbl support may require additional care here.  */
8004
      coproc = 1;
8005 160 khays
      goto ld_st;
8006 16 khays
    case M_LDC2_AB:
8007 160 khays
      ab = 1;
8008
    case M_LDC2_OB:
8009 16 khays
      s = "ldc2";
8010 160 khays
      fmt = COP12_FMT;
8011
      off12 = mips_opts.micromips;
8012 16 khays
      /* Itbl support may require additional care here.  */
8013
      coproc = 1;
8014 160 khays
      goto ld_st;
8015 16 khays
    case M_LDC3_AB:
8016 160 khays
      ab = 1;
8017 16 khays
      s = "ldc3";
8018 160 khays
      fmt = "E,o(b)";
8019 16 khays
      /* Itbl support may require additional care here.  */
8020
      coproc = 1;
8021 160 khays
      goto ld_st;
8022 16 khays
    case M_LDL_AB:
8023 160 khays
      ab = 1;
8024
    case M_LDL_OB:
8025 16 khays
      s = "ldl";
8026 160 khays
      fmt = MEM12_FMT;
8027
      off12 = mips_opts.micromips;
8028
      goto ld_st;
8029 16 khays
    case M_LDR_AB:
8030 160 khays
      ab = 1;
8031
    case M_LDR_OB:
8032 16 khays
      s = "ldr";
8033 160 khays
      fmt = MEM12_FMT;
8034
      off12 = mips_opts.micromips;
8035
      goto ld_st;
8036 16 khays
    case M_LL_AB:
8037 160 khays
      ab = 1;
8038
    case M_LL_OB:
8039 16 khays
      s = "ll";
8040 160 khays
      fmt = MEM12_FMT;
8041
      off12 = mips_opts.micromips;
8042 16 khays
      goto ld;
8043
    case M_LLD_AB:
8044 160 khays
      ab = 1;
8045
    case M_LLD_OB:
8046 16 khays
      s = "lld";
8047 160 khays
      fmt = MEM12_FMT;
8048
      off12 = mips_opts.micromips;
8049 16 khays
      goto ld;
8050
    case M_LWU_AB:
8051 160 khays
      ab = 1;
8052
    case M_LWU_OB:
8053 16 khays
      s = "lwu";
8054 160 khays
      fmt = MEM12_FMT;
8055
      off12 = mips_opts.micromips;
8056
      goto ld;
8057
    case M_LWP_AB:
8058
      ab = 1;
8059
    case M_LWP_OB:
8060
      gas_assert (mips_opts.micromips);
8061
      s = "lwp";
8062
      fmt = "t,~(b)";
8063
      off12 = 1;
8064
      lp = 1;
8065
      goto ld;
8066
    case M_LDP_AB:
8067
      ab = 1;
8068
    case M_LDP_OB:
8069
      gas_assert (mips_opts.micromips);
8070
      s = "ldp";
8071
      fmt = "t,~(b)";
8072
      off12 = 1;
8073
      lp = 1;
8074
      goto ld;
8075
    case M_LWM_AB:
8076
      ab = 1;
8077
    case M_LWM_OB:
8078
      gas_assert (mips_opts.micromips);
8079
      s = "lwm";
8080
      fmt = "n,~(b)";
8081
      off12 = 1;
8082
      goto ld_st;
8083
    case M_LDM_AB:
8084
      ab = 1;
8085
    case M_LDM_OB:
8086
      gas_assert (mips_opts.micromips);
8087
      s = "ldm";
8088
      fmt = "n,~(b)";
8089
      off12 = 1;
8090
      goto ld_st;
8091
 
8092 16 khays
    ld:
8093 160 khays
      if (breg == treg + lp)
8094
        goto ld_st;
8095 16 khays
      else
8096 160 khays
        tempreg = treg + lp;
8097
      goto ld_noat;
8098
 
8099 16 khays
    case M_SB_AB:
8100 160 khays
      ab = 1;
8101 16 khays
      s = "sb";
8102 160 khays
      fmt = "t,o(b)";
8103
      goto ld_st;
8104 16 khays
    case M_SH_AB:
8105 160 khays
      ab = 1;
8106 16 khays
      s = "sh";
8107 160 khays
      fmt = "t,o(b)";
8108
      goto ld_st;
8109 16 khays
    case M_SW_AB:
8110 160 khays
      ab = 1;
8111 16 khays
      s = "sw";
8112 160 khays
      fmt = "t,o(b)";
8113
      goto ld_st;
8114 16 khays
    case M_SWC0_AB:
8115 160 khays
      ab = 1;
8116
      gas_assert (!mips_opts.micromips);
8117 16 khays
      s = "swc0";
8118 160 khays
      fmt = "E,o(b)";
8119 16 khays
      /* Itbl support may require additional care here.  */
8120
      coproc = 1;
8121 160 khays
      goto ld_st;
8122 16 khays
    case M_SWC1_AB:
8123 160 khays
      ab = 1;
8124 16 khays
      s = "swc1";
8125 160 khays
      fmt = "T,o(b)";
8126 16 khays
      /* Itbl support may require additional care here.  */
8127
      coproc = 1;
8128 160 khays
      goto ld_st;
8129 16 khays
    case M_SWC2_AB:
8130 160 khays
      ab = 1;
8131
    case M_SWC2_OB:
8132 16 khays
      s = "swc2";
8133 160 khays
      fmt = COP12_FMT;
8134
      off12 = mips_opts.micromips;
8135 16 khays
      /* Itbl support may require additional care here.  */
8136
      coproc = 1;
8137 160 khays
      goto ld_st;
8138 16 khays
    case M_SWC3_AB:
8139 160 khays
      ab = 1;
8140
      gas_assert (!mips_opts.micromips);
8141 16 khays
      s = "swc3";
8142 160 khays
      fmt = "E,o(b)";
8143 16 khays
      /* Itbl support may require additional care here.  */
8144
      coproc = 1;
8145 160 khays
      goto ld_st;
8146 16 khays
    case M_SWL_AB:
8147 160 khays
      ab = 1;
8148
    case M_SWL_OB:
8149 16 khays
      s = "swl";
8150 160 khays
      fmt = MEM12_FMT;
8151
      off12 = mips_opts.micromips;
8152
      goto ld_st;
8153 16 khays
    case M_SWR_AB:
8154 160 khays
      ab = 1;
8155
    case M_SWR_OB:
8156 16 khays
      s = "swr";
8157 160 khays
      fmt = MEM12_FMT;
8158
      off12 = mips_opts.micromips;
8159
      goto ld_st;
8160 16 khays
    case M_SC_AB:
8161 160 khays
      ab = 1;
8162
    case M_SC_OB:
8163 16 khays
      s = "sc";
8164 160 khays
      fmt = MEM12_FMT;
8165
      off12 = mips_opts.micromips;
8166
      goto ld_st;
8167 16 khays
    case M_SCD_AB:
8168 160 khays
      ab = 1;
8169
    case M_SCD_OB:
8170 16 khays
      s = "scd";
8171 160 khays
      fmt = MEM12_FMT;
8172
      off12 = mips_opts.micromips;
8173
      goto ld_st;
8174 16 khays
    case M_CACHE_AB:
8175 160 khays
      ab = 1;
8176
    case M_CACHE_OB:
8177 16 khays
      s = "cache";
8178 160 khays
      fmt = mips_opts.micromips ? "k,~(b)" : "k,o(b)";
8179
      off12 = mips_opts.micromips;
8180
      goto ld_st;
8181 16 khays
    case M_PREF_AB:
8182 160 khays
      ab = 1;
8183
    case M_PREF_OB:
8184 16 khays
      s = "pref";
8185 160 khays
      fmt = !mips_opts.micromips ? "k,o(b)" : "k,~(b)";
8186
      off12 = mips_opts.micromips;
8187
      goto ld_st;
8188 16 khays
    case M_SDC1_AB:
8189 160 khays
      ab = 1;
8190 16 khays
      s = "sdc1";
8191 160 khays
      fmt = "T,o(b)";
8192 16 khays
      coproc = 1;
8193
      /* Itbl support may require additional care here.  */
8194 160 khays
      goto ld_st;
8195 16 khays
    case M_SDC2_AB:
8196 160 khays
      ab = 1;
8197
    case M_SDC2_OB:
8198 16 khays
      s = "sdc2";
8199 160 khays
      fmt = COP12_FMT;
8200
      off12 = mips_opts.micromips;
8201 16 khays
      /* Itbl support may require additional care here.  */
8202
      coproc = 1;
8203 160 khays
      goto ld_st;
8204 16 khays
    case M_SDC3_AB:
8205 160 khays
      ab = 1;
8206
      gas_assert (!mips_opts.micromips);
8207 16 khays
      s = "sdc3";
8208 160 khays
      fmt = "E,o(b)";
8209 16 khays
      /* Itbl support may require additional care here.  */
8210
      coproc = 1;
8211 160 khays
      goto ld_st;
8212 16 khays
    case M_SDL_AB:
8213 160 khays
      ab = 1;
8214
    case M_SDL_OB:
8215 16 khays
      s = "sdl";
8216 160 khays
      fmt = MEM12_FMT;
8217
      off12 = mips_opts.micromips;
8218
      goto ld_st;
8219 16 khays
    case M_SDR_AB:
8220 160 khays
      ab = 1;
8221
    case M_SDR_OB:
8222 16 khays
      s = "sdr";
8223 160 khays
      fmt = MEM12_FMT;
8224
      off12 = mips_opts.micromips;
8225
      goto ld_st;
8226
    case M_SWP_AB:
8227
      ab = 1;
8228
    case M_SWP_OB:
8229
      gas_assert (mips_opts.micromips);
8230
      s = "swp";
8231
      fmt = "t,~(b)";
8232
      off12 = 1;
8233
      goto ld_st;
8234
    case M_SDP_AB:
8235
      ab = 1;
8236
    case M_SDP_OB:
8237
      gas_assert (mips_opts.micromips);
8238
      s = "sdp";
8239
      fmt = "t,~(b)";
8240
      off12 = 1;
8241
      goto ld_st;
8242
    case M_SWM_AB:
8243
      ab = 1;
8244
    case M_SWM_OB:
8245
      gas_assert (mips_opts.micromips);
8246
      s = "swm";
8247
      fmt = "n,~(b)";
8248
      off12 = 1;
8249
      goto ld_st;
8250
    case M_SDM_AB:
8251
      ab = 1;
8252
    case M_SDM_OB:
8253
      gas_assert (mips_opts.micromips);
8254
      s = "sdm";
8255
      fmt = "n,~(b)";
8256
      off12 = 1;
8257
 
8258
    ld_st:
8259 16 khays
      tempreg = AT;
8260
      used_at = 1;
8261 160 khays
    ld_noat:
8262 16 khays
      if (coproc
8263
          && NO_ISA_COP (mips_opts.arch)
8264
          && (ip->insn_mo->pinfo2 & (INSN2_M_FP_S | INSN2_M_FP_D)) == 0)
8265
        {
8266
          as_bad (_("Opcode not supported on this processor: %s"),
8267
                  mips_cpu_info_from_arch (mips_opts.arch)->name);
8268
          break;
8269
        }
8270
 
8271
      if (offset_expr.X_op != O_constant
8272
          && offset_expr.X_op != O_symbol)
8273
        {
8274
          as_bad (_("Expression too complex"));
8275
          offset_expr.X_op = O_constant;
8276
        }
8277
 
8278
      if (HAVE_32BIT_ADDRESSES
8279
          && !IS_SEXT_32BIT_NUM (offset_expr.X_add_number))
8280
        {
8281
          char value [32];
8282
 
8283
          sprintf_vma (value, offset_expr.X_add_number);
8284
          as_bad (_("Number (0x%s) larger than 32 bits"), value);
8285
        }
8286
 
8287
      /* A constant expression in PIC code can be handled just as it
8288
         is in non PIC code.  */
8289
      if (offset_expr.X_op == O_constant)
8290
        {
8291 160 khays
          int hipart = 0;
8292
 
8293 16 khays
          expr1.X_add_number = offset_expr.X_add_number;
8294
          normalize_address_expr (&expr1);
8295 160 khays
          if (!off12 && !IS_SEXT_16BIT_NUM (expr1.X_add_number))
8296 16 khays
            {
8297
              expr1.X_add_number = ((expr1.X_add_number + 0x8000)
8298
                                    & ~(bfd_vma) 0xffff);
8299 160 khays
              hipart = 1;
8300
            }
8301
          else if (off12 && !IS_SEXT_12BIT_NUM (expr1.X_add_number))
8302
            {
8303
              expr1.X_add_number = ((expr1.X_add_number + 0x800)
8304
                                    & ~(bfd_vma) 0xfff);
8305
              hipart = 1;
8306
            }
8307
          if (hipart)
8308
            {
8309 16 khays
              load_register (tempreg, &expr1, HAVE_64BIT_ADDRESSES);
8310
              if (breg != 0)
8311
                macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t",
8312
                             tempreg, tempreg, breg);
8313
              breg = tempreg;
8314
            }
8315 166 khays
          if (off0)
8316
            {
8317
              if (offset_expr.X_add_number == 0)
8318
                tempreg = breg;
8319
              else
8320
                macro_build (&offset_expr, ADDRESS_ADDI_INSN,
8321
                             "t,r,j", tempreg, breg, BFD_RELOC_LO16);
8322
              macro_build (NULL, s, fmt, treg, tempreg);
8323
            }
8324
          else if (!off12)
8325 160 khays
            macro_build (&offset_expr, s, fmt, treg, BFD_RELOC_LO16, breg);
8326
          else
8327
            macro_build (NULL, s, fmt,
8328
                         treg, (unsigned long) offset_expr.X_add_number, breg);
8329 16 khays
        }
8330 166 khays
      else if (off12 || off0)
8331 160 khays
        {
8332 166 khays
          /* A 12-bit or 0-bit offset field is too narrow to be used
8333
             for a low-part relocation, so load the whole address into
8334
             the auxillary register.  In the case of "A(b)" addresses,
8335
             we first load absolute address "A" into the register and
8336
             then add base register "b".  In the case of "o(b)" addresses,
8337
             we simply need to add 16-bit offset "o" to base register "b", and
8338 160 khays
             offset_reloc already contains the relocations associated
8339
             with "o".  */
8340
          if (ab)
8341
            {
8342
              load_address (tempreg, &offset_expr, &used_at);
8343
              if (breg != 0)
8344
                macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t",
8345
                             tempreg, tempreg, breg);
8346
            }
8347
          else
8348
            macro_build (&offset_expr, ADDRESS_ADDI_INSN, "t,r,j",
8349
                         tempreg, breg, -1,
8350
                         offset_reloc[0], offset_reloc[1], offset_reloc[2]);
8351
          expr1.X_add_number = 0;
8352 166 khays
          if (off0)
8353
            macro_build (NULL, s, fmt, treg, tempreg);
8354
          else
8355
            macro_build (NULL, s, fmt,
8356
                         treg, (unsigned long) expr1.X_add_number, tempreg);
8357 160 khays
        }
8358 16 khays
      else if (mips_pic == NO_PIC)
8359
        {
8360
          /* If this is a reference to a GP relative symbol, and there
8361
             is no base register, we want
8362
               <op>     $treg,<sym>($gp)        (BFD_RELOC_GPREL16)
8363
             Otherwise, if there is no base register, we want
8364
               lui      $tempreg,<sym>          (BFD_RELOC_HI16_S)
8365
               <op>     $treg,<sym>($tempreg)   (BFD_RELOC_LO16)
8366
             If we have a constant, we need two instructions anyhow,
8367
             so we always use the latter form.
8368
 
8369
             If we have a base register, and this is a reference to a
8370
             GP relative symbol, we want
8371
               addu     $tempreg,$breg,$gp
8372
               <op>     $treg,<sym>($tempreg)   (BFD_RELOC_GPREL16)
8373
             Otherwise we want
8374
               lui      $tempreg,<sym>          (BFD_RELOC_HI16_S)
8375
               addu     $tempreg,$tempreg,$breg
8376
               <op>     $treg,<sym>($tempreg)   (BFD_RELOC_LO16)
8377
             With a constant we always use the latter case.
8378
 
8379
             With 64bit address space and no base register and $at usable,
8380
             we want
8381
               lui      $tempreg,<sym>          (BFD_RELOC_MIPS_HIGHEST)
8382
               lui      $at,<sym>               (BFD_RELOC_HI16_S)
8383
               daddiu   $tempreg,<sym>          (BFD_RELOC_MIPS_HIGHER)
8384
               dsll32   $tempreg,0
8385
               daddu    $tempreg,$at
8386
               <op>     $treg,<sym>($tempreg)   (BFD_RELOC_LO16)
8387
             If we have a base register, we want
8388
               lui      $tempreg,<sym>          (BFD_RELOC_MIPS_HIGHEST)
8389
               lui      $at,<sym>               (BFD_RELOC_HI16_S)
8390
               daddiu   $tempreg,<sym>          (BFD_RELOC_MIPS_HIGHER)
8391
               daddu    $at,$breg
8392
               dsll32   $tempreg,0
8393
               daddu    $tempreg,$at
8394
               <op>     $treg,<sym>($tempreg)   (BFD_RELOC_LO16)
8395
 
8396
             Without $at we can't generate the optimal path for superscalar
8397
             processors here since this would require two temporary registers.
8398
               lui      $tempreg,<sym>          (BFD_RELOC_MIPS_HIGHEST)
8399
               daddiu   $tempreg,<sym>          (BFD_RELOC_MIPS_HIGHER)
8400
               dsll     $tempreg,16
8401
               daddiu   $tempreg,<sym>          (BFD_RELOC_HI16_S)
8402
               dsll     $tempreg,16
8403
               <op>     $treg,<sym>($tempreg)   (BFD_RELOC_LO16)
8404
             If we have a base register, we want
8405
               lui      $tempreg,<sym>          (BFD_RELOC_MIPS_HIGHEST)
8406
               daddiu   $tempreg,<sym>          (BFD_RELOC_MIPS_HIGHER)
8407
               dsll     $tempreg,16
8408
               daddiu   $tempreg,<sym>          (BFD_RELOC_HI16_S)
8409
               dsll     $tempreg,16
8410
               daddu    $tempreg,$tempreg,$breg
8411
               <op>     $treg,<sym>($tempreg)   (BFD_RELOC_LO16)
8412
 
8413
             For GP relative symbols in 64bit address space we can use
8414
             the same sequence as in 32bit address space.  */
8415
          if (HAVE_64BIT_SYMBOLS)
8416
            {
8417
              if ((valueT) offset_expr.X_add_number <= MAX_GPREL_OFFSET
8418
                  && !nopic_need_relax (offset_expr.X_add_symbol, 1))
8419
                {
8420
                  relax_start (offset_expr.X_add_symbol);
8421
                  if (breg == 0)
8422
                    {
8423
                      macro_build (&offset_expr, s, fmt, treg,
8424
                                   BFD_RELOC_GPREL16, mips_gp_register);
8425
                    }
8426
                  else
8427
                    {
8428
                      macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t",
8429
                                   tempreg, breg, mips_gp_register);
8430
                      macro_build (&offset_expr, s, fmt, treg,
8431
                                   BFD_RELOC_GPREL16, tempreg);
8432
                    }
8433
                  relax_switch ();
8434
                }
8435
 
8436
              if (used_at == 0 && mips_opts.at)
8437
                {
8438 160 khays
                  macro_build (&offset_expr, "lui", LUI_FMT, tempreg,
8439 16 khays
                               BFD_RELOC_MIPS_HIGHEST);
8440 160 khays
                  macro_build (&offset_expr, "lui", LUI_FMT, AT,
8441 16 khays
                               BFD_RELOC_HI16_S);
8442
                  macro_build (&offset_expr, "daddiu", "t,r,j", tempreg,
8443
                               tempreg, BFD_RELOC_MIPS_HIGHER);
8444
                  if (breg != 0)
8445
                    macro_build (NULL, "daddu", "d,v,t", AT, AT, breg);
8446 160 khays
                  macro_build (NULL, "dsll32", SHFT_FMT, tempreg, tempreg, 0);
8447 16 khays
                  macro_build (NULL, "daddu", "d,v,t", tempreg, tempreg, AT);
8448
                  macro_build (&offset_expr, s, fmt, treg, BFD_RELOC_LO16,
8449
                               tempreg);
8450
                  used_at = 1;
8451
                }
8452
              else
8453
                {
8454 160 khays
                  macro_build (&offset_expr, "lui", LUI_FMT, tempreg,
8455 16 khays
                               BFD_RELOC_MIPS_HIGHEST);
8456
                  macro_build (&offset_expr, "daddiu", "t,r,j", tempreg,
8457
                               tempreg, BFD_RELOC_MIPS_HIGHER);
8458 160 khays
                  macro_build (NULL, "dsll", SHFT_FMT, tempreg, tempreg, 16);
8459 16 khays
                  macro_build (&offset_expr, "daddiu", "t,r,j", tempreg,
8460
                               tempreg, BFD_RELOC_HI16_S);
8461 160 khays
                  macro_build (NULL, "dsll", SHFT_FMT, tempreg, tempreg, 16);
8462 16 khays
                  if (breg != 0)
8463
                    macro_build (NULL, "daddu", "d,v,t",
8464
                                 tempreg, tempreg, breg);
8465
                  macro_build (&offset_expr, s, fmt, treg,
8466
                               BFD_RELOC_LO16, tempreg);
8467
                }
8468
 
8469
              if (mips_relax.sequence)
8470
                relax_end ();
8471
              break;
8472
            }
8473
 
8474
          if (breg == 0)
8475
            {
8476
              if ((valueT) offset_expr.X_add_number <= MAX_GPREL_OFFSET
8477
                  && !nopic_need_relax (offset_expr.X_add_symbol, 1))
8478
                {
8479
                  relax_start (offset_expr.X_add_symbol);
8480
                  macro_build (&offset_expr, s, fmt, treg, BFD_RELOC_GPREL16,
8481
                               mips_gp_register);
8482
                  relax_switch ();
8483
                }
8484
              macro_build_lui (&offset_expr, tempreg);
8485
              macro_build (&offset_expr, s, fmt, treg,
8486
                           BFD_RELOC_LO16, tempreg);
8487
              if (mips_relax.sequence)
8488
                relax_end ();
8489
            }
8490
          else
8491
            {
8492
              if ((valueT) offset_expr.X_add_number <= MAX_GPREL_OFFSET
8493
                  && !nopic_need_relax (offset_expr.X_add_symbol, 1))
8494
                {
8495
                  relax_start (offset_expr.X_add_symbol);
8496
                  macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t",
8497
                               tempreg, breg, mips_gp_register);
8498
                  macro_build (&offset_expr, s, fmt, treg,
8499
                               BFD_RELOC_GPREL16, tempreg);
8500
                  relax_switch ();
8501
                }
8502
              macro_build_lui (&offset_expr, tempreg);
8503
              macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t",
8504
                           tempreg, tempreg, breg);
8505
              macro_build (&offset_expr, s, fmt, treg,
8506
                           BFD_RELOC_LO16, tempreg);
8507
              if (mips_relax.sequence)
8508
                relax_end ();
8509
            }
8510
        }
8511
      else if (!mips_big_got)
8512
        {
8513
          int lw_reloc_type = (int) BFD_RELOC_MIPS_GOT16;
8514
 
8515
          /* If this is a reference to an external symbol, we want
8516
               lw       $tempreg,<sym>($gp)     (BFD_RELOC_MIPS_GOT16)
8517
               nop
8518
               <op>     $treg,0($tempreg)
8519
             Otherwise we want
8520
               lw       $tempreg,<sym>($gp)     (BFD_RELOC_MIPS_GOT16)
8521
               nop
8522
               addiu    $tempreg,$tempreg,<sym> (BFD_RELOC_LO16)
8523
               <op>     $treg,0($tempreg)
8524
 
8525
             For NewABI, we want
8526
               lw       $tempreg,<sym>($gp)     (BFD_RELOC_MIPS_GOT_PAGE)
8527
               <op>     $treg,<sym>($tempreg)   (BFD_RELOC_MIPS_GOT_OFST)
8528
 
8529
             If there is a base register, we add it to $tempreg before
8530
             the <op>.  If there is a constant, we stick it in the
8531
             <op> instruction.  We don't handle constants larger than
8532
             16 bits, because we have no way to load the upper 16 bits
8533
             (actually, we could handle them for the subset of cases
8534
             in which we are not using $at).  */
8535
          gas_assert (offset_expr.X_op == O_symbol);
8536
          if (HAVE_NEWABI)
8537
            {
8538
              macro_build (&offset_expr, ADDRESS_LOAD_INSN, "t,o(b)", tempreg,
8539
                           BFD_RELOC_MIPS_GOT_PAGE, mips_gp_register);
8540
              if (breg != 0)
8541
                macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t",
8542
                             tempreg, tempreg, breg);
8543
              macro_build (&offset_expr, s, fmt, treg,
8544
                           BFD_RELOC_MIPS_GOT_OFST, tempreg);
8545
              break;
8546
            }
8547
          expr1.X_add_number = offset_expr.X_add_number;
8548
          offset_expr.X_add_number = 0;
8549
          if (expr1.X_add_number < -0x8000
8550
              || expr1.X_add_number >= 0x8000)
8551
            as_bad (_("PIC code offset overflow (max 16 signed bits)"));
8552
          macro_build (&offset_expr, ADDRESS_LOAD_INSN, "t,o(b)", tempreg,
8553
                       lw_reloc_type, mips_gp_register);
8554
          load_delay_nop ();
8555
          relax_start (offset_expr.X_add_symbol);
8556
          relax_switch ();
8557
          macro_build (&offset_expr, ADDRESS_ADDI_INSN, "t,r,j", tempreg,
8558
                       tempreg, BFD_RELOC_LO16);
8559
          relax_end ();
8560
          if (breg != 0)
8561
            macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t",
8562
                         tempreg, tempreg, breg);
8563
          macro_build (&expr1, s, fmt, treg, BFD_RELOC_LO16, tempreg);
8564
        }
8565
      else if (mips_big_got && !HAVE_NEWABI)
8566
        {
8567
          int gpdelay;
8568
 
8569
          /* If this is a reference to an external symbol, we want
8570
               lui      $tempreg,<sym>          (BFD_RELOC_MIPS_GOT_HI16)
8571
               addu     $tempreg,$tempreg,$gp
8572
               lw       $tempreg,<sym>($tempreg) (BFD_RELOC_MIPS_GOT_LO16)
8573
               <op>     $treg,0($tempreg)
8574
             Otherwise we want
8575
               lw       $tempreg,<sym>($gp)     (BFD_RELOC_MIPS_GOT16)
8576
               nop
8577
               addiu    $tempreg,$tempreg,<sym> (BFD_RELOC_LO16)
8578
               <op>     $treg,0($tempreg)
8579
             If there is a base register, we add it to $tempreg before
8580
             the <op>.  If there is a constant, we stick it in the
8581
             <op> instruction.  We don't handle constants larger than
8582
             16 bits, because we have no way to load the upper 16 bits
8583
             (actually, we could handle them for the subset of cases
8584
             in which we are not using $at).  */
8585
          gas_assert (offset_expr.X_op == O_symbol);
8586
          expr1.X_add_number = offset_expr.X_add_number;
8587
          offset_expr.X_add_number = 0;
8588
          if (expr1.X_add_number < -0x8000
8589
              || expr1.X_add_number >= 0x8000)
8590
            as_bad (_("PIC code offset overflow (max 16 signed bits)"));
8591
          gpdelay = reg_needs_delay (mips_gp_register);
8592
          relax_start (offset_expr.X_add_symbol);
8593 160 khays
          macro_build (&offset_expr, "lui", LUI_FMT, tempreg,
8594 16 khays
                       BFD_RELOC_MIPS_GOT_HI16);
8595
          macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t", tempreg, tempreg,
8596
                       mips_gp_register);
8597
          macro_build (&offset_expr, ADDRESS_LOAD_INSN, "t,o(b)", tempreg,
8598
                       BFD_RELOC_MIPS_GOT_LO16, tempreg);
8599
          relax_switch ();
8600
          if (gpdelay)
8601
            macro_build (NULL, "nop", "");
8602
          macro_build (&offset_expr, ADDRESS_LOAD_INSN, "t,o(b)", tempreg,
8603
                       BFD_RELOC_MIPS_GOT16, mips_gp_register);
8604
          load_delay_nop ();
8605
          macro_build (&offset_expr, ADDRESS_ADDI_INSN, "t,r,j", tempreg,
8606
                       tempreg, BFD_RELOC_LO16);
8607
          relax_end ();
8608
 
8609
          if (breg != 0)
8610
            macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t",
8611
                         tempreg, tempreg, breg);
8612
          macro_build (&expr1, s, fmt, treg, BFD_RELOC_LO16, tempreg);
8613
        }
8614
      else if (mips_big_got && HAVE_NEWABI)
8615
        {
8616
          /* If this is a reference to an external symbol, we want
8617
               lui      $tempreg,<sym>          (BFD_RELOC_MIPS_GOT_HI16)
8618
               add      $tempreg,$tempreg,$gp
8619
               lw       $tempreg,<sym>($tempreg) (BFD_RELOC_MIPS_GOT_LO16)
8620
               <op>     $treg,<ofst>($tempreg)
8621
             Otherwise, for local symbols, we want:
8622
               lw       $tempreg,<sym>($gp)     (BFD_RELOC_MIPS_GOT_PAGE)
8623
               <op>     $treg,<sym>($tempreg)   (BFD_RELOC_MIPS_GOT_OFST)  */
8624
          gas_assert (offset_expr.X_op == O_symbol);
8625
          expr1.X_add_number = offset_expr.X_add_number;
8626
          offset_expr.X_add_number = 0;
8627
          if (expr1.X_add_number < -0x8000
8628
              || expr1.X_add_number >= 0x8000)
8629
            as_bad (_("PIC code offset overflow (max 16 signed bits)"));
8630
          relax_start (offset_expr.X_add_symbol);
8631 160 khays
          macro_build (&offset_expr, "lui", LUI_FMT, tempreg,
8632 16 khays
                       BFD_RELOC_MIPS_GOT_HI16);
8633
          macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t", tempreg, tempreg,
8634
                       mips_gp_register);
8635
          macro_build (&offset_expr, ADDRESS_LOAD_INSN, "t,o(b)", tempreg,
8636
                       BFD_RELOC_MIPS_GOT_LO16, tempreg);
8637
          if (breg != 0)
8638
            macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t",
8639
                         tempreg, tempreg, breg);
8640
          macro_build (&expr1, s, fmt, treg, BFD_RELOC_LO16, tempreg);
8641
 
8642
          relax_switch ();
8643
          offset_expr.X_add_number = expr1.X_add_number;
8644
          macro_build (&offset_expr, ADDRESS_LOAD_INSN, "t,o(b)", tempreg,
8645
                       BFD_RELOC_MIPS_GOT_PAGE, mips_gp_register);
8646
          if (breg != 0)
8647
            macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t",
8648
                         tempreg, tempreg, breg);
8649
          macro_build (&offset_expr, s, fmt, treg,
8650
                       BFD_RELOC_MIPS_GOT_OFST, tempreg);
8651
          relax_end ();
8652
        }
8653
      else
8654
        abort ();
8655
 
8656
      break;
8657
 
8658
    case M_LI:
8659
    case M_LI_S:
8660
      load_register (treg, &imm_expr, 0);
8661
      break;
8662
 
8663
    case M_DLI:
8664
      load_register (treg, &imm_expr, 1);
8665
      break;
8666
 
8667
    case M_LI_SS:
8668
      if (imm_expr.X_op == O_constant)
8669
        {
8670
          used_at = 1;
8671
          load_register (AT, &imm_expr, 0);
8672
          macro_build (NULL, "mtc1", "t,G", AT, treg);
8673
          break;
8674
        }
8675
      else
8676
        {
8677
          gas_assert (offset_expr.X_op == O_symbol
8678
                      && strcmp (segment_name (S_GET_SEGMENT
8679
                                               (offset_expr.X_add_symbol)),
8680
                                 ".lit4") == 0
8681
                      && offset_expr.X_add_number == 0);
8682
          macro_build (&offset_expr, "lwc1", "T,o(b)", treg,
8683
                       BFD_RELOC_MIPS_LITERAL, mips_gp_register);
8684
          break;
8685
        }
8686
 
8687
    case M_LI_D:
8688
      /* Check if we have a constant in IMM_EXPR.  If the GPRs are 64 bits
8689
         wide, IMM_EXPR is the entire value.  Otherwise IMM_EXPR is the high
8690
         order 32 bits of the value and the low order 32 bits are either
8691
         zero or in OFFSET_EXPR.  */
8692
      if (imm_expr.X_op == O_constant || imm_expr.X_op == O_big)
8693
        {
8694
          if (HAVE_64BIT_GPRS)
8695
            load_register (treg, &imm_expr, 1);
8696
          else
8697
            {
8698
              int hreg, lreg;
8699
 
8700
              if (target_big_endian)
8701
                {
8702
                  hreg = treg;
8703
                  lreg = treg + 1;
8704
                }
8705
              else
8706
                {
8707
                  hreg = treg + 1;
8708
                  lreg = treg;
8709
                }
8710
 
8711
              if (hreg <= 31)
8712
                load_register (hreg, &imm_expr, 0);
8713
              if (lreg <= 31)
8714
                {
8715
                  if (offset_expr.X_op == O_absent)
8716
                    move_register (lreg, 0);
8717
                  else
8718
                    {
8719
                      gas_assert (offset_expr.X_op == O_constant);
8720
                      load_register (lreg, &offset_expr, 0);
8721
                    }
8722
                }
8723
            }
8724
          break;
8725
        }
8726
 
8727
      /* We know that sym is in the .rdata section.  First we get the
8728
         upper 16 bits of the address.  */
8729
      if (mips_pic == NO_PIC)
8730
        {
8731
          macro_build_lui (&offset_expr, AT);
8732
          used_at = 1;
8733
        }
8734
      else
8735
        {
8736
          macro_build (&offset_expr, ADDRESS_LOAD_INSN, "t,o(b)", AT,
8737
                       BFD_RELOC_MIPS_GOT16, mips_gp_register);
8738
          used_at = 1;
8739
        }
8740
 
8741
      /* Now we load the register(s).  */
8742
      if (HAVE_64BIT_GPRS)
8743
        {
8744
          used_at = 1;
8745
          macro_build (&offset_expr, "ld", "t,o(b)", treg, BFD_RELOC_LO16, AT);
8746
        }
8747
      else
8748
        {
8749
          used_at = 1;
8750
          macro_build (&offset_expr, "lw", "t,o(b)", treg, BFD_RELOC_LO16, AT);
8751
          if (treg != RA)
8752
            {
8753
              /* FIXME: How in the world do we deal with the possible
8754
                 overflow here?  */
8755
              offset_expr.X_add_number += 4;
8756
              macro_build (&offset_expr, "lw", "t,o(b)",
8757
                           treg + 1, BFD_RELOC_LO16, AT);
8758
            }
8759
        }
8760
      break;
8761
 
8762
    case M_LI_DD:
8763
      /* Check if we have a constant in IMM_EXPR.  If the FPRs are 64 bits
8764
         wide, IMM_EXPR is the entire value and the GPRs are known to be 64
8765
         bits wide as well.  Otherwise IMM_EXPR is the high order 32 bits of
8766
         the value and the low order 32 bits are either zero or in
8767
         OFFSET_EXPR.  */
8768
      if (imm_expr.X_op == O_constant || imm_expr.X_op == O_big)
8769
        {
8770
          used_at = 1;
8771
          load_register (AT, &imm_expr, HAVE_64BIT_FPRS);
8772
          if (HAVE_64BIT_FPRS)
8773
            {
8774
              gas_assert (HAVE_64BIT_GPRS);
8775
              macro_build (NULL, "dmtc1", "t,S", AT, treg);
8776
            }
8777
          else
8778
            {
8779
              macro_build (NULL, "mtc1", "t,G", AT, treg + 1);
8780
              if (offset_expr.X_op == O_absent)
8781
                macro_build (NULL, "mtc1", "t,G", 0, treg);
8782
              else
8783
                {
8784
                  gas_assert (offset_expr.X_op == O_constant);
8785
                  load_register (AT, &offset_expr, 0);
8786
                  macro_build (NULL, "mtc1", "t,G", AT, treg);
8787
                }
8788
            }
8789
          break;
8790
        }
8791
 
8792
      gas_assert (offset_expr.X_op == O_symbol
8793
                  && offset_expr.X_add_number == 0);
8794
      s = segment_name (S_GET_SEGMENT (offset_expr.X_add_symbol));
8795
      if (strcmp (s, ".lit8") == 0)
8796
        {
8797 160 khays
          if (mips_opts.isa != ISA_MIPS1 || mips_opts.micromips)
8798 16 khays
            {
8799
              macro_build (&offset_expr, "ldc1", "T,o(b)", treg,
8800
                           BFD_RELOC_MIPS_LITERAL, mips_gp_register);
8801
              break;
8802
            }
8803
          breg = mips_gp_register;
8804
          r = BFD_RELOC_MIPS_LITERAL;
8805
          goto dob;
8806
        }
8807
      else
8808
        {
8809
          gas_assert (strcmp (s, RDATA_SECTION_NAME) == 0);
8810
          used_at = 1;
8811
          if (mips_pic != NO_PIC)
8812
            macro_build (&offset_expr, ADDRESS_LOAD_INSN, "t,o(b)", AT,
8813
                         BFD_RELOC_MIPS_GOT16, mips_gp_register);
8814
          else
8815
            {
8816
              /* FIXME: This won't work for a 64 bit address.  */
8817
              macro_build_lui (&offset_expr, AT);
8818
            }
8819
 
8820 160 khays
          if (mips_opts.isa != ISA_MIPS1 || mips_opts.micromips)
8821 16 khays
            {
8822
              macro_build (&offset_expr, "ldc1", "T,o(b)",
8823
                           treg, BFD_RELOC_LO16, AT);
8824
              break;
8825
            }
8826
          breg = AT;
8827
          r = BFD_RELOC_LO16;
8828
          goto dob;
8829
        }
8830
 
8831
    case M_L_DOB:
8832
      /* Even on a big endian machine $fn comes before $fn+1.  We have
8833
         to adjust when loading from memory.  */
8834
      r = BFD_RELOC_LO16;
8835
    dob:
8836 160 khays
      gas_assert (!mips_opts.micromips);
8837 16 khays
      gas_assert (mips_opts.isa == ISA_MIPS1);
8838
      macro_build (&offset_expr, "lwc1", "T,o(b)",
8839
                   target_big_endian ? treg + 1 : treg, r, breg);
8840
      /* FIXME: A possible overflow which I don't know how to deal
8841
         with.  */
8842
      offset_expr.X_add_number += 4;
8843
      macro_build (&offset_expr, "lwc1", "T,o(b)",
8844
                   target_big_endian ? treg : treg + 1, r, breg);
8845
      break;
8846
 
8847
    case M_S_DOB:
8848 160 khays
      gas_assert (!mips_opts.micromips);
8849 16 khays
      gas_assert (mips_opts.isa == ISA_MIPS1);
8850
      /* Even on a big endian machine $fn comes before $fn+1.  We have
8851
         to adjust when storing to memory.  */
8852
      macro_build (&offset_expr, "swc1", "T,o(b)",
8853
                   target_big_endian ? treg + 1 : treg, BFD_RELOC_LO16, breg);
8854
      offset_expr.X_add_number += 4;
8855
      macro_build (&offset_expr, "swc1", "T,o(b)",
8856
                   target_big_endian ? treg : treg + 1, BFD_RELOC_LO16, breg);
8857
      break;
8858
 
8859
    case M_L_DAB:
8860 160 khays
      gas_assert (!mips_opts.micromips);
8861 16 khays
      /*
8862
       * The MIPS assembler seems to check for X_add_number not
8863
       * being double aligned and generating:
8864
       *        lui     at,%hi(foo+1)
8865
       *        addu    at,at,v1
8866
       *        addiu   at,at,%lo(foo+1)
8867
       *        lwc1    f2,0(at)
8868
       *        lwc1    f3,4(at)
8869
       * But, the resulting address is the same after relocation so why
8870
       * generate the extra instruction?
8871
       */
8872
      /* Itbl support may require additional care here.  */
8873
      coproc = 1;
8874 160 khays
      fmt = "T,o(b)";
8875 16 khays
      if (mips_opts.isa != ISA_MIPS1)
8876
        {
8877
          s = "ldc1";
8878 160 khays
          goto ld_st;
8879 16 khays
        }
8880
      s = "lwc1";
8881
      goto ldd_std;
8882
 
8883
    case M_S_DAB:
8884 160 khays
      gas_assert (!mips_opts.micromips);
8885
      /* Itbl support may require additional care here.  */
8886
      coproc = 1;
8887
      fmt = "T,o(b)";
8888 16 khays
      if (mips_opts.isa != ISA_MIPS1)
8889
        {
8890
          s = "sdc1";
8891 160 khays
          goto ld_st;
8892 16 khays
        }
8893
      s = "swc1";
8894
      goto ldd_std;
8895
 
8896
    case M_LD_AB:
8897 160 khays
      fmt = "t,o(b)";
8898 16 khays
      if (HAVE_64BIT_GPRS)
8899
        {
8900
          s = "ld";
8901
          goto ld;
8902
        }
8903
      s = "lw";
8904
      goto ldd_std;
8905
 
8906
    case M_SD_AB:
8907 160 khays
      fmt = "t,o(b)";
8908 16 khays
      if (HAVE_64BIT_GPRS)
8909
        {
8910
          s = "sd";
8911 160 khays
          goto ld_st;
8912 16 khays
        }
8913
      s = "sw";
8914
 
8915
    ldd_std:
8916
      if (offset_expr.X_op != O_symbol
8917
          && offset_expr.X_op != O_constant)
8918
        {
8919
          as_bad (_("Expression too complex"));
8920
          offset_expr.X_op = O_constant;
8921
        }
8922
 
8923
      if (HAVE_32BIT_ADDRESSES
8924
          && !IS_SEXT_32BIT_NUM (offset_expr.X_add_number))
8925
        {
8926
          char value [32];
8927
 
8928
          sprintf_vma (value, offset_expr.X_add_number);
8929
          as_bad (_("Number (0x%s) larger than 32 bits"), value);
8930
        }
8931
 
8932
      /* Even on a big endian machine $fn comes before $fn+1.  We have
8933
         to adjust when loading from memory.  We set coproc if we must
8934
         load $fn+1 first.  */
8935
      /* Itbl support may require additional care here.  */
8936
      if (!target_big_endian)
8937
        coproc = 0;
8938
 
8939
      if (mips_pic == NO_PIC || offset_expr.X_op == O_constant)
8940
        {
8941
          /* If this is a reference to a GP relative symbol, we want
8942
               <op>     $treg,<sym>($gp)        (BFD_RELOC_GPREL16)
8943
               <op>     $treg+1,<sym>+4($gp)    (BFD_RELOC_GPREL16)
8944
             If we have a base register, we use this
8945
               addu     $at,$breg,$gp
8946
               <op>     $treg,<sym>($at)        (BFD_RELOC_GPREL16)
8947
               <op>     $treg+1,<sym>+4($at)    (BFD_RELOC_GPREL16)
8948
             If this is not a GP relative symbol, we want
8949
               lui      $at,<sym>               (BFD_RELOC_HI16_S)
8950
               <op>     $treg,<sym>($at)        (BFD_RELOC_LO16)
8951
               <op>     $treg+1,<sym>+4($at)    (BFD_RELOC_LO16)
8952
             If there is a base register, we add it to $at after the
8953
             lui instruction.  If there is a constant, we always use
8954
             the last case.  */
8955
          if (offset_expr.X_op == O_symbol
8956
              && (valueT) offset_expr.X_add_number <= MAX_GPREL_OFFSET
8957
              && !nopic_need_relax (offset_expr.X_add_symbol, 1))
8958
            {
8959
              relax_start (offset_expr.X_add_symbol);
8960
              if (breg == 0)
8961
                {
8962
                  tempreg = mips_gp_register;
8963
                }
8964
              else
8965
                {
8966
                  macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t",
8967
                               AT, breg, mips_gp_register);
8968
                  tempreg = AT;
8969
                  used_at = 1;
8970
                }
8971
 
8972
              /* Itbl support may require additional care here.  */
8973
              macro_build (&offset_expr, s, fmt, coproc ? treg + 1 : treg,
8974
                           BFD_RELOC_GPREL16, tempreg);
8975
              offset_expr.X_add_number += 4;
8976
 
8977
              /* Set mips_optimize to 2 to avoid inserting an
8978
                 undesired nop.  */
8979
              hold_mips_optimize = mips_optimize;
8980
              mips_optimize = 2;
8981
              /* Itbl support may require additional care here.  */
8982
              macro_build (&offset_expr, s, fmt, coproc ? treg : treg + 1,
8983
                           BFD_RELOC_GPREL16, tempreg);
8984
              mips_optimize = hold_mips_optimize;
8985
 
8986
              relax_switch ();
8987
 
8988
              offset_expr.X_add_number -= 4;
8989
            }
8990
          used_at = 1;
8991
          macro_build_lui (&offset_expr, AT);
8992
          if (breg != 0)
8993
            macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t", AT, breg, AT);
8994
          /* Itbl support may require additional care here.  */
8995
          macro_build (&offset_expr, s, fmt, coproc ? treg + 1 : treg,
8996
                       BFD_RELOC_LO16, AT);
8997
          /* FIXME: How do we handle overflow here?  */
8998
          offset_expr.X_add_number += 4;
8999
          /* Itbl support may require additional care here.  */
9000
          macro_build (&offset_expr, s, fmt, coproc ? treg : treg + 1,
9001
                       BFD_RELOC_LO16, AT);
9002
          if (mips_relax.sequence)
9003
            relax_end ();
9004
        }
9005
      else if (!mips_big_got)
9006
        {
9007
          /* If this is a reference to an external symbol, we want
9008
               lw       $at,<sym>($gp)          (BFD_RELOC_MIPS_GOT16)
9009
               nop
9010
               <op>     $treg,0($at)
9011
               <op>     $treg+1,4($at)
9012
             Otherwise we want
9013
               lw       $at,<sym>($gp)          (BFD_RELOC_MIPS_GOT16)
9014
               nop
9015
               <op>     $treg,<sym>($at)        (BFD_RELOC_LO16)
9016
               <op>     $treg+1,<sym>+4($at)    (BFD_RELOC_LO16)
9017
             If there is a base register we add it to $at before the
9018
             lwc1 instructions.  If there is a constant we include it
9019
             in the lwc1 instructions.  */
9020
          used_at = 1;
9021
          expr1.X_add_number = offset_expr.X_add_number;
9022
          if (expr1.X_add_number < -0x8000
9023
              || expr1.X_add_number >= 0x8000 - 4)
9024
            as_bad (_("PIC code offset overflow (max 16 signed bits)"));
9025
          load_got_offset (AT, &offset_expr);
9026
          load_delay_nop ();
9027
          if (breg != 0)
9028
            macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t", AT, breg, AT);
9029
 
9030
          /* Set mips_optimize to 2 to avoid inserting an undesired
9031
             nop.  */
9032
          hold_mips_optimize = mips_optimize;
9033
          mips_optimize = 2;
9034
 
9035
          /* Itbl support may require additional care here.  */
9036
          relax_start (offset_expr.X_add_symbol);
9037
          macro_build (&expr1, s, fmt, coproc ? treg + 1 : treg,
9038
                       BFD_RELOC_LO16, AT);
9039
          expr1.X_add_number += 4;
9040
          macro_build (&expr1, s, fmt, coproc ? treg : treg + 1,
9041
                       BFD_RELOC_LO16, AT);
9042
          relax_switch ();
9043
          macro_build (&offset_expr, s, fmt, coproc ? treg + 1 : treg,
9044
                       BFD_RELOC_LO16, AT);
9045
          offset_expr.X_add_number += 4;
9046
          macro_build (&offset_expr, s, fmt, coproc ? treg : treg + 1,
9047
                       BFD_RELOC_LO16, AT);
9048
          relax_end ();
9049
 
9050
          mips_optimize = hold_mips_optimize;
9051
        }
9052
      else if (mips_big_got)
9053
        {
9054
          int gpdelay;
9055
 
9056
          /* If this is a reference to an external symbol, we want
9057
               lui      $at,<sym>               (BFD_RELOC_MIPS_GOT_HI16)
9058
               addu     $at,$at,$gp
9059
               lw       $at,<sym>($at)          (BFD_RELOC_MIPS_GOT_LO16)
9060
               nop
9061
               <op>     $treg,0($at)
9062
               <op>     $treg+1,4($at)
9063
             Otherwise we want
9064
               lw       $at,<sym>($gp)          (BFD_RELOC_MIPS_GOT16)
9065
               nop
9066
               <op>     $treg,<sym>($at)        (BFD_RELOC_LO16)
9067
               <op>     $treg+1,<sym>+4($at)    (BFD_RELOC_LO16)
9068
             If there is a base register we add it to $at before the
9069
             lwc1 instructions.  If there is a constant we include it
9070
             in the lwc1 instructions.  */
9071
          used_at = 1;
9072
          expr1.X_add_number = offset_expr.X_add_number;
9073
          offset_expr.X_add_number = 0;
9074
          if (expr1.X_add_number < -0x8000
9075
              || expr1.X_add_number >= 0x8000 - 4)
9076
            as_bad (_("PIC code offset overflow (max 16 signed bits)"));
9077
          gpdelay = reg_needs_delay (mips_gp_register);
9078
          relax_start (offset_expr.X_add_symbol);
9079 160 khays
          macro_build (&offset_expr, "lui", LUI_FMT,
9080 16 khays
                       AT, BFD_RELOC_MIPS_GOT_HI16);
9081
          macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t",
9082
                       AT, AT, mips_gp_register);
9083
          macro_build (&offset_expr, ADDRESS_LOAD_INSN, "t,o(b)",
9084
                       AT, BFD_RELOC_MIPS_GOT_LO16, AT);
9085
          load_delay_nop ();
9086
          if (breg != 0)
9087
            macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t", AT, breg, AT);
9088
          /* Itbl support may require additional care here.  */
9089
          macro_build (&expr1, s, fmt, coproc ? treg + 1 : treg,
9090
                       BFD_RELOC_LO16, AT);
9091
          expr1.X_add_number += 4;
9092
 
9093
          /* Set mips_optimize to 2 to avoid inserting an undesired
9094
             nop.  */
9095
          hold_mips_optimize = mips_optimize;
9096
          mips_optimize = 2;
9097
          /* Itbl support may require additional care here.  */
9098
          macro_build (&expr1, s, fmt, coproc ? treg : treg + 1,
9099
                       BFD_RELOC_LO16, AT);
9100
          mips_optimize = hold_mips_optimize;
9101
          expr1.X_add_number -= 4;
9102
 
9103
          relax_switch ();
9104
          offset_expr.X_add_number = expr1.X_add_number;
9105
          if (gpdelay)
9106
            macro_build (NULL, "nop", "");
9107
          macro_build (&offset_expr, ADDRESS_LOAD_INSN, "t,o(b)", AT,
9108
                       BFD_RELOC_MIPS_GOT16, mips_gp_register);
9109
          load_delay_nop ();
9110
          if (breg != 0)
9111
            macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t", AT, breg, AT);
9112
          /* Itbl support may require additional care here.  */
9113
          macro_build (&offset_expr, s, fmt, coproc ? treg + 1 : treg,
9114
                       BFD_RELOC_LO16, AT);
9115
          offset_expr.X_add_number += 4;
9116
 
9117
          /* Set mips_optimize to 2 to avoid inserting an undesired
9118
             nop.  */
9119
          hold_mips_optimize = mips_optimize;
9120
          mips_optimize = 2;
9121
          /* Itbl support may require additional care here.  */
9122
          macro_build (&offset_expr, s, fmt, coproc ? treg : treg + 1,
9123
                       BFD_RELOC_LO16, AT);
9124
          mips_optimize = hold_mips_optimize;
9125
          relax_end ();
9126
        }
9127
      else
9128
        abort ();
9129
 
9130
      break;
9131
 
9132
    case M_LD_OB:
9133
      s = HAVE_64BIT_GPRS ? "ld" : "lw";
9134
      goto sd_ob;
9135
    case M_SD_OB:
9136
      s = HAVE_64BIT_GPRS ? "sd" : "sw";
9137
    sd_ob:
9138
      macro_build (&offset_expr, s, "t,o(b)", treg,
9139
                   -1, offset_reloc[0], offset_reloc[1], offset_reloc[2],
9140
                   breg);
9141
      if (!HAVE_64BIT_GPRS)
9142
        {
9143
          offset_expr.X_add_number += 4;
9144
          macro_build (&offset_expr, s, "t,o(b)", treg + 1,
9145
                       -1, offset_reloc[0], offset_reloc[1], offset_reloc[2],
9146
                       breg);
9147
        }
9148
      break;
9149
 
9150 166 khays
 
9151
    case M_SAA_AB:
9152
      ab = 1;
9153
    case M_SAA_OB:
9154
      s = "saa";
9155
      off0 = 1;
9156
      fmt = "t,(b)";
9157
      goto ld_st;
9158
    case M_SAAD_AB:
9159
      ab = 1;
9160
    case M_SAAD_OB:
9161
      s = "saad";
9162
      off0 = 1;
9163
      fmt = "t,(b)";
9164
      goto ld_st;
9165
 
9166 16 khays
   /* New code added to support COPZ instructions.
9167
      This code builds table entries out of the macros in mip_opcodes.
9168
      R4000 uses interlocks to handle coproc delays.
9169
      Other chips (like the R3000) require nops to be inserted for delays.
9170
 
9171
      FIXME: Currently, we require that the user handle delays.
9172
      In order to fill delay slots for non-interlocked chips,
9173
      we must have a way to specify delays based on the coprocessor.
9174
      Eg. 4 cycles if load coproc reg from memory, 1 if in cache, etc.
9175
      What are the side-effects of the cop instruction?
9176
      What cache support might we have and what are its effects?
9177
      Both coprocessor & memory require delays. how long???
9178
      What registers are read/set/modified?
9179
 
9180
      If an itbl is provided to interpret cop instructions,
9181
      this knowledge can be encoded in the itbl spec.  */
9182
 
9183
    case M_COP0:
9184
      s = "c0";
9185
      goto copz;
9186
    case M_COP1:
9187
      s = "c1";
9188
      goto copz;
9189
    case M_COP2:
9190
      s = "c2";
9191
      goto copz;
9192
    case M_COP3:
9193
      s = "c3";
9194
    copz:
9195 160 khays
      gas_assert (!mips_opts.micromips);
9196 16 khays
      if (NO_ISA_COP (mips_opts.arch)
9197
          && (ip->insn_mo->pinfo2 & INSN2_M_FP_S) == 0)
9198
        {
9199 166 khays
          as_bad (_("Opcode not supported on this processor: %s"),
9200 16 khays
                  mips_cpu_info_from_arch (mips_opts.arch)->name);
9201
          break;
9202
        }
9203
 
9204
      /* For now we just do C (same as Cz).  The parameter will be
9205
         stored in insn_opcode by mips_ip.  */
9206
      macro_build (NULL, s, "C", ip->insn_opcode);
9207
      break;
9208
 
9209
    case M_MOVE:
9210
      move_register (dreg, sreg);
9211
      break;
9212
 
9213
    case M_DMUL:
9214
      dbl = 1;
9215
    case M_MUL:
9216
      macro_build (NULL, dbl ? "dmultu" : "multu", "s,t", sreg, treg);
9217 160 khays
      macro_build (NULL, "mflo", MFHL_FMT, dreg);
9218 16 khays
      break;
9219
 
9220
    case M_DMUL_I:
9221
      dbl = 1;
9222
    case M_MUL_I:
9223
      /* The MIPS assembler some times generates shifts and adds.  I'm
9224
         not trying to be that fancy. GCC should do this for us
9225
         anyway.  */
9226
      used_at = 1;
9227
      load_register (AT, &imm_expr, dbl);
9228
      macro_build (NULL, dbl ? "dmult" : "mult", "s,t", sreg, AT);
9229 160 khays
      macro_build (NULL, "mflo", MFHL_FMT, dreg);
9230 16 khays
      break;
9231
 
9232
    case M_DMULO_I:
9233
      dbl = 1;
9234
    case M_MULO_I:
9235
      imm = 1;
9236
      goto do_mulo;
9237
 
9238
    case M_DMULO:
9239
      dbl = 1;
9240
    case M_MULO:
9241
    do_mulo:
9242
      start_noreorder ();
9243
      used_at = 1;
9244
      if (imm)
9245
        load_register (AT, &imm_expr, dbl);
9246
      macro_build (NULL, dbl ? "dmult" : "mult", "s,t", sreg, imm ? AT : treg);
9247 160 khays
      macro_build (NULL, "mflo", MFHL_FMT, dreg);
9248
      macro_build (NULL, dbl ? "dsra32" : "sra", SHFT_FMT, dreg, dreg, RA);
9249
      macro_build (NULL, "mfhi", MFHL_FMT, AT);
9250 16 khays
      if (mips_trap)
9251 160 khays
        macro_build (NULL, "tne", TRAP_FMT, dreg, AT, 6);
9252 16 khays
      else
9253
        {
9254 160 khays
          if (mips_opts.micromips)
9255
            micromips_label_expr (&label_expr);
9256
          else
9257
            label_expr.X_add_number = 8;
9258
          macro_build (&label_expr, "beq", "s,t,p", dreg, AT);
9259 16 khays
          macro_build (NULL, "nop", "");
9260 160 khays
          macro_build (NULL, "break", BRK_FMT, 6);
9261
          if (mips_opts.micromips)
9262
            micromips_add_label ();
9263 16 khays
        }
9264
      end_noreorder ();
9265 160 khays
      macro_build (NULL, "mflo", MFHL_FMT, dreg);
9266 16 khays
      break;
9267
 
9268
    case M_DMULOU_I:
9269
      dbl = 1;
9270
    case M_MULOU_I:
9271
      imm = 1;
9272
      goto do_mulou;
9273
 
9274
    case M_DMULOU:
9275
      dbl = 1;
9276
    case M_MULOU:
9277
    do_mulou:
9278
      start_noreorder ();
9279
      used_at = 1;
9280
      if (imm)
9281
        load_register (AT, &imm_expr, dbl);
9282
      macro_build (NULL, dbl ? "dmultu" : "multu", "s,t",
9283
                   sreg, imm ? AT : treg);
9284 160 khays
      macro_build (NULL, "mfhi", MFHL_FMT, AT);
9285
      macro_build (NULL, "mflo", MFHL_FMT, dreg);
9286 16 khays
      if (mips_trap)
9287 160 khays
        macro_build (NULL, "tne", TRAP_FMT, AT, ZERO, 6);
9288 16 khays
      else
9289
        {
9290 160 khays
          if (mips_opts.micromips)
9291
            micromips_label_expr (&label_expr);
9292
          else
9293
            label_expr.X_add_number = 8;
9294
          macro_build (&label_expr, "beq", "s,t,p", AT, ZERO);
9295 16 khays
          macro_build (NULL, "nop", "");
9296 160 khays
          macro_build (NULL, "break", BRK_FMT, 6);
9297
          if (mips_opts.micromips)
9298
            micromips_add_label ();
9299 16 khays
        }
9300
      end_noreorder ();
9301
      break;
9302
 
9303
    case M_DROL:
9304
      if (ISA_HAS_DROR (mips_opts.isa) || CPU_HAS_DROR (mips_opts.arch))
9305
        {
9306
          if (dreg == sreg)
9307
            {
9308
              tempreg = AT;
9309
              used_at = 1;
9310
            }
9311
          else
9312
            {
9313
              tempreg = dreg;
9314
            }
9315
          macro_build (NULL, "dnegu", "d,w", tempreg, treg);
9316
          macro_build (NULL, "drorv", "d,t,s", dreg, sreg, tempreg);
9317
          break;
9318
        }
9319
      used_at = 1;
9320
      macro_build (NULL, "dsubu", "d,v,t", AT, ZERO, treg);
9321
      macro_build (NULL, "dsrlv", "d,t,s", AT, sreg, AT);
9322
      macro_build (NULL, "dsllv", "d,t,s", dreg, sreg, treg);
9323
      macro_build (NULL, "or", "d,v,t", dreg, dreg, AT);
9324
      break;
9325
 
9326
    case M_ROL:
9327
      if (ISA_HAS_ROR (mips_opts.isa) || CPU_HAS_ROR (mips_opts.arch))
9328
        {
9329
          if (dreg == sreg)
9330
            {
9331
              tempreg = AT;
9332
              used_at = 1;
9333
            }
9334
          else
9335
            {
9336
              tempreg = dreg;
9337
            }
9338
          macro_build (NULL, "negu", "d,w", tempreg, treg);
9339
          macro_build (NULL, "rorv", "d,t,s", dreg, sreg, tempreg);
9340
          break;
9341
        }
9342
      used_at = 1;
9343
      macro_build (NULL, "subu", "d,v,t", AT, ZERO, treg);
9344
      macro_build (NULL, "srlv", "d,t,s", AT, sreg, AT);
9345
      macro_build (NULL, "sllv", "d,t,s", dreg, sreg, treg);
9346
      macro_build (NULL, "or", "d,v,t", dreg, dreg, AT);
9347
      break;
9348
 
9349
    case M_DROL_I:
9350
      {
9351
        unsigned int rot;
9352
        char *l;
9353
        char *rr;
9354
 
