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[/] [openrisc/] [trunk/] [gnu-src/] [binutils-2.20.1/] [gas/] [config/] [tc-ia64.c] - Blame information for rev 413

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/* tc-ia64.c -- Assembler for the HP/Intel IA-64 architecture.
2
   Copyright 1998, 1999, 2000, 2001, 2002, 2003, 2004, 2005, 2006, 2007,
3
   2008, 2009   Free Software Foundation, Inc.
4
   Contributed by David Mosberger-Tang <davidm@hpl.hp.com>
5
 
6
   This file is part of GAS, the GNU Assembler.
7
 
8
   GAS is free software; you can redistribute it and/or modify
9
   it under the terms of the GNU General Public License as published by
10
   the Free Software Foundation; either version 3, or (at your option)
11
   any later version.
12
 
13
   GAS is distributed in the hope that it will be useful,
14
   but WITHOUT ANY WARRANTY; without even the implied warranty of
15
   MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
16
   GNU General Public License for more details.
17
 
18
   You should have received a copy of the GNU General Public License
19
   along with GAS; see the file COPYING.  If not, write to
20
   the Free Software Foundation, 51 Franklin Street - Fifth Floor,
21
   Boston, MA 02110-1301, USA.  */
22
 
23
/*
24
  TODO:
25
 
26
  - optional operands
27
  - directives:
28
        .eb
29
        .estate
30
        .lb
31
        .popsection
32
        .previous
33
        .psr
34
        .pushsection
35
  - labels are wrong if automatic alignment is introduced
36
    (e.g., checkout the second real10 definition in test-data.s)
37
  - DV-related stuff:
38
        <reg>.safe_across_calls and any other DV-related directives I don't
39
          have documentation for.
40
        verify mod-sched-brs reads/writes are checked/marked (and other
41
        notes)
42
 
43
 */
44
 
45
#include "as.h"
46
#include "safe-ctype.h"
47
#include "dwarf2dbg.h"
48
#include "subsegs.h"
49
 
50
#include "opcode/ia64.h"
51
 
52
#include "elf/ia64.h"
53
#include "bfdver.h"
54
#include <time.h>
55
 
56
#ifdef HAVE_LIMITS_H
57
#include <limits.h>
58
#endif
59
 
60
#define NELEMS(a)       ((int) (sizeof (a)/sizeof ((a)[0])))
61
 
62
/* Some systems define MIN in, e.g., param.h.  */
63
#undef MIN
64
#define MIN(a,b)        ((a) < (b) ? (a) : (b))
65
 
66
#define NUM_SLOTS       4
67
#define PREV_SLOT       md.slot[(md.curr_slot + NUM_SLOTS - 1) % NUM_SLOTS]
68
#define CURR_SLOT       md.slot[md.curr_slot]
69
 
70
#define O_pseudo_fixup (O_max + 1)
71
 
72
enum special_section
73
  {
74
    /* IA-64 ABI section pseudo-ops.  */
75
    SPECIAL_SECTION_BSS = 0,
76
    SPECIAL_SECTION_SBSS,
77
    SPECIAL_SECTION_SDATA,
78
    SPECIAL_SECTION_RODATA,
79
    SPECIAL_SECTION_COMMENT,
80
    SPECIAL_SECTION_UNWIND,
81
    SPECIAL_SECTION_UNWIND_INFO,
82
    /* HPUX specific section pseudo-ops.  */
83
    SPECIAL_SECTION_INIT_ARRAY,
84
    SPECIAL_SECTION_FINI_ARRAY,
85
  };
86
 
87
enum reloc_func
88
  {
89
    FUNC_DTP_MODULE,
90
    FUNC_DTP_RELATIVE,
91
    FUNC_FPTR_RELATIVE,
92
    FUNC_GP_RELATIVE,
93
    FUNC_LT_RELATIVE,
94
    FUNC_LT_RELATIVE_X,
95
    FUNC_PC_RELATIVE,
96
    FUNC_PLT_RELATIVE,
97
    FUNC_SEC_RELATIVE,
98
    FUNC_SEG_RELATIVE,
99
    FUNC_TP_RELATIVE,
100
    FUNC_LTV_RELATIVE,
101
    FUNC_LT_FPTR_RELATIVE,
102
    FUNC_LT_DTP_MODULE,
103
    FUNC_LT_DTP_RELATIVE,
104
    FUNC_LT_TP_RELATIVE,
105
    FUNC_IPLT_RELOC,
106
  };
107
 
108
enum reg_symbol
109
  {
110
    REG_GR      = 0,
111
    REG_FR      = (REG_GR + 128),
112
    REG_AR      = (REG_FR + 128),
113
    REG_CR      = (REG_AR + 128),
114
    REG_P       = (REG_CR + 128),
115
    REG_BR      = (REG_P  + 64),
116
    REG_IP      = (REG_BR + 8),
117
    REG_CFM,
118
    REG_PR,
119
    REG_PR_ROT,
120
    REG_PSR,
121
    REG_PSR_L,
122
    REG_PSR_UM,
123
    /* The following are pseudo-registers for use by gas only.  */
124
    IND_CPUID,
125
    IND_DBR,
126
    IND_DTR,
127
    IND_ITR,
128
    IND_IBR,
129
    IND_MSR,
130
    IND_PKR,
131
    IND_PMC,
132
    IND_PMD,
133
    IND_RR,
134
    /* The following pseudo-registers are used for unwind directives only:  */
135
    REG_PSP,
136
    REG_PRIUNAT,
137
    REG_NUM
138
  };
139
 
140
enum dynreg_type
141
  {
142
    DYNREG_GR = 0,       /* dynamic general purpose register */
143
    DYNREG_FR,          /* dynamic floating point register */
144
    DYNREG_PR,          /* dynamic predicate register */
145
    DYNREG_NUM_TYPES
146
  };
147
 
148
enum operand_match_result
149
  {
150
    OPERAND_MATCH,
151
    OPERAND_OUT_OF_RANGE,
152
    OPERAND_MISMATCH
153
  };
154
 
155
/* On the ia64, we can't know the address of a text label until the
156
   instructions are packed into a bundle.  To handle this, we keep
157
   track of the list of labels that appear in front of each
158
   instruction.  */
159
struct label_fix
160
{
161
  struct label_fix *next;
162
  struct symbol *sym;
163
  bfd_boolean dw2_mark_labels;
164
};
165
 
166
/* This is the endianness of the current section.  */
167
extern int target_big_endian;
168
 
169
/* This is the default endianness.  */
170
static int default_big_endian = TARGET_BYTES_BIG_ENDIAN;
171
 
172
void (*ia64_number_to_chars) (char *, valueT, int);
173
 
174
static void ia64_float_to_chars_bigendian (char *, LITTLENUM_TYPE *, int);
175
static void ia64_float_to_chars_littleendian (char *, LITTLENUM_TYPE *, int);
176
 
177
static void (*ia64_float_to_chars) (char *, LITTLENUM_TYPE *, int);
178
 
179
static struct hash_control *alias_hash;
180
static struct hash_control *alias_name_hash;
181
static struct hash_control *secalias_hash;
182
static struct hash_control *secalias_name_hash;
183
 
184
/* List of chars besides those in app.c:symbol_chars that can start an
185
   operand.  Used to prevent the scrubber eating vital white-space.  */
186
const char ia64_symbol_chars[] = "@?";
187
 
188
/* Characters which always start a comment.  */
189
const char comment_chars[] = "";
190
 
191
/* Characters which start a comment at the beginning of a line.  */
192
const char line_comment_chars[] = "#";
193
 
194
/* Characters which may be used to separate multiple commands on a
195
   single line.  */
196
const char line_separator_chars[] = ";{}";
197
 
198
/* Characters which are used to indicate an exponent in a floating
199
   point number.  */
200
const char EXP_CHARS[] = "eE";
201
 
202
/* Characters which mean that a number is a floating point constant,
203
   as in 0d1.0.  */
204
const char FLT_CHARS[] = "rRsSfFdDxXpP";
205
 
206
/* ia64-specific option processing:  */
207
 
208
const char *md_shortopts = "m:N:x::";
209
 
210
struct option md_longopts[] =
211
  {
212
#define OPTION_MCONSTANT_GP (OPTION_MD_BASE + 1)
213
    {"mconstant-gp", no_argument, NULL, OPTION_MCONSTANT_GP},
214
#define OPTION_MAUTO_PIC (OPTION_MD_BASE + 2)
215
    {"mauto-pic", no_argument, NULL, OPTION_MAUTO_PIC}
216
  };
217
 
218
size_t md_longopts_size = sizeof (md_longopts);
219
 
220
static struct
221
  {
222
    struct hash_control *pseudo_hash;   /* pseudo opcode hash table */
223
    struct hash_control *reg_hash;      /* register name hash table */
224
    struct hash_control *dynreg_hash;   /* dynamic register hash table */
225
    struct hash_control *const_hash;    /* constant hash table */
226
    struct hash_control *entry_hash;    /* code entry hint hash table */
227
 
228
    /* If X_op is != O_absent, the registername for the instruction's
229
       qualifying predicate.  If NULL, p0 is assumed for instructions
230
       that are predictable.  */
231
    expressionS qp;
232
 
233
    /* Optimize for which CPU.  */
234
    enum
235
      {
236
        itanium1,
237
        itanium2
238
      } tune;
239
 
240
    /* What to do when hint.b is used.  */
241
    enum
242
      {
243
        hint_b_error,
244
        hint_b_warning,
245
        hint_b_ok
246
      } hint_b;
247
 
248
    unsigned int
249
      manual_bundling : 1,
250
      debug_dv: 1,
251
      detect_dv: 1,
252
      explicit_mode : 1,            /* which mode we're in */
253
      default_explicit_mode : 1,    /* which mode is the default */
254
      mode_explicitly_set : 1,      /* was the current mode explicitly set? */
255
      auto_align : 1,
256
      keep_pending_output : 1;
257
 
258
    /* What to do when something is wrong with unwind directives.  */
259
    enum
260
      {
261
        unwind_check_warning,
262
        unwind_check_error
263
      } unwind_check;
264
 
265
    /* Each bundle consists of up to three instructions.  We keep
266
       track of four most recent instructions so we can correctly set
267
       the end_of_insn_group for the last instruction in a bundle.  */
268
    int curr_slot;
269
    int num_slots_in_use;
270
    struct slot
271
      {
272
        unsigned int
273
          end_of_insn_group : 1,
274
          manual_bundling_on : 1,
275
          manual_bundling_off : 1,
276
          loc_directive_seen : 1;
277
        signed char user_template;      /* user-selected template, if any */
278
        unsigned char qp_regno;         /* qualifying predicate */
279
        /* This duplicates a good fraction of "struct fix" but we
280
           can't use a "struct fix" instead since we can't call
281
           fix_new_exp() until we know the address of the instruction.  */
282
        int num_fixups;
283
        struct insn_fix
284
          {
285
            bfd_reloc_code_real_type code;
286
            enum ia64_opnd opnd;        /* type of operand in need of fix */
287
            unsigned int is_pcrel : 1;  /* is operand pc-relative? */
288
            expressionS expr;           /* the value to be inserted */
289
          }
290
        fixup[2];                       /* at most two fixups per insn */
291
        struct ia64_opcode *idesc;
292
        struct label_fix *label_fixups;
293
        struct label_fix *tag_fixups;
294
        struct unw_rec_list *unwind_record;     /* Unwind directive.  */
295
        expressionS opnd[6];
296
        char *src_file;
297
        unsigned int src_line;
298
        struct dwarf2_line_info debug_line;
299
      }
300
    slot[NUM_SLOTS];
301
 
302
    segT last_text_seg;
303
 
304
    struct dynreg
305
      {
306
        struct dynreg *next;            /* next dynamic register */
307
        const char *name;
308
        unsigned short base;            /* the base register number */
309
        unsigned short num_regs;        /* # of registers in this set */
310
      }
311
    *dynreg[DYNREG_NUM_TYPES], in, loc, out, rot;
312
 
313
    flagword flags;                     /* ELF-header flags */
314
 
315
    struct mem_offset {
316
      unsigned hint:1;              /* is this hint currently valid? */
317
      bfd_vma offset;               /* mem.offset offset */
318
      bfd_vma base;                 /* mem.offset base */
319
    } mem_offset;
320
 
321
    int path;                       /* number of alt. entry points seen */
322
    const char **entry_labels;      /* labels of all alternate paths in
323
                                       the current DV-checking block.  */
324
    int maxpaths;                   /* size currently allocated for
325
                                       entry_labels */
326
 
327
    int pointer_size;       /* size in bytes of a pointer */
328
    int pointer_size_shift; /* shift size of a pointer for alignment */
329
 
330
    symbolS *indregsym[IND_RR - IND_CPUID + 1];
331
  }
332
md;
333
 
334
/* These are not const, because they are modified to MMI for non-itanium1
335
   targets below.  */
336
/* MFI bundle of nops.  */
337
static unsigned char le_nop[16] =
338
{
339
  0x0c, 0x00, 0x00, 0x00, 0x01, 0x00, 0x00, 0x00,
340
  0x00, 0x02, 0x00, 0x00, 0x00, 0x00, 0x04, 0x00
341
};
342
/* MFI bundle of nops with stop-bit.  */
343
static unsigned char le_nop_stop[16] =
344
{
345
  0x0d, 0x00, 0x00, 0x00, 0x01, 0x00, 0x00, 0x00,
346
  0x00, 0x02, 0x00, 0x00, 0x00, 0x00, 0x04, 0x00
347
};
348
 
349
/* application registers:  */
350
 
351
#define AR_K0           0
352
#define AR_K7           7
353
#define AR_RSC          16
354
#define AR_BSP          17
355
#define AR_BSPSTORE     18
356
#define AR_RNAT         19
357
#define AR_FCR          21
358
#define AR_EFLAG        24
359
#define AR_CSD          25
360
#define AR_SSD          26
361
#define AR_CFLG         27
362
#define AR_FSR          28
363
#define AR_FIR          29
364
#define AR_FDR          30
365
#define AR_CCV          32
366
#define AR_UNAT         36
367
#define AR_FPSR         40
368
#define AR_ITC          44
369
#define AR_RUC          45
370
#define AR_PFS          64
371
#define AR_LC           65
372
#define AR_EC           66
373
 
374
static const struct
375
  {
376
    const char *name;
377
    unsigned int regnum;
378
  }
379
ar[] =
380
  {
381
    {"ar.k0",           AR_K0},         {"ar.k1",       AR_K0 + 1},
382
    {"ar.k2",           AR_K0 + 2},     {"ar.k3",       AR_K0 + 3},
383
    {"ar.k4",           AR_K0 + 4},     {"ar.k5",       AR_K0 + 5},
384
    {"ar.k6",           AR_K0 + 6},     {"ar.k7",       AR_K7},
385
    {"ar.rsc",          AR_RSC},        {"ar.bsp",      AR_BSP},
386
    {"ar.bspstore",     AR_BSPSTORE},   {"ar.rnat",     AR_RNAT},
387
    {"ar.fcr",          AR_FCR},        {"ar.eflag",    AR_EFLAG},
388
    {"ar.csd",          AR_CSD},        {"ar.ssd",      AR_SSD},
389
    {"ar.cflg",         AR_CFLG},       {"ar.fsr",      AR_FSR},
390
    {"ar.fir",          AR_FIR},        {"ar.fdr",      AR_FDR},
391
    {"ar.ccv",          AR_CCV},        {"ar.unat",     AR_UNAT},
392
    {"ar.fpsr",         AR_FPSR},       {"ar.itc",      AR_ITC},
393
    {"ar.ruc",          AR_RUC},        {"ar.pfs",      AR_PFS},
394
    {"ar.lc",           AR_LC},         {"ar.ec",       AR_EC},
395
  };
396
 
397
/* control registers:  */
398
 
399
#define CR_DCR           0
400
#define CR_ITM           1
401
#define CR_IVA           2
402
#define CR_PTA           8
403
#define CR_GPTA          9
404
#define CR_IPSR         16
405
#define CR_ISR          17
406
#define CR_IIP          19
407
#define CR_IFA          20
408
#define CR_ITIR         21
409
#define CR_IIPA         22
410
#define CR_IFS          23
411
#define CR_IIM          24
412
#define CR_IHA          25
413
#define CR_IIB0         26
414
#define CR_IIB1         27
415
#define CR_LID          64
416
#define CR_IVR          65
417
#define CR_TPR          66
418
#define CR_EOI          67
419
#define CR_IRR0         68
420
#define CR_IRR3         71
421
#define CR_ITV          72
422
#define CR_PMV          73
423
#define CR_CMCV         74
424
#define CR_LRR0         80
425
#define CR_LRR1         81
426
 
427
static const struct
428
  {
429
    const char *name;
430
    unsigned int regnum;
431
  }
432
cr[] =
433
  {
434
    {"cr.dcr",  CR_DCR},
435
    {"cr.itm",  CR_ITM},
436
    {"cr.iva",  CR_IVA},
437
    {"cr.pta",  CR_PTA},
438
    {"cr.gpta", CR_GPTA},
439
    {"cr.ipsr", CR_IPSR},
440
    {"cr.isr",  CR_ISR},
441
    {"cr.iip",  CR_IIP},
442
    {"cr.ifa",  CR_IFA},
443
    {"cr.itir", CR_ITIR},
444
    {"cr.iipa", CR_IIPA},
445
    {"cr.ifs",  CR_IFS},
446
    {"cr.iim",  CR_IIM},
447
    {"cr.iha",  CR_IHA},
448
    {"cr.iib0", CR_IIB0},
449
    {"cr.iib1", CR_IIB1},
450
    {"cr.lid",  CR_LID},
451
    {"cr.ivr",  CR_IVR},
452
    {"cr.tpr",  CR_TPR},
453
    {"cr.eoi",  CR_EOI},
454
    {"cr.irr0", CR_IRR0},
455
    {"cr.irr1", CR_IRR0 + 1},
456
    {"cr.irr2", CR_IRR0 + 2},
457
    {"cr.irr3", CR_IRR3},
458
    {"cr.itv",  CR_ITV},
459
    {"cr.pmv",  CR_PMV},
460
    {"cr.cmcv", CR_CMCV},
461
    {"cr.lrr0", CR_LRR0},
462
    {"cr.lrr1", CR_LRR1}
463
  };
464
 