9355
        if (imm_expr.X_op != O_constant)
9356
          as_bad (_("Improper rotate count"));
9357
        rot = imm_expr.X_add_number & 0x3f;
9358
        if (ISA_HAS_DROR (mips_opts.isa) || CPU_HAS_DROR (mips_opts.arch))
9359
          {
9360
            rot = (64 - rot) & 0x3f;
9361
            if (rot >= 32)
9362 160 khays
              macro_build (NULL, "dror32", SHFT_FMT, dreg, sreg, rot - 32);
9363 16 khays
            else
9364 160 khays
              macro_build (NULL, "dror", SHFT_FMT, dreg, sreg, rot);
9365 16 khays
            break;
9366
          }
9367
        if (rot == 0)
9368
          {
9369 160 khays
            macro_build (NULL, "dsrl", SHFT_FMT, dreg, sreg, 0);
9370 16 khays
            break;
9371
          }
9372
        l = (rot < 0x20) ? "dsll" : "dsll32";
9373
        rr = ((0x40 - rot) < 0x20) ? "dsrl" : "dsrl32";
9374
        rot &= 0x1f;
9375
        used_at = 1;
9376 160 khays
        macro_build (NULL, l, SHFT_FMT, AT, sreg, rot);
9377
        macro_build (NULL, rr, SHFT_FMT, dreg, sreg, (0x20 - rot) & 0x1f);
9378 16 khays
        macro_build (NULL, "or", "d,v,t", dreg, dreg, AT);
9379
      }
9380
      break;
9381
 
9382
    case M_ROL_I:
9383
      {
9384
        unsigned int rot;
9385
 
9386
        if (imm_expr.X_op != O_constant)
9387
          as_bad (_("Improper rotate count"));
9388
        rot = imm_expr.X_add_number & 0x1f;
9389
        if (ISA_HAS_ROR (mips_opts.isa) || CPU_HAS_ROR (mips_opts.arch))
9390
          {
9391 160 khays
            macro_build (NULL, "ror", SHFT_FMT, dreg, sreg, (32 - rot) & 0x1f);
9392 16 khays
            break;
9393
          }
9394
        if (rot == 0)
9395
          {
9396 160 khays
            macro_build (NULL, "srl", SHFT_FMT, dreg, sreg, 0);
9397 16 khays
            break;
9398
          }
9399
        used_at = 1;
9400 160 khays
        macro_build (NULL, "sll", SHFT_FMT, AT, sreg, rot);
9401
        macro_build (NULL, "srl", SHFT_FMT, dreg, sreg, (0x20 - rot) & 0x1f);
9402 16 khays
        macro_build (NULL, "or", "d,v,t", dreg, dreg, AT);
9403
      }
9404
      break;
9405
 
9406
    case M_DROR:
9407
      if (ISA_HAS_DROR (mips_opts.isa) || CPU_HAS_DROR (mips_opts.arch))
9408
        {
9409
          macro_build (NULL, "drorv", "d,t,s", dreg, sreg, treg);
9410
          break;
9411
        }
9412
      used_at = 1;
9413
      macro_build (NULL, "dsubu", "d,v,t", AT, ZERO, treg);
9414
      macro_build (NULL, "dsllv", "d,t,s", AT, sreg, AT);
9415
      macro_build (NULL, "dsrlv", "d,t,s", dreg, sreg, treg);
9416
      macro_build (NULL, "or", "d,v,t", dreg, dreg, AT);
9417
      break;
9418
 
9419
    case M_ROR:
9420
      if (ISA_HAS_ROR (mips_opts.isa) || CPU_HAS_ROR (mips_opts.arch))
9421
        {
9422
          macro_build (NULL, "rorv", "d,t,s", dreg, sreg, treg);
9423
          break;
9424
        }
9425
      used_at = 1;
9426
      macro_build (NULL, "subu", "d,v,t", AT, ZERO, treg);
9427
      macro_build (NULL, "sllv", "d,t,s", AT, sreg, AT);
9428
      macro_build (NULL, "srlv", "d,t,s", dreg, sreg, treg);
9429
      macro_build (NULL, "or", "d,v,t", dreg, dreg, AT);
9430
      break;
9431
 
9432
    case M_DROR_I:
9433
      {
9434
        unsigned int rot;
9435
        char *l;
9436
        char *rr;
9437
 
9438
        if (imm_expr.X_op != O_constant)
9439
          as_bad (_("Improper rotate count"));
9440
        rot = imm_expr.X_add_number & 0x3f;
9441
        if (ISA_HAS_DROR (mips_opts.isa) || CPU_HAS_DROR (mips_opts.arch))
9442
          {
9443
            if (rot >= 32)
9444 160 khays
              macro_build (NULL, "dror32", SHFT_FMT, dreg, sreg, rot - 32);
9445 16 khays
            else
9446 160 khays
              macro_build (NULL, "dror", SHFT_FMT, dreg, sreg, rot);
9447 16 khays
            break;
9448
          }
9449
        if (rot == 0)
9450
          {
9451 160 khays
            macro_build (NULL, "dsrl", SHFT_FMT, dreg, sreg, 0);
9452 16 khays
            break;
9453
          }
9454
        rr = (rot < 0x20) ? "dsrl" : "dsrl32";
9455
        l = ((0x40 - rot) < 0x20) ? "dsll" : "dsll32";
9456
        rot &= 0x1f;
9457
        used_at = 1;
9458 160 khays
        macro_build (NULL, rr, SHFT_FMT, AT, sreg, rot);
9459
        macro_build (NULL, l, SHFT_FMT, dreg, sreg, (0x20 - rot) & 0x1f);
9460 16 khays
        macro_build (NULL, "or", "d,v,t", dreg, dreg, AT);
9461
      }
9462
      break;
9463
 
9464
    case M_ROR_I:
9465
      {
9466
        unsigned int rot;
9467
 
9468
        if (imm_expr.X_op != O_constant)
9469
          as_bad (_("Improper rotate count"));
9470
        rot = imm_expr.X_add_number & 0x1f;
9471
        if (ISA_HAS_ROR (mips_opts.isa) || CPU_HAS_ROR (mips_opts.arch))
9472
          {
9473 160 khays
            macro_build (NULL, "ror", SHFT_FMT, dreg, sreg, rot);
9474 16 khays
            break;
9475
          }
9476
        if (rot == 0)
9477
          {
9478 160 khays
            macro_build (NULL, "srl", SHFT_FMT, dreg, sreg, 0);
9479 16 khays
            break;
9480
          }
9481
        used_at = 1;
9482 160 khays
        macro_build (NULL, "srl", SHFT_FMT, AT, sreg, rot);
9483
        macro_build (NULL, "sll", SHFT_FMT, dreg, sreg, (0x20 - rot) & 0x1f);
9484 16 khays
        macro_build (NULL, "or", "d,v,t", dreg, dreg, AT);
9485
      }
9486
      break;
9487
 
9488
    case M_SEQ:
9489
      if (sreg == 0)
9490
        macro_build (&expr1, "sltiu", "t,r,j", dreg, treg, BFD_RELOC_LO16);
9491
      else if (treg == 0)
9492
        macro_build (&expr1, "sltiu", "t,r,j", dreg, sreg, BFD_RELOC_LO16);
9493
      else
9494
        {
9495
          macro_build (NULL, "xor", "d,v,t", dreg, sreg, treg);
9496
          macro_build (&expr1, "sltiu", "t,r,j", dreg, dreg, BFD_RELOC_LO16);
9497
        }
9498
      break;
9499
 
9500
    case M_SEQ_I:
9501
      if (imm_expr.X_op == O_constant && imm_expr.X_add_number == 0)
9502
        {
9503
          macro_build (&expr1, "sltiu", "t,r,j", dreg, sreg, BFD_RELOC_LO16);
9504
          break;
9505
        }
9506
      if (sreg == 0)
9507
        {
9508
          as_warn (_("Instruction %s: result is always false"),
9509
                   ip->insn_mo->name);
9510
          move_register (dreg, 0);
9511
          break;
9512
        }
9513
      if (CPU_HAS_SEQ (mips_opts.arch)
9514
          && -512 <= imm_expr.X_add_number
9515
          && imm_expr.X_add_number < 512)
9516
        {
9517
          macro_build (NULL, "seqi", "t,r,+Q", dreg, sreg,
9518
                       (int) imm_expr.X_add_number);
9519
          break;
9520
        }
9521
      if (imm_expr.X_op == O_constant
9522
          && imm_expr.X_add_number >= 0
9523
          && imm_expr.X_add_number < 0x10000)
9524
        {
9525
          macro_build (&imm_expr, "xori", "t,r,i", dreg, sreg, BFD_RELOC_LO16);
9526
        }
9527
      else if (imm_expr.X_op == O_constant
9528
               && imm_expr.X_add_number > -0x8000
9529
               && imm_expr.X_add_number < 0)
9530
        {
9531
          imm_expr.X_add_number = -imm_expr.X_add_number;
9532
          macro_build (&imm_expr, HAVE_32BIT_GPRS ? "addiu" : "daddiu",
9533
                       "t,r,j", dreg, sreg, BFD_RELOC_LO16);
9534
        }
9535
      else if (CPU_HAS_SEQ (mips_opts.arch))
9536
        {
9537
          used_at = 1;
9538
          load_register (AT, &imm_expr, HAVE_64BIT_GPRS);
9539
          macro_build (NULL, "seq", "d,v,t", dreg, sreg, AT);
9540
          break;
9541
        }
9542
      else
9543
        {
9544
          load_register (AT, &imm_expr, HAVE_64BIT_GPRS);
9545
          macro_build (NULL, "xor", "d,v,t", dreg, sreg, AT);
9546
          used_at = 1;
9547
        }
9548
      macro_build (&expr1, "sltiu", "t,r,j", dreg, dreg, BFD_RELOC_LO16);
9549
      break;
9550
 
9551
    case M_SGE:         /* sreg >= treg <==> not (sreg < treg) */
9552
      s = "slt";
9553
      goto sge;
9554
    case M_SGEU:
9555
      s = "sltu";
9556
    sge:
9557
      macro_build (NULL, s, "d,v,t", dreg, sreg, treg);
9558
      macro_build (&expr1, "xori", "t,r,i", dreg, dreg, BFD_RELOC_LO16);
9559
      break;
9560
 
9561
    case M_SGE_I:               /* sreg >= I <==> not (sreg < I) */
9562
    case M_SGEU_I:
9563
      if (imm_expr.X_op == O_constant
9564
          && imm_expr.X_add_number >= -0x8000
9565
          && imm_expr.X_add_number < 0x8000)
9566
        {
9567
          macro_build (&imm_expr, mask == M_SGE_I ? "slti" : "sltiu", "t,r,j",
9568
                       dreg, sreg, BFD_RELOC_LO16);
9569
        }
9570
      else
9571
        {
9572
          load_register (AT, &imm_expr, HAVE_64BIT_GPRS);
9573
          macro_build (NULL, mask == M_SGE_I ? "slt" : "sltu", "d,v,t",
9574
                       dreg, sreg, AT);
9575
          used_at = 1;
9576
        }
9577
      macro_build (&expr1, "xori", "t,r,i", dreg, dreg, BFD_RELOC_LO16);
9578
      break;
9579
 
9580
    case M_SGT:         /* sreg > treg  <==>  treg < sreg */
9581
      s = "slt";
9582
      goto sgt;
9583
    case M_SGTU:
9584
      s = "sltu";
9585
    sgt:
9586
      macro_build (NULL, s, "d,v,t", dreg, treg, sreg);
9587
      break;
9588
 
9589
    case M_SGT_I:               /* sreg > I  <==>  I < sreg */
9590
      s = "slt";
9591
      goto sgti;
9592
    case M_SGTU_I:
9593
      s = "sltu";
9594
    sgti:
9595
      used_at = 1;
9596
      load_register (AT, &imm_expr, HAVE_64BIT_GPRS);
9597
      macro_build (NULL, s, "d,v,t", dreg, AT, sreg);
9598
      break;
9599
 
9600
    case M_SLE: /* sreg <= treg  <==>  treg >= sreg  <==>  not (treg < sreg) */
9601
      s = "slt";
9602
      goto sle;
9603
    case M_SLEU:
9604
      s = "sltu";
9605
    sle:
9606
      macro_build (NULL, s, "d,v,t", dreg, treg, sreg);
9607
      macro_build (&expr1, "xori", "t,r,i", dreg, dreg, BFD_RELOC_LO16);
9608
      break;
9609
 
9610
    case M_SLE_I:       /* sreg <= I <==> I >= sreg <==> not (I < sreg) */
9611
      s = "slt";
9612
      goto slei;
9613
    case M_SLEU_I:
9614
      s = "sltu";
9615
    slei:
9616
      used_at = 1;
9617
      load_register (AT, &imm_expr, HAVE_64BIT_GPRS);
9618
      macro_build (NULL, s, "d,v,t", dreg, AT, sreg);
9619
      macro_build (&expr1, "xori", "t,r,i", dreg, dreg, BFD_RELOC_LO16);
9620
      break;
9621
 
9622
    case M_SLT_I:
9623
      if (imm_expr.X_op == O_constant
9624
          && imm_expr.X_add_number >= -0x8000
9625
          && imm_expr.X_add_number < 0x8000)
9626
        {
9627
          macro_build (&imm_expr, "slti", "t,r,j", dreg, sreg, BFD_RELOC_LO16);
9628
          break;
9629
        }
9630
      used_at = 1;
9631
      load_register (AT, &imm_expr, HAVE_64BIT_GPRS);
9632
      macro_build (NULL, "slt", "d,v,t", dreg, sreg, AT);
9633
      break;
9634
 
9635
    case M_SLTU_I:
9636
      if (imm_expr.X_op == O_constant
9637
          && imm_expr.X_add_number >= -0x8000
9638
          && imm_expr.X_add_number < 0x8000)
9639
        {
9640
          macro_build (&imm_expr, "sltiu", "t,r,j", dreg, sreg,
9641
                       BFD_RELOC_LO16);
9642
          break;
9643
        }
9644
      used_at = 1;
9645
      load_register (AT, &imm_expr, HAVE_64BIT_GPRS);
9646
      macro_build (NULL, "sltu", "d,v,t", dreg, sreg, AT);
9647
      break;
9648
 
9649
    case M_SNE:
9650
      if (sreg == 0)
9651
        macro_build (NULL, "sltu", "d,v,t", dreg, 0, treg);
9652
      else if (treg == 0)
9653
        macro_build (NULL, "sltu", "d,v,t", dreg, 0, sreg);
9654
      else
9655
        {
9656
          macro_build (NULL, "xor", "d,v,t", dreg, sreg, treg);
9657
          macro_build (NULL, "sltu", "d,v,t", dreg, 0, dreg);
9658
        }
9659
      break;
9660
 
9661
    case M_SNE_I:
9662
      if (imm_expr.X_op == O_constant && imm_expr.X_add_number == 0)
9663
        {
9664
          macro_build (NULL, "sltu", "d,v,t", dreg, 0, sreg);
9665
          break;
9666
        }
9667
      if (sreg == 0)
9668
        {
9669
          as_warn (_("Instruction %s: result is always true"),
9670
                   ip->insn_mo->name);
9671
          macro_build (&expr1, HAVE_32BIT_GPRS ? "addiu" : "daddiu", "t,r,j",
9672
                       dreg, 0, BFD_RELOC_LO16);
9673
          break;
9674
        }
9675
      if (CPU_HAS_SEQ (mips_opts.arch)
9676
          && -512 <= imm_expr.X_add_number
9677
          && imm_expr.X_add_number < 512)
9678
        {
9679
          macro_build (NULL, "snei", "t,r,+Q", dreg, sreg,
9680
                       (int) imm_expr.X_add_number);
9681
          break;
9682
        }
9683
      if (imm_expr.X_op == O_constant
9684
          && imm_expr.X_add_number >= 0
9685
          && imm_expr.X_add_number < 0x10000)
9686
        {
9687
          macro_build (&imm_expr, "xori", "t,r,i", dreg, sreg, BFD_RELOC_LO16);
9688
        }
9689
      else if (imm_expr.X_op == O_constant
9690
               && imm_expr.X_add_number > -0x8000
9691
               && imm_expr.X_add_number < 0)
9692
        {
9693
          imm_expr.X_add_number = -imm_expr.X_add_number;
9694
          macro_build (&imm_expr, HAVE_32BIT_GPRS ? "addiu" : "daddiu",
9695
                       "t,r,j", dreg, sreg, BFD_RELOC_LO16);
9696
        }
9697
      else if (CPU_HAS_SEQ (mips_opts.arch))
9698
        {
9699
          used_at = 1;
9700
          load_register (AT, &imm_expr, HAVE_64BIT_GPRS);
9701
          macro_build (NULL, "sne", "d,v,t", dreg, sreg, AT);
9702
          break;
9703
        }
9704
      else
9705
        {
9706
          load_register (AT, &imm_expr, HAVE_64BIT_GPRS);
9707
          macro_build (NULL, "xor", "d,v,t", dreg, sreg, AT);
9708
          used_at = 1;
9709
        }
9710
      macro_build (NULL, "sltu", "d,v,t", dreg, 0, dreg);
9711
      break;
9712
 
9713 160 khays
    case M_SUB_I:
9714
      s = "addi";
9715
      s2 = "sub";
9716
      goto do_subi;
9717
    case M_SUBU_I:
9718
      s = "addiu";
9719
      s2 = "subu";
9720
      goto do_subi;
9721 16 khays
    case M_DSUB_I:
9722
      dbl = 1;
9723 160 khays
      s = "daddi";
9724
      s2 = "dsub";
9725
      if (!mips_opts.micromips)
9726
        goto do_subi;
9727 16 khays
      if (imm_expr.X_op == O_constant
9728 160 khays
          && imm_expr.X_add_number > -0x200
9729
          && imm_expr.X_add_number <= 0x200)
9730 16 khays
        {
9731 160 khays
          macro_build (NULL, s, "t,r,.", dreg, sreg, -imm_expr.X_add_number);
9732 16 khays
          break;
9733
        }
9734 160 khays
      goto do_subi_i;
9735 16 khays
    case M_DSUBU_I:
9736
      dbl = 1;
9737 160 khays
      s = "daddiu";
9738
      s2 = "dsubu";
9739
    do_subi:
9740 16 khays
      if (imm_expr.X_op == O_constant
9741
          && imm_expr.X_add_number > -0x8000
9742
          && imm_expr.X_add_number <= 0x8000)
9743
        {
9744
          imm_expr.X_add_number = -imm_expr.X_add_number;
9745 160 khays
          macro_build (&imm_expr, s, "t,r,j", dreg, sreg, BFD_RELOC_LO16);
9746 16 khays
          break;
9747
        }
9748 160 khays
    do_subi_i:
9749 16 khays
      used_at = 1;
9750
      load_register (AT, &imm_expr, dbl);
9751 160 khays
      macro_build (NULL, s2, "d,v,t", dreg, sreg, AT);
9752 16 khays
      break;
9753
 
9754
    case M_TEQ_I:
9755
      s = "teq";
9756
      goto trap;
9757
    case M_TGE_I:
9758
      s = "tge";
9759
      goto trap;
9760
    case M_TGEU_I:
9761
      s = "tgeu";
9762
      goto trap;
9763
    case M_TLT_I:
9764
      s = "tlt";
9765
      goto trap;
9766
    case M_TLTU_I:
9767
      s = "tltu";
9768
      goto trap;
9769
    case M_TNE_I:
9770
      s = "tne";
9771
    trap:
9772
      used_at = 1;
9773
      load_register (AT, &imm_expr, HAVE_64BIT_GPRS);
9774
      macro_build (NULL, s, "s,t", sreg, AT);
9775
      break;
9776
 
9777
    case M_TRUNCWS:
9778
    case M_TRUNCWD:
9779 160 khays
      gas_assert (!mips_opts.micromips);
9780 16 khays
      gas_assert (mips_opts.isa == ISA_MIPS1);
9781
      used_at = 1;
9782
      sreg = (ip->insn_opcode >> 11) & 0x1f;    /* floating reg */
9783
      dreg = (ip->insn_opcode >> 06) & 0x1f;    /* floating reg */
9784
 
9785
      /*
9786
       * Is the double cfc1 instruction a bug in the mips assembler;
9787
       * or is there a reason for it?
9788
       */
9789
      start_noreorder ();
9790
      macro_build (NULL, "cfc1", "t,G", treg, RA);
9791
      macro_build (NULL, "cfc1", "t,G", treg, RA);
9792
      macro_build (NULL, "nop", "");
9793
      expr1.X_add_number = 3;
9794
      macro_build (&expr1, "ori", "t,r,i", AT, treg, BFD_RELOC_LO16);
9795
      expr1.X_add_number = 2;
9796
      macro_build (&expr1, "xori", "t,r,i", AT, AT, BFD_RELOC_LO16);
9797
      macro_build (NULL, "ctc1", "t,G", AT, RA);
9798
      macro_build (NULL, "nop", "");
9799
      macro_build (NULL, mask == M_TRUNCWD ? "cvt.w.d" : "cvt.w.s", "D,S",
9800
                   dreg, sreg);
9801
      macro_build (NULL, "ctc1", "t,G", treg, RA);
9802
      macro_build (NULL, "nop", "");
9803
      end_noreorder ();
9804
      break;
9805
 
9806 160 khays
    case M_ULH_A:
9807
      ab = 1;
9808 16 khays
    case M_ULH:
9809
      s = "lb";
9810 160 khays
      s2 = "lbu";
9811
      off = 1;
9812
      goto uld_st;
9813
    case M_ULHU_A:
9814
      ab = 1;
9815 16 khays
    case M_ULHU:
9816
      s = "lbu";
9817 160 khays
      s2 = "lbu";
9818
      off = 1;
9819
      goto uld_st;
9820
    case M_ULW_A:
9821
      ab = 1;
9822
    case M_ULW:
9823
      s = "lwl";
9824
      s2 = "lwr";
9825
      off12 = mips_opts.micromips;
9826
      off = 3;
9827
      goto uld_st;
9828
    case M_ULD_A:
9829
      ab = 1;
9830 16 khays
    case M_ULD:
9831
      s = "ldl";
9832
      s2 = "ldr";
9833 160 khays
      off12 = mips_opts.micromips;
9834 16 khays
      off = 7;
9835 160 khays
      goto uld_st;
9836
    case M_USH_A:
9837
      ab = 1;
9838
    case M_USH:
9839
      s = "sb";
9840
      s2 = "sb";
9841
      off = 1;
9842
      ust = 1;
9843
      goto uld_st;
9844
    case M_USW_A:
9845
      ab = 1;
9846
    case M_USW:
9847
      s = "swl";
9848
      s2 = "swr";
9849
      off12 = mips_opts.micromips;
9850 16 khays
      off = 3;
9851 160 khays
      ust = 1;
9852
      goto uld_st;
9853
    case M_USD_A:
9854
      ab = 1;
9855
    case M_USD:
9856
      s = "sdl";
9857
      s2 = "sdr";
9858
      off12 = mips_opts.micromips;
9859
      off = 7;
9860
      ust = 1;
9861
 
9862
    uld_st:
9863
      if (!ab && offset_expr.X_add_number >= 0x8000 - off)
9864 16 khays
        as_bad (_("Operand overflow"));
9865 160 khays
 
9866
      ep = &offset_expr;
9867
      expr1.X_add_number = 0;
9868
      if (ab)
9869 16 khays
        {
9870
          used_at = 1;
9871
          tempreg = AT;
9872 160 khays
          load_address (tempreg, ep, &used_at);
9873
          if (breg != 0)
9874
            macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t",
9875
                         tempreg, tempreg, breg);
9876
          breg = tempreg;
9877
          tempreg = treg;
9878
          ep = &expr1;
9879 16 khays
        }
9880 160 khays
      else if (off12
9881
               && (offset_expr.X_op != O_constant
9882
                   || !IS_SEXT_12BIT_NUM (offset_expr.X_add_number)
9883
                   || !IS_SEXT_12BIT_NUM (offset_expr.X_add_number + off)))
9884
        {
9885
          used_at = 1;
9886
          tempreg = AT;
9887
          macro_build (ep, ADDRESS_ADDI_INSN, "t,r,j", tempreg, breg,
9888
                       -1, offset_reloc[0], offset_reloc[1], offset_reloc[2]);
9889
          breg = tempreg;
9890
          tempreg = treg;
9891
          ep = &expr1;
9892
        }
9893
      else if (!ust && treg == breg)
9894
        {
9895
          used_at = 1;
9896
          tempreg = AT;
9897
        }
9898 16 khays
      else
9899 160 khays
        tempreg = treg;
9900 16 khays
 
9901 160 khays
      if (off == 1)
9902
        goto ulh_sh;
9903 16 khays
 
9904
      if (!target_big_endian)
9905 160 khays
        ep->X_add_number += off;
9906
      if (!off12)
9907
        macro_build (ep, s, "t,o(b)", tempreg, BFD_RELOC_LO16, breg);
9908 16 khays
      else
9909 160 khays
        macro_build (NULL, s, "t,~(b)",
9910
                     tempreg, (unsigned long) ep->X_add_number, breg);
9911
 
9912 16 khays
      if (!target_big_endian)
9913 160 khays
        ep->X_add_number -= off;
9914 16 khays
      else
9915 160 khays
        ep->X_add_number += off;
9916
      if (!off12)
9917
        macro_build (ep, s2, "t,o(b)", tempreg, BFD_RELOC_LO16, breg);
9918
      else
9919
        macro_build (NULL, s2, "t,~(b)",
9920
                     tempreg, (unsigned long) ep->X_add_number, breg);
9921 16 khays
 
9922 160 khays
      /* If necessary, move the result in tempreg to the final destination.  */
9923
      if (!ust && treg != tempreg)
9924
        {
9925
          /* Protect second load's delay slot.  */
9926
          load_delay_nop ();
9927
          move_register (treg, tempreg);
9928
        }
9929 16 khays
      break;
9930
 
9931 160 khays
    ulh_sh:
9932 16 khays
      used_at = 1;
9933 160 khays
      if (target_big_endian == ust)
9934
        ep->X_add_number += off;
9935
      tempreg = ust || ab ? treg : AT;
9936
      macro_build (ep, s, "t,o(b)", tempreg, BFD_RELOC_LO16, breg);
9937 16 khays
 
9938 160 khays
      /* For halfword transfers we need a temporary register to shuffle
9939
         bytes.  Unfortunately for M_USH_A we have none available before
9940
         the next store as AT holds the base address.  We deal with this
9941
         case by clobbering TREG and then restoring it as with ULH.  */
9942
      tempreg = ust == ab ? treg : AT;
9943
      if (ust)
9944
        macro_build (NULL, "srl", SHFT_FMT, tempreg, treg, 8);
9945 16 khays
 
9946 160 khays
      if (target_big_endian == ust)
9947
        ep->X_add_number -= off;
9948 16 khays
      else
9949 160 khays
        ep->X_add_number += off;
9950
      macro_build (ep, s2, "t,o(b)", tempreg, BFD_RELOC_LO16, breg);
9951 16 khays
 
9952 160 khays
      /* For M_USH_A re-retrieve the LSB.  */
9953
      if (ust && ab)
9954
        {
9955
          if (target_big_endian)
9956
            ep->X_add_number += off;
9957
          else
9958
            ep->X_add_number -= off;
9959
          macro_build (&expr1, "lbu", "t,o(b)", AT, BFD_RELOC_LO16, AT);
9960
        }
9961
      /* For ULH and M_USH_A OR the LSB in.  */
9962
      if (!ust || ab)
9963
        {
9964
          tempreg = !ab ? AT : treg;
9965
          macro_build (NULL, "sll", SHFT_FMT, tempreg, tempreg, 8);
9966
          macro_build (NULL, "or", "d,v,t", treg, treg, AT);
9967
        }
9968 16 khays
      break;
9969
 
9970
    default:
9971
      /* FIXME: Check if this is one of the itbl macros, since they
9972
         are added dynamically.  */
9973
      as_bad (_("Macro %s not implemented yet"), ip->insn_mo->name);
9974
      break;
9975
    }
9976
  if (!mips_opts.at && used_at)
9977
    as_bad (_("Macro used $at after \".set noat\""));
9978
}
9979
 
9980
/* Implement macros in mips16 mode.  */
9981
 
9982
static void
9983
mips16_macro (struct mips_cl_insn *ip)
9984
{
9985
  int mask;
9986
  int xreg, yreg, zreg, tmp;
9987
  expressionS expr1;
9988
  int dbl;
9989
  const char *s, *s2, *s3;
9990
 
9991
  mask = ip->insn_mo->mask;
9992
 
9993
  xreg = MIPS16_EXTRACT_OPERAND (RX, *ip);
9994
  yreg = MIPS16_EXTRACT_OPERAND (RY, *ip);
9995
  zreg = MIPS16_EXTRACT_OPERAND (RZ, *ip);
9996
 
9997
  expr1.X_op = O_constant;
9998
  expr1.X_op_symbol = NULL;
9999
  expr1.X_add_symbol = NULL;
10000
  expr1.X_add_number = 1;
10001
 
10002
  dbl = 0;
10003
 
10004
  switch (mask)
10005
    {
10006
    default:
10007
      internalError ();
10008
 
10009
    case M_DDIV_3:
10010
      dbl = 1;
10011
    case M_DIV_3:
10012
      s = "mflo";
10013
      goto do_div3;
10014
    case M_DREM_3:
10015
      dbl = 1;
10016
    case M_REM_3:
10017
      s = "mfhi";
10018
    do_div3:
10019
      start_noreorder ();
10020
      macro_build (NULL, dbl ? "ddiv" : "div", "0,x,y", xreg, yreg);
10021
      expr1.X_add_number = 2;
10022
      macro_build (&expr1, "bnez", "x,p", yreg);
10023
      macro_build (NULL, "break", "6", 7);
10024
 
10025
      /* FIXME: The normal code checks for of -1 / -0x80000000 here,
10026
         since that causes an overflow.  We should do that as well,
10027
         but I don't see how to do the comparisons without a temporary
10028
         register.  */
10029
      end_noreorder ();
10030
      macro_build (NULL, s, "x", zreg);
10031
      break;
10032
 
10033
    case M_DIVU_3:
10034
      s = "divu";
10035
      s2 = "mflo";
10036
      goto do_divu3;
10037
    case M_REMU_3:
10038
      s = "divu";
10039
      s2 = "mfhi";
10040
      goto do_divu3;
10041
    case M_DDIVU_3:
10042
      s = "ddivu";
10043
      s2 = "mflo";
10044
      goto do_divu3;
10045
    case M_DREMU_3:
10046
      s = "ddivu";
10047
      s2 = "mfhi";
10048
    do_divu3:
10049
      start_noreorder ();
10050
      macro_build (NULL, s, "0,x,y", xreg, yreg);
10051
      expr1.X_add_number = 2;
10052
      macro_build (&expr1, "bnez", "x,p", yreg);
10053
      macro_build (NULL, "break", "6", 7);
10054
      end_noreorder ();
10055
      macro_build (NULL, s2, "x", zreg);
10056
      break;
10057
 
10058
    case M_DMUL:
10059
      dbl = 1;
10060
    case M_MUL:
10061
      macro_build (NULL, dbl ? "dmultu" : "multu", "x,y", xreg, yreg);
10062
      macro_build (NULL, "mflo", "x", zreg);
10063
      break;
10064
 
10065
    case M_DSUBU_I:
10066
      dbl = 1;
10067
      goto do_subu;
10068
    case M_SUBU_I:
10069
    do_subu:
10070
      if (imm_expr.X_op != O_constant)
10071
        as_bad (_("Unsupported large constant"));
10072
      imm_expr.X_add_number = -imm_expr.X_add_number;
10073
      macro_build (&imm_expr, dbl ? "daddiu" : "addiu", "y,x,4", yreg, xreg);
10074
      break;
10075
 
10076
    case M_SUBU_I_2:
10077
      if (imm_expr.X_op != O_constant)
10078
        as_bad (_("Unsupported large constant"));
10079
      imm_expr.X_add_number = -imm_expr.X_add_number;
10080
      macro_build (&imm_expr, "addiu", "x,k", xreg);
10081
      break;
10082
 
10083
    case M_DSUBU_I_2:
10084
      if (imm_expr.X_op != O_constant)
10085
        as_bad (_("Unsupported large constant"));
10086
      imm_expr.X_add_number = -imm_expr.X_add_number;
10087
      macro_build (&imm_expr, "daddiu", "y,j", yreg);
10088
      break;
10089
 
10090
    case M_BEQ:
10091
      s = "cmp";
10092
      s2 = "bteqz";
10093
      goto do_branch;
10094
    case M_BNE:
10095
      s = "cmp";
10096
      s2 = "btnez";
10097
      goto do_branch;
10098
    case M_BLT:
10099
      s = "slt";
10100
      s2 = "btnez";
10101
      goto do_branch;
10102
    case M_BLTU:
10103
      s = "sltu";
10104
      s2 = "btnez";
10105
      goto do_branch;
10106
    case M_BLE:
10107
      s = "slt";
10108
      s2 = "bteqz";
10109
      goto do_reverse_branch;
10110
    case M_BLEU:
10111
      s = "sltu";
10112
      s2 = "bteqz";
10113
      goto do_reverse_branch;
10114
    case M_BGE:
10115
      s = "slt";
10116
      s2 = "bteqz";
10117
      goto do_branch;
10118
    case M_BGEU:
10119
      s = "sltu";
10120
      s2 = "bteqz";
10121
      goto do_branch;
10122
    case M_BGT:
10123
      s = "slt";
10124
      s2 = "btnez";
10125
      goto do_reverse_branch;
10126
    case M_BGTU:
10127
      s = "sltu";
10128
      s2 = "btnez";
10129
 
10130
    do_reverse_branch:
10131
      tmp = xreg;
10132
      xreg = yreg;
10133
      yreg = tmp;
10134
 
10135
    do_branch:
10136
      macro_build (NULL, s, "x,y", xreg, yreg);
10137
      macro_build (&offset_expr, s2, "p");
10138
      break;
10139
 
10140
    case M_BEQ_I:
10141
      s = "cmpi";
10142
      s2 = "bteqz";
10143
      s3 = "x,U";
10144
      goto do_branch_i;
10145
    case M_BNE_I:
10146
      s = "cmpi";
10147
      s2 = "btnez";
10148
      s3 = "x,U";
10149
      goto do_branch_i;
10150
    case M_BLT_I:
10151
      s = "slti";
10152
      s2 = "btnez";
10153
      s3 = "x,8";
10154
      goto do_branch_i;
10155
    case M_BLTU_I:
10156
      s = "sltiu";
10157
      s2 = "btnez";
10158
      s3 = "x,8";
10159
      goto do_branch_i;
10160
    case M_BLE_I:
10161
      s = "slti";
10162
      s2 = "btnez";
10163
      s3 = "x,8";
10164
      goto do_addone_branch_i;
10165
    case M_BLEU_I:
10166
      s = "sltiu";
10167
      s2 = "btnez";
10168
      s3 = "x,8";
10169
      goto do_addone_branch_i;
10170
    case M_BGE_I:
10171
      s = "slti";
10172
      s2 = "bteqz";
10173
      s3 = "x,8";
10174
      goto do_branch_i;
10175
    case M_BGEU_I:
10176
      s = "sltiu";
10177
      s2 = "bteqz";
10178
      s3 = "x,8";
10179
      goto do_branch_i;
10180
    case M_BGT_I:
10181
      s = "slti";
10182
      s2 = "bteqz";
10183
      s3 = "x,8";
10184
      goto do_addone_branch_i;
10185
    case M_BGTU_I:
10186
      s = "sltiu";
10187
      s2 = "bteqz";
10188
      s3 = "x,8";
10189
 
10190
    do_addone_branch_i:
10191
      if (imm_expr.X_op != O_constant)
10192
        as_bad (_("Unsupported large constant"));
10193
      ++imm_expr.X_add_number;
10194
 
10195
    do_branch_i:
10196
      macro_build (&imm_expr, s, s3, xreg);
10197
      macro_build (&offset_expr, s2, "p");
10198
      break;
10199
 
10200
    case M_ABS:
10201
      expr1.X_add_number = 0;
10202
      macro_build (&expr1, "slti", "x,8", yreg);
10203
      if (xreg != yreg)
10204
        move_register (xreg, yreg);
10205
      expr1.X_add_number = 2;
10206
      macro_build (&expr1, "bteqz", "p");
10207
      macro_build (NULL, "neg", "x,w", xreg, xreg);
10208
    }
10209
}
10210
 
10211
/* For consistency checking, verify that all bits are specified either
10212
   by the match/mask part of the instruction definition, or by the
10213
   operand list.  */
10214
static int
10215
validate_mips_insn (const struct mips_opcode *opc)
10216
{
10217
  const char *p = opc->args;
10218
  char c;
10219
  unsigned long used_bits = opc->mask;
10220
 
10221
  if ((used_bits & opc->match) != opc->match)
10222
    {
10223
      as_bad (_("internal: bad mips opcode (mask error): %s %s"),
10224
              opc->name, opc->args);
10225
      return 0;
10226
    }
10227
#define USE_BITS(mask,shift)    (used_bits |= ((mask) << (shift)))
10228
  while (*p)
10229
    switch (c = *p++)
10230
      {
10231
      case ',': break;
10232
      case '(': break;
10233
      case ')': break;
10234
      case '+':
10235
        switch (c = *p++)
10236
          {
10237
          case '1': USE_BITS (OP_MASK_UDI1,     OP_SH_UDI1);    break;
10238
          case '2': USE_BITS (OP_MASK_UDI2,     OP_SH_UDI2);    break;
10239
          case '3': USE_BITS (OP_MASK_UDI3,     OP_SH_UDI3);    break;
10240
          case '4': USE_BITS (OP_MASK_UDI4,     OP_SH_UDI4);    break;
10241
          case 'A': USE_BITS (OP_MASK_SHAMT,    OP_SH_SHAMT);   break;
10242
          case 'B': USE_BITS (OP_MASK_INSMSB,   OP_SH_INSMSB);  break;
10243
          case 'C': USE_BITS (OP_MASK_EXTMSBD,  OP_SH_EXTMSBD); break;
10244
          case 'D': USE_BITS (OP_MASK_RD,       OP_SH_RD);
10245
                    USE_BITS (OP_MASK_SEL,      OP_SH_SEL);     break;
10246
          case 'E': USE_BITS (OP_MASK_SHAMT,    OP_SH_SHAMT);   break;
10247
          case 'F': USE_BITS (OP_MASK_INSMSB,   OP_SH_INSMSB);  break;
10248
          case 'G': USE_BITS (OP_MASK_EXTMSBD,  OP_SH_EXTMSBD); break;
10249
          case 'H': USE_BITS (OP_MASK_EXTMSBD,  OP_SH_EXTMSBD); break;
10250
          case 'I': break;
10251
          case 't': USE_BITS (OP_MASK_RT,       OP_SH_RT);      break;
10252
          case 'T': USE_BITS (OP_MASK_RT,       OP_SH_RT);
10253
                    USE_BITS (OP_MASK_SEL,      OP_SH_SEL);     break;
10254
          case 'x': USE_BITS (OP_MASK_BBITIND,  OP_SH_BBITIND); break;
10255
          case 'X': USE_BITS (OP_MASK_BBITIND,  OP_SH_BBITIND); break;
10256
          case 'p': USE_BITS (OP_MASK_CINSPOS,  OP_SH_CINSPOS); break;
10257
          case 'P': USE_BITS (OP_MASK_CINSPOS,  OP_SH_CINSPOS); break;
10258
          case 'Q': USE_BITS (OP_MASK_SEQI,     OP_SH_SEQI);    break;
10259
          case 's': USE_BITS (OP_MASK_CINSLM1,  OP_SH_CINSLM1); break;
10260
          case 'S': USE_BITS (OP_MASK_CINSLM1,  OP_SH_CINSLM1); break;
10261
          case 'z': USE_BITS (OP_MASK_RZ,       OP_SH_RZ);      break;
10262
          case 'Z': USE_BITS (OP_MASK_FZ,       OP_SH_FZ);      break;
10263
          case 'a': USE_BITS (OP_MASK_OFFSET_A, OP_SH_OFFSET_A); break;
10264
          case 'b': USE_BITS (OP_MASK_OFFSET_B, OP_SH_OFFSET_B); break;
10265
          case 'c': USE_BITS (OP_MASK_OFFSET_C, OP_SH_OFFSET_C); break;
10266
 
10267
          default:
10268
            as_bad (_("internal: bad mips opcode (unknown extension operand type `+%c'): %s %s"),
10269
                    c, opc->name, opc->args);
10270
            return 0;
10271
          }
10272
        break;
10273
      case '<': USE_BITS (OP_MASK_SHAMT,        OP_SH_SHAMT);   break;
10274
      case '>': USE_BITS (OP_MASK_SHAMT,        OP_SH_SHAMT);   break;
10275
      case 'A': break;
10276
      case 'B': USE_BITS (OP_MASK_CODE20,       OP_SH_CODE20);  break;
10277
      case 'C': USE_BITS (OP_MASK_COPZ,         OP_SH_COPZ);    break;
10278
      case 'D': USE_BITS (OP_MASK_FD,           OP_SH_FD);      break;
10279
      case 'E': USE_BITS (OP_MASK_RT,           OP_SH_RT);      break;
10280
      case 'F': break;
10281
      case 'G': USE_BITS (OP_MASK_RD,           OP_SH_RD);      break;
10282
      case 'H': USE_BITS (OP_MASK_SEL,          OP_SH_SEL);     break;
10283
      case 'I': break;
10284
      case 'J': USE_BITS (OP_MASK_CODE19,       OP_SH_CODE19);  break;
10285
      case 'K': USE_BITS (OP_MASK_RD,           OP_SH_RD);      break;
10286
      case 'L': break;
10287
      case 'M': USE_BITS (OP_MASK_CCC,          OP_SH_CCC);     break;
10288
      case 'N': USE_BITS (OP_MASK_BCC,          OP_SH_BCC);     break;
10289
      case 'O': USE_BITS (OP_MASK_ALN,          OP_SH_ALN);     break;
10290
      case 'Q': USE_BITS (OP_MASK_VSEL,         OP_SH_VSEL);
10291
                USE_BITS (OP_MASK_FT,           OP_SH_FT);      break;
10292
      case 'R': USE_BITS (OP_MASK_FR,           OP_SH_FR);      break;
10293
      case 'S': USE_BITS (OP_MASK_FS,           OP_SH_FS);      break;
10294
      case 'T': USE_BITS (OP_MASK_FT,           OP_SH_FT);      break;
10295
      case 'V': USE_BITS (OP_MASK_FS,           OP_SH_FS);      break;
10296
      case 'W': USE_BITS (OP_MASK_FT,           OP_SH_FT);      break;
10297
      case 'X': USE_BITS (OP_MASK_FD,           OP_SH_FD);      break;
10298
      case 'Y': USE_BITS (OP_MASK_FS,           OP_SH_FS);      break;
10299
      case 'Z': USE_BITS (OP_MASK_FT,           OP_SH_FT);      break;
10300
      case 'a': USE_BITS (OP_MASK_TARGET,       OP_SH_TARGET);  break;
10301
      case 'b': USE_BITS (OP_MASK_RS,           OP_SH_RS);      break;
10302
      case 'c': USE_BITS (OP_MASK_CODE,         OP_SH_CODE);    break;
10303
      case 'd': USE_BITS (OP_MASK_RD,           OP_SH_RD);      break;
10304
      case 'f': break;
10305
      case 'h': USE_BITS (OP_MASK_PREFX,        OP_SH_PREFX);   break;
10306
      case 'i': USE_BITS (OP_MASK_IMMEDIATE,    OP_SH_IMMEDIATE); break;
10307
      case 'j': USE_BITS (OP_MASK_DELTA,        OP_SH_DELTA);   break;
10308
      case 'k': USE_BITS (OP_MASK_CACHE,        OP_SH_CACHE);   break;
10309
      case 'l': break;
10310
      case 'o': USE_BITS (OP_MASK_DELTA,        OP_SH_DELTA);   break;
10311
      case 'p': USE_BITS (OP_MASK_DELTA,        OP_SH_DELTA);   break;
10312
      case 'q': USE_BITS (OP_MASK_CODE2,        OP_SH_CODE2);   break;
10313
      case 'r': USE_BITS (OP_MASK_RS,           OP_SH_RS);      break;
10314
      case 's': USE_BITS (OP_MASK_RS,           OP_SH_RS);      break;
10315
      case 't': USE_BITS (OP_MASK_RT,           OP_SH_RT);      break;
10316
      case 'u': USE_BITS (OP_MASK_IMMEDIATE,    OP_SH_IMMEDIATE); break;
10317
      case 'v': USE_BITS (OP_MASK_RS,           OP_SH_RS);      break;
10318
      case 'w': USE_BITS (OP_MASK_RT,           OP_SH_RT);      break;
10319
      case 'x': break;
10320
      case 'z': break;
10321
      case 'P': USE_BITS (OP_MASK_PERFREG,      OP_SH_PERFREG); break;
10322
      case 'U': USE_BITS (OP_MASK_RD,           OP_SH_RD);
10323
                USE_BITS (OP_MASK_RT,           OP_SH_RT);      break;
10324
      case 'e': USE_BITS (OP_MASK_VECBYTE,      OP_SH_VECBYTE); break;
10325
      case '%': USE_BITS (OP_MASK_VECALIGN,     OP_SH_VECALIGN); break;
10326
      case '[': break;
10327
      case ']': break;
10328
      case '1': USE_BITS (OP_MASK_SHAMT,        OP_SH_SHAMT);   break;
10329
      case '2': USE_BITS (OP_MASK_BP,           OP_SH_BP);      break;
10330
      case '3': USE_BITS (OP_MASK_SA3,          OP_SH_SA3);     break;
10331
      case '4': USE_BITS (OP_MASK_SA4,          OP_SH_SA4);     break;
10332
      case '5': USE_BITS (OP_MASK_IMM8,         OP_SH_IMM8);    break;
10333
      case '6': USE_BITS (OP_MASK_RS,           OP_SH_RS);      break;
10334
      case '7': USE_BITS (OP_MASK_DSPACC,       OP_SH_DSPACC);  break;
10335
      case '8': USE_BITS (OP_MASK_WRDSP,        OP_SH_WRDSP);   break;
10336
      case '9': USE_BITS (OP_MASK_DSPACC_S,     OP_SH_DSPACC_S);break;
10337
      case '0': USE_BITS (OP_MASK_DSPSFT,       OP_SH_DSPSFT);  break;
10338
      case '\'': USE_BITS (OP_MASK_RDDSP,       OP_SH_RDDSP);   break;
10339
      case ':': USE_BITS (OP_MASK_DSPSFT_7,     OP_SH_DSPSFT_7);break;
10340
      case '@': USE_BITS (OP_MASK_IMM10,        OP_SH_IMM10);   break;
10341
      case '!': USE_BITS (OP_MASK_MT_U,         OP_SH_MT_U);    break;
10342
      case '$': USE_BITS (OP_MASK_MT_H,         OP_SH_MT_H);    break;
10343
      case '*': USE_BITS (OP_MASK_MTACC_T,      OP_SH_MTACC_T); break;
10344
      case '&': USE_BITS (OP_MASK_MTACC_D,      OP_SH_MTACC_D); break;
10345 160 khays
      case '\\': USE_BITS (OP_MASK_3BITPOS,     OP_SH_3BITPOS); break;
10346
      case '~': USE_BITS (OP_MASK_OFFSET12,     OP_SH_OFFSET12); break;
10347 16 khays
      case 'g': USE_BITS (OP_MASK_RD,           OP_SH_RD);      break;
10348
      default:
10349
        as_bad (_("internal: bad mips opcode (unknown operand type `%c'): %s %s"),
10350
                c, opc->name, opc->args);
10351
        return 0;
10352
      }
10353
#undef USE_BITS
10354
  if (used_bits != 0xffffffff)
10355
    {
10356
      as_bad (_("internal: bad mips opcode (bits 0x%lx undefined): %s %s"),
10357
              ~used_bits & 0xffffffff, opc->name, opc->args);
10358
      return 0;
10359
    }
10360
  return 1;
10361
}
10362
 
10363 160 khays
/* For consistency checking, verify that the length implied matches the
10364
   major opcode and that all bits are specified either by the match/mask
10365
   part of the instruction definition, or by the operand list.  */
10366
 
10367
static int
10368
validate_micromips_insn (const struct mips_opcode *opc)
10369
{
10370
  unsigned long match = opc->match;
10371
  unsigned long mask = opc->mask;
10372
  const char *p = opc->args;
10373
  unsigned long insn_bits;
10374
  unsigned long used_bits;
10375
  unsigned long major;
10376
  unsigned int length;
10377
  char e;
10378
  char c;
10379
 
10380
  if ((mask & match) != match)
10381
    {
10382
      as_bad (_("Internal error: bad microMIPS opcode (mask error): %s %s"),
10383
              opc->name, opc->args);
10384
      return 0;
10385
    }
10386
  length = micromips_insn_length (opc);
10387
  if (length != 2 && length != 4)
10388
    {
10389
      as_bad (_("Internal error: bad microMIPS opcode (incorrect length: %u): "
10390
                "%s %s"), length, opc->name, opc->args);
10391
      return 0;
10392
    }
10393
  major = match >> (10 + 8 * (length - 2));
10394
  if ((length == 2 && (major & 7) != 1 && (major & 6) != 2)
10395
      || (length == 4 && (major & 7) != 0 && (major & 4) != 4))
10396
    {
10397
      as_bad (_("Internal error: bad microMIPS opcode "
10398
                "(opcode/length mismatch): %s %s"), opc->name, opc->args);
10399
      return 0;
10400
    }
10401
 
10402
  /* Shift piecewise to avoid an overflow where unsigned long is 32-bit.  */
10403
  insn_bits = 1 << 4 * length;
10404
  insn_bits <<= 4 * length;
10405
  insn_bits -= 1;
10406
  used_bits = mask;
10407
#define USE_BITS(field) \
10408
  (used_bits |= MICROMIPSOP_MASK_##field << MICROMIPSOP_SH_##field)
10409
  while (*p)
10410
    switch (c = *p++)
10411
      {
10412
      case ',': break;
10413
      case '(': break;
10414
      case ')': break;
10415
      case '+':
10416
        e = c;
10417
        switch (c = *p++)
10418
          {
10419
          case 'A': USE_BITS (EXTLSB);  break;
10420
          case 'B': USE_BITS (INSMSB);  break;
10421
          case 'C': USE_BITS (EXTMSBD); break;
10422
          case 'D': USE_BITS (RS);      USE_BITS (SEL); break;
10423
          case 'E': USE_BITS (EXTLSB);  break;
10424
          case 'F': USE_BITS (INSMSB);  break;
10425
          case 'G': USE_BITS (EXTMSBD); break;
10426
          case 'H': USE_BITS (EXTMSBD); break;
10427
          default:
10428
            as_bad (_("Internal error: bad mips opcode "
10429
                      "(unknown extension operand type `%c%c'): %s %s"),
10430
                    e, c, opc->name, opc->args);
10431
            return 0;
10432
          }
10433
        break;
10434
      case 'm':
10435
        e = c;
10436
        switch (c = *p++)
10437
          {
10438
          case 'A': USE_BITS (IMMA);    break;
10439
          case 'B': USE_BITS (IMMB);    break;
10440
          case 'C': USE_BITS (IMMC);    break;
10441
          case 'D': USE_BITS (IMMD);    break;
10442
          case 'E': USE_BITS (IMME);    break;
10443
          case 'F': USE_BITS (IMMF);    break;
10444
          case 'G': USE_BITS (IMMG);    break;
10445
          case 'H': USE_BITS (IMMH);    break;
10446
          case 'I': USE_BITS (IMMI);    break;
10447
          case 'J': USE_BITS (IMMJ);    break;
10448
          case 'L': USE_BITS (IMML);    break;
10449
          case 'M': USE_BITS (IMMM);    break;
10450
          case 'N': USE_BITS (IMMN);    break;
10451
          case 'O': USE_BITS (IMMO);    break;
10452
          case 'P': USE_BITS (IMMP);    break;
10453
          case 'Q': USE_BITS (IMMQ);    break;
10454
          case 'U': USE_BITS (IMMU);    break;
10455
          case 'W': USE_BITS (IMMW);    break;
10456
          case 'X': USE_BITS (IMMX);    break;
10457
          case 'Y': USE_BITS (IMMY);    break;
10458
          case 'Z': break;
10459
          case 'a': break;
10460
          case 'b': USE_BITS (MB);      break;
10461
          case 'c': USE_BITS (MC);      break;
10462
          case 'd': USE_BITS (MD);      break;
10463
          case 'e': USE_BITS (ME);      break;
10464
          case 'f': USE_BITS (MF);      break;
10465
          case 'g': USE_BITS (MG);      break;
10466
          case 'h': USE_BITS (MH);      break;
10467
          case 'i': USE_BITS (MI);      break;
10468
          case 'j': USE_BITS (MJ);      break;
10469
          case 'l': USE_BITS (ML);      break;
10470
          case 'm': USE_BITS (MM);      break;
10471
          case 'n': USE_BITS (MN);      break;
10472
          case 'p': USE_BITS (MP);      break;
10473
          case 'q': USE_BITS (MQ);      break;
10474
          case 'r': break;
10475
          case 's': break;
10476
          case 't': break;
10477
          case 'x': break;
10478
          case 'y': break;
10479
          case 'z': break;
10480
          default:
10481
            as_bad (_("Internal error: bad mips opcode "
10482
                      "(unknown extension operand type `%c%c'): %s %s"),
10483
                    e, c, opc->name, opc->args);
10484
            return 0;
10485
          }
10486
        break;
10487
      case '.': USE_BITS (OFFSET10);    break;
10488
      case '1': USE_BITS (STYPE);       break;
10489
      case '<': USE_BITS (SHAMT);       break;
10490
      case '>': USE_BITS (SHAMT);       break;
10491
      case 'B': USE_BITS (CODE10);      break;
10492
      case 'C': USE_BITS (COPZ);        break;
10493
      case 'D': USE_BITS (FD);          break;
10494
      case 'E': USE_BITS (RT);          break;
10495
      case 'G': USE_BITS (RS);          break;
10496 163 khays
      case 'H': USE_BITS (SEL);         break;
10497 160 khays
      case 'K': USE_BITS (RS);          break;
10498
      case 'M': USE_BITS (CCC);         break;
10499
      case 'N': USE_BITS (BCC);         break;
10500
      case 'R': USE_BITS (FR);          break;
10501
      case 'S': USE_BITS (FS);          break;
10502
      case 'T': USE_BITS (FT);          break;
10503
      case 'V': USE_BITS (FS);          break;
10504
      case '\\': USE_BITS (3BITPOS);    break;
10505
      case 'a': USE_BITS (TARGET);      break;
10506
      case 'b': USE_BITS (RS);          break;
10507
      case 'c': USE_BITS (CODE);        break;
10508
      case 'd': USE_BITS (RD);          break;
10509
      case 'h': USE_BITS (PREFX);       break;
10510
      case 'i': USE_BITS (IMMEDIATE);   break;
10511
      case 'j': USE_BITS (DELTA);       break;
10512
      case 'k': USE_BITS (CACHE);       break;
10513
      case 'n': USE_BITS (RT);          break;
10514
      case 'o': USE_BITS (DELTA);       break;
10515
      case 'p': USE_BITS (DELTA);       break;
10516
      case 'q': USE_BITS (CODE2);       break;
10517
      case 'r': USE_BITS (RS);          break;
10518
      case 's': USE_BITS (RS);          break;
10519
      case 't': USE_BITS (RT);          break;
10520
      case 'u': USE_BITS (IMMEDIATE);   break;
10521
      case 'v': USE_BITS (RS);          break;
10522
      case 'w': USE_BITS (RT);          break;
10523
      case 'y': USE_BITS (RS3);         break;
10524
      case 'z': break;
10525
      case '|': USE_BITS (TRAP);        break;
10526
      case '~': USE_BITS (OFFSET12);    break;
10527
      default:
10528
        as_bad (_("Internal error: bad microMIPS opcode "
10529
                  "(unknown operand type `%c'): %s %s"),
10530
                c, opc->name, opc->args);
10531
        return 0;
10532
      }
10533
#undef USE_BITS
10534
  if (used_bits != insn_bits)
10535
    {
10536
      if (~used_bits & insn_bits)
10537
        as_bad (_("Internal error: bad microMIPS opcode "
10538
                  "(bits 0x%lx undefined): %s %s"),
10539
                ~used_bits & insn_bits, opc->name, opc->args);
10540
      if (used_bits & ~insn_bits)
10541
        as_bad (_("Internal error: bad microMIPS opcode "
10542
                  "(bits 0x%lx defined): %s %s"),
10543
                used_bits & ~insn_bits, opc->name, opc->args);
10544
      return 0;
10545
    }
10546
  return 1;
10547
}
10548
 
10549 16 khays
/* UDI immediates.  */
10550
struct mips_immed {
10551
  char          type;
10552
  unsigned int  shift;
10553
  unsigned long mask;
10554
  const char *  desc;
10555
};
10556
 
10557
static const struct mips_immed mips_immed[] = {
10558
  { '1',        OP_SH_UDI1,     OP_MASK_UDI1,           0},
10559
  { '2',        OP_SH_UDI2,     OP_MASK_UDI2,           0},
10560
  { '3',        OP_SH_UDI3,     OP_MASK_UDI3,           0},
10561
  { '4',        OP_SH_UDI4,     OP_MASK_UDI4,           0},
10562
  { 0,0,0,0 }
10563
};
10564
 
10565
/* Check whether an odd floating-point register is allowed.  */
10566
static int
10567
mips_oddfpreg_ok (const struct mips_opcode *insn, int argnum)
10568
{
10569
  const char *s = insn->name;
10570
 
10571
  if (insn->pinfo == INSN_MACRO)
10572
    /* Let a macro pass, we'll catch it later when it is expanded.  */
10573
    return 1;
10574
 
10575
  if (ISA_HAS_ODD_SINGLE_FPR (mips_opts.isa))
10576
    {
10577
      /* Allow odd registers for single-precision ops.  */
10578
      switch (insn->pinfo & (FP_S | FP_D))
10579
        {
10580
        case FP_S:
10581
        case 0:
10582
          return 1;     /* both single precision - ok */
10583
        case FP_D:
10584
          return 0;      /* both double precision - fail */
10585
        default:
10586
          break;
10587
        }
10588
 
10589
      /* Cvt.w.x and cvt.x.w allow an odd register for a 'w' or 's' operand.  */
10590
      s = strchr (insn->name, '.');
10591
      if (argnum == 2)
10592
        s = s != NULL ? strchr (s + 1, '.') : NULL;
10593
      return (s != NULL && (s[1] == 'w' || s[1] == 's'));
10594
    }
10595
 
10596
  /* Single-precision coprocessor loads and moves are OK too.  */
10597
  if ((insn->pinfo & FP_S)
10598
      && (insn->pinfo & (INSN_COPROC_MEMORY_DELAY | INSN_STORE_MEMORY
10599
                         | INSN_LOAD_COPROC_DELAY | INSN_COPROC_MOVE_DELAY)))
10600
    return 1;
10601
 
10602
  return 0;
10603
}
10604
 
10605 160 khays
/* Check if EXPR is a constant between MIN (inclusive) and MAX (exclusive)
10606
   taking bits from BIT up.  */
10607
static int
10608
expr_const_in_range (expressionS *ep, offsetT min, offsetT max, int bit)
10609
{
10610
  return (ep->X_op == O_constant
10611
          && (ep->X_add_number & ((1 << bit) - 1)) == 0
10612
          && ep->X_add_number >= min << bit
10613
          && ep->X_add_number < max << bit);
10614
}
10615
 
10616 16 khays
/* This routine assembles an instruction into its binary format.  As a
10617
   side effect, it sets one of the global variables imm_reloc or
10618
   offset_reloc to the type of relocation to do if one of the operands
10619
   is an address expression.  */
10620
 
10621
static void
10622
mips_ip (char *str, struct mips_cl_insn *ip)
10623
{
10624 160 khays
  bfd_boolean wrong_delay_slot_insns = FALSE;
10625
  bfd_boolean need_delay_slot_ok = TRUE;
10626
  struct mips_opcode *firstinsn = NULL;
10627
  const struct mips_opcode *past;
10628
  struct hash_control *hash;
10629 16 khays
  char *s;
10630
  const char *args;
10631
  char c = 0;
10632
  struct mips_opcode *insn;
10633
  char *argsStart;
10634
  unsigned int regno;
10635
  unsigned int lastregno;
10636 160 khays
  unsigned int destregno = 0;
10637 16 khays
  unsigned int lastpos = 0;
10638
  unsigned int limlo, limhi;
10639
  char *s_reset;
10640
  offsetT min_range, max_range;
10641 160 khays
  long opend;
10642
  char *name;
10643 16 khays
  int argnum;
10644
  unsigned int rtype;
10645 160 khays
  char *dot;
10646
  long end;
10647 16 khays
 
10648
  insn_error = NULL;
10649
 
10650 160 khays
  if (mips_opts.micromips)
10651
    {
10652
      hash = micromips_op_hash;
10653
      past = &micromips_opcodes[bfd_micromips_num_opcodes];
10654
    }
10655
  else
10656
    {
10657
      hash = op_hash;
10658
      past = &mips_opcodes[NUMOPCODES];
10659
    }
10660
  forced_insn_length = 0;
10661 16 khays
  insn = NULL;
10662 160 khays
 
10663
  /* We first try to match an instruction up to a space or to the end.  */
10664
  for (end = 0; str[end] != '\0' && !ISSPACE (str[end]); end++)
10665 16 khays
    continue;
10666
 
10667 160 khays
  /* Make a copy of the instruction so that we can fiddle with it.  */
10668
  name = alloca (end + 1);
10669
  memcpy (name, str, end);
10670
  name[end] = '\0';
10671
 
10672
  for (;;)
10673 16 khays
    {
10674 160 khays
      insn = (struct mips_opcode *) hash_find (hash, name);
10675 16 khays
 
10676 160 khays
      if (insn != NULL || !mips_opts.micromips)
10677
        break;
10678
      if (forced_insn_length)
10679
        break;
10680 16 khays
 
10681 160 khays
      /* See if there's an instruction size override suffix,
10682
         either `16' or `32', at the end of the mnemonic proper,
10683
         that defines the operation, i.e. before the first `.'
10684
         character if any.  Strip it and retry.  */
10685
      dot = strchr (name, '.');
10686
      opend = dot != NULL ? dot - name : end;
10687
      if (opend < 3)
10688
        break;
10689
      if (name[opend - 2] == '1' && name[opend - 1] == '6')
10690
        forced_insn_length = 2;
10691
      else if (name[opend - 2] == '3' && name[opend - 1] == '2')
10692
        forced_insn_length = 4;
10693
      else
10694
        break;
10695
      memcpy (name + opend - 2, name + opend, end - opend + 1);
10696
    }
10697 16 khays
  if (insn == NULL)
10698
    {
10699 160 khays
      insn_error = _("Unrecognized opcode");
10700
      return;
10701 16 khays
    }
10702
 
10703 160 khays
  /* For microMIPS instructions placed in a fixed-length branch delay slot
10704
     we make up to two passes over the relevant fragment of the opcode
10705
     table.  First we try instructions that meet the delay slot's length
10706
     requirement.  If none matched, then we retry with the remaining ones
10707
     and if one matches, then we use it and then issue an appropriate
10708
     warning later on.  */
10709
  argsStart = s = str + end;
10710 16 khays
  for (;;)
10711
    {
10712 160 khays
      bfd_boolean delay_slot_ok;
10713
      bfd_boolean size_ok;
10714 16 khays
      bfd_boolean ok;
10715
 
10716 160 khays
      gas_assert (strcmp (insn->name, name) == 0);
10717 16 khays
 
10718
      ok = is_opcode_valid (insn);
10719 160 khays
      size_ok = is_size_valid (insn);
10720
      delay_slot_ok = is_delay_slot_valid (insn);
10721
      if (!delay_slot_ok && !wrong_delay_slot_insns)
10722 16 khays
        {
10723 160 khays
          firstinsn = insn;
10724
          wrong_delay_slot_insns = TRUE;
10725
        }
10726
      if (!ok || !size_ok || delay_slot_ok != need_delay_slot_ok)
10727
        {
10728
          static char buf[256];
10729
 
10730
          if (insn + 1 < past && strcmp (insn->name, insn[1].name) == 0)
10731 16 khays
            {
10732
              ++insn;
10733
              continue;
10734
            }
10735 160 khays
          if (wrong_delay_slot_insns && need_delay_slot_ok)
10736 16 khays
            {
10737 160 khays
              gas_assert (firstinsn);
10738
              need_delay_slot_ok = FALSE;
10739
              past = insn + 1;
10740
              insn = firstinsn;
10741
              continue;
10742 16 khays
            }
10743 160 khays
 
10744
          if (insn_error)
10745
            return;
10746
 
10747
          if (!ok)
10748 166 khays
            sprintf (buf, _("Opcode not supported on this processor: %s (%s)"),
10749 160 khays
                     mips_cpu_info_from_arch (mips_opts.arch)->name,
10750
                     mips_cpu_info_from_isa (mips_opts.isa)->name);
10751
          else
10752
            sprintf (buf, _("Unrecognized %u-bit version of microMIPS opcode"),
10753
                     8 * forced_insn_length);
10754
          insn_error = buf;
10755
 
10756
          return;
10757 16 khays
        }
10758
 
10759
      create_insn (ip, insn);
10760
      insn_error = NULL;
10761
      argnum = 1;
10762
      lastregno = 0xffffffff;
10763
      for (args = insn->args;; ++args)
10764
        {
10765
          int is_mdmx;
10766
 
10767
          s += strspn (s, " \t");
10768
          is_mdmx = 0;
10769
          switch (*args)
10770
            {
10771
            case '\0':          /* end of args */
10772
              if (*s == '\0')
10773
                return;
10774
              break;
10775
 
10776
            case '2': /* DSP 2-bit unsigned immediate in bit 11.  */
10777 160 khays
              gas_assert (!mips_opts.micromips);
10778 16 khays
              my_getExpression (&imm_expr, s);
10779
              check_absolute_expr (ip, &imm_expr);
10780
              if ((unsigned long) imm_expr.X_add_number != 1
10781
                  && (unsigned long) imm_expr.X_add_number != 3)
10782
                {
10783
                  as_bad (_("BALIGN immediate not 1 or 3 (%lu)"),
10784
                          (unsigned long) imm_expr.X_add_number);
10785
                }
10786 160 khays
              INSERT_OPERAND (0, BP, *ip, imm_expr.X_add_number);
10787 16 khays
              imm_expr.X_op = O_absent;
10788
              s = expr_end;
10789
              continue;
10790
 
10791
            case '3': /* DSP 3-bit unsigned immediate in bit 21.  */
10792 160 khays
              gas_assert (!mips_opts.micromips);
10793 16 khays
              my_getExpression (&imm_expr, s);
10794
              check_absolute_expr (ip, &imm_expr);
10795
              if (imm_expr.X_add_number & ~OP_MASK_SA3)
10796
                {
10797
                  as_bad (_("DSP immediate not in range 0..%d (%lu)"),
10798
                          OP_MASK_SA3, (unsigned long) imm_expr.X_add_number);
10799
                }
10800 160 khays
              INSERT_OPERAND (0, SA3, *ip, imm_expr.X_add_number);
10801 16 khays
              imm_expr.X_op = O_absent;
10802
              s = expr_end;
10803
              continue;
10804
 
10805
            case '4': /* DSP 4-bit unsigned immediate in bit 21.  */
10806 160 khays
              gas_assert (!mips_opts.micromips);
10807 16 khays
              my_getExpression (&imm_expr, s);
10808
              check_absolute_expr (ip, &imm_expr);
10809
              if (imm_expr.X_add_number & ~OP_MASK_SA4)
10810
                {
10811
                  as_bad (_("DSP immediate not in range 0..%d (%lu)"),
10812
                          OP_MASK_SA4, (unsigned long) imm_expr.X_add_number);
10813
                }
10814 160 khays
              INSERT_OPERAND (0, SA4, *ip, imm_expr.X_add_number);
10815 16 khays
              imm_expr.X_op = O_absent;
10816
              s = expr_end;
10817
              continue;
10818
 
10819
            case '5': /* DSP 8-bit unsigned immediate in bit 16.  */
10820 160 khays
              gas_assert (!mips_opts.micromips);
10821 16 khays
              my_getExpression (&imm_expr, s);
10822
              check_absolute_expr (ip, &imm_expr);
10823
              if (imm_expr.X_add_number & ~OP_MASK_IMM8)
10824
                {
10825
                  as_bad (_("DSP immediate not in range 0..%d (%lu)"),
10826
                          OP_MASK_IMM8, (unsigned long) imm_expr.X_add_number);
10827
                }
10828 160 khays
              INSERT_OPERAND (0, IMM8, *ip, imm_expr.X_add_number);
10829 16 khays
              imm_expr.X_op = O_absent;
10830
              s = expr_end;
10831
              continue;
10832
 
10833
            case '6': /* DSP 5-bit unsigned immediate in bit 21.  */
10834 160 khays
              gas_assert (!mips_opts.micromips);
10835 16 khays
              my_getExpression (&imm_expr, s);
10836
              check_absolute_expr (ip, &imm_expr);
10837
              if (imm_expr.X_add_number & ~OP_MASK_RS)
10838
                {
10839
                  as_bad (_("DSP immediate not in range 0..%d (%lu)"),
10840
                          OP_MASK_RS, (unsigned long) imm_expr.X_add_number);
10841
                }
10842 160 khays
              INSERT_OPERAND (0, RS, *ip, imm_expr.X_add_number);
10843 16 khays
              imm_expr.X_op = O_absent;
10844
              s = expr_end;
10845
              continue;
10846
 
10847
            case '7': /* Four DSP accumulators in bits 11,12.  */
10848 160 khays
              gas_assert (!mips_opts.micromips);
10849 16 khays
              if (s[0] == '$' && s[1] == 'a' && s[2] == 'c' &&
10850
                  s[3] >= '0' && s[3] <= '3')
10851
                {
10852
                  regno = s[3] - '0';
10853
                  s += 4;
10854 160 khays
                  INSERT_OPERAND (0, DSPACC, *ip, regno);
10855 16 khays
                  continue;
10856
                }
10857
              else
10858
                as_bad (_("Invalid dsp acc register"));
10859
              break;
10860
 
10861
            case '8': /* DSP 6-bit unsigned immediate in bit 11.  */
10862 160 khays
              gas_assert (!mips_opts.micromips);
10863 16 khays
              my_getExpression (&imm_expr, s);
10864
              check_absolute_expr (ip, &imm_expr);
10865
              if (imm_expr.X_add_number & ~OP_MASK_WRDSP)
10866
                {
10867
                  as_bad (_("DSP immediate not in range 0..%d (%lu)"),
10868
                          OP_MASK_WRDSP,
10869
                          (unsigned long) imm_expr.X_add_number);
10870
                }
10871 160 khays
              INSERT_OPERAND (0, WRDSP, *ip, imm_expr.X_add_number);
10872 16 khays
              imm_expr.X_op = O_absent;
10873
              s = expr_end;
10874
              continue;
10875
 
10876
            case '9': /* Four DSP accumulators in bits 21,22.  */
10877 160 khays
              gas_assert (!mips_opts.micromips);
10878 16 khays
              if (s[0] == '$' && s[1] == 'a' && s[2] == 'c' &&
10879
                  s[3] >= '0' && s[3] <= '3')
10880
                {
10881
                  regno = s[3] - '0';
10882
                  s += 4;
10883 160 khays
                  INSERT_OPERAND (0, DSPACC_S, *ip, regno);
10884 16 khays
                  continue;
10885
                }
10886
              else
10887
                as_bad (_("Invalid dsp acc register"));
10888
              break;
10889
 
10890
            case '0': /* DSP 6-bit signed immediate in bit 20.  */
10891 160 khays
              gas_assert (!mips_opts.micromips);
10892 16 khays
              my_getExpression (&imm_expr, s);
10893
              check_absolute_expr (ip, &imm_expr);
10894
              min_range = -((OP_MASK_DSPSFT + 1) >> 1);
10895
              max_range = ((OP_MASK_DSPSFT + 1) >> 1) - 1;
10896
              if (imm_expr.X_add_number < min_range ||
10897
                  imm_expr.X_add_number > max_range)
10898
                {
10899
                  as_bad (_("DSP immediate not in range %ld..%ld (%ld)"),
10900
                          (long) min_range, (long) max_range,
10901
                          (long) imm_expr.X_add_number);
10902
                }
10903 160 khays
              INSERT_OPERAND (0, DSPSFT, *ip, imm_expr.X_add_number);
10904 16 khays
              imm_expr.X_op = O_absent;
10905
              s = expr_end;
10906
              continue;
10907
 
10908
            case '\'': /* DSP 6-bit unsigned immediate in bit 16.  */
10909 160 khays
              gas_assert (!mips_opts.micromips);
10910 16 khays
              my_getExpression (&imm_expr, s);
10911
              check_absolute_expr (ip, &imm_expr);
10912
              if (imm_expr.X_add_number & ~OP_MASK_RDDSP)
10913
                {
10914
                  as_bad (_("DSP immediate not in range 0..%d (%lu)"),
10915
                          OP_MASK_RDDSP,
10916
                          (unsigned long) imm_expr.X_add_number);
10917
                }
10918 160 khays
              INSERT_OPERAND (0, RDDSP, *ip, imm_expr.X_add_number);
10919 16 khays
              imm_expr.X_op = O_absent;
10920
              s = expr_end;
10921
              continue;
10922
 
10923
            case ':': /* DSP 7-bit signed immediate in bit 19.  */
10924 160 khays
              gas_assert (!mips_opts.micromips);
10925 16 khays
              my_getExpression (&imm_expr, s);
10926
              check_absolute_expr (ip, &imm_expr);
10927
              min_range = -((OP_MASK_DSPSFT_7 + 1) >> 1);
10928
              max_range = ((OP_MASK_DSPSFT_7 + 1) >> 1) - 1;
10929
              if (imm_expr.X_add_number < min_range ||
10930
                  imm_expr.X_add_number > max_range)
10931
                {
10932
                  as_bad (_("DSP immediate not in range %ld..%ld (%ld)"),
10933
                          (long) min_range, (long) max_range,
10934
                          (long) imm_expr.X_add_number);
10935
                }
10936 160 khays
              INSERT_OPERAND (0, DSPSFT_7, *ip, imm_expr.X_add_number);
10937 16 khays
              imm_expr.X_op = O_absent;
10938
              s = expr_end;
10939
              continue;
10940
 
10941
            case '@': /* DSP 10-bit signed immediate in bit 16.  */
10942 160 khays
              gas_assert (!mips_opts.micromips);
10943 16 khays
              my_getExpression (&imm_expr, s);
10944
              check_absolute_expr (ip, &imm_expr);
10945
              min_range = -((OP_MASK_IMM10 + 1) >> 1);
10946
              max_range = ((OP_MASK_IMM10 + 1) >> 1) - 1;
10947
              if (imm_expr.X_add_number < min_range ||
10948
                  imm_expr.X_add_number > max_range)
10949
                {
10950
                  as_bad (_("DSP immediate not in range %ld..%ld (%ld)"),
10951
                          (long) min_range, (long) max_range,
10952
                          (long) imm_expr.X_add_number);
10953
                }
10954 160 khays
              INSERT_OPERAND (0, IMM10, *ip, imm_expr.X_add_number);
10955 16 khays
              imm_expr.X_op = O_absent;
10956
              s = expr_end;
10957
              continue;
10958
 
10959
            case '!': /* MT usermode flag bit.  */
10960 160 khays
              gas_assert (!mips_opts.micromips);
10961 16 khays
              my_getExpression (&imm_expr, s);
10962
              check_absolute_expr (ip, &imm_expr);
10963
              if (imm_expr.X_add_number & ~OP_MASK_MT_U)
10964
                as_bad (_("MT usermode bit not 0 or 1 (%lu)"),
10965
                        (unsigned long) imm_expr.X_add_number);
10966 160 khays
              INSERT_OPERAND (0, MT_U, *ip, imm_expr.X_add_number);
10967 16 khays
              imm_expr.X_op = O_absent;
10968
              s = expr_end;
10969
              continue;
10970
 
10971
            case '$': /* MT load high flag bit.  */
10972 160 khays
              gas_assert (!mips_opts.micromips);
10973 16 khays
              my_getExpression (&imm_expr, s);
10974
              check_absolute_expr (ip, &imm_expr);
10975
              if (imm_expr.X_add_number & ~OP_MASK_MT_H)
10976
                as_bad (_("MT load high bit not 0 or 1 (%lu)"),
10977
                        (unsigned long) imm_expr.X_add_number);
10978 160 khays
              INSERT_OPERAND (0, MT_H, *ip, imm_expr.X_add_number);
10979 16 khays
              imm_expr.X_op = O_absent;
10980
              s = expr_end;
10981
              continue;
10982
 
10983
            case '*': /* Four DSP accumulators in bits 18,19.  */
10984 160 khays
              gas_assert (!mips_opts.micromips);
10985 16 khays
              if (s[0] == '$' && s[1] == 'a' && s[2] == 'c' &&
10986
                  s[3] >= '0' && s[3] <= '3')
10987
                {
10988
                  regno = s[3] - '0';
10989
                  s += 4;
10990 160 khays
                  INSERT_OPERAND (0, MTACC_T, *ip, regno);
10991 16 khays
                  continue;
10992
                }
10993
              else
10994
                as_bad (_("Invalid dsp/smartmips acc register"));
10995
              break;
10996
 
10997
            case '&': /* Four DSP accumulators in bits 13,14.  */
10998 160 khays
              gas_assert (!mips_opts.micromips);
10999 16 khays
              if (s[0] == '$' && s[1] == 'a' && s[2] == 'c' &&
11000
                  s[3] >= '0' && s[3] <= '3')
11001
                {
11002
                  regno = s[3] - '0';
11003
                  s += 4;
11004 160 khays
                  INSERT_OPERAND (0, MTACC_D, *ip, regno);
11005 16 khays
                  continue;
11006
                }
11007
              else
11008
                as_bad (_("Invalid dsp/smartmips acc register"));
11009
              break;
11010
 
11011 160 khays
            case '\\':          /* 3-bit bit position.  */
11012
              {
11013 166 khays
                unsigned long mask = (mips_opts.micromips
11014
                                      ? MICROMIPSOP_MASK_3BITPOS
11015
                                      : OP_MASK_3BITPOS);
11016 160 khays
 
11017
                my_getExpression (&imm_expr, s);
11018
                check_absolute_expr (ip, &imm_expr);
11019
                if ((unsigned long) imm_expr.X_add_number > mask)
11020
                  as_warn (_("Bit position for %s not in range 0..%lu (%lu)"),
11021
                           ip->insn_mo->name,
11022
                           mask, (unsigned long) imm_expr.X_add_number);
11023
                INSERT_OPERAND (mips_opts.micromips,
11024
                                3BITPOS, *ip, imm_expr.X_add_number);
11025
                imm_expr.X_op = O_absent;
11026
                s = expr_end;
11027
              }
11028
              continue;
11029
 
11030 16 khays
            case ',':
11031
              ++argnum;
11032
              if (*s++ == *args)
11033
                continue;
11034
              s--;
11035
              switch (*++args)
11036
                {
11037
                case 'r':
11038
                case 'v':
11039 160 khays
                  INSERT_OPERAND (mips_opts.micromips, RS, *ip, lastregno);
11040 16 khays
                  continue;
11041
 
11042
                case 'w':
11043 160 khays
                  INSERT_OPERAND (mips_opts.micromips, RT, *ip, lastregno);
11044 16 khays
                  continue;
11045
 
11046
                case 'W':
11047 160 khays
                  gas_assert (!mips_opts.micromips);
11048
                  INSERT_OPERAND (0, FT, *ip, lastregno);
11049 16 khays
                  continue;
11050
 
11051
                case 'V':
11052 160 khays
                  INSERT_OPERAND (mips_opts.micromips, FS, *ip, lastregno);
11053 16 khays
                  continue;
11054
                }
11055
              break;
11056
 
11057
            case '(':
11058
              /* Handle optional base register.
11059
                 Either the base register is omitted or
11060
                 we must have a left paren.  */
11061
              /* This is dependent on the next operand specifier
11062
                 is a base register specification.  */
11063 160 khays
              gas_assert (args[1] == 'b'
11064
                          || (mips_opts.micromips
11065
                              && args[1] == 'm'
11066
                              && (args[2] == 'l' || args[2] == 'n'
11067
                                  || args[2] == 's' || args[2] == 'a')));
11068
              if (*s == '\0' && args[1] == 'b')
11069 16 khays
                return;
11070 160 khays
              /* Fall through.  */
11071 16 khays
 
11072
            case ')':           /* These must match exactly.  */
11073 160 khays
              if (*s++ == *args)
11074
                continue;
11075
              break;
11076
 
11077
            case '[':           /* These must match exactly.  */
11078 16 khays
            case ']':
11079 160 khays
              gas_assert (!mips_opts.micromips);
11080 16 khays
              if (*s++ == *args)
11081
                continue;
11082
              break;
11083
 
11084
            case '+':           /* Opcode extension character.  */
11085
              switch (*++args)
11086
                {
11087
                case '1':       /* UDI immediates.  */
11088
                case '2':
11089
                case '3':
11090
                case '4':
11091 160 khays
                  gas_assert (!mips_opts.micromips);
11092 16 khays
                  {
11093
                    const struct mips_immed *imm = mips_immed;
11094
 
11095
                    while (imm->type && imm->type != *args)
11096
                      ++imm;
11097
                    if (! imm->type)
11098
                      internalError ();
11099
                    my_getExpression (&imm_expr, s);
11100
                    check_absolute_expr (ip, &imm_expr);
11101
                    if ((unsigned long) imm_expr.X_add_number & ~imm->mask)
11102
                      {
11103
                        as_warn (_("Illegal %s number (%lu, 0x%lx)"),
11104
                                 imm->desc ? imm->desc : ip->insn_mo->name,
11105
                                 (unsigned long) imm_expr.X_add_number,
11106
                                 (unsigned long) imm_expr.X_add_number);
11107
                        imm_expr.X_add_number &= imm->mask;
11108
                      }
11109
                    ip->insn_opcode |= ((unsigned long) imm_expr.X_add_number
11110
                                        << imm->shift);
11111
                    imm_expr.X_op = O_absent;
11112
                    s = expr_end;
11113
                  }
11114
                  continue;
11115
 
11116
                case 'A':               /* ins/ext position, becomes LSB.  */
11117
                  limlo = 0;
11118
                  limhi = 31;
11119
                  goto do_lsb;
11120
                case 'E':
11121
                  limlo = 32;
11122
                  limhi = 63;
11123
                  goto do_lsb;
11124
                do_lsb:
11125
                  my_getExpression (&imm_expr, s);
11126
                  check_absolute_expr (ip, &imm_expr);
11127
                  if ((unsigned long) imm_expr.X_add_number < limlo
11128
                      || (unsigned long) imm_expr.X_add_number > limhi)
11129
                    {
11130
                      as_bad (_("Improper position (%lu)"),
11131
                              (unsigned long) imm_expr.X_add_number);
11132
                      imm_expr.X_add_number = limlo;
11133
                    }
11134
                  lastpos = imm_expr.X_add_number;
11135 160 khays
                  INSERT_OPERAND (mips_opts.micromips,
11136
                                  EXTLSB, *ip, imm_expr.X_add_number);
11137 16 khays
                  imm_expr.X_op = O_absent;
11138
                  s = expr_end;
11139
                  continue;
11140
 
11141
                case 'B':               /* ins size, becomes MSB.  */
11142
                  limlo = 1;
11143
                  limhi = 32;
11144
                  goto do_msb;
11145
                case 'F':
11146
                  limlo = 33;
11147
                  limhi = 64;
11148
                  goto do_msb;
11149
                do_msb:
11150
                  my_getExpression (&imm_expr, s);
11151
                  check_absolute_expr (ip, &imm_expr);
11152
                  /* Check for negative input so that small negative numbers
11153
                     will not succeed incorrectly.  The checks against
11154
                     (pos+size) transitively check "size" itself,
11155
                     assuming that "pos" is reasonable.  */
11156
                  if ((long) imm_expr.X_add_number < 0
11157
                      || ((unsigned long) imm_expr.X_add_number
11158
                          + lastpos) < limlo
11159
                      || ((unsigned long) imm_expr.X_add_number
11160
                          + lastpos) > limhi)
11161
                    {
11162
                      as_bad (_("Improper insert size (%lu, position %lu)"),
11163
                              (unsigned long) imm_expr.X_add_number,
11164
                              (unsigned long) lastpos);
11165
                      imm_expr.X_add_number = limlo - lastpos;
11166
                    }
11167 160 khays
                  INSERT_OPERAND (mips_opts.micromips, INSMSB, *ip,
11168
                                  lastpos + imm_expr.X_add_number - 1);
11169 16 khays
                  imm_expr.X_op = O_absent;
11170
                  s = expr_end;
11171
                  continue;
11172
 
11173
                case 'C':               /* ext size, becomes MSBD.  */
11174
                  limlo = 1;
11175
                  limhi = 32;
11176
                  goto do_msbd;
11177
                case 'G':
11178
                  limlo = 33;
11179
                  limhi = 64;
11180
                  goto do_msbd;
11181
                case 'H':
11182
                  limlo = 33;
11183
                  limhi = 64;
11184
                  goto do_msbd;
11185
                do_msbd:
11186
                  my_getExpression (&imm_expr, s);
11187
                  check_absolute_expr (ip, &imm_expr);
11188
                  /* Check for negative input so that small negative numbers
11189
                     will not succeed incorrectly.  The checks against
11190
                     (pos+size) transitively check "size" itself,
11191
                     assuming that "pos" is reasonable.  */
11192
                  if ((long) imm_expr.X_add_number < 0
11193
                      || ((unsigned long) imm_expr.X_add_number
11194
                          + lastpos) < limlo
11195
                      || ((unsigned long) imm_expr.X_add_number
11196
                          + lastpos) > limhi)
11197
                    {
11198
                      as_bad (_("Improper extract size (%lu, position %lu)"),
11199
                              (unsigned long) imm_expr.X_add_number,
11200
                              (unsigned long) lastpos);
11201
                      imm_expr.X_add_number = limlo - lastpos;
11202
                    }
11203 160 khays
                  INSERT_OPERAND (mips_opts.micromips,
11204
                                  EXTMSBD, *ip, imm_expr.X_add_number - 1);
11205 16 khays
                  imm_expr.X_op = O_absent;
11206
                  s = expr_end;
11207
                  continue;
11208
 
11209
                case 'D':
11210
                  /* +D is for disassembly only; never match.  */
11211
                  break;
11212
 
11213
                case 'I':
11214
                  /* "+I" is like "I", except that imm2_expr is used.  */
11215
                  my_getExpression (&imm2_expr, s);
11216
                  if (imm2_expr.X_op != O_big
11217
                      && imm2_expr.X_op != O_constant)
11218
                  insn_error = _("absolute expression required");
11219
                  if (HAVE_32BIT_GPRS)
11220
                    normalize_constant_expr (&imm2_expr);
11221
                  s = expr_end;
11222
                  continue;
11223
 
11224
                case 'T': /* Coprocessor register.  */
11225 160 khays
                  gas_assert (!mips_opts.micromips);
11226 16 khays
                  /* +T is for disassembly only; never match.  */
11227
                  break;
11228
 
11229
                case 't': /* Coprocessor register number.  */
11230 160 khays
                  gas_assert (!mips_opts.micromips);
11231 16 khays
                  if (s[0] == '$' && ISDIGIT (s[1]))
11232
                    {
11233
                      ++s;
11234
                      regno = 0;
11235
                      do
11236
                        {
11237
                          regno *= 10;
11238
                          regno += *s - '0';
11239
                          ++s;
11240
                        }
11241
                      while (ISDIGIT (*s));
11242
                      if (regno > 31)
11243
                        as_bad (_("Invalid register number (%d)"), regno);
11244
                      else
11245
                        {
11246 160 khays
                          INSERT_OPERAND (0, RT, *ip, regno);
11247 16 khays
                          continue;
11248
                        }
11249
                    }
11250
                  else
11251
                    as_bad (_("Invalid coprocessor 0 register number"));
11252
                  break;
11253
 
11254
                case 'x':
11255
                  /* bbit[01] and bbit[01]32 bit index.  Give error if index
11256
                     is not in the valid range.  */
11257 160 khays
                  gas_assert (!mips_opts.micromips);
11258 16 khays
                  my_getExpression (&imm_expr, s);
11259
                  check_absolute_expr (ip, &imm_expr);
11260
                  if ((unsigned) imm_expr.X_add_number > 31)
11261
                    {
11262
                      as_bad (_("Improper bit index (%lu)"),
11263
                              (unsigned long) imm_expr.X_add_number);
11264
                      imm_expr.X_add_number = 0;
11265
                    }
11266 160 khays
                  INSERT_OPERAND (0, BBITIND, *ip, imm_expr.X_add_number);
11267 16 khays
                  imm_expr.X_op = O_absent;
11268
                  s = expr_end;
11269
                  continue;
11270
 
11271
                case 'X':
11272
                  /* bbit[01] bit index when bbit is used but we generate
11273
                     bbit[01]32 because the index is over 32.  Move to the
11274
                     next candidate if index is not in the valid range.  */
11275 160 khays
                  gas_assert (!mips_opts.micromips);
11276 16 khays
                  my_getExpression (&imm_expr, s);
11277
                  check_absolute_expr (ip, &imm_expr);
11278
                  if ((unsigned) imm_expr.X_add_number < 32
11279
                      || (unsigned) imm_expr.X_add_number > 63)
11280
                    break;
11281 160 khays
                  INSERT_OPERAND (0, BBITIND, *ip, imm_expr.X_add_number - 32);
11282 16 khays
                  imm_expr.X_op = O_absent;
11283
                  s = expr_end;
11284
                  continue;
11285
 
11286
                case 'p':
11287
                  /* cins, cins32, exts and exts32 position field.  Give error
11288
                     if it's not in the valid range.  */
11289 160 khays
                  gas_assert (!mips_opts.micromips);
11290 16 khays
                  my_getExpression (&imm_expr, s);
11291
                  check_absolute_expr (ip, &imm_expr);
11292
                  if ((unsigned) imm_expr.X_add_number > 31)
11293
                    {
11294
                      as_bad (_("Improper position (%lu)"),
11295
                              (unsigned long) imm_expr.X_add_number);
11296
                      imm_expr.X_add_number = 0;
11297
                    }
11298
                  /* Make the pos explicit to simplify +S.  */
11299
                  lastpos = imm_expr.X_add_number + 32;
11300 160 khays
                  INSERT_OPERAND (0, CINSPOS, *ip, imm_expr.X_add_number);
11301 16 khays
                  imm_expr.X_op = O_absent;
11302
                  s = expr_end;
11303
                  continue;
11304
 
11305
                case 'P':
11306
                  /* cins, cins32, exts and exts32 position field.  Move to
11307
                     the next candidate if it's not in the valid range.  */
11308 160 khays
                  gas_assert (!mips_opts.micromips);
11309 16 khays
                  my_getExpression (&imm_expr, s);
11310
                  check_absolute_expr (ip, &imm_expr);
11311
                  if ((unsigned) imm_expr.X_add_number < 32
11312
                      || (unsigned) imm_expr.X_add_number > 63)
11313
                    break;
11314
                  lastpos = imm_expr.X_add_number;
11315 160 khays
                  INSERT_OPERAND (0, CINSPOS, *ip, imm_expr.X_add_number - 32);
11316 16 khays
                  imm_expr.X_op = O_absent;
11317
                  s = expr_end;
11318
                  continue;
11319
 
11320
                case 's':
11321
                  /* cins and exts length-minus-one field.  */
11322 160 khays
                  gas_assert (!mips_opts.micromips);
11323 16 khays
                  my_getExpression (&imm_expr, s);
11324
                  check_absolute_expr (ip, &imm_expr);
11325
                  if ((unsigned long) imm_expr.X_add_number > 31)
11326
                    {
11327
                      as_bad (_("Improper size (%lu)"),
11328
                              (unsigned long) imm_expr.X_add_number);
11329
                      imm_expr.X_add_number = 0;
11330
                    }
11331 160 khays
                  INSERT_OPERAND (0, CINSLM1, *ip, imm_expr.X_add_number);
11332 16 khays
                  imm_expr.X_op = O_absent;
11333
                  s = expr_end;
11334
                  continue;
11335
 
11336
                case 'S':
11337
                  /* cins32/exts32 and cins/exts aliasing cint32/exts32
11338
                     length-minus-one field.  */
11339 160 khays
                  gas_assert (!mips_opts.micromips);
11340 16 khays
                  my_getExpression (&imm_expr, s);
11341
                  check_absolute_expr (ip, &imm_expr);
11342
                  if ((long) imm_expr.X_add_number < 0
11343
                      || (unsigned long) imm_expr.X_add_number + lastpos > 63)
11344
                    {
11345
                      as_bad (_("Improper size (%lu)"),
11346
                              (unsigned long) imm_expr.X_add_number);
11347
                      imm_expr.X_add_number = 0;
11348
                    }
11349 160 khays
                  INSERT_OPERAND (0, CINSLM1, *ip, imm_expr.X_add_number);
11350 16 khays
                  imm_expr.X_op = O_absent;
11351
                  s = expr_end;
11352
                  continue;
11353
 
11354
                case 'Q':
11355
                  /* seqi/snei immediate field.  */
11356 160 khays
                  gas_assert (!mips_opts.micromips);
11357 16 khays
                  my_getExpression (&imm_expr, s);
11358
                  check_absolute_expr (ip, &imm_expr);
11359
                  if ((long) imm_expr.X_add_number < -512
11360
                      || (long) imm_expr.X_add_number >= 512)
11361
                    {
11362
                      as_bad (_("Improper immediate (%ld)"),
11363
                               (long) imm_expr.X_add_number);
11364
                      imm_expr.X_add_number = 0;
11365
                    }
11366 160 khays
                  INSERT_OPERAND (0, SEQI, *ip, imm_expr.X_add_number);
11367 16 khays
                  imm_expr.X_op = O_absent;
11368
                  s = expr_end;
11369
                  continue;
11370
 
11371
                case 'a': /* 8-bit signed offset in bit 6 */
11372 160 khays
                  gas_assert (!mips_opts.micromips);
11373 16 khays
                  my_getExpression (&imm_expr, s);
11374
                  check_absolute_expr (ip, &imm_expr);
11375
                  min_range = -((OP_MASK_OFFSET_A + 1) >> 1);
11376
                  max_range = ((OP_MASK_OFFSET_A + 1) >> 1) - 1;
11377
                  if (imm_expr.X_add_number < min_range
11378
                      || imm_expr.X_add_number > max_range)
11379
                    {
11380
                      as_bad (_("Offset not in range %ld..%ld (%ld)"),
11381
                              (long) min_range, (long) max_range,
11382
                              (long) imm_expr.X_add_number);
11383
                    }
11384 160 khays
                  INSERT_OPERAND (0, OFFSET_A, *ip, imm_expr.X_add_number);
11385 16 khays
                  imm_expr.X_op = O_absent;
11386
                  s = expr_end;
11387
                  continue;
11388
 
11389
                case 'b': /* 8-bit signed offset in bit 3 */
11390 160 khays
                  gas_assert (!mips_opts.micromips);
11391 16 khays
                  my_getExpression (&imm_expr, s);
11392
                  check_absolute_expr (ip, &imm_expr);
11393
                  min_range = -((OP_MASK_OFFSET_B + 1) >> 1);
11394
                  max_range = ((OP_MASK_OFFSET_B + 1) >> 1) - 1;
11395
                  if (imm_expr.X_add_number < min_range
11396
                      || imm_expr.X_add_number > max_range)
11397
                    {
11398
                      as_bad (_("Offset not in range %ld..%ld (%ld)"),
11399
                              (long) min_range, (long) max_range,
11400
                              (long) imm_expr.X_add_number);
11401
                    }
11402 160 khays
                  INSERT_OPERAND (0, OFFSET_B, *ip, imm_expr.X_add_number);
11403 16 khays
                  imm_expr.X_op = O_absent;
11404
                  s = expr_end;
11405
                  continue;
11406
 
11407
                case 'c': /* 9-bit signed offset in bit 6 */
11408 160 khays
                  gas_assert (!mips_opts.micromips);
11409 16 khays
                  my_getExpression (&imm_expr, s);
11410
                  check_absolute_expr (ip, &imm_expr);
11411
                  min_range = -((OP_MASK_OFFSET_C + 1) >> 1);
11412
                  max_range = ((OP_MASK_OFFSET_C + 1) >> 1) - 1;
11413
                  /* We check the offset range before adjusted.  */
11414
                  min_range <<= 4;
11415
                  max_range <<= 4;
11416
                  if (imm_expr.X_add_number < min_range
11417
                      || imm_expr.X_add_number > max_range)
11418
                    {
11419
                      as_bad (_("Offset not in range %ld..%ld (%ld)"),
11420
                              (long) min_range, (long) max_range,
11421
                              (long) imm_expr.X_add_number);
11422
                    }
11423
                  if (imm_expr.X_add_number & 0xf)
11424
                    {
11425
                      as_bad (_("Offset not 16 bytes alignment (%ld)"),
11426
                              (long) imm_expr.X_add_number);
11427
                    }
11428
                  /* Right shift 4 bits to adjust the offset operand.  */
11429 160 khays
                  INSERT_OPERAND (0, OFFSET_C, *ip,
11430
                                  imm_expr.X_add_number >> 4);
11431 16 khays
                  imm_expr.X_op = O_absent;
11432
                  s = expr_end;
11433
                  continue;
11434
 
11435
                case 'z':
11436 160 khays
                  gas_assert (!mips_opts.micromips);
11437 16 khays
                  if (!reg_lookup (&s, RTYPE_NUM | RTYPE_GP, &regno))
11438
                    break;
11439
                  if (regno == AT && mips_opts.at)
11440
                    {
11441
                      if (mips_opts.at == ATREG)
11442
                        as_warn (_("used $at without \".set noat\""));
11443
                      else
11444
                        as_warn (_("used $%u with \".set at=$%u\""),
11445
                                 regno, mips_opts.at);
11446
                    }
11447 160 khays
                  INSERT_OPERAND (0, RZ, *ip, regno);
11448 16 khays
                  continue;
11449
 
11450
                case 'Z':
11451 160 khays
                  gas_assert (!mips_opts.micromips);
11452 16 khays
                  if (!reg_lookup (&s, RTYPE_FPU, &regno))
11453
                    break;
11454 160 khays
                  INSERT_OPERAND (0, FZ, *ip, regno);
11455 16 khays
                  continue;
11456
 
11457
                default:
11458 160 khays
                  as_bad (_("Internal error: bad %s opcode "
11459 16 khays
                            "(unknown extension operand type `+%c'): %s %s"),
11460 160 khays
                          mips_opts.micromips ? "microMIPS" : "MIPS",
11461 16 khays
                          *args, insn->name, insn->args);
11462
                  /* Further processing is fruitless.  */
11463
                  return;
11464
                }
11465
              break;
11466
 
11467 160 khays
            case '.':           /* 10-bit offset.  */
11468
              gas_assert (mips_opts.micromips);
11469
            case '~':           /* 12-bit offset.  */
11470
              {
11471
                int shift = *args == '.' ? 9 : 11;
11472
                size_t i;
11473
 
11474
                /* Check whether there is only a single bracketed expression
11475
                   left.  If so, it must be the base register and the
11476
                   constant must be zero.  */
11477
                if (*s == '(' && strchr (s + 1, '(') == 0)
11478
                  continue;
11479
 
11480
                /* If this value won't fit into the offset, then go find
11481
                   a macro that will generate a 16- or 32-bit offset code
11482
                   pattern.  */
11483
                i = my_getSmallExpression (&imm_expr, imm_reloc, s);
11484
                if ((i == 0 && (imm_expr.X_op != O_constant
11485
                                || imm_expr.X_add_number >= 1 << shift
11486
                                || imm_expr.X_add_number < -1 << shift))
11487
                    || i > 0)
11488
                  {
11489
                    imm_expr.X_op = O_absent;
11490
                    break;
11491
                  }
11492
                if (shift == 9)
11493
                  INSERT_OPERAND (1, OFFSET10, *ip, imm_expr.X_add_number);
11494
                else
11495
                  INSERT_OPERAND (mips_opts.micromips,
11496
                                  OFFSET12, *ip, imm_expr.X_add_number);
11497
                imm_expr.X_op = O_absent;
11498
                s = expr_end;
11499
              }
11500
              continue;
11501
 
11502 16 khays
            case '<':           /* must be at least one digit */
11503
              /*
11504
               * According to the manual, if the shift amount is greater
11505
               * than 31 or less than 0, then the shift amount should be
11506
               * mod 32.  In reality the mips assembler issues an error.
11507
               * We issue a warning and mask out all but the low 5 bits.
11508
               */
11509
              my_getExpression (&imm_expr, s);
11510
              check_absolute_expr (ip, &imm_expr);
11511
              if ((unsigned long) imm_expr.X_add_number > 31)
11512
                as_warn (_("Improper shift amount (%lu)"),
11513
                         (unsigned long) imm_expr.X_add_number);
11514 160 khays
              INSERT_OPERAND (mips_opts.micromips,
11515
                              SHAMT, *ip, imm_expr.X_add_number);
11516 16 khays
              imm_expr.X_op = O_absent;
11517
              s = expr_end;
11518
              continue;
11519
 
11520
            case '>':           /* shift amount minus 32 */
11521
              my_getExpression (&imm_expr, s);
11522
              check_absolute_expr (ip, &imm_expr);
11523
              if ((unsigned long) imm_expr.X_add_number < 32
11524
                  || (unsigned long) imm_expr.X_add_number > 63)
11525
                break;
11526 160 khays
              INSERT_OPERAND (mips_opts.micromips,
11527
                              SHAMT, *ip, imm_expr.X_add_number - 32);
11528 16 khays
              imm_expr.X_op = O_absent;
11529
              s = expr_end;
11530
              continue;
11531
 
11532
            case 'k':           /* CACHE code.  */
11533
            case 'h':           /* PREFX code.  */
11534
            case '1':           /* SYNC type.  */
11535
              my_getExpression (&imm_expr, s);
11536
              check_absolute_expr (ip, &imm_expr);
11537
              if ((unsigned long) imm_expr.X_add_number > 31)
11538
                as_warn (_("Invalid value for `%s' (%lu)"),
11539
                         ip->insn_mo->name,
11540
                         (unsigned long) imm_expr.X_add_number);
11541 160 khays
              switch (*args)
11542 16 khays
                {
11543 160 khays
                case 'k':
11544
                  if (mips_fix_cn63xxp1
11545
                      && !mips_opts.micromips
11546
                      && strcmp ("pref", insn->name) == 0)
11547 16 khays
                    switch (imm_expr.X_add_number)
11548
                      {
11549
                      case 5:
11550
                      case 25:
11551
                      case 26:
11552
                      case 27:
11553
                      case 28:
11554
                      case 29:
11555
                      case 30:
11556
                      case 31:  /* These are ok.  */
11557
                        break;
11558
 
11559
                      default:  /* The rest must be changed to 28.  */
11560
                        imm_expr.X_add_number = 28;
11561
                        break;
11562
                      }
11563 160 khays
                  INSERT_OPERAND (mips_opts.micromips,
11564
                                  CACHE, *ip, imm_expr.X_add_number);
11565
                  break;
11566
                case 'h':
11567
                  INSERT_OPERAND (mips_opts.micromips,
11568
                                  PREFX, *ip, imm_expr.X_add_number);
11569
                  break;
11570
                case '1':
11571
                  INSERT_OPERAND (mips_opts.micromips,
11572
                                  STYPE, *ip, imm_expr.X_add_number);
11573
                  break;
11574 16 khays
                }
11575
              imm_expr.X_op = O_absent;
11576
              s = expr_end;
11577
              continue;
11578
 
11579
            case 'c':           /* BREAK code.  */
11580 160 khays
              {
11581
                unsigned long mask = (mips_opts.micromips
11582
                                      ? MICROMIPSOP_MASK_CODE
11583
                                      : OP_MASK_CODE);
11584
 
11585
                my_getExpression (&imm_expr, s);
11586
                check_absolute_expr (ip, &imm_expr);
11587
                if ((unsigned long) imm_expr.X_add_number > mask)
11588
                  as_warn (_("Code for %s not in range 0..%lu (%lu)"),
11589
                           ip->insn_mo->name,
11590
                           mask, (unsigned long) imm_expr.X_add_number);
11591
                INSERT_OPERAND (mips_opts.micromips,
11592
                                CODE, *ip, imm_expr.X_add_number);
11593
                imm_expr.X_op = O_absent;
11594
                s = expr_end;
11595
              }
11596 16 khays
              continue;
11597
 
11598
            case 'q':           /* Lower BREAK code.  */
11599 160 khays
              {
11600
                unsigned long mask = (mips_opts.micromips
11601
                                      ? MICROMIPSOP_MASK_CODE2
11602
                                      : OP_MASK_CODE2);
11603
 
11604
                my_getExpression (&imm_expr, s);
11605
                check_absolute_expr (ip, &imm_expr);
11606
                if ((unsigned long) imm_expr.X_add_number > mask)
11607
                  as_warn (_("Lower code for %s not in range 0..%lu (%lu)"),
11608
                           ip->insn_mo->name,
11609
                           mask, (unsigned long) imm_expr.X_add_number);
11610
                INSERT_OPERAND (mips_opts.micromips,
11611
                                CODE2, *ip, imm_expr.X_add_number);
11612
                imm_expr.X_op = O_absent;
11613
                s = expr_end;
11614
              }
11615 16 khays
              continue;
11616
 
11617 160 khays
            case 'B':           /* 20- or 10-bit syscall/break/wait code.  */
11618
              {
11619
                unsigned long mask = (mips_opts.micromips
11620
                                      ? MICROMIPSOP_MASK_CODE10
11621
                                      : OP_MASK_CODE20);
11622
 
11623
                my_getExpression (&imm_expr, s);
11624
                check_absolute_expr (ip, &imm_expr);
11625
                if ((unsigned long) imm_expr.X_add_number > mask)
11626
                  as_warn (_("Code for %s not in range 0..%lu (%lu)"),
11627
                           ip->insn_mo->name,
11628
                           mask, (unsigned long) imm_expr.X_add_number);
11629
                if (mips_opts.micromips)
11630
                  INSERT_OPERAND (1, CODE10, *ip, imm_expr.X_add_number);
11631
                else
11632
                  INSERT_OPERAND (0, CODE20, *ip, imm_expr.X_add_number);
11633
                imm_expr.X_op = O_absent;
11634
                s = expr_end;
11635
              }
11636 16 khays
              continue;
11637
 
11638 160 khays
            case 'C':           /* 25- or 23-bit coprocessor code.  */
11639
              {
11640
                unsigned long mask = (mips_opts.micromips
11641
                                      ? MICROMIPSOP_MASK_COPZ
11642
                                      : OP_MASK_COPZ);
11643
 
11644
                my_getExpression (&imm_expr, s);
11645
                check_absolute_expr (ip, &imm_expr);
11646
                if ((unsigned long) imm_expr.X_add_number > mask)
11647
                  as_warn (_("Coproccesor code > %u bits (%lu)"),
11648
                           mips_opts.micromips ? 23U : 25U,
11649 16 khays
                           (unsigned long) imm_expr.X_add_number);
11650 160 khays
                INSERT_OPERAND (mips_opts.micromips,
11651
                                COPZ, *ip, imm_expr.X_add_number);
11652
                imm_expr.X_op = O_absent;
11653
                s = expr_end;
11654
              }
11655 16 khays
              continue;
11656
 
11657 160 khays
            case 'J':           /* 19-bit WAIT code.  */
11658
              gas_assert (!mips_opts.micromips);
11659 16 khays
              my_getExpression (&imm_expr, s);
11660
              check_absolute_expr (ip, &imm_expr);
11661
              if ((unsigned long) imm_expr.X_add_number > OP_MASK_CODE19)
11662 160 khays
                {
11663
                  as_warn (_("Illegal 19-bit code (%lu)"),
11664 16 khays
                           (unsigned long) imm_expr.X_add_number);
11665 160 khays
                  imm_expr.X_add_number &= OP_MASK_CODE19;
11666
                }
11667
              INSERT_OPERAND (0, CODE19, *ip, imm_expr.X_add_number);
11668 16 khays
              imm_expr.X_op = O_absent;
11669
              s = expr_end;
11670
              continue;
11671
 
11672
            case 'P':           /* Performance register.  */
11673 160 khays
              gas_assert (!mips_opts.micromips);
11674 16 khays
              my_getExpression (&imm_expr, s);
11675
              check_absolute_expr (ip, &imm_expr);
11676
              if (imm_expr.X_add_number != 0 && imm_expr.X_add_number != 1)
11677
                as_warn (_("Invalid performance register (%lu)"),
11678
                         (unsigned long) imm_expr.X_add_number);
11679 160 khays
              INSERT_OPERAND (0, PERFREG, *ip, imm_expr.X_add_number);
11680 16 khays
              imm_expr.X_op = O_absent;
11681
              s = expr_end;
11682
              continue;
11683
 
11684
            case 'G':           /* Coprocessor destination register.  */
11685 160 khays
              {
11686
                unsigned long opcode = ip->insn_opcode;
11687
                unsigned long mask;
11688
                unsigned int types;
11689
                int cop0;
11690 16 khays
 
11691 160 khays
                if (mips_opts.micromips)
11692
                  {
11693
                    mask = ~((MICROMIPSOP_MASK_RT << MICROMIPSOP_SH_RT)
11694
                             | (MICROMIPSOP_MASK_RS << MICROMIPSOP_SH_RS)
11695
                             | (MICROMIPSOP_MASK_SEL << MICROMIPSOP_SH_SEL));
11696
                    opcode &= mask;
11697
                    switch (opcode)
11698
                      {
11699
                      case 0x000000fc:                          /* mfc0  */
11700
                      case 0x000002fc:                          /* mtc0  */
11701
                      case 0x580000fc:                          /* dmfc0 */
11702
                      case 0x580002fc:                          /* dmtc0 */
11703
                        cop0 = 1;
11704
                        break;
11705
                      default:
11706
                        cop0 = 0;
11707
                        break;
11708
                      }
11709
                  }
11710
                else
11711
                  {
11712
                    opcode = (opcode >> OP_SH_OP) & OP_MASK_OP;
11713
                    cop0 = opcode == OP_OP_COP0;
11714
                  }
11715
                types = RTYPE_NUM | (cop0 ? RTYPE_CP0 : RTYPE_GP);
11716
                ok = reg_lookup (&s, types, &regno);
11717
                if (mips_opts.micromips)
11718
                  INSERT_OPERAND (1, RS, *ip, regno);
11719
                else
11720
                  INSERT_OPERAND (0, RD, *ip, regno);
11721
                if (ok)
11722
                  {
11723
                    lastregno = regno;
11724
                    continue;
11725
                  }
11726
              }
11727
              break;
11728
 
11729
            case 'y':           /* ALNV.PS source register.  */
11730
              gas_assert (mips_opts.micromips);
11731
              goto do_reg;
11732
            case 'x':           /* Ignore register name.  */
11733
            case 'U':           /* Destination register (CLO/CLZ).  */
11734
            case 'g':           /* Coprocessor destination register.  */
11735
              gas_assert (!mips_opts.micromips);
11736 16 khays
            case 'b':           /* Base register.  */
11737
            case 'd':           /* Destination register.  */
11738
            case 's':           /* Source register.  */
11739
            case 't':           /* Target register.  */
11740
            case 'r':           /* Both target and source.  */
11741
            case 'v':           /* Both dest and source.  */
11742
            case 'w':           /* Both dest and target.  */
11743
            case 'E':           /* Coprocessor target register.  */
11744
            case 'K':           /* RDHWR destination register.  */
11745
            case 'z':           /* Must be zero register.  */
11746 160 khays
            do_reg:
11747 16 khays
              s_reset = s;
11748
              if (*args == 'E' || *args == 'K')
11749
                ok = reg_lookup (&s, RTYPE_NUM, &regno);
11750
              else
11751
                {
11752
                  ok = reg_lookup (&s, RTYPE_NUM | RTYPE_GP, &regno);
11753
                  if (regno == AT && mips_opts.at)
11754
                    {
11755
                      if (mips_opts.at == ATREG)
11756
                        as_warn (_("Used $at without \".set noat\""));
11757
                      else
11758
                        as_warn (_("Used $%u with \".set at=$%u\""),
11759
                                 regno, mips_opts.at);
11760
                    }
11761
                }
11762
              if (ok)
11763
                {
11764
                  c = *args;
11765
                  if (*s == ' ')
11766
                    ++s;
11767
                  if (args[1] != *s)
11768
                    {
11769
                      if (c == 'r' || c == 'v' || c == 'w')
11770
                        {
11771
                          regno = lastregno;
11772
                          s = s_reset;
11773
                          ++args;
11774
                        }
11775
                    }
11776
                  /* 'z' only matches $0.  */
11777
                  if (c == 'z' && regno != 0)
11778
                    break;
11779
 
11780
                  if (c == 's' && !strncmp (ip->insn_mo->name, "jalr", 4))
11781
                    {
11782
                      if (regno == lastregno)
11783
                        {
11784
                          insn_error
11785
                            = _("Source and destination must be different");
11786
                          continue;
11787
                        }
11788
                      if (regno == 31 && lastregno == 0xffffffff)
11789
                        {
11790
                          insn_error
11791
                            = _("A destination register must be supplied");
11792
                          continue;
11793
                        }
11794
                    }
11795
                  /* Now that we have assembled one operand, we use the args
11796
                     string to figure out where it goes in the instruction.  */
11797
                  switch (c)
11798
                    {
11799
                    case 'r':
11800
                    case 's':
11801
                    case 'v':
11802
                    case 'b':
11803 160 khays
                      INSERT_OPERAND (mips_opts.micromips, RS, *ip, regno);
11804 16 khays
                      break;
11805 160 khays
 
11806
                    case 'K':
11807
                      if (mips_opts.micromips)
11808
                        INSERT_OPERAND (1, RS, *ip, regno);
11809
                      else
11810
                        INSERT_OPERAND (0, RD, *ip, regno);
11811
                      break;
11812
 
11813 16 khays
                    case 'd':
11814
                    case 'g':
11815 160 khays
                      INSERT_OPERAND (mips_opts.micromips, RD, *ip, regno);
11816 16 khays
                      break;
11817 160 khays
 
11818 16 khays
                    case 'U':
11819 160 khays
                      gas_assert (!mips_opts.micromips);
11820
                      INSERT_OPERAND (0, RD, *ip, regno);
11821
                      INSERT_OPERAND (0, RT, *ip, regno);
11822 16 khays
                      break;
11823 160 khays
 
11824 16 khays
                    case 'w':
11825
                    case 't':
11826
                    case 'E':
11827 160 khays
                      INSERT_OPERAND (mips_opts.micromips, RT, *ip, regno);
11828 16 khays
                      break;
11829 160 khays
 
11830
                    case 'y':
11831
                      gas_assert (mips_opts.micromips);
11832
                      INSERT_OPERAND (1, RS3, *ip, regno);
11833
                      break;
11834
 
11835 16 khays
                    case 'x':
11836
                      /* This case exists because on the r3000 trunc
11837
                         expands into a macro which requires a gp
11838
                         register.  On the r6000 or r4000 it is
11839
                         assembled into a single instruction which
11840
                         ignores the register.  Thus the insn version
11841
                         is MIPS_ISA2 and uses 'x', and the macro
11842
                         version is MIPS_ISA1 and uses 't'.  */
11843
                      break;
11844 160 khays
 
11845 16 khays
                    case 'z':
11846
                      /* This case is for the div instruction, which
11847
                         acts differently if the destination argument
11848
                         is $0.  This only matches $0, and is checked
11849
                         outside the switch.  */
11850
                      break;
11851
                    }
11852
                  lastregno = regno;
11853
                  continue;
11854
                }
11855
              switch (*args++)
11856
                {
11857
                case 'r':
11858
                case 'v':
11859 160 khays
                  INSERT_OPERAND (mips_opts.micromips, RS, *ip, lastregno);
11860 16 khays
                  continue;
11861 160 khays
 
11862 16 khays
                case 'w':
11863 160 khays
                  INSERT_OPERAND (mips_opts.micromips, RT, *ip, lastregno);
11864 16 khays
                  continue;
11865
                }
11866
              break;
11867
 
11868
            case 'O':           /* MDMX alignment immediate constant.  */
11869 160 khays
              gas_assert (!mips_opts.micromips);
11870 16 khays
              my_getExpression (&imm_expr, s);
11871
              check_absolute_expr (ip, &imm_expr);
11872
              if ((unsigned long) imm_expr.X_add_number > OP_MASK_ALN)
11873
                as_warn (_("Improper align amount (%ld), using low bits"),
11874
                         (long) imm_expr.X_add_number);
11875 160 khays
              INSERT_OPERAND (0, ALN, *ip, imm_expr.X_add_number);
11876 16 khays
              imm_expr.X_op = O_absent;
11877
              s = expr_end;
11878
              continue;
11879
 
11880
            case 'Q':           /* MDMX vector, element sel, or const.  */
11881
              if (s[0] != '$')
11882
                {
11883
                  /* MDMX Immediate.  */
11884 160 khays
                  gas_assert (!mips_opts.micromips);
11885 16 khays
                  my_getExpression (&imm_expr, s);
11886
                  check_absolute_expr (ip, &imm_expr);
11887
                  if ((unsigned long) imm_expr.X_add_number > OP_MASK_FT)
11888
                    as_warn (_("Invalid MDMX Immediate (%ld)"),
11889
                             (long) imm_expr.X_add_number);
11890 160 khays
                  INSERT_OPERAND (0, FT, *ip, imm_expr.X_add_number);
11891 16 khays
                  if (ip->insn_opcode & (OP_MASK_VSEL << OP_SH_VSEL))
11892
                    ip->insn_opcode |= MDMX_FMTSEL_IMM_QH << OP_SH_VSEL;
11893
                  else
11894
                    ip->insn_opcode |= MDMX_FMTSEL_IMM_OB << OP_SH_VSEL;
11895
                  imm_expr.X_op = O_absent;
11896
                  s = expr_end;
11897
                  continue;
11898
                }
11899
              /* Not MDMX Immediate.  Fall through.  */
11900
            case 'X':           /* MDMX destination register.  */
11901
            case 'Y':           /* MDMX source register.  */
11902
            case 'Z':           /* MDMX target register.  */
11903
              is_mdmx = 1;
11904 160 khays
            case 'W':
11905
              gas_assert (!mips_opts.micromips);
11906 16 khays
            case 'D':           /* Floating point destination register.  */
11907
            case 'S':           /* Floating point source register.  */
11908
            case 'T':           /* Floating point target register.  */
11909
            case 'R':           /* Floating point source register.  */
11910
            case 'V':
11911
              rtype = RTYPE_FPU;
11912
              if (is_mdmx
11913
                  || (mips_opts.ase_mdmx
11914
                      && (ip->insn_mo->pinfo & FP_D)
11915
                      && (ip->insn_mo->pinfo & (INSN_COPROC_MOVE_DELAY
11916
                                                | INSN_COPROC_MEMORY_DELAY
11917
                                                | INSN_LOAD_COPROC_DELAY
11918
                                                | INSN_LOAD_MEMORY_DELAY
11919
                                                | INSN_STORE_MEMORY))))
11920
                rtype |= RTYPE_VEC;
11921
              s_reset = s;
11922
              if (reg_lookup (&s, rtype, &regno))
11923
                {
11924
                  if ((regno & 1) != 0
11925
                      && HAVE_32BIT_FPRS
11926
                      && !mips_oddfpreg_ok (ip->insn_mo, argnum))
11927
                    as_warn (_("Float register should be even, was %d"),
11928
                             regno);
11929
 
11930
                  c = *args;
11931
                  if (*s == ' ')
11932
                    ++s;
11933
                  if (args[1] != *s)
11934
                    {
11935
                      if (c == 'V' || c == 'W')
11936
                        {
11937
                          regno = lastregno;
11938
                          s = s_reset;
11939
                          ++args;
11940
                        }
11941
                    }
11942
                  switch (c)
11943
                    {
11944
                    case 'D':
11945
                    case 'X':
11946 160 khays
                      INSERT_OPERAND (mips_opts.micromips, FD, *ip, regno);
11947 16 khays
                      break;
11948 160 khays
 
11949 16 khays
                    case 'V':
11950
                    case 'S':
11951
                    case 'Y':
11952 160 khays
                      INSERT_OPERAND (mips_opts.micromips, FS, *ip, regno);
11953 16 khays
                      break;
11954 160 khays
 
11955 16 khays
                    case 'Q':
11956
                      /* This is like 'Z', but also needs to fix the MDMX
11957
                         vector/scalar select bits.  Note that the
11958
                         scalar immediate case is handled above.  */
11959
                      if (*s == '[')
11960
                        {
11961
                          int is_qh = (ip->insn_opcode & (1 << OP_SH_VSEL));
11962
                          int max_el = (is_qh ? 3 : 7);
11963
                          s++;
11964
                          my_getExpression(&imm_expr, s);
11965
                          check_absolute_expr (ip, &imm_expr);
11966
                          s = expr_end;
11967
                          if (imm_expr.X_add_number > max_el)
11968
                            as_bad (_("Bad element selector %ld"),
11969
                                    (long) imm_expr.X_add_number);
11970
                          imm_expr.X_add_number &= max_el;
11971
                          ip->insn_opcode |= (imm_expr.X_add_number
11972
                                              << (OP_SH_VSEL +
11973
                                                  (is_qh ? 2 : 1)));
11974
                          imm_expr.X_op = O_absent;
11975
                          if (*s != ']')
11976
                            as_warn (_("Expecting ']' found '%s'"), s);
11977
                          else
11978
                            s++;
11979
                        }
11980
                      else
11981
                        {
11982
                          if (ip->insn_opcode & (OP_MASK_VSEL << OP_SH_VSEL))
11983
                            ip->insn_opcode |= (MDMX_FMTSEL_VEC_QH
11984
                                                << OP_SH_VSEL);
11985
                          else
11986
                            ip->insn_opcode |= (MDMX_FMTSEL_VEC_OB <<
11987
                                                OP_SH_VSEL);
11988
                        }
11989
                      /* Fall through.  */
11990
                    case 'W':
11991
                    case 'T':
11992
                    case 'Z':
11993 160 khays
                      INSERT_OPERAND (mips_opts.micromips, FT, *ip, regno);
11994 16 khays
                      break;
11995 160 khays
 
11996 16 khays
                    case 'R':
11997 160 khays
                      INSERT_OPERAND (mips_opts.micromips, FR, *ip, regno);
11998 16 khays
                      break;
11999
                    }
12000
                  lastregno = regno;
12001
                  continue;
12002
                }
12003
 
12004
              switch (*args++)
12005
                {
12006
                case 'V':
12007 160 khays
                  INSERT_OPERAND (mips_opts.micromips, FS, *ip, lastregno);
12008 16 khays
                  continue;
12009 160 khays
 
12010 16 khays
                case 'W':
12011 160 khays
                  INSERT_OPERAND (mips_opts.micromips, FT, *ip, lastregno);
12012 16 khays
                  continue;
12013
                }
12014
              break;
12015
 