465
#define PSR_MFL         4
466
#define PSR_IC          13
467
#define PSR_DFL         18
468
#define PSR_CPL         32
469
 
470
static const struct const_desc
471
  {
472
    const char *name;
473
    valueT value;
474
  }
475
const_bits[] =
476
  {
477
    /* PSR constant masks:  */
478
 
479
    /* 0: reserved */
480
    {"psr.be",  ((valueT) 1) << 1},
481
    {"psr.up",  ((valueT) 1) << 2},
482
    {"psr.ac",  ((valueT) 1) << 3},
483
    {"psr.mfl", ((valueT) 1) << 4},
484
    {"psr.mfh", ((valueT) 1) << 5},
485
    /* 6-12: reserved */
486
    {"psr.ic",  ((valueT) 1) << 13},
487
    {"psr.i",   ((valueT) 1) << 14},
488
    {"psr.pk",  ((valueT) 1) << 15},
489
    /* 16: reserved */
490
    {"psr.dt",  ((valueT) 1) << 17},
491
    {"psr.dfl", ((valueT) 1) << 18},
492
    {"psr.dfh", ((valueT) 1) << 19},
493
    {"psr.sp",  ((valueT) 1) << 20},
494
    {"psr.pp",  ((valueT) 1) << 21},
495
    {"psr.di",  ((valueT) 1) << 22},
496
    {"psr.si",  ((valueT) 1) << 23},
497
    {"psr.db",  ((valueT) 1) << 24},
498
    {"psr.lp",  ((valueT) 1) << 25},
499
    {"psr.tb",  ((valueT) 1) << 26},
500
    {"psr.rt",  ((valueT) 1) << 27},
501
    /* 28-31: reserved */
502
    /* 32-33: cpl (current privilege level) */
503
    {"psr.is",  ((valueT) 1) << 34},
504
    {"psr.mc",  ((valueT) 1) << 35},
505
    {"psr.it",  ((valueT) 1) << 36},
506
    {"psr.id",  ((valueT) 1) << 37},
507
    {"psr.da",  ((valueT) 1) << 38},
508
    {"psr.dd",  ((valueT) 1) << 39},
509
    {"psr.ss",  ((valueT) 1) << 40},
510
    /* 41-42: ri (restart instruction) */
511
    {"psr.ed",  ((valueT) 1) << 43},
512
    {"psr.bn",  ((valueT) 1) << 44},
513
  };
514
 
515
/* indirect register-sets/memory:  */
516
 
517
static const struct
518
  {
519
    const char *name;
520
    unsigned int regnum;
521
  }
522
indirect_reg[] =
523
  {
524
    { "CPUID",  IND_CPUID },
525
    { "cpuid",  IND_CPUID },
526
    { "dbr",    IND_DBR },
527
    { "dtr",    IND_DTR },
528
    { "itr",    IND_ITR },
529
    { "ibr",    IND_IBR },
530
    { "msr",    IND_MSR },
531
    { "pkr",    IND_PKR },
532
    { "pmc",    IND_PMC },
533
    { "pmd",    IND_PMD },
534
    { "rr",     IND_RR },
535
  };
536
 
537
/* Pseudo functions used to indicate relocation types (these functions
538
   start with an at sign (@).  */
539
static struct
540
  {
541
    const char *name;
542
    enum pseudo_type
543
      {
544
        PSEUDO_FUNC_NONE,
545
        PSEUDO_FUNC_RELOC,
546
        PSEUDO_FUNC_CONST,
547
        PSEUDO_FUNC_REG,
548
        PSEUDO_FUNC_FLOAT
549
      }
550
    type;
551
    union
552
      {
553
        unsigned long ival;
554
        symbolS *sym;
555
      }
556
    u;
557
  }
558
pseudo_func[] =
559
  {
560
    /* reloc pseudo functions (these must come first!):  */
561
    { "dtpmod", PSEUDO_FUNC_RELOC, { 0 } },
562
    { "dtprel", PSEUDO_FUNC_RELOC, { 0 } },
563
    { "fptr",   PSEUDO_FUNC_RELOC, { 0 } },
564
    { "gprel",  PSEUDO_FUNC_RELOC, { 0 } },
565
    { "ltoff",  PSEUDO_FUNC_RELOC, { 0 } },
566
    { "ltoffx", PSEUDO_FUNC_RELOC, { 0 } },
567
    { "pcrel",  PSEUDO_FUNC_RELOC, { 0 } },
568
    { "pltoff", PSEUDO_FUNC_RELOC, { 0 } },
569
    { "secrel", PSEUDO_FUNC_RELOC, { 0 } },
570
    { "segrel", PSEUDO_FUNC_RELOC, { 0 } },
571
    { "tprel",  PSEUDO_FUNC_RELOC, { 0 } },
572
    { "ltv",    PSEUDO_FUNC_RELOC, { 0 } },
573
    { NULL, 0, { 0 } },   /* placeholder for FUNC_LT_FPTR_RELATIVE */
574
    { NULL, 0, { 0 } },   /* placeholder for FUNC_LT_DTP_MODULE */
575
    { NULL, 0, { 0 } },   /* placeholder for FUNC_LT_DTP_RELATIVE */
576
    { NULL, 0, { 0 } },   /* placeholder for FUNC_LT_TP_RELATIVE */
577
    { "iplt",   PSEUDO_FUNC_RELOC, { 0 } },
578
 
579
    /* mbtype4 constants:  */
580
    { "alt",    PSEUDO_FUNC_CONST, { 0xa } },
581
    { "brcst",  PSEUDO_FUNC_CONST, { 0x0 } },
582
    { "mix",    PSEUDO_FUNC_CONST, { 0x8 } },
583
    { "rev",    PSEUDO_FUNC_CONST, { 0xb } },
584
    { "shuf",   PSEUDO_FUNC_CONST, { 0x9 } },
585
 
586
    /* fclass constants:  */
587
    { "nat",    PSEUDO_FUNC_CONST, { 0x100 } },
588
    { "qnan",   PSEUDO_FUNC_CONST, { 0x080 } },
589
    { "snan",   PSEUDO_FUNC_CONST, { 0x040 } },
590
    { "pos",    PSEUDO_FUNC_CONST, { 0x001 } },
591
    { "neg",    PSEUDO_FUNC_CONST, { 0x002 } },
592
    { "zero",   PSEUDO_FUNC_CONST, { 0x004 } },
593
    { "unorm",  PSEUDO_FUNC_CONST, { 0x008 } },
594
    { "norm",   PSEUDO_FUNC_CONST, { 0x010 } },
595
    { "inf",    PSEUDO_FUNC_CONST, { 0x020 } },
596
 
597
    { "natval", PSEUDO_FUNC_CONST, { 0x100 } }, /* old usage */
598
 
599
    /* hint constants: */
600
    { "pause",  PSEUDO_FUNC_CONST, { 0x0 } },
601
 
602
    /* unwind-related constants:  */
603
    { "svr4",   PSEUDO_FUNC_CONST,      { ELFOSABI_NONE } },
604
    { "hpux",   PSEUDO_FUNC_CONST,      { ELFOSABI_HPUX } },
605
    { "nt",     PSEUDO_FUNC_CONST,      { 2 } },                /* conflicts w/ELFOSABI_NETBSD */
606
    { "linux",  PSEUDO_FUNC_CONST,      { ELFOSABI_LINUX } },
607
    { "freebsd", PSEUDO_FUNC_CONST,     { ELFOSABI_FREEBSD } },
608
    { "openvms", PSEUDO_FUNC_CONST,     { ELFOSABI_OPENVMS } },
609
    { "nsk",    PSEUDO_FUNC_CONST,      { ELFOSABI_NSK } },
610
 
611
    /* unwind-related registers:  */
612
    { "priunat",PSEUDO_FUNC_REG, { REG_PRIUNAT } }
613
  };
614
 
615
/* 41-bit nop opcodes (one per unit):  */
616
static const bfd_vma nop[IA64_NUM_UNITS] =
617
  {
618
    0x0000000000LL,     /* NIL => break 0 */
619
    0x0008000000LL,     /* I-unit nop */
620
    0x0008000000LL,     /* M-unit nop */
621
    0x4000000000LL,     /* B-unit nop */
622
    0x0008000000LL,     /* F-unit nop */
623
    0x0000000000LL,     /* L-"unit" nop immediate */
624
    0x0008000000LL,     /* X-unit nop */
625
  };
626
 
627
/* Can't be `const' as it's passed to input routines (which have the
628
   habit of setting temporary sentinels.  */
629
static char special_section_name[][20] =
630
  {
631
    {".bss"}, {".sbss"}, {".sdata"}, {".rodata"}, {".comment"},
632
    {".IA_64.unwind"}, {".IA_64.unwind_info"},
633
    {".init_array"}, {".fini_array"}
634
  };
635
 
636
/* The best template for a particular sequence of up to three
637
   instructions:  */
638
#define N       IA64_NUM_TYPES
639
static unsigned char best_template[N][N][N];
640
#undef N
641
 
642
/* Resource dependencies currently in effect */
643
static struct rsrc {
644
  int depind;                       /* dependency index */
645
  const struct ia64_dependency *dependency; /* actual dependency */
646
  unsigned specific:1,              /* is this a specific bit/regno? */
647
    link_to_qp_branch:1;           /* will a branch on the same QP clear it?*/
648
  int index;                        /* specific regno/bit within dependency */
649
  int note;                         /* optional qualifying note (0 if none) */
650
#define STATE_NONE 0
651
#define STATE_STOP 1
652
#define STATE_SRLZ 2
653
  int insn_srlz;                    /* current insn serialization state */
654
  int data_srlz;                    /* current data serialization state */
655
  int qp_regno;                     /* qualifying predicate for this usage */
656
  char *file;                       /* what file marked this dependency */
657
  unsigned int line;                /* what line marked this dependency */
658
  struct mem_offset mem_offset;     /* optional memory offset hint */
659
  enum { CMP_NONE, CMP_OR, CMP_AND } cmp_type; /* OR or AND compare? */
660
  int path;                         /* corresponding code entry index */
661
} *regdeps = NULL;
662
static int regdepslen = 0;
663
static int regdepstotlen = 0;
664
static const char *dv_mode[] = { "RAW", "WAW", "WAR" };
665
static const char *dv_sem[] = { "none", "implied", "impliedf",
666
                                "data", "instr", "specific", "stop", "other" };
667
static const char *dv_cmp_type[] = { "none", "OR", "AND" };
668
 
669
/* Current state of PR mutexation */
670
static struct qpmutex {
671
  valueT prmask;
672
  int path;
673
} *qp_mutexes = NULL;          /* QP mutex bitmasks */
674
static int qp_mutexeslen = 0;
675
static int qp_mutexestotlen = 0;
676
static valueT qp_safe_across_calls = 0;
677
 
678
/* Current state of PR implications */
679
static struct qp_imply {
680
  unsigned p1:6;
681
  unsigned p2:6;
682
  unsigned p2_branched:1;
683
  int path;
684
} *qp_implies = NULL;
685
static int qp_implieslen = 0;
686
static int qp_impliestotlen = 0;
687
 
688
/* Keep track of static GR values so that indirect register usage can
689
   sometimes be tracked.  */
690
static struct gr {
691
  unsigned known:1;
692
  int path;
693
  valueT value;
694
} gr_values[128] = {
695
  {
696
    1,
697
#ifdef INT_MAX
698
    INT_MAX,
699
#else
700
    (((1 << (8 * sizeof(gr_values->path) - 2)) - 1) << 1) + 1,
701
#endif
702
 
703
  }
704
};
705
 
706
/* Remember the alignment frag.  */
707
static fragS *align_frag;
708
 
709
/* These are the routines required to output the various types of
710
   unwind records.  */
711
 
712
/* A slot_number is a frag address plus the slot index (0-2).  We use the
713
   frag address here so that if there is a section switch in the middle of
714
   a function, then instructions emitted to a different section are not
715
   counted.  Since there may be more than one frag for a function, this
716
   means we also need to keep track of which frag this address belongs to
717
   so we can compute inter-frag distances.  This also nicely solves the
718
   problem with nops emitted for align directives, which can't easily be
719
   counted, but can easily be derived from frag sizes.  */
720
 
721
typedef struct unw_rec_list {
722
  unwind_record r;
723
  unsigned long slot_number;
724
  fragS *slot_frag;
725
  struct unw_rec_list *next;
726
} unw_rec_list;
727
 
728
#define SLOT_NUM_NOT_SET        (unsigned)-1
729
 
730
/* Linked list of saved prologue counts.  A very poor
731
   implementation of a map from label numbers to prologue counts.  */
732
typedef struct label_prologue_count
733
{
734
  struct label_prologue_count *next;
735
  unsigned long label_number;
736
  unsigned int prologue_count;
737
} label_prologue_count;
738
 
739
typedef struct proc_pending
740
{
741
  symbolS *sym;
742
  struct proc_pending *next;
743
} proc_pending;
744
 
745
static struct
746
{
747
  /* Maintain a list of unwind entries for the current function.  */
748
  unw_rec_list *list;
749
  unw_rec_list *tail;
750
 
751
  /* Any unwind entries that should be attached to the current slot
752
     that an insn is being constructed for.  */
753
  unw_rec_list *current_entry;
754
 
755
  /* These are used to create the unwind table entry for this function.  */
756
  proc_pending proc_pending;
757
  symbolS *info;                /* pointer to unwind info */
758
  symbolS *personality_routine;
759
  segT saved_text_seg;
760
  subsegT saved_text_subseg;
761
  unsigned int force_unwind_entry : 1;  /* force generation of unwind entry? */
762
 
763
  /* TRUE if processing unwind directives in a prologue region.  */
764
  unsigned int prologue : 1;
765
  unsigned int prologue_mask : 4;
766
  unsigned int prologue_gr : 7;
767
  unsigned int body : 1;
768
  unsigned int insn : 1;
769
  unsigned int prologue_count;  /* number of .prologues seen so far */
770
  /* Prologue counts at previous .label_state directives.  */
771
  struct label_prologue_count * saved_prologue_counts;
772
 
773
  /* List of split up .save-s.  */
774
  unw_p_record *pending_saves;
775
} unwind;
776
 
777
/* The input value is a negated offset from psp, and specifies an address
778
   psp - offset.  The encoded value is psp + 16 - (4 * offset).  Thus we
779
   must add 16 and divide by 4 to get the encoded value.  */
780
 
781
#define ENCODED_PSP_OFFSET(OFFSET) (((OFFSET) + 16) / 4)
782
 
783
typedef void (*vbyte_func) (int, char *, char *);
784
 
785
/* Forward declarations:  */
786
static void dot_alias (int);
787
static int parse_operand_and_eval (expressionS *, int);
788
static void emit_one_bundle (void);
789
static bfd_reloc_code_real_type ia64_gen_real_reloc_type (struct symbol *,
790
                                                          bfd_reloc_code_real_type);
791
static void insn_group_break (int, int, int);
792
static void add_qp_mutex (valueT);
793
static void add_qp_imply (int, int);
794
static void clear_qp_mutex (valueT);
795
static void clear_qp_implies (valueT, valueT);
796
static void print_dependency (const char *, int);
797
static void instruction_serialization (void);
798
static void data_serialization (void);
799
static void output_R3_format (vbyte_func, unw_record_type, unsigned long);
800
static void output_B3_format (vbyte_func, unsigned long, unsigned long);
801
static void output_B4_format (vbyte_func, unw_record_type, unsigned long);
802
static void free_saved_prologue_counts (void);
803
 
804
/* Determine if application register REGNUM resides only in the integer
805
   unit (as opposed to the memory unit).  */
806
static int
807
ar_is_only_in_integer_unit (int reg)
808
{
809
  reg -= REG_AR;
810
  return reg >= 64 && reg <= 111;
811
}
812
 
813
/* Determine if application register REGNUM resides only in the memory
814
   unit (as opposed to the integer unit).  */
815
static int
816
ar_is_only_in_memory_unit (int reg)
817
{
818
  reg -= REG_AR;
819
  return reg >= 0 && reg <= 47;
820
}
821
 
822
/* Switch to section NAME and create section if necessary.  It's
823
   rather ugly that we have to manipulate input_line_pointer but I
824
   don't see any other way to accomplish the same thing without
825
   changing obj-elf.c (which may be the Right Thing, in the end).  */
826
static void
827
set_section (char *name)
828
{
829
  char *saved_input_line_pointer;
830
 
831
  saved_input_line_pointer = input_line_pointer;
832
  input_line_pointer = name;
833
  obj_elf_section (0);
834
  input_line_pointer = saved_input_line_pointer;
835
}
836
 
837
/* Map 's' to SHF_IA_64_SHORT.  */
838
 
839
bfd_vma
840
ia64_elf_section_letter (int letter, char **ptr_msg)
841
{
842
  if (letter == 's')
843
    return SHF_IA_64_SHORT;
844
  else if (letter == 'o')
845
    return SHF_LINK_ORDER;
846
#ifdef TE_VMS
847
  else if (letter == 'O')
848
    return SHF_IA_64_VMS_OVERLAID;
849
  else if (letter == 'g')
850
    return SHF_IA_64_VMS_GLOBAL;
851
#endif
852
 