12016
            case 'I':
12017
              my_getExpression (&imm_expr, s);
12018
              if (imm_expr.X_op != O_big
12019
                  && imm_expr.X_op != O_constant)
12020
                insn_error = _("absolute expression required");
12021
              if (HAVE_32BIT_GPRS)
12022
                normalize_constant_expr (&imm_expr);
12023
              s = expr_end;
12024
              continue;
12025
 
12026
            case 'A':
12027
              my_getExpression (&offset_expr, s);
12028
              normalize_address_expr (&offset_expr);
12029
              *imm_reloc = BFD_RELOC_32;
12030
              s = expr_end;
12031
              continue;
12032
 
12033
            case 'F':
12034
            case 'L':
12035
            case 'f':
12036
            case 'l':
12037
              {
12038
                int f64;
12039
                int using_gprs;
12040
                char *save_in;
12041
                char *err;
12042
                unsigned char temp[8];
12043
                int len;
12044
                unsigned int length;
12045
                segT seg;
12046
                subsegT subseg;
12047
                char *p;
12048
 
12049
                /* These only appear as the last operand in an
12050
                   instruction, and every instruction that accepts
12051
                   them in any variant accepts them in all variants.
12052
                   This means we don't have to worry about backing out
12053
                   any changes if the instruction does not match.
12054
 
12055
                   The difference between them is the size of the
12056
                   floating point constant and where it goes.  For 'F'
12057
                   and 'L' the constant is 64 bits; for 'f' and 'l' it
12058
                   is 32 bits.  Where the constant is placed is based
12059
                   on how the MIPS assembler does things:
12060
                    F -- .rdata
12061
                    L -- .lit8
12062
                    f -- immediate value
12063
                    l -- .lit4
12064
 
12065
                    The .lit4 and .lit8 sections are only used if
12066
                    permitted by the -G argument.
12067
 
12068
                    The code below needs to know whether the target register
12069
                    is 32 or 64 bits wide.  It relies on the fact 'f' and
12070
                    'F' are used with GPR-based instructions and 'l' and
12071
                    'L' are used with FPR-based instructions.  */
12072
 
12073
                f64 = *args == 'F' || *args == 'L';
12074
                using_gprs = *args == 'F' || *args == 'f';
12075
 
12076
                save_in = input_line_pointer;
12077
                input_line_pointer = s;
12078
                err = md_atof (f64 ? 'd' : 'f', (char *) temp, &len);
12079
                length = len;
12080
                s = input_line_pointer;
12081
                input_line_pointer = save_in;
12082
                if (err != NULL && *err != '\0')
12083
                  {
12084
                    as_bad (_("Bad floating point constant: %s"), err);
12085
                    memset (temp, '\0', sizeof temp);
12086
                    length = f64 ? 8 : 4;
12087
                  }
12088
 
12089
                gas_assert (length == (unsigned) (f64 ? 8 : 4));
12090
 
12091
                if (*args == 'f'
12092
                    || (*args == 'l'
12093
                        && (g_switch_value < 4
12094
                            || (temp[0] == 0 && temp[1] == 0)
12095
                            || (temp[2] == 0 && temp[3] == 0))))
12096
                  {
12097
                    imm_expr.X_op = O_constant;
12098
                    if (!target_big_endian)
12099
                      imm_expr.X_add_number = bfd_getl32 (temp);
12100
                    else
12101
                      imm_expr.X_add_number = bfd_getb32 (temp);
12102
                  }
12103
                else if (length > 4
12104
                         && !mips_disable_float_construction
12105
                         /* Constants can only be constructed in GPRs and
12106
                            copied to FPRs if the GPRs are at least as wide
12107
                            as the FPRs.  Force the constant into memory if
12108
                            we are using 64-bit FPRs but the GPRs are only
12109
                            32 bits wide.  */
12110
                         && (using_gprs
12111
                             || !(HAVE_64BIT_FPRS && HAVE_32BIT_GPRS))
12112
                         && ((temp[0] == 0 && temp[1] == 0)
12113
                             || (temp[2] == 0 && temp[3] == 0))
12114
                         && ((temp[4] == 0 && temp[5] == 0)
12115
                             || (temp[6] == 0 && temp[7] == 0)))
12116
                  {
12117
                    /* The value is simple enough to load with a couple of
12118
                       instructions.  If using 32-bit registers, set
12119
                       imm_expr to the high order 32 bits and offset_expr to
12120
                       the low order 32 bits.  Otherwise, set imm_expr to
12121
                       the entire 64 bit constant.  */
12122
                    if (using_gprs ? HAVE_32BIT_GPRS : HAVE_32BIT_FPRS)
12123
                      {
12124
                        imm_expr.X_op = O_constant;
12125
                        offset_expr.X_op = O_constant;
12126
                        if (!target_big_endian)
12127
                          {
12128
                            imm_expr.X_add_number = bfd_getl32 (temp + 4);
12129
                            offset_expr.X_add_number = bfd_getl32 (temp);
12130
                          }
12131
                        else
12132
                          {
12133
                            imm_expr.X_add_number = bfd_getb32 (temp);
12134
                            offset_expr.X_add_number = bfd_getb32 (temp + 4);
12135
                          }
12136
                        if (offset_expr.X_add_number == 0)
12137
                          offset_expr.X_op = O_absent;
12138
                      }
12139
                    else if (sizeof (imm_expr.X_add_number) > 4)
12140
                      {
12141
                        imm_expr.X_op = O_constant;
12142
                        if (!target_big_endian)
12143
                          imm_expr.X_add_number = bfd_getl64 (temp);
12144
                        else
12145
                          imm_expr.X_add_number = bfd_getb64 (temp);
12146
                      }
12147
                    else
12148
                      {
12149
                        imm_expr.X_op = O_big;
12150
                        imm_expr.X_add_number = 4;
12151
                        if (!target_big_endian)
12152
                          {
12153
                            generic_bignum[0] = bfd_getl16 (temp);
12154
                            generic_bignum[1] = bfd_getl16 (temp + 2);
12155
                            generic_bignum[2] = bfd_getl16 (temp + 4);
12156
                            generic_bignum[3] = bfd_getl16 (temp + 6);
12157
                          }
12158
                        else
12159
                          {
12160
                            generic_bignum[0] = bfd_getb16 (temp + 6);
12161
                            generic_bignum[1] = bfd_getb16 (temp + 4);
12162
                            generic_bignum[2] = bfd_getb16 (temp + 2);
12163
                            generic_bignum[3] = bfd_getb16 (temp);
12164
                          }
12165
                      }
12166
                  }
12167
                else
12168
                  {
12169
                    const char *newname;
12170
                    segT new_seg;
12171
 
12172
                    /* Switch to the right section.  */
12173
                    seg = now_seg;
12174
                    subseg = now_subseg;
12175
                    switch (*args)
12176
                      {
12177
                      default: /* unused default case avoids warnings.  */
12178
                      case 'L':
12179
                        newname = RDATA_SECTION_NAME;
12180
                        if (g_switch_value >= 8)
12181
                          newname = ".lit8";
12182
                        break;
12183
                      case 'F':
12184
                        newname = RDATA_SECTION_NAME;
12185
                        break;
12186
                      case 'l':
12187
                        gas_assert (g_switch_value >= 4);
12188
                        newname = ".lit4";
12189
                        break;
12190
                      }
12191
                    new_seg = subseg_new (newname, (subsegT) 0);
12192
                    if (IS_ELF)
12193
                      bfd_set_section_flags (stdoutput, new_seg,
12194
                                             (SEC_ALLOC
12195
                                              | SEC_LOAD
12196
                                              | SEC_READONLY
12197
                                              | SEC_DATA));
12198
                    frag_align (*args == 'l' ? 2 : 3, 0, 0);
12199
                    if (IS_ELF && strncmp (TARGET_OS, "elf", 3) != 0)
12200
                      record_alignment (new_seg, 4);
12201
                    else
12202
                      record_alignment (new_seg, *args == 'l' ? 2 : 3);
12203
                    if (seg == now_seg)
12204
                      as_bad (_("Can't use floating point insn in this section"));
12205
 
12206
                    /* Set the argument to the current address in the
12207
                       section.  */
12208
                    offset_expr.X_op = O_symbol;
12209
                    offset_expr.X_add_symbol = symbol_temp_new_now ();
12210
                    offset_expr.X_add_number = 0;
12211
 
12212
                    /* Put the floating point number into the section.  */
12213
                    p = frag_more ((int) length);
12214
                    memcpy (p, temp, length);
12215
 
12216
                    /* Switch back to the original section.  */
12217
                    subseg_set (seg, subseg);
12218
                  }
12219
              }
12220
              continue;
12221
 
12222
            case 'i':           /* 16-bit unsigned immediate.  */
12223
            case 'j':           /* 16-bit signed immediate.  */
12224
              *imm_reloc = BFD_RELOC_LO16;
12225
              if (my_getSmallExpression (&imm_expr, imm_reloc, s) == 0)
12226
                {
12227
                  int more;
12228
                  offsetT minval, maxval;
12229
 
12230 160 khays
                  more = (insn + 1 < past
12231 16 khays
                          && strcmp (insn->name, insn[1].name) == 0);
12232
 
12233
                  /* If the expression was written as an unsigned number,
12234
                     only treat it as signed if there are no more
12235
                     alternatives.  */
12236
                  if (more
12237
                      && *args == 'j'
12238
                      && sizeof (imm_expr.X_add_number) <= 4
12239
                      && imm_expr.X_op == O_constant
12240
                      && imm_expr.X_add_number < 0
12241
                      && imm_expr.X_unsigned
12242
                      && HAVE_64BIT_GPRS)
12243
                    break;
12244
 
12245
                  /* For compatibility with older assemblers, we accept
12246
                     0x8000-0xffff as signed 16-bit numbers when only
12247
                     signed numbers are allowed.  */
12248
                  if (*args == 'i')
12249
                    minval = 0, maxval = 0xffff;
12250
                  else if (more)
12251
                    minval = -0x8000, maxval = 0x7fff;
12252
                  else
12253
                    minval = -0x8000, maxval = 0xffff;
12254
 
12255
                  if (imm_expr.X_op != O_constant
12256
                      || imm_expr.X_add_number < minval
12257
                      || imm_expr.X_add_number > maxval)
12258
                    {
12259
                      if (more)
12260
                        break;
12261
                      if (imm_expr.X_op == O_constant
12262
                          || imm_expr.X_op == O_big)
12263
                        as_bad (_("Expression out of range"));
12264
                    }
12265
                }
12266
              s = expr_end;
12267
              continue;
12268
 
12269
            case 'o':           /* 16-bit offset.  */
12270
              offset_reloc[0] = BFD_RELOC_LO16;
12271
              offset_reloc[1] = BFD_RELOC_UNUSED;
12272
              offset_reloc[2] = BFD_RELOC_UNUSED;
12273
 
12274
              /* Check whether there is only a single bracketed expression
12275
                 left.  If so, it must be the base register and the
12276
                 constant must be zero.  */
12277
              if (*s == '(' && strchr (s + 1, '(') == 0)
12278
                {
12279
                  offset_expr.X_op = O_constant;
12280
                  offset_expr.X_add_number = 0;
12281
                  continue;
12282
                }
12283
 
12284
              /* If this value won't fit into a 16 bit offset, then go
12285
                 find a macro that will generate the 32 bit offset
12286
                 code pattern.  */
12287
              if (my_getSmallExpression (&offset_expr, offset_reloc, s) == 0
12288
                  && (offset_expr.X_op != O_constant
12289
                      || offset_expr.X_add_number >= 0x8000
12290
                      || offset_expr.X_add_number < -0x8000))
12291
                break;
12292
 
12293
              s = expr_end;
12294
              continue;
12295
 
12296
            case 'p':           /* PC-relative offset.  */
12297
              *offset_reloc = BFD_RELOC_16_PCREL_S2;
12298
              my_getExpression (&offset_expr, s);
12299
              s = expr_end;
12300
              continue;
12301
 
12302
            case 'u':           /* Upper 16 bits.  */
12303
              if (my_getSmallExpression (&imm_expr, imm_reloc, s) == 0
12304
                  && imm_expr.X_op == O_constant
12305
                  && (imm_expr.X_add_number < 0
12306
                      || imm_expr.X_add_number >= 0x10000))
12307
                as_bad (_("lui expression (%lu) not in range 0..65535"),
12308
                        (unsigned long) imm_expr.X_add_number);
12309
              s = expr_end;
12310
              continue;
12311
 
12312
            case 'a':           /* 26-bit address.  */
12313 160 khays
              *offset_reloc = BFD_RELOC_MIPS_JMP;
12314 16 khays
              my_getExpression (&offset_expr, s);
12315
              s = expr_end;
12316
              continue;
12317
 
12318
            case 'N':           /* 3-bit branch condition code.  */
12319
            case 'M':           /* 3-bit compare condition code.  */
12320
              rtype = RTYPE_CCC;
12321
              if (ip->insn_mo->pinfo & (FP_D | FP_S))
12322
                rtype |= RTYPE_FCC;
12323
              if (!reg_lookup (&s, rtype, &regno))
12324
                break;
12325
              if ((strcmp (str + strlen (str) - 3, ".ps") == 0
12326
                   || strcmp (str + strlen (str) - 5, "any2f") == 0
12327
                   || strcmp (str + strlen (str) - 5, "any2t") == 0)
12328
                  && (regno & 1) != 0)
12329
                as_warn (_("Condition code register should be even for %s, "
12330
                           "was %d"),
12331
                         str, regno);
12332
              if ((strcmp (str + strlen (str) - 5, "any4f") == 0
12333
                   || strcmp (str + strlen (str) - 5, "any4t") == 0)
12334
                  && (regno & 3) != 0)
12335
                as_warn (_("Condition code register should be 0 or 4 for %s, "
12336
                           "was %d"),
12337
                         str, regno);
12338
              if (*args == 'N')
12339 160 khays
                INSERT_OPERAND (mips_opts.micromips, BCC, *ip, regno);
12340 16 khays
              else
12341 160 khays
                INSERT_OPERAND (mips_opts.micromips, CCC, *ip, regno);
12342 16 khays
              continue;
12343
 
12344
            case 'H':
12345
              if (s[0] == '0' && (s[1] == 'x' || s[1] == 'X'))
12346
                s += 2;
12347
              if (ISDIGIT (*s))
12348
                {
12349
                  c = 0;
12350
                  do
12351
                    {
12352
                      c *= 10;
12353
                      c += *s - '0';
12354
                      ++s;
12355
                    }
12356
                  while (ISDIGIT (*s));
12357
                }
12358
              else
12359
                c = 8; /* Invalid sel value.  */
12360
 
12361
              if (c > 7)
12362
                as_bad (_("Invalid coprocessor sub-selection value (0-7)"));
12363 160 khays
              INSERT_OPERAND (mips_opts.micromips, SEL, *ip, c);
12364 16 khays
              continue;
12365
 
12366
            case 'e':
12367 160 khays
              gas_assert (!mips_opts.micromips);
12368 16 khays
              /* Must be at least one digit.  */
12369
              my_getExpression (&imm_expr, s);
12370
              check_absolute_expr (ip, &imm_expr);
12371
 
12372
              if ((unsigned long) imm_expr.X_add_number
12373
                  > (unsigned long) OP_MASK_VECBYTE)
12374
                {
12375
                  as_bad (_("bad byte vector index (%ld)"),
12376
                           (long) imm_expr.X_add_number);
12377
                  imm_expr.X_add_number = 0;
12378
                }
12379
 
12380 160 khays
              INSERT_OPERAND (0, VECBYTE, *ip, imm_expr.X_add_number);
12381 16 khays
              imm_expr.X_op = O_absent;
12382
              s = expr_end;
12383
              continue;
12384
 
12385
            case '%':
12386 160 khays
              gas_assert (!mips_opts.micromips);
12387 16 khays
              my_getExpression (&imm_expr, s);
12388
              check_absolute_expr (ip, &imm_expr);
12389
 
12390
              if ((unsigned long) imm_expr.X_add_number
12391
                  > (unsigned long) OP_MASK_VECALIGN)
12392
                {
12393
                  as_bad (_("bad byte vector index (%ld)"),
12394
                           (long) imm_expr.X_add_number);
12395
                  imm_expr.X_add_number = 0;
12396
                }
12397
 
12398 160 khays
              INSERT_OPERAND (0, VECALIGN, *ip, imm_expr.X_add_number);
12399 16 khays
              imm_expr.X_op = O_absent;
12400
              s = expr_end;
12401
              continue;
12402
 
12403 160 khays
            case 'm':           /* Opcode extension character.  */
12404
              gas_assert (mips_opts.micromips);
12405
              c = *++args;
12406
              switch (c)
12407
                {
12408
                case 'r':
12409
                  if (strncmp (s, "$pc", 3) == 0)
12410
                    {
12411
                      s += 3;
12412
                      continue;
12413
                    }
12414
                  break;
12415
 
12416
                case 'a':
12417
                case 'b':
12418
                case 'c':
12419
                case 'd':
12420
                case 'e':
12421
                case 'f':
12422
                case 'g':
12423
                case 'h':
12424
                case 'i':
12425
                case 'j':
12426
                case 'l':
12427
                case 'm':
12428
                case 'n':
12429
                case 'p':
12430
                case 'q':
12431
                case 's':
12432
                case 't':
12433
                case 'x':
12434
                case 'y':
12435
                case 'z':
12436
                  s_reset = s;
12437
                  ok = reg_lookup (&s, RTYPE_NUM | RTYPE_GP, &regno);
12438
                  if (regno == AT && mips_opts.at)
12439
                    {
12440
                      if (mips_opts.at == ATREG)
12441
                        as_warn (_("Used $at without \".set noat\""));
12442
                      else
12443
                        as_warn (_("Used $%u with \".set at=$%u\""),
12444
                                 regno, mips_opts.at);
12445
                    }
12446
                  if (!ok)
12447
                    {
12448
                      if (c == 'c')
12449
                        {
12450
                          gas_assert (args[1] == ',');
12451
                          regno = lastregno;
12452
                          ++args;
12453
                        }
12454
                      else if (c == 't')
12455
                        {
12456
                          gas_assert (args[1] == ',');
12457
                          ++args;
12458
                          continue;                     /* Nothing to do.  */
12459
                        }
12460
                      else
12461
                        break;
12462
                    }
12463
 
12464
                  if (c == 'j' && !strncmp (ip->insn_mo->name, "jalr", 4))
12465
                    {
12466
                      if (regno == lastregno)
12467
                        {
12468
                          insn_error
12469
                            = _("Source and destination must be different");
12470
                          continue;
12471
                        }
12472
                      if (regno == 31 && lastregno == 0xffffffff)
12473
                        {
12474
                          insn_error
12475
                            = _("A destination register must be supplied");
12476
                          continue;
12477
                        }
12478
                    }
12479
 
12480
                  if (*s == ' ')
12481
                    ++s;
12482
                  if (args[1] != *s)
12483
                    {
12484
                      if (c == 'e')
12485
                        {
12486
                          gas_assert (args[1] == ',');
12487
                          regno = lastregno;
12488
                          s = s_reset;
12489
                          ++args;
12490
                        }
12491
                      else if (c == 't')
12492
                        {
12493
                          gas_assert (args[1] == ',');
12494
                          s = s_reset;
12495
                          ++args;
12496
                          continue;                     /* Nothing to do.  */
12497
                        }
12498
                    }
12499
 
12500
                  /* Make sure regno is the same as lastregno.  */
12501
                  if (c == 't' && regno != lastregno)
12502
                    break;
12503
 
12504
                  /* Make sure regno is the same as destregno.  */
12505
                  if (c == 'x' && regno != destregno)
12506
                    break;
12507
 
12508
                  /* We need to save regno, before regno maps to the
12509
                     microMIPS register encoding.  */
12510
                  lastregno = regno;
12511
 
12512
                  if (c == 'f')
12513
                    destregno = regno;
12514
 
12515
                  switch (c)
12516
                    {
12517
                      case 'a':
12518
                        if (regno != GP)
12519
                          regno = ILLEGAL_REG;
12520
                        break;
12521
 
12522
                      case 'b':
12523
                        regno = mips32_to_micromips_reg_b_map[regno];
12524
                        break;
12525
 
12526
                      case 'c':
12527
                        regno = mips32_to_micromips_reg_c_map[regno];
12528
                        break;
12529
 
12530
                      case 'd':
12531
                        regno = mips32_to_micromips_reg_d_map[regno];
12532
                        break;
12533
 
12534
                      case 'e':
12535
                        regno = mips32_to_micromips_reg_e_map[regno];
12536
                        break;
12537
 
12538
                      case 'f':
12539
                        regno = mips32_to_micromips_reg_f_map[regno];
12540
                        break;
12541
 
12542
                      case 'g':
12543
                        regno = mips32_to_micromips_reg_g_map[regno];
12544
                        break;
12545
 
12546
                      case 'h':
12547
                        regno = mips32_to_micromips_reg_h_map[regno];
12548
                        break;
12549
 
12550
                      case 'i':
12551
                        switch (EXTRACT_OPERAND (1, MI, *ip))
12552
                          {
12553
                            case 4:
12554
                              if (regno == 21)
12555
                                regno = 3;
12556
                              else if (regno == 22)
12557
                                regno = 4;
12558
                              else if (regno == 5)
12559
                                regno = 5;
12560
                              else if (regno == 6)
12561
                                regno = 6;
12562
                              else if (regno == 7)
12563
                                regno = 7;
12564
                              else
12565
                                regno = ILLEGAL_REG;
12566
                              break;
12567
 
12568
                            case 5:
12569
                              if (regno == 6)
12570
                                regno = 0;
12571
                              else if (regno == 7)
12572
                                regno = 1;
12573
                              else
12574
                                regno = ILLEGAL_REG;
12575
                              break;
12576
 
12577
                            case 6:
12578
                              if (regno == 7)
12579
                                regno = 2;
12580
                              else
12581
                                regno = ILLEGAL_REG;
12582
                              break;
12583
 
12584
                            default:
12585
                              regno = ILLEGAL_REG;
12586
                              break;
12587
                          }
12588
                        break;
12589
 
12590
                      case 'l':
12591
                        regno = mips32_to_micromips_reg_l_map[regno];
12592
                        break;
12593
 
12594
                      case 'm':
12595
                        regno = mips32_to_micromips_reg_m_map[regno];
12596
                        break;
12597
 
12598
                      case 'n':
12599
                        regno = mips32_to_micromips_reg_n_map[regno];
12600
                        break;
12601
 
12602
                      case 'q':
12603
                        regno = mips32_to_micromips_reg_q_map[regno];
12604
                        break;
12605
 
12606
                      case 's':
12607
                        if (regno != SP)
12608
                          regno = ILLEGAL_REG;
12609
                        break;
12610
 
12611
                      case 'y':
12612
                        if (regno != 31)
12613
                          regno = ILLEGAL_REG;
12614
                        break;
12615
 
12616
                      case 'z':
12617
                        if (regno != ZERO)
12618
                          regno = ILLEGAL_REG;
12619
                        break;
12620
 
12621
                      case 'j': /* Do nothing.  */
12622
                      case 'p':
12623
                      case 't':
12624
                      case 'x':
12625
                        break;
12626
 
12627
                      default:
12628
                        internalError ();
12629
                    }
12630
 
12631
                  if (regno == ILLEGAL_REG)
12632
                    break;
12633
 
12634
                  switch (c)
12635
                    {
12636
                      case 'b':
12637
                        INSERT_OPERAND (1, MB, *ip, regno);
12638
                        break;
12639
 
12640
                      case 'c':
12641
                        INSERT_OPERAND (1, MC, *ip, regno);
12642
                        break;
12643
 
12644
                      case 'd':
12645
                        INSERT_OPERAND (1, MD, *ip, regno);
12646
                        break;
12647
 
12648
                      case 'e':
12649
                        INSERT_OPERAND (1, ME, *ip, regno);
12650
                        break;
12651
 
12652
                      case 'f':
12653
                        INSERT_OPERAND (1, MF, *ip, regno);
12654
                        break;
12655
 
12656
                      case 'g':
12657
                        INSERT_OPERAND (1, MG, *ip, regno);
12658
                        break;
12659
 
12660
                      case 'h':
12661
                        INSERT_OPERAND (1, MH, *ip, regno);
12662
                        break;
12663
 
12664
                      case 'i':
12665
                        INSERT_OPERAND (1, MI, *ip, regno);
12666
                        break;
12667
 
12668
                      case 'j':
12669
                        INSERT_OPERAND (1, MJ, *ip, regno);
12670
                        break;
12671
 
12672
                      case 'l':
12673
                        INSERT_OPERAND (1, ML, *ip, regno);
12674
                        break;
12675
 
12676
                      case 'm':
12677
                        INSERT_OPERAND (1, MM, *ip, regno);
12678
                        break;
12679
 
12680
                      case 'n':
12681
                        INSERT_OPERAND (1, MN, *ip, regno);
12682
                        break;
12683
 
12684
                      case 'p':
12685
                        INSERT_OPERAND (1, MP, *ip, regno);
12686
                        break;
12687
 
12688
                      case 'q':
12689
                        INSERT_OPERAND (1, MQ, *ip, regno);
12690
                        break;
12691
 
12692
                      case 'a': /* Do nothing.  */
12693
                      case 's': /* Do nothing.  */
12694
                      case 't': /* Do nothing.  */
12695
                      case 'x': /* Do nothing.  */
12696
                      case 'y': /* Do nothing.  */
12697
                      case 'z': /* Do nothing.  */
12698
                        break;
12699
 
12700
                      default:
12701
                        internalError ();
12702
                    }
12703
                  continue;
12704
 
12705
                case 'A':
12706
                  {
12707
                    bfd_reloc_code_real_type r[3];
12708
                    expressionS ep;
12709
                    int imm;
12710
 
12711
                    /* Check whether there is only a single bracketed
12712
                       expression left.  If so, it must be the base register
12713
                       and the constant must be zero.  */
12714
                    if (*s == '(' && strchr (s + 1, '(') == 0)
12715
                      {
12716
                        INSERT_OPERAND (1, IMMA, *ip, 0);
12717
                        continue;
12718
                      }
12719
 
12720
                    if (my_getSmallExpression (&ep, r, s) > 0
12721
                        || !expr_const_in_range (&ep, -64, 64, 2))
12722
                      break;
12723
 
12724
                    imm = ep.X_add_number >> 2;
12725
                    INSERT_OPERAND (1, IMMA, *ip, imm);
12726
                  }
12727
                  s = expr_end;
12728
                  continue;
12729
 
12730
                case 'B':
12731
                  {
12732
                    bfd_reloc_code_real_type r[3];
12733
                    expressionS ep;
12734
                    int imm;
12735
 
12736
                    if (my_getSmallExpression (&ep, r, s) > 0
12737
                        || ep.X_op != O_constant)
12738
                      break;
12739
 
12740
                    for (imm = 0; imm < 8; imm++)
12741
                      if (micromips_imm_b_map[imm] == ep.X_add_number)
12742
                        break;
12743
                    if (imm >= 8)
12744
                      break;
12745
 
12746
                    INSERT_OPERAND (1, IMMB, *ip, imm);
12747
                  }
12748
                  s = expr_end;
12749
                  continue;
12750
 
12751
                case 'C':
12752
                  {
12753
                    bfd_reloc_code_real_type r[3];
12754
                    expressionS ep;
12755
                    int imm;
12756
 
12757
                    if (my_getSmallExpression (&ep, r, s) > 0
12758
                        || ep.X_op != O_constant)
12759
                      break;
12760
 
12761
                    for (imm = 0; imm < 16; imm++)
12762
                      if (micromips_imm_c_map[imm] == ep.X_add_number)
12763
                        break;
12764
                    if (imm >= 16)
12765
                      break;
12766
 
12767
                    INSERT_OPERAND (1, IMMC, *ip, imm);
12768
                  }
12769
                  s = expr_end;
12770
                  continue;
12771
 
12772
                case 'D':       /* pc relative offset */
12773
                case 'E':       /* pc relative offset */
12774
                  my_getExpression (&offset_expr, s);
12775
                  if (offset_expr.X_op == O_register)
12776
                    break;
12777
 
12778
                  if (!forced_insn_length)
12779
                    *offset_reloc = (int) BFD_RELOC_UNUSED + c;
12780
                  else if (c == 'D')
12781
                    *offset_reloc = BFD_RELOC_MICROMIPS_10_PCREL_S1;
12782
                  else
12783
                    *offset_reloc = BFD_RELOC_MICROMIPS_7_PCREL_S1;
12784
                  s = expr_end;
12785
                  continue;
12786
 
12787
                case 'F':
12788
                  {
12789
                    bfd_reloc_code_real_type r[3];
12790
                    expressionS ep;
12791
                    int imm;
12792
 
12793
                    if (my_getSmallExpression (&ep, r, s) > 0
12794
                        || !expr_const_in_range (&ep, 0, 16, 0))
12795
                      break;
12796
 
12797
                    imm = ep.X_add_number;
12798
                    INSERT_OPERAND (1, IMMF, *ip, imm);
12799
                  }
12800
                  s = expr_end;
12801
                  continue;
12802
 
12803
                case 'G':
12804
                  {
12805
                    bfd_reloc_code_real_type r[3];
12806
                    expressionS ep;
12807
                    int imm;
12808
 
12809
                    /* Check whether there is only a single bracketed
12810
                       expression left.  If so, it must be the base register
12811
                       and the constant must be zero.  */
12812
                    if (*s == '(' && strchr (s + 1, '(') == 0)
12813
                      {
12814
                        INSERT_OPERAND (1, IMMG, *ip, 0);
12815
                        continue;
12816
                      }
12817
 
12818
                    if (my_getSmallExpression (&ep, r, s) > 0
12819
                        || !expr_const_in_range (&ep, -1, 15, 0))
12820
                      break;
12821
 
12822
                    imm = ep.X_add_number & 15;
12823
                    INSERT_OPERAND (1, IMMG, *ip, imm);
12824
                  }
12825
                  s = expr_end;
12826
                  continue;
12827
 
12828
                case 'H':
12829
                  {
12830
                    bfd_reloc_code_real_type r[3];
12831
                    expressionS ep;
12832
                    int imm;
12833
 
12834
                    /* Check whether there is only a single bracketed
12835
                       expression left.  If so, it must be the base register
12836
                       and the constant must be zero.  */
12837
                    if (*s == '(' && strchr (s + 1, '(') == 0)
12838
                      {
12839
                        INSERT_OPERAND (1, IMMH, *ip, 0);
12840
                        continue;
12841
                      }
12842
 
12843
                    if (my_getSmallExpression (&ep, r, s) > 0
12844
                        || !expr_const_in_range (&ep, 0, 16, 1))
12845
                      break;
12846
 
12847
                    imm = ep.X_add_number >> 1;
12848
                    INSERT_OPERAND (1, IMMH, *ip, imm);
12849
                  }
12850
                  s = expr_end;
12851
                  continue;
12852
 
12853
                case 'I':
12854
                  {
12855
                    bfd_reloc_code_real_type r[3];
12856
                    expressionS ep;
12857
                    int imm;
12858
 
12859
                    if (my_getSmallExpression (&ep, r, s) > 0
12860
                        || !expr_const_in_range (&ep, -1, 127, 0))
12861
                      break;
12862
 
12863
                    imm = ep.X_add_number & 127;
12864
                    INSERT_OPERAND (1, IMMI, *ip, imm);
12865
                  }
12866
                  s = expr_end;
12867
                  continue;
12868
 
12869
                case 'J':
12870
                  {
12871
                    bfd_reloc_code_real_type r[3];
12872
                    expressionS ep;
12873
                    int imm;
12874
 
12875
                    /* Check whether there is only a single bracketed
12876
                       expression left.  If so, it must be the base register
12877
                       and the constant must be zero.  */
12878
                    if (*s == '(' && strchr (s + 1, '(') == 0)
12879
                      {
12880
                        INSERT_OPERAND (1, IMMJ, *ip, 0);
12881
                        continue;
12882
                      }
12883
 
12884
                    if (my_getSmallExpression (&ep, r, s) > 0
12885
                        || !expr_const_in_range (&ep, 0, 16, 2))
12886
                      break;
12887
 
12888
                    imm = ep.X_add_number >> 2;
12889
                    INSERT_OPERAND (1, IMMJ, *ip, imm);
12890
                  }
12891
                  s = expr_end;
12892
                  continue;
12893
 
12894
                case 'L':
12895
                  {
12896
                    bfd_reloc_code_real_type r[3];
12897
                    expressionS ep;
12898
                    int imm;
12899
 
12900
                    /* Check whether there is only a single bracketed
12901
                       expression left.  If so, it must be the base register
12902
                       and the constant must be zero.  */
12903
                    if (*s == '(' && strchr (s + 1, '(') == 0)
12904
                      {
12905
                        INSERT_OPERAND (1, IMML, *ip, 0);
12906
                        continue;
12907
                      }
12908
 
12909
                    if (my_getSmallExpression (&ep, r, s) > 0
12910
                        || !expr_const_in_range (&ep, 0, 16, 0))
12911
                      break;
12912
 
12913
                    imm = ep.X_add_number;
12914
                    INSERT_OPERAND (1, IMML, *ip, imm);
12915
                  }
12916
                  s = expr_end;
12917
                  continue;
12918
 
12919
                case 'M':
12920
                  {
12921
                    bfd_reloc_code_real_type r[3];
12922
                    expressionS ep;
12923
                    int imm;
12924
 
12925
                    if (my_getSmallExpression (&ep, r, s) > 0
12926
                        || !expr_const_in_range (&ep, 1, 9, 0))
12927
                      break;
12928
 
12929
                    imm = ep.X_add_number & 7;
12930
                    INSERT_OPERAND (1, IMMM, *ip, imm);
12931
                  }
12932
                  s = expr_end;
12933
                  continue;
12934
 
12935
                case 'N':       /* Register list for lwm and swm.  */
12936
                  {
12937
                    /* A comma-separated list of registers and/or
12938
                       dash-separated contiguous ranges including
12939
                       both ra and a set of one or more registers
12940
                       starting at s0 up to s3 which have to be
12941
                       consecutive, e.g.:
12942
 
12943
                       s0, ra
12944
                       s0, s1, ra, s2, s3
12945
                       s0-s2, ra
12946
 
12947
                       and any permutations of these.  */
12948
                    unsigned int reglist;
12949
                    int imm;
12950
 
12951
                    if (!reglist_lookup (&s, RTYPE_NUM | RTYPE_GP, &reglist))
12952
                      break;
12953
 
12954
                    if ((reglist & 0xfff1ffff) != 0x80010000)
12955
                      break;
12956
 
12957
                    reglist = (reglist >> 17) & 7;
12958
                    reglist += 1;
12959
                    if ((reglist & -reglist) != reglist)
12960
                      break;
12961
 
12962
                    imm = ffs (reglist) - 1;
12963
                    INSERT_OPERAND (1, IMMN, *ip, imm);
12964
                  }
12965
                  continue;
12966
 
12967
                case 'O':       /* sdbbp 4-bit code.  */
12968
                  {
12969
                    bfd_reloc_code_real_type r[3];
12970
                    expressionS ep;
12971
                    int imm;
12972
 
12973
                    if (my_getSmallExpression (&ep, r, s) > 0
12974
                        || !expr_const_in_range (&ep, 0, 16, 0))
12975
                      break;
12976
 
12977
                    imm = ep.X_add_number;
12978
                    INSERT_OPERAND (1, IMMO, *ip, imm);
12979
                  }
12980
                  s = expr_end;
12981
                  continue;
12982
 
12983
                case 'P':
12984
                  {
12985
                    bfd_reloc_code_real_type r[3];
12986
                    expressionS ep;
12987
                    int imm;
12988
 
12989
                    if (my_getSmallExpression (&ep, r, s) > 0
12990
                        || !expr_const_in_range (&ep, 0, 32, 2))
12991
                      break;
12992
 
12993
                    imm = ep.X_add_number >> 2;
12994
                    INSERT_OPERAND (1, IMMP, *ip, imm);
12995
                  }
12996
                  s = expr_end;
12997
                  continue;
12998
 
12999
                case 'Q':
13000
                  {
13001
                    bfd_reloc_code_real_type r[3];
13002
                    expressionS ep;
13003
                    int imm;
13004
 
13005
                    if (my_getSmallExpression (&ep, r, s) > 0
13006
                        || !expr_const_in_range (&ep, -0x400000, 0x400000, 2))
13007
                      break;
13008
 
13009
                    imm = ep.X_add_number >> 2;
13010
                    INSERT_OPERAND (1, IMMQ, *ip, imm);
13011
                  }
13012
                  s = expr_end;
13013
                  continue;
13014
 
13015
                case 'U':
13016
                  {
13017
                    bfd_reloc_code_real_type r[3];
13018
                    expressionS ep;
13019
                    int imm;
13020
 
13021
                    /* Check whether there is only a single bracketed
13022
                       expression left.  If so, it must be the base register
13023
                       and the constant must be zero.  */
13024
                    if (*s == '(' && strchr (s + 1, '(') == 0)
13025
                      {
13026
                        INSERT_OPERAND (1, IMMU, *ip, 0);
13027
                        continue;
13028
                      }
13029
 
13030
                    if (my_getSmallExpression (&ep, r, s) > 0
13031
                        || !expr_const_in_range (&ep, 0, 32, 2))
13032
                      break;
13033
 
13034
                    imm = ep.X_add_number >> 2;
13035
                    INSERT_OPERAND (1, IMMU, *ip, imm);
13036
                  }
13037
                  s = expr_end;
13038
                  continue;
13039
 
13040
                case 'W':
13041
                  {
13042
                    bfd_reloc_code_real_type r[3];
13043
                    expressionS ep;
13044
                    int imm;
13045
 
13046
                    if (my_getSmallExpression (&ep, r, s) > 0
13047
                        || !expr_const_in_range (&ep, 0, 64, 2))
13048
                      break;
13049
 
13050
                    imm = ep.X_add_number >> 2;
13051
                    INSERT_OPERAND (1, IMMW, *ip, imm);
13052
                  }
13053
                  s = expr_end;
13054
                  continue;
13055
 
13056
                case 'X':
13057
                  {
13058
                    bfd_reloc_code_real_type r[3];
13059
                    expressionS ep;
13060
                    int imm;
13061
 
13062
                    if (my_getSmallExpression (&ep, r, s) > 0
13063
                        || !expr_const_in_range (&ep, -8, 8, 0))
13064
                      break;
13065
 
13066
                    imm = ep.X_add_number;
13067
                    INSERT_OPERAND (1, IMMX, *ip, imm);
13068
                  }
13069
                  s = expr_end;
13070
                  continue;
13071
 
13072
                case 'Y':
13073
                  {
13074
                    bfd_reloc_code_real_type r[3];
13075
                    expressionS ep;
13076
                    int imm;
13077
 
13078
                    if (my_getSmallExpression (&ep, r, s) > 0
13079
                        || expr_const_in_range (&ep, -2, 2, 2)
13080
                        || !expr_const_in_range (&ep, -258, 258, 2))
13081
                      break;
13082
 
13083
                    imm = ep.X_add_number >> 2;
13084
                    imm = ((imm >> 1) & ~0xff) | (imm & 0xff);
13085
                    INSERT_OPERAND (1, IMMY, *ip, imm);
13086
                  }
13087
                  s = expr_end;
13088
                  continue;
13089
 
13090
                case 'Z':
13091
                  {
13092
                    bfd_reloc_code_real_type r[3];
13093
                    expressionS ep;
13094
 
13095
                    if (my_getSmallExpression (&ep, r, s) > 0
13096
                        || !expr_const_in_range (&ep, 0, 1, 0))
13097
                      break;
13098
                  }
13099
                  s = expr_end;
13100
                  continue;
13101
 
13102
                default:
13103
                  as_bad (_("Internal error: bad microMIPS opcode "
13104
                            "(unknown extension operand type `m%c'): %s %s"),
13105
                          *args, insn->name, insn->args);
13106
                  /* Further processing is fruitless.  */
13107
                  return;
13108
                }
13109
              break;
13110
 
13111
            case 'n':           /* Register list for 32-bit lwm and swm.  */
13112
              gas_assert (mips_opts.micromips);
13113
              {
13114
                /* A comma-separated list of registers and/or
13115
                   dash-separated contiguous ranges including
13116
                   at least one of ra and a set of one or more
13117
                   registers starting at s0 up to s7 and then
13118
                   s8 which have to be consecutive, e.g.:
13119
 
13120
                   ra
13121
                   s0
13122
                   ra, s0, s1, s2
13123
                   s0-s8
13124
                   s0-s5, ra
13125
 
13126
                   and any permutations of these.  */
13127
                unsigned int reglist;
13128
                int imm;
13129
                int ra;
13130
 
13131
                if (!reglist_lookup (&s, RTYPE_NUM | RTYPE_GP, &reglist))
13132
                  break;
13133
 
13134
                if ((reglist & 0x3f00ffff) != 0)
13135
                  break;
13136
 
13137
                ra = (reglist >> 27) & 0x10;
13138
                reglist = ((reglist >> 22) & 0x100) | ((reglist >> 16) & 0xff);
13139
                reglist += 1;
13140
                if ((reglist & -reglist) != reglist)
13141
                  break;
13142
 
13143
                imm = (ffs (reglist) - 1) | ra;
13144
                INSERT_OPERAND (1, RT, *ip, imm);
13145
                imm_expr.X_op = O_absent;
13146
              }
13147
              continue;
13148
 
13149
            case '|':           /* 4-bit trap code.  */
13150
              gas_assert (mips_opts.micromips);
13151
              my_getExpression (&imm_expr, s);
13152
              check_absolute_expr (ip, &imm_expr);
13153
              if ((unsigned long) imm_expr.X_add_number
13154
                  > MICROMIPSOP_MASK_TRAP)
13155
                as_bad (_("Trap code (%lu) for %s not in 0..15 range"),
13156
                        (unsigned long) imm_expr.X_add_number,
13157
                        ip->insn_mo->name);
13158
              INSERT_OPERAND (1, TRAP, *ip, imm_expr.X_add_number);
13159
              imm_expr.X_op = O_absent;
13160
              s = expr_end;
13161
              continue;
13162
 
13163 16 khays
            default:
13164
              as_bad (_("Bad char = '%c'\n"), *args);
13165
              internalError ();
13166
            }
13167
          break;
13168
        }
13169
      /* Args don't match.  */
13170 160 khays
      s = argsStart;
13171
      insn_error = _("Illegal operands");
13172
      if (insn + 1 < past && !strcmp (insn->name, insn[1].name))
13173 16 khays
        {
13174
          ++insn;
13175
          continue;
13176
        }
13177 160 khays
      else if (wrong_delay_slot_insns && need_delay_slot_ok)
13178
        {
13179
          gas_assert (firstinsn);
13180
          need_delay_slot_ok = FALSE;
13181
          past = insn + 1;
13182
          insn = firstinsn;
13183
          continue;
13184
        }
13185 16 khays
      return;
13186
    }
13187
}
13188
 
13189
#define SKIP_SPACE_TABS(S) { while (*(S) == ' ' || *(S) == '\t') ++(S); }
13190
 
13191
/* This routine assembles an instruction into its binary format when
13192
   assembling for the mips16.  As a side effect, it sets one of the
13193 160 khays
   global variables imm_reloc or offset_reloc to the type of relocation
13194
   to do if one of the operands is an address expression.  It also sets
13195
   forced_insn_length to the resulting instruction size in bytes if the
13196
   user explicitly requested a small or extended instruction.  */
13197 16 khays
 
13198
static void
13199
mips16_ip (char *str, struct mips_cl_insn *ip)
13200
{
13201
  char *s;
13202
  const char *args;
13203
  struct mips_opcode *insn;
13204
  char *argsstart;
13205
  unsigned int regno;
13206
  unsigned int lastregno = 0;
13207
  char *s_reset;
13208
  size_t i;
13209
 
13210
  insn_error = NULL;
13211
 
13212 160 khays
  forced_insn_length = 0;
13213 16 khays
 
13214
  for (s = str; ISLOWER (*s); ++s)
13215
    ;
13216
  switch (*s)
13217
    {
13218
    case '\0':
13219
      break;
13220
 
13221
    case ' ':
13222
      *s++ = '\0';
13223
      break;
13224
 
13225
    case '.':
13226
      if (s[1] == 't' && s[2] == ' ')
13227
        {
13228
          *s = '\0';
13229 160 khays
          forced_insn_length = 2;
13230 16 khays
          s += 3;
13231
          break;
13232
        }
13233
      else if (s[1] == 'e' && s[2] == ' ')
13234
        {
13235
          *s = '\0';
13236 160 khays
          forced_insn_length = 4;
13237 16 khays
          s += 3;
13238
          break;
13239
        }
13240
      /* Fall through.  */
13241
    default:
13242
      insn_error = _("unknown opcode");
13243
      return;
13244
    }
13245
 
13246 160 khays
  if (mips_opts.noautoextend && !forced_insn_length)
13247
    forced_insn_length = 2;
13248 16 khays
 
13249
  if ((insn = (struct mips_opcode *) hash_find (mips16_op_hash, str)) == NULL)
13250
    {
13251
      insn_error = _("unrecognized opcode");
13252
      return;
13253
    }
13254
 
13255
  argsstart = s;
13256
  for (;;)
13257
    {
13258
      bfd_boolean ok;
13259
 
13260
      gas_assert (strcmp (insn->name, str) == 0);
13261
 
13262
      ok = is_opcode_valid_16 (insn);
13263
      if (! ok)
13264
        {
13265
          if (insn + 1 < &mips16_opcodes[bfd_mips16_num_opcodes]
13266
              && strcmp (insn->name, insn[1].name) == 0)
13267
            {
13268
              ++insn;
13269
              continue;
13270
            }
13271
          else
13272
            {
13273
              if (!insn_error)
13274
                {
13275
                  static char buf[100];
13276
                  sprintf (buf,
13277 166 khays
                           _("Opcode not supported on this processor: %s (%s)"),
13278 16 khays
                           mips_cpu_info_from_arch (mips_opts.arch)->name,
13279
                           mips_cpu_info_from_isa (mips_opts.isa)->name);
13280
                  insn_error = buf;
13281
                }
13282
              return;
13283
            }
13284
        }
13285
 
13286
      create_insn (ip, insn);
13287
      imm_expr.X_op = O_absent;
13288
      imm_reloc[0] = BFD_RELOC_UNUSED;
13289
      imm_reloc[1] = BFD_RELOC_UNUSED;
13290
      imm_reloc[2] = BFD_RELOC_UNUSED;
13291
      imm2_expr.X_op = O_absent;
13292
      offset_expr.X_op = O_absent;
13293
      offset_reloc[0] = BFD_RELOC_UNUSED;
13294
      offset_reloc[1] = BFD_RELOC_UNUSED;
13295
      offset_reloc[2] = BFD_RELOC_UNUSED;
13296
      for (args = insn->args; 1; ++args)
13297
        {
13298
          int c;
13299
 
13300
          if (*s == ' ')
13301
            ++s;
13302
 
13303
          /* In this switch statement we call break if we did not find
13304
             a match, continue if we did find a match, or return if we
13305
             are done.  */
13306
 
13307
          c = *args;
13308
          switch (c)
13309
            {
13310
            case '\0':
13311
              if (*s == '\0')
13312
                {
13313
                  /* Stuff the immediate value in now, if we can.  */
13314
                  if (imm_expr.X_op == O_constant
13315
                      && *imm_reloc > BFD_RELOC_UNUSED
13316
                      && *imm_reloc != BFD_RELOC_MIPS16_GOT16
13317
                      && *imm_reloc != BFD_RELOC_MIPS16_CALL16
13318
                      && insn->pinfo != INSN_MACRO)
13319
                    {
13320
                      valueT tmp;
13321
 
13322
                      switch (*offset_reloc)
13323
                        {
13324
                          case BFD_RELOC_MIPS16_HI16_S:
13325
                            tmp = (imm_expr.X_add_number + 0x8000) >> 16;
13326
                            break;
13327
 
13328
                          case BFD_RELOC_MIPS16_HI16:
13329
                            tmp = imm_expr.X_add_number >> 16;
13330
                            break;
13331
 
13332
                          case BFD_RELOC_MIPS16_LO16:
13333
                            tmp = ((imm_expr.X_add_number + 0x8000) & 0xffff)
13334
                                  - 0x8000;
13335
                            break;
13336
 
13337
                          case BFD_RELOC_UNUSED:
13338
                            tmp = imm_expr.X_add_number;
13339
                            break;
13340
 
13341
                          default:
13342
                            internalError ();
13343
                        }
13344
                      *offset_reloc = BFD_RELOC_UNUSED;
13345
 
13346
                      mips16_immed (NULL, 0, *imm_reloc - BFD_RELOC_UNUSED,
13347 160 khays
                                    tmp, TRUE, forced_insn_length == 2,
13348
                                    forced_insn_length == 4, &ip->insn_opcode,
13349 16 khays
                                    &ip->use_extend, &ip->extend);
13350
                      imm_expr.X_op = O_absent;
13351
                      *imm_reloc = BFD_RELOC_UNUSED;
13352
                    }
13353
 
13354
                  return;
13355
                }
13356
              break;
13357
 
13358
            case ',':
13359
              if (*s++ == c)
13360
                continue;
13361
              s--;
13362
              switch (*++args)
13363
                {
13364
                case 'v':
13365
                  MIPS16_INSERT_OPERAND (RX, *ip, lastregno);
13366
                  continue;
13367
                case 'w':
13368
                  MIPS16_INSERT_OPERAND (RY, *ip, lastregno);
13369
                  continue;
13370
                }
13371
              break;
13372
 
13373
            case '(':
13374
            case ')':
13375
              if (*s++ == c)
13376
                continue;
13377
              break;
13378
 
13379
            case 'v':
13380
            case 'w':
13381
              if (s[0] != '$')
13382
                {
13383
                  if (c == 'v')
13384
                    MIPS16_INSERT_OPERAND (RX, *ip, lastregno);
13385
                  else
13386
                    MIPS16_INSERT_OPERAND (RY, *ip, lastregno);
13387
                  ++args;
13388
                  continue;
13389
                }
13390
              /* Fall through.  */
13391
            case 'x':
13392
            case 'y':
13393
            case 'z':
13394
            case 'Z':
13395
            case '0':
13396
            case 'S':
13397
            case 'R':
13398
            case 'X':
13399
            case 'Y':
13400
              s_reset = s;
13401
              if (!reg_lookup (&s, RTYPE_NUM | RTYPE_GP, &regno))
13402
                {
13403
                  if (c == 'v' || c == 'w')
13404
                    {
13405
                      if (c == 'v')
13406
                        MIPS16_INSERT_OPERAND (RX, *ip, lastregno);
13407
                      else
13408
                        MIPS16_INSERT_OPERAND (RY, *ip, lastregno);
13409
                      ++args;
13410
                      continue;
13411
                    }
13412
                  break;
13413
                }
13414
 
13415
              if (*s == ' ')
13416
                ++s;
13417
              if (args[1] != *s)
13418
                {
13419
                  if (c == 'v' || c == 'w')
13420
                    {
13421
                      regno = mips16_to_32_reg_map[lastregno];
13422
                      s = s_reset;
13423
                      ++args;
13424
                    }
13425
                }
13426
 
13427
              switch (c)
13428
                {
13429
                case 'x':
13430
                case 'y':
13431
                case 'z':
13432
                case 'v':
13433
                case 'w':
13434
                case 'Z':
13435
                  regno = mips32_to_16_reg_map[regno];
13436
                  break;
13437
 
13438
                case '0':
13439
                  if (regno != 0)
13440
                    regno = ILLEGAL_REG;
13441
                  break;
13442
 
13443
                case 'S':
13444
                  if (regno != SP)
13445
                    regno = ILLEGAL_REG;
13446
                  break;
13447
 
13448
                case 'R':
13449
                  if (regno != RA)
13450
                    regno = ILLEGAL_REG;
13451
                  break;
13452
 
13453
                case 'X':
13454
                case 'Y':
13455
                  if (regno == AT && mips_opts.at)
13456
                    {
13457
                      if (mips_opts.at == ATREG)
13458
                        as_warn (_("used $at without \".set noat\""));
13459
                      else
13460
                        as_warn (_("used $%u with \".set at=$%u\""),
13461
                                 regno, mips_opts.at);
13462
                    }
13463
                  break;
13464
 
13465
                default:
13466
                  internalError ();
13467
                }
13468
 
13469
              if (regno == ILLEGAL_REG)
13470
                break;
13471
 
13472
              switch (c)
13473
                {
13474
                case 'x':
13475
                case 'v':
13476
                  MIPS16_INSERT_OPERAND (RX, *ip, regno);
13477
                  break;
13478
                case 'y':
13479
                case 'w':
13480
                  MIPS16_INSERT_OPERAND (RY, *ip, regno);
13481
                  break;
13482
                case 'z':
13483
                  MIPS16_INSERT_OPERAND (RZ, *ip, regno);
13484
                  break;
13485
                case 'Z':
13486
                  MIPS16_INSERT_OPERAND (MOVE32Z, *ip, regno);
13487
                case '0':
13488
                case 'S':
13489
                case 'R':
13490
                  break;
13491
                case 'X':
13492
                  MIPS16_INSERT_OPERAND (REGR32, *ip, regno);
13493
                  break;
13494
                case 'Y':
13495
                  regno = ((regno & 7) << 2) | ((regno & 0x18) >> 3);
13496
                  MIPS16_INSERT_OPERAND (REG32R, *ip, regno);
13497
                  break;
13498
                default:
13499
                  internalError ();
13500
                }
13501
 
13502
              lastregno = regno;
13503
              continue;
13504
 
13505
            case 'P':
13506
              if (strncmp (s, "$pc", 3) == 0)
13507
                {
13508
                  s += 3;
13509
                  continue;
13510
                }
13511
              break;
13512
 
13513
            case '5':
13514
            case 'H':
13515
            case 'W':
13516
            case 'D':
13517
            case 'j':
13518
            case 'V':
13519
            case 'C':
13520
            case 'U':
13521
            case 'k':
13522
            case 'K':
13523
              i = my_getSmallExpression (&imm_expr, imm_reloc, s);
13524
              if (i > 0)
13525
                {
13526
                  if (imm_expr.X_op != O_constant)
13527
                    {
13528 160 khays
                      forced_insn_length = 4;
13529 16 khays
                      ip->use_extend = TRUE;
13530
                      ip->extend = 0;
13531
                    }
13532
                  else
13533
                    {
13534
                      /* We need to relax this instruction.  */
13535
                      *offset_reloc = *imm_reloc;
13536
                      *imm_reloc = (int) BFD_RELOC_UNUSED + c;
13537
                    }
13538
                  s = expr_end;
13539
                  continue;
13540
                }
13541
              *imm_reloc = BFD_RELOC_UNUSED;
13542
              /* Fall through.  */
13543
            case '<':
13544
            case '>':
13545
            case '[':
13546
            case ']':
13547
            case '4':
13548
            case '8':
13549
              my_getExpression (&imm_expr, s);
13550
              if (imm_expr.X_op == O_register)
13551
                {
13552
                  /* What we thought was an expression turned out to
13553
                     be a register.  */
13554
 
13555
                  if (s[0] == '(' && args[1] == '(')
13556
                    {
13557
                      /* It looks like the expression was omitted
13558
                         before a register indirection, which means
13559
                         that the expression is implicitly zero.  We
13560
                         still set up imm_expr, so that we handle
13561
                         explicit extensions correctly.  */
13562
                      imm_expr.X_op = O_constant;
13563
                      imm_expr.X_add_number = 0;
13564
                      *imm_reloc = (int) BFD_RELOC_UNUSED + c;
13565
                      continue;
13566
                    }
13567
 
13568
                  break;
13569
                }
13570
 
13571
              /* We need to relax this instruction.  */
13572
              *imm_reloc = (int) BFD_RELOC_UNUSED + c;
13573
              s = expr_end;
13574
              continue;
13575
 
13576
            case 'p':
13577
            case 'q':
13578
            case 'A':
13579
            case 'B':
13580
            case 'E':
13581
              /* We use offset_reloc rather than imm_reloc for the PC
13582
                 relative operands.  This lets macros with both
13583
                 immediate and address operands work correctly.  */
13584
              my_getExpression (&offset_expr, s);
13585
 
13586
              if (offset_expr.X_op == O_register)
13587
                break;
13588
 
13589
              /* We need to relax this instruction.  */
13590
              *offset_reloc = (int) BFD_RELOC_UNUSED + c;
13591
              s = expr_end;
13592
              continue;
13593
 
13594
            case '6':           /* break code */
13595
              my_getExpression (&imm_expr, s);
13596
              check_absolute_expr (ip, &imm_expr);
13597
              if ((unsigned long) imm_expr.X_add_number > 63)
13598
                as_warn (_("Invalid value for `%s' (%lu)"),
13599
                         ip->insn_mo->name,
13600
                         (unsigned long) imm_expr.X_add_number);
13601
              MIPS16_INSERT_OPERAND (IMM6, *ip, imm_expr.X_add_number);
13602
              imm_expr.X_op = O_absent;
13603
              s = expr_end;
13604
              continue;
13605
 
13606
            case 'a':           /* 26 bit address */
13607
              my_getExpression (&offset_expr, s);
13608
              s = expr_end;
13609
              *offset_reloc = BFD_RELOC_MIPS16_JMP;
13610
              ip->insn_opcode <<= 16;
13611
              continue;
13612
 
13613
            case 'l':           /* register list for entry macro */
13614
            case 'L':           /* register list for exit macro */
13615
              {
13616
                int mask;
13617
 
13618
                if (c == 'l')
13619
                  mask = 0;
13620
                else
13621
                  mask = 7 << 3;
13622
                while (*s != '\0')
13623
                  {
13624
                    unsigned int freg, reg1, reg2;
13625
 
13626
                    while (*s == ' ' || *s == ',')
13627
                      ++s;
13628
                    if (reg_lookup (&s, RTYPE_GP | RTYPE_NUM, &reg1))
13629
                      freg = 0;
13630
                    else if (reg_lookup (&s, RTYPE_FPU, &reg1))
13631
                      freg = 1;
13632
                    else
13633
                      {
13634
                        as_bad (_("can't parse register list"));
13635
                        break;
13636
                      }
13637
                    if (*s == ' ')
13638
                      ++s;
13639
                    if (*s != '-')
13640
                      reg2 = reg1;
13641
                    else
13642
                      {
13643
                        ++s;
13644
                        if (!reg_lookup (&s, freg ? RTYPE_FPU
13645
                                         : (RTYPE_GP | RTYPE_NUM), &reg2))
13646
                          {
13647
                            as_bad (_("invalid register list"));
13648
                            break;
13649
                          }
13650
                      }
13651
                    if (freg && reg1 == 0 && reg2 == 0 && c == 'L')
13652
                      {
13653
                        mask &= ~ (7 << 3);
13654
                        mask |= 5 << 3;
13655
                      }
13656
                    else if (freg && reg1 == 0 && reg2 == 1 && c == 'L')
13657
                      {
13658
                        mask &= ~ (7 << 3);
13659
                        mask |= 6 << 3;
13660
                      }
13661
                    else if (reg1 == 4 && reg2 >= 4 && reg2 <= 7 && c != 'L')
13662
                      mask |= (reg2 - 3) << 3;
13663
                    else if (reg1 == 16 && reg2 >= 16 && reg2 <= 17)
13664
                      mask |= (reg2 - 15) << 1;
13665
                    else if (reg1 == RA && reg2 == RA)
13666
                      mask |= 1;
13667
                    else
13668
                      {
13669
                        as_bad (_("invalid register list"));
13670
                        break;
13671
                      }
13672
                  }
13673
                /* The mask is filled in in the opcode table for the
13674
                   benefit of the disassembler.  We remove it before
13675
                   applying the actual mask.  */
13676
                ip->insn_opcode &= ~ ((7 << 3) << MIPS16OP_SH_IMM6);
13677
                ip->insn_opcode |= mask << MIPS16OP_SH_IMM6;
13678
              }
13679
            continue;
13680
 
13681
            case 'm':           /* Register list for save insn.  */
13682
            case 'M':           /* Register list for restore insn.  */
13683
              {
13684
                int opcode = 0;
13685
                int framesz = 0, seen_framesz = 0;
13686
                int nargs = 0, statics = 0, sregs = 0;
13687
 
13688
                while (*s != '\0')
13689
                  {
13690
                    unsigned int reg1, reg2;
13691
 
13692
                    SKIP_SPACE_TABS (s);
13693
                    while (*s == ',')
13694
                      ++s;
13695
                    SKIP_SPACE_TABS (s);
13696
 
13697
                    my_getExpression (&imm_expr, s);
13698
                    if (imm_expr.X_op == O_constant)
13699
                      {
13700
                        /* Handle the frame size.  */
13701
                        if (seen_framesz)
13702
                          {
13703
                            as_bad (_("more than one frame size in list"));
13704
                            break;
13705
                          }
13706
                        seen_framesz = 1;
13707
                        framesz = imm_expr.X_add_number;
13708
                        imm_expr.X_op = O_absent;
13709
                        s = expr_end;
13710
                        continue;
13711
                      }
13712
 
13713
                    if (! reg_lookup (&s, RTYPE_GP | RTYPE_NUM, &reg1))
13714
                      {
13715
                        as_bad (_("can't parse register list"));
13716
                        break;
13717
                      }
13718
 
13719
                    while (*s == ' ')
13720
                      ++s;
13721
 
13722
                    if (*s != '-')
13723
                      reg2 = reg1;
13724
                    else
13725
                      {
13726
                        ++s;
13727
                        if (! reg_lookup (&s, RTYPE_GP | RTYPE_NUM, &reg2)
13728
                            || reg2 < reg1)
13729
                          {
13730
                            as_bad (_("can't parse register list"));
13731
                            break;
13732
                          }
13733
                      }
13734
 