853
  *ptr_msg = _("Bad .section directive: want a,o,s,w,x,M,S,G,T in string");
854
  return -1;
855
}
856
 
857
/* Map SHF_IA_64_SHORT to SEC_SMALL_DATA.  */
858
 
859
flagword
860
ia64_elf_section_flags (flagword flags,
861
                        bfd_vma attr,
862
                        int type ATTRIBUTE_UNUSED)
863
{
864
  if (attr & SHF_IA_64_SHORT)
865
    flags |= SEC_SMALL_DATA;
866
  return flags;
867
}
868
 
869
int
870
ia64_elf_section_type (const char *str, size_t len)
871
{
872
#define STREQ(s) ((len == sizeof (s) - 1) && (strncmp (str, s, sizeof (s) - 1) == 0))
873
 
874
  if (STREQ (ELF_STRING_ia64_unwind_info))
875
    return SHT_PROGBITS;
876
 
877
  if (STREQ (ELF_STRING_ia64_unwind_info_once))
878
    return SHT_PROGBITS;
879
 
880
  if (STREQ (ELF_STRING_ia64_unwind))
881
    return SHT_IA_64_UNWIND;
882
 
883
  if (STREQ (ELF_STRING_ia64_unwind_once))
884
    return SHT_IA_64_UNWIND;
885
 
886
  if (STREQ ("unwind"))
887
    return SHT_IA_64_UNWIND;
888
 
889
  return -1;
890
#undef STREQ
891
}
892
 
893
static unsigned int
894
set_regstack (unsigned int ins,
895
              unsigned int locs,
896
              unsigned int outs,
897
              unsigned int rots)
898
{
899
  /* Size of frame.  */
900
  unsigned int sof;
901
 
902
  sof = ins + locs + outs;
903
  if (sof > 96)
904
    {
905
      as_bad (_("Size of frame exceeds maximum of 96 registers"));
906
      return 0;
907
    }
908
  if (rots > sof)
909
    {
910
      as_warn (_("Size of rotating registers exceeds frame size"));
911
      return 0;
912
    }
913
  md.in.base = REG_GR + 32;
914
  md.loc.base = md.in.base + ins;
915
  md.out.base = md.loc.base + locs;
916
 
917
  md.in.num_regs  = ins;
918
  md.loc.num_regs = locs;
919
  md.out.num_regs = outs;
920
  md.rot.num_regs = rots;
921
  return sof;
922
}
923
 
924
void
925
ia64_flush_insns (void)
926
{
927
  struct label_fix *lfix;
928
  segT saved_seg;
929
  subsegT saved_subseg;
930
  unw_rec_list *ptr;
931
  bfd_boolean mark;
932
 
933
  if (!md.last_text_seg)
934
    return;
935
 
936
  saved_seg = now_seg;
937
  saved_subseg = now_subseg;
938
 
939
  subseg_set (md.last_text_seg, 0);
940
 
941
  while (md.num_slots_in_use > 0)
942
    emit_one_bundle ();         /* force out queued instructions */
943
 
944
  /* In case there are labels following the last instruction, resolve
945
     those now.  */
946
  mark = FALSE;
947
  for (lfix = CURR_SLOT.label_fixups; lfix; lfix = lfix->next)
948
    {
949
      symbol_set_value_now (lfix->sym);
950
      mark |= lfix->dw2_mark_labels;
951
    }
952
  if (mark)
953
    {
954
      dwarf2_where (&CURR_SLOT.debug_line);
955
      CURR_SLOT.debug_line.flags |= DWARF2_FLAG_BASIC_BLOCK;
956
      dwarf2_gen_line_info (frag_now_fix (), &CURR_SLOT.debug_line);
957
      dwarf2_consume_line_info ();
958
    }
959
  CURR_SLOT.label_fixups = 0;
960
 
961
  for (lfix = CURR_SLOT.tag_fixups; lfix; lfix = lfix->next)
962
    symbol_set_value_now (lfix->sym);
963
  CURR_SLOT.tag_fixups = 0;
964
 
965
  /* In case there are unwind directives following the last instruction,
966
     resolve those now.  We only handle prologue, body, and endp directives
967
     here.  Give an error for others.  */
968
  for (ptr = unwind.current_entry; ptr; ptr = ptr->next)
969
    {
970
      switch (ptr->r.type)
971
        {
972
        case prologue:
973
        case prologue_gr:
974
        case body:
975
        case endp:
976
          ptr->slot_number = (unsigned long) frag_more (0);
977
          ptr->slot_frag = frag_now;
978
          break;
979
 
980
          /* Allow any record which doesn't have a "t" field (i.e.,
981
             doesn't relate to a particular instruction).  */
982
        case unwabi:
983
        case br_gr:
984
        case copy_state:
985
        case fr_mem:
986
        case frgr_mem:
987
        case gr_gr:
988
        case gr_mem:
989
        case label_state:
990
        case rp_br:
991
        case spill_base:
992
        case spill_mask:
993
          /* nothing */
994
          break;
995
 
996
        default:
997
          as_bad (_("Unwind directive not followed by an instruction."));
998
          break;
999
        }
1000
    }
1001
  unwind.current_entry = NULL;
1002
 
1003
  subseg_set (saved_seg, saved_subseg);
1004
 
1005
  if (md.qp.X_op == O_register)
1006
    as_bad (_("qualifying predicate not followed by instruction"));
1007
}
1008
 
1009
static void
1010
ia64_do_align (int nbytes)
1011
{
1012
  char *saved_input_line_pointer = input_line_pointer;
1013
 
1014
  input_line_pointer = "";
1015
  s_align_bytes (nbytes);
1016
  input_line_pointer = saved_input_line_pointer;
1017
}
1018
 
1019
void
1020
ia64_cons_align (int nbytes)
1021
{
1022
  if (md.auto_align)
1023
    {
1024
      char *saved_input_line_pointer = input_line_pointer;
1025
      input_line_pointer = "";
1026
      s_align_bytes (nbytes);
1027
      input_line_pointer = saved_input_line_pointer;
1028
    }
1029
}
1030
 
1031
/* Output COUNT bytes to a memory location.  */
1032
static char *vbyte_mem_ptr = NULL;
1033
 
1034
static void
1035
output_vbyte_mem (int count, char *ptr, char *comment ATTRIBUTE_UNUSED)
1036
{
1037
  int x;
1038
  if (vbyte_mem_ptr == NULL)
1039
    abort ();
1040
 
1041
  if (count == 0)
1042
    return;
1043
  for (x = 0; x < count; x++)
1044
    *(vbyte_mem_ptr++) = ptr[x];
1045
}
1046
 
1047
/* Count the number of bytes required for records.  */
1048
static int vbyte_count = 0;
1049
static void
1050
count_output (int count,
1051
              char *ptr ATTRIBUTE_UNUSED,
1052
              char *comment ATTRIBUTE_UNUSED)
1053
{
1054
  vbyte_count += count;
1055
}
1056
 
1057
static void
1058
output_R1_format (vbyte_func f, unw_record_type rtype, int rlen)
1059
{
1060
  int r = 0;
1061
  char byte;
1062
  if (rlen > 0x1f)
1063
    {
1064
      output_R3_format (f, rtype, rlen);
1065
      return;
1066
    }
1067
 
1068
  if (rtype == body)
1069
    r = 1;
1070
  else if (rtype != prologue)
1071
    as_bad (_("record type is not valid"));
1072
 
1073
  byte = UNW_R1 | (r << 5) | (rlen & 0x1f);
1074
  (*f) (1, &byte, NULL);
1075
}
1076
 
1077
static void
1078
output_R2_format (vbyte_func f, int mask, int grsave, unsigned long rlen)
1079
{
1080
  char bytes[20];
1081
  int count = 2;
1082
  mask = (mask & 0x0f);
1083
  grsave = (grsave & 0x7f);
1084
 
1085
  bytes[0] = (UNW_R2 | (mask >> 1));
1086
  bytes[1] = (((mask & 0x01) << 7) | grsave);
1087
  count += output_leb128 (bytes + 2, rlen, 0);
1088
  (*f) (count, bytes, NULL);
1089
}
1090
 
1091
static void
1092
output_R3_format (vbyte_func f, unw_record_type rtype, unsigned long rlen)
1093
{
1094
  int r = 0, count;
1095
  char bytes[20];
1096
  if (rlen <= 0x1f)
1097
    {
1098
      output_R1_format (f, rtype, rlen);
1099
      return;
1100
    }
1101
 
1102
  if (rtype == body)
1103
    r = 1;
1104
  else if (rtype != prologue)
1105
    as_bad (_("record type is not valid"));
1106
  bytes[0] = (UNW_R3 | r);
1107
  count = output_leb128 (bytes + 1, rlen, 0);
1108
  (*f) (count + 1, bytes, NULL);
1109
}
1110
 
1111
static void
1112
output_P1_format (vbyte_func f, int brmask)
1113
{
1114
  char byte;
1115
  byte = UNW_P1 | (brmask & 0x1f);
1116
  (*f) (1, &byte, NULL);
1117
}
1118
 
1119
static void
1120
output_P2_format (vbyte_func f, int brmask, int gr)
1121
{
1122
  char bytes[2];
1123
  brmask = (brmask & 0x1f);
1124
  bytes[0] = UNW_P2 | (brmask >> 1);
1125
  bytes[1] = (((brmask & 1) << 7) | gr);
1126
  (*f) (2, bytes, NULL);
1127
}
1128
 
1129
static void
1130
output_P3_format (vbyte_func f, unw_record_type rtype, int reg)
1131
{
1132
  char bytes[2];
1133
  int r = 0;
1134
  reg = (reg & 0x7f);
1135
  switch (rtype)
1136
    {
1137
    case psp_gr:
1138
      r = 0;
1139
      break;
1140
    case rp_gr:
1141
      r = 1;
1142
      break;
1143
    case pfs_gr:
1144
      r = 2;
1145
      break;
1146
    case preds_gr:
1147
      r = 3;
1148
      break;
1149
    case unat_gr:
1150
      r = 4;
1151
      break;
1152
    case lc_gr:
1153
      r = 5;
1154
      break;
1155
    case rp_br:
1156
      r = 6;
1157
      break;
1158
    case rnat_gr:
1159
      r = 7;
1160
      break;
1161
    case bsp_gr:
1162
      r = 8;
1163
      break;
1164
    case bspstore_gr:
1165
      r = 9;
1166
      break;
1167
    case fpsr_gr:
1168
      r = 10;
1169
      break;
1170
    case priunat_gr:
1171
      r = 11;
1172
      break;
1173
    default:
1174
      as_bad (_("Invalid record type for P3 format."));
1175
    }
1176
  bytes[0] = (UNW_P3 | (r >> 1));
1177
  bytes[1] = (((r & 1) << 7) | reg);
1178
  (*f) (2, bytes, NULL);
1179
}
1180
 
1181
static void
1182
output_P4_format (vbyte_func f, unsigned char *imask, unsigned long imask_size)
1183
{
1184
  imask[0] = UNW_P4;
1185
  (*f) (imask_size, (char *) imask, NULL);
1186
}
1187
 
1188
static void
1189
output_P5_format (vbyte_func f, int grmask, unsigned long frmask)
1190
{
1191
  char bytes[4];
1192
  grmask = (grmask & 0x0f);
1193
 
1194
  bytes[0] = UNW_P5;
1195
  bytes[1] = ((grmask << 4) | ((frmask & 0x000f0000) >> 16));
1196
  bytes[2] = ((frmask & 0x0000ff00) >> 8);
1197
  bytes[3] = (frmask & 0x000000ff);
1198
  (*f) (4, bytes, NULL);
1199
}
1200
 
1201
static void
1202
output_P6_format (vbyte_func f, unw_record_type rtype, int rmask)
1203
{
1204
  char byte;
1205
  int r = 0;
1206
 
1207
  if (rtype == gr_mem)
1208
    r = 1;
1209
  else if (rtype != fr_mem)
1210
    as_bad (_("Invalid record type for format P6"));
1211
  byte = (UNW_P6 | (r << 4) | (rmask & 0x0f));
1212
  (*f) (1, &byte, NULL);
1213
}
1214
 
1215
static void
1216
output_P7_format (vbyte_func f,
1217
                  unw_record_type rtype,
1218
                  unsigned long w1,
1219
                  unsigned long w2)
1220
{
1221
  char bytes[20];
1222
  int count = 1;
1223
  int r = 0;
1224
  count += output_leb128 (bytes + 1, w1, 0);
1225
  switch (rtype)
1226
    {
1227
    case mem_stack_f:
1228
      r = 0;
1229
      count += output_leb128 (bytes + count, w2 >> 4, 0);
1230
      break;
1231
    case mem_stack_v:
1232
      r = 1;
1233
      break;
1234
    case spill_base:
1235
      r = 2;
1236
      break;
1237
    case psp_sprel:
1238
      r = 3;
1239
      break;
1240
    case rp_when:
1241
      r = 4;
1242
      break;
1243
    case rp_psprel:
1244
      r = 5;
1245
      break;
1246
    case pfs_when:
1247
      r = 6;
1248
      break;
1249
    case pfs_psprel:
1250
      r = 7;
1251
      break;
1252
    case preds_when:
1253
      r = 8;
1254
      break;
1255
    case preds_psprel:
1256
      r = 9;
1257
      break;
1258
    case lc_when:
1259
      r = 10;
1260
      break;
1261
    case lc_psprel:
1262
      r = 11;
1263
      break;
1264
    case unat_when:
1265
      r = 12;
1266
      break;
1267
    case unat_psprel:
1268
      r = 13;
1269
      break;
1270
    case fpsr_when:
1271
      r = 14;
1272
      break;
1273
    case fpsr_psprel:
1274
      r = 15;
1275
      break;
1276
    default:
1277
      break;
1278
    }
1279
  bytes[0] = (UNW_P7 | r);
1280
  (*f) (count, bytes, NULL);
1281
}
1282
 
1283
static void
1284
output_P8_format (vbyte_func f, unw_record_type rtype, unsigned long t)
1285
{
1286
  char bytes[20];
1287
  int r = 0;
1288
  int count = 2;
1289
  bytes[0] = UNW_P8;
1290
  switch (rtype)
1291
    {
1292
    case rp_sprel:
1293
      r = 1;
1294
      break;
1295
    case pfs_sprel:
1296
      r = 2;
1297
      break;
1298
    case preds_sprel:
1299
      r = 3;
1300
      break;
1301
    case lc_sprel:
1302
      r = 4;
1303
      break;
1304
    case unat_sprel:
1305
      r = 5;
1306
      break;
1307
    case fpsr_sprel:
1308
      r = 6;
1309
      break;
1310
    case bsp_when:
1311
      r = 7;
1312
      break;
1313
    case bsp_psprel:
1314
      r = 8;
1315
      break;
1316
    case bsp_sprel:
1317
      r = 9;
1318
      break;
1319
    case bspstore_when:
1320
      r = 10;
1321
      break;
1322
    case bspstore_psprel:
1323
      r = 11;
1324
      break;
1325
    case bspstore_sprel:
1326
      r = 12;
1327
      break;
1328
    case rnat_when:
1329
      r = 13;
1330
      break;
1331
    case rnat_psprel:
1332
      r = 14;
1333
      break;
1334
    case rnat_sprel:
1335
      r = 15;
1336
      break;
1337
    case priunat_when_gr:
1338
      r = 16;
1339
      break;
1340
    case priunat_psprel:
1341
      r = 17;
1342
      break;
1343
    case priunat_sprel:
1344
      r = 18;
1345
      break;
1346
    case priunat_when_mem:
1347
      r = 19;
1348
      break;
1349
    default:
1350
      break;
1351
    }
1352
  bytes[1] = r;
1353
  count += output_leb128 (bytes + 2, t, 0);
1354
  (*f) (count, bytes, NULL);
1355
}
1356
 
1357
static void
1358
output_P9_format (vbyte_func f, int grmask, int gr)
1359
{
1360
  char bytes[3];
1361
  bytes[0] = UNW_P9;
1362
  bytes[1] = (grmask & 0x0f);
1363
  bytes[2] = (gr & 0x7f);
1364
  (*f) (3, bytes, NULL);
1365
}
1366
 
1367
static void
1368
output_P10_format (vbyte_func f, int abi, int context)
1369
{
1370
  char bytes[3];
1371
  bytes[0] = UNW_P10;
1372
  bytes[1] = (abi & 0xff);
1373
  bytes[2] = (context & 0xff);
1374
  (*f) (3, bytes, NULL);
1375
}
1376
 
1377
static void
1378
output_B1_format (vbyte_func f, unw_record_type rtype, unsigned long label)
1379
{
1380
  char byte;
1381
  int r = 0;
1382
  if (label > 0x1f)
1383
    {
1384
      output_B4_format (f, rtype, label);
1385
      return;
1386
    }
1387
  if (rtype == copy_state)
1388
    r = 1;
1389
  else if (rtype != label_state)
1390
    as_bad (_("Invalid record type for format B1"));
1391
 
1392
  byte = (UNW_B1 | (r << 5) | (label & 0x1f));
1393
  (*f) (1, &byte, NULL);
1394
}
1395
 
1396
static void
1397
output_B2_format (vbyte_func f, unsigned long ecount, unsigned long t)
1398
{
1399
  char bytes[20];
1400
  int count = 1;
1401
  if (ecount > 0x1f)
1402
    {
1403
      output_B3_format (f, ecount, t);
1404
      return;
1405
    }
1406
  bytes[0] = (UNW_B2 | (ecount & 0x1f));
1407
  count += output_leb128 (bytes + 1, t, 0);
1408
  (*f) (count, bytes, NULL);
1409
}
1410
 