13735
                    while (reg1 <= reg2)
13736
                      {
13737
                        if (reg1 >= 4 && reg1 <= 7)
13738
                          {
13739
                            if (!seen_framesz)
13740
                                /* args $a0-$a3 */
13741
                                nargs |= 1 << (reg1 - 4);
13742
                            else
13743
                                /* statics $a0-$a3 */
13744
                                statics |= 1 << (reg1 - 4);
13745
                          }
13746
                        else if ((reg1 >= 16 && reg1 <= 23) || reg1 == 30)
13747
                          {
13748
                            /* $s0-$s8 */
13749
                            sregs |= 1 << ((reg1 == 30) ? 8 : (reg1 - 16));
13750
                          }
13751
                        else if (reg1 == 31)
13752
                          {
13753
                            /* Add $ra to insn.  */
13754
                            opcode |= 0x40;
13755
                          }
13756
                        else
13757
                          {
13758
                            as_bad (_("unexpected register in list"));
13759
                            break;
13760
                          }
13761
                        if (++reg1 == 24)
13762
                          reg1 = 30;
13763
                      }
13764
                  }
13765
 
13766
                /* Encode args/statics combination.  */
13767
                if (nargs & statics)
13768
                  as_bad (_("arg/static registers overlap"));
13769
                else if (nargs == 0xf)
13770
                  /* All $a0-$a3 are args.  */
13771
                  opcode |= MIPS16_ALL_ARGS << 16;
13772
                else if (statics == 0xf)
13773
                  /* All $a0-$a3 are statics.  */
13774
                  opcode |= MIPS16_ALL_STATICS << 16;
13775
                else
13776
                  {
13777
                    int narg = 0, nstat = 0;
13778
 
13779
                    /* Count arg registers.  */
13780
                    while (nargs & 0x1)
13781
                      {
13782
                        nargs >>= 1;
13783
                        narg++;
13784
                      }
13785
                    if (nargs != 0)
13786
                      as_bad (_("invalid arg register list"));
13787
 
13788
                    /* Count static registers.  */
13789
                    while (statics & 0x8)
13790
                      {
13791
                        statics = (statics << 1) & 0xf;
13792
                        nstat++;
13793
                      }
13794
                    if (statics != 0)
13795
                      as_bad (_("invalid static register list"));
13796
 
13797
                    /* Encode args/statics.  */
13798
                    opcode |= ((narg << 2) | nstat) << 16;
13799
                  }
13800
 
13801
                /* Encode $s0/$s1.  */
13802
                if (sregs & (1 << 0))            /* $s0 */
13803
                  opcode |= 0x20;
13804
                if (sregs & (1 << 1))           /* $s1 */
13805
                  opcode |= 0x10;
13806
                sregs >>= 2;
13807
 
13808
                if (sregs != 0)
13809
                  {
13810
                    /* Count regs $s2-$s8.  */
13811
                    int nsreg = 0;
13812
                    while (sregs & 1)
13813
                      {
13814
                        sregs >>= 1;
13815
                        nsreg++;
13816
                      }
13817
                    if (sregs != 0)
13818
                      as_bad (_("invalid static register list"));
13819
                    /* Encode $s2-$s8. */
13820
                    opcode |= nsreg << 24;
13821
                  }
13822
 
13823
                /* Encode frame size.  */
13824
                if (!seen_framesz)
13825
                  as_bad (_("missing frame size"));
13826
                else if ((framesz & 7) != 0 || framesz < 0
13827
                         || framesz > 0xff * 8)
13828
                  as_bad (_("invalid frame size"));
13829
                else if (framesz != 128 || (opcode >> 16) != 0)
13830
                  {
13831
                    framesz /= 8;
13832
                    opcode |= (((framesz & 0xf0) << 16)
13833
                             | (framesz & 0x0f));
13834
                  }
13835
 
13836
                /* Finally build the instruction.  */
13837
                if ((opcode >> 16) != 0 || framesz == 0)
13838
                  {
13839
                    ip->use_extend = TRUE;
13840
                    ip->extend = opcode >> 16;
13841
                  }
13842
                ip->insn_opcode |= opcode & 0x7f;
13843
              }
13844
            continue;
13845
 
13846
            case 'e':           /* extend code */
13847
              my_getExpression (&imm_expr, s);
13848
              check_absolute_expr (ip, &imm_expr);
13849
              if ((unsigned long) imm_expr.X_add_number > 0x7ff)
13850
                {
13851
                  as_warn (_("Invalid value for `%s' (%lu)"),
13852
                           ip->insn_mo->name,
13853
                           (unsigned long) imm_expr.X_add_number);
13854
                  imm_expr.X_add_number &= 0x7ff;
13855
                }
13856
              ip->insn_opcode |= imm_expr.X_add_number;
13857
              imm_expr.X_op = O_absent;
13858
              s = expr_end;
13859
              continue;
13860
 
13861
            default:
13862
              internalError ();
13863
            }
13864
          break;
13865
        }
13866
 
13867
      /* Args don't match.  */
13868
      if (insn + 1 < &mips16_opcodes[bfd_mips16_num_opcodes] &&
13869
          strcmp (insn->name, insn[1].name) == 0)
13870
        {
13871
          ++insn;
13872
          s = argsstart;
13873
          continue;
13874
        }
13875
 
13876
      insn_error = _("illegal operands");
13877
 
13878
      return;
13879
    }
13880
}
13881
 
13882
/* This structure holds information we know about a mips16 immediate
13883
   argument type.  */
13884
 
13885
struct mips16_immed_operand
13886
{
13887
  /* The type code used in the argument string in the opcode table.  */
13888
  int type;
13889
  /* The number of bits in the short form of the opcode.  */
13890
  int nbits;
13891
  /* The number of bits in the extended form of the opcode.  */
13892
  int extbits;
13893
  /* The amount by which the short form is shifted when it is used;
13894
     for example, the sw instruction has a shift count of 2.  */
13895
  int shift;
13896
  /* The amount by which the short form is shifted when it is stored
13897
     into the instruction code.  */
13898
  int op_shift;
13899
  /* Non-zero if the short form is unsigned.  */
13900
  int unsp;
13901
  /* Non-zero if the extended form is unsigned.  */
13902
  int extu;
13903
  /* Non-zero if the value is PC relative.  */
13904
  int pcrel;
13905
};
13906
 
13907
/* The mips16 immediate operand types.  */
13908
 
13909
static const struct mips16_immed_operand mips16_immed_operands[] =
13910
{
13911
  { '<',  3,  5, 0, MIPS16OP_SH_RZ,   1, 1, 0 },
13912
  { '>',  3,  5, 0, MIPS16OP_SH_RX,   1, 1, 0 },
13913
  { '[',  3,  6, 0, MIPS16OP_SH_RZ,   1, 1, 0 },
13914
  { ']',  3,  6, 0, MIPS16OP_SH_RX,   1, 1, 0 },
13915
  { '4',  4, 15, 0, MIPS16OP_SH_IMM4, 0, 0, 0 },
13916
  { '5',  5, 16, 0, MIPS16OP_SH_IMM5, 1, 0, 0 },
13917
  { 'H',  5, 16, 1, MIPS16OP_SH_IMM5, 1, 0, 0 },
13918
  { 'W',  5, 16, 2, MIPS16OP_SH_IMM5, 1, 0, 0 },
13919
  { 'D',  5, 16, 3, MIPS16OP_SH_IMM5, 1, 0, 0 },
13920
  { 'j',  5, 16, 0, MIPS16OP_SH_IMM5, 0, 0, 0 },
13921
  { '8',  8, 16, 0, MIPS16OP_SH_IMM8, 1, 0, 0 },
13922
  { 'V',  8, 16, 2, MIPS16OP_SH_IMM8, 1, 0, 0 },
13923
  { 'C',  8, 16, 3, MIPS16OP_SH_IMM8, 1, 0, 0 },
13924
  { 'U',  8, 16, 0, MIPS16OP_SH_IMM8, 1, 1, 0 },
13925
  { 'k',  8, 16, 0, MIPS16OP_SH_IMM8, 0, 0, 0 },
13926
  { 'K',  8, 16, 3, MIPS16OP_SH_IMM8, 0, 0, 0 },
13927
  { 'p',  8, 16, 0, MIPS16OP_SH_IMM8, 0, 0, 1 },
13928
  { 'q', 11, 16, 0, MIPS16OP_SH_IMM8, 0, 0, 1 },
13929
  { 'A',  8, 16, 2, MIPS16OP_SH_IMM8, 1, 0, 1 },
13930
  { 'B',  5, 16, 3, MIPS16OP_SH_IMM5, 1, 0, 1 },
13931
  { 'E',  5, 16, 2, MIPS16OP_SH_IMM5, 1, 0, 1 }
13932
};
13933
 
13934
#define MIPS16_NUM_IMMED \
13935
  (sizeof mips16_immed_operands / sizeof mips16_immed_operands[0])
13936
 
13937
/* Handle a mips16 instruction with an immediate value.  This or's the
13938
   small immediate value into *INSN.  It sets *USE_EXTEND to indicate
13939
   whether an extended value is needed; if one is needed, it sets
13940
   *EXTEND to the value.  The argument type is TYPE.  The value is VAL.
13941
   If SMALL is true, an unextended opcode was explicitly requested.
13942
   If EXT is true, an extended opcode was explicitly requested.  If
13943
   WARN is true, warn if EXT does not match reality.  */
13944
 
13945
static void
13946
mips16_immed (char *file, unsigned int line, int type, offsetT val,
13947
              bfd_boolean warn, bfd_boolean small, bfd_boolean ext,
13948
              unsigned long *insn, bfd_boolean *use_extend,
13949
              unsigned short *extend)
13950
{
13951
  const struct mips16_immed_operand *op;
13952
  int mintiny, maxtiny;
13953
  bfd_boolean needext;
13954
 
13955
  op = mips16_immed_operands;
13956
  while (op->type != type)
13957
    {
13958
      ++op;
13959
      gas_assert (op < mips16_immed_operands + MIPS16_NUM_IMMED);
13960
    }
13961
 
13962
  if (op->unsp)
13963
    {
13964
      if (type == '<' || type == '>' || type == '[' || type == ']')
13965
        {
13966
          mintiny = 1;
13967
          maxtiny = 1 << op->nbits;
13968
        }
13969
      else
13970
        {
13971
          mintiny = 0;
13972
          maxtiny = (1 << op->nbits) - 1;
13973
        }
13974
    }
13975
  else
13976
    {
13977
      mintiny = - (1 << (op->nbits - 1));
13978
      maxtiny = (1 << (op->nbits - 1)) - 1;
13979
    }
13980
 
13981
  /* Branch offsets have an implicit 0 in the lowest bit.  */
13982
  if (type == 'p' || type == 'q')
13983
    val /= 2;
13984
 
13985
  if ((val & ((1 << op->shift) - 1)) != 0
13986
      || val < (mintiny << op->shift)
13987
      || val > (maxtiny << op->shift))
13988
    needext = TRUE;
13989
  else
13990
    needext = FALSE;
13991
 
13992
  if (warn && ext && ! needext)
13993
    as_warn_where (file, line,
13994
                   _("extended operand requested but not required"));
13995
  if (small && needext)
13996
    as_bad_where (file, line, _("invalid unextended operand value"));
13997
 
13998
  if (small || (! ext && ! needext))
13999
    {
14000
      int insnval;
14001
 
14002
      *use_extend = FALSE;
14003
      insnval = ((val >> op->shift) & ((1 << op->nbits) - 1));
14004
      insnval <<= op->op_shift;
14005
      *insn |= insnval;
14006
    }
14007
  else
14008
    {
14009
      long minext, maxext;
14010
      int extval;
14011
 
14012
      if (op->extu)
14013
        {
14014
          minext = 0;
14015
          maxext = (1 << op->extbits) - 1;
14016
        }
14017
      else
14018
        {
14019
          minext = - (1 << (op->extbits - 1));
14020
          maxext = (1 << (op->extbits - 1)) - 1;
14021
        }
14022
      if (val < minext || val > maxext)
14023
        as_bad_where (file, line,
14024
                      _("operand value out of range for instruction"));
14025
 
14026
      *use_extend = TRUE;
14027
      if (op->extbits == 16)
14028
        {
14029
          extval = ((val >> 11) & 0x1f) | (val & 0x7e0);
14030
          val &= 0x1f;
14031
        }
14032
      else if (op->extbits == 15)
14033
        {
14034
          extval = ((val >> 11) & 0xf) | (val & 0x7f0);
14035
          val &= 0xf;
14036
        }
14037
      else
14038
        {
14039
          extval = ((val & 0x1f) << 6) | (val & 0x20);
14040
          val = 0;
14041
        }
14042
 
14043
      *extend = (unsigned short) extval;
14044
      *insn |= val;
14045
    }
14046
}
14047
 
14048
struct percent_op_match
14049
{
14050
  const char *str;
14051
  bfd_reloc_code_real_type reloc;
14052
};
14053
 
14054
static const struct percent_op_match mips_percent_op[] =
14055
{
14056
  {"%lo", BFD_RELOC_LO16},
14057
#ifdef OBJ_ELF
14058
  {"%call_hi", BFD_RELOC_MIPS_CALL_HI16},
14059
  {"%call_lo", BFD_RELOC_MIPS_CALL_LO16},
14060
  {"%call16", BFD_RELOC_MIPS_CALL16},
14061
  {"%got_disp", BFD_RELOC_MIPS_GOT_DISP},
14062
  {"%got_page", BFD_RELOC_MIPS_GOT_PAGE},
14063
  {"%got_ofst", BFD_RELOC_MIPS_GOT_OFST},
14064
  {"%got_hi", BFD_RELOC_MIPS_GOT_HI16},
14065
  {"%got_lo", BFD_RELOC_MIPS_GOT_LO16},
14066
  {"%got", BFD_RELOC_MIPS_GOT16},
14067
  {"%gp_rel", BFD_RELOC_GPREL16},
14068
  {"%half", BFD_RELOC_16},
14069
  {"%highest", BFD_RELOC_MIPS_HIGHEST},
14070
  {"%higher", BFD_RELOC_MIPS_HIGHER},
14071
  {"%neg", BFD_RELOC_MIPS_SUB},
14072
  {"%tlsgd", BFD_RELOC_MIPS_TLS_GD},
14073
  {"%tlsldm", BFD_RELOC_MIPS_TLS_LDM},
14074
  {"%dtprel_hi", BFD_RELOC_MIPS_TLS_DTPREL_HI16},
14075
  {"%dtprel_lo", BFD_RELOC_MIPS_TLS_DTPREL_LO16},
14076
  {"%tprel_hi", BFD_RELOC_MIPS_TLS_TPREL_HI16},
14077
  {"%tprel_lo", BFD_RELOC_MIPS_TLS_TPREL_LO16},
14078
  {"%gottprel", BFD_RELOC_MIPS_TLS_GOTTPREL},
14079
#endif
14080
  {"%hi", BFD_RELOC_HI16_S}
14081
};
14082
 
14083
static const struct percent_op_match mips16_percent_op[] =
14084
{
14085
  {"%lo", BFD_RELOC_MIPS16_LO16},
14086
  {"%gprel", BFD_RELOC_MIPS16_GPREL},
14087
  {"%got", BFD_RELOC_MIPS16_GOT16},
14088
  {"%call16", BFD_RELOC_MIPS16_CALL16},
14089 166 khays
  {"%hi", BFD_RELOC_MIPS16_HI16_S},
14090
  {"%tlsgd", BFD_RELOC_MIPS16_TLS_GD},
14091
  {"%tlsldm", BFD_RELOC_MIPS16_TLS_LDM},
14092
  {"%dtprel_hi", BFD_RELOC_MIPS16_TLS_DTPREL_HI16},
14093
  {"%dtprel_lo", BFD_RELOC_MIPS16_TLS_DTPREL_LO16},
14094
  {"%tprel_hi", BFD_RELOC_MIPS16_TLS_TPREL_HI16},
14095
  {"%tprel_lo", BFD_RELOC_MIPS16_TLS_TPREL_LO16},
14096
  {"%gottprel", BFD_RELOC_MIPS16_TLS_GOTTPREL}
14097 16 khays
};
14098
 
14099
 
14100
/* Return true if *STR points to a relocation operator.  When returning true,
14101
   move *STR over the operator and store its relocation code in *RELOC.
14102
   Leave both *STR and *RELOC alone when returning false.  */
14103
 
14104
static bfd_boolean
14105
parse_relocation (char **str, bfd_reloc_code_real_type *reloc)
14106
{
14107
  const struct percent_op_match *percent_op;
14108
  size_t limit, i;
14109
 
14110
  if (mips_opts.mips16)
14111
    {
14112
      percent_op = mips16_percent_op;
14113
      limit = ARRAY_SIZE (mips16_percent_op);
14114
    }
14115
  else
14116
    {
14117
      percent_op = mips_percent_op;
14118
      limit = ARRAY_SIZE (mips_percent_op);
14119
    }
14120
 
14121
  for (i = 0; i < limit; i++)
14122
    if (strncasecmp (*str, percent_op[i].str, strlen (percent_op[i].str)) == 0)
14123
      {
14124
        int len = strlen (percent_op[i].str);
14125
 
14126
        if (!ISSPACE ((*str)[len]) && (*str)[len] != '(')
14127
          continue;
14128
 
14129
        *str += strlen (percent_op[i].str);
14130
        *reloc = percent_op[i].reloc;
14131
 
14132
        /* Check whether the output BFD supports this relocation.
14133
           If not, issue an error and fall back on something safe.  */
14134
        if (!bfd_reloc_type_lookup (stdoutput, percent_op[i].reloc))
14135
          {
14136
            as_bad (_("relocation %s isn't supported by the current ABI"),
14137
                    percent_op[i].str);
14138
            *reloc = BFD_RELOC_UNUSED;
14139
          }
14140
        return TRUE;
14141
      }
14142
  return FALSE;
14143
}
14144
 
14145
 
14146
/* Parse string STR as a 16-bit relocatable operand.  Store the
14147
   expression in *EP and the relocations in the array starting
14148
   at RELOC.  Return the number of relocation operators used.
14149
 
14150
   On exit, EXPR_END points to the first character after the expression.  */
14151
 
14152
static size_t
14153
my_getSmallExpression (expressionS *ep, bfd_reloc_code_real_type *reloc,
14154
                       char *str)
14155
{
14156
  bfd_reloc_code_real_type reversed_reloc[3];
14157
  size_t reloc_index, i;
14158
  int crux_depth, str_depth;
14159
  char *crux;
14160
 
14161
  /* Search for the start of the main expression, recoding relocations
14162
     in REVERSED_RELOC.  End the loop with CRUX pointing to the start
14163
     of the main expression and with CRUX_DEPTH containing the number
14164
     of open brackets at that point.  */
14165
  reloc_index = -1;
14166
  str_depth = 0;
14167
  do
14168
    {
14169
      reloc_index++;
14170
      crux = str;
14171
      crux_depth = str_depth;
14172
 
14173
      /* Skip over whitespace and brackets, keeping count of the number
14174
         of brackets.  */
14175
      while (*str == ' ' || *str == '\t' || *str == '(')
14176
        if (*str++ == '(')
14177
          str_depth++;
14178
    }
14179
  while (*str == '%'
14180
         && reloc_index < (HAVE_NEWABI ? 3 : 1)
14181
         && parse_relocation (&str, &reversed_reloc[reloc_index]));
14182
 
14183
  my_getExpression (ep, crux);
14184
  str = expr_end;
14185
 
14186
  /* Match every open bracket.  */
14187
  while (crux_depth > 0 && (*str == ')' || *str == ' ' || *str == '\t'))
14188
    if (*str++ == ')')
14189
      crux_depth--;
14190
 
14191
  if (crux_depth > 0)
14192
    as_bad (_("unclosed '('"));
14193
 
14194
  expr_end = str;
14195
 
14196
  if (reloc_index != 0)
14197
    {
14198
      prev_reloc_op_frag = frag_now;
14199
      for (i = 0; i < reloc_index; i++)
14200
        reloc[i] = reversed_reloc[reloc_index - 1 - i];
14201
    }
14202
 
14203
  return reloc_index;
14204
}
14205
 
14206
static void
14207
my_getExpression (expressionS *ep, char *str)
14208
{
14209
  char *save_in;
14210
 
14211
  save_in = input_line_pointer;
14212
  input_line_pointer = str;
14213
  expression (ep);
14214
  expr_end = input_line_pointer;
14215
  input_line_pointer = save_in;
14216
}
14217
 
14218
char *
14219
md_atof (int type, char *litP, int *sizeP)
14220
{
14221
  return ieee_md_atof (type, litP, sizeP, target_big_endian);
14222
}
14223
 
14224
void
14225
md_number_to_chars (char *buf, valueT val, int n)
14226
{
14227
  if (target_big_endian)
14228
    number_to_chars_bigendian (buf, val, n);
14229
  else
14230
    number_to_chars_littleendian (buf, val, n);
14231
}
14232
 
14233
#ifdef OBJ_ELF
14234
static int support_64bit_objects(void)
14235
{
14236
  const char **list, **l;
14237
  int yes;
14238
 
14239
  list = bfd_target_list ();
14240
  for (l = list; *l != NULL; l++)
14241
    if (strcmp (*l, ELF_TARGET ("elf64-", "big")) == 0
14242
        || strcmp (*l, ELF_TARGET ("elf64-", "little")) == 0)
14243
      break;
14244
  yes = (*l != NULL);
14245
  free (list);
14246
  return yes;
14247
}
14248
#endif /* OBJ_ELF */
14249
 
14250
const char *md_shortopts = "O::g::G:";
14251
 
14252
enum options
14253
  {
14254
    OPTION_MARCH = OPTION_MD_BASE,
14255
    OPTION_MTUNE,
14256
    OPTION_MIPS1,
14257
    OPTION_MIPS2,
14258
    OPTION_MIPS3,
14259
    OPTION_MIPS4,
14260
    OPTION_MIPS5,
14261
    OPTION_MIPS32,
14262
    OPTION_MIPS64,
14263
    OPTION_MIPS32R2,
14264
    OPTION_MIPS64R2,
14265
    OPTION_MIPS16,
14266
    OPTION_NO_MIPS16,
14267
    OPTION_MIPS3D,
14268
    OPTION_NO_MIPS3D,
14269
    OPTION_MDMX,
14270
    OPTION_NO_MDMX,
14271
    OPTION_DSP,
14272
    OPTION_NO_DSP,
14273
    OPTION_MT,
14274
    OPTION_NO_MT,
14275
    OPTION_SMARTMIPS,
14276
    OPTION_NO_SMARTMIPS,
14277
    OPTION_DSPR2,
14278
    OPTION_NO_DSPR2,
14279 160 khays
    OPTION_MICROMIPS,
14280
    OPTION_NO_MICROMIPS,
14281
    OPTION_MCU,
14282
    OPTION_NO_MCU,
14283 16 khays
    OPTION_COMPAT_ARCH_BASE,
14284
    OPTION_M4650,
14285
    OPTION_NO_M4650,
14286
    OPTION_M4010,
14287
    OPTION_NO_M4010,
14288
    OPTION_M4100,
14289
    OPTION_NO_M4100,
14290
    OPTION_M3900,
14291
    OPTION_NO_M3900,
14292
    OPTION_M7000_HILO_FIX,
14293
    OPTION_MNO_7000_HILO_FIX,
14294
    OPTION_FIX_24K,
14295
    OPTION_NO_FIX_24K,
14296
    OPTION_FIX_LOONGSON2F_JUMP,
14297
    OPTION_NO_FIX_LOONGSON2F_JUMP,
14298
    OPTION_FIX_LOONGSON2F_NOP,
14299
    OPTION_NO_FIX_LOONGSON2F_NOP,
14300
    OPTION_FIX_VR4120,
14301
    OPTION_NO_FIX_VR4120,
14302
    OPTION_FIX_VR4130,
14303
    OPTION_NO_FIX_VR4130,
14304
    OPTION_FIX_CN63XXP1,
14305
    OPTION_NO_FIX_CN63XXP1,
14306
    OPTION_TRAP,
14307
    OPTION_BREAK,
14308
    OPTION_EB,
14309
    OPTION_EL,
14310
    OPTION_FP32,
14311
    OPTION_GP32,
14312
    OPTION_CONSTRUCT_FLOATS,
14313
    OPTION_NO_CONSTRUCT_FLOATS,
14314
    OPTION_FP64,
14315
    OPTION_GP64,
14316
    OPTION_RELAX_BRANCH,
14317
    OPTION_NO_RELAX_BRANCH,
14318
    OPTION_MSHARED,
14319
    OPTION_MNO_SHARED,
14320
    OPTION_MSYM32,
14321
    OPTION_MNO_SYM32,
14322
    OPTION_SOFT_FLOAT,
14323
    OPTION_HARD_FLOAT,
14324
    OPTION_SINGLE_FLOAT,
14325
    OPTION_DOUBLE_FLOAT,
14326
    OPTION_32,
14327
#ifdef OBJ_ELF
14328
    OPTION_CALL_SHARED,
14329
    OPTION_CALL_NONPIC,
14330
    OPTION_NON_SHARED,
14331
    OPTION_XGOT,
14332
    OPTION_MABI,
14333
    OPTION_N32,
14334
    OPTION_64,
14335
    OPTION_MDEBUG,
14336
    OPTION_NO_MDEBUG,
14337
    OPTION_PDR,
14338
    OPTION_NO_PDR,
14339
    OPTION_MVXWORKS_PIC,
14340
#endif /* OBJ_ELF */
14341
    OPTION_END_OF_ENUM
14342
  };
14343
 
14344
struct option md_longopts[] =
14345
{
14346
  /* Options which specify architecture.  */
14347
  {"march", required_argument, NULL, OPTION_MARCH},
14348
  {"mtune", required_argument, NULL, OPTION_MTUNE},
14349
  {"mips0", no_argument, NULL, OPTION_MIPS1},
14350
  {"mips1", no_argument, NULL, OPTION_MIPS1},
14351
  {"mips2", no_argument, NULL, OPTION_MIPS2},
14352
  {"mips3", no_argument, NULL, OPTION_MIPS3},
14353
  {"mips4", no_argument, NULL, OPTION_MIPS4},
14354
  {"mips5", no_argument, NULL, OPTION_MIPS5},
14355
  {"mips32", no_argument, NULL, OPTION_MIPS32},
14356
  {"mips64", no_argument, NULL, OPTION_MIPS64},
14357
  {"mips32r2", no_argument, NULL, OPTION_MIPS32R2},
14358
  {"mips64r2", no_argument, NULL, OPTION_MIPS64R2},
14359
 
14360
  /* Options which specify Application Specific Extensions (ASEs).  */
14361
  {"mips16", no_argument, NULL, OPTION_MIPS16},
14362
  {"no-mips16", no_argument, NULL, OPTION_NO_MIPS16},
14363
  {"mips3d", no_argument, NULL, OPTION_MIPS3D},
14364
  {"no-mips3d", no_argument, NULL, OPTION_NO_MIPS3D},
14365
  {"mdmx", no_argument, NULL, OPTION_MDMX},
14366
  {"no-mdmx", no_argument, NULL, OPTION_NO_MDMX},
14367
  {"mdsp", no_argument, NULL, OPTION_DSP},
14368
  {"mno-dsp", no_argument, NULL, OPTION_NO_DSP},
14369
  {"mmt", no_argument, NULL, OPTION_MT},
14370
  {"mno-mt", no_argument, NULL, OPTION_NO_MT},
14371
  {"msmartmips", no_argument, NULL, OPTION_SMARTMIPS},
14372
  {"mno-smartmips", no_argument, NULL, OPTION_NO_SMARTMIPS},
14373
  {"mdspr2", no_argument, NULL, OPTION_DSPR2},
14374
  {"mno-dspr2", no_argument, NULL, OPTION_NO_DSPR2},
14375 160 khays
  {"mmicromips", no_argument, NULL, OPTION_MICROMIPS},
14376
  {"mno-micromips", no_argument, NULL, OPTION_NO_MICROMIPS},
14377
  {"mmcu", no_argument, NULL, OPTION_MCU},
14378
  {"mno-mcu", no_argument, NULL, OPTION_NO_MCU},
14379 16 khays
 
14380
  /* Old-style architecture options.  Don't add more of these.  */
14381
  {"m4650", no_argument, NULL, OPTION_M4650},
14382
  {"no-m4650", no_argument, NULL, OPTION_NO_M4650},
14383
  {"m4010", no_argument, NULL, OPTION_M4010},
14384
  {"no-m4010", no_argument, NULL, OPTION_NO_M4010},
14385
  {"m4100", no_argument, NULL, OPTION_M4100},
14386
  {"no-m4100", no_argument, NULL, OPTION_NO_M4100},
14387
  {"m3900", no_argument, NULL, OPTION_M3900},
14388
  {"no-m3900", no_argument, NULL, OPTION_NO_M3900},
14389
 
14390
  /* Options which enable bug fixes.  */
14391
  {"mfix7000", no_argument, NULL, OPTION_M7000_HILO_FIX},
14392
  {"no-fix-7000", no_argument, NULL, OPTION_MNO_7000_HILO_FIX},
14393
  {"mno-fix7000", no_argument, NULL, OPTION_MNO_7000_HILO_FIX},
14394
  {"mfix-loongson2f-jump", no_argument, NULL, OPTION_FIX_LOONGSON2F_JUMP},
14395
  {"mno-fix-loongson2f-jump", no_argument, NULL, OPTION_NO_FIX_LOONGSON2F_JUMP},
14396
  {"mfix-loongson2f-nop", no_argument, NULL, OPTION_FIX_LOONGSON2F_NOP},
14397
  {"mno-fix-loongson2f-nop", no_argument, NULL, OPTION_NO_FIX_LOONGSON2F_NOP},
14398
  {"mfix-vr4120",    no_argument, NULL, OPTION_FIX_VR4120},
14399
  {"mno-fix-vr4120", no_argument, NULL, OPTION_NO_FIX_VR4120},
14400
  {"mfix-vr4130",    no_argument, NULL, OPTION_FIX_VR4130},
14401
  {"mno-fix-vr4130", no_argument, NULL, OPTION_NO_FIX_VR4130},
14402
  {"mfix-24k",    no_argument, NULL, OPTION_FIX_24K},
14403
  {"mno-fix-24k", no_argument, NULL, OPTION_NO_FIX_24K},
14404
  {"mfix-cn63xxp1", no_argument, NULL, OPTION_FIX_CN63XXP1},
14405
  {"mno-fix-cn63xxp1", no_argument, NULL, OPTION_NO_FIX_CN63XXP1},
14406
 
14407
  /* Miscellaneous options.  */
14408
  {"trap", no_argument, NULL, OPTION_TRAP},
14409
  {"no-break", no_argument, NULL, OPTION_TRAP},
14410
  {"break", no_argument, NULL, OPTION_BREAK},
14411
  {"no-trap", no_argument, NULL, OPTION_BREAK},
14412
  {"EB", no_argument, NULL, OPTION_EB},
14413
  {"EL", no_argument, NULL, OPTION_EL},
14414
  {"mfp32", no_argument, NULL, OPTION_FP32},
14415
  {"mgp32", no_argument, NULL, OPTION_GP32},
14416
  {"construct-floats", no_argument, NULL, OPTION_CONSTRUCT_FLOATS},
14417
  {"no-construct-floats", no_argument, NULL, OPTION_NO_CONSTRUCT_FLOATS},
14418
  {"mfp64", no_argument, NULL, OPTION_FP64},
14419
  {"mgp64", no_argument, NULL, OPTION_GP64},
14420
  {"relax-branch", no_argument, NULL, OPTION_RELAX_BRANCH},
14421
  {"no-relax-branch", no_argument, NULL, OPTION_NO_RELAX_BRANCH},
14422
  {"mshared", no_argument, NULL, OPTION_MSHARED},
14423
  {"mno-shared", no_argument, NULL, OPTION_MNO_SHARED},
14424
  {"msym32", no_argument, NULL, OPTION_MSYM32},
14425
  {"mno-sym32", no_argument, NULL, OPTION_MNO_SYM32},
14426
  {"msoft-float", no_argument, NULL, OPTION_SOFT_FLOAT},
14427
  {"mhard-float", no_argument, NULL, OPTION_HARD_FLOAT},
14428
  {"msingle-float", no_argument, NULL, OPTION_SINGLE_FLOAT},
14429
  {"mdouble-float", no_argument, NULL, OPTION_DOUBLE_FLOAT},
14430
 
14431
  /* Strictly speaking this next option is ELF specific,
14432
     but we allow it for other ports as well in order to
14433
     make testing easier.  */
14434
  {"32",          no_argument, NULL, OPTION_32},
14435
 
14436
  /* ELF-specific options.  */
14437
#ifdef OBJ_ELF
14438
  {"KPIC",        no_argument, NULL, OPTION_CALL_SHARED},
14439
  {"call_shared", no_argument, NULL, OPTION_CALL_SHARED},
14440
  {"call_nonpic", no_argument, NULL, OPTION_CALL_NONPIC},
14441
  {"non_shared",  no_argument, NULL, OPTION_NON_SHARED},
14442
  {"xgot",        no_argument, NULL, OPTION_XGOT},
14443
  {"mabi", required_argument, NULL, OPTION_MABI},
14444
  {"n32",         no_argument, NULL, OPTION_N32},
14445
  {"64",          no_argument, NULL, OPTION_64},
14446
  {"mdebug", no_argument, NULL, OPTION_MDEBUG},
14447
  {"no-mdebug", no_argument, NULL, OPTION_NO_MDEBUG},
14448
  {"mpdr", no_argument, NULL, OPTION_PDR},
14449
  {"mno-pdr", no_argument, NULL, OPTION_NO_PDR},
14450
  {"mvxworks-pic", no_argument, NULL, OPTION_MVXWORKS_PIC},
14451
#endif /* OBJ_ELF */
14452
 
14453
  {NULL, no_argument, NULL, 0}
14454
};
14455
size_t md_longopts_size = sizeof (md_longopts);
14456
 
14457
/* Set STRING_PTR (either &mips_arch_string or &mips_tune_string) to
14458
   NEW_VALUE.  Warn if another value was already specified.  Note:
14459
   we have to defer parsing the -march and -mtune arguments in order
14460
   to handle 'from-abi' correctly, since the ABI might be specified
14461
   in a later argument.  */
14462
 
14463
static void
14464
mips_set_option_string (const char **string_ptr, const char *new_value)
14465
{
14466
  if (*string_ptr != 0 && strcasecmp (*string_ptr, new_value) != 0)
14467
    as_warn (_("A different %s was already specified, is now %s"),
14468
             string_ptr == &mips_arch_string ? "-march" : "-mtune",
14469
             new_value);
14470
 
14471
  *string_ptr = new_value;
14472
}
14473
 
14474
int
14475
md_parse_option (int c, char *arg)
14476
{
14477
  switch (c)
14478
    {
14479
    case OPTION_CONSTRUCT_FLOATS:
14480
      mips_disable_float_construction = 0;
14481
      break;
14482
 
14483
    case OPTION_NO_CONSTRUCT_FLOATS:
14484
      mips_disable_float_construction = 1;
14485
      break;
14486
 
14487
    case OPTION_TRAP:
14488
      mips_trap = 1;
14489
      break;
14490
 
14491
    case OPTION_BREAK:
14492
      mips_trap = 0;
14493
      break;
14494
 
14495
    case OPTION_EB:
14496
      target_big_endian = 1;
14497
      break;
14498
 
14499
    case OPTION_EL:
14500
      target_big_endian = 0;
14501
      break;
14502
 
14503
    case 'O':
14504
      if (arg == NULL)
14505
        mips_optimize = 1;
14506
      else if (arg[0] == '0')
14507
        mips_optimize = 0;
14508
      else if (arg[0] == '1')
14509
        mips_optimize = 1;
14510
      else
14511
        mips_optimize = 2;
14512
      break;
14513
 
14514
    case 'g':
14515
      if (arg == NULL)
14516
        mips_debug = 2;
14517
      else
14518
        mips_debug = atoi (arg);
14519
      break;
14520
 
14521
    case OPTION_MIPS1:
14522
      file_mips_isa = ISA_MIPS1;
14523
      break;
14524
 
14525
    case OPTION_MIPS2:
14526
      file_mips_isa = ISA_MIPS2;
14527
      break;
14528
 
14529
    case OPTION_MIPS3:
14530
      file_mips_isa = ISA_MIPS3;
14531
      break;
14532
 
14533
    case OPTION_MIPS4:
14534
      file_mips_isa = ISA_MIPS4;
14535
      break;
14536
 
14537
    case OPTION_MIPS5:
14538
      file_mips_isa = ISA_MIPS5;
14539
      break;
14540
 
14541
    case OPTION_MIPS32:
14542
      file_mips_isa = ISA_MIPS32;
14543
      break;
14544
 
14545
    case OPTION_MIPS32R2:
14546
      file_mips_isa = ISA_MIPS32R2;
14547
      break;
14548
 
14549
    case OPTION_MIPS64R2:
14550
      file_mips_isa = ISA_MIPS64R2;
14551
      break;
14552
 
14553
    case OPTION_MIPS64:
14554
      file_mips_isa = ISA_MIPS64;
14555
      break;
14556
 
14557
    case OPTION_MTUNE:
14558
      mips_set_option_string (&mips_tune_string, arg);
14559
      break;
14560
 
14561
    case OPTION_MARCH:
14562
      mips_set_option_string (&mips_arch_string, arg);
14563
      break;
14564
 
14565
    case OPTION_M4650:
14566
      mips_set_option_string (&mips_arch_string, "4650");
14567
      mips_set_option_string (&mips_tune_string, "4650");
14568
      break;
14569
 
14570
    case OPTION_NO_M4650:
14571
      break;
14572
 
14573
    case OPTION_M4010:
14574
      mips_set_option_string (&mips_arch_string, "4010");
14575
      mips_set_option_string (&mips_tune_string, "4010");
14576
      break;
14577
 
14578
    case OPTION_NO_M4010:
14579
      break;
14580
 
14581
    case OPTION_M4100:
14582
      mips_set_option_string (&mips_arch_string, "4100");
14583
      mips_set_option_string (&mips_tune_string, "4100");
14584
      break;
14585
 
14586
    case OPTION_NO_M4100:
14587
      break;
14588
 
14589
    case OPTION_M3900:
14590
      mips_set_option_string (&mips_arch_string, "3900");
14591
      mips_set_option_string (&mips_tune_string, "3900");
14592
      break;
14593
 
14594
    case OPTION_NO_M3900:
14595
      break;
14596
 
14597
    case OPTION_MDMX:
14598
      mips_opts.ase_mdmx = 1;
14599
      break;
14600
 
14601
    case OPTION_NO_MDMX:
14602
      mips_opts.ase_mdmx = 0;
14603
      break;
14604
 
14605
    case OPTION_DSP:
14606
      mips_opts.ase_dsp = 1;
14607
      mips_opts.ase_dspr2 = 0;
14608
      break;
14609
 
14610
    case OPTION_NO_DSP:
14611
      mips_opts.ase_dsp = 0;
14612
      mips_opts.ase_dspr2 = 0;
14613
      break;
14614
 
14615
    case OPTION_DSPR2:
14616
      mips_opts.ase_dspr2 = 1;
14617
      mips_opts.ase_dsp = 1;
14618
      break;
14619
 
14620
    case OPTION_NO_DSPR2:
14621
      mips_opts.ase_dspr2 = 0;
14622
      mips_opts.ase_dsp = 0;
14623
      break;
14624
 
14625
    case OPTION_MT:
14626
      mips_opts.ase_mt = 1;
14627
      break;
14628
 
14629
    case OPTION_NO_MT:
14630
      mips_opts.ase_mt = 0;
14631
      break;
14632
 
14633 160 khays
    case OPTION_MCU:
14634
      mips_opts.ase_mcu = 1;
14635
      break;
14636
 
14637
    case OPTION_NO_MCU:
14638
      mips_opts.ase_mcu = 0;
14639
      break;
14640
 
14641
    case OPTION_MICROMIPS:
14642
      if (mips_opts.mips16 == 1)
14643
        {
14644
          as_bad (_("-mmicromips cannot be used with -mips16"));
14645
          return 0;
14646
        }
14647
      mips_opts.micromips = 1;
14648
      mips_no_prev_insn ();
14649
      break;
14650
 
14651
    case OPTION_NO_MICROMIPS:
14652
      mips_opts.micromips = 0;
14653
      mips_no_prev_insn ();
14654
      break;
14655
 
14656 16 khays
    case OPTION_MIPS16:
14657 160 khays
      if (mips_opts.micromips == 1)
14658
        {
14659
          as_bad (_("-mips16 cannot be used with -micromips"));
14660
          return 0;
14661
        }
14662 16 khays
      mips_opts.mips16 = 1;
14663
      mips_no_prev_insn ();
14664
      break;
14665
 
14666
    case OPTION_NO_MIPS16:
14667
      mips_opts.mips16 = 0;
14668
      mips_no_prev_insn ();
14669
      break;
14670
 
14671
    case OPTION_MIPS3D:
14672
      mips_opts.ase_mips3d = 1;
14673
      break;
14674
 
14675
    case OPTION_NO_MIPS3D:
14676
      mips_opts.ase_mips3d = 0;
14677
      break;
14678
 
14679
    case OPTION_SMARTMIPS:
14680
      mips_opts.ase_smartmips = 1;
14681
      break;
14682
 
14683
    case OPTION_NO_SMARTMIPS:
14684
      mips_opts.ase_smartmips = 0;
14685
      break;
14686
 
14687
    case OPTION_FIX_24K:
14688
      mips_fix_24k = 1;
14689
      break;
14690
 
14691
    case OPTION_NO_FIX_24K:
14692
      mips_fix_24k = 0;
14693
      break;
14694
 
14695
    case OPTION_FIX_LOONGSON2F_JUMP:
14696
      mips_fix_loongson2f_jump = TRUE;
14697
      break;
14698
 
14699
    case OPTION_NO_FIX_LOONGSON2F_JUMP:
14700
      mips_fix_loongson2f_jump = FALSE;
14701
      break;
14702
 
14703
    case OPTION_FIX_LOONGSON2F_NOP:
14704
      mips_fix_loongson2f_nop = TRUE;
14705
      break;
14706
 
14707
    case OPTION_NO_FIX_LOONGSON2F_NOP:
14708
      mips_fix_loongson2f_nop = FALSE;
14709
      break;
14710
 
14711
    case OPTION_FIX_VR4120:
14712
      mips_fix_vr4120 = 1;
14713
      break;
14714
 
14715
    case OPTION_NO_FIX_VR4120:
14716
      mips_fix_vr4120 = 0;
14717
      break;
14718
 
14719
    case OPTION_FIX_VR4130:
14720
      mips_fix_vr4130 = 1;
14721
      break;
14722
 
14723
    case OPTION_NO_FIX_VR4130:
14724
      mips_fix_vr4130 = 0;
14725
      break;
14726
 
14727
    case OPTION_FIX_CN63XXP1:
14728
      mips_fix_cn63xxp1 = TRUE;
14729
      break;
14730
 
14731
    case OPTION_NO_FIX_CN63XXP1:
14732
      mips_fix_cn63xxp1 = FALSE;
14733
      break;
14734
 
14735
    case OPTION_RELAX_BRANCH:
14736
      mips_relax_branch = 1;
14737
      break;
14738
 
14739
    case OPTION_NO_RELAX_BRANCH:
14740
      mips_relax_branch = 0;
14741
      break;
14742
 
14743
    case OPTION_MSHARED:
14744
      mips_in_shared = TRUE;
14745
      break;
14746
 
14747
    case OPTION_MNO_SHARED:
14748
      mips_in_shared = FALSE;
14749
      break;
14750
 
14751
    case OPTION_MSYM32:
14752
      mips_opts.sym32 = TRUE;
14753
      break;
14754
 
14755
    case OPTION_MNO_SYM32:
14756
      mips_opts.sym32 = FALSE;
14757
      break;
14758
 
14759
#ifdef OBJ_ELF
14760
      /* When generating ELF code, we permit -KPIC and -call_shared to
14761
         select SVR4_PIC, and -non_shared to select no PIC.  This is
14762
         intended to be compatible with Irix 5.  */
14763
    case OPTION_CALL_SHARED:
14764
      if (!IS_ELF)
14765
        {
14766
          as_bad (_("-call_shared is supported only for ELF format"));
14767
          return 0;
14768
        }
14769
      mips_pic = SVR4_PIC;
14770
      mips_abicalls = TRUE;
14771
      break;
14772
 
14773
    case OPTION_CALL_NONPIC:
14774
      if (!IS_ELF)
14775
        {
14776
          as_bad (_("-call_nonpic is supported only for ELF format"));
14777
          return 0;
14778
        }
14779
      mips_pic = NO_PIC;
14780
      mips_abicalls = TRUE;
14781
      break;
14782
 
14783
    case OPTION_NON_SHARED:
14784
      if (!IS_ELF)
14785
        {
14786
          as_bad (_("-non_shared is supported only for ELF format"));
14787
          return 0;
14788
        }
14789
      mips_pic = NO_PIC;
14790
      mips_abicalls = FALSE;
14791
      break;
14792
 
14793
      /* The -xgot option tells the assembler to use 32 bit offsets
14794
         when accessing the got in SVR4_PIC mode.  It is for Irix
14795
         compatibility.  */
14796
    case OPTION_XGOT:
14797
      mips_big_got = 1;
14798
      break;
14799
#endif /* OBJ_ELF */
14800
 
14801
    case 'G':
14802
      g_switch_value = atoi (arg);
14803
      g_switch_seen = 1;
14804
      break;
14805
 
14806
      /* The -32, -n32 and -64 options are shortcuts for -mabi=32, -mabi=n32
14807
         and -mabi=64.  */
14808
    case OPTION_32:
14809
      if (IS_ELF)
14810
        mips_abi = O32_ABI;
14811
      /* We silently ignore -32 for non-ELF targets.  This greatly
14812
         simplifies the construction of the MIPS GAS test cases.  */
14813
      break;
14814
 
14815
#ifdef OBJ_ELF
14816
    case OPTION_N32:
14817
      if (!IS_ELF)
14818
        {
14819
          as_bad (_("-n32 is supported for ELF format only"));
14820
          return 0;
14821
        }
14822
      mips_abi = N32_ABI;
14823
      break;
14824
 
14825
    case OPTION_64:
14826
      if (!IS_ELF)
14827
        {
14828
          as_bad (_("-64 is supported for ELF format only"));
14829
          return 0;
14830
        }
14831
      mips_abi = N64_ABI;
14832
      if (!support_64bit_objects())
14833
        as_fatal (_("No compiled in support for 64 bit object file format"));
14834
      break;
14835
#endif /* OBJ_ELF */
14836
 
14837
    case OPTION_GP32:
14838
      file_mips_gp32 = 1;
14839
      break;
14840
 
14841
    case OPTION_GP64:
14842
      file_mips_gp32 = 0;
14843
      break;
14844
 
14845
    case OPTION_FP32:
14846
      file_mips_fp32 = 1;
14847
      break;
14848
 
14849
    case OPTION_FP64:
14850
      file_mips_fp32 = 0;
14851
      break;
14852
 
14853
    case OPTION_SINGLE_FLOAT:
14854
      file_mips_single_float = 1;
14855
      break;
14856
 
14857
    case OPTION_DOUBLE_FLOAT:
14858
      file_mips_single_float = 0;
14859
      break;
14860
 
14861
    case OPTION_SOFT_FLOAT:
14862
      file_mips_soft_float = 1;
14863
      break;
14864
 
14865
    case OPTION_HARD_FLOAT:
14866
      file_mips_soft_float = 0;
14867
      break;
14868
 
14869
#ifdef OBJ_ELF
14870
    case OPTION_MABI:
14871
      if (!IS_ELF)
14872
        {
14873
          as_bad (_("-mabi is supported for ELF format only"));
14874
          return 0;
14875
        }
14876
      if (strcmp (arg, "32") == 0)
14877
        mips_abi = O32_ABI;
14878
      else if (strcmp (arg, "o64") == 0)
14879
        mips_abi = O64_ABI;
14880
      else if (strcmp (arg, "n32") == 0)
14881
        mips_abi = N32_ABI;
14882
      else if (strcmp (arg, "64") == 0)
14883
        {
14884
          mips_abi = N64_ABI;
14885
          if (! support_64bit_objects())
14886
            as_fatal (_("No compiled in support for 64 bit object file "
14887
                        "format"));
14888
        }
14889
      else if (strcmp (arg, "eabi") == 0)
14890
        mips_abi = EABI_ABI;
14891
      else
14892
        {
14893
          as_fatal (_("invalid abi -mabi=%s"), arg);
14894
          return 0;
14895
        }
14896
      break;
14897
#endif /* OBJ_ELF */
14898
 
14899
    case OPTION_M7000_HILO_FIX:
14900
      mips_7000_hilo_fix = TRUE;
14901
      break;
14902
 
14903
    case OPTION_MNO_7000_HILO_FIX:
14904
      mips_7000_hilo_fix = FALSE;
14905
      break;
14906
 
14907
#ifdef OBJ_ELF
14908
    case OPTION_MDEBUG:
14909
      mips_flag_mdebug = TRUE;
14910
      break;
14911
 
14912
    case OPTION_NO_MDEBUG:
14913
      mips_flag_mdebug = FALSE;
14914
      break;
14915
 
14916
    case OPTION_PDR:
14917
      mips_flag_pdr = TRUE;
14918
      break;
14919
 
14920
    case OPTION_NO_PDR:
14921
      mips_flag_pdr = FALSE;
14922
      break;
14923
 
14924
    case OPTION_MVXWORKS_PIC:
14925
      mips_pic = VXWORKS_PIC;
14926
      break;
14927
#endif /* OBJ_ELF */
14928
 
14929
    default:
14930
      return 0;
14931
    }
14932
 
14933
    mips_fix_loongson2f = mips_fix_loongson2f_nop || mips_fix_loongson2f_jump;
14934
 
14935
  return 1;
14936
}
14937
 
14938
/* Set up globals to generate code for the ISA or processor
14939
   described by INFO.  */
14940
 
14941
static void
14942
mips_set_architecture (const struct mips_cpu_info *info)
14943
{
14944
  if (info != 0)
14945
    {
14946
      file_mips_arch = info->cpu;
14947
      mips_opts.arch = info->cpu;
14948
      mips_opts.isa = info->isa;
14949
    }
14950
}
14951
 
14952
 
14953
/* Likewise for tuning.  */
14954
 
14955
static void
14956
mips_set_tune (const struct mips_cpu_info *info)
14957
{
14958
  if (info != 0)
14959
    mips_tune = info->cpu;
14960
}
14961
 
14962
 
14963
void
14964
mips_after_parse_args (void)
14965
{
14966
  const struct mips_cpu_info *arch_info = 0;
14967
  const struct mips_cpu_info *tune_info = 0;
14968
 
14969
  /* GP relative stuff not working for PE */
14970
  if (strncmp (TARGET_OS, "pe", 2) == 0)
14971
    {
14972
      if (g_switch_seen && g_switch_value != 0)
14973
        as_bad (_("-G not supported in this configuration."));
14974
      g_switch_value = 0;
14975
    }
14976
 
14977
  if (mips_abi == NO_ABI)
14978
    mips_abi = MIPS_DEFAULT_ABI;
14979
 
14980
  /* The following code determines the architecture and register size.
14981
     Similar code was added to GCC 3.3 (see override_options() in
14982
     config/mips/mips.c).  The GAS and GCC code should be kept in sync
14983
     as much as possible.  */
14984
 
14985
  if (mips_arch_string != 0)
14986
    arch_info = mips_parse_cpu ("-march", mips_arch_string);
14987
 
14988
  if (file_mips_isa != ISA_UNKNOWN)
14989
    {
14990
      /* Handle -mipsN.  At this point, file_mips_isa contains the
14991
         ISA level specified by -mipsN, while arch_info->isa contains
14992
         the -march selection (if any).  */
14993
      if (arch_info != 0)
14994
        {
14995
          /* -march takes precedence over -mipsN, since it is more descriptive.
14996
             There's no harm in specifying both as long as the ISA levels
14997
             are the same.  */
14998
          if (file_mips_isa != arch_info->isa)
14999
            as_bad (_("-%s conflicts with the other architecture options, which imply -%s"),
15000
                    mips_cpu_info_from_isa (file_mips_isa)->name,
15001
                    mips_cpu_info_from_isa (arch_info->isa)->name);
15002
        }
15003
      else
15004
        arch_info = mips_cpu_info_from_isa (file_mips_isa);
15005
    }
15006
 
15007
  if (arch_info == 0)
15008
    arch_info = mips_parse_cpu ("default CPU", MIPS_CPU_STRING_DEFAULT);
15009
 
15010
  if (ABI_NEEDS_64BIT_REGS (mips_abi) && !ISA_HAS_64BIT_REGS (arch_info->isa))
15011
    as_bad (_("-march=%s is not compatible with the selected ABI"),
15012
            arch_info->name);
15013
 
15014
  mips_set_architecture (arch_info);
15015
 
15016
  /* Optimize for file_mips_arch, unless -mtune selects a different processor.  */
15017
  if (mips_tune_string != 0)
15018
    tune_info = mips_parse_cpu ("-mtune", mips_tune_string);
15019
 
15020
  if (tune_info == 0)
15021
    mips_set_tune (arch_info);
15022
  else
15023
    mips_set_tune (tune_info);
15024
 
15025
  if (file_mips_gp32 >= 0)
15026
    {
15027
      /* The user specified the size of the integer registers.  Make sure
15028
         it agrees with the ABI and ISA.  */
15029
      if (file_mips_gp32 == 0 && !ISA_HAS_64BIT_REGS (mips_opts.isa))
15030
        as_bad (_("-mgp64 used with a 32-bit processor"));
15031
      else if (file_mips_gp32 == 1 && ABI_NEEDS_64BIT_REGS (mips_abi))
15032
        as_bad (_("-mgp32 used with a 64-bit ABI"));
15033
      else if (file_mips_gp32 == 0 && ABI_NEEDS_32BIT_REGS (mips_abi))
15034
        as_bad (_("-mgp64 used with a 32-bit ABI"));
15035
    }
15036
  else
15037
    {
15038
      /* Infer the integer register size from the ABI and processor.
15039
         Restrict ourselves to 32-bit registers if that's all the
15040
         processor has, or if the ABI cannot handle 64-bit registers.  */
15041
      file_mips_gp32 = (ABI_NEEDS_32BIT_REGS (mips_abi)
15042
                        || !ISA_HAS_64BIT_REGS (mips_opts.isa));
15043
    }
15044
 
15045
  switch (file_mips_fp32)
15046
    {
15047
    default:
15048
    case -1:
15049
      /* No user specified float register size.
15050
         ??? GAS treats single-float processors as though they had 64-bit
15051
         float registers (although it complains when double-precision
15052
         instructions are used).  As things stand, saying they have 32-bit
15053
         registers would lead to spurious "register must be even" messages.
15054
         So here we assume float registers are never smaller than the
15055
         integer ones.  */
15056
      if (file_mips_gp32 == 0)
15057
        /* 64-bit integer registers implies 64-bit float registers.  */
15058
        file_mips_fp32 = 0;
15059
      else if ((mips_opts.ase_mips3d > 0 || mips_opts.ase_mdmx > 0)
15060
               && ISA_HAS_64BIT_FPRS (mips_opts.isa))
15061
        /* -mips3d and -mdmx imply 64-bit float registers, if possible.  */
15062
        file_mips_fp32 = 0;
15063
      else
15064
        /* 32-bit float registers.  */
15065
        file_mips_fp32 = 1;
15066
      break;
15067
 
15068
    /* The user specified the size of the float registers.  Check if it
15069
       agrees with the ABI and ISA.  */
15070
    case 0:
15071
      if (!ISA_HAS_64BIT_FPRS (mips_opts.isa))
15072
        as_bad (_("-mfp64 used with a 32-bit fpu"));
15073
      else if (ABI_NEEDS_32BIT_REGS (mips_abi)
15074
               && !ISA_HAS_MXHC1 (mips_opts.isa))
15075
        as_warn (_("-mfp64 used with a 32-bit ABI"));
15076
      break;
15077
    case 1:
15078
      if (ABI_NEEDS_64BIT_REGS (mips_abi))
15079
        as_warn (_("-mfp32 used with a 64-bit ABI"));
15080
      break;
15081
    }
15082
 
15083
  /* End of GCC-shared inference code.  */
15084
 
15085
  /* This flag is set when we have a 64-bit capable CPU but use only
15086
     32-bit wide registers.  Note that EABI does not use it.  */
15087
  if (ISA_HAS_64BIT_REGS (mips_opts.isa)
15088
      && ((mips_abi == NO_ABI && file_mips_gp32 == 1)
15089
          || mips_abi == O32_ABI))
15090
    mips_32bitmode = 1;
15091
 
15092
  if (mips_opts.isa == ISA_MIPS1 && mips_trap)
15093
    as_bad (_("trap exception not supported at ISA 1"));
15094
 
15095
  /* If the selected architecture includes support for ASEs, enable
15096
     generation of code for them.  */
15097
  if (mips_opts.mips16 == -1)
15098
    mips_opts.mips16 = (CPU_HAS_MIPS16 (file_mips_arch)) ? 1 : 0;
15099 160 khays
  if (mips_opts.micromips == -1)
15100
    mips_opts.micromips = (CPU_HAS_MICROMIPS (file_mips_arch)) ? 1 : 0;
15101 16 khays
  if (mips_opts.ase_mips3d == -1)
15102
    mips_opts.ase_mips3d = ((arch_info->flags & MIPS_CPU_ASE_MIPS3D)
15103
                            && file_mips_fp32 == 0) ? 1 : 0;
15104
  if (mips_opts.ase_mips3d && file_mips_fp32 == 1)
15105
    as_bad (_("-mfp32 used with -mips3d"));
15106
 
15107
  if (mips_opts.ase_mdmx == -1)
15108
    mips_opts.ase_mdmx = ((arch_info->flags & MIPS_CPU_ASE_MDMX)
15109
                          && file_mips_fp32 == 0) ? 1 : 0;
15110
  if (mips_opts.ase_mdmx && file_mips_fp32 == 1)
15111
    as_bad (_("-mfp32 used with -mdmx"));
15112
 
15113
  if (mips_opts.ase_smartmips == -1)
15114
    mips_opts.ase_smartmips = (arch_info->flags & MIPS_CPU_ASE_SMARTMIPS) ? 1 : 0;
15115
  if (mips_opts.ase_smartmips && !ISA_SUPPORTS_SMARTMIPS)
15116
    as_warn (_("%s ISA does not support SmartMIPS"),
15117
             mips_cpu_info_from_isa (mips_opts.isa)->name);
15118
 
15119
  if (mips_opts.ase_dsp == -1)
15120
    mips_opts.ase_dsp = (arch_info->flags & MIPS_CPU_ASE_DSP) ? 1 : 0;
15121
  if (mips_opts.ase_dsp && !ISA_SUPPORTS_DSP_ASE)
15122
    as_warn (_("%s ISA does not support DSP ASE"),
15123
             mips_cpu_info_from_isa (mips_opts.isa)->name);
15124
 
15125
  if (mips_opts.ase_dspr2 == -1)
15126
    {
15127
      mips_opts.ase_dspr2 = (arch_info->flags & MIPS_CPU_ASE_DSPR2) ? 1 : 0;
15128
      mips_opts.ase_dsp = (arch_info->flags & MIPS_CPU_ASE_DSP) ? 1 : 0;
15129
    }
15130
  if (mips_opts.ase_dspr2 && !ISA_SUPPORTS_DSPR2_ASE)
15131
    as_warn (_("%s ISA does not support DSP R2 ASE"),
15132
             mips_cpu_info_from_isa (mips_opts.isa)->name);
15133
 
15134
  if (mips_opts.ase_mt == -1)
15135
    mips_opts.ase_mt = (arch_info->flags & MIPS_CPU_ASE_MT) ? 1 : 0;
15136
  if (mips_opts.ase_mt && !ISA_SUPPORTS_MT_ASE)
15137
    as_warn (_("%s ISA does not support MT ASE"),
15138
             mips_cpu_info_from_isa (mips_opts.isa)->name);
15139
 
15140 160 khays
  if (mips_opts.ase_mcu == -1)
15141
    mips_opts.ase_mcu = (arch_info->flags & MIPS_CPU_ASE_MCU) ? 1 : 0;
15142
  if (mips_opts.ase_mcu && !ISA_SUPPORTS_MCU_ASE)
15143
      as_warn (_("%s ISA does not support MCU ASE"),
15144
               mips_cpu_info_from_isa (mips_opts.isa)->name);
15145
 
15146 16 khays
  file_mips_isa = mips_opts.isa;
15147
  file_ase_mips3d = mips_opts.ase_mips3d;
15148
  file_ase_mdmx = mips_opts.ase_mdmx;
15149
  file_ase_smartmips = mips_opts.ase_smartmips;
15150
  file_ase_dsp = mips_opts.ase_dsp;
15151
  file_ase_dspr2 = mips_opts.ase_dspr2;
15152
  file_ase_mt = mips_opts.ase_mt;
15153
  mips_opts.gp32 = file_mips_gp32;
15154
  mips_opts.fp32 = file_mips_fp32;
15155
  mips_opts.soft_float = file_mips_soft_float;
15156
  mips_opts.single_float = file_mips_single_float;
15157
 
15158
  if (mips_flag_mdebug < 0)
15159
    {
15160
#ifdef OBJ_MAYBE_ECOFF
15161
      if (OUTPUT_FLAVOR == bfd_target_ecoff_flavour)
15162
        mips_flag_mdebug = 1;
15163
      else
15164
#endif /* OBJ_MAYBE_ECOFF */
15165
        mips_flag_mdebug = 0;
15166
    }
15167
}
15168
 
15169
void
15170
mips_init_after_args (void)
15171
{
15172
  /* initialize opcodes */
15173
  bfd_mips_num_opcodes = bfd_mips_num_builtin_opcodes;
15174
  mips_opcodes = (struct mips_opcode *) mips_builtin_opcodes;
15175
}
15176
 
15177
long
15178
md_pcrel_from (fixS *fixP)
15179
{
15180
  valueT addr = fixP->fx_where + fixP->fx_frag->fr_address;
15181
  switch (fixP->fx_r_type)
15182
    {
15183 160 khays
    case BFD_RELOC_MICROMIPS_7_PCREL_S1:
15184
    case BFD_RELOC_MICROMIPS_10_PCREL_S1:
15185
      /* Return the address of the delay slot.  */
15186
      return addr + 2;
15187
 
15188
    case BFD_RELOC_MICROMIPS_16_PCREL_S1:
15189
    case BFD_RELOC_MICROMIPS_JMP:
15190 16 khays
    case BFD_RELOC_16_PCREL_S2:
15191
    case BFD_RELOC_MIPS_JMP:
15192
      /* Return the address of the delay slot.  */
15193
      return addr + 4;
15194 160 khays
 
15195 16 khays
    default:
15196
      /* We have no relocation type for PC relative MIPS16 instructions.  */
15197
      if (fixP->fx_addsy && S_GET_SEGMENT (fixP->fx_addsy) != now_seg)
15198
        as_bad_where (fixP->fx_file, fixP->fx_line,
15199
                      _("PC relative MIPS16 instruction references a different section"));
15200
      return addr;
15201
    }
15202
}
15203
 
15204
/* This is called before the symbol table is processed.  In order to
15205
   work with gcc when using mips-tfile, we must keep all local labels.
15206
   However, in other cases, we want to discard them.  If we were
15207
   called with -g, but we didn't see any debugging information, it may
15208
   mean that gcc is smuggling debugging information through to
15209
   mips-tfile, in which case we must generate all local labels.  */
15210
 
15211
void
15212
mips_frob_file_before_adjust (void)
15213
{
15214
#ifndef NO_ECOFF_DEBUGGING
15215
  if (ECOFF_DEBUGGING
15216
      && mips_debug != 0
15217
      && ! ecoff_debugging_seen)
15218
    flag_keep_locals = 1;
15219
#endif
15220
}
15221
 
15222
/* Sort any unmatched HI16 and GOT16 relocs so that they immediately precede
15223
   the corresponding LO16 reloc.  This is called before md_apply_fix and
15224
   tc_gen_reloc.  Unmatched relocs can only be generated by use of explicit
15225
   relocation operators.
15226
 
15227
   For our purposes, a %lo() expression matches a %got() or %hi()
15228
   expression if:
15229
 
15230
      (a) it refers to the same symbol; and
15231
      (b) the offset applied in the %lo() expression is no lower than
15232
          the offset applied in the %got() or %hi().
15233
 
15234
   (b) allows us to cope with code like:
15235
 
15236
        lui     $4,%hi(foo)
15237
        lh      $4,%lo(foo+2)($4)
15238
 
15239
   ...which is legal on RELA targets, and has a well-defined behaviour
15240
   if the user knows that adding 2 to "foo" will not induce a carry to
15241
   the high 16 bits.
15242
 
15243
   When several %lo()s match a particular %got() or %hi(), we use the
15244
   following rules to distinguish them:
15245
 
15246
     (1) %lo()s with smaller offsets are a better match than %lo()s with
15247
         higher offsets.
15248
 
15249
     (2) %lo()s with no matching %got() or %hi() are better than those
15250
         that already have a matching %got() or %hi().
15251
 
15252
     (3) later %lo()s are better than earlier %lo()s.
15253
 
15254
   These rules are applied in order.
15255
 
15256
   (1) means, among other things, that %lo()s with identical offsets are
15257
   chosen if they exist.
15258
 
15259
   (2) means that we won't associate several high-part relocations with
15260
   the same low-part relocation unless there's no alternative.  Having
15261
   several high parts for the same low part is a GNU extension; this rule
15262
   allows careful users to avoid it.
15263
 
15264
   (3) is purely cosmetic.  mips_hi_fixup_list is is in reverse order,
15265
   with the last high-part relocation being at the front of the list.
15266
   It therefore makes sense to choose the last matching low-part
15267
   relocation, all other things being equal.  It's also easier
15268
   to code that way.  */
15269
 
15270
void
15271
mips_frob_file (void)
15272
{
15273
  struct mips_hi_fixup *l;
15274
  bfd_reloc_code_real_type looking_for_rtype = BFD_RELOC_UNUSED;
15275
 
15276
  for (l = mips_hi_fixup_list; l != NULL; l = l->next)
15277
    {
15278
      segment_info_type *seginfo;
15279
      bfd_boolean matched_lo_p;
15280
      fixS **hi_pos, **lo_pos, **pos;
15281
 
15282
      gas_assert (reloc_needs_lo_p (l->fixp->fx_r_type));
15283
 
15284
      /* If a GOT16 relocation turns out to be against a global symbol,
15285
         there isn't supposed to be a matching LO.  */
15286
      if (got16_reloc_p (l->fixp->fx_r_type)
15287
          && !pic_need_relax (l->fixp->fx_addsy, l->seg))
15288
        continue;
15289
 
15290
      /* Check quickly whether the next fixup happens to be a matching %lo.  */
15291
      if (fixup_has_matching_lo_p (l->fixp))
15292
        continue;
15293
 
15294
      seginfo = seg_info (l->seg);
15295
 
15296
      /* Set HI_POS to the position of this relocation in the chain.
15297
         Set LO_POS to the position of the chosen low-part relocation.
15298
         MATCHED_LO_P is true on entry to the loop if *POS is a low-part
15299
         relocation that matches an immediately-preceding high-part
15300
         relocation.  */
15301
      hi_pos = NULL;
15302
      lo_pos = NULL;
15303
      matched_lo_p = FALSE;
15304
      looking_for_rtype = matching_lo_reloc (l->fixp->fx_r_type);
15305
 
15306
      for (pos = &seginfo->fix_root; *pos != NULL; pos = &(*pos)->fx_next)
15307
        {
15308
          if (*pos == l->fixp)
15309
            hi_pos = pos;
15310
 
15311
          if ((*pos)->fx_r_type == looking_for_rtype
15312
              && symbol_same_p ((*pos)->fx_addsy, l->fixp->fx_addsy)
15313
              && (*pos)->fx_offset >= l->fixp->fx_offset
15314
              && (lo_pos == NULL
15315
                  || (*pos)->fx_offset < (*lo_pos)->fx_offset
15316
                  || (!matched_lo_p
15317
                      && (*pos)->fx_offset == (*lo_pos)->fx_offset)))
15318
            lo_pos = pos;
15319
 
15320
          matched_lo_p = (reloc_needs_lo_p ((*pos)->fx_r_type)
15321
                          && fixup_has_matching_lo_p (*pos));
15322
        }
15323
 
15324
      /* If we found a match, remove the high-part relocation from its
15325
         current position and insert it before the low-part relocation.
15326
         Make the offsets match so that fixup_has_matching_lo_p()
15327
         will return true.
15328
 
15329
         We don't warn about unmatched high-part relocations since some
15330
         versions of gcc have been known to emit dead "lui ...%hi(...)"
15331
         instructions.  */
15332
      if (lo_pos != NULL)
15333
        {
15334
          l->fixp->fx_offset = (*lo_pos)->fx_offset;
15335
          if (l->fixp->fx_next != *lo_pos)
15336
            {
15337
              *hi_pos = l->fixp->fx_next;
15338
              l->fixp->fx_next = *lo_pos;
15339
              *lo_pos = l->fixp;
15340
            }
15341
        }
15342
    }
15343
}
15344
 
15345
/* We may have combined relocations without symbols in the N32/N64 ABI.
15346
   We have to prevent gas from dropping them.  */
15347
 
15348
int
15349
mips_force_relocation (fixS *fixp)
15350
{
15351
  if (generic_force_reloc (fixp))
15352
    return 1;
15353
 
15354 160 khays
  /* We want to keep BFD_RELOC_MICROMIPS_*_PCREL_S1 relocation,
15355
     so that the linker relaxation can update targets.  */
15356
  if (fixp->fx_r_type == BFD_RELOC_MICROMIPS_7_PCREL_S1
15357
      || fixp->fx_r_type == BFD_RELOC_MICROMIPS_10_PCREL_S1
15358
      || fixp->fx_r_type == BFD_RELOC_MICROMIPS_16_PCREL_S1)
15359
    return 1;
15360
 
15361 16 khays
  if (HAVE_NEWABI
15362
      && S_GET_SEGMENT (fixp->fx_addsy) == bfd_abs_section_ptr
15363
      && (fixp->fx_r_type == BFD_RELOC_MIPS_SUB
15364
          || hi16_reloc_p (fixp->fx_r_type)
15365
          || lo16_reloc_p (fixp->fx_r_type)))
15366
    return 1;
15367
 
15368
  return 0;
15369
}
15370
 
15371
/* Apply a fixup to the object file.  */
15372
 
15373
void
15374
md_apply_fix (fixS *fixP, valueT *valP, segT seg ATTRIBUTE_UNUSED)
15375
{
15376
  bfd_byte *buf;
15377
  long insn;
15378
  reloc_howto_type *howto;
15379
 
15380
  /* We ignore generic BFD relocations we don't know about.  */
15381
  howto = bfd_reloc_type_lookup (stdoutput, fixP->fx_r_type);
15382
  if (! howto)
15383
    return;
15384
 
15385 160 khays
  gas_assert (fixP->fx_size == 2
15386
              || fixP->fx_size == 4
15387 16 khays
              || fixP->fx_r_type == BFD_RELOC_16
15388
              || fixP->fx_r_type == BFD_RELOC_64
15389
              || fixP->fx_r_type == BFD_RELOC_CTOR
15390
              || fixP->fx_r_type == BFD_RELOC_MIPS_SUB
15391 160 khays
              || fixP->fx_r_type == BFD_RELOC_MICROMIPS_SUB
15392 16 khays
              || fixP->fx_r_type == BFD_RELOC_VTABLE_INHERIT
15393
              || fixP->fx_r_type == BFD_RELOC_VTABLE_ENTRY
15394
              || fixP->fx_r_type == BFD_RELOC_MIPS_TLS_DTPREL64);
15395
 
15396
  buf = (bfd_byte *) (fixP->fx_frag->fr_literal + fixP->fx_where);
15397
 
15398 160 khays
  gas_assert (!fixP->fx_pcrel || fixP->fx_r_type == BFD_RELOC_16_PCREL_S2
15399
              || fixP->fx_r_type == BFD_RELOC_MICROMIPS_7_PCREL_S1
15400
              || fixP->fx_r_type == BFD_RELOC_MICROMIPS_10_PCREL_S1
15401
              || fixP->fx_r_type == BFD_RELOC_MICROMIPS_16_PCREL_S1);
15402 16 khays
 
15403
  /* Don't treat parts of a composite relocation as done.  There are two
15404
     reasons for this:
15405
 
15406
     (1) The second and third parts will be against 0 (RSS_UNDEF) but
15407
         should nevertheless be emitted if the first part is.
15408
 
15409
     (2) In normal usage, composite relocations are never assembly-time
15410
         constants.  The easiest way of dealing with the pathological
15411
         exceptions is to generate a relocation against STN_UNDEF and
15412
         leave everything up to the linker.  */
15413
  if (fixP->fx_addsy == NULL && !fixP->fx_pcrel && fixP->fx_tcbit == 0)
15414
    fixP->fx_done = 1;
15415
 
15416
  switch (fixP->fx_r_type)
15417
    {
15418
    case BFD_RELOC_MIPS_TLS_GD:
15419
    case BFD_RELOC_MIPS_TLS_LDM:
15420
    case BFD_RELOC_MIPS_TLS_DTPREL32:
15421
    case BFD_RELOC_MIPS_TLS_DTPREL64:
15422
    case BFD_RELOC_MIPS_TLS_DTPREL_HI16:
15423
    case BFD_RELOC_MIPS_TLS_DTPREL_LO16:
15424
    case BFD_RELOC_MIPS_TLS_GOTTPREL:
15425 166 khays
    case BFD_RELOC_MIPS_TLS_TPREL32:
15426
    case BFD_RELOC_MIPS_TLS_TPREL64:
15427 16 khays
    case BFD_RELOC_MIPS_TLS_TPREL_HI16:
15428
    case BFD_RELOC_MIPS_TLS_TPREL_LO16:
15429 160 khays
    case BFD_RELOC_MICROMIPS_TLS_GD:
15430
    case BFD_RELOC_MICROMIPS_TLS_LDM:
15431
    case BFD_RELOC_MICROMIPS_TLS_DTPREL_HI16:
15432
    case BFD_RELOC_MICROMIPS_TLS_DTPREL_LO16:
15433
    case BFD_RELOC_MICROMIPS_TLS_GOTTPREL:
15434
    case BFD_RELOC_MICROMIPS_TLS_TPREL_HI16:
15435
    case BFD_RELOC_MICROMIPS_TLS_TPREL_LO16:
15436 166 khays
    case BFD_RELOC_MIPS16_TLS_GD:
15437
    case BFD_RELOC_MIPS16_TLS_LDM:
15438
    case BFD_RELOC_MIPS16_TLS_DTPREL_HI16:
15439
    case BFD_RELOC_MIPS16_TLS_DTPREL_LO16:
15440
    case BFD_RELOC_MIPS16_TLS_GOTTPREL:
15441
    case BFD_RELOC_MIPS16_TLS_TPREL_HI16:
15442
    case BFD_RELOC_MIPS16_TLS_TPREL_LO16:
15443 16 khays
      S_SET_THREAD_LOCAL (fixP->fx_addsy);
15444
      /* fall through */
15445
 
15446
    case BFD_RELOC_MIPS_JMP:
15447
    case BFD_RELOC_MIPS_SHIFT5:
15448
    case BFD_RELOC_MIPS_SHIFT6:
15449
    case BFD_RELOC_MIPS_GOT_DISP:
15450
    case BFD_RELOC_MIPS_GOT_PAGE:
15451
    case BFD_RELOC_MIPS_GOT_OFST:
15452
    case BFD_RELOC_MIPS_SUB:
15453
    case BFD_RELOC_MIPS_INSERT_A:
15454
    case BFD_RELOC_MIPS_INSERT_B:
15455
    case BFD_RELOC_MIPS_DELETE:
15456
    case BFD_RELOC_MIPS_HIGHEST:
15457
    case BFD_RELOC_MIPS_HIGHER:
15458
    case BFD_RELOC_MIPS_SCN_DISP:
15459
    case BFD_RELOC_MIPS_REL16:
15460
    case BFD_RELOC_MIPS_RELGOT:
15461
    case BFD_RELOC_MIPS_JALR:
15462
    case BFD_RELOC_HI16:
15463
    case BFD_RELOC_HI16_S:
15464
    case BFD_RELOC_GPREL16:
15465
    case BFD_RELOC_MIPS_LITERAL:
15466
    case BFD_RELOC_MIPS_CALL16:
15467
    case BFD_RELOC_MIPS_GOT16:
15468
    case BFD_RELOC_GPREL32:
15469
    case BFD_RELOC_MIPS_GOT_HI16:
15470
    case BFD_RELOC_MIPS_GOT_LO16:
15471
    case BFD_RELOC_MIPS_CALL_HI16:
15472
    case BFD_RELOC_MIPS_CALL_LO16:
15473
    case BFD_RELOC_MIPS16_GPREL:
15474
    case BFD_RELOC_MIPS16_GOT16:
15475
    case BFD_RELOC_MIPS16_CALL16:
15476
    case BFD_RELOC_MIPS16_HI16:
15477
    case BFD_RELOC_MIPS16_HI16_S:
15478
    case BFD_RELOC_MIPS16_JMP:
15479 160 khays
    case BFD_RELOC_MICROMIPS_JMP:
15480
    case BFD_RELOC_MICROMIPS_GOT_DISP:
15481
    case BFD_RELOC_MICROMIPS_GOT_PAGE:
15482
    case BFD_RELOC_MICROMIPS_GOT_OFST:
15483
    case BFD_RELOC_MICROMIPS_SUB:
15484
    case BFD_RELOC_MICROMIPS_HIGHEST:
15485
    case BFD_RELOC_MICROMIPS_HIGHER:
15486
    case BFD_RELOC_MICROMIPS_SCN_DISP:
15487
    case BFD_RELOC_MICROMIPS_JALR:
15488
    case BFD_RELOC_MICROMIPS_HI16:
15489
    case BFD_RELOC_MICROMIPS_HI16_S:
15490
    case BFD_RELOC_MICROMIPS_GPREL16:
15491
    case BFD_RELOC_MICROMIPS_LITERAL:
15492
    case BFD_RELOC_MICROMIPS_CALL16:
15493
    case BFD_RELOC_MICROMIPS_GOT16:
15494
    case BFD_RELOC_MICROMIPS_GOT_HI16:
15495
    case BFD_RELOC_MICROMIPS_GOT_LO16:
15496
    case BFD_RELOC_MICROMIPS_CALL_HI16:
15497
    case BFD_RELOC_MICROMIPS_CALL_LO16:
15498 16 khays
      /* Nothing needed to do.  The value comes from the reloc entry.  */
15499
      break;
15500
 
15501
    case BFD_RELOC_64:
15502
      /* This is handled like BFD_RELOC_32, but we output a sign
15503
         extended value if we are only 32 bits.  */
15504
      if (fixP->fx_done)
15505
        {
15506
          if (8 <= sizeof (valueT))
15507
            md_number_to_chars ((char *) buf, *valP, 8);
15508
          else
15509
            {
15510
              valueT hiv;
15511
 
15512
              if ((*valP & 0x80000000) != 0)
15513
                hiv = 0xffffffff;
15514
              else
15515
                hiv = 0;
15516
              md_number_to_chars ((char *)(buf + (target_big_endian ? 4 : 0)),
15517
                                  *valP, 4);
15518
              md_number_to_chars ((char *)(buf + (target_big_endian ? 0 : 4)),
15519
                                  hiv, 4);
15520
            }
15521
        }
15522
      break;
15523
 
15524
    case BFD_RELOC_RVA:
15525
    case BFD_RELOC_32:
15526
    case BFD_RELOC_16:
15527
      /* If we are deleting this reloc entry, we must fill in the
15528
         value now.  This can happen if we have a .word which is not
15529
         resolved when it appears but is later defined.  */
15530
      if (fixP->fx_done)
15531
        md_number_to_chars ((char *) buf, *valP, fixP->fx_size);
15532
      break;
15533
 
15534
    case BFD_RELOC_LO16:
15535
    case BFD_RELOC_MIPS16_LO16:
15536 160 khays
    case BFD_RELOC_MICROMIPS_LO16:
15537 16 khays
      /* FIXME: Now that embedded-PIC is gone, some of this code/comment
15538
         may be safe to remove, but if so it's not obvious.  */
15539
      /* When handling an embedded PIC switch statement, we can wind
15540
         up deleting a LO16 reloc.  See the 'o' case in mips_ip.  */
15541
      if (fixP->fx_done)
15542
        {
15543
          if (*valP + 0x8000 > 0xffff)
15544
            as_bad_where (fixP->fx_file, fixP->fx_line,
15545
                          _("relocation overflow"));
15546 160 khays
          /* 32-bit microMIPS instructions are divided into two halfwords.
15547
             Relocations always refer to the second halfword, regardless
15548
             of endianness.  */
15549
          if (target_big_endian || fixP->fx_r_type == BFD_RELOC_MICROMIPS_LO16)
15550 16 khays
            buf += 2;
15551
          md_number_to_chars ((char *) buf, *valP, 2);
15552
        }
15553
      break;
15554
 
15555
    case BFD_RELOC_16_PCREL_S2:
15556
      if ((*valP & 0x3) != 0)
15557
        as_bad_where (fixP->fx_file, fixP->fx_line,
15558
                      _("Branch to misaligned address (%lx)"), (long) *valP);
15559
 
15560
      /* We need to save the bits in the instruction since fixup_segment()
15561
         might be deleting the relocation entry (i.e., a branch within
15562
         the current segment).  */
15563
      if (! fixP->fx_done)
15564
        break;
15565
 
15566
      /* Update old instruction data.  */
15567
      if (target_big_endian)
15568
        insn = (buf[0] << 24) | (buf[1] << 16) | (buf[2] << 8) | buf[3];
15569
      else
15570
        insn = (buf[3] << 24) | (buf[2] << 16) | (buf[1] << 8) | buf[0];
15571
 
15572
      if (*valP + 0x20000 <= 0x3ffff)
15573
        {
15574
          insn |= (*valP >> 2) & 0xffff;
15575
          md_number_to_chars ((char *) buf, insn, 4);
15576
        }
15577
      else if (mips_pic == NO_PIC
15578
               && fixP->fx_done
15579
               && fixP->fx_frag->fr_address >= text_section->vma
15580
               && (fixP->fx_frag->fr_address
15581
                   < text_section->vma + bfd_get_section_size (text_section))
15582
               && ((insn & 0xffff0000) == 0x10000000     /* beq $0,$0 */
15583
                   || (insn & 0xffff0000) == 0x04010000  /* bgez $0 */
15584
                   || (insn & 0xffff0000) == 0x04110000)) /* bgezal $0 */
15585
        {
15586
          /* The branch offset is too large.  If this is an
15587
             unconditional branch, and we are not generating PIC code,
15588
             we can convert it to an absolute jump instruction.  */
15589
          if ((insn & 0xffff0000) == 0x04110000)         /* bgezal $0 */
15590
            insn = 0x0c000000;  /* jal */
15591
          else
15592
            insn = 0x08000000;  /* j */
15593
          fixP->fx_r_type = BFD_RELOC_MIPS_JMP;
15594
          fixP->fx_done = 0;
15595
          fixP->fx_addsy = section_symbol (text_section);
15596
          *valP += md_pcrel_from (fixP);
15597
          md_number_to_chars ((char *) buf, insn, 4);
15598
        }
15599
      else
15600
        {
15601
          /* If we got here, we have branch-relaxation disabled,
15602
             and there's nothing we can do to fix this instruction
15603
             without turning it into a longer sequence.  */
15604
          as_bad_where (fixP->fx_file, fixP->fx_line,
15605
                        _("Branch out of range"));
15606
        }
15607
      break;
15608
 
15609 160 khays
    case BFD_RELOC_MICROMIPS_7_PCREL_S1:
15610
    case BFD_RELOC_MICROMIPS_10_PCREL_S1:
15611
    case BFD_RELOC_MICROMIPS_16_PCREL_S1:
15612
      /* We adjust the offset back to even.  */
15613
      if ((*valP & 0x1) != 0)
15614
        --(*valP);
15615
 
15616
      if (! fixP->fx_done)
15617
        break;
15618
 
15619
      /* Should never visit here, because we keep the relocation.  */
15620
      abort ();
15621
      break;
15622
 
15623 16 khays
    case BFD_RELOC_VTABLE_INHERIT:
15624
      fixP->fx_done = 0;
15625
      if (fixP->fx_addsy
15626
          && !S_IS_DEFINED (fixP->fx_addsy)
15627
          && !S_IS_WEAK (fixP->fx_addsy))
15628
        S_SET_WEAK (fixP->fx_addsy);
15629
      break;
15630
 
15631
    case BFD_RELOC_VTABLE_ENTRY:
15632
      fixP->fx_done = 0;
15633
      break;
15634
 
15635
    default:
15636
      internalError ();
15637
    }
15638
 
15639
  /* Remember value for tc_gen_reloc.  */
15640
  fixP->fx_addnumber = *valP;
15641
}
15642
 
15643
static symbolS *
15644
get_symbol (void)
15645
{
15646
  int c;
15647
  char *name;
15648
  symbolS *p;
15649
 
15650
  name = input_line_pointer;
15651
  c = get_symbol_end ();
15652
  p = (symbolS *) symbol_find_or_make (name);
15653
  *input_line_pointer = c;
15654
  return p;
15655
}
15656
 
15657
/* Align the current frag to a given power of two.  If a particular
15658
   fill byte should be used, FILL points to an integer that contains
15659
   that byte, otherwise FILL is null.
15660
 
15661 166 khays
   This function used to have the comment:
15662 16 khays
 
15663 166 khays
      The MIPS assembler also automatically adjusts any preceding label.
15664
 
15665
   The implementation therefore applied the adjustment to a maximum of
15666
   one label.  However, other label adjustments are applied to batches
15667
   of labels, and adjusting just one caused problems when new labels
15668
   were added for the sake of debugging or unwind information.
15669
   We therefore adjust all preceding labels (given as LABELS) instead.  */
15670
 
15671 16 khays
static void
15672 166 khays
mips_align (int to, int *fill, struct insn_label_list *labels)
15673 16 khays
{
15674
  mips_emit_delays ();
15675 160 khays
  mips_record_compressed_mode ();
15676 16 khays
  if (fill == NULL && subseg_text_p (now_seg))
15677
    frag_align_code (to, 0);
15678
  else
15679
    frag_align (to, fill ? *fill : 0, 0);
15680
  record_alignment (now_seg, to);
15681 166 khays
  mips_move_labels (labels, FALSE);
15682 16 khays
}
15683
 
15684
/* Align to a given power of two.  .align 0 turns off the automatic
15685
   alignment used by the data creating pseudo-ops.  */
15686
 
15687
static void
15688
s_align (int x ATTRIBUTE_UNUSED)
15689
{
15690
  int temp, fill_value, *fill_ptr;
15691
  long max_alignment = 28;
15692
 
15693
  /* o Note that the assembler pulls down any immediately preceding label
15694
       to the aligned address.
15695
     o It's not documented but auto alignment is reinstated by
15696
       a .align pseudo instruction.
15697
     o Note also that after auto alignment is turned off the mips assembler
15698
       issues an error on attempt to assemble an improperly aligned data item.
15699
       We don't.  */
15700
 
15701
  temp = get_absolute_expression ();
15702
  if (temp > max_alignment)
15703
    as_bad (_("Alignment too large: %d. assumed."), temp = max_alignment);
15704
  else if (temp < 0)
15705
    {
15706
      as_warn (_("Alignment negative: 0 assumed."));
15707
      temp = 0;
15708
    }
15709
  if (*input_line_pointer == ',')
15710
    {
15711
      ++input_line_pointer;
15712
      fill_value = get_absolute_expression ();
15713
      fill_ptr = &fill_value;
15714
    }
15715
  else
15716
    fill_ptr = 0;
15717
  if (temp)
15718
    {
15719
      segment_info_type *si = seg_info (now_seg);
15720
      struct insn_label_list *l = si->label_list;
15721
      /* Auto alignment should be switched on by next section change.  */
15722
      auto_align = 1;
15723 166 khays
      mips_align (temp, fill_ptr, l);
15724 16 khays
    }
15725
  else
15726
    {
15727
      auto_align = 0;
15728
    }
15729
 
15730
  demand_empty_rest_of_line ();
15731
}
15732
 
15733
static void
15734
s_change_sec (int sec)
15735
{
15736
  segT seg;
15737
 
15738
#ifdef OBJ_ELF
15739
  /* The ELF backend needs to know that we are changing sections, so
15740
     that .previous works correctly.  We could do something like check
15741
     for an obj_section_change_hook macro, but that might be confusing
15742
     as it would not be appropriate to use it in the section changing
15743
     functions in read.c, since obj-elf.c intercepts those.  FIXME:
15744
     This should be cleaner, somehow.  */
15745
  if (IS_ELF)
15746
    obj_elf_section_change_hook ();
15747
#endif
15748
 
15749
  mips_emit_delays ();
15750
 
15751
  switch (sec)
15752
    {
15753
    case 't':
15754
      s_text (0);
15755
      break;
15756
    case 'd':
15757
      s_data (0);
15758
      break;
15759
    case 'b':
15760
      subseg_set (bss_section, (subsegT) get_absolute_expression ());
15761
      demand_empty_rest_of_line ();
15762
      break;
15763
 
15764
    case 'r':
15765
      seg = subseg_new (RDATA_SECTION_NAME,
15766
                        (subsegT) get_absolute_expression ());
15767
      if (IS_ELF)
15768
        {
15769
          bfd_set_section_flags (stdoutput, seg, (SEC_ALLOC | SEC_LOAD
15770
                                                  | SEC_READONLY | SEC_RELOC
15771
                                                  | SEC_DATA));
15772
          if (strncmp (TARGET_OS, "elf", 3) != 0)
15773
            record_alignment (seg, 4);
15774
        }
15775
      demand_empty_rest_of_line ();
15776
      break;
15777
 
15778
    case 's':
15779
      seg = subseg_new (".sdata", (subsegT) get_absolute_expression ());
15780
      if (IS_ELF)
15781
        {
15782
          bfd_set_section_flags (stdoutput, seg,
15783
                                 SEC_ALLOC | SEC_LOAD | SEC_RELOC | SEC_DATA);
15784
          if (strncmp (TARGET_OS, "elf", 3) != 0)
15785
            record_alignment (seg, 4);
15786
        }
15787
      demand_empty_rest_of_line ();
15788
      break;
15789
 
15790
    case 'B':
15791
      seg = subseg_new (".sbss", (subsegT) get_absolute_expression ());
15792
      if (IS_ELF)
15793
        {
15794
          bfd_set_section_flags (stdoutput, seg, SEC_ALLOC);
15795
          if (strncmp (TARGET_OS, "elf", 3) != 0)
15796
            record_alignment (seg, 4);
15797
        }
15798
      demand_empty_rest_of_line ();
15799
      break;
15800
    }
15801
 
15802
  auto_align = 1;
15803
}
15804
 
15805
void
15806
s_change_section (int ignore ATTRIBUTE_UNUSED)
15807
{
15808
#ifdef OBJ_ELF
15809
  char *section_name;
15810
  char c;
15811
  char next_c = 0;
15812
  int section_type;
15813
  int section_flag;
15814
  int section_entry_size;
15815
  int section_alignment;
15816
 
15817
  if (!IS_ELF)
15818
    return;
15819
 
15820
  section_name = input_line_pointer;
15821
  c = get_symbol_end ();
15822
  if (c)
15823
    next_c = *(input_line_pointer + 1);
15824
 
15825
  /* Do we have .section Name<,"flags">?  */
15826
  if (c != ',' || (c == ',' && next_c == '"'))
15827
    {
15828
      /* just after name is now '\0'.  */
15829
      *input_line_pointer = c;
15830
      input_line_pointer = section_name;
15831
      obj_elf_section (ignore);
15832
      return;
15833
    }
15834
  input_line_pointer++;
15835
 
15836
  /* Do we have .section Name<,type><,flag><,entry_size><,alignment>  */
15837
  if (c == ',')
15838
    section_type = get_absolute_expression ();
15839
  else
15840
    section_type = 0;
15841
  if (*input_line_pointer++ == ',')
15842
    section_flag = get_absolute_expression ();
15843
  else
15844
    section_flag = 0;
15845
  if (*input_line_pointer++ == ',')
15846
    section_entry_size = get_absolute_expression ();
15847
  else
15848
    section_entry_size = 0;
15849
  if (*input_line_pointer++ == ',')
15850
    section_alignment = get_absolute_expression ();
15851
  else
15852
    section_alignment = 0;
15853
  /* FIXME: really ignore?  */
15854
  (void) section_alignment;
15855
 
15856
  section_name = xstrdup (section_name);
15857
 
15858
  /* When using the generic form of .section (as implemented by obj-elf.c),
15859
     there's no way to set the section type to SHT_MIPS_DWARF.  Users have
15860
     traditionally had to fall back on the more common @progbits instead.
15861
 
15862
     There's nothing really harmful in this, since bfd will correct
15863
     SHT_PROGBITS to SHT_MIPS_DWARF before writing out the file.  But it
15864
     means that, for backwards compatibility, the special_section entries
15865
     for dwarf sections must use SHT_PROGBITS rather than SHT_MIPS_DWARF.
15866
 
15867
     Even so, we shouldn't force users of the MIPS .section syntax to
15868
     incorrectly label the sections as SHT_PROGBITS.  The best compromise
15869
     seems to be to map SHT_MIPS_DWARF to SHT_PROGBITS before calling the
15870
     generic type-checking code.  */
15871
  if (section_type == SHT_MIPS_DWARF)
15872
    section_type = SHT_PROGBITS;
15873
 
15874
  obj_elf_change_section (section_name, section_type, section_flag,
15875
                          section_entry_size, 0, 0, 0);
15876
 
15877
  if (now_seg->name != section_name)
15878
    free (section_name);
15879
#endif /* OBJ_ELF */
15880
}
15881
 
15882
void
15883
mips_enable_auto_align (void)
15884
{
15885
  auto_align = 1;
15886
}
15887
 
15888
static void
15889
s_cons (int log_size)
15890
{
15891
  segment_info_type *si = seg_info (now_seg);
15892
  struct insn_label_list *l = si->label_list;
15893
 
15894
  mips_emit_delays ();
15895
  if (log_size > 0 && auto_align)
15896 166 khays
    mips_align (log_size, 0, l);
15897 16 khays
  cons (1 << log_size);
15898
  mips_clear_insn_labels ();
15899
}
15900
 
15901
static void
15902
s_float_cons (int type)
15903
{
15904
  segment_info_type *si = seg_info (now_seg);
15905
  struct insn_label_list *l = si->label_list;
15906
 
15907
  mips_emit_delays ();
15908
 
15909
  if (auto_align)
15910
    {
15911
      if (type == 'd')
15912 166 khays
        mips_align (3, 0, l);
15913 16 khays
      else
15914 166 khays
        mips_align (2, 0, l);
15915 16 khays
    }
15916
 
15917
  float_cons (type);
15918
  mips_clear_insn_labels ();
15919
}
15920
 
15921
/* Handle .globl.  We need to override it because on Irix 5 you are
15922
   permitted to say
15923
       .globl foo .text
15924
   where foo is an undefined symbol, to mean that foo should be
15925
   considered to be the address of a function.  */
15926
 
15927
static void
15928
s_mips_globl (int x ATTRIBUTE_UNUSED)
15929
{
15930
  char *name;
15931
  int c;
15932
  symbolS *symbolP;
15933
  flagword flag;
15934
 
15935
  do
15936
    {
15937
      name = input_line_pointer;
15938
      c = get_symbol_end ();
15939
      symbolP = symbol_find_or_make (name);
15940
      S_SET_EXTERNAL (symbolP);
15941
 
15942
      *input_line_pointer = c;
15943
      SKIP_WHITESPACE ();
15944
 
15945
      /* On Irix 5, every global symbol that is not explicitly labelled as
15946
         being a function is apparently labelled as being an object.  */
15947
      flag = BSF_OBJECT;
15948
 
15949
      if (!is_end_of_line[(unsigned char) *input_line_pointer]
15950
          && (*input_line_pointer != ','))
15951
        {
15952
          char *secname;
15953
          asection *sec;
15954
 
15955
          secname = input_line_pointer;
15956
          c = get_symbol_end ();
15957
          sec = bfd_get_section_by_name (stdoutput, secname);
15958
          if (sec == NULL)
15959
            as_bad (_("%s: no such section"), secname);
15960
          *input_line_pointer = c;
15961
 
15962
          if (sec != NULL && (sec->flags & SEC_CODE) != 0)
15963
            flag = BSF_FUNCTION;
15964
        }
15965
 
15966
      symbol_get_bfdsym (symbolP)->flags |= flag;
15967
 
15968
      c = *input_line_pointer;
15969
      if (c == ',')
15970
        {
15971
          input_line_pointer++;
15972
          SKIP_WHITESPACE ();
15973
          if (is_end_of_line[(unsigned char) *input_line_pointer])
15974
            c = '\n';
15975
        }
15976
    }
15977
  while (c == ',');
15978
 
15979
  demand_empty_rest_of_line ();
15980
}
15981
 
15982
static void
15983
s_option (int x ATTRIBUTE_UNUSED)
15984
{
15985
  char *opt;
15986
  char c;
15987
 
15988
  opt = input_line_pointer;
15989
  c = get_symbol_end ();
15990
 
15991
  if (*opt == 'O')
15992
    {
15993
      /* FIXME: What does this mean?  */
15994
    }
15995
  else if (strncmp (opt, "pic", 3) == 0)
15996
    {
15997
      int i;
15998
 
15999
      i = atoi (opt + 3);
16000
      if (i == 0)
16001
        mips_pic = NO_PIC;
16002
      else if (i == 2)
16003
        {
16004 163 khays
          mips_pic = SVR4_PIC;
16005 16 khays
          mips_abicalls = TRUE;
16006
        }
16007
      else
16008
        as_bad (_(".option pic%d not supported"), i);
16009
 
16010
      if (mips_pic == SVR4_PIC)
16011
        {
16012
          if (g_switch_seen && g_switch_value != 0)
16013
            as_warn (_("-G may not be used with SVR4 PIC code"));
16014
          g_switch_value = 0;
16015
          bfd_set_gp_size (stdoutput, 0);
16016
        }
16017
    }
16018
  else
16019
    as_warn (_("Unrecognized option \"%s\""), opt);
16020
 
16021
  *input_line_pointer = c;
16022
  demand_empty_rest_of_line ();
16023
}
16024
 
16025
/* This structure is used to hold a stack of .set values.  */
16026
 
16027
struct mips_option_stack
16028
{
16029
  struct mips_option_stack *next;
16030
  struct mips_set_options options;
16031
};
16032
 
16033
static struct mips_option_stack *mips_opts_stack;
16034
 
16035
/* Handle the .set pseudo-op.  */
16036
 
16037
static void
16038
s_mipsset (int x ATTRIBUTE_UNUSED)
16039
{
16040
  char *name = input_line_pointer, ch;
16041
 
16042
  while (!is_end_of_line[(unsigned char) *input_line_pointer])
16043
    ++input_line_pointer;
16044
  ch = *input_line_pointer;
16045
  *input_line_pointer = '\0';
16046
 
16047
  if (strcmp (name, "reorder") == 0)
16048
    {
16049
      if (mips_opts.noreorder)
16050
        end_noreorder ();
16051
    }
16052
  else if (strcmp (name, "noreorder") == 0)
16053
    {
16054
      if (!mips_opts.noreorder)
16055
        start_noreorder ();
16056
    }
16057
  else if (strncmp (name, "at=", 3) == 0)
16058
    {
16059
      char *s = name + 3;
16060
 
16061
      if (!reg_lookup (&s, RTYPE_NUM | RTYPE_GP, &mips_opts.at))
16062
        as_bad (_("Unrecognized register name `%s'"), s);
16063
    }
16064
  else if (strcmp (name, "at") == 0)
16065
    {
16066
      mips_opts.at = ATREG;
16067
    }
16068
  else if (strcmp (name, "noat") == 0)
16069
    {
16070
      mips_opts.at = ZERO;
16071
    }
16072
  else if (strcmp (name, "macro") == 0)
16073
    {
16074
      mips_opts.warn_about_macros = 0;
16075
    }
16076
  else if (strcmp (name, "nomacro") == 0)
16077
    {
16078
      if (mips_opts.noreorder == 0)
16079
        as_bad (_("`noreorder' must be set before `nomacro'"));
16080
      mips_opts.warn_about_macros = 1;
16081
    }
16082
  else if (strcmp (name, "move") == 0 || strcmp (name, "novolatile") == 0)
16083
    {
16084
      mips_opts.nomove = 0;
16085
    }
16086
  else if (strcmp (name, "nomove") == 0 || strcmp (name, "volatile") == 0)
16087
    {
16088
      mips_opts.nomove = 1;
16089
    }
16090
  else if (strcmp (name, "bopt") == 0)
16091
    {
16092
      mips_opts.nobopt = 0;
16093
    }
16094
  else if (strcmp (name, "nobopt") == 0)
16095
    {
16096
      mips_opts.nobopt = 1;
16097
    }
16098
  else if (strcmp (name, "gp=default") == 0)
16099
    mips_opts.gp32 = file_mips_gp32;
16100
  else if (strcmp (name, "gp=32") == 0)
16101
    mips_opts.gp32 = 1;
16102
  else if (strcmp (name, "gp=64") == 0)
16103
    {
16104
      if (!ISA_HAS_64BIT_REGS (mips_opts.isa))
16105
        as_warn (_("%s isa does not support 64-bit registers"),
16106
                 mips_cpu_info_from_isa (mips_opts.isa)->name);
16107
      mips_opts.gp32 = 0;
16108
    }
16109
  else if (strcmp (name, "fp=default") == 0)
16110
    mips_opts.fp32 = file_mips_fp32;
16111
  else if (strcmp (name, "fp=32") == 0)
16112
    mips_opts.fp32 = 1;
16113
  else if (strcmp (name, "fp=64") == 0)
16114
    {
16115
      if (!ISA_HAS_64BIT_FPRS (mips_opts.isa))
16116
        as_warn (_("%s isa does not support 64-bit floating point registers"),
16117
                 mips_cpu_info_from_isa (mips_opts.isa)->name);
16118
      mips_opts.fp32 = 0;
16119
    }
16120
  else if (strcmp (name, "softfloat") == 0)
16121
    mips_opts.soft_float = 1;
16122
  else if (strcmp (name, "hardfloat") == 0)
16123
    mips_opts.soft_float = 0;
16124
  else if (strcmp (name, "singlefloat") == 0)
16125
    mips_opts.single_float = 1;
16126
  else if (strcmp (name, "doublefloat") == 0)
16127
    mips_opts.single_float = 0;
16128
  else if (strcmp (name, "mips16") == 0
16129
           || strcmp (name, "MIPS-16") == 0)
16130 160 khays
    {
16131
      if (mips_opts.micromips == 1)
16132
        as_fatal (_("`mips16' cannot be used with `micromips'"));
16133
      mips_opts.mips16 = 1;
16134
    }
16135 16 khays
  else if (strcmp (name, "nomips16") == 0
16136
           || strcmp (name, "noMIPS-16") == 0)
16137
    mips_opts.mips16 = 0;
16138 160 khays
  else if (strcmp (name, "micromips") == 0)
16139
    {
16140
      if (mips_opts.mips16 == 1)
16141
        as_fatal (_("`micromips' cannot be used with `mips16'"));
16142
      mips_opts.micromips = 1;
16143
    }
16144
  else if (strcmp (name, "nomicromips") == 0)
16145
    mips_opts.micromips = 0;
16146 16 khays
  else if (strcmp (name, "smartmips") == 0)
16147
    {
16148
      if (!ISA_SUPPORTS_SMARTMIPS)
16149
        as_warn (_("%s ISA does not support SmartMIPS ASE"),
16150
                 mips_cpu_info_from_isa (mips_opts.isa)->name);
16151
      mips_opts.ase_smartmips = 1;
16152
    }
16153
  else if (strcmp (name, "nosmartmips") == 0)
16154
    mips_opts.ase_smartmips = 0;
16155
  else if (strcmp (name, "mips3d") == 0)
16156
    mips_opts.ase_mips3d = 1;
16157
  else if (strcmp (name, "nomips3d") == 0)
16158
    mips_opts.ase_mips3d = 0;
16159
  else if (strcmp (name, "mdmx") == 0)
16160
    mips_opts.ase_mdmx = 1;
16161
  else if (strcmp (name, "nomdmx") == 0)
16162
    mips_opts.ase_mdmx = 0;
16163
  else if (strcmp (name, "dsp") == 0)
16164
    {
16165
      if (!ISA_SUPPORTS_DSP_ASE)
16166
        as_warn (_("%s ISA does not support DSP ASE"),
16167
                 mips_cpu_info_from_isa (mips_opts.isa)->name);
16168
      mips_opts.ase_dsp = 1;
16169
      mips_opts.ase_dspr2 = 0;
16170
    }
16171
  else if (strcmp (name, "nodsp") == 0)
16172
    {
16173
      mips_opts.ase_dsp = 0;
16174
      mips_opts.ase_dspr2 = 0;
16175
    }
16176
  else if (strcmp (name, "dspr2") == 0)
16177
    {
16178
      if (!ISA_SUPPORTS_DSPR2_ASE)
16179
        as_warn (_("%s ISA does not support DSP R2 ASE"),
16180
                 mips_cpu_info_from_isa (mips_opts.isa)->name);
16181
      mips_opts.ase_dspr2 = 1;
16182
      mips_opts.ase_dsp = 1;
16183
    }
16184
  else if (strcmp (name, "nodspr2") == 0)
16185
    {
16186
      mips_opts.ase_dspr2 = 0;
16187
      mips_opts.ase_dsp = 0;
16188
    }
16189
  else if (strcmp (name, "mt") == 0)
16190
    {
16191
      if (!ISA_SUPPORTS_MT_ASE)
16192
        as_warn (_("%s ISA does not support MT ASE"),
16193
                 mips_cpu_info_from_isa (mips_opts.isa)->name);
16194
      mips_opts.ase_mt = 1;
16195
    }
16196
  else if (strcmp (name, "nomt") == 0)
16197
    mips_opts.ase_mt = 0;
16198 160 khays
  else if (strcmp (name, "mcu") == 0)
16199
    mips_opts.ase_mcu = 1;
16200
  else if (strcmp (name, "nomcu") == 0)
16201
    mips_opts.ase_mcu = 0;
16202 16 khays
  else if (strncmp (name, "mips", 4) == 0 || strncmp (name, "arch=", 5) == 0)
16203
    {
16204
      int reset = 0;
16205
 
16206
      /* Permit the user to change the ISA and architecture on the fly.
16207
         Needless to say, misuse can cause serious problems.  */
16208
      if (strcmp (name, "mips0") == 0 || strcmp (name, "arch=default") == 0)
16209
        {
16210
          reset = 1;
16211
          mips_opts.isa = file_mips_isa;
16212
          mips_opts.arch = file_mips_arch;
16213
        }
16214
      else if (strncmp (name, "arch=", 5) == 0)
16215
        {
16216
          const struct mips_cpu_info *p;
16217
 
16218
          p = mips_parse_cpu("internal use", name + 5);
16219
          if (!p)
16220
            as_bad (_("unknown architecture %s"), name + 5);
16221
          else
16222
            {
16223
              mips_opts.arch = p->cpu;
16224
              mips_opts.isa = p->isa;
16225
            }
16226
        }
16227
      else if (strncmp (name, "mips", 4) == 0)
16228
        {
16229
          const struct mips_cpu_info *p;
16230
 
16231
          p = mips_parse_cpu("internal use", name);
16232
          if (!p)
16233
            as_bad (_("unknown ISA level %s"), name + 4);
16234
          else
16235
            {
16236
              mips_opts.arch = p->cpu;
16237
              mips_opts.isa = p->isa;
16238
            }
16239
        }
16240
      else
16241
        as_bad (_("unknown ISA or architecture %s"), name);
16242
 
16243
      switch (mips_opts.isa)
16244
        {
16245
        case  0:
16246
          break;
16247
        case ISA_MIPS1:
16248
        case ISA_MIPS2:
16249
        case ISA_MIPS32:
16250
        case ISA_MIPS32R2:
16251
          mips_opts.gp32 = 1;
16252
          mips_opts.fp32 = 1;
16253
          break;
16254
        case ISA_MIPS3:
16255
        case ISA_MIPS4:
16256
        case ISA_MIPS5:
16257
        case ISA_MIPS64:
16258
        case ISA_MIPS64R2:
16259
          mips_opts.gp32 = 0;
16260
          mips_opts.fp32 = 0;
16261
          break;
16262
        default:
16263
          as_bad (_("unknown ISA level %s"), name + 4);
16264
          break;
16265
        }
16266
      if (reset)
16267
        {
16268
          mips_opts.gp32 = file_mips_gp32;
16269
          mips_opts.fp32 = file_mips_fp32;
16270
        }
16271
    }
16272
  else if (strcmp (name, "autoextend") == 0)
16273
    mips_opts.noautoextend = 0;
16274
  else if (strcmp (name, "noautoextend") == 0)
16275
    mips_opts.noautoextend = 1;
16276
  else if (strcmp (name, "push") == 0)
16277
    {
16278
      struct mips_option_stack *s;
16279
 
16280
      s = (struct mips_option_stack *) xmalloc (sizeof *s);
16281
      s->next = mips_opts_stack;
16282
      s->options = mips_opts;
16283
      mips_opts_stack = s;
16284
    }
16285
  else if (strcmp (name, "pop") == 0)
16286
    {
16287
      struct mips_option_stack *s;
16288
 
16289
      s = mips_opts_stack;
16290
      if (s == NULL)
16291
        as_bad (_(".set pop with no .set push"));
16292
      else
16293
        {
16294
          /* If we're changing the reorder mode we need to handle
16295
             delay slots correctly.  */
16296
          if (s->options.noreorder && ! mips_opts.noreorder)
16297
            start_noreorder ();
16298
          else if (! s->options.noreorder && mips_opts.noreorder)
16299
            end_noreorder ();
16300
 
16301
          mips_opts = s->options;
16302
          mips_opts_stack = s->next;
16303
          free (s);
16304
        }
16305
    }
16306
  else if (strcmp (name, "sym32") == 0)
16307
    mips_opts.sym32 = TRUE;
16308
  else if (strcmp (name, "nosym32") == 0)
16309
    mips_opts.sym32 = FALSE;
16310
  else if (strchr (name, ','))
16311
    {
16312
      /* Generic ".set" directive; use the generic handler.  */
16313
      *input_line_pointer = ch;
16314
      input_line_pointer = name;
16315
      s_set (0);
16316
      return;
16317
    }
16318
  else
16319
    {
16320
      as_warn (_("Tried to set unrecognized symbol: %s\n"), name);
16321
    }
16322
  *input_line_pointer = ch;
16323
  demand_empty_rest_of_line ();
16324
}
16325
 
16326
/* Handle the .abicalls pseudo-op.  I believe this is equivalent to
16327
   .option pic2.  It means to generate SVR4 PIC calls.  */
16328
 
16329
static void
16330
s_abicalls (int ignore ATTRIBUTE_UNUSED)
16331
{
16332
  mips_pic = SVR4_PIC;
16333
  mips_abicalls = TRUE;
16334
 
16335
  if (g_switch_seen && g_switch_value != 0)
16336
    as_warn (_("-G may not be used with SVR4 PIC code"));
16337
  g_switch_value = 0;
16338
 
16339
  bfd_set_gp_size (stdoutput, 0);
16340
  demand_empty_rest_of_line ();
16341
}
16342
 
16343
/* Handle the .cpload pseudo-op.  This is used when generating SVR4
16344
   PIC code.  It sets the $gp register for the function based on the
16345
   function address, which is in the register named in the argument.
16346
   This uses a relocation against _gp_disp, which is handled specially
16347
   by the linker.  The result is:
16348
        lui     $gp,%hi(_gp_disp)
16349
        addiu   $gp,$gp,%lo(_gp_disp)
16350
        addu    $gp,$gp,.cpload argument
16351
   The .cpload argument is normally $25 == $t9.
16352
 
16353
   The -mno-shared option changes this to:
16354
        lui     $gp,%hi(__gnu_local_gp)
16355
        addiu   $gp,$gp,%lo(__gnu_local_gp)
16356
   and the argument is ignored.  This saves an instruction, but the
16357
   resulting code is not position independent; it uses an absolute
16358
   address for __gnu_local_gp.  Thus code assembled with -mno-shared
16359
   can go into an ordinary executable, but not into a shared library.  */
16360
 
16361
static void
16362
s_cpload (int ignore ATTRIBUTE_UNUSED)
16363
{
16364
  expressionS ex;
16365
  int reg;
16366
  int in_shared;
16367
 
16368
  /* If we are not generating SVR4 PIC code, or if this is NewABI code,
16369
     .cpload is ignored.  */
16370
  if (mips_pic != SVR4_PIC || HAVE_NEWABI)
16371
    {
16372
      s_ignore (0);
16373
      return;
16374
    }
16375
 
16376
  /* .cpload should be in a .set noreorder section.  */
16377
  if (mips_opts.noreorder == 0)
16378
    as_warn (_(".cpload not in noreorder section"));
16379
 
16380
  reg = tc_get_register (0);
16381
 
16382
  /* If we need to produce a 64-bit address, we are better off using
16383
     the default instruction sequence.  */
16384
  in_shared = mips_in_shared || HAVE_64BIT_SYMBOLS;
16385
 
16386
  ex.X_op = O_symbol;
16387
  ex.X_add_symbol = symbol_find_or_make (in_shared ? "_gp_disp" :
16388
                                         "__gnu_local_gp");
16389
  ex.X_op_symbol = NULL;
16390
  ex.X_add_number = 0;
16391
 
16392
  /* In ELF, this symbol is implicitly an STT_OBJECT symbol.  */
16393
  symbol_get_bfdsym (ex.X_add_symbol)->flags |= BSF_OBJECT;
16394
 
16395
  macro_start ();
16396
  macro_build_lui (&ex, mips_gp_register);
16397
  macro_build (&ex, "addiu", "t,r,j", mips_gp_register,
16398
               mips_gp_register, BFD_RELOC_LO16);
16399
  if (in_shared)
16400
    macro_build (NULL, "addu", "d,v,t", mips_gp_register,
16401
                 mips_gp_register, reg);
16402
  macro_end ();
16403
 
16404
  demand_empty_rest_of_line ();
16405
}
16406
 
16407
/* Handle the .cpsetup pseudo-op defined for NewABI PIC code.  The syntax is:
16408
     .cpsetup $reg1, offset|$reg2, label
16409
 
16410
   If offset is given, this results in:
16411
     sd         $gp, offset($sp)
16412
     lui        $gp, %hi(%neg(%gp_rel(label)))
16413
     addiu      $gp, $gp, %lo(%neg(%gp_rel(label)))
16414
     daddu      $gp, $gp, $reg1
16415
 
16416
   If $reg2 is given, this results in:
16417
     daddu      $reg2, $gp, $0
16418
     lui        $gp, %hi(%neg(%gp_rel(label)))
16419
     addiu      $gp, $gp, %lo(%neg(%gp_rel(label)))
16420
     daddu      $gp, $gp, $reg1
16421
   $reg1 is normally $25 == $t9.
16422
 
16423
   The -mno-shared option replaces the last three instructions with
16424
        lui     $gp,%hi(_gp)
16425
        addiu   $gp,$gp,%lo(_gp)  */
16426
 
16427
static void
16428
s_cpsetup (int ignore ATTRIBUTE_UNUSED)
16429
{
16430
  expressionS ex_off;
16431
  expressionS ex_sym;
16432
  int reg1;
16433
 
16434
  /* If we are not generating SVR4 PIC code, .cpsetup is ignored.
16435
     We also need NewABI support.  */
16436
  if (mips_pic != SVR4_PIC || ! HAVE_NEWABI)
16437
    {
16438
      s_ignore (0);
16439
      return;
16440
    }
16441
 
16442
  reg1 = tc_get_register (0);
16443
  SKIP_WHITESPACE ();
16444
  if (*input_line_pointer != ',')
16445
    {
16446
      as_bad (_("missing argument separator ',' for .cpsetup"));
16447
      return;
16448
    }
16449
  else
16450
    ++input_line_pointer;
16451
  SKIP_WHITESPACE ();
16452
  if (*input_line_pointer == '$')
16453
    {
16454
      mips_cpreturn_register = tc_get_register (0);
16455
      mips_cpreturn_offset = -1;
16456
    }
16457
  else
16458
    {
16459
      mips_cpreturn_offset = get_absolute_expression ();
16460
      mips_cpreturn_register = -1;
16461
    }
16462
  SKIP_WHITESPACE ();
16463
  if (*input_line_pointer != ',')
16464
    {
16465
      as_bad (_("missing argument separator ',' for .cpsetup"));
16466
      return;
16467
    }
16468
  else
16469
    ++input_line_pointer;
16470
  SKIP_WHITESPACE ();
16471
  expression (&ex_sym);
16472
 
16473
  macro_start ();
16474
  if (mips_cpreturn_register == -1)
16475
    {
16476
      ex_off.X_op = O_constant;
16477
      ex_off.X_add_symbol = NULL;
16478
      ex_off.X_op_symbol = NULL;
16479
      ex_off.X_add_number = mips_cpreturn_offset;
16480
 
16481
      macro_build (&ex_off, "sd", "t,o(b)", mips_gp_register,
16482
                   BFD_RELOC_LO16, SP);
16483
    }
16484
  else
16485
    macro_build (NULL, "daddu", "d,v,t", mips_cpreturn_register,
16486
                 mips_gp_register, 0);
16487
 
16488
  if (mips_in_shared || HAVE_64BIT_SYMBOLS)
16489
    {
16490 160 khays
      macro_build (&ex_sym, "lui", LUI_FMT, mips_gp_register,
16491 16 khays
                   -1, BFD_RELOC_GPREL16, BFD_RELOC_MIPS_SUB,
16492
                   BFD_RELOC_HI16_S);
16493
 
16494
      macro_build (&ex_sym, "addiu", "t,r,j", mips_gp_register,
16495
                   mips_gp_register, -1, BFD_RELOC_GPREL16,
16496
                   BFD_RELOC_MIPS_SUB, BFD_RELOC_LO16);
16497
 
16498
      macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t", mips_gp_register,
16499
                   mips_gp_register, reg1);
16500
    }
16501
  else
16502
    {
16503
      expressionS ex;
16504
 
16505
      ex.X_op = O_symbol;
16506
      ex.X_add_symbol = symbol_find_or_make ("__gnu_local_gp");
16507
      ex.X_op_symbol = NULL;
16508
      ex.X_add_number = 0;
16509
 
16510
      /* In ELF, this symbol is implicitly an STT_OBJECT symbol.  */
16511
      symbol_get_bfdsym (ex.X_add_symbol)->flags |= BSF_OBJECT;
16512
 
16513
      macro_build_lui (&ex, mips_gp_register);
16514
      macro_build (&ex, "addiu", "t,r,j", mips_gp_register,
16515
                   mips_gp_register, BFD_RELOC_LO16);
16516
    }
16517
 
16518
  macro_end ();
16519
 
16520
  demand_empty_rest_of_line ();
16521
}
16522
 
16523
static void
16524
s_cplocal (int ignore ATTRIBUTE_UNUSED)
16525
{
16526
  /* If we are not generating SVR4 PIC code, or if this is not NewABI code,
16527
     .cplocal is ignored.  */
16528
  if (mips_pic != SVR4_PIC || ! HAVE_NEWABI)
16529
    {
16530
      s_ignore (0);
16531
      return;
16532
    }
16533
 
16534
  mips_gp_register = tc_get_register (0);
16535
  demand_empty_rest_of_line ();
16536
}
16537
 
16538
/* Handle the .cprestore pseudo-op.  This stores $gp into a given
16539
   offset from $sp.  The offset is remembered, and after making a PIC
16540
   call $gp is restored from that location.  */
16541
 
16542
static void
16543
s_cprestore (int ignore ATTRIBUTE_UNUSED)
16544
{
16545
  expressionS ex;
16546
 
16547
  /* If we are not generating SVR4 PIC code, or if this is NewABI code,
16548
     .cprestore is ignored.  */
16549
  if (mips_pic != SVR4_PIC || HAVE_NEWABI)
16550
    {
16551
      s_ignore (0);
16552
      return;
16553
    }
16554
 
16555
  mips_cprestore_offset = get_absolute_expression ();
16556
  mips_cprestore_valid = 1;
16557
 
16558
  ex.X_op = O_constant;
16559
  ex.X_add_symbol = NULL;
16560
  ex.X_op_symbol = NULL;
16561
  ex.X_add_number = mips_cprestore_offset;
16562
 
16563
  macro_start ();
16564
  macro_build_ldst_constoffset (&ex, ADDRESS_STORE_INSN, mips_gp_register,
16565
                                SP, HAVE_64BIT_ADDRESSES);
16566
  macro_end ();
16567
 
16568
  demand_empty_rest_of_line ();
16569
}
16570
 
16571
/* Handle the .cpreturn pseudo-op defined for NewABI PIC code. If an offset
16572
   was given in the preceding .cpsetup, it results in:
16573
     ld         $gp, offset($sp)
16574
 
16575
   If a register $reg2 was given there, it results in:
16576
     daddu      $gp, $reg2, $0  */
16577
 
16578
static void
16579
s_cpreturn (int ignore ATTRIBUTE_UNUSED)
16580
{
16581
  expressionS ex;
16582
 
16583
  /* If we are not generating SVR4 PIC code, .cpreturn is ignored.
16584
     We also need NewABI support.  */
16585
  if (mips_pic != SVR4_PIC || ! HAVE_NEWABI)
16586
    {
16587
      s_ignore (0);
16588
      return;
16589
    }
16590
 
16591
  macro_start ();
16592
  if (mips_cpreturn_register == -1)
16593
    {
16594
      ex.X_op = O_constant;
16595
      ex.X_add_symbol = NULL;
16596
      ex.X_op_symbol = NULL;
16597
      ex.X_add_number = mips_cpreturn_offset;
16598
 
16599
      macro_build (&ex, "ld", "t,o(b)", mips_gp_register, BFD_RELOC_LO16, SP);
16600
    }
16601
  else
16602
    macro_build (NULL, "daddu", "d,v,t", mips_gp_register,
16603
                 mips_cpreturn_register, 0);
16604
  macro_end ();
16605
 
16606
  demand_empty_rest_of_line ();
16607
}
16608
 
16609 166 khays
/* Handle a .dtprelword, .dtpreldword, .tprelword, or .tpreldword
16610
   pseudo-op; DIRSTR says which. The pseudo-op generates a BYTES-size
16611
   DTP- or TP-relative relocation of type RTYPE, for use in either DWARF
16612
   debug information or MIPS16 TLS.  */
16613 16 khays
 