1411
static void
1412
output_B3_format (vbyte_func f, unsigned long ecount, unsigned long t)
1413
{
1414
  char bytes[20];
1415
  int count = 1;
1416
  if (ecount <= 0x1f)
1417
    {
1418
      output_B2_format (f, ecount, t);
1419
      return;
1420
    }
1421
  bytes[0] = UNW_B3;
1422
  count += output_leb128 (bytes + 1, t, 0);
1423
  count += output_leb128 (bytes + count, ecount, 0);
1424
  (*f) (count, bytes, NULL);
1425
}
1426
 
1427
static void
1428
output_B4_format (vbyte_func f, unw_record_type rtype, unsigned long label)
1429
{
1430
  char bytes[20];
1431
  int r = 0;
1432
  int count = 1;
1433
  if (label <= 0x1f)
1434
    {
1435
      output_B1_format (f, rtype, label);
1436
      return;
1437
    }
1438
 
1439
  if (rtype == copy_state)
1440
    r = 1;
1441
  else if (rtype != label_state)
1442
    as_bad (_("Invalid record type for format B1"));
1443
 
1444
  bytes[0] = (UNW_B4 | (r << 3));
1445
  count += output_leb128 (bytes + 1, label, 0);
1446
  (*f) (count, bytes, NULL);
1447
}
1448
 
1449
static char
1450
format_ab_reg (int ab, int reg)
1451
{
1452
  int ret;
1453
  ab = (ab & 3);
1454
  reg = (reg & 0x1f);
1455
  ret = (ab << 5) | reg;
1456
  return ret;
1457
}
1458
 
1459
static void
1460
output_X1_format (vbyte_func f,
1461
                  unw_record_type rtype,
1462
                  int ab,
1463
                  int reg,
1464
                  unsigned long t,
1465
                  unsigned long w1)
1466
{
1467
  char bytes[20];
1468
  int r = 0;
1469
  int count = 2;
1470
  bytes[0] = UNW_X1;
1471
 
1472
  if (rtype == spill_sprel)
1473
    r = 1;
1474
  else if (rtype != spill_psprel)
1475
    as_bad (_("Invalid record type for format X1"));
1476
  bytes[1] = ((r << 7) | format_ab_reg (ab, reg));
1477
  count += output_leb128 (bytes + 2, t, 0);
1478
  count += output_leb128 (bytes + count, w1, 0);
1479
  (*f) (count, bytes, NULL);
1480
}
1481
 
1482
static void
1483
output_X2_format (vbyte_func f,
1484
                  int ab,
1485
                  int reg,
1486
                  int x,
1487
                  int y,
1488
                  int treg,
1489
                  unsigned long t)
1490
{
1491
  char bytes[20];
1492
  int count = 3;
1493
  bytes[0] = UNW_X2;
1494
  bytes[1] = (((x & 1) << 7) | format_ab_reg (ab, reg));
1495
  bytes[2] = (((y & 1) << 7) | (treg & 0x7f));
1496
  count += output_leb128 (bytes + 3, t, 0);
1497
  (*f) (count, bytes, NULL);
1498
}
1499
 
1500
static void
1501
output_X3_format (vbyte_func f,
1502
                  unw_record_type rtype,
1503
                  int qp,
1504
                  int ab,
1505
                  int reg,
1506
                  unsigned long t,
1507
                  unsigned long w1)
1508
{
1509
  char bytes[20];
1510
  int r = 0;
1511
  int count = 3;
1512
  bytes[0] = UNW_X3;
1513
 
1514
  if (rtype == spill_sprel_p)
1515
    r = 1;
1516
  else if (rtype != spill_psprel_p)
1517
    as_bad (_("Invalid record type for format X3"));
1518
  bytes[1] = ((r << 7) | (qp & 0x3f));
1519
  bytes[2] = format_ab_reg (ab, reg);
1520
  count += output_leb128 (bytes + 3, t, 0);
1521
  count += output_leb128 (bytes + count, w1, 0);
1522
  (*f) (count, bytes, NULL);
1523
}
1524
 
1525
static void
1526
output_X4_format (vbyte_func f,
1527
                  int qp,
1528
                  int ab,
1529
                  int reg,
1530
                  int x,
1531
                  int y,
1532
                  int treg,
1533
                  unsigned long t)
1534
{
1535
  char bytes[20];
1536
  int count = 4;
1537
  bytes[0] = UNW_X4;
1538
  bytes[1] = (qp & 0x3f);
1539
  bytes[2] = (((x & 1) << 7) | format_ab_reg (ab, reg));
1540
  bytes[3] = (((y & 1) << 7) | (treg & 0x7f));
1541
  count += output_leb128 (bytes + 4, t, 0);
1542
  (*f) (count, bytes, NULL);
1543
}
1544
 
1545
/* This function checks whether there are any outstanding .save-s and
1546
   discards them if so.  */
1547
 
1548
static void
1549
check_pending_save (void)
1550
{
1551
  if (unwind.pending_saves)
1552
    {
1553
      unw_rec_list *cur, *prev;
1554
 
1555
      as_warn (_("Previous .save incomplete"));
1556
      for (cur = unwind.list, prev = NULL; cur; )
1557
        if (&cur->r.record.p == unwind.pending_saves)
1558
          {
1559
            if (prev)
1560
              prev->next = cur->next;
1561
            else
1562
              unwind.list = cur->next;
1563
            if (cur == unwind.tail)
1564
              unwind.tail = prev;
1565
            if (cur == unwind.current_entry)
1566
              unwind.current_entry = cur->next;
1567
            /* Don't free the first discarded record, it's being used as
1568
               terminator for (currently) br_gr and gr_gr processing, and
1569
               also prevents leaving a dangling pointer to it in its
1570
               predecessor.  */
1571
            cur->r.record.p.grmask = 0;
1572
            cur->r.record.p.brmask = 0;
1573
            cur->r.record.p.frmask = 0;
1574
            prev = cur->r.record.p.next;
1575
            cur->r.record.p.next = NULL;
1576
            cur = prev;
1577
            break;
1578
          }
1579
        else
1580
          {
1581
            prev = cur;
1582
            cur = cur->next;
1583
          }
1584
      while (cur)
1585
        {
1586
          prev = cur;
1587
          cur = cur->r.record.p.next;
1588
          free (prev);
1589
        }
1590
      unwind.pending_saves = NULL;
1591
    }
1592
}
1593
 
1594
/* This function allocates a record list structure, and initializes fields.  */
1595
 
1596
static unw_rec_list *
1597
alloc_record (unw_record_type t)
1598
{
1599
  unw_rec_list *ptr;
1600
  ptr = xmalloc (sizeof (*ptr));
1601
  memset (ptr, 0, sizeof (*ptr));
1602
  ptr->slot_number = SLOT_NUM_NOT_SET;
1603
  ptr->r.type = t;
1604
  return ptr;
1605
}
1606
 
1607
/* Dummy unwind record used for calculating the length of the last prologue or
1608
   body region.  */
1609
 
1610
static unw_rec_list *
1611
output_endp (void)
1612
{
1613
  unw_rec_list *ptr = alloc_record (endp);
1614
  return ptr;
1615
}
1616
 
1617
static unw_rec_list *
1618
output_prologue (void)
1619
{
1620
  unw_rec_list *ptr = alloc_record (prologue);
1621
  memset (&ptr->r.record.r.mask, 0, sizeof (ptr->r.record.r.mask));
1622
  return ptr;
1623
}
1624
 
1625
static unw_rec_list *
1626
output_prologue_gr (unsigned int saved_mask, unsigned int reg)
1627
{
1628
  unw_rec_list *ptr = alloc_record (prologue_gr);
1629
  memset (&ptr->r.record.r.mask, 0, sizeof (ptr->r.record.r.mask));
1630
  ptr->r.record.r.grmask = saved_mask;
1631
  ptr->r.record.r.grsave = reg;
1632
  return ptr;
1633
}
1634
 
1635
static unw_rec_list *
1636
output_body (void)
1637
{
1638
  unw_rec_list *ptr = alloc_record (body);
1639
  return ptr;
1640
}
1641
 
1642
static unw_rec_list *
1643
output_mem_stack_f (unsigned int size)
1644
{
1645
  unw_rec_list *ptr = alloc_record (mem_stack_f);
1646
  ptr->r.record.p.size = size;
1647
  return ptr;
1648
}
1649
 
1650
static unw_rec_list *
1651
output_mem_stack_v (void)
1652
{
1653
  unw_rec_list *ptr = alloc_record (mem_stack_v);
1654
  return ptr;
1655
}
1656
 
1657
static unw_rec_list *
1658
output_psp_gr (unsigned int gr)
1659
{
1660
  unw_rec_list *ptr = alloc_record (psp_gr);
1661
  ptr->r.record.p.r.gr = gr;
1662
  return ptr;
1663
}
1664
 
1665
static unw_rec_list *
1666
output_psp_sprel (unsigned int offset)
1667
{
1668
  unw_rec_list *ptr = alloc_record (psp_sprel);
1669
  ptr->r.record.p.off.sp = offset / 4;
1670
  return ptr;
1671
}
1672
 
1673
static unw_rec_list *
1674
output_rp_when (void)
1675
{
1676
  unw_rec_list *ptr = alloc_record (rp_when);
1677
  return ptr;
1678
}
1679
 
1680
static unw_rec_list *
1681
output_rp_gr (unsigned int gr)
1682
{
1683
  unw_rec_list *ptr = alloc_record (rp_gr);
1684
  ptr->r.record.p.r.gr = gr;
1685
  return ptr;
1686
}
1687
 
1688
static unw_rec_list *
1689
output_rp_br (unsigned int br)
1690
{
1691
  unw_rec_list *ptr = alloc_record (rp_br);
1692
  ptr->r.record.p.r.br = br;
1693
  return ptr;
1694
}
1695
 
1696
static unw_rec_list *
1697
output_rp_psprel (unsigned int offset)
1698
{
1699
  unw_rec_list *ptr = alloc_record (rp_psprel);
1700
  ptr->r.record.p.off.psp = ENCODED_PSP_OFFSET (offset);
1701
  return ptr;
1702
}
1703
 
1704
static unw_rec_list *
1705
output_rp_sprel (unsigned int offset)
1706
{
1707
  unw_rec_list *ptr = alloc_record (rp_sprel);
1708
  ptr->r.record.p.off.sp = offset / 4;
1709
  return ptr;
1710
}
1711
 
1712
static unw_rec_list *
1713
output_pfs_when (void)
1714
{
1715
  unw_rec_list *ptr = alloc_record (pfs_when);
1716
  return ptr;
1717
}
1718
 
1719
static unw_rec_list *
1720
output_pfs_gr (unsigned int gr)
1721
{
1722
  unw_rec_list *ptr = alloc_record (pfs_gr);
1723
  ptr->r.record.p.r.gr = gr;
1724
  return ptr;
1725
}
1726
 
1727
static unw_rec_list *
1728
output_pfs_psprel (unsigned int offset)
1729
{
1730
  unw_rec_list *ptr = alloc_record (pfs_psprel);
1731
  ptr->r.record.p.off.psp = ENCODED_PSP_OFFSET (offset);
1732
  return ptr;
1733
}
1734
 
1735
static unw_rec_list *
1736
output_pfs_sprel (unsigned int offset)
1737
{
1738
  unw_rec_list *ptr = alloc_record (pfs_sprel);
1739
  ptr->r.record.p.off.sp = offset / 4;
1740
  return ptr;
1741
}
1742
 
1743
static unw_rec_list *
1744
output_preds_when (void)
1745
{
1746
  unw_rec_list *ptr = alloc_record (preds_when);
1747
  return ptr;
1748
}
1749
 
1750
static unw_rec_list *
1751
output_preds_gr (unsigned int gr)
1752
{
1753
  unw_rec_list *ptr = alloc_record (preds_gr);
1754
  ptr->r.record.p.r.gr = gr;
1755
  return ptr;
1756
}
1757
 
1758
static unw_rec_list *
1759
output_preds_psprel (unsigned int offset)
1760
{
1761
  unw_rec_list *ptr = alloc_record (preds_psprel);
1762
  ptr->r.record.p.off.psp = ENCODED_PSP_OFFSET (offset);
1763
  return ptr;
1764
}
1765
 
1766
static unw_rec_list *
1767
output_preds_sprel (unsigned int offset)
1768
{
1769
  unw_rec_list *ptr = alloc_record (preds_sprel);
1770
  ptr->r.record.p.off.sp = offset / 4;
1771
  return ptr;
1772
}
1773
 
1774
static unw_rec_list *
1775
output_fr_mem (unsigned int mask)
1776
{
1777
  unw_rec_list *ptr = alloc_record (fr_mem);
1778
  unw_rec_list *cur = ptr;
1779
 
1780
  ptr->r.record.p.frmask = mask;
1781
  unwind.pending_saves = &ptr->r.record.p;
1782
  for (;;)
1783
    {
1784
      unw_rec_list *prev = cur;
1785
 
1786
      /* Clear least significant set bit.  */
1787
      mask &= ~(mask & (~mask + 1));
1788
      if (!mask)
1789
        return ptr;
1790
      cur = alloc_record (fr_mem);
1791
      cur->r.record.p.frmask = mask;
1792
      /* Retain only least significant bit.  */
1793
      prev->r.record.p.frmask ^= mask;
1794
      prev->r.record.p.next = cur;
1795
    }
1796
}
1797
 
1798
static unw_rec_list *
1799
output_frgr_mem (unsigned int gr_mask, unsigned int fr_mask)
1800
{
1801
  unw_rec_list *ptr = alloc_record (frgr_mem);
1802
  unw_rec_list *cur = ptr;
1803
 
1804
  unwind.pending_saves = &cur->r.record.p;
1805
  cur->r.record.p.frmask = fr_mask;
1806
  while (fr_mask)
1807
    {
1808
      unw_rec_list *prev = cur;
1809
 
1810
      /* Clear least significant set bit.  */
1811
      fr_mask &= ~(fr_mask & (~fr_mask + 1));
1812
      if (!gr_mask && !fr_mask)
1813
        return ptr;
1814
      cur = alloc_record (frgr_mem);
1815
      cur->r.record.p.frmask = fr_mask;
1816
      /* Retain only least significant bit.  */
1817
      prev->r.record.p.frmask ^= fr_mask;
1818
      prev->r.record.p.next = cur;
1819
    }
1820
  cur->r.record.p.grmask = gr_mask;
1821
  for (;;)
1822
    {
1823
      unw_rec_list *prev = cur;
1824
 
1825
      /* Clear least significant set bit.  */
1826
      gr_mask &= ~(gr_mask & (~gr_mask + 1));
1827
      if (!gr_mask)
1828
        return ptr;
1829
      cur = alloc_record (frgr_mem);
1830
      cur->r.record.p.grmask = gr_mask;
1831
      /* Retain only least significant bit.  */
1832
      prev->r.record.p.grmask ^= gr_mask;
1833
      prev->r.record.p.next = cur;
1834
    }
1835
}
1836
 
1837
static unw_rec_list *
1838
output_gr_gr (unsigned int mask, unsigned int reg)
1839
{
1840
  unw_rec_list *ptr = alloc_record (gr_gr);
1841
  unw_rec_list *cur = ptr;
1842
 
1843
  ptr->r.record.p.grmask = mask;
1844
  ptr->r.record.p.r.gr = reg;
1845
  unwind.pending_saves = &ptr->r.record.p;
1846
  for (;;)
1847
    {
1848
      unw_rec_list *prev = cur;
1849
 
1850
      /* Clear least significant set bit.  */
1851
      mask &= ~(mask & (~mask + 1));
1852
      if (!mask)
1853
        return ptr;
1854
      cur = alloc_record (gr_gr);
1855
      cur->r.record.p.grmask = mask;
1856
      /* Indicate this record shouldn't be output.  */
1857
      cur->r.record.p.r.gr = REG_NUM;
1858
      /* Retain only least significant bit.  */
1859
      prev->r.record.p.grmask ^= mask;
1860
      prev->r.record.p.next = cur;
1861
    }
1862
}
1863
 
1864
static unw_rec_list *
1865
output_gr_mem (unsigned int mask)
1866
{
1867
  unw_rec_list *ptr = alloc_record (gr_mem);
1868
  unw_rec_list *cur = ptr;
1869
 
1870
  ptr->r.record.p.grmask = mask;
1871
  unwind.pending_saves = &ptr->r.record.p;
1872
  for (;;)
1873
    {
1874
      unw_rec_list *prev = cur;
1875
 
1876
      /* Clear least significant set bit.  */
1877
      mask &= ~(mask & (~mask + 1));
1878
      if (!mask)
1879
        return ptr;
1880
      cur = alloc_record (gr_mem);
1881
      cur->r.record.p.grmask = mask;
1882
      /* Retain only least significant bit.  */
1883
      prev->r.record.p.grmask ^= mask;
1884
      prev->r.record.p.next = cur;
1885
    }
1886
}
1887
 
1888
static unw_rec_list *
1889
output_br_mem (unsigned int mask)
1890
{
1891
  unw_rec_list *ptr = alloc_record (br_mem);
1892
  unw_rec_list *cur = ptr;
1893
 
1894
  ptr->r.record.p.brmask = mask;
1895
  unwind.pending_saves = &ptr->r.record.p;
1896
  for (;;)
1897
    {
1898
      unw_rec_list *prev = cur;
1899
 
1900
      /* Clear least significant set bit.  */
1901
      mask &= ~(mask & (~mask + 1));
1902
      if (!mask)
1903
        return ptr;
1904
      cur = alloc_record (br_mem);
1905
      cur->r.record.p.brmask = mask;
1906
      /* Retain only least significant bit.  */
1907
      prev->r.record.p.brmask ^= mask;
1908
      prev->r.record.p.next = cur;
1909
    }
1910
}
1911
 
1912
static unw_rec_list *
1913
output_br_gr (unsigned int mask, unsigned int reg)
1914
{
1915
  unw_rec_list *ptr = alloc_record (br_gr);
1916
  unw_rec_list *cur = ptr;
1917
 
1918
  ptr->r.record.p.brmask = mask;
1919
  ptr->r.record.p.r.gr = reg;
1920
  unwind.pending_saves = &ptr->r.record.p;
1921
  for (;;)
1922
    {
1923
      unw_rec_list *prev = cur;
1924
 
1925
      /* Clear least significant set bit.  */
1926
      mask &= ~(mask & (~mask + 1));
1927
      if (!mask)
1928
        return ptr;
1929
      cur = alloc_record (br_gr);
1930
      cur->r.record.p.brmask = mask;
1931
      /* Indicate this record shouldn't be output.  */
1932
      cur->r.record.p.r.gr = REG_NUM;
1933
      /* Retain only least significant bit.  */
1934
      prev->r.record.p.brmask ^= mask;
1935
      prev->r.record.p.next = cur;
1936
    }
1937
}
1938
 
1939
static unw_rec_list *
1940
output_spill_base (unsigned int offset)
1941
{
1942
  unw_rec_list *ptr = alloc_record (spill_base);
1943
  ptr->r.record.p.off.psp = ENCODED_PSP_OFFSET (offset);
1944
  return ptr;
1945
}
1946
 
1947
static unw_rec_list *
1948
output_unat_when (void)
1949
{
1950
  unw_rec_list *ptr = alloc_record (unat_when);
1951
  return ptr;
1952
}
1953
 
1954
static unw_rec_list *
1955
output_unat_gr (unsigned int gr)
1956
{
1957
  unw_rec_list *ptr = alloc_record (unat_gr);
1958
  ptr->r.record.p.r.gr = gr;
1959
  return ptr;
1960
}
1961
 
1962
static unw_rec_list *
1963
output_unat_psprel (unsigned int offset)
1964
{
1965
  unw_rec_list *ptr = alloc_record (unat_psprel);
1966
  ptr->r.record.p.off.psp = ENCODED_PSP_OFFSET (offset);
1967
  return ptr;
1968
}
1969
 
1970
static unw_rec_list *
1971
output_unat_sprel (unsigned int offset)
1972
{
1973
  unw_rec_list *ptr = alloc_record (unat_sprel);
1974
  ptr->r.record.p.off.sp = offset / 4;
1975
  return ptr;
1976
}
1977
 
1978
static unw_rec_list *
1979
output_lc_when (void)
1980
{
1981
  unw_rec_list *ptr = alloc_record (lc_when);
1982
  return ptr;
1983
}
1984
 
1985
static unw_rec_list *
1986
output_lc_gr (unsigned int gr)
1987
{
1988
  unw_rec_list *ptr = alloc_record (lc_gr);
1989
  ptr->r.record.p.r.gr = gr;
1990
  return ptr;
1991
}
1992
 
1993
static unw_rec_list *
1994
output_lc_psprel (unsigned int offset)
1995
{
1996
  unw_rec_list *ptr = alloc_record (lc_psprel);
1997
  ptr->r.record.p.off.psp = ENCODED_PSP_OFFSET (offset);
1998
  return ptr;
1999
}
2000
 
2001
static unw_rec_list *
2002
output_lc_sprel (unsigned int offset)
2003
{
2004
  unw_rec_list *ptr = alloc_record (lc_sprel);
2005
  ptr->r.record.p.off.sp = offset / 4;
2006
  return ptr;
2007
}
2008
 
2009
static unw_rec_list *
2010
output_fpsr_when (void)
2011
{
2012
  unw_rec_list *ptr = alloc_record (fpsr_when);
2013
  return ptr;
2014
}
2015
 
2016
static unw_rec_list *
2017
output_fpsr_gr (unsigned int gr)
2018
{
2019
  unw_rec_list *ptr = alloc_record (fpsr_gr);
2020
  ptr->r.record.p.r.gr = gr;
2021
  return ptr;
2022
}
2023
 
2024
static unw_rec_list *
2025
output_fpsr_psprel (unsigned int offset)
2026
{
2027
  unw_rec_list *ptr = alloc_record (fpsr_psprel);
2028
  ptr->r.record.p.off.psp = ENCODED_PSP_OFFSET (offset);
2029
  return ptr;
2030
}
2031
 
2032
static unw_rec_list *
2033
output_fpsr_sprel (unsigned int offset)
2034
{
2035
  unw_rec_list *ptr = alloc_record (fpsr_sprel);
2036
  ptr->r.record.p.off.sp = offset / 4;
2037
  return ptr;
2038
}
2039
 
2040
static unw_rec_list *
2041
output_priunat_when_gr (void)
2042
{
2043
  unw_rec_list *ptr = alloc_record (priunat_when_gr);
2044
  return ptr;
2045
}
2046
 
2047
static unw_rec_list *
2048
output_priunat_when_mem (void)
2049
{
2050
  unw_rec_list *ptr = alloc_record (priunat_when_mem);
2051
  return ptr;
2052
}
2053
 
2054
static unw_rec_list *
2055
output_priunat_gr (unsigned int gr)
2056
{
2057
  unw_rec_list *ptr = alloc_record (priunat_gr);
2058
  ptr->r.record.p.r.gr = gr;
2059
  return ptr;
2060
}
2061
 
2062
static unw_rec_list *
2063
output_priunat_psprel (unsigned int offset)
2064
{
2065
  unw_rec_list *ptr = alloc_record (priunat_psprel);
2066
  ptr->r.record.p.off.psp = ENCODED_PSP_OFFSET (offset);
2067
  return ptr;
2068
}
2069
 
2070
static unw_rec_list *
2071
output_priunat_sprel (unsigned int offset)
2072
{
2073
  unw_rec_list *ptr = alloc_record (priunat_sprel);
2074
  ptr->r.record.p.off.sp = offset / 4;
2075
  return ptr;
2076
}
2077
 
2078
static unw_rec_list *
2079
output_bsp_when (void)
2080
{
2081
  unw_rec_list *ptr = alloc_record (bsp_when);
2082
  return ptr;
2083
}
2084
 
2085
static unw_rec_list *
2086
output_bsp_gr (unsigned int gr)
2087
{
2088
  unw_rec_list *ptr = alloc_record (bsp_gr);
2089
  ptr->r.record.p.r.gr = gr;
2090
  return ptr;
2091
}
2092
 
2093
static unw_rec_list *
2094
output_bsp_psprel (unsigned int offset)
2095
{
2096
  unw_rec_list *ptr = alloc_record (bsp_psprel);
2097
  ptr->r.record.p.off.psp = ENCODED_PSP_OFFSET (offset);
2098
  return ptr;
2099
}
2100
 
2101
static unw_rec_list *
2102
output_bsp_sprel (unsigned int offset)
2103
{
2104
  unw_rec_list *ptr = alloc_record (bsp_sprel);
2105
  ptr->r.record.p.off.sp = offset / 4;
2106
  return ptr;
2107
}
2108
 
2109
static unw_rec_list *
2110
output_bspstore_when (void)
2111
{
2112
  unw_rec_list *ptr = alloc_record (bspstore_when);
2113
  return ptr;
2114
}
2115
 
2116
static unw_rec_list *
2117
output_bspstore_gr (unsigned int gr)
2118
{
2119
  unw_rec_list *ptr = alloc_record (bspstore_gr);
2120
  ptr->r.record.p.r.gr = gr;
2121
  return ptr;
2122
}
2123
 
2124
static unw_rec_list *
2125
output_bspstore_psprel (unsigned int offset)
2126
{
2127
  unw_rec_list *ptr = alloc_record (bspstore_psprel);
2128
  ptr->r.record.p.off.psp = ENCODED_PSP_OFFSET (offset);
2129
  return ptr;
2130
}
2131
 
2132
static unw_rec_list *
2133
output_bspstore_sprel (unsigned int offset)
2134
{
2135
  unw_rec_list *ptr = alloc_record (bspstore_sprel);
2136
  ptr->r.record.p.off.sp = offset / 4;
2137
  return ptr;
2138
}
2139
 
2140
static unw_rec_list *
2141
output_rnat_when (void)
2142
{
2143
  unw_rec_list *ptr = alloc_record (rnat_when);
2144
  return ptr;
2145
}
2146
 
2147
static unw_rec_list *
2148
output_rnat_gr (unsigned int gr)
2149
{
2150
  unw_rec_list *ptr = alloc_record (rnat_gr);
2151
  ptr->r.record.p.r.gr = gr;
2152
  return ptr;
2153
}
2154
 
2155
static unw_rec_list *
2156
output_rnat_psprel (unsigned int offset)
2157
{
2158
  unw_rec_list *ptr = alloc_record (rnat_psprel);
2159
  ptr->r.record.p.off.psp = ENCODED_PSP_OFFSET (offset);
2160
  return ptr;
2161
}
2162
 
2163
static unw_rec_list *
2164
output_rnat_sprel (unsigned int offset)
2165
{
2166
  unw_rec_list *ptr = alloc_record (rnat_sprel);
2167
  ptr->r.record.p.off.sp = offset / 4;
2168
  return ptr;
2169
}
2170
 
2171
static unw_rec_list *
2172
output_unwabi (unsigned long abi, unsigned long context)
2173
{
2174
  unw_rec_list *ptr = alloc_record (unwabi);
2175
  ptr->r.record.p.abi = abi;
2176
  ptr->r.record.p.context = context;
2177
  return ptr;
2178
}
2179
 
2180
static unw_rec_list *
2181
output_epilogue (unsigned long ecount)
2182
{
2183
  unw_rec_list *ptr = alloc_record (epilogue);
2184
  ptr->r.record.b.ecount = ecount;
2185
  return ptr;
2186
}
2187
 
2188
static unw_rec_list *
2189
output_label_state (unsigned long label)
2190
{
2191
  unw_rec_list *ptr = alloc_record (label_state);
2192
  ptr->r.record.b.label = label;
2193
  return ptr;
2194
}
2195
 
2196
static unw_rec_list *
2197
output_copy_state (unsigned long label)
2198
{
2199
  unw_rec_list *ptr = alloc_record (copy_state);
2200
  ptr->r.record.b.label = label;
2201
  return ptr;
2202
}
2203
 
2204
static unw_rec_list *
2205
output_spill_psprel (unsigned int ab,
2206
                     unsigned int reg,
2207
                     unsigned int offset,
2208
                     unsigned int predicate)
2209
{
2210
  unw_rec_list *ptr = alloc_record (predicate ? spill_psprel_p : spill_psprel);
2211
  ptr->r.record.x.ab = ab;
2212
  ptr->r.record.x.reg = reg;
2213
  ptr->r.record.x.where.pspoff = ENCODED_PSP_OFFSET (offset);
2214
  ptr->r.record.x.qp = predicate;
2215
  return ptr;
2216
}
2217
 
2218
static unw_rec_list *
2219
output_spill_sprel (unsigned int ab,
2220
                    unsigned int reg,
2221
                    unsigned int offset,
2222
                    unsigned int predicate)
2223
{
2224
  unw_rec_list *ptr = alloc_record (predicate ? spill_sprel_p : spill_sprel);
2225
  ptr->r.record.x.ab = ab;
2226
  ptr->r.record.x.reg = reg;
2227
  ptr->r.record.x.where.spoff = offset / 4;
2228
  ptr->r.record.x.qp = predicate;
2229
  return ptr;
2230
}
2231
 
2232
static unw_rec_list *
2233
output_spill_reg (unsigned int ab,
2234
                  unsigned int reg,
2235
                  unsigned int targ_reg,
2236
                  unsigned int xy,
2237
                  unsigned int predicate)
2238
{
2239
  unw_rec_list *ptr = alloc_record (predicate ? spill_reg_p : spill_reg);
2240
  ptr->r.record.x.ab = ab;
2241
  ptr->r.record.x.reg = reg;
2242
  ptr->r.record.x.where.reg = targ_reg;
2243
  ptr->r.record.x.xy = xy;
2244
  ptr->r.record.x.qp = predicate;
2245
  return ptr;
2246
}
2247
 
2248
/* Given a unw_rec_list process the correct format with the
2249
   specified function.  */
2250
 
2251
static void
2252
process_one_record (unw_rec_list *ptr, vbyte_func f)
2253
{
2254
  unsigned int fr_mask, gr_mask;
2255
 
2256
  switch (ptr->r.type)
2257
    {
2258
      /* This is a dummy record that takes up no space in the output.  */
2259
    case endp:
2260
      break;
2261
 
2262
    case gr_mem:
2263
    case fr_mem:
2264
    case br_mem:
2265
    case frgr_mem:
2266
      /* These are taken care of by prologue/prologue_gr.  */
2267
      break;
2268
 
2269
    case prologue_gr:
2270
    case prologue:
2271
      if (ptr->r.type == prologue_gr)
2272
        output_R2_format (f, ptr->r.record.r.grmask,
2273
                          ptr->r.record.r.grsave, ptr->r.record.r.rlen);
2274
      else
2275
        output_R1_format (f, ptr->r.type, ptr->r.record.r.rlen);
2276
 
2277
      /* Output descriptor(s) for union of register spills (if any).  */
2278
      gr_mask = ptr->r.record.r.mask.gr_mem;
2279
      fr_mask = ptr->r.record.r.mask.fr_mem;
2280
      if (fr_mask)
2281
        {
2282
          if ((fr_mask & ~0xfUL) == 0)
2283
            output_P6_format (f, fr_mem, fr_mask);
2284
          else
2285
            {
2286
              output_P5_format (f, gr_mask, fr_mask);
2287
              gr_mask = 0;
2288
            }
2289
        }
2290
      if (gr_mask)
2291
        output_P6_format (f, gr_mem, gr_mask);
2292
      if (ptr->r.record.r.mask.br_mem)
2293
        output_P1_format (f, ptr->r.record.r.mask.br_mem);
2294
 
2295
      /* output imask descriptor if necessary:  */
2296
      if (ptr->r.record.r.mask.i)
2297
        output_P4_format (f, ptr->r.record.r.mask.i,
2298
                          ptr->r.record.r.imask_size);
2299
      break;
2300
 
2301
    case body:
2302
      output_R1_format (f, ptr->r.type, ptr->r.record.r.rlen);
2303
      break;
2304
    case mem_stack_f:
2305
    case mem_stack_v:
2306
      output_P7_format (f, ptr->r.type, ptr->r.record.p.t,
2307
                        ptr->r.record.p.size);
2308
      break;
2309
    case psp_gr:
2310
    case rp_gr:
2311
    case pfs_gr:
2312
    case preds_gr:
2313
    case unat_gr:
2314
    case lc_gr:
2315
    case fpsr_gr:
2316
    case priunat_gr:
2317
    case bsp_gr:
2318
    case bspstore_gr:
2319
    case rnat_gr:
2320
      output_P3_format (f, ptr->r.type, ptr->r.record.p.r.gr);
2321
      break;
2322
    case rp_br:
2323
      output_P3_format (f, rp_br, ptr->r.record.p.r.br);
2324
      break;
2325
    case psp_sprel:
2326
      output_P7_format (f, psp_sprel, ptr->r.record.p.off.sp, 0);
2327
      break;
2328
    case rp_when:
2329
    case pfs_when:
2330
    case preds_when:
2331
    case unat_when:
2332
    case lc_when:
2333
    case fpsr_when:
2334
      output_P7_format (f, ptr->r.type, ptr->r.record.p.t, 0);
2335
      break;
2336
    case rp_psprel:
2337
    case pfs_psprel:
2338
    case preds_psprel:
2339
    case unat_psprel:
2340
    case lc_psprel:
2341
    case fpsr_psprel:
2342
    case spill_base:
2343
      output_P7_format (f, ptr->r.type, ptr->r.record.p.off.psp, 0);
2344
      break;
2345
    case rp_sprel:
2346
    case pfs_sprel:
2347
    case preds_sprel:
2348
    case unat_sprel:
2349
    case lc_sprel:
2350
    case fpsr_sprel:
2351
    case priunat_sprel:
2352
    case bsp_sprel:
2353
    case bspstore_sprel:
2354
    case rnat_sprel:
2355
      output_P8_format (f, ptr->r.type, ptr->r.record.p.off.sp);
2356
      break;
2357
    case gr_gr:
2358
      if (ptr->r.record.p.r.gr < REG_NUM)
2359
        {
2360
          const unw_rec_list *cur = ptr;
2361
 
2362
          gr_mask = cur->r.record.p.grmask;
2363
          while ((cur = cur->r.record.p.next) != NULL)
2364
            gr_mask |= cur->r.record.p.grmask;
2365
          output_P9_format (f, gr_mask, ptr->r.record.p.r.gr);
2366
        }
2367
      break;
2368
    case br_gr:
2369
      if (ptr->r.record.p.r.gr < REG_NUM)
2370
        {
2371
          const unw_rec_list *cur = ptr;
2372
 
2373
          gr_mask = cur->r.record.p.brmask;
2374
          while ((cur = cur->r.record.p.next) != NULL)
2375
            gr_mask |= cur->r.record.p.brmask;
2376
          output_P2_format (f, gr_mask, ptr->r.record.p.r.gr);
2377
        }
2378
      break;
2379
    case spill_mask:
2380
      as_bad (_("spill_mask record unimplemented."));
2381
      break;
2382
    case priunat_when_gr:
2383
    case priunat_when_mem:
2384
    case bsp_when:
2385
    case bspstore_when:
2386
    case rnat_when:
2387
      output_P8_format (f, ptr->r.type, ptr->r.record.p.t);
2388
      break;
2389
    case priunat_psprel:
2390
    case bsp_psprel:
2391
    case bspstore_psprel:
2392
    case rnat_psprel:
2393
      output_P8_format (f, ptr->r.type, ptr->r.record.p.off.psp);
2394
      break;
2395
    case unwabi:
2396
      output_P10_format (f, ptr->r.record.p.abi, ptr->r.record.p.context);
2397
      break;
2398
    case epilogue:
2399
      output_B3_format (f, ptr->r.record.b.ecount, ptr->r.record.b.t);
2400
      break;
2401
    case label_state:
2402
    case copy_state:
2403
      output_B4_format (f, ptr->r.type, ptr->r.record.b.label);
2404
      break;
2405
    case spill_psprel:
2406
      output_X1_format (f, ptr->r.type, ptr->r.record.x.ab,
2407
                        ptr->r.record.x.reg, ptr->r.record.x.t,
2408
                        ptr->r.record.x.where.pspoff);
2409
      break;
2410
    case spill_sprel:
2411
      output_X1_format (f, ptr->r.type, ptr->r.record.x.ab,
2412
                        ptr->r.record.x.reg, ptr->r.record.x.t,
2413
                        ptr->r.record.x.where.spoff);
2414
      break;
2415
    case spill_reg:
2416
      output_X2_format (f, ptr->r.record.x.ab, ptr->r.record.x.reg,
2417
                        ptr->r.record.x.xy >> 1, ptr->r.record.x.xy,
2418
                        ptr->r.record.x.where.reg, ptr->r.record.x.t);
2419
      break;
2420
    case spill_psprel_p:
2421
      output_X3_format (f, ptr->r.type, ptr->r.record.x.qp,
2422
                        ptr->r.record.x.ab, ptr->r.record.x.reg,
2423
                        ptr->r.record.x.t, ptr->r.record.x.where.pspoff);
2424
      break;
2425
    case spill_sprel_p:
2426
      output_X3_format (f, ptr->r.type, ptr->r.record.x.qp,
2427
                        ptr->r.record.x.ab, ptr->r.record.x.reg,
2428
                        ptr->r.record.x.t, ptr->r.record.x.where.spoff);
2429
      break;
2430
    case spill_reg_p:
2431
      output_X4_format (f, ptr->r.record.x.qp, ptr->r.record.x.ab,
2432
                        ptr->r.record.x.reg, ptr->r.record.x.xy >> 1,
2433
                        ptr->r.record.x.xy, ptr->r.record.x.where.reg,
2434
                        ptr->r.record.x.t);
2435
      break;
2436
    default:
2437
      as_bad (_("record_type_not_valid"));
2438
      break;
2439
    }
2440
}
2441
 
2442
/* Given a unw_rec_list list, process all the records with
2443
   the specified function.  */
2444
static void
2445
process_unw_records (unw_rec_list *list, vbyte_func f)
2446
{
2447
  unw_rec_list *ptr;
2448
  for (ptr = list; ptr; ptr = ptr->next)
2449
    process_one_record (ptr, f);
2450
}
2451
 
2452
/* Determine the size of a record list in bytes.  */
2453
static int
2454
calc_record_size (unw_rec_list *list)
2455
{
2456
  vbyte_count = 0;
2457
  process_unw_records (list, count_output);
2458
  return vbyte_count;
2459
}
2460
 
2461
/* Return the number of bits set in the input value.
2462
   Perhaps this has a better place...  */
2463
#if __GNUC__ > 3 || (__GNUC__ == 3 && __GNUC_MINOR__ >= 4)
2464
# define popcount __builtin_popcount
2465
#else
2466
static int
2467
popcount (unsigned x)
2468
{
2469
  static const unsigned char popcnt[16] =
2470
    {
2471
      0, 1, 1, 2,
2472
      1, 2, 2, 3,
2473
      1, 2, 2, 3,
2474
      2, 3, 3, 4
2475
    };
2476
 
2477
  if (x < NELEMS (popcnt))
2478
    return popcnt[x];
2479
  return popcnt[x % NELEMS (popcnt)] + popcount (x / NELEMS (popcnt));
2480
}
2481
#endif
2482
 
2483
/* Update IMASK bitmask to reflect the fact that one or more registers
2484
   of type TYPE are saved starting at instruction with index T.  If N
2485
   bits are set in REGMASK, it is assumed that instructions T through
2486
   T+N-1 save these registers.
2487
 
2488
   TYPE values:
2489
        0: no save
2490
        1: instruction saves next fp reg
2491
        2: instruction saves next general reg
2492
        3: instruction saves next branch reg */
2493
static void
2494
set_imask (unw_rec_list *region,
2495
           unsigned long regmask,
2496
           unsigned long t,
2497
           unsigned int type)
2498
{
2499
  unsigned char *imask;
2500
  unsigned long imask_size;
2501
  unsigned int i;
2502
  int pos;
2503
 
2504
  imask = region->r.record.r.mask.i;
2505
  imask_size = region->r.record.r.imask_size;
2506
  if (!imask)
2507
    {
2508
      imask_size = (region->r.record.r.rlen * 2 + 7) / 8 + 1;
2509
      imask = xmalloc (imask_size);
2510
      memset (imask, 0, imask_size);
2511
 
2512
      region->r.record.r.imask_size = imask_size;
2513
      region->r.record.r.mask.i = imask;
2514
    }
2515
 
2516
  i = (t / 4) + 1;
2517
  pos = 2 * (3 - t % 4);
2518
  while (regmask)
2519
    {
2520
      if (i >= imask_size)
2521
        {
2522
          as_bad (_("Ignoring attempt to spill beyond end of region"));
2523
          return;
2524
        }
2525
 
2526
      imask[i] |= (type & 0x3) << pos;
2527
 
2528
      regmask &= (regmask - 1);
2529
      pos -= 2;
2530
      if (pos < 0)
2531
        {
2532
          pos = 0;
2533
          ++i;
2534
        }
2535
    }
2536
}
2537
 
2538
/* Return the number of instruction slots from FIRST_ADDR to SLOT_ADDR.
2539
   SLOT_FRAG is the frag containing SLOT_ADDR, and FIRST_FRAG is the frag
2540
   containing FIRST_ADDR.  If BEFORE_RELAX, then we use worst-case estimates
2541
   for frag sizes.  */
2542
 
2543
static unsigned long
2544
slot_index (unsigned long slot_addr,
2545
            fragS *slot_frag,
2546
            unsigned long first_addr,
2547
            fragS *first_frag,
2548
            int before_relax)
2549
{
2550
  unsigned long index = 0;
2551
 
2552
  /* First time we are called, the initial address and frag are invalid.  */
2553
  if (first_addr == 0)
2554
    return 0;
2555
 
2556
  /* If the two addresses are in different frags, then we need to add in
2557
     the remaining size of this frag, and then the entire size of intermediate
2558
     frags.  */
2559
  while (slot_frag != first_frag)
2560
    {
2561
      unsigned long start_addr = (unsigned long) &first_frag->fr_literal;
2562
 
2563
      if (! before_relax)
2564
        {
2565
          /* We can get the final addresses only during and after
2566
             relaxation.  */
2567
          if (first_frag->fr_next && first_frag->fr_next->fr_address)
2568
            index += 3 * ((first_frag->fr_next->fr_address
2569
                           - first_frag->fr_address
2570
                             - first_frag->fr_fix) >> 4);
2571
        }
2572
      else
2573
        /* We don't know what the final addresses will be. We try our
2574
           best to estimate.  */
2575
        switch (first_frag->fr_type)
2576
          {
2577
          default:
2578
            break;
2579
 
2580
          case rs_space:
2581
            as_fatal (_("Only constant space allocation is supported"));
2582
            break;
2583
 
2584
          case rs_align:
2585
          case rs_align_code:
2586
          case rs_align_test:
2587
            /* Take alignment into account.  Assume the worst case
2588
               before relaxation.  */
2589
            index += 3 * ((1 << first_frag->fr_offset) >> 4);
2590
            break;
2591
 
2592
          case rs_org:
2593
            if (first_frag->fr_symbol)
2594
              {
2595
                as_fatal (_("Only constant offsets are supported"));
2596
                break;
2597
              }
2598
          case rs_fill:
2599
            index += 3 * (first_frag->fr_offset >> 4);
2600
            break;
2601
          }
2602
 
2603
      /* Add in the full size of the frag converted to instruction slots.  */
2604
      index += 3 * (first_frag->fr_fix >> 4);
2605
      /* Subtract away the initial part before first_addr.  */
2606
      index -= (3 * ((first_addr >> 4) - (start_addr >> 4))
2607
                + ((first_addr & 0x3) - (start_addr & 0x3)));
2608
 
2609
      /* Move to the beginning of the next frag.  */
2610
      first_frag = first_frag->fr_next;
2611
      first_addr = (unsigned long) &first_frag->fr_literal;
2612
 
2613
      /* This can happen if there is section switching in the middle of a
2614
         function, causing the frag chain for the function to be broken.
2615
         It is too difficult to recover safely from this problem, so we just
2616
         exit with an error.  */
2617
      if (first_frag == NULL)
2618
        as_fatal (_("Section switching in code is not supported."));
2619
    }
2620
 
2621
  /* Add in the used part of the last frag.  */
2622
  index += (3 * ((slot_addr >> 4) - (first_addr >> 4))
2623
            + ((slot_addr & 0x3) - (first_addr & 0x3)));
2624
  return index;
2625
}
2626
 
2627
/* Optimize unwind record directives.  */
2628
 
2629
static unw_rec_list *
2630
optimize_unw_records (unw_rec_list *list)
2631
{
2632
  if (!list)
2633
    return NULL;
2634
 
2635
  /* If the only unwind record is ".prologue" or ".prologue" followed
2636
     by ".body", then we can optimize the unwind directives away.  */
2637
  if (list->r.type == prologue
2638
      && (list->next->r.type == endp
2639
          || (list->next->r.type == body && list->next->next->r.type == endp)))
2640
    return NULL;
2641
 
2642
  return list;
2643
}
2644
 
2645
/* Given a complete record list, process any records which have
2646
   unresolved fields, (ie length counts for a prologue).  After
2647
   this has been run, all necessary information should be available
2648
   within each record to generate an image.  */
2649
 
2650
static void
2651
fixup_unw_records (unw_rec_list *list, int before_relax)
2652
{
2653
  unw_rec_list *ptr, *region = 0;
2654
  unsigned long first_addr = 0, rlen = 0, t;
2655
  fragS *first_frag = 0;
2656
 
2657
  for (ptr = list; ptr; ptr = ptr->next)
2658
    {
2659
      if (ptr->slot_number == SLOT_NUM_NOT_SET)
2660
        as_bad (_(" Insn slot not set in unwind record."));
2661
      t = slot_index (ptr->slot_number, ptr->slot_frag,
2662
                      first_addr, first_frag, before_relax);
2663
      switch (ptr->r.type)
2664
        {
2665
        case prologue:
2666
        case prologue_gr:
2667
        case body:
2668
          {
2669
            unw_rec_list *last;
2670
            int size;
2671
            unsigned long last_addr = 0;
2672
            fragS *last_frag = NULL;
2673
 
2674
            first_addr = ptr->slot_number;
2675
            first_frag = ptr->slot_frag;
2676
            /* Find either the next body/prologue start, or the end of
2677
               the function, and determine the size of the region.  */
2678
            for (last = ptr->next; last != NULL; last = last->next)
2679
              if (last->r.type == prologue || last->r.type == prologue_gr
2680
                  || last->r.type == body || last->r.type == endp)
2681
                {
2682
                  last_addr = last->slot_number;
2683
                  last_frag = last->slot_frag;
2684
                  break;
2685
                }
2686
            size = slot_index (last_addr, last_frag, first_addr, first_frag,
2687
                               before_relax);
2688
            rlen = ptr->r.record.r.rlen = size;
2689
            if (ptr->r.type == body)
2690
              /* End of region.  */
2691
              region = 0;
2692
            else
2693
              region = ptr;
2694
            break;
2695
          }
2696
        case epilogue:
2697
          if (t < rlen)
2698
            ptr->r.record.b.t = rlen - 1 - t;
2699
          else
2700
            /* This happens when a memory-stack-less procedure uses a
2701
               ".restore sp" directive at the end of a region to pop
2702
               the frame state.  */
2703
            ptr->r.record.b.t = 0;
2704
          break;
2705
 
2706
        case mem_stack_f:
2707
        case mem_stack_v:
2708
        case rp_when:
2709
        case pfs_when:
2710
        case preds_when:
2711
        case unat_when:
2712
        case lc_when:
2713
        case fpsr_when:
2714
        case priunat_when_gr:
2715
        case priunat_when_mem:
2716
        case bsp_when:
2717
        case bspstore_when:
2718
        case rnat_when:
2719
          ptr->r.record.p.t = t;
2720
          break;
2721
 
2722
        case spill_reg:
2723
        case spill_sprel:
2724
        case spill_psprel:
2725
        case spill_reg_p:
2726
        case spill_sprel_p:
2727
        case spill_psprel_p:
2728
          ptr->r.record.x.t = t;
2729
          break;
2730
 
2731
        case frgr_mem:
2732
          if (!region)
2733
            {
2734
              as_bad (_("frgr_mem record before region record!"));
2735
              return;
2736
            }
2737
          region->r.record.r.mask.fr_mem |= ptr->r.record.p.frmask;
2738
          region->r.record.r.mask.gr_mem |= ptr->r.record.p.grmask;
2739
          set_imask (region, ptr->r.record.p.frmask, t, 1);
2740
          set_imask (region, ptr->r.record.p.grmask, t, 2);
2741
          break;
2742
        case fr_mem:
2743
          if (!region)
2744
            {
2745
              as_bad (_("fr_mem record before region record!"));
2746
              return;
2747
            }
2748
          region->r.record.r.mask.fr_mem |= ptr->r.record.p.frmask;
2749
          set_imask (region, ptr->r.record.p.frmask, t, 1);
2750
          break;
2751
        case gr_mem:
2752
          if (!region)
2753
            {
2754
              as_bad (_("gr_mem record before region record!"));
2755
              return;
2756
            }
2757
          region->r.record.r.mask.gr_mem |= ptr->r.record.p.grmask;
2758
          set_imask (region, ptr->r.record.p.grmask, t, 2);
2759
          break;
2760
        case br_mem:
2761
          if (!region)
2762
            {
2763
              as_bad (_("br_mem record before region record!"));
2764
              return;
2765
            }
2766
          region->r.record.r.mask.br_mem |= ptr->r.record.p.brmask;
2767
          set_imask (region, ptr->r.record.p.brmask, t, 3);
2768
          break;
2769
 
2770
        case gr_gr:
2771
          if (!region)
2772
            {
2773
              as_bad (_("gr_gr record before region record!"));
2774
              return;
2775
            }
2776
          set_imask (region, ptr->r.record.p.grmask, t, 2);
2777
          break;
2778
        case br_gr:
2779
          if (!region)
2780
            {
2781
              as_bad (_("br_gr record before region record!"));
2782
              return;
2783
            }
2784
          set_imask (region, ptr->r.record.p.brmask, t, 3);
2785
          break;
2786
 
2787
        default:
2788
          break;
2789
        }
2790
    }
2791
}
2792
 
2793
/* Estimate the size of a frag before relaxing.  We only have one type of frag
2794
   to handle here, which is the unwind info frag.  */
2795
 
2796
int
2797
ia64_estimate_size_before_relax (fragS *frag,
2798
                                 asection *segtype ATTRIBUTE_UNUSED)
2799
{
2800
  unw_rec_list *list;
2801
  int len, size, pad;
2802
 
2803
  /* ??? This code is identical to the first part of ia64_convert_frag.  */
2804
  list = (unw_rec_list *) frag->fr_opcode;
2805
  fixup_unw_records (list, 0);
2806
 
2807
  len = calc_record_size (list);
2808
  /* pad to pointer-size boundary.  */
2809
  pad = len % md.pointer_size;
2810
  if (pad != 0)
2811
    len += md.pointer_size - pad;
2812
  /* Add 8 for the header.  */
2813
  size = len + 8;
2814
  /* Add a pointer for the personality offset.  */
2815
  if (frag->fr_offset)
2816
    size += md.pointer_size;
2817
 
2818
  /* fr_var carries the max_chars that we created the fragment with.
2819
     We must, of course, have allocated enough memory earlier.  */
2820
  gas_assert (frag->fr_var >= size);
2821
 
2822
  return frag->fr_fix + size;
2823
}
2824
 
2825
/* This function converts a rs_machine_dependent variant frag into a
2826
  normal fill frag with the unwind image from the the record list.  */
2827
void
2828
ia64_convert_frag (fragS *frag)
2829
{
2830
  unw_rec_list *list;
2831
  int len, size, pad;
2832
  valueT flag_value;
2833
 
2834
  /* ??? This code is identical to ia64_estimate_size_before_relax.  */
2835
  list = (unw_rec_list *) frag->fr_opcode;
2836
  fixup_unw_records (list, 0);
2837
 
2838
  len = calc_record_size (list);
2839
  /* pad to pointer-size boundary.  */
2840
  pad = len % md.pointer_size;
2841
  if (pad != 0)
2842
    len += md.pointer_size - pad;
2843
  /* Add 8 for the header.  */
2844
  size = len + 8;
2845
  /* Add a pointer for the personality offset.  */
2846
  if (frag->fr_offset)
2847
    size += md.pointer_size;
2848
 
2849
  /* fr_var carries the max_chars that we created the fragment with.
2850
     We must, of course, have allocated enough memory earlier.  */
2851
  gas_assert (frag->fr_var >= size);
2852
 
2853
  /* Initialize the header area. fr_offset is initialized with
2854
     unwind.personality_routine.  */
2855
  if (frag->fr_offset)
2856
    {
2857
      if (md.flags & EF_IA_64_ABI64)
2858
        flag_value = (bfd_vma) 3 << 32;
2859
      else
2860
        /* 32-bit unwind info block.  */
2861
        flag_value = (bfd_vma) 0x1003 << 32;
2862
    }
2863
  else
2864
    flag_value = 0;
2865
 
2866
 md_number_to_chars (frag->fr_literal,
2867
                     (((bfd_vma) 1 << 48) /* Version.  */
2868
                      | flag_value        /* U & E handler flags.  */
2869
                      | (len / md.pointer_size)), /* Length.  */
2870
                     8);
2871
 
2872
  /* Skip the header.  */
2873
  vbyte_mem_ptr = frag->fr_literal + 8;
2874
  process_unw_records (list, output_vbyte_mem);
2875
 
2876
  /* Fill the padding bytes with zeros.  */
2877
  if (pad != 0)
2878
    md_number_to_chars (frag->fr_literal + len + 8 - md.pointer_size + pad, 0,
2879
                        md.pointer_size - pad);
2880
  /* Fill the unwind personality with zeros.  */
2881
  if (frag->fr_offset)
2882
    md_number_to_chars (frag->fr_literal + size - md.pointer_size, 0,
2883
                        md.pointer_size);
2884
 
2885
  frag->fr_fix += size;
2886
  frag->fr_type = rs_fill;
2887
  frag->fr_var = 0;
2888
  frag->fr_offset = 0;
2889
}
2890
 
2891
static int
2892
parse_predicate_and_operand (expressionS *e, unsigned *qp, const char *po)
2893
{
2894
  int sep = parse_operand_and_eval (e, ',');
2895
 
2896
  *qp = e->X_add_number - REG_P;
2897
  if (e->X_op != O_register || *qp > 63)
2898
    {
2899
      as_bad (_("First operand to .%s must be a predicate"), po);
2900
      *qp = 0;
2901
    }
2902
  else if (*qp == 0)
2903
    as_warn (_("Pointless use of p0 as first operand to .%s"), po);
2904
  if (sep == ',')
2905
    sep = parse_operand_and_eval (e, ',');
2906
  else
2907
    e->X_op = O_absent;
2908
  return sep;
2909
}
2910
 
2911
static void
2912
convert_expr_to_ab_reg (const expressionS *e,
2913
                        unsigned int *ab,
2914
                        unsigned int *regp,
2915
                        const char *po,
2916
                        int n)
2917
{
2918
  unsigned int reg = e->X_add_number;
2919
 
2920
  *ab = *regp = 0; /* Anything valid is good here.  */
2921
 
2922
  if (e->X_op != O_register)
2923
    reg = REG_GR; /* Anything invalid is good here.  */
2924
 
2925
  if (reg >= (REG_GR + 4) && reg <= (REG_GR + 7))
2926
    {
2927
      *ab = 0;
2928
      *regp = reg - REG_GR;
2929
    }
2930
  else if ((reg >= (REG_FR + 2) && reg <= (REG_FR + 5))
2931
           || (reg >= (REG_FR + 16) && reg <= (REG_FR + 31)))
2932
    {
2933
      *ab = 1;
2934
      *regp = reg - REG_FR;
2935
    }
2936
  else if (reg >= (REG_BR + 1) && reg <= (REG_BR + 5))
2937
    {
2938
      *ab = 2;
2939
      *regp = reg - REG_BR;
2940
    }
2941
  else
2942
    {
2943
      *ab = 3;
2944
      switch (reg)
2945
        {
2946
        case REG_PR:            *regp =  0; break;
2947
        case REG_PSP:           *regp =  1; break;
2948
        case REG_PRIUNAT:       *regp =  2; break;
2949
        case REG_BR + 0: *regp =  3; break;
2950
        case REG_AR + AR_BSP:   *regp =  4; break;
2951
        case REG_AR + AR_BSPSTORE: *regp = 5; break;
2952
        case REG_AR + AR_RNAT:  *regp =  6; break;
2953
        case REG_AR + AR_UNAT:  *regp =  7; break;
2954
        case REG_AR + AR_FPSR:  *regp =  8; break;
2955
        case REG_AR + AR_PFS:   *regp =  9; break;
2956
        case REG_AR + AR_LC:    *regp = 10; break;
2957
 
2958
        default:
2959
          as_bad (_("Operand %d to .%s must be a preserved register"), n, po);
2960
          break;
2961
        }
2962
    }
2963
}
2964
 
2965
static void
2966
convert_expr_to_xy_reg (const expressionS *e,
2967
                        unsigned int *xy,
2968
                        unsigned int *regp,
2969
                        const char *po,
2970
                        int n)
2971
{
2972
  unsigned int reg = e->X_add_number;
2973
 
2974
  *xy = *regp = 0; /* Anything valid is good here.  */
2975
 
2976
  if (e->X_op != O_register)
2977
    reg = REG_GR; /* Anything invalid is good here.  */
2978
 
2979
  if (reg >= (REG_GR + 1) && reg <= (REG_GR + 127))
2980
    {
2981
      *xy = 0;
2982
      *regp = reg - REG_GR;
2983
    }
2984
  else if (reg >= (REG_FR + 2) && reg <= (REG_FR + 127))
2985
    {
2986
      *xy = 1;
2987
      *regp = reg - REG_FR;
2988
    }
2989
  else if (reg >= REG_BR && reg <= (REG_BR + 7))
2990
    {
2991
      *xy = 2;
2992
      *regp = reg - REG_BR;
2993
    }
2994
  else
2995
    as_bad (_("Operand %d to .%s must be a writable register"), n, po);
2996
}
2997
 
2998
static void
2999
dot_align (int arg)
3000
{
3001
  /* The current frag is an alignment frag.  */
3002
  align_frag = frag_now;
3003
  s_align_bytes (arg);
3004
}
3005
 
3006
static void
3007
dot_radix (int dummy ATTRIBUTE_UNUSED)
3008
{
3009
  char *radix;
3010
  int ch;
3011
 
3012
  SKIP_WHITESPACE ();
3013
 
3014
  if (is_it_end_of_statement ())
3015
    return;
3016
  radix = input_line_pointer;
3017
  ch = get_symbol_end ();
3018
  ia64_canonicalize_symbol_name (radix);
3019
  if (strcasecmp (radix, "C"))
3020
    as_bad (_("Radix `%s' unsupported or invalid"), radix);
3021
  *input_line_pointer = ch;
3022
  demand_empty_rest_of_line ();
3023
}
3024
 
3025
/* Helper function for .loc directives.  If the assembler is not generating
3026
   line number info, then we need to remember which instructions have a .loc
3027
   directive, and only call dwarf2_gen_line_info for those instructions.  */
3028
 
3029
static void
3030
dot_loc (int x)
3031
{
3032
  CURR_SLOT.loc_directive_seen = 1;
3033
  dwarf2_directive_loc (x);
3034
}
3035
 
3036
/* .sbss, .bss etc. are macros that expand into ".section SECNAME".  */
3037
static void
3038
dot_special_section (int which)
3039
{
3040
  set_section ((char *) special_section_name[which]);
3041
}
3042
 
3043
/* Return -1 for warning and 0 for error.  */
3044
 
3045
static int
3046
unwind_diagnostic (const char * region, const char *directive)
3047
{
3048
  if (md.unwind_check == unwind_check_warning)
3049
    {
3050
      as_warn (_(".%s outside of %s"), directive, region);
3051
      return -1;
3052
    }
3053
  else
3054
    {
3055
      as_bad (_(".%s outside of %s"), directive, region);
3056
      ignore_rest_of_line ();
3057
      return 0;
3058
    }
3059
}
3060
 
3061
/* Return 1 if a directive is in a procedure, -1 if a directive isn't in
3062
   a procedure but the unwind directive check is set to warning, 0 if
3063
   a directive isn't in a procedure and the unwind directive check is set
3064
   to error.  */
3065
 
3066
static int
3067
in_procedure (const char *directive)
3068
{
3069
  if (unwind.proc_pending.sym
3070
      && (!unwind.saved_text_seg || strcmp (directive, "endp") == 0))
3071
    return 1;
3072
  return unwind_diagnostic ("procedure", directive);
3073
}
3074
 
3075
/* Return 1 if a directive is in a prologue, -1 if a directive isn't in
3076
   a prologue but the unwind directive check is set to warning, 0 if
3077
   a directive isn't in a prologue and the unwind directive check is set
3078
   to error.  */
3079
 
3080
static int
3081
in_prologue (const char *directive)
3082
{
3083
  int in = in_procedure (directive);
3084
 
3085
  if (in > 0 && !unwind.prologue)
3086
    in = unwind_diagnostic ("prologue", directive);
3087
  check_pending_save ();
3088
  return in;
3089
}
3090
 
3091
/* Return 1 if a directive is in a body, -1 if a directive isn't in
3092
   a body but the unwind directive check is set to warning, 0 if
3093
   a directive isn't in a body and the unwind directive check is set
3094
   to error.  */
3095
 
3096
static int
3097
in_body (const char *directive)
3098
{
3099
  int in = in_procedure (directive);
3100
 
3101
  if (in > 0 && !unwind.body)
3102
    in = unwind_diagnostic ("body region", directive);
3103
  return in;
3104
}
3105
 
3106
static void
3107
add_unwind_entry (unw_rec_list *ptr, int sep)
3108
{
3109
  if (ptr)
3110
    {
3111
      if (unwind.tail)
3112
        unwind.tail->next = ptr;
3113
      else
3114
        unwind.list = ptr;
3115
      unwind.tail = ptr;
3116
 
3117
      /* The current entry can in fact be a chain of unwind entries.  */
3118
      if (unwind.current_entry == NULL)
3119
        unwind.current_entry = ptr;
3120
    }
3121
 
3122
  /* The current entry can in fact be a chain of unwind entries.  */
3123
  if (unwind.current_entry == NULL)
3124
    unwind.current_entry = ptr;
3125
 
3126
  if (sep == ',')
3127
    {
3128
      /* Parse a tag permitted for the current directive.  */
3129
      int ch;
3130
 
3131
      SKIP_WHITESPACE ();
3132
      ch = get_symbol_end ();
3133
      /* FIXME: For now, just issue a warning that this isn't implemented.  */
3134
      {
3135
        static int warned;
3136
 
3137
        if (!warned)
3138
          {
3139
            warned = 1;
3140
            as_warn (_("Tags on unwind pseudo-ops aren't supported, yet"));
3141
          }
3142
      }
3143
      *input_line_pointer = ch;
3144
    }
3145
  if (sep != NOT_A_CHAR)
3146
    demand_empty_rest_of_line ();
3147
}
3148
 
3149
static void
3150
dot_fframe (int dummy ATTRIBUTE_UNUSED)
3151
{
3152
  expressionS e;
3153
  int sep;
3154
 
3155
  if (!in_prologue ("fframe"))
3156
    return;
3157
 
3158
  sep = parse_operand_and_eval (&e, ',');
3159
 
3160
  if (e.X_op != O_constant)
3161
    {
3162
      as_bad (_("First operand to .fframe must be a constant"));
3163
      e.X_add_number = 0;
3164
    }
3165
  add_unwind_entry (output_mem_stack_f (e.X_add_number), sep);
3166
}
3167
 
3168
static void
3169
dot_vframe (int dummy ATTRIBUTE_UNUSED)
3170
{
3171
  expressionS e;
3172
  unsigned reg;
3173
  int sep;
3174
 
3175
  if (!in_prologue ("vframe"))
3176
    return;
3177
 
3178
  sep = parse_operand_and_eval (&e, ',');
3179
  reg = e.X_add_number - REG_GR;
3180
  if (e.X_op != O_register || reg > 127)
3181
    {
3182
      as_bad (_("First operand to .vframe must be a general register"));
3183
      reg = 0;
3184
    }
3185
  add_unwind_entry (output_mem_stack_v (), sep);
3186
  if (! (unwind.prologue_mask & 2))
3187
    add_unwind_entry (output_psp_gr (reg), NOT_A_CHAR);
3188
  else if (reg != unwind.prologue_gr
3189
                  + (unsigned) popcount (unwind.prologue_mask & (-2 << 1)))
3190
    as_warn (_("Operand of .vframe contradicts .prologue"));
3191
}
3192
 
3193
static void
3194
dot_vframesp (int psp)
3195
{
3196
  expressionS e;
3197
  int sep;
3198
 
3199
  if (psp)
3200
    as_warn (_(".vframepsp is meaningless, assuming .vframesp was meant"));
3201
 
3202
  if (!in_prologue ("vframesp"))
3203
    return;
3204
 
3205
  sep = parse_operand_and_eval (&e, ',');
3206
  if (e.X_op != O_constant)
3207
    {
3208
      as_bad (_("Operand to .vframesp must be a constant (sp-relative offset)"));
3209
      e.X_add_number = 0;
3210
    }
3211
  add_unwind_entry (output_mem_stack_v (), sep);
3212
  add_unwind_entry (output_psp_sprel (e.X_add_number), NOT_A_CHAR);
3213
}
3214
 
3215
static void
3216
dot_save (int dummy ATTRIBUTE_UNUSED)
3217
{
3218
  expressionS e1, e2;
3219
  unsigned reg1, reg2;
3220
  int sep;
3221
 
3222
  if (!in_prologue ("save"))
3223
    return;
3224
 
3225
  sep = parse_operand_and_eval (&e1, ',');
3226
  if (sep == ',')
3227
    sep = parse_operand_and_eval (&e2, ',');
3228
  else
3229
    e2.X_op = O_absent;
3230
 
3231
  reg1 = e1.X_add_number;
3232
  /* Make sure its a valid ar.xxx reg, OR its br0, aka 'rp'.  */
3233
  if (e1.X_op != O_register)
3234
    {
3235
      as_bad (_("First operand to .save not a register"));
3236
      reg1 = REG_PR; /* Anything valid is good here.  */
3237
    }
3238
  reg2 = e2.X_add_number - REG_GR;
3239
  if (e2.X_op != O_register || reg2 > 127)
3240
    {
3241
      as_bad (_("Second operand to .save not a valid register"));
3242
      reg2 = 0;
3243
    }
3244
  switch (reg1)
3245
    {
3246
    case REG_AR + AR_BSP:
3247
      add_unwind_entry (output_bsp_when (), sep);
3248
      add_unwind_entry (output_bsp_gr (reg2), NOT_A_CHAR);
3249
      break;
3250
    case REG_AR + AR_BSPSTORE:
3251
      add_unwind_entry (output_bspstore_when (), sep);
3252
      add_unwind_entry (output_bspstore_gr (reg2), NOT_A_CHAR);
3253
      break;
3254
    case REG_AR + AR_RNAT:
3255
      add_unwind_entry (output_rnat_when (), sep);
3256
      add_unwind_entry (output_rnat_gr (reg2), NOT_A_CHAR);
3257
      break;
3258
    case REG_AR + AR_UNAT:
3259
      add_unwind_entry (output_unat_when (), sep);
3260
      add_unwind_entry (output_unat_gr (reg2), NOT_A_CHAR);
3261
      break;
3262
    case REG_AR + AR_FPSR:
3263
      add_unwind_entry (output_fpsr_when (), sep);
3264
      add_unwind_entry (output_fpsr_gr (reg2), NOT_A_CHAR);
3265
      break;
3266
    case REG_AR + AR_PFS:
3267
      add_unwind_entry (output_pfs_when (), sep);
3268
      if (! (unwind.prologue_mask & 4))
3269
        add_unwind_entry (output_pfs_gr (reg2), NOT_A_CHAR);
3270
      else if (reg2 != unwind.prologue_gr
3271
                       + (unsigned) popcount (unwind.prologue_mask & (-4 << 1)))
3272
        as_warn (_("Second operand of .save contradicts .prologue"));
3273
      break;
3274
    case REG_AR + AR_LC:
3275
      add_unwind_entry (output_lc_when (), sep);
3276
      add_unwind_entry (output_lc_gr (reg2), NOT_A_CHAR);
3277
      break;
3278
    case REG_BR:
3279
      add_unwind_entry (output_rp_when (), sep);
3280
      if (! (unwind.prologue_mask & 8))
3281
        add_unwind_entry (output_rp_gr (reg2), NOT_A_CHAR);
3282
      else if (reg2 != unwind.prologue_gr)
3283
        as_warn (_("Second operand of .save contradicts .prologue"));
3284
      break;
3285
    case REG_PR:
3286
      add_unwind_entry (output_preds_when (), sep);
3287
      if (! (unwind.prologue_mask & 1))
3288
        add_unwind_entry (output_preds_gr (reg2), NOT_A_CHAR);
3289
      else if (reg2 != unwind.prologue_gr
3290
                       + (unsigned) popcount (unwind.prologue_mask & (-1 << 1)))
3291
        as_warn (_("Second operand of .save contradicts .prologue"));
3292
      break;
3293
    case REG_PRIUNAT:
3294
      add_unwind_entry (output_priunat_when_gr (), sep);
3295
      add_unwind_entry (output_priunat_gr (reg2), NOT_A_CHAR);
3296
      break;
3297
    default:
3298
      as_bad (_("First operand to .save not a valid register"));
3299
      add_unwind_entry (NULL, sep);
3300
      break;
3301
    }
3302
}
3303
 
3304
static void
3305
dot_restore (int dummy ATTRIBUTE_UNUSED)
3306
{
3307
  expressionS e1;
3308
  unsigned long ecount; /* # of _additional_ regions to pop */
3309
  int sep;
3310
 
3311
  if (!in_body ("restore"))
3312
    return;
3313
 
3314
  sep = parse_operand_and_eval (&e1, ',');
3315
  if (e1.X_op != O_register || e1.X_add_number != REG_GR + 12)
3316
    as_bad (_("First operand to .restore must be stack pointer (sp)"));
3317
 
3318
  if (sep == ',')
3319
    {
3320
      expressionS e2;
3321
 
3322
      sep = parse_operand_and_eval (&e2, ',');
3323
      if (e2.X_op != O_constant || e2.X_add_number < 0)
3324
        {
3325
          as_bad (_("Second operand to .restore must be a constant >= 0"));
3326
          e2.X_add_number = 0;
3327
        }
3328
      ecount = e2.X_add_number;
3329
    }
3330
  else
3331
    ecount = unwind.prologue_count - 1;
3332
 
3333
  if (ecount >= unwind.prologue_count)
3334
    {
3335
      as_bad (_("Epilogue count of %lu exceeds number of nested prologues (%u)"),
3336
              ecount + 1, unwind.prologue_count);
3337
      ecount = 0;
3338
    }
3339
 
3340
  add_unwind_entry (output_epilogue (ecount), sep);
3341
 
3342
  if (ecount < unwind.prologue_count)
3343
    unwind.prologue_count -= ecount + 1;
3344
  else
3345
    unwind.prologue_count = 0;
3346
}
3347
 
3348
static void
3349
dot_restorereg (int pred)
3350
{
3351
  unsigned int qp, ab, reg;
3352
  expressionS e;
3353
  int sep;
3354
  const char * const po = pred ? "restorereg.p" : "restorereg";
3355
 
3356
  if (!in_procedure (po))
3357
    return;
3358
 
3359
  if (pred)
3360
    sep = parse_predicate_and_operand (&e, &qp, po);
3361
  else
3362
    {
3363
      sep = parse_operand_and_eval (&e, ',');
3364
      qp = 0;
3365
    }
3366
  convert_expr_to_ab_reg (&e, &ab, &reg, po, 1 + pred);
3367
 
3368
  add_unwind_entry (output_spill_reg (ab, reg, 0, 0, qp), sep);
3369
}
3370
 
3371
static char *special_linkonce_name[] =
3372
  {
3373
    ".gnu.linkonce.ia64unw.", ".gnu.linkonce.ia64unwi."
3374
  };
3375
 
3376
static void
3377
start_unwind_section (const segT text_seg, int sec_index)
3378
{
3379
  /*
3380
    Use a slightly ugly scheme to derive the unwind section names from
3381
    the text section name:
3382
 
3383
    text sect.  unwind table sect.
3384
    name:       name:                      comments:
3385
    ----------  -----------------          --------------------------------
3386
    .text       .IA_64.unwind
3387
    .text.foo   .IA_64.unwind.text.foo
3388
    .foo        .IA_64.unwind.foo
3389
    .gnu.linkonce.t.foo
3390
                .gnu.linkonce.ia64unw.foo
3391
    _info       .IA_64.unwind_info         gas issues error message (ditto)
3392
    _infoFOO    .IA_64.unwind_infoFOO      gas issues error message (ditto)
3393
 
3394
    This mapping is done so that:
3395
 
3396
        (a) An object file with unwind info only in .text will use
3397
            unwind section names .IA_64.unwind and .IA_64.unwind_info.
3398
            This follows the letter of the ABI and also ensures backwards
3399
            compatibility with older toolchains.
3400
 
3401
        (b) An object file with unwind info in multiple text sections
3402
            will use separate unwind sections for each text section.
3403
            This allows us to properly set the "sh_info" and "sh_link"
3404
            fields in SHT_IA_64_UNWIND as required by the ABI and also
3405
            lets GNU ld support programs with multiple segments
3406
            containing unwind info (as might be the case for certain
3407
            embedded applications).
3408
 
3409
        (c) An error is issued if there would be a name clash.
3410
  */
3411
 
3412
  const char *text_name, *sec_text_name;
3413
  char *sec_name;
3414
  const char *prefix = special_section_name [sec_index];
3415
  const char *suffix;
3416
  size_t prefix_len, suffix_len, sec_name_len;
3417
 
3418
  sec_text_name = segment_name (text_seg);
3419
  text_name = sec_text_name;
3420
  if (strncmp (text_name, "_info", 5) == 0)
3421
    {
3422
      as_bad (_("Illegal section name `%s' (causes unwind section name clash)"),
3423
              text_name);
3424
      ignore_rest_of_line ();
3425
      return;
3426
    }
3427
  if (strcmp (text_name, ".text") == 0)
3428
    text_name = "";
3429
 
3430
  /* Build the unwind section name by appending the (possibly stripped)
3431
     text section name to the unwind prefix.  */
3432
  suffix = text_name;
3433
  if (strncmp (text_name, ".gnu.linkonce.t.",
3434
               sizeof (".gnu.linkonce.t.") - 1) == 0)
3435
    {
3436
      prefix = special_linkonce_name [sec_index - SPECIAL_SECTION_UNWIND];
3437
      suffix += sizeof (".gnu.linkonce.t.") - 1;
3438
    }
3439
 
3440
  prefix_len = strlen (prefix);
3441
  suffix_len = strlen (suffix);
3442
  sec_name_len = prefix_len + suffix_len;
3443
  sec_name = alloca (sec_name_len + 1);
3444
  memcpy (sec_name, prefix, prefix_len);
3445
  memcpy (sec_name + prefix_len, suffix, suffix_len);
3446
  sec_name [sec_name_len] = '\0';
3447
 
3448
  /* Handle COMDAT group.  */
3449
  if ((text_seg->flags & SEC_LINK_ONCE) != 0
3450
      && (elf_section_flags (text_seg) & SHF_GROUP) != 0)
3451
    {
3452
      char *section;
3453
      size_t len, group_name_len;
3454
      const char *group_name = elf_group_name (text_seg);
3455
 
3456
      if (group_name == NULL)
3457
        {
3458
          as_bad (_("Group section `%s' has no group signature"),
3459
                  sec_text_name);
3460
          ignore_rest_of_line ();
3461
          return;
3462
        }
3463
      /* We have to construct a fake section directive. */
3464
      group_name_len = strlen (group_name);
3465
      len = (sec_name_len
3466
             + 16                       /* ,"aG",@progbits,  */
3467
             + group_name_len           /* ,group_name  */
3468
             + 7);                      /* ,comdat  */
3469
 
3470
      section = alloca (len + 1);
3471
      memcpy (section, sec_name, sec_name_len);
3472
      memcpy (section + sec_name_len, ",\"aG\",@progbits,", 16);
3473
      memcpy (section + sec_name_len + 16, group_name, group_name_len);
3474
      memcpy (section + len - 7, ",comdat", 7);
3475
      section [len] = '\0';
3476
      set_section (section);
3477
    }
3478
  else
3479
    {
3480
      set_section (sec_name);
3481
      bfd_set_section_flags (stdoutput, now_seg,
3482
                             SEC_LOAD | SEC_ALLOC | SEC_READONLY);
3483
    }
3484
 
3485
  elf_linked_to_section (now_seg) = text_seg;
3486
}
3487
 
3488
static void
3489
generate_unwind_image (const segT text_seg)
3490
{
3491
  int size, pad;
3492
  unw_rec_list *list;
3493
 
3494
  /* Mark the end of the unwind info, so that we can compute the size of the
3495
     last unwind region.  */
3496
  add_unwind_entry (output_endp (), NOT_A_CHAR);
3497
 
3498
  /* Force out pending instructions, to make sure all unwind records have
3499
     a valid slot_number field.  */
3500
  ia64_flush_insns ();
3501
 
3502
  /* Generate the unwind record.  */
3503
  list = optimize_unw_records (unwind.list);
3504
  fixup_unw_records (list, 1);
3505
  size = calc_record_size (list);
3506
 
3507
  if (size > 0 || unwind.force_unwind_entry)
3508
    {
3509
      unwind.force_unwind_entry = 0;
3510
      /* pad to pointer-size boundary.  */
3511
      pad = size % md.pointer_size;
3512
      if (pad != 0)
3513
        size += md.pointer_size - pad;
3514
      /* Add 8 for the header.  */
3515
      size += 8;
3516
      /* Add a pointer for the personality offset.  */
3517
      if (unwind.personality_routine)
3518
        size += md.pointer_size;
3519
    }
3520
 
3521
  /* If there are unwind records, switch sections, and output the info.  */
3522
  if (size != 0)
3523
    {
3524
      expressionS exp;
3525
      bfd_reloc_code_real_type reloc;
3526
 
3527
      start_unwind_section (text_seg, SPECIAL_SECTION_UNWIND_INFO);
3528
 
3529
      /* Make sure the section has 4 byte alignment for ILP32 and
3530
         8 byte alignment for LP64.  */
3531
      frag_align (md.pointer_size_shift, 0, 0);
3532
      record_alignment (now_seg, md.pointer_size_shift);
3533
 
3534
      /* Set expression which points to start of unwind descriptor area.  */
3535
      unwind.info = expr_build_dot ();
3536
 
3537
      frag_var (rs_machine_dependent, size, size, 0, 0,
3538
                (offsetT) (long) unwind.personality_routine,
3539
                (char *) list);
3540
 
3541
      /* Add the personality address to the image.  */
3542
      if (unwind.personality_routine != 0)
3543
        {
3544
          exp.X_op = O_symbol;
3545
          exp.X_add_symbol = unwind.personality_routine;
3546
          exp.X_add_number = 0;
3547
 
3548
          if (md.flags & EF_IA_64_BE)
3549
            {
3550
              if (md.flags & EF_IA_64_ABI64)
3551
                reloc = BFD_RELOC_IA64_LTOFF_FPTR64MSB;
3552
              else
3553
                reloc = BFD_RELOC_IA64_LTOFF_FPTR32MSB;
3554
            }
3555
          else
3556
            {
3557
              if (md.flags & EF_IA_64_ABI64)
3558
                reloc = BFD_RELOC_IA64_LTOFF_FPTR64LSB;
3559
              else
3560
                reloc = BFD_RELOC_IA64_LTOFF_FPTR32LSB;
3561
            }
3562
 
3563
          fix_new_exp (frag_now, frag_now_fix () - md.pointer_size,
3564
                       md.pointer_size, &exp, 0, reloc);
3565
          unwind.personality_routine = 0;
3566
        }
3567
    }
3568
 
3569
  free_saved_prologue_counts ();
3570
  unwind.list = unwind.tail = unwind.current_entry = NULL;
3571
}
3572
 
3573
static void
3574
dot_handlerdata (int dummy ATTRIBUTE_UNUSED)
3575
{
3576
  if (!in_procedure ("handlerdata"))
3577
    return;
3578
  unwind.force_unwind_entry = 1;
3579
 
3580
  /* Remember which segment we're in so we can switch back after .endp */
3581
  unwind.saved_text_seg = now_seg;
3582
  unwind.saved_text_subseg = now_subseg;
3583
 
3584
  /* Generate unwind info into unwind-info section and then leave that
3585
     section as the currently active one so dataXX directives go into
3586
     the language specific data area of the unwind info block.  */
3587
  generate_unwind_image (now_seg);
3588
  demand_empty_rest_of_line ();
3589
}
3590
 
3591
static void
3592
dot_unwentry (int dummy ATTRIBUTE_UNUSED)
3593
{
3594
  if (!in_procedure ("unwentry"))
3595
    return;
3596
  unwind.force_unwind_entry = 1;
3597
  demand_empty_rest_of_line ();
3598
}
3599
 
3600
static void
3601
dot_altrp (int dummy ATTRIBUTE_UNUSED)
3602
{
3603
  expressionS e;
3604
  unsigned reg;
3605
 
3606
  if (!in_prologue ("altrp"))
3607
    return;
3608
 
3609
  parse_operand_and_eval (&e, 0);
3610
  reg = e.X_add_number - REG_BR;
3611
  if (e.X_op != O_register || reg > 7)
3612
    {
3613
      as_bad (_("First operand to .altrp not a valid branch register"));
3614
      reg = 0;
3615
    }
3616
  add_unwind_entry (output_rp_br (reg), 0);
3617
}
3618
 
3619
static void
3620
dot_savemem (int psprel)
3621
{
3622
  expressionS e1, e2;
3623
  int sep;
3624
  int reg1, val;
3625
  const char * const po = psprel ? "savepsp" : "savesp";
3626
 
3627
  if (!in_prologue (po))
3628
    return;
3629
 
3630
  sep = parse_operand_and_eval (&e1, ',');
3631
  if (sep == ',')
3632
    sep = parse_operand_and_eval (&e2, ',');
3633
  else
3634
    e2.X_op = O_absent;
3635
 
3636
  reg1 = e1.X_add_number;
3637
  val = e2.X_add_number;
3638
 
3639
  /* Make sure its a valid ar.xxx reg, OR its br0, aka 'rp'.  */
3640
  if (e1.X_op != O_register)
3641
    {
3642
      as_bad (_("First operand to .%s not a register"), po);
3643
      reg1 = REG_PR; /* Anything valid is good here.  */
3644
    }
3645
  if (e2.X_op != O_constant)
3646
    {
3647
      as_bad (_("Second operand to .%s not a constant"), po);
3648
      val = 0;
3649
    }
3650
 
3651
  switch (reg1)
3652
    {
3653
    case REG_AR + AR_BSP:
3654
      add_unwind_entry (output_bsp_when (), sep);
3655
      add_unwind_entry ((psprel
3656
                         ? output_bsp_psprel
3657
                         : output_bsp_sprel) (val), NOT_A_CHAR);
3658
      break;
3659
    case REG_AR + AR_BSPSTORE:
3660
      add_unwind_entry (output_bspstore_when (), sep);
3661
      add_unwind_entry ((psprel
3662
                         ? output_bspstore_psprel
3663
                         : output_bspstore_sprel) (val), NOT_A_CHAR);
3664
      break;
3665
    case REG_AR + AR_RNAT:
3666
      add_unwind_entry (output_rnat_when (), sep);
3667
      add_unwind_entry ((psprel
3668
                         ? output_rnat_psprel
3669
                         : output_rnat_sprel) (val), NOT_A_CHAR);
3670
      break;
3671
    case REG_AR + AR_UNAT:
3672
      add_unwind_entry (output_unat_when (), sep);
3673
      add_unwind_entry ((psprel
3674
                         ? output_unat_psprel
3675
                         : output_unat_sprel) (val), NOT_A_CHAR);
3676
      break;
3677
    case REG_AR + AR_FPSR:
3678
      add_unwind_entry (output_fpsr_when (), sep);
3679
      add_unwind_entry ((psprel
3680
                         ? output_fpsr_psprel
3681
                         : output_fpsr_sprel) (val), NOT_A_CHAR);
3682
      break;
3683
    case REG_AR + AR_PFS:
3684
      add_unwind_entry (output_pfs_when (), sep);
3685
      add_unwind_entry ((psprel
3686
                         ? output_pfs_psprel
3687
                         : output_pfs_sprel) (val), NOT_A_CHAR);
3688
      break;
3689
    case REG_AR + AR_LC:
3690
      add_unwind_entry (output_lc_when (), sep);
3691
      add_unwind_entry ((psprel
3692
                         ? output_lc_psprel
3693
                         : output_lc_sprel) (val), NOT_A_CHAR);
3694
      break;
3695
    case REG_BR:
3696
      add_unwind_entry (output_rp_when (), sep);
3697
      add_unwind_entry ((psprel
3698
                         ? output_rp_psprel
3699
                         : output_rp_sprel) (val), NOT_A_CHAR);
3700
      break;
3701
    case REG_PR:
3702
      add_unwind_entry (output_preds_when (), sep);
3703
      add_unwind_entry ((psprel
3704
                         ? output_preds_psprel
3705
                         : output_preds_sprel) (val), NOT_A_CHAR);
3706
      break;
3707
    case REG_PRIUNAT:
3708
      add_unwind_entry (output_priunat_when_mem (), sep);
3709
      add_unwind_entry ((psprel
3710
                         ? output_priunat_psprel
3711
                         : output_priunat_sprel) (val), NOT_A_CHAR);
3712
      break;
3713
    default:
3714
      as_bad (_("First operand to .%s not a valid register"), po);
3715
      add_unwind_entry (NULL, sep);
3716
      break;
3717
    }
3718
}
3719
 
3720
static void
3721
dot_saveg (int dummy ATTRIBUTE_UNUSED)
3722
{
3723
  expressionS e;
3724
  unsigned grmask;
3725
  int sep;
3726
 
3727
  if (!in_prologue ("save.g"))
3728
    return;
3729
 
3730
  sep = parse_operand_and_eval (&e, ',');
3731
 
3732
  grmask = e.X_add_number;
3733
  if (e.X_op != O_constant
3734
      || e.X_add_number <= 0
3735
      || e.X_add_number > 0xf)
3736
    {
3737
      as_bad (_("First operand to .save.g must be a positive 4-bit constant"));
3738
      grmask = 0;
3739
    }
3740
 
3741
  if (sep == ',')
3742
    {
3743
      unsigned reg;
3744
      int n = popcount (grmask);
3745
 
3746
      parse_operand_and_eval (&e, 0);
3747
      reg = e.X_add_number - REG_GR;
3748
      if (e.X_op != O_register || reg > 127)
3749
        {
3750
          as_bad (_("Second operand to .save.g must be a general register"));
3751
          reg = 0;
3752
        }
3753
      else if (reg > 128U - n)
3754
        {
3755
          as_bad (_("Second operand to .save.g must be the first of %d general registers"), n);
3756
          reg = 0;
3757
        }
3758
      add_unwind_entry (output_gr_gr (grmask, reg), 0);
3759
    }
3760
  else
3761
    add_unwind_entry (output_gr_mem (grmask), 0);
3762
}
3763
 
3764
static void
3765
dot_savef (int dummy ATTRIBUTE_UNUSED)
3766
{
3767
  expressionS e;
3768
 
3769
  if (!in_prologue ("save.f"))
3770
    return;
3771
 
3772
  parse_operand_and_eval (&e, 0);
3773
 
3774
  if (e.X_op != O_constant
3775
      || e.X_add_number <= 0
3776
      || e.X_add_number > 0xfffff)
3777
    {
3778
      as_bad