16614
static void
16615 166 khays
s_tls_rel_directive (const size_t bytes, const char *dirstr,
16616
                     bfd_reloc_code_real_type rtype)
16617 16 khays
{
16618
  expressionS ex;
16619
  char *p;
16620
 
16621
  expression (&ex);
16622
 
16623
  if (ex.X_op != O_symbol)
16624
    {
16625 166 khays
      as_bad (_("Unsupported use of %s"), dirstr);
16626 16 khays
      ignore_rest_of_line ();
16627
    }
16628
 
16629
  p = frag_more (bytes);
16630
  md_number_to_chars (p, 0, bytes);
16631 166 khays
  fix_new_exp (frag_now, p - frag_now->fr_literal, bytes, &ex, FALSE, rtype);
16632 16 khays
  demand_empty_rest_of_line ();
16633 166 khays
  mips_clear_insn_labels ();
16634 16 khays
}
16635
 
16636
/* Handle .dtprelword.  */
16637
 
16638
static void
16639
s_dtprelword (int ignore ATTRIBUTE_UNUSED)
16640
{
16641 166 khays
  s_tls_rel_directive (4, ".dtprelword", BFD_RELOC_MIPS_TLS_DTPREL32);
16642 16 khays
}
16643
 
16644
/* Handle .dtpreldword.  */
16645
 
16646
static void
16647
s_dtpreldword (int ignore ATTRIBUTE_UNUSED)
16648
{
16649 166 khays
  s_tls_rel_directive (8, ".dtpreldword", BFD_RELOC_MIPS_TLS_DTPREL64);
16650 16 khays
}
16651
 
16652 166 khays
/* Handle .tprelword.  */
16653
 
16654
static void
16655
s_tprelword (int ignore ATTRIBUTE_UNUSED)
16656
{
16657
  s_tls_rel_directive (4, ".tprelword", BFD_RELOC_MIPS_TLS_TPREL32);
16658
}
16659
 
16660
/* Handle .tpreldword.  */
16661
 
16662
static void
16663
s_tpreldword (int ignore ATTRIBUTE_UNUSED)
16664
{
16665
  s_tls_rel_directive (8, ".tpreldword", BFD_RELOC_MIPS_TLS_TPREL64);
16666
}
16667
 
16668 16 khays
/* Handle the .gpvalue pseudo-op.  This is used when generating NewABI PIC
16669
   code.  It sets the offset to use in gp_rel relocations.  */
16670
 
16671
static void
16672
s_gpvalue (int ignore ATTRIBUTE_UNUSED)
16673
{
16674
  /* If we are not generating SVR4 PIC code, .gpvalue is ignored.
16675
     We also need NewABI support.  */
16676
  if (mips_pic != SVR4_PIC || ! HAVE_NEWABI)
16677
    {
16678
      s_ignore (0);
16679
      return;
16680
    }
16681
 
16682
  mips_gprel_offset = get_absolute_expression ();
16683
 
16684
  demand_empty_rest_of_line ();
16685
}
16686
 
16687
/* Handle the .gpword pseudo-op.  This is used when generating PIC
16688
   code.  It generates a 32 bit GP relative reloc.  */
16689
 
16690
static void
16691
s_gpword (int ignore ATTRIBUTE_UNUSED)
16692
{
16693
  segment_info_type *si;
16694
  struct insn_label_list *l;
16695
  expressionS ex;
16696
  char *p;
16697
 
16698
  /* When not generating PIC code, this is treated as .word.  */
16699
  if (mips_pic != SVR4_PIC)
16700
    {
16701
      s_cons (2);
16702
      return;
16703
    }
16704
 
16705
  si = seg_info (now_seg);
16706
  l = si->label_list;
16707
  mips_emit_delays ();
16708
  if (auto_align)
16709 166 khays
    mips_align (2, 0, l);
16710 16 khays
 
16711
  expression (&ex);
16712
  mips_clear_insn_labels ();
16713
 
16714
  if (ex.X_op != O_symbol || ex.X_add_number != 0)
16715
    {
16716
      as_bad (_("Unsupported use of .gpword"));
16717
      ignore_rest_of_line ();
16718
    }
16719
 
16720
  p = frag_more (4);
16721
  md_number_to_chars (p, 0, 4);
16722
  fix_new_exp (frag_now, p - frag_now->fr_literal, 4, &ex, FALSE,
16723
               BFD_RELOC_GPREL32);
16724
 
16725
  demand_empty_rest_of_line ();
16726
}
16727
 
16728
static void
16729
s_gpdword (int ignore ATTRIBUTE_UNUSED)
16730
{
16731
  segment_info_type *si;
16732
  struct insn_label_list *l;
16733
  expressionS ex;
16734
  char *p;
16735
 
16736
  /* When not generating PIC code, this is treated as .dword.  */
16737
  if (mips_pic != SVR4_PIC)
16738
    {
16739
      s_cons (3);
16740
      return;
16741
    }
16742
 
16743
  si = seg_info (now_seg);
16744
  l = si->label_list;
16745
  mips_emit_delays ();
16746
  if (auto_align)
16747 166 khays
    mips_align (3, 0, l);
16748 16 khays
 
16749
  expression (&ex);
16750
  mips_clear_insn_labels ();
16751
 
16752
  if (ex.X_op != O_symbol || ex.X_add_number != 0)
16753
    {
16754
      as_bad (_("Unsupported use of .gpdword"));
16755
      ignore_rest_of_line ();
16756
    }
16757
 
16758
  p = frag_more (8);
16759
  md_number_to_chars (p, 0, 8);
16760
  fix_new_exp (frag_now, p - frag_now->fr_literal, 4, &ex, FALSE,
16761
               BFD_RELOC_GPREL32)->fx_tcbit = 1;
16762
 
16763
  /* GPREL32 composed with 64 gives a 64-bit GP offset.  */
16764
  fix_new (frag_now, p - frag_now->fr_literal, 8, NULL, 0,
16765
           FALSE, BFD_RELOC_64)->fx_tcbit = 1;
16766
 
16767
  demand_empty_rest_of_line ();
16768
}
16769
 
16770
/* Handle the .cpadd pseudo-op.  This is used when dealing with switch
16771
   tables in SVR4 PIC code.  */
16772
 
16773
static void
16774
s_cpadd (int ignore ATTRIBUTE_UNUSED)
16775
{
16776
  int reg;
16777
 
16778
  /* This is ignored when not generating SVR4 PIC code.  */
16779
  if (mips_pic != SVR4_PIC)
16780
    {
16781
      s_ignore (0);
16782
      return;
16783
    }
16784
 
16785
  /* Add $gp to the register named as an argument.  */
16786
  macro_start ();
16787
  reg = tc_get_register (0);
16788
  macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t", reg, reg, mips_gp_register);
16789
  macro_end ();
16790
 
16791
  demand_empty_rest_of_line ();
16792
}
16793
 
16794
/* Handle the .insn pseudo-op.  This marks instruction labels in
16795 160 khays
   mips16/micromips mode.  This permits the linker to handle them specially,
16796 16 khays
   such as generating jalx instructions when needed.  We also make
16797
   them odd for the duration of the assembly, in order to generate the
16798
   right sort of code.  We will make them even in the adjust_symtab
16799
   routine, while leaving them marked.  This is convenient for the
16800
   debugger and the disassembler.  The linker knows to make them odd
16801
   again.  */
16802
 
16803
static void
16804
s_insn (int ignore ATTRIBUTE_UNUSED)
16805
{
16806 160 khays
  mips_mark_labels ();
16807 16 khays
 
16808
  demand_empty_rest_of_line ();
16809
}
16810
 
16811
/* Handle a .stabn directive.  We need these in order to mark a label
16812
   as being a mips16 text label correctly.  Sometimes the compiler
16813
   will emit a label, followed by a .stabn, and then switch sections.
16814
   If the label and .stabn are in mips16 mode, then the label is
16815
   really a mips16 text label.  */
16816
 
16817
static void
16818
s_mips_stab (int type)
16819
{
16820
  if (type == 'n')
16821 160 khays
    mips_mark_labels ();
16822 16 khays
 
16823
  s_stab (type);
16824
}
16825
 
16826
/* Handle the .weakext pseudo-op as defined in Kane and Heinrich.  */
16827
 
16828
static void
16829
s_mips_weakext (int ignore ATTRIBUTE_UNUSED)
16830
{
16831
  char *name;
16832
  int c;
16833
  symbolS *symbolP;
16834
  expressionS exp;
16835
 
16836
  name = input_line_pointer;
16837
  c = get_symbol_end ();
16838
  symbolP = symbol_find_or_make (name);
16839
  S_SET_WEAK (symbolP);
16840
  *input_line_pointer = c;
16841
 
16842
  SKIP_WHITESPACE ();
16843
 
16844
  if (! is_end_of_line[(unsigned char) *input_line_pointer])
16845
    {
16846
      if (S_IS_DEFINED (symbolP))
16847
        {
16848
          as_bad (_("ignoring attempt to redefine symbol %s"),
16849
                  S_GET_NAME (symbolP));
16850
          ignore_rest_of_line ();
16851
          return;
16852
        }
16853
 
16854
      if (*input_line_pointer == ',')
16855
        {
16856
          ++input_line_pointer;
16857
          SKIP_WHITESPACE ();
16858
        }
16859
 
16860
      expression (&exp);
16861
      if (exp.X_op != O_symbol)
16862
        {
16863
          as_bad (_("bad .weakext directive"));
16864
          ignore_rest_of_line ();
16865
          return;
16866
        }
16867
      symbol_set_value_expression (symbolP, &exp);
16868
    }
16869
 
16870
  demand_empty_rest_of_line ();
16871
}
16872
 
16873
/* Parse a register string into a number.  Called from the ECOFF code
16874
   to parse .frame.  The argument is non-zero if this is the frame
16875
   register, so that we can record it in mips_frame_reg.  */
16876
 
16877
int
16878
tc_get_register (int frame)
16879
{
16880
  unsigned int reg;
16881
 
16882
  SKIP_WHITESPACE ();
16883
  if (! reg_lookup (&input_line_pointer, RWARN | RTYPE_NUM | RTYPE_GP, &reg))
16884
    reg = 0;
16885
  if (frame)
16886
    {
16887
      mips_frame_reg = reg != 0 ? reg : SP;
16888
      mips_frame_reg_valid = 1;
16889
      mips_cprestore_valid = 0;
16890
    }
16891
  return reg;
16892
}
16893
 
16894
valueT
16895
md_section_align (asection *seg, valueT addr)
16896
{
16897
  int align = bfd_get_section_alignment (stdoutput, seg);
16898
 
16899
  if (IS_ELF)
16900
    {
16901
      /* We don't need to align ELF sections to the full alignment.
16902
         However, Irix 5 may prefer that we align them at least to a 16
16903
         byte boundary.  We don't bother to align the sections if we
16904
         are targeted for an embedded system.  */
16905
      if (strncmp (TARGET_OS, "elf", 3) == 0)
16906
        return addr;
16907
      if (align > 4)
16908
        align = 4;
16909
    }
16910
 
16911
  return ((addr + (1 << align) - 1) & (-1 << align));
16912
}
16913
 
16914
/* Utility routine, called from above as well.  If called while the
16915
   input file is still being read, it's only an approximation.  (For
16916
   example, a symbol may later become defined which appeared to be
16917
   undefined earlier.)  */
16918
 
16919
static int
16920
nopic_need_relax (symbolS *sym, int before_relaxing)
16921
{
16922
  if (sym == 0)
16923
    return 0;
16924
 
16925
  if (g_switch_value > 0)
16926
    {
16927
      const char *symname;
16928
      int change;
16929
 
16930
      /* Find out whether this symbol can be referenced off the $gp
16931
         register.  It can be if it is smaller than the -G size or if
16932
         it is in the .sdata or .sbss section.  Certain symbols can
16933
         not be referenced off the $gp, although it appears as though
16934
         they can.  */
16935
      symname = S_GET_NAME (sym);
16936
      if (symname != (const char *) NULL
16937
          && (strcmp (symname, "eprol") == 0
16938
              || strcmp (symname, "etext") == 0
16939
              || strcmp (symname, "_gp") == 0
16940
              || strcmp (symname, "edata") == 0
16941
              || strcmp (symname, "_fbss") == 0
16942
              || strcmp (symname, "_fdata") == 0
16943
              || strcmp (symname, "_ftext") == 0
16944
              || strcmp (symname, "end") == 0
16945
              || strcmp (symname, "_gp_disp") == 0))
16946
        change = 1;
16947
      else if ((! S_IS_DEFINED (sym) || S_IS_COMMON (sym))
16948
               && (0
16949
#ifndef NO_ECOFF_DEBUGGING
16950
                   || (symbol_get_obj (sym)->ecoff_extern_size != 0
16951
                       && (symbol_get_obj (sym)->ecoff_extern_size
16952
                           <= g_switch_value))
16953
#endif
16954
                   /* We must defer this decision until after the whole
16955
                      file has been read, since there might be a .extern
16956
                      after the first use of this symbol.  */
16957
                   || (before_relaxing
16958
#ifndef NO_ECOFF_DEBUGGING
16959
                       && symbol_get_obj (sym)->ecoff_extern_size == 0
16960
#endif
16961
                       && S_GET_VALUE (sym) == 0)
16962
                   || (S_GET_VALUE (sym) != 0
16963
                       && S_GET_VALUE (sym) <= g_switch_value)))
16964
        change = 0;
16965
      else
16966
        {
16967
          const char *segname;
16968
 
16969
          segname = segment_name (S_GET_SEGMENT (sym));
16970
          gas_assert (strcmp (segname, ".lit8") != 0
16971
                  && strcmp (segname, ".lit4") != 0);
16972
          change = (strcmp (segname, ".sdata") != 0
16973
                    && strcmp (segname, ".sbss") != 0
16974
                    && strncmp (segname, ".sdata.", 7) != 0
16975
                    && strncmp (segname, ".sbss.", 6) != 0
16976
                    && strncmp (segname, ".gnu.linkonce.sb.", 17) != 0
16977
                    && strncmp (segname, ".gnu.linkonce.s.", 16) != 0);
16978
        }
16979
      return change;
16980
    }
16981
  else
16982
    /* We are not optimizing for the $gp register.  */
16983
    return 1;
16984
}
16985
 
16986
 
16987
/* Return true if the given symbol should be considered local for SVR4 PIC.  */
16988
 
16989
static bfd_boolean
16990
pic_need_relax (symbolS *sym, asection *segtype)
16991
{
16992
  asection *symsec;
16993
 
16994
  /* Handle the case of a symbol equated to another symbol.  */
16995
  while (symbol_equated_reloc_p (sym))
16996
    {
16997
      symbolS *n;
16998
 
16999
      /* It's possible to get a loop here in a badly written program.  */
17000
      n = symbol_get_value_expression (sym)->X_add_symbol;
17001
      if (n == sym)
17002
        break;
17003
      sym = n;
17004
    }
17005
 
17006
  if (symbol_section_p (sym))
17007
    return TRUE;
17008
 
17009
  symsec = S_GET_SEGMENT (sym);
17010
 
17011
  /* This must duplicate the test in adjust_reloc_syms.  */
17012
  return (symsec != &bfd_und_section
17013
          && symsec != &bfd_abs_section
17014
          && !bfd_is_com_section (symsec)
17015
          && !s_is_linkonce (sym, segtype)
17016
#ifdef OBJ_ELF
17017
          /* A global or weak symbol is treated as external.  */
17018
          && (!IS_ELF || (! S_IS_WEAK (sym) && ! S_IS_EXTERNAL (sym)))
17019
#endif
17020
          );
17021
}
17022
 
17023
 
17024
/* Given a mips16 variant frag FRAGP, return non-zero if it needs an
17025
   extended opcode.  SEC is the section the frag is in.  */
17026
 
17027
static int
17028
mips16_extended_frag (fragS *fragp, asection *sec, long stretch)
17029
{
17030
  int type;
17031
  const struct mips16_immed_operand *op;
17032
  offsetT val;
17033
  int mintiny, maxtiny;
17034
  segT symsec;
17035
  fragS *sym_frag;
17036
 
17037
  if (RELAX_MIPS16_USER_SMALL (fragp->fr_subtype))
17038
    return 0;
17039
  if (RELAX_MIPS16_USER_EXT (fragp->fr_subtype))
17040
    return 1;
17041
 
17042
  type = RELAX_MIPS16_TYPE (fragp->fr_subtype);
17043
  op = mips16_immed_operands;
17044
  while (op->type != type)
17045
    {
17046
      ++op;
17047
      gas_assert (op < mips16_immed_operands + MIPS16_NUM_IMMED);
17048
    }
17049
 
17050
  if (op->unsp)
17051
    {
17052
      if (type == '<' || type == '>' || type == '[' || type == ']')
17053
        {
17054
          mintiny = 1;
17055
          maxtiny = 1 << op->nbits;
17056
        }
17057
      else
17058
        {
17059
          mintiny = 0;
17060
          maxtiny = (1 << op->nbits) - 1;
17061
        }
17062
    }
17063
  else
17064
    {
17065
      mintiny = - (1 << (op->nbits - 1));
17066
      maxtiny = (1 << (op->nbits - 1)) - 1;
17067
    }
17068
 
17069
  sym_frag = symbol_get_frag (fragp->fr_symbol);
17070
  val = S_GET_VALUE (fragp->fr_symbol);
17071
  symsec = S_GET_SEGMENT (fragp->fr_symbol);
17072
 
17073
  if (op->pcrel)
17074
    {
17075
      addressT addr;
17076
 
17077
      /* We won't have the section when we are called from
17078
         mips_relax_frag.  However, we will always have been called
17079
         from md_estimate_size_before_relax first.  If this is a
17080
         branch to a different section, we mark it as such.  If SEC is
17081
         NULL, and the frag is not marked, then it must be a branch to
17082
         the same section.  */
17083
      if (sec == NULL)
17084
        {
17085
          if (RELAX_MIPS16_LONG_BRANCH (fragp->fr_subtype))
17086
            return 1;
17087
        }
17088
      else
17089
        {
17090
          /* Must have been called from md_estimate_size_before_relax.  */
17091
          if (symsec != sec)
17092
            {
17093
              fragp->fr_subtype =
17094
                RELAX_MIPS16_MARK_LONG_BRANCH (fragp->fr_subtype);
17095
 
17096
              /* FIXME: We should support this, and let the linker
17097
                 catch branches and loads that are out of range.  */
17098
              as_bad_where (fragp->fr_file, fragp->fr_line,
17099
                            _("unsupported PC relative reference to different section"));
17100
 
17101
              return 1;
17102
            }
17103
          if (fragp != sym_frag && sym_frag->fr_address == 0)
17104
            /* Assume non-extended on the first relaxation pass.
17105
               The address we have calculated will be bogus if this is
17106
               a forward branch to another frag, as the forward frag
17107
               will have fr_address == 0.  */
17108
            return 0;
17109
        }
17110
 
17111
      /* In this case, we know for sure that the symbol fragment is in
17112
         the same section.  If the relax_marker of the symbol fragment
17113
         differs from the relax_marker of this fragment, we have not
17114
         yet adjusted the symbol fragment fr_address.  We want to add
17115
         in STRETCH in order to get a better estimate of the address.
17116
         This particularly matters because of the shift bits.  */
17117
      if (stretch != 0
17118
          && sym_frag->relax_marker != fragp->relax_marker)
17119
        {
17120
          fragS *f;
17121
 
17122
          /* Adjust stretch for any alignment frag.  Note that if have
17123
             been expanding the earlier code, the symbol may be
17124
             defined in what appears to be an earlier frag.  FIXME:
17125
             This doesn't handle the fr_subtype field, which specifies
17126
             a maximum number of bytes to skip when doing an
17127
             alignment.  */
17128
          for (f = fragp; f != NULL && f != sym_frag; f = f->fr_next)
17129
            {
17130
              if (f->fr_type == rs_align || f->fr_type == rs_align_code)
17131
                {
17132
                  if (stretch < 0)
17133
                    stretch = - ((- stretch)
17134
                                 & ~ ((1 << (int) f->fr_offset) - 1));
17135
                  else
17136
                    stretch &= ~ ((1 << (int) f->fr_offset) - 1);
17137
                  if (stretch == 0)
17138
                    break;
17139
                }
17140
            }
17141
          if (f != NULL)
17142
            val += stretch;
17143
        }
17144
 
17145
      addr = fragp->fr_address + fragp->fr_fix;
17146
 
17147
      /* The base address rules are complicated.  The base address of
17148
         a branch is the following instruction.  The base address of a
17149
         PC relative load or add is the instruction itself, but if it
17150
         is in a delay slot (in which case it can not be extended) use
17151
         the address of the instruction whose delay slot it is in.  */
17152
      if (type == 'p' || type == 'q')
17153
        {
17154
          addr += 2;
17155
 
17156
          /* If we are currently assuming that this frag should be
17157
             extended, then, the current address is two bytes
17158
             higher.  */
17159
          if (RELAX_MIPS16_EXTENDED (fragp->fr_subtype))
17160
            addr += 2;
17161
 
17162
          /* Ignore the low bit in the target, since it will be set
17163
             for a text label.  */
17164
          if ((val & 1) != 0)
17165
            --val;
17166
        }
17167
      else if (RELAX_MIPS16_JAL_DSLOT (fragp->fr_subtype))
17168
        addr -= 4;
17169
      else if (RELAX_MIPS16_DSLOT (fragp->fr_subtype))
17170
        addr -= 2;
17171
 
17172
      val -= addr & ~ ((1 << op->shift) - 1);
17173
 
17174
      /* Branch offsets have an implicit 0 in the lowest bit.  */
17175
      if (type == 'p' || type == 'q')
17176
        val /= 2;
17177
 
17178
      /* If any of the shifted bits are set, we must use an extended
17179
         opcode.  If the address depends on the size of this
17180
         instruction, this can lead to a loop, so we arrange to always
17181
         use an extended opcode.  We only check this when we are in
17182
         the main relaxation loop, when SEC is NULL.  */
17183
      if ((val & ((1 << op->shift) - 1)) != 0 && sec == NULL)
17184
        {
17185
          fragp->fr_subtype =
17186
            RELAX_MIPS16_MARK_LONG_BRANCH (fragp->fr_subtype);
17187
          return 1;
17188
        }
17189
 
17190
      /* If we are about to mark a frag as extended because the value
17191
         is precisely maxtiny + 1, then there is a chance of an
17192
         infinite loop as in the following code:
17193
             la $4,foo
17194
             .skip      1020
17195
             .align     2
17196
           foo:
17197
         In this case when the la is extended, foo is 0x3fc bytes
17198
         away, so the la can be shrunk, but then foo is 0x400 away, so
17199
         the la must be extended.  To avoid this loop, we mark the
17200
         frag as extended if it was small, and is about to become
17201
         extended with a value of maxtiny + 1.  */
17202
      if (val == ((maxtiny + 1) << op->shift)
17203
          && ! RELAX_MIPS16_EXTENDED (fragp->fr_subtype)
17204
          && sec == NULL)
17205
        {
17206
          fragp->fr_subtype =
17207
            RELAX_MIPS16_MARK_LONG_BRANCH (fragp->fr_subtype);
17208
          return 1;
17209
        }
17210
    }
17211
  else if (symsec != absolute_section && sec != NULL)
17212
    as_bad_where (fragp->fr_file, fragp->fr_line, _("unsupported relocation"));
17213
 
17214
  if ((val & ((1 << op->shift) - 1)) != 0
17215
      || val < (mintiny << op->shift)
17216
      || val > (maxtiny << op->shift))
17217
    return 1;
17218
  else
17219
    return 0;
17220
}
17221
 
17222
/* Compute the length of a branch sequence, and adjust the
17223
   RELAX_BRANCH_TOOFAR bit accordingly.  If FRAGP is NULL, the
17224
   worst-case length is computed, with UPDATE being used to indicate
17225
   whether an unconditional (-1), branch-likely (+1) or regular (0)
17226
   branch is to be computed.  */
17227
static int
17228
relaxed_branch_length (fragS *fragp, asection *sec, int update)
17229
{
17230
  bfd_boolean toofar;
17231
  int length;
17232
 
17233
  if (fragp
17234
      && S_IS_DEFINED (fragp->fr_symbol)
17235
      && sec == S_GET_SEGMENT (fragp->fr_symbol))
17236
    {
17237
      addressT addr;
17238
      offsetT val;
17239
 
17240
      val = S_GET_VALUE (fragp->fr_symbol) + fragp->fr_offset;
17241
 
17242
      addr = fragp->fr_address + fragp->fr_fix + 4;
17243
 
17244
      val -= addr;
17245
 
17246
      toofar = val < - (0x8000 << 2) || val >= (0x8000 << 2);
17247
    }
17248
  else if (fragp)
17249
    /* If the symbol is not defined or it's in a different segment,
17250
       assume the user knows what's going on and emit a short
17251
       branch.  */
17252
    toofar = FALSE;
17253
  else
17254
    toofar = TRUE;
17255
 
17256
  if (fragp && update && toofar != RELAX_BRANCH_TOOFAR (fragp->fr_subtype))
17257
    fragp->fr_subtype
17258
      = RELAX_BRANCH_ENCODE (RELAX_BRANCH_AT (fragp->fr_subtype),
17259
                             RELAX_BRANCH_UNCOND (fragp->fr_subtype),
17260
                             RELAX_BRANCH_LIKELY (fragp->fr_subtype),
17261
                             RELAX_BRANCH_LINK (fragp->fr_subtype),
17262
                             toofar);
17263
 
17264
  length = 4;
17265
  if (toofar)
17266
    {
17267
      if (fragp ? RELAX_BRANCH_LIKELY (fragp->fr_subtype) : (update > 0))
17268
        length += 8;
17269
 
17270
      if (mips_pic != NO_PIC)
17271
        {
17272
          /* Additional space for PIC loading of target address.  */
17273
          length += 8;
17274
          if (mips_opts.isa == ISA_MIPS1)
17275
            /* Additional space for $at-stabilizing nop.  */
17276
            length += 4;
17277
        }
17278
 
17279
      /* If branch is conditional.  */
17280
      if (fragp ? !RELAX_BRANCH_UNCOND (fragp->fr_subtype) : (update >= 0))
17281
        length += 8;
17282
    }
17283
 
17284
  return length;
17285
}
17286
 
17287 160 khays
/* Compute the length of a branch sequence, and adjust the
17288
   RELAX_MICROMIPS_TOOFAR32 bit accordingly.  If FRAGP is NULL, the
17289
   worst-case length is computed, with UPDATE being used to indicate
17290
   whether an unconditional (-1), or regular (0) branch is to be
17291
   computed.  */
17292
 
17293
static int
17294
relaxed_micromips_32bit_branch_length (fragS *fragp, asection *sec, int update)
17295
{
17296
  bfd_boolean toofar;
17297
  int length;
17298
 
17299
  if (fragp
17300
      && S_IS_DEFINED (fragp->fr_symbol)
17301
      && sec == S_GET_SEGMENT (fragp->fr_symbol))
17302
    {
17303
      addressT addr;
17304
      offsetT val;
17305
 
17306
      val = S_GET_VALUE (fragp->fr_symbol) + fragp->fr_offset;
17307
      /* Ignore the low bit in the target, since it will be set
17308
         for a text label.  */
17309
      if ((val & 1) != 0)
17310
        --val;
17311
 
17312
      addr = fragp->fr_address + fragp->fr_fix + 4;
17313
 
17314
      val -= addr;
17315
 
17316
      toofar = val < - (0x8000 << 1) || val >= (0x8000 << 1);
17317
    }
17318
  else if (fragp)
17319
    /* If the symbol is not defined or it's in a different segment,
17320
       assume the user knows what's going on and emit a short
17321
       branch.  */
17322
    toofar = FALSE;
17323
  else
17324
    toofar = TRUE;
17325
 
17326
  if (fragp && update
17327
      && toofar != RELAX_MICROMIPS_TOOFAR32 (fragp->fr_subtype))
17328
    fragp->fr_subtype = (toofar
17329
                         ? RELAX_MICROMIPS_MARK_TOOFAR32 (fragp->fr_subtype)
17330
                         : RELAX_MICROMIPS_CLEAR_TOOFAR32 (fragp->fr_subtype));
17331
 
17332
  length = 4;
17333
  if (toofar)
17334
    {
17335
      bfd_boolean compact_known = fragp != NULL;
17336
      bfd_boolean compact = FALSE;
17337
      bfd_boolean uncond;
17338
 
17339
      if (compact_known)
17340
        compact = RELAX_MICROMIPS_COMPACT (fragp->fr_subtype);
17341
      if (fragp)
17342
        uncond = RELAX_MICROMIPS_UNCOND (fragp->fr_subtype);
17343
      else
17344
        uncond = update < 0;
17345
 
17346
      /* If label is out of range, we turn branch <br>:
17347
 
17348
                <br>    label                   # 4 bytes
17349
            0:
17350
 
17351
         into:
17352
 
17353
                j       label                   # 4 bytes
17354
                nop                             # 2 bytes if compact && !PIC
17355
            0:
17356
       */
17357
      if (mips_pic == NO_PIC && (!compact_known || compact))
17358
        length += 2;
17359
 
17360
      /* If assembling PIC code, we further turn:
17361
 
17362
                        j       label                   # 4 bytes
17363
 
17364
         into:
17365
 
17366
                        lw/ld   at, %got(label)(gp)     # 4 bytes
17367
                        d/addiu at, %lo(label)          # 4 bytes
17368
                        jr/c    at                      # 2 bytes
17369
       */
17370
      if (mips_pic != NO_PIC)
17371
        length += 6;
17372
 
17373
      /* If branch <br> is conditional, we prepend negated branch <brneg>:
17374
 
17375
                        <brneg> 0f                      # 4 bytes
17376
                        nop                             # 2 bytes if !compact
17377
       */
17378
      if (!uncond)
17379
        length += (compact_known && compact) ? 4 : 6;
17380
    }
17381
 
17382
  return length;
17383
}
17384
 
17385
/* Compute the length of a branch, and adjust the RELAX_MICROMIPS_TOOFAR16
17386
   bit accordingly.  */
17387
 
17388
static int
17389
relaxed_micromips_16bit_branch_length (fragS *fragp, asection *sec, int update)
17390
{
17391
  bfd_boolean toofar;
17392
 
17393
  if (fragp
17394
      && S_IS_DEFINED (fragp->fr_symbol)
17395
      && sec == S_GET_SEGMENT (fragp->fr_symbol))
17396
    {
17397
      addressT addr;
17398
      offsetT val;
17399
      int type;
17400
 
17401
      val = S_GET_VALUE (fragp->fr_symbol) + fragp->fr_offset;
17402
      /* Ignore the low bit in the target, since it will be set
17403
         for a text label.  */
17404
      if ((val & 1) != 0)
17405
        --val;
17406
 
17407
      /* Assume this is a 2-byte branch.  */
17408
      addr = fragp->fr_address + fragp->fr_fix + 2;
17409
 
17410
      /* We try to avoid the infinite loop by not adding 2 more bytes for
17411
         long branches.  */
17412
 
17413
      val -= addr;
17414
 
17415
      type = RELAX_MICROMIPS_TYPE (fragp->fr_subtype);
17416
      if (type == 'D')
17417
        toofar = val < - (0x200 << 1) || val >= (0x200 << 1);
17418
      else if (type == 'E')
17419
        toofar = val < - (0x40 << 1) || val >= (0x40 << 1);
17420
      else
17421
        abort ();
17422
    }
17423
  else
17424
    /* If the symbol is not defined or it's in a different segment,
17425
       we emit a normal 32-bit branch.  */
17426
    toofar = TRUE;
17427
 
17428
  if (fragp && update
17429
      && toofar != RELAX_MICROMIPS_TOOFAR16 (fragp->fr_subtype))
17430
    fragp->fr_subtype
17431
      = toofar ? RELAX_MICROMIPS_MARK_TOOFAR16 (fragp->fr_subtype)
17432
               : RELAX_MICROMIPS_CLEAR_TOOFAR16 (fragp->fr_subtype);
17433
 
17434
  if (toofar)
17435
    return 4;
17436
 
17437
  return 2;
17438
}
17439
 
17440 16 khays
/* Estimate the size of a frag before relaxing.  Unless this is the
17441
   mips16, we are not really relaxing here, and the final size is
17442
   encoded in the subtype information.  For the mips16, we have to
17443
   decide whether we are using an extended opcode or not.  */
17444
 
17445
int
17446
md_estimate_size_before_relax (fragS *fragp, asection *segtype)
17447
{
17448
  int change;
17449
 
17450
  if (RELAX_BRANCH_P (fragp->fr_subtype))
17451
    {
17452
 
17453
      fragp->fr_var = relaxed_branch_length (fragp, segtype, FALSE);
17454
 
17455
      return fragp->fr_var;
17456
    }
17457
 
17458
  if (RELAX_MIPS16_P (fragp->fr_subtype))
17459
    /* We don't want to modify the EXTENDED bit here; it might get us
17460
       into infinite loops.  We change it only in mips_relax_frag().  */
17461
    return (RELAX_MIPS16_EXTENDED (fragp->fr_subtype) ? 4 : 2);
17462
 
17463 160 khays
  if (RELAX_MICROMIPS_P (fragp->fr_subtype))
17464
    {
17465
      int length = 4;
17466
 
17467
      if (RELAX_MICROMIPS_TYPE (fragp->fr_subtype) != 0)
17468
        length = relaxed_micromips_16bit_branch_length (fragp, segtype, FALSE);
17469
      if (length == 4 && RELAX_MICROMIPS_RELAX32 (fragp->fr_subtype))
17470
        length = relaxed_micromips_32bit_branch_length (fragp, segtype, FALSE);
17471
      fragp->fr_var = length;
17472
 
17473
      return length;
17474
    }
17475
 
17476 16 khays
  if (mips_pic == NO_PIC)
17477
    change = nopic_need_relax (fragp->fr_symbol, 0);
17478
  else if (mips_pic == SVR4_PIC)
17479
    change = pic_need_relax (fragp->fr_symbol, segtype);
17480
  else if (mips_pic == VXWORKS_PIC)
17481
    /* For vxworks, GOT16 relocations never have a corresponding LO16.  */
17482
    change = 0;
17483
  else
17484
    abort ();
17485
 
17486
  if (change)
17487
    {
17488
      fragp->fr_subtype |= RELAX_USE_SECOND;
17489
      return -RELAX_FIRST (fragp->fr_subtype);
17490
    }
17491
  else
17492
    return -RELAX_SECOND (fragp->fr_subtype);
17493
}
17494
 
17495
/* This is called to see whether a reloc against a defined symbol
17496
   should be converted into a reloc against a section.  */
17497
 
17498
int
17499
mips_fix_adjustable (fixS *fixp)
17500
{
17501
  if (fixp->fx_r_type == BFD_RELOC_VTABLE_INHERIT
17502
      || fixp->fx_r_type == BFD_RELOC_VTABLE_ENTRY)
17503
    return 0;
17504
 
17505
  if (fixp->fx_addsy == NULL)
17506
    return 1;
17507
 
17508
  /* If symbol SYM is in a mergeable section, relocations of the form
17509
     SYM + 0 can usually be made section-relative.  The mergeable data
17510
     is then identified by the section offset rather than by the symbol.
17511
 
17512
     However, if we're generating REL LO16 relocations, the offset is split
17513
     between the LO16 and parterning high part relocation.  The linker will
17514
     need to recalculate the complete offset in order to correctly identify
17515
     the merge data.
17516
 
17517
     The linker has traditionally not looked for the parterning high part
17518
     relocation, and has thus allowed orphaned R_MIPS_LO16 relocations to be
17519
     placed anywhere.  Rather than break backwards compatibility by changing
17520
     this, it seems better not to force the issue, and instead keep the
17521
     original symbol.  This will work with either linker behavior.  */
17522
  if ((lo16_reloc_p (fixp->fx_r_type)
17523
       || reloc_needs_lo_p (fixp->fx_r_type))
17524
      && HAVE_IN_PLACE_ADDENDS
17525
      && (S_GET_SEGMENT (fixp->fx_addsy)->flags & SEC_MERGE) != 0)
17526
    return 0;
17527
 
17528
  /* There is no place to store an in-place offset for JALR relocations.
17529
     Likewise an in-range offset of PC-relative relocations may overflow
17530
     the in-place relocatable field if recalculated against the start
17531
     address of the symbol's containing section.  */
17532
  if (HAVE_IN_PLACE_ADDENDS
17533 160 khays
      && (fixp->fx_pcrel || jalr_reloc_p (fixp->fx_r_type)))
17534 16 khays
    return 0;
17535
 
17536
#ifdef OBJ_ELF
17537
  /* R_MIPS16_26 relocations against non-MIPS16 functions might resolve
17538
     to a floating-point stub.  The same is true for non-R_MIPS16_26
17539
     relocations against MIPS16 functions; in this case, the stub becomes
17540
     the function's canonical address.
17541
 
17542
     Floating-point stubs are stored in unique .mips16.call.* or
17543
     .mips16.fn.* sections.  If a stub T for function F is in section S,
17544
     the first relocation in section S must be against F; this is how the
17545
     linker determines the target function.  All relocations that might
17546
     resolve to T must also be against F.  We therefore have the following
17547
     restrictions, which are given in an intentionally-redundant way:
17548
 
17549
       1. We cannot reduce R_MIPS16_26 relocations against non-MIPS16
17550
          symbols.
17551
 
17552
       2. We cannot reduce a stub's relocations against non-MIPS16 symbols
17553
          if that stub might be used.
17554
 
17555
       3. We cannot reduce non-R_MIPS16_26 relocations against MIPS16
17556
          symbols.
17557
 
17558
       4. We cannot reduce a stub's relocations against MIPS16 symbols if
17559
          that stub might be used.
17560
 
17561
     There is a further restriction:
17562
 
17563 160 khays
       5. We cannot reduce jump relocations (R_MIPS_26, R_MIPS16_26 or
17564
          R_MICROMIPS_26_S1) against MIPS16 or microMIPS symbols on
17565
          targets with in-place addends; the relocation field cannot
17566 16 khays
          encode the low bit.
17567
 
17568 160 khays
     For simplicity, we deal with (3)-(4) by not reducing _any_ relocation
17569
     against a MIPS16 symbol.  We deal with (5) by by not reducing any
17570
     such relocations on REL targets.
17571 16 khays
 
17572
     We deal with (1)-(2) by saying that, if there's a R_MIPS16_26
17573
     relocation against some symbol R, no relocation against R may be
17574
     reduced.  (Note that this deals with (2) as well as (1) because
17575
     relocations against global symbols will never be reduced on ELF
17576
     targets.)  This approach is a little simpler than trying to detect
17577
     stub sections, and gives the "all or nothing" per-symbol consistency
17578
     that we have for MIPS16 symbols.  */
17579
  if (IS_ELF
17580
      && fixp->fx_subsy == NULL
17581
      && (ELF_ST_IS_MIPS16 (S_GET_OTHER (fixp->fx_addsy))
17582 160 khays
          || *symbol_get_tc (fixp->fx_addsy)
17583
          || (HAVE_IN_PLACE_ADDENDS
17584
              && ELF_ST_IS_MICROMIPS (S_GET_OTHER (fixp->fx_addsy))
17585
              && jmp_reloc_p (fixp->fx_r_type))))
17586 16 khays
    return 0;
17587
#endif
17588
 
17589
  return 1;
17590
}
17591
 
17592
/* Translate internal representation of relocation info to BFD target
17593
   format.  */
17594
 
17595
arelent **
17596
tc_gen_reloc (asection *section ATTRIBUTE_UNUSED, fixS *fixp)
17597
{
17598
  static arelent *retval[4];
17599
  arelent *reloc;
17600
  bfd_reloc_code_real_type code;
17601
 
17602
  memset (retval, 0, sizeof(retval));
17603
  reloc = retval[0] = (arelent *) xcalloc (1, sizeof (arelent));
17604
  reloc->sym_ptr_ptr = (asymbol **) xmalloc (sizeof (asymbol *));
17605
  *reloc->sym_ptr_ptr = symbol_get_bfdsym (fixp->fx_addsy);
17606
  reloc->address = fixp->fx_frag->fr_address + fixp->fx_where;
17607
 
17608
  if (fixp->fx_pcrel)
17609
    {
17610 160 khays
      gas_assert (fixp->fx_r_type == BFD_RELOC_16_PCREL_S2
17611
                  || fixp->fx_r_type == BFD_RELOC_MICROMIPS_7_PCREL_S1
17612
                  || fixp->fx_r_type == BFD_RELOC_MICROMIPS_10_PCREL_S1
17613
                  || fixp->fx_r_type == BFD_RELOC_MICROMIPS_16_PCREL_S1);
17614 16 khays
 
17615
      /* At this point, fx_addnumber is "symbol offset - pcrel address".
17616
         Relocations want only the symbol offset.  */
17617
      reloc->addend = fixp->fx_addnumber + reloc->address;
17618
      if (!IS_ELF)
17619
        {
17620
          /* A gruesome hack which is a result of the gruesome gas
17621
             reloc handling.  What's worse, for COFF (as opposed to
17622
             ECOFF), we might need yet another copy of reloc->address.
17623
             See bfd_install_relocation.  */
17624
          reloc->addend += reloc->address;
17625
        }
17626
    }
17627
  else
17628
    reloc->addend = fixp->fx_addnumber;
17629
 
17630
  /* Since the old MIPS ELF ABI uses Rel instead of Rela, encode the vtable
17631
     entry to be used in the relocation's section offset.  */
17632
  if (! HAVE_NEWABI && fixp->fx_r_type == BFD_RELOC_VTABLE_ENTRY)
17633
    {
17634
      reloc->address = reloc->addend;
17635
      reloc->addend = 0;
17636
    }
17637
 
17638
  code = fixp->fx_r_type;
17639
 
17640
  reloc->howto = bfd_reloc_type_lookup (stdoutput, code);
17641
  if (reloc->howto == NULL)
17642
    {
17643
      as_bad_where (fixp->fx_file, fixp->fx_line,
17644
                    _("Can not represent %s relocation in this object file format"),
17645
                    bfd_get_reloc_code_name (code));
17646
      retval[0] = NULL;
17647
    }
17648
 
17649
  return retval;
17650
}
17651
 
17652
/* Relax a machine dependent frag.  This returns the amount by which
17653
   the current size of the frag should change.  */
17654
 
17655
int
17656
mips_relax_frag (asection *sec, fragS *fragp, long stretch)
17657
{
17658
  if (RELAX_BRANCH_P (fragp->fr_subtype))
17659
    {
17660
      offsetT old_var = fragp->fr_var;
17661
 
17662
      fragp->fr_var = relaxed_branch_length (fragp, sec, TRUE);
17663
 
17664
      return fragp->fr_var - old_var;
17665
    }
17666
 
17667 160 khays
  if (RELAX_MICROMIPS_P (fragp->fr_subtype))
17668
    {
17669
      offsetT old_var = fragp->fr_var;
17670
      offsetT new_var = 4;
17671
 
17672
      if (RELAX_MICROMIPS_TYPE (fragp->fr_subtype) != 0)
17673
        new_var = relaxed_micromips_16bit_branch_length (fragp, sec, TRUE);
17674
      if (new_var == 4 && RELAX_MICROMIPS_RELAX32 (fragp->fr_subtype))
17675
        new_var = relaxed_micromips_32bit_branch_length (fragp, sec, TRUE);
17676
      fragp->fr_var = new_var;
17677
 
17678
      return new_var - old_var;
17679
    }
17680
 
17681 16 khays
  if (! RELAX_MIPS16_P (fragp->fr_subtype))
17682
    return 0;
17683
 
17684
  if (mips16_extended_frag (fragp, NULL, stretch))
17685
    {
17686
      if (RELAX_MIPS16_EXTENDED (fragp->fr_subtype))
17687
        return 0;
17688
      fragp->fr_subtype = RELAX_MIPS16_MARK_EXTENDED (fragp->fr_subtype);
17689
      return 2;
17690
    }
17691
  else
17692
    {
17693
      if (! RELAX_MIPS16_EXTENDED (fragp->fr_subtype))
17694
        return 0;
17695
      fragp->fr_subtype = RELAX_MIPS16_CLEAR_EXTENDED (fragp->fr_subtype);
17696
      return -2;
17697
    }
17698
 
17699
  return 0;
17700
}
17701
 
17702
/* Convert a machine dependent frag.  */
17703
 
17704
void
17705
md_convert_frag (bfd *abfd ATTRIBUTE_UNUSED, segT asec, fragS *fragp)
17706
{
17707
  if (RELAX_BRANCH_P (fragp->fr_subtype))
17708
    {
17709
      bfd_byte *buf;
17710
      unsigned long insn;
17711
      expressionS exp;
17712
      fixS *fixp;
17713
 
17714
      buf = (bfd_byte *)fragp->fr_literal + fragp->fr_fix;
17715
 
17716
      if (target_big_endian)
17717
        insn = bfd_getb32 (buf);
17718
      else
17719
        insn = bfd_getl32 (buf);
17720
 
17721
      if (!RELAX_BRANCH_TOOFAR (fragp->fr_subtype))
17722
        {
17723
          /* We generate a fixup instead of applying it right now
17724
             because, if there are linker relaxations, we're going to
17725
             need the relocations.  */
17726
          exp.X_op = O_symbol;
17727
          exp.X_add_symbol = fragp->fr_symbol;
17728
          exp.X_add_number = fragp->fr_offset;
17729
 
17730
          fixp = fix_new_exp (fragp, buf - (bfd_byte *)fragp->fr_literal,
17731
                              4, &exp, TRUE, BFD_RELOC_16_PCREL_S2);
17732
          fixp->fx_file = fragp->fr_file;
17733
          fixp->fx_line = fragp->fr_line;
17734
 
17735
          md_number_to_chars ((char *) buf, insn, 4);
17736
          buf += 4;
17737
        }
17738
      else
17739
        {
17740
          int i;
17741
 
17742
          as_warn_where (fragp->fr_file, fragp->fr_line,
17743
                         _("Relaxed out-of-range branch into a jump"));
17744
 
17745
          if (RELAX_BRANCH_UNCOND (fragp->fr_subtype))
17746
            goto uncond;
17747
 
17748
          if (!RELAX_BRANCH_LIKELY (fragp->fr_subtype))
17749
            {
17750
              /* Reverse the branch.  */
17751
              switch ((insn >> 28) & 0xf)
17752
                {
17753
                case 4:
17754
                  /* bc[0-3][tf]l? and bc1any[24][ft] instructions can
17755
                     have the condition reversed by tweaking a single
17756
                     bit, and their opcodes all have 0x4???????.  */
17757
                  gas_assert ((insn & 0xf1000000) == 0x41000000);
17758
                  insn ^= 0x00010000;
17759
                  break;
17760
 
17761
                case 0:
17762
                  /* bltz       0x04000000      bgez    0x04010000
17763
                     bltzal     0x04100000      bgezal  0x04110000  */
17764
                  gas_assert ((insn & 0xfc0e0000) == 0x04000000);
17765
                  insn ^= 0x00010000;
17766
                  break;
17767
 
17768
                case 1:
17769
                  /* beq        0x10000000      bne     0x14000000
17770
                     blez       0x18000000      bgtz    0x1c000000  */
17771
                  insn ^= 0x04000000;
17772
                  break;
17773
 
17774
                default:
17775
                  abort ();
17776
                }
17777
            }
17778
 
17779
          if (RELAX_BRANCH_LINK (fragp->fr_subtype))
17780
            {
17781
              /* Clear the and-link bit.  */
17782
              gas_assert ((insn & 0xfc1c0000) == 0x04100000);
17783
 
17784
              /* bltzal         0x04100000      bgezal  0x04110000
17785
                 bltzall        0x04120000      bgezall 0x04130000  */
17786
              insn &= ~0x00100000;
17787
            }
17788
 
17789
          /* Branch over the branch (if the branch was likely) or the
17790
             full jump (not likely case).  Compute the offset from the
17791
             current instruction to branch to.  */
17792
          if (RELAX_BRANCH_LIKELY (fragp->fr_subtype))
17793
            i = 16;
17794
          else
17795
            {
17796
              /* How many bytes in instructions we've already emitted?  */
17797
              i = buf - (bfd_byte *)fragp->fr_literal - fragp->fr_fix;
17798
              /* How many bytes in instructions from here to the end?  */
17799
              i = fragp->fr_var - i;
17800
            }
17801
          /* Convert to instruction count.  */
17802
          i >>= 2;
17803
          /* Branch counts from the next instruction.  */
17804
          i--;
17805
          insn |= i;
17806
          /* Branch over the jump.  */
17807
          md_number_to_chars ((char *) buf, insn, 4);
17808
          buf += 4;
17809
 
17810
          /* nop */
17811
          md_number_to_chars ((char *) buf, 0, 4);
17812
          buf += 4;
17813
 
17814
          if (RELAX_BRANCH_LIKELY (fragp->fr_subtype))
17815
            {
17816
              /* beql $0, $0, 2f */
17817
              insn = 0x50000000;
17818
              /* Compute the PC offset from the current instruction to
17819
                 the end of the variable frag.  */
17820
              /* How many bytes in instructions we've already emitted?  */
17821
              i = buf - (bfd_byte *)fragp->fr_literal - fragp->fr_fix;
17822
              /* How many bytes in instructions from here to the end?  */
17823
              i = fragp->fr_var - i;
17824
              /* Convert to instruction count.  */
17825
              i >>= 2;
17826
              /* Don't decrement i, because we want to branch over the
17827
                 delay slot.  */
17828
 
17829
              insn |= i;
17830
              md_number_to_chars ((char *) buf, insn, 4);
17831
              buf += 4;
17832
 
17833
              md_number_to_chars ((char *) buf, 0, 4);
17834
              buf += 4;
17835
            }
17836
 
17837
        uncond:
17838
          if (mips_pic == NO_PIC)
17839
            {
17840
              /* j or jal.  */
17841
              insn = (RELAX_BRANCH_LINK (fragp->fr_subtype)
17842
                      ? 0x0c000000 : 0x08000000);
17843
              exp.X_op = O_symbol;
17844
              exp.X_add_symbol = fragp->fr_symbol;
17845
              exp.X_add_number = fragp->fr_offset;
17846
 
17847
              fixp = fix_new_exp (fragp, buf - (bfd_byte *)fragp->fr_literal,
17848
                                  4, &exp, FALSE, BFD_RELOC_MIPS_JMP);
17849
              fixp->fx_file = fragp->fr_file;
17850
              fixp->fx_line = fragp->fr_line;
17851
 
17852
              md_number_to_chars ((char *) buf, insn, 4);
17853
              buf += 4;
17854
            }
17855
          else
17856
            {
17857
              unsigned long at = RELAX_BRANCH_AT (fragp->fr_subtype);
17858
 
17859
              /* lw/ld $at, <sym>($gp)  R_MIPS_GOT16 */
17860
              insn = HAVE_64BIT_ADDRESSES ? 0xdf800000 : 0x8f800000;
17861
              insn |= at << OP_SH_RT;
17862
              exp.X_op = O_symbol;
17863
              exp.X_add_symbol = fragp->fr_symbol;
17864
              exp.X_add_number = fragp->fr_offset;
17865
 
17866
              if (fragp->fr_offset)
17867
                {
17868
                  exp.X_add_symbol = make_expr_symbol (&exp);
17869
                  exp.X_add_number = 0;
17870
                }
17871
 
17872
              fixp = fix_new_exp (fragp, buf - (bfd_byte *)fragp->fr_literal,
17873
                                  4, &exp, FALSE, BFD_RELOC_MIPS_GOT16);
17874
              fixp->fx_file = fragp->fr_file;
17875
              fixp->fx_line = fragp->fr_line;
17876
 
17877
              md_number_to_chars ((char *) buf, insn, 4);
17878
              buf += 4;
17879
 
17880
              if (mips_opts.isa == ISA_MIPS1)
17881
                {
17882
                  /* nop */
17883
                  md_number_to_chars ((char *) buf, 0, 4);
17884
                  buf += 4;
17885
                }
17886
 
17887
              /* d/addiu $at, $at, <sym>  R_MIPS_LO16 */
17888
              insn = HAVE_64BIT_ADDRESSES ? 0x64000000 : 0x24000000;
17889
              insn |= at << OP_SH_RS | at << OP_SH_RT;
17890
 
17891
              fixp = fix_new_exp (fragp, buf - (bfd_byte *)fragp->fr_literal,
17892
                                  4, &exp, FALSE, BFD_RELOC_LO16);
17893
              fixp->fx_file = fragp->fr_file;
17894
              fixp->fx_line = fragp->fr_line;
17895
 
17896
              md_number_to_chars ((char *) buf, insn, 4);
17897
              buf += 4;
17898
 
17899
              /* j(al)r $at.  */
17900
              if (RELAX_BRANCH_LINK (fragp->fr_subtype))
17901
                insn = 0x0000f809;
17902
              else
17903
                insn = 0x00000008;
17904
              insn |= at << OP_SH_RS;
17905
 
17906
              md_number_to_chars ((char *) buf, insn, 4);
17907
              buf += 4;
17908
            }
17909
        }
17910
 
17911
      gas_assert (buf == (bfd_byte *)fragp->fr_literal
17912
              + fragp->fr_fix + fragp->fr_var);
17913
 
17914
      fragp->fr_fix += fragp->fr_var;
17915
 
17916
      return;
17917
    }
17918
 
17919 160 khays
  /* Relax microMIPS branches.  */
17920
  if (RELAX_MICROMIPS_P (fragp->fr_subtype))
17921
    {
17922
      bfd_byte *buf = (bfd_byte *) (fragp->fr_literal + fragp->fr_fix);
17923
      bfd_boolean compact = RELAX_MICROMIPS_COMPACT (fragp->fr_subtype);
17924
      bfd_boolean al = RELAX_MICROMIPS_LINK (fragp->fr_subtype);
17925
      int type = RELAX_MICROMIPS_TYPE (fragp->fr_subtype);
17926
      bfd_boolean short_ds;
17927
      unsigned long insn;
17928
      expressionS exp;
17929
      fixS *fixp;
17930
 
17931
      exp.X_op = O_symbol;
17932
      exp.X_add_symbol = fragp->fr_symbol;
17933
      exp.X_add_number = fragp->fr_offset;
17934
 
17935
      fragp->fr_fix += fragp->fr_var;
17936
 
17937
      /* Handle 16-bit branches that fit or are forced to fit.  */
17938
      if (type != 0 && !RELAX_MICROMIPS_TOOFAR16 (fragp->fr_subtype))
17939
        {
17940
          /* We generate a fixup instead of applying it right now,
17941
             because if there is linker relaxation, we're going to
17942
             need the relocations.  */
17943
          if (type == 'D')
17944
            fixp = fix_new_exp (fragp,
17945
                                buf - (bfd_byte *) fragp->fr_literal,
17946
                                2, &exp, TRUE,
17947
                                BFD_RELOC_MICROMIPS_10_PCREL_S1);
17948
          else if (type == 'E')
17949
            fixp = fix_new_exp (fragp,
17950
                                buf - (bfd_byte *) fragp->fr_literal,
17951
                                2, &exp, TRUE,
17952
                                BFD_RELOC_MICROMIPS_7_PCREL_S1);
17953
          else
17954
            abort ();
17955
 
17956
          fixp->fx_file = fragp->fr_file;
17957
          fixp->fx_line = fragp->fr_line;
17958
 
17959
          /* These relocations can have an addend that won't fit in
17960
             2 octets.  */
17961
          fixp->fx_no_overflow = 1;
17962
 
17963
          return;
17964
        }
17965
 
17966
      /* Handle 32-bit branches that fit or are forced to fit.  */
17967
      if (!RELAX_MICROMIPS_RELAX32 (fragp->fr_subtype)
17968
          || !RELAX_MICROMIPS_TOOFAR32 (fragp->fr_subtype))
17969
        {
17970
          /* We generate a fixup instead of applying it right now,
17971
             because if there is linker relaxation, we're going to
17972
             need the relocations.  */
17973
          fixp = fix_new_exp (fragp, buf - (bfd_byte *) fragp->fr_literal,
17974
                              4, &exp, TRUE, BFD_RELOC_MICROMIPS_16_PCREL_S1);
17975
          fixp->fx_file = fragp->fr_file;
17976
          fixp->fx_line = fragp->fr_line;
17977
 
17978
          if (type == 0)
17979
            return;
17980
        }
17981
 
17982
      /* Relax 16-bit branches to 32-bit branches.  */
17983
      if (type != 0)
17984
        {
17985
          if (target_big_endian)
17986
            insn = bfd_getb16 (buf);
17987
          else
17988
            insn = bfd_getl16 (buf);
17989
 
17990
          if ((insn & 0xfc00) == 0xcc00)                /* b16  */
17991
            insn = 0x94000000;                          /* beq  */
17992
          else if ((insn & 0xdc00) == 0x8c00)           /* beqz16/bnez16  */
17993
            {
17994
              unsigned long regno;
17995
 
17996
              regno = (insn >> MICROMIPSOP_SH_MD) & MICROMIPSOP_MASK_MD;
17997
              regno = micromips_to_32_reg_d_map [regno];
17998
              insn = ((insn & 0x2000) << 16) | 0x94000000;      /* beq/bne  */
17999
              insn |= regno << MICROMIPSOP_SH_RS;
18000
            }
18001
          else
18002
            abort ();
18003
 
18004
          /* Nothing else to do, just write it out.  */
18005
          if (!RELAX_MICROMIPS_RELAX32 (fragp->fr_subtype)
18006
              || !RELAX_MICROMIPS_TOOFAR32 (fragp->fr_subtype))
18007
            {
18008
              md_number_to_chars ((char *) buf, insn >> 16, 2);
18009
              buf += 2;
18010
              md_number_to_chars ((char *) buf, insn & 0xffff, 2);
18011
              buf += 2;
18012
 
18013
              gas_assert (buf == ((bfd_byte *) fragp->fr_literal
18014
                                  + fragp->fr_fix));
18015
              return;
18016
            }
18017
        }
18018
      else
18019
        {
18020
          unsigned long next;
18021
 
18022
          if (target_big_endian)
18023
            {
18024
              insn = bfd_getb16 (buf);
18025
              next = bfd_getb16 (buf + 2);
18026
            }
18027
          else
18028
            {
18029
              insn = bfd_getl16 (buf);
18030
              next = bfd_getl16 (buf + 2);
18031
            }
18032
          insn = (insn << 16) | next;
18033
        }
18034
 
18035
      /* Relax 32-bit branches to a sequence of instructions.  */
18036
      as_warn_where (fragp->fr_file, fragp->fr_line,
18037
                     _("Relaxed out-of-range branch into a jump"));
18038
 
18039
      /* Set the short-delay-slot bit.  */
18040
      short_ds = al && (insn & 0x02000000) != 0;
18041
 
18042
      if (!RELAX_MICROMIPS_UNCOND (fragp->fr_subtype))
18043
        {
18044
          symbolS *l;
18045
 
18046
          /* Reverse the branch.  */
18047
          if ((insn & 0xfc000000) == 0x94000000                 /* beq  */
18048
              || (insn & 0xfc000000) == 0xb4000000)             /* bne  */
18049
            insn ^= 0x20000000;
18050
          else if ((insn & 0xffe00000) == 0x40000000            /* bltz  */
18051
                   || (insn & 0xffe00000) == 0x40400000         /* bgez  */
18052
                   || (insn & 0xffe00000) == 0x40800000         /* blez  */
18053
                   || (insn & 0xffe00000) == 0x40c00000         /* bgtz  */
18054
                   || (insn & 0xffe00000) == 0x40a00000         /* bnezc  */
18055
                   || (insn & 0xffe00000) == 0x40e00000         /* beqzc  */
18056
                   || (insn & 0xffe00000) == 0x40200000         /* bltzal  */
18057
                   || (insn & 0xffe00000) == 0x40600000         /* bgezal  */
18058
                   || (insn & 0xffe00000) == 0x42200000         /* bltzals  */
18059
                   || (insn & 0xffe00000) == 0x42600000)        /* bgezals  */
18060
            insn ^= 0x00400000;
18061
          else if ((insn & 0xffe30000) == 0x43800000            /* bc1f  */
18062
                   || (insn & 0xffe30000) == 0x43a00000         /* bc1t  */
18063
                   || (insn & 0xffe30000) == 0x42800000         /* bc2f  */
18064
                   || (insn & 0xffe30000) == 0x42a00000)        /* bc2t  */
18065
            insn ^= 0x00200000;
18066
          else
18067
            abort ();
18068
 
18069
          if (al)
18070
            {
18071
              /* Clear the and-link and short-delay-slot bits.  */
18072
              gas_assert ((insn & 0xfda00000) == 0x40200000);
18073
 
18074
              /* bltzal  0x40200000     bgezal  0x40600000  */
18075
              /* bltzals 0x42200000     bgezals 0x42600000  */
18076
              insn &= ~0x02200000;
18077
            }
18078
 
18079
          /* Make a label at the end for use with the branch.  */
18080
          l = symbol_new (micromips_label_name (), asec, fragp->fr_fix, fragp);
18081
          micromips_label_inc ();
18082
#if defined(OBJ_ELF) || defined(OBJ_MAYBE_ELF)
18083
          if (IS_ELF)
18084
            S_SET_OTHER (l, ELF_ST_SET_MICROMIPS (S_GET_OTHER (l)));
18085
#endif
18086
 
18087
          /* Refer to it.  */
18088
          fixp = fix_new (fragp, buf - (bfd_byte *) fragp->fr_literal,
18089
                          4, l, 0, TRUE, BFD_RELOC_MICROMIPS_16_PCREL_S1);
18090
          fixp->fx_file = fragp->fr_file;
18091
          fixp->fx_line = fragp->fr_line;
18092
 
18093
          /* Branch over the jump.  */
18094
          md_number_to_chars ((char *) buf, insn >> 16, 2);
18095
          buf += 2;
18096
          md_number_to_chars ((char *) buf, insn & 0xffff, 2);
18097
          buf += 2;
18098
 
18099
          if (!compact)
18100
            {
18101
              /* nop  */
18102
              insn = 0x0c00;
18103
              md_number_to_chars ((char *) buf, insn, 2);
18104
              buf += 2;
18105
            }
18106
        }
18107
 
18108
      if (mips_pic == NO_PIC)
18109
        {
18110
          unsigned long jal = short_ds ? 0x74000000 : 0xf4000000; /* jal/s  */
18111
 
18112
          /* j/jal/jals <sym>  R_MICROMIPS_26_S1  */
18113
          insn = al ? jal : 0xd4000000;
18114
 
18115
          fixp = fix_new_exp (fragp, buf - (bfd_byte *) fragp->fr_literal,
18116
                              4, &exp, FALSE, BFD_RELOC_MICROMIPS_JMP);
18117
          fixp->fx_file = fragp->fr_file;
18118
          fixp->fx_line = fragp->fr_line;
18119
 
18120
          md_number_to_chars ((char *) buf, insn >> 16, 2);
18121
          buf += 2;
18122
          md_number_to_chars ((char *) buf, insn & 0xffff, 2);
18123
          buf += 2;
18124
 
18125
          if (compact)
18126
            {
18127
              /* nop  */
18128
              insn = 0x0c00;
18129
              md_number_to_chars ((char *) buf, insn, 2);
18130
              buf += 2;
18131
            }
18132
        }
18133
      else
18134
        {
18135
          unsigned long at = RELAX_MICROMIPS_AT (fragp->fr_subtype);
18136
          unsigned long jalr = short_ds ? 0x45e0 : 0x45c0;      /* jalr/s  */
18137
          unsigned long jr = compact ? 0x45a0 : 0x4580;         /* jr/c  */
18138
 
18139
          /* lw/ld $at, <sym>($gp)  R_MICROMIPS_GOT16  */
18140
          insn = HAVE_64BIT_ADDRESSES ? 0xdc1c0000 : 0xfc1c0000;
18141
          insn |= at << MICROMIPSOP_SH_RT;
18142
 
18143
          if (exp.X_add_number)
18144
            {
18145
              exp.X_add_symbol = make_expr_symbol (&exp);
18146
              exp.X_add_number = 0;
18147
            }
18148
 
18149
          fixp = fix_new_exp (fragp, buf - (bfd_byte *) fragp->fr_literal,
18150
                              4, &exp, FALSE, BFD_RELOC_MICROMIPS_GOT16);
18151
          fixp->fx_file = fragp->fr_file;
18152
          fixp->fx_line = fragp->fr_line;
18153
 
18154
          md_number_to_chars ((char *) buf, insn >> 16, 2);
18155
          buf += 2;
18156
          md_number_to_chars ((char *) buf, insn & 0xffff, 2);
18157
          buf += 2;
18158
 
18159
          /* d/addiu $at, $at, <sym>  R_MICROMIPS_LO16  */
18160
          insn = HAVE_64BIT_ADDRESSES ? 0x5c000000 : 0x30000000;
18161
          insn |= at << MICROMIPSOP_SH_RT | at << MICROMIPSOP_SH_RS;
18162
 
18163
          fixp = fix_new_exp (fragp, buf - (bfd_byte *) fragp->fr_literal,
18164
                              4, &exp, FALSE, BFD_RELOC_MICROMIPS_LO16);
18165
          fixp->fx_file = fragp->fr_file;
18166
          fixp->fx_line = fragp->fr_line;
18167
 
18168
          md_number_to_chars ((char *) buf, insn >> 16, 2);
18169
          buf += 2;
18170
          md_number_to_chars ((char *) buf, insn & 0xffff, 2);
18171
          buf += 2;
18172
 
18173
          /* jr/jrc/jalr/jalrs $at  */
18174
          insn = al ? jalr : jr;
18175
          insn |= at << MICROMIPSOP_SH_MJ;
18176
 
18177
          md_number_to_chars ((char *) buf, insn & 0xffff, 2);
18178
          buf += 2;
18179
        }
18180
 
18181
      gas_assert (buf == (bfd_byte *) fragp->fr_literal + fragp->fr_fix);
18182
      return;
18183
    }
18184
 
18185 16 khays
  if (RELAX_MIPS16_P (fragp->fr_subtype))
18186
    {
18187
      int type;
18188
      const struct mips16_immed_operand *op;
18189
      bfd_boolean small, ext;
18190
      offsetT val;
18191
      bfd_byte *buf;
18192
      unsigned long insn;
18193
      bfd_boolean use_extend;
18194
      unsigned short extend;
18195
 
18196
      type = RELAX_MIPS16_TYPE (fragp->fr_subtype);
18197
      op = mips16_immed_operands;
18198
      while (op->type != type)
18199
        ++op;
18200
 
18201
      if (RELAX_MIPS16_EXTENDED (fragp->fr_subtype))
18202
        {
18203
          small = FALSE;
18204
          ext = TRUE;
18205
        }
18206
      else
18207
        {
18208
          small = TRUE;
18209
          ext = FALSE;
18210
        }
18211
 
18212
      val = resolve_symbol_value (fragp->fr_symbol);
18213
      if (op->pcrel)
18214
        {
18215
          addressT addr;
18216
 
18217
          addr = fragp->fr_address + fragp->fr_fix;
18218
 
18219
          /* The rules for the base address of a PC relative reloc are
18220
             complicated; see mips16_extended_frag.  */
18221
          if (type == 'p' || type == 'q')
18222
            {
18223
              addr += 2;
18224
              if (ext)
18225
                addr += 2;
18226
              /* Ignore the low bit in the target, since it will be
18227
                 set for a text label.  */
18228
              if ((val & 1) != 0)
18229
                --val;
18230
            }
18231
          else if (RELAX_MIPS16_JAL_DSLOT (fragp->fr_subtype))
18232
            addr -= 4;
18233
          else if (RELAX_MIPS16_DSLOT (fragp->fr_subtype))
18234
            addr -= 2;
18235
 
18236
          addr &= ~ (addressT) ((1 << op->shift) - 1);
18237
          val -= addr;
18238
 
18239
          /* Make sure the section winds up with the alignment we have
18240
             assumed.  */
18241
          if (op->shift > 0)
18242
            record_alignment (asec, op->shift);
18243
        }
18244
 
18245
      if (ext
18246
          && (RELAX_MIPS16_JAL_DSLOT (fragp->fr_subtype)
18247
              || RELAX_MIPS16_DSLOT (fragp->fr_subtype)))
18248
        as_warn_where (fragp->fr_file, fragp->fr_line,
18249
                       _("extended instruction in delay slot"));
18250
 
18251
      buf = (bfd_byte *) (fragp->fr_literal + fragp->fr_fix);
18252
 
18253
      if (target_big_endian)
18254
        insn = bfd_getb16 (buf);
18255
      else
18256
        insn = bfd_getl16 (buf);
18257
 
18258
      mips16_immed (fragp->fr_file, fragp->fr_line, type, val,
18259
                    RELAX_MIPS16_USER_EXT (fragp->fr_subtype),
18260
                    small, ext, &insn, &use_extend, &extend);
18261
 
18262
      if (use_extend)
18263
        {
18264
          md_number_to_chars ((char *) buf, 0xf000 | extend, 2);
18265
          fragp->fr_fix += 2;
18266
          buf += 2;
18267
        }
18268
 
18269
      md_number_to_chars ((char *) buf, insn, 2);
18270
      fragp->fr_fix += 2;
18271
      buf += 2;
18272
    }
18273
  else
18274
    {
18275 160 khays
      relax_substateT subtype = fragp->fr_subtype;
18276
      bfd_boolean second_longer = (subtype & RELAX_SECOND_LONGER) != 0;
18277
      bfd_boolean use_second = (subtype & RELAX_USE_SECOND) != 0;
18278 16 khays
      int first, second;
18279
      fixS *fixp;
18280
 
18281 160 khays
      first = RELAX_FIRST (subtype);
18282
      second = RELAX_SECOND (subtype);
18283 16 khays
      fixp = (fixS *) fragp->fr_opcode;
18284
 
18285 160 khays
      /* If the delay slot chosen does not match the size of the instruction,
18286
         then emit a warning.  */
18287
      if ((!use_second && (subtype & RELAX_DELAY_SLOT_SIZE_FIRST) != 0)
18288
           || (use_second && (subtype & RELAX_DELAY_SLOT_SIZE_SECOND) != 0))
18289
        {
18290
          relax_substateT s;
18291
          const char *msg;
18292
 
18293
          s = subtype & (RELAX_DELAY_SLOT_16BIT
18294
                         | RELAX_DELAY_SLOT_SIZE_FIRST
18295
                         | RELAX_DELAY_SLOT_SIZE_SECOND);
18296
          msg = macro_warning (s);
18297
          if (msg != NULL)
18298 163 khays
            as_warn_where (fragp->fr_file, fragp->fr_line, "%s", msg);
18299 160 khays
          subtype &= ~s;
18300
        }
18301
 
18302 16 khays
      /* Possibly emit a warning if we've chosen the longer option.  */
18303 160 khays
      if (use_second == second_longer)
18304 16 khays
        {
18305 160 khays
          relax_substateT s;
18306
          const char *msg;
18307
 
18308
          s = (subtype
18309
               & (RELAX_SECOND_LONGER | RELAX_NOMACRO | RELAX_DELAY_SLOT));
18310
          msg = macro_warning (s);
18311
          if (msg != NULL)
18312 163 khays
            as_warn_where (fragp->fr_file, fragp->fr_line, "%s", msg);
18313 160 khays
          subtype &= ~s;
18314 16 khays
        }
18315
 
18316
      /* Go through all the fixups for the first sequence.  Disable them
18317
         (by marking them as done) if we're going to use the second
18318
         sequence instead.  */
18319
      while (fixp
18320
             && fixp->fx_frag == fragp
18321
             && fixp->fx_where < fragp->fr_fix - second)
18322
        {
18323 160 khays
          if (subtype & RELAX_USE_SECOND)
18324 16 khays
            fixp->fx_done = 1;
18325
          fixp = fixp->fx_next;
18326
        }
18327
 
18328
      /* Go through the fixups for the second sequence.  Disable them if
18329
         we're going to use the first sequence, otherwise adjust their
18330
         addresses to account for the relaxation.  */
18331
      while (fixp && fixp->fx_frag == fragp)
18332
        {
18333 160 khays
          if (subtype & RELAX_USE_SECOND)
18334 16 khays
            fixp->fx_where -= first;
18335
          else
18336
            fixp->fx_done = 1;
18337
          fixp = fixp->fx_next;
18338
        }
18339
 
18340
      /* Now modify the frag contents.  */
18341 160 khays
      if (subtype & RELAX_USE_SECOND)
18342 16 khays
        {
18343
          char *start;
18344
 
18345
          start = fragp->fr_literal + fragp->fr_fix - first - second;
18346
          memmove (start, start + first, second);
18347
          fragp->fr_fix -= first;
18348
        }
18349
      else
18350
        fragp->fr_fix -= second;
18351
    }
18352
}
18353
 
18354
#ifdef OBJ_ELF
18355
 
18356
/* This function is called after the relocs have been generated.
18357
   We've been storing mips16 text labels as odd.  Here we convert them
18358
   back to even for the convenience of the debugger.  */
18359
 
18360
void
18361
mips_frob_file_after_relocs (void)
18362
{
18363
  asymbol **syms;
18364
  unsigned int count, i;
18365
 
18366
  if (!IS_ELF)
18367
    return;
18368
 
18369
  syms = bfd_get_outsymbols (stdoutput);
18370
  count = bfd_get_symcount (stdoutput);
18371
  for (i = 0; i < count; i++, syms++)
18372 160 khays
    if (ELF_ST_IS_COMPRESSED (elf_symbol (*syms)->internal_elf_sym.st_other)
18373
        && ((*syms)->value & 1) != 0)
18374
      {
18375
        (*syms)->value &= ~1;
18376
        /* If the symbol has an odd size, it was probably computed
18377
           incorrectly, so adjust that as well.  */
18378
        if ((elf_symbol (*syms)->internal_elf_sym.st_size & 1) != 0)
18379
          ++elf_symbol (*syms)->internal_elf_sym.st_size;
18380
      }
18381 16 khays
}
18382
 
18383
#endif
18384
 
18385
/* This function is called whenever a label is defined, including fake
18386
   labels instantiated off the dot special symbol.  It is used when
18387
   handling branch delays; if a branch has a label, we assume we cannot
18388
   move it.  This also bumps the value of the symbol by 1 in compressed
18389
   code.  */
18390
 
18391
void
18392
mips_record_label (symbolS *sym)
18393
{
18394
  segment_info_type *si = seg_info (now_seg);
18395
  struct insn_label_list *l;
18396
 
18397
  if (free_insn_labels == NULL)
18398
    l = (struct insn_label_list *) xmalloc (sizeof *l);
18399
  else
18400
    {
18401
      l = free_insn_labels;
18402
      free_insn_labels = l->next;
18403
    }
18404
 
18405
  l->label = sym;
18406
  l->next = si->label_list;
18407
  si->label_list = l;
18408
}
18409
 
18410
/* This function is called as tc_frob_label() whenever a label is defined
18411
   and adds a DWARF-2 record we only want for true labels.  */
18412
 
18413
void
18414
mips_define_label (symbolS *sym)
18415
{
18416
  mips_record_label (sym);
18417
#ifdef OBJ_ELF
18418
  dwarf2_emit_label (sym);
18419
#endif
18420
}
18421
 
18422
#if defined (OBJ_ELF) || defined (OBJ_MAYBE_ELF)
18423
 
18424
/* Some special processing for a MIPS ELF file.  */
18425
 
18426
void
18427
mips_elf_final_processing (void)
18428
{
18429
  /* Write out the register information.  */
18430
  if (mips_abi != N64_ABI)
18431
    {
18432
      Elf32_RegInfo s;
18433
 
18434
      s.ri_gprmask = mips_gprmask;
18435
      s.ri_cprmask[0] = mips_cprmask[0];
18436
      s.ri_cprmask[1] = mips_cprmask[1];
18437
      s.ri_cprmask[2] = mips_cprmask[2];
18438
      s.ri_cprmask[3] = mips_cprmask[3];
18439
      /* The gp_value field is set by the MIPS ELF backend.  */
18440
 
18441
      bfd_mips_elf32_swap_reginfo_out (stdoutput, &s,
18442
                                       ((Elf32_External_RegInfo *)
18443
                                        mips_regmask_frag));
18444
    }
18445
  else
18446
    {
18447
      Elf64_Internal_RegInfo s;
18448
 
18449
      s.ri_gprmask = mips_gprmask;
18450
      s.ri_pad = 0;
18451
      s.ri_cprmask[0] = mips_cprmask[0];
18452
      s.ri_cprmask[1] = mips_cprmask[1];
18453
      s.ri_cprmask[2] = mips_cprmask[2];
18454
      s.ri_cprmask[3] = mips_cprmask[3];
18455
      /* The gp_value field is set by the MIPS ELF backend.  */
18456
 
18457
      bfd_mips_elf64_swap_reginfo_out (stdoutput, &s,
18458
                                       ((Elf64_External_RegInfo *)
18459
                                        mips_regmask_frag));
18460
    }
18461
 
18462
  /* Set the MIPS ELF flag bits.  FIXME: There should probably be some
18463
     sort of BFD interface for this.  */
18464
  if (mips_any_noreorder)
18465
    elf_elfheader (stdoutput)->e_flags |= EF_MIPS_NOREORDER;
18466
  if (mips_pic != NO_PIC)
18467
    {
18468 163 khays
      elf_elfheader (stdoutput)->e_flags |= EF_MIPS_PIC;
18469 16 khays
      elf_elfheader (stdoutput)->e_flags |= EF_MIPS_CPIC;
18470
    }
18471
  if (mips_abicalls)
18472
    elf_elfheader (stdoutput)->e_flags |= EF_MIPS_CPIC;
18473
 
18474
  /* Set MIPS ELF flags for ASEs.  */
18475
  /* We may need to define a new flag for DSP ASE, and set this flag when
18476
     file_ase_dsp is true.  */
18477
  /* Same for DSP R2.  */
18478
  /* We may need to define a new flag for MT ASE, and set this flag when
18479
     file_ase_mt is true.  */
18480
  if (file_ase_mips16)
18481
    elf_elfheader (stdoutput)->e_flags |= EF_MIPS_ARCH_ASE_M16;
18482 160 khays
  if (file_ase_micromips)
18483
    elf_elfheader (stdoutput)->e_flags |= EF_MIPS_ARCH_ASE_MICROMIPS;
18484 16 khays
#if 0 /* XXX FIXME */
18485
  if (file_ase_mips3d)
18486
    elf_elfheader (stdoutput)->e_flags |= ???;
18487
#endif
18488
  if (file_ase_mdmx)
18489
    elf_elfheader (stdoutput)->e_flags |= EF_MIPS_ARCH_ASE_MDMX;
18490
 
18491
  /* Set the MIPS ELF ABI flags.  */
18492
  if (mips_abi == O32_ABI && USE_E_MIPS_ABI_O32)
18493
    elf_elfheader (stdoutput)->e_flags |= E_MIPS_ABI_O32;
18494
  else if (mips_abi == O64_ABI)
18495
    elf_elfheader (stdoutput)->e_flags |= E_MIPS_ABI_O64;
18496
  else if (mips_abi == EABI_ABI)
18497
    {
18498
      if (!file_mips_gp32)
18499
        elf_elfheader (stdoutput)->e_flags |= E_MIPS_ABI_EABI64;
18500
      else
18501
        elf_elfheader (stdoutput)->e_flags |= E_MIPS_ABI_EABI32;
18502
    }
18503
  else if (mips_abi == N32_ABI)
18504
    elf_elfheader (stdoutput)->e_flags |= EF_MIPS_ABI2;
18505
 
18506
  /* Nothing to do for N64_ABI.  */
18507
 
18508
  if (mips_32bitmode)
18509
    elf_elfheader (stdoutput)->e_flags |= EF_MIPS_32BITMODE;
18510
 
18511
#if 0 /* XXX FIXME */
18512
  /* 32 bit code with 64 bit FP registers.  */
18513
  if (!file_mips_fp32 && ABI_NEEDS_32BIT_REGS (mips_abi))
18514
    elf_elfheader (stdoutput)->e_flags |= ???;
18515
#endif
18516
}
18517
 
18518
#endif /* OBJ_ELF || OBJ_MAYBE_ELF */
18519
 
18520
typedef struct proc {
18521
  symbolS *func_sym;
18522
  symbolS *func_end_sym;
18523
  unsigned long reg_mask;
18524
  unsigned long reg_offset;
18525
  unsigned long fpreg_mask;
18526
  unsigned long fpreg_offset;
18527
  unsigned long frame_offset;
18528
  unsigned long frame_reg;
18529
  unsigned long pc_reg;
18530
} procS;
18531
 
18532
static procS cur_proc;
18533
static procS *cur_proc_ptr;
18534
static int numprocs;
18535
 
18536 160 khays
/* Implement NOP_OPCODE.  We encode a MIPS16 nop as "1", a microMIPS nop
18537
   as "2", and a normal nop as "0".  */
18538 16 khays
 
18539 160 khays
#define NOP_OPCODE_MIPS         0
18540
#define NOP_OPCODE_MIPS16       1
18541
#define NOP_OPCODE_MICROMIPS    2
18542
 
18543 16 khays
char
18544
mips_nop_opcode (void)
18545
{
18546 160 khays
  if (seg_info (now_seg)->tc_segment_info_data.micromips)
18547
    return NOP_OPCODE_MICROMIPS;
18548
  else if (seg_info (now_seg)->tc_segment_info_data.mips16)
18549
    return NOP_OPCODE_MIPS16;
18550
  else
18551
    return NOP_OPCODE_MIPS;
18552 16 khays
}
18553
 
18554 160 khays
/* Fill in an rs_align_code fragment.  Unlike elsewhere we want to use
18555
   32-bit microMIPS NOPs here (if applicable).  */
18556 16 khays
 
18557
void
18558
mips_handle_align (fragS *fragp)
18559
{
18560 160 khays
  char nop_opcode;
18561 16 khays
  char *p;
18562
  int bytes, size, excess;
18563
  valueT opcode;
18564
 
18565
  if (fragp->fr_type != rs_align_code)
18566
    return;
18567
 
18568
  p = fragp->fr_literal + fragp->fr_fix;
18569 160 khays
  nop_opcode = *p;
18570
  switch (nop_opcode)
18571 16 khays
    {
18572 160 khays
    case NOP_OPCODE_MICROMIPS:
18573
      opcode = micromips_nop32_insn.insn_opcode;
18574
      size = 4;
18575
      break;
18576
    case NOP_OPCODE_MIPS16:
18577 16 khays
      opcode = mips16_nop_insn.insn_opcode;
18578
      size = 2;
18579 160 khays
      break;
18580
    case NOP_OPCODE_MIPS:
18581
    default:
18582 16 khays
      opcode = nop_insn.insn_opcode;
18583
      size = 4;
18584 160 khays
      break;
18585 16 khays
    }
18586
 
18587
  bytes = fragp->fr_next->fr_address - fragp->fr_address - fragp->fr_fix;
18588
  excess = bytes % size;
18589 160 khays
 
18590
  /* Handle the leading part if we're not inserting a whole number of
18591
     instructions, and make it the end of the fixed part of the frag.
18592
     Try to fit in a short microMIPS NOP if applicable and possible,
18593
     and use zeroes otherwise.  */
18594
  gas_assert (excess < 4);
18595
  fragp->fr_fix += excess;
18596
  switch (excess)
18597 16 khays
    {
18598 160 khays
    case 3:
18599
      *p++ = '\0';
18600
      /* Fall through.  */
18601
    case 2:
18602
      if (nop_opcode == NOP_OPCODE_MICROMIPS)
18603
        {
18604
          md_number_to_chars (p, micromips_nop16_insn.insn_opcode, 2);
18605
          p += 2;
18606
          break;
18607
        }
18608
      *p++ = '\0';
18609
      /* Fall through.  */
18610
    case 1:
18611
      *p++ = '\0';
18612
      /* Fall through.  */
18613
    case 0:
18614
      break;
18615 16 khays
    }
18616
 
18617
  md_number_to_chars (p, opcode, size);
18618
  fragp->fr_var = size;
18619
}
18620
 
18621
static void
18622
md_obj_begin (void)
18623
{
18624
}
18625
 
18626
static void
18627
md_obj_end (void)
18628
{
18629
  /* Check for premature end, nesting errors, etc.  */
18630
  if (cur_proc_ptr)
18631
    as_warn (_("missing .end at end of assembly"));
18632
}
18633
 
18634
static long
18635
get_number (void)
18636
{
18637
  int negative = 0;
18638
  long val = 0;
18639
 
18640
  if (*input_line_pointer == '-')
18641
    {
18642
      ++input_line_pointer;
18643
      negative = 1;
18644
    }
18645
  if (!ISDIGIT (*input_line_pointer))
18646
    as_bad (_("expected simple number"));
18647
  if (input_line_pointer[0] == '0')
18648
    {
18649
      if (input_line_pointer[1] == 'x')
18650
        {
18651
          input_line_pointer += 2;
18652
          while (ISXDIGIT (*input_line_pointer))
18653
            {
18654
              val <<= 4;
18655
              val |= hex_value (*input_line_pointer++);
18656
            }
18657
          return negative ? -val : val;
18658
        }
18659
      else
18660
        {
18661
          ++input_line_pointer;
18662
          while (ISDIGIT (*input_line_pointer))
18663
            {
18664
              val <<= 3;
18665
              val |= *input_line_pointer++ - '0';
18666
            }
18667
          return negative ? -val : val;
18668
        }
18669
    }
18670
  if (!ISDIGIT (*input_line_pointer))
18671
    {
18672
      printf (_(" *input_line_pointer == '%c' 0x%02x\n"),
18673
              *input_line_pointer, *input_line_pointer);
18674
      as_warn (_("invalid number"));
18675
      return -1;
18676
    }
18677
  while (ISDIGIT (*input_line_pointer))
18678
    {
18679
      val *= 10;
18680
      val += *input_line_pointer++ - '0';
18681
    }
18682
  return negative ? -val : val;
18683
}
18684
 
18685
/* The .file directive; just like the usual .file directive, but there
18686
   is an initial number which is the ECOFF file index.  In the non-ECOFF
18687
   case .file implies DWARF-2.  */
18688
 
18689
static void
18690
s_mips_file (int x ATTRIBUTE_UNUSED)
18691
{
18692
  static int first_file_directive = 0;
18693
 
18694
  if (ECOFF_DEBUGGING)
18695
    {
18696
      get_number ();
18697
      s_app_file (0);
18698
    }
18699
  else
18700
    {
18701
      char *filename;
18702
 
18703
      filename = dwarf2_directive_file (0);
18704
 
18705
      /* Versions of GCC up to 3.1 start files with a ".file"
18706
         directive even for stabs output.  Make sure that this
18707
         ".file" is handled.  Note that you need a version of GCC
18708
         after 3.1 in order to support DWARF-2 on MIPS.  */
18709
      if (filename != NULL && ! first_file_directive)
18710
        {
18711
          (void) new_logical_line (filename, -1);
18712
          s_app_file_string (filename, 0);
18713
        }
18714
      first_file_directive = 1;
18715
    }
18716
}
18717
 
18718
/* The .loc directive, implying DWARF-2.  */
18719
 
18720
static void
18721
s_mips_loc (int x ATTRIBUTE_UNUSED)
18722
{
18723
  if (!ECOFF_DEBUGGING)
18724
    dwarf2_directive_loc (0);
18725
}
18726
 
18727
/* The .end directive.  */
18728
 
18729
static void
18730
s_mips_end (int x ATTRIBUTE_UNUSED)
18731
{
18732
  symbolS *p;
18733
 
18734
  /* Following functions need their own .frame and .cprestore directives.  */
18735
  mips_frame_reg_valid = 0;
18736
  mips_cprestore_valid = 0;
18737
 
18738
  if (!is_end_of_line[(unsigned char) *input_line_pointer])
18739
    {
18740
      p = get_symbol ();
18741
      demand_empty_rest_of_line ();
18742
    }
18743
  else
18744
    p = NULL;
18745
 
18746
  if ((bfd_get_section_flags (stdoutput, now_seg) & SEC_CODE) == 0)
18747
    as_warn (_(".end not in text section"));
18748
 
18749
  if (!cur_proc_ptr)
18750
    {
18751
      as_warn (_(".end directive without a preceding .ent directive."));
18752
      demand_empty_rest_of_line ();
18753
      return;
18754
    }
18755
 
18756
  if (p != NULL)
18757
    {
18758
      gas_assert (S_GET_NAME (p));
18759
      if (strcmp (S_GET_NAME (p), S_GET_NAME (cur_proc_ptr->func_sym)))
18760
        as_warn (_(".end symbol does not match .ent symbol."));
18761
 
18762
      if (debug_type == DEBUG_STABS)
18763
        stabs_generate_asm_endfunc (S_GET_NAME (p),
18764
                                    S_GET_NAME (p));
18765
    }
18766
  else
18767
    as_warn (_(".end directive missing or unknown symbol"));
18768
 
18769
#ifdef OBJ_ELF
18770
  /* Create an expression to calculate the size of the function.  */
18771
  if (p && cur_proc_ptr)
18772
    {
18773
      OBJ_SYMFIELD_TYPE *obj = symbol_get_obj (p);
18774
      expressionS *exp = xmalloc (sizeof (expressionS));
18775
 
18776
      obj->size = exp;
18777
      exp->X_op = O_subtract;
18778
      exp->X_add_symbol = symbol_temp_new_now ();
18779
      exp->X_op_symbol = p;
18780
      exp->X_add_number = 0;
18781
 
18782
      cur_proc_ptr->func_end_sym = exp->X_add_symbol;
18783
    }
18784
 
18785
  /* Generate a .pdr section.  */
18786
  if (IS_ELF && !ECOFF_DEBUGGING && mips_flag_pdr)
18787
    {
18788
      segT saved_seg = now_seg;
18789
      subsegT saved_subseg = now_subseg;
18790
      expressionS exp;
18791
      char *fragp;
18792
 
18793
#ifdef md_flush_pending_output
18794
      md_flush_pending_output ();
18795
#endif
18796
 
18797
      gas_assert (pdr_seg);
18798
      subseg_set (pdr_seg, 0);
18799
 
18800
      /* Write the symbol.  */
18801
      exp.X_op = O_symbol;
18802
      exp.X_add_symbol = p;
18803
      exp.X_add_number = 0;
18804
      emit_expr (&exp, 4);
18805
 
18806
      fragp = frag_more (7 * 4);
18807
 
18808
      md_number_to_chars (fragp, cur_proc_ptr->reg_mask, 4);
18809
      md_number_to_chars (fragp + 4, cur_proc_ptr->reg_offset, 4);
18810
      md_number_to_chars (fragp + 8, cur_proc_ptr->fpreg_mask, 4);
18811
      md_number_to_chars (fragp + 12, cur_proc_ptr->fpreg_offset, 4);
18812
      md_number_to_chars (fragp + 16, cur_proc_ptr->frame_offset, 4);
18813
      md_number_to_chars (fragp + 20, cur_proc_ptr->frame_reg, 4);
18814
      md_number_to_chars (fragp + 24, cur_proc_ptr->pc_reg, 4);
18815
 
18816
      subseg_set (saved_seg, saved_subseg);
18817
    }
18818
#endif /* OBJ_ELF */
18819
 
18820
  cur_proc_ptr = NULL;
18821
}
18822
 
18823
/* The .aent and .ent directives.  */
18824
 
18825
static void
18826
s_mips_ent (int aent)
18827
{
18828
  symbolS *symbolP;
18829
 
18830
  symbolP = get_symbol ();
18831
  if (*input_line_pointer == ',')
18832
    ++input_line_pointer;
18833
  SKIP_WHITESPACE ();
18834
  if (ISDIGIT (*input_line_pointer)
18835
      || *input_line_pointer == '-')
18836
    get_number ();
18837
 
18838
  if ((bfd_get_section_flags (stdoutput, now_seg) & SEC_CODE) == 0)
18839
    as_warn (_(".ent or .aent not in text section."));
18840
 
18841
  if (!aent && cur_proc_ptr)
18842
    as_warn (_("missing .end"));
18843
 
18844
  if (!aent)
18845
    {
18846
      /* This function needs its own .frame and .cprestore directives.  */
18847
      mips_frame_reg_valid = 0;
18848
      mips_cprestore_valid = 0;
18849
 
18850
      cur_proc_ptr = &cur_proc;
18851
      memset (cur_proc_ptr, '\0', sizeof (procS));
18852
 
18853
      cur_proc_ptr->func_sym = symbolP;
18854
 
18855
      ++numprocs;
18856
 
18857
      if (debug_type == DEBUG_STABS)
18858
        stabs_generate_asm_func (S_GET_NAME (symbolP),
18859
                                 S_GET_NAME (symbolP));
18860
    }
18861
 
18862
  symbol_get_bfdsym (symbolP)->flags |= BSF_FUNCTION;
18863
 
18864
  demand_empty_rest_of_line ();
18865
}
18866
 
18867
/* The .frame directive. If the mdebug section is present (IRIX 5 native)
18868
   then ecoff.c (ecoff_directive_frame) is used. For embedded targets,
18869
   s_mips_frame is used so that we can set the PDR information correctly.
18870
   We can't use the ecoff routines because they make reference to the ecoff
18871
   symbol table (in the mdebug section).  */
18872
 
18873
static void
18874
s_mips_frame (int ignore ATTRIBUTE_UNUSED)
18875
{
18876
#ifdef OBJ_ELF
18877
  if (IS_ELF && !ECOFF_DEBUGGING)
18878
    {
18879
      long val;
18880
 
18881
      if (cur_proc_ptr == (procS *) NULL)
18882
        {
18883
          as_warn (_(".frame outside of .ent"));
18884
          demand_empty_rest_of_line ();
18885
          return;
18886
        }
18887
 
18888
      cur_proc_ptr->frame_reg = tc_get_register (1);
18889
 
18890
      SKIP_WHITESPACE ();
18891
      if (*input_line_pointer++ != ','
18892
          || get_absolute_expression_and_terminator (&val) != ',')
18893
        {
18894
          as_warn (_("Bad .frame directive"));
18895
          --input_line_pointer;
18896
          demand_empty_rest_of_line ();
18897
          return;
18898
        }
18899
 
18900
      cur_proc_ptr->frame_offset = val;
18901
      cur_proc_ptr->pc_reg = tc_get_register (0);
18902
 
18903
      demand_empty_rest_of_line ();
18904
    }
18905
  else
18906
#endif /* OBJ_ELF */
18907
    s_ignore (ignore);
18908
}
18909
 
18910
/* The .fmask and .mask directives. If the mdebug section is present
18911
   (IRIX 5 native) then ecoff.c (ecoff_directive_mask) is used. For
18912
   embedded targets, s_mips_mask is used so that we can set the PDR
18913
   information correctly. We can't use the ecoff routines because they
18914
   make reference to the ecoff symbol table (in the mdebug section).  */
18915
 
18916
static void
18917
s_mips_mask (int reg_type)
18918
{
18919
#ifdef OBJ_ELF
18920
  if (IS_ELF && !ECOFF_DEBUGGING)
18921
    {
18922
      long mask, off;
18923
 
18924
      if (cur_proc_ptr == (procS *) NULL)
18925
        {
18926
          as_warn (_(".mask/.fmask outside of .ent"));
18927
          demand_empty_rest_of_line ();
18928
          return;
18929
        }
18930
 
18931
      if (get_absolute_expression_and_terminator (&mask) != ',')
18932
        {
18933
          as_warn (_("Bad .mask/.fmask directive"));
18934
          --input_line_pointer;
18935
          demand_empty_rest_of_line ();
18936
          return;
18937
        }
18938
 
18939
      off = get_absolute_expression ();
18940
 
18941
      if (reg_type == 'F')
18942
        {
18943
          cur_proc_ptr->fpreg_mask = mask;
18944
          cur_proc_ptr->fpreg_offset = off;
18945
        }
18946
      else
18947
        {
18948
          cur_proc_ptr->reg_mask = mask;
18949
          cur_proc_ptr->reg_offset = off;
18950
        }
18951
 
18952
      demand_empty_rest_of_line ();
18953
    }
18954
  else
18955
#endif /* OBJ_ELF */
18956
    s_ignore (reg_type);
18957
}
18958
 
18959
/* A table describing all the processors gas knows about.  Names are
18960
   matched in the order listed.
18961
 
18962
   To ease comparison, please keep this table in the same order as
18963
   gcc's mips_cpu_info_table[].  */
18964
static const struct mips_cpu_info mips_cpu_info_table[] =
18965
{
18966
  /* Entries for generic ISAs */
18967
  { "mips1",          MIPS_CPU_IS_ISA,          ISA_MIPS1,      CPU_R3000 },
18968
  { "mips2",          MIPS_CPU_IS_ISA,          ISA_MIPS2,      CPU_R6000 },
18969
  { "mips3",          MIPS_CPU_IS_ISA,          ISA_MIPS3,      CPU_R4000 },
18970
  { "mips4",          MIPS_CPU_IS_ISA,          ISA_MIPS4,      CPU_R8000 },
18971
  { "mips5",          MIPS_CPU_IS_ISA,          ISA_MIPS5,      CPU_MIPS5 },
18972
  { "mips32",         MIPS_CPU_IS_ISA,          ISA_MIPS32,     CPU_MIPS32 },
18973
  { "mips32r2",       MIPS_CPU_IS_ISA,          ISA_MIPS32R2,   CPU_MIPS32R2 },
18974
  { "mips64",         MIPS_CPU_IS_ISA,          ISA_MIPS64,     CPU_MIPS64 },
18975
  { "mips64r2",       MIPS_CPU_IS_ISA,          ISA_MIPS64R2,   CPU_MIPS64R2 },
18976
 
18977
  /* MIPS I */
18978
  { "r3000",          0,                 ISA_MIPS1,      CPU_R3000 },
18979
  { "r2000",          0,                 ISA_MIPS1,      CPU_R3000 },
18980
  { "r3900",          0,                 ISA_MIPS1,      CPU_R3900 },
18981
 
18982
  /* MIPS II */
18983
  { "r6000",          0,                 ISA_MIPS2,      CPU_R6000 },
18984
 
18985
  /* MIPS III */
18986
  { "r4000",          0,                 ISA_MIPS3,      CPU_R4000 },
18987
  { "r4010",          0,                 ISA_MIPS2,      CPU_R4010 },
18988
  { "vr4100",         0,                 ISA_MIPS3,      CPU_VR4100 },
18989
  { "vr4111",         0,                 ISA_MIPS3,      CPU_R4111 },
18990
  { "vr4120",         0,                 ISA_MIPS3,      CPU_VR4120 },
18991
  { "vr4130",         0,                 ISA_MIPS3,      CPU_VR4120 },
18992
  { "vr4181",         0,                 ISA_MIPS3,      CPU_R4111 },
18993
  { "vr4300",         0,                 ISA_MIPS3,      CPU_R4300 },
18994
  { "r4400",          0,                 ISA_MIPS3,      CPU_R4400 },
18995
  { "r4600",          0,                 ISA_MIPS3,      CPU_R4600 },
18996
  { "orion",          0,                 ISA_MIPS3,      CPU_R4600 },
18997
  { "r4650",          0,                 ISA_MIPS3,      CPU_R4650 },
18998
  /* ST Microelectronics Loongson 2E and 2F cores */
18999
  { "loongson2e",     0,                 ISA_MIPS3,   CPU_LOONGSON_2E },
19000
  { "loongson2f",     0,                 ISA_MIPS3,   CPU_LOONGSON_2F },
19001
 
19002
  /* MIPS IV */
19003
  { "r8000",          0,                 ISA_MIPS4,      CPU_R8000 },
19004
  { "r10000",         0,                 ISA_MIPS4,      CPU_R10000 },
19005
  { "r12000",         0,                 ISA_MIPS4,      CPU_R12000 },
19006
  { "r14000",         0,                 ISA_MIPS4,      CPU_R14000 },
19007
  { "r16000",         0,                 ISA_MIPS4,      CPU_R16000 },
19008
  { "vr5000",         0,                 ISA_MIPS4,      CPU_R5000 },
19009
  { "vr5400",         0,                 ISA_MIPS4,      CPU_VR5400 },
19010
  { "vr5500",         0,                 ISA_MIPS4,      CPU_VR5500 },
19011
  { "rm5200",         0,                 ISA_MIPS4,      CPU_R5000 },
19012
  { "rm5230",         0,                 ISA_MIPS4,      CPU_R5000 },
19013
  { "rm5231",         0,                 ISA_MIPS4,      CPU_R5000 },
19014
  { "rm5261",         0,                 ISA_MIPS4,      CPU_R5000 },
19015
  { "rm5721",         0,                 ISA_MIPS4,      CPU_R5000 },
19016
  { "rm7000",         0,                 ISA_MIPS4,      CPU_RM7000 },
19017
  { "rm9000",         0,                 ISA_MIPS4,      CPU_RM9000 },
19018
 
19019
  /* MIPS 32 */
19020
  { "4kc",            0,                 ISA_MIPS32,     CPU_MIPS32 },
19021
  { "4km",            0,                 ISA_MIPS32,     CPU_MIPS32 },
19022
  { "4kp",            0,                 ISA_MIPS32,     CPU_MIPS32 },
19023
  { "4ksc",           MIPS_CPU_ASE_SMARTMIPS,   ISA_MIPS32,     CPU_MIPS32 },
19024
 
19025
  /* MIPS 32 Release 2 */
19026
  { "4kec",           0,                 ISA_MIPS32R2,   CPU_MIPS32R2 },
19027
  { "4kem",           0,                 ISA_MIPS32R2,   CPU_MIPS32R2 },
19028
  { "4kep",           0,                 ISA_MIPS32R2,   CPU_MIPS32R2 },
19029
  { "4ksd",           MIPS_CPU_ASE_SMARTMIPS,   ISA_MIPS32R2,   CPU_MIPS32R2 },
19030
  { "m4k",            0,                 ISA_MIPS32R2,   CPU_MIPS32R2 },
19031
  { "m4kp",           0,                 ISA_MIPS32R2,   CPU_MIPS32R2 },
19032 160 khays
  { "m14k",           MIPS_CPU_ASE_MCU,         ISA_MIPS32R2,   CPU_MIPS32R2 },
19033
  { "m14kc",          MIPS_CPU_ASE_MCU,         ISA_MIPS32R2,   CPU_MIPS32R2 },
19034 166 khays
  { "m14ke",          MIPS_CPU_ASE_DSP | MIPS_CPU_ASE_DSPR2 | MIPS_CPU_ASE_MCU,
19035
                                                ISA_MIPS32R2,   CPU_MIPS32R2 },
19036
  { "m14kec",         MIPS_CPU_ASE_DSP | MIPS_CPU_ASE_DSPR2 | MIPS_CPU_ASE_MCU,
19037
                                                ISA_MIPS32R2,   CPU_MIPS32R2 },
19038 16 khays
  { "24kc",           0,                 ISA_MIPS32R2,   CPU_MIPS32R2 },
19039
  { "24kf2_1",        0,                 ISA_MIPS32R2,   CPU_MIPS32R2 },
19040
  { "24kf",           0,                 ISA_MIPS32R2,   CPU_MIPS32R2 },
19041
  { "24kf1_1",        0,                 ISA_MIPS32R2,   CPU_MIPS32R2 },
19042
  /* Deprecated forms of the above.  */
19043
  { "24kfx",          0,                 ISA_MIPS32R2,   CPU_MIPS32R2 },
19044
  { "24kx",           0,                 ISA_MIPS32R2,   CPU_MIPS32R2 },
19045
  /* 24KE is a 24K with DSP ASE, other ASEs are optional.  */
19046
  { "24kec",          MIPS_CPU_ASE_DSP,         ISA_MIPS32R2,   CPU_MIPS32R2 },
19047
  { "24kef2_1",       MIPS_CPU_ASE_DSP,         ISA_MIPS32R2,   CPU_MIPS32R2 },
19048
  { "24kef",          MIPS_CPU_ASE_DSP,         ISA_MIPS32R2,   CPU_MIPS32R2 },
19049
  { "24kef1_1",       MIPS_CPU_ASE_DSP,         ISA_MIPS32R2,   CPU_MIPS32R2 },
19050
  /* Deprecated forms of the above.  */
19051
  { "24kefx",         MIPS_CPU_ASE_DSP,         ISA_MIPS32R2,   CPU_MIPS32R2 },
19052
  { "24kex",          MIPS_CPU_ASE_DSP,         ISA_MIPS32R2,   CPU_MIPS32R2 },
19053
  /* 34K is a 24K with DSP and MT ASE, other ASEs are optional.  */
19054
  { "34kc",           MIPS_CPU_ASE_DSP | MIPS_CPU_ASE_MT,
19055
                                                ISA_MIPS32R2,   CPU_MIPS32R2 },
19056
  { "34kf2_1",        MIPS_CPU_ASE_DSP | MIPS_CPU_ASE_MT,
19057
                                                ISA_MIPS32R2,   CPU_MIPS32R2 },
19058
  { "34kf",           MIPS_CPU_ASE_DSP | MIPS_CPU_ASE_MT,
19059
                                                ISA_MIPS32R2,   CPU_MIPS32R2 },
19060
  { "34kf1_1",        MIPS_CPU_ASE_DSP | MIPS_CPU_ASE_MT,
19061
                                                ISA_MIPS32R2,   CPU_MIPS32R2 },
19062
  /* Deprecated forms of the above.  */
19063
  { "34kfx",          MIPS_CPU_ASE_DSP | MIPS_CPU_ASE_MT,
19064
                                                ISA_MIPS32R2,   CPU_MIPS32R2 },
19065
  { "34kx",           MIPS_CPU_ASE_DSP | MIPS_CPU_ASE_MT,
19066
                                                ISA_MIPS32R2,   CPU_MIPS32R2 },
19067
  /* 74K with DSP and DSPR2 ASE, other ASEs are optional.  */
19068
  { "74kc",           MIPS_CPU_ASE_DSP | MIPS_CPU_ASE_DSPR2,
19069
                                                ISA_MIPS32R2,   CPU_MIPS32R2 },
19070
  { "74kf2_1",        MIPS_CPU_ASE_DSP | MIPS_CPU_ASE_DSPR2,
19071
                                                ISA_MIPS32R2,   CPU_MIPS32R2 },
19072
  { "74kf",           MIPS_CPU_ASE_DSP | MIPS_CPU_ASE_DSPR2,
19073
                                                ISA_MIPS32R2,   CPU_MIPS32R2 },
19074
  { "74kf1_1",        MIPS_CPU_ASE_DSP | MIPS_CPU_ASE_DSPR2,
19075
                                                ISA_MIPS32R2,   CPU_MIPS32R2 },
19076
  { "74kf3_2",        MIPS_CPU_ASE_DSP | MIPS_CPU_ASE_DSPR2,
19077
                                                ISA_MIPS32R2,   CPU_MIPS32R2 },
19078
  /* Deprecated forms of the above.  */
19079
  { "74kfx",          MIPS_CPU_ASE_DSP | MIPS_CPU_ASE_DSPR2,
19080
                                                ISA_MIPS32R2,   CPU_MIPS32R2 },
19081
  { "74kx",           MIPS_CPU_ASE_DSP | MIPS_CPU_ASE_DSPR2,
19082
                                                ISA_MIPS32R2,   CPU_MIPS32R2 },
19083
  /* 1004K cores are multiprocessor versions of the 34K.  */
19084
  { "1004kc",         MIPS_CPU_ASE_DSP | MIPS_CPU_ASE_MT,
19085
                                                ISA_MIPS32R2,   CPU_MIPS32R2 },
19086
  { "1004kf2_1",      MIPS_CPU_ASE_DSP | MIPS_CPU_ASE_MT,
19087
                                                ISA_MIPS32R2,   CPU_MIPS32R2 },
19088
  { "1004kf",         MIPS_CPU_ASE_DSP | MIPS_CPU_ASE_MT,
19089
                                                ISA_MIPS32R2,   CPU_MIPS32R2 },
19090
  { "1004kf1_1",      MIPS_CPU_ASE_DSP | MIPS_CPU_ASE_MT,
19091
                                                ISA_MIPS32R2,   CPU_MIPS32R2 },
19092
 
19093
  /* MIPS 64 */
19094
  { "5kc",            0,                 ISA_MIPS64,     CPU_MIPS64 },
19095
  { "5kf",            0,                 ISA_MIPS64,     CPU_MIPS64 },
19096
  { "20kc",           MIPS_CPU_ASE_MIPS3D,      ISA_MIPS64,     CPU_MIPS64 },
19097
  { "25kf",           MIPS_CPU_ASE_MIPS3D,      ISA_MIPS64,     CPU_MIPS64 },
19098
 
19099
  /* Broadcom SB-1 CPU core */
19100
  { "sb1",            MIPS_CPU_ASE_MIPS3D | MIPS_CPU_ASE_MDMX,
19101
                                                ISA_MIPS64,     CPU_SB1 },
19102
  /* Broadcom SB-1A CPU core */
19103
  { "sb1a",           MIPS_CPU_ASE_MIPS3D | MIPS_CPU_ASE_MDMX,
19104
                                                ISA_MIPS64,     CPU_SB1 },
19105
 
19106
  { "loongson3a",     0,                 ISA_MIPS64,     CPU_LOONGSON_3A },
19107
 
19108
  /* MIPS 64 Release 2 */
19109
 
19110
  /* Cavium Networks Octeon CPU core */
19111
  { "octeon",         0,      ISA_MIPS64R2,   CPU_OCTEON },
19112 166 khays
  { "octeon+",        0,      ISA_MIPS64R2,   CPU_OCTEONP },
19113
  { "octeon2",        0,      ISA_MIPS64R2,   CPU_OCTEON2 },
19114 16 khays
 
19115
  /* RMI Xlr */
19116
  { "xlr",            0,      ISA_MIPS64,     CPU_XLR },
19117
 
19118
  /* End marker */
19119
  { NULL, 0, 0, 0 }
19120
};
19121
 
19122
 
19123
/* Return true if GIVEN is the same as CANONICAL, or if it is CANONICAL
19124
   with a final "000" replaced by "k".  Ignore case.
19125
 
19126
   Note: this function is shared between GCC and GAS.  */
19127
 
19128
static bfd_boolean
19129
mips_strict_matching_cpu_name_p (const char *canonical, const char *given)
19130
{
19131
  while (*given != 0 && TOLOWER (*given) == TOLOWER (*canonical))
19132
    given++, canonical++;
19133
 
19134
  return ((*given == 0 && *canonical == 0)
19135
          || (strcmp (canonical, "000") == 0 && strcasecmp (given, "k") == 0));
19136
}
19137
 
19138
 
19139
/* Return true if GIVEN matches CANONICAL, where GIVEN is a user-supplied
19140
   CPU name.  We've traditionally allowed a lot of variation here.
19141
 
19142
   Note: this function is shared between GCC and GAS.  */
19143
 
19144
static bfd_boolean
19145
mips_matching_cpu_name_p (const char *canonical, const char *given)
19146
{
19147
  /* First see if the name matches exactly, or with a final "000"
19148
     turned into "k".  */
19149
  if (mips_strict_matching_cpu_name_p (canonical, given))
19150
    return TRUE;
19151
 
19152
  /* If not, try comparing based on numerical designation alone.
19153
     See if GIVEN is an unadorned number, or 'r' followed by a number.  */
19154
  if (TOLOWER (*given) == 'r')
19155
    given++;
19156
  if (!ISDIGIT (*given))
19157
    return FALSE;
19158
 
19159
  /* Skip over some well-known prefixes in the canonical name,
19160
     hoping to find a number there too.  */
19161
  if (TOLOWER (canonical[0]) == 'v' && TOLOWER (canonical[1]) == 'r')
19162
    canonical += 2;
19163
  else if (TOLOWER (canonical[0]) == 'r' && TOLOWER (canonical[1]) == 'm')
19164
    canonical += 2;
19165
  else if (TOLOWER (canonical[0]) == 'r')
19166
    canonical += 1;
19167
 
19168
  return mips_strict_matching_cpu_name_p (canonical, given);
19169
}
19170
 
19171
 
19172
/* Parse an option that takes the name of a processor as its argument.
19173
   OPTION is the name of the option and CPU_STRING is the argument.
19174
   Return the corresponding processor enumeration if the CPU_STRING is
19175
   recognized, otherwise report an error and return null.
19176
 
19177
   A similar function exists in GCC.  */
19178
 
19179
static const struct mips_cpu_info *
19180
mips_parse_cpu (const char *option, const char *cpu_string)
19181
{
19182
  const struct mips_cpu_info *p;
19183
 
19184
  /* 'from-abi' selects the most compatible architecture for the given
19185
     ABI: MIPS I for 32-bit ABIs and MIPS III for 64-bit ABIs.  For the
19186
     EABIs, we have to decide whether we're using the 32-bit or 64-bit
19187
     version.  Look first at the -mgp options, if given, otherwise base
19188
     the choice on MIPS_DEFAULT_64BIT.
19189
 
19190
     Treat NO_ABI like the EABIs.  One reason to do this is that the
19191
     plain 'mips' and 'mips64' configs have 'from-abi' as their default
19192
     architecture.  This code picks MIPS I for 'mips' and MIPS III for
19193
     'mips64', just as we did in the days before 'from-abi'.  */
19194
  if (strcasecmp (cpu_string, "from-abi") == 0)
19195
    {
19196
      if (ABI_NEEDS_32BIT_REGS (mips_abi))
19197
        return mips_cpu_info_from_isa (ISA_MIPS1);
19198
 
19199
      if (ABI_NEEDS_64BIT_REGS (mips_abi))
19200
        return mips_cpu_info_from_isa (ISA_MIPS3);
19201
 
19202
      if (file_mips_gp32 >= 0)
19203
        return mips_cpu_info_from_isa (file_mips_gp32 ? ISA_MIPS1 : ISA_MIPS3);
19204
 
19205
      return mips_cpu_info_from_isa (MIPS_DEFAULT_64BIT
19206
                                     ? ISA_MIPS3
19207
                                     : ISA_MIPS1);
19208
    }
19209
 
19210
  /* 'default' has traditionally been a no-op.  Probably not very useful.  */
19211
  if (strcasecmp (cpu_string, "default") == 0)
19212
    return 0;
19213
 
19214
  for (p = mips_cpu_info_table; p->name != 0; p++)
19215
    if (mips_matching_cpu_name_p (p->name, cpu_string))
19216
      return p;
19217
 
19218
  as_bad (_("Bad value (%s) for %s"), cpu_string, option);
19219
  return 0;
19220
}
19221
 
19222
/* Return the canonical processor information for ISA (a member of the
19223
   ISA_MIPS* enumeration).  */
19224
 
19225
static const struct mips_cpu_info *
19226
mips_cpu_info_from_isa (int isa)
19227
{
19228
  int i;
19229
 
19230
  for (i = 0; mips_cpu_info_table[i].name != NULL; i++)
19231
    if ((mips_cpu_info_table[i].flags & MIPS_CPU_IS_ISA)
19232
        && isa == mips_cpu_info_table[i].isa)
19233
      return (&mips_cpu_info_table[i]);
19234
 
19235
  return NULL;
19236
}
19237
 
19238
static const struct mips_cpu_info *
19239
mips_cpu_info_from_arch (int arch)
19240
{
19241
  int i;
19242
 
19243
  for (i = 0; mips_cpu_info_table[i].name != NULL; i++)
19244
    if (arch == mips_cpu_info_table[i].cpu)
19245
      return (&mips_cpu_info_table[i]);
19246
 
19247
  return NULL;
19248
}
19249
 
19250
static void
19251
show (FILE *stream, const char *string, int *col_p, int *first_p)
19252
{
19253
  if (*first_p)
19254
    {
19255
      fprintf (stream, "%24s", "");
19256
      *col_p = 24;
19257
    }
19258
  else
19259
    {
19260
      fprintf (stream, ", ");
19261
      *col_p += 2;
19262
    }
19263
 
19264
  if (*col_p + strlen (string) > 72)
19265
    {
19266
      fprintf (stream, "\n%24s", "");
19267
      *col_p = 24;
19268
    }
19269
 
19270
  fprintf (stream, "%s", string);
19271
  *col_p += strlen (string);
19272
 
19273
  *first_p = 0;
19274
}
19275
 
19276
void
19277
md_show_usage (FILE *stream)
19278
{
19279
  int column, first;
19280
  size_t i;
19281
 
19282
  fprintf (stream, _("\
19283
MIPS options:\n\
19284
-EB                     generate big endian output\n\
19285
-EL                     generate little endian output\n\
19286
-g, -g2                 do not remove unneeded NOPs or swap branches\n\
19287
-G NUM                  allow referencing objects up to NUM bytes\n\
19288
                        implicitly with the gp register [default 8]\n"));
19289
  fprintf (stream, _("\
19290
-mips1                  generate MIPS ISA I instructions\n\
19291
-mips2                  generate MIPS ISA II instructions\n\
19292
-mips3                  generate MIPS ISA III instructions\n\
19293
-mips4                  generate MIPS ISA IV instructions\n\
19294
-mips5                  generate MIPS ISA V instructions\n\
19295
-mips32                 generate MIPS32 ISA instructions\n\
19296
-mips32r2               generate MIPS32 release 2 ISA instructions\n\
19297
-mips64                 generate MIPS64 ISA instructions\n\
19298
-mips64r2               generate MIPS64 release 2 ISA instructions\n\
19299
-march=CPU/-mtune=CPU   generate code/schedule for CPU, where CPU is one of:\n"));
19300
 
19301
  first = 1;
19302
 
19303
  for (i = 0; mips_cpu_info_table[i].name != NULL; i++)
19304
    show (stream, mips_cpu_info_table[i].name, &column, &first);
19305
  show (stream, "from-abi", &column, &first);
19306
  fputc ('\n', stream);
19307
 
19308
  fprintf (stream, _("\
19309
-mCPU                   equivalent to -march=CPU -mtune=CPU. Deprecated.\n\
19310
-no-mCPU                don't generate code specific to CPU.\n\
19311
                        For -mCPU and -no-mCPU, CPU must be one of:\n"));
19312
 
19313
  first = 1;
19314
 
19315
  show (stream, "3900", &column, &first);
19316
  show (stream, "4010", &column, &first);
19317
  show (stream, "4100", &column, &first);
19318
  show (stream, "4650", &column, &first);
19319
  fputc ('\n', stream);
19320
 
19321
  fprintf (stream, _("\
19322
-mips16                 generate mips16 instructions\n\
19323
-no-mips16              do not generate mips16 instructions\n"));
19324
  fprintf (stream, _("\
19325 160 khays
-mmicromips             generate microMIPS instructions\n\
19326
-mno-micromips          do not generate microMIPS instructions\n"));
19327
  fprintf (stream, _("\
19328 16 khays
-msmartmips             generate smartmips instructions\n\
19329
-mno-smartmips          do not generate smartmips instructions\n"));
19330
  fprintf (stream, _("\
19331
-mdsp                   generate DSP instructions\n\
19332
-mno-dsp                do not generate DSP instructions\n"));
19333
  fprintf (stream, _("\
19334
-mdspr2                 generate DSP R2 instructions\n\
19335
-mno-dspr2              do not generate DSP R2 instructions\n"));
19336
  fprintf (stream, _("\
19337
-mmt                    generate MT instructions\n\
19338
-mno-mt                 do not generate MT instructions\n"));
19339
  fprintf (stream, _("\
19340 160 khays
-mmcu                   generate MCU instructions\n\
19341
-mno-mcu                do not generate MCU instructions\n"));
19342
  fprintf (stream, _("\
19343 16 khays
-mfix-loongson2f-jump   work around Loongson2F JUMP instructions\n\
19344
-mfix-loongson2f-nop    work around Loongson2F NOP errata\n\
19345
-mfix-vr4120            work around certain VR4120 errata\n\
19346
-mfix-vr4130            work around VR4130 mflo/mfhi errata\n\
19347
-mfix-24k               insert a nop after ERET and DERET instructions\n\
19348
-mfix-cn63xxp1          work around CN63XXP1 PREF errata\n\
19349
-mgp32                  use 32-bit GPRs, regardless of the chosen ISA\n\
19350
-mfp32                  use 32-bit FPRs, regardless of the chosen ISA\n\
19351
-msym32                 assume all symbols have 32-bit values\n\
19352
-O0                     remove unneeded NOPs, do not swap branches\n\
19353
-O                      remove unneeded NOPs and swap branches\n\
19354
--trap, --no-break      trap exception on div by 0 and mult overflow\n\
19355
--break, --no-trap      break exception on div by 0 and mult overflow\n"));
19356
  fprintf (stream, _("\
19357
-mhard-float            allow floating-point instructions\n\
19358
-msoft-float            do not allow floating-point instructions\n\
19359
-msingle-float          only allow 32-bit floating-point operations\n\
19360
-mdouble-float          allow 32-bit and 64-bit floating-point operations\n\
19361
--[no-]construct-floats [dis]allow floating point values to be constructed\n"
19362
                     ));
19363
#ifdef OBJ_ELF
19364
  fprintf (stream, _("\
19365
-KPIC, -call_shared     generate SVR4 position independent code\n\
19366
-call_nonpic            generate non-PIC code that can operate with DSOs\n\
19367
-mvxworks-pic           generate VxWorks position independent code\n\
19368
-non_shared             do not generate code that can operate with DSOs\n\
19369
-xgot                   assume a 32 bit GOT\n\
19370
-mpdr, -mno-pdr         enable/disable creation of .pdr sections\n\
19371
-mshared, -mno-shared   disable/enable .cpload optimization for\n\
19372
                        position dependent (non shared) code\n\
19373
-mabi=ABI               create ABI conformant object file for:\n"));
19374
 
19375
  first = 1;
19376
 
19377
  show (stream, "32", &column, &first);
19378
  show (stream, "o64", &column, &first);
19379
  show (stream, "n32", &column, &first);
19380
  show (stream, "64", &column, &first);
19381
  show (stream, "eabi", &column, &first);
19382
 
19383
  fputc ('\n', stream);
19384
 
19385
  fprintf (stream, _("\
19386
-32                     create o32 ABI object file (default)\n\
19387
-n32                    create n32 ABI object file\n\
19388
-64                     create 64 ABI object file\n"));
19389
#endif
19390
}
19391
 
19392
#ifdef TE_IRIX
19393
enum dwarf2_format
19394
mips_dwarf2_format (asection *sec ATTRIBUTE_UNUSED)
19395
{
19396
  if (HAVE_64BIT_SYMBOLS)
19397
    return dwarf2_format_64bit_irix;
19398
  else
19399
    return dwarf2_format_32bit;
19400
}
19401
#endif
19402
 
19403
int
19404
mips_dwarf2_addr_size (void)
19405
{
19406
  if (HAVE_64BIT_OBJECTS)
19407
    return 8;
19408
  else
19409
    return 4;
19410
}
19411
 
19412
/* Standard calling conventions leave the CFA at SP on entry.  */
19413
void
19414
mips_cfi_frame_initial_instructions (void)
19415
{
19416
  cfi_add_CFA_def_cfa_register (SP);
19417
}
19418
 
19419
int
19420
tc_mips_regname_to_dw2regnum (char *regname)
19421
{
19422
  unsigned int regnum = -1;
19423
  unsigned int reg;
19424
 
19425
  if (reg_lookup (&regname, RTYPE_GP | RTYPE_NUM, &reg))
19426
    regnum = reg;
19427
 
19428
  return regnum;
19429
}

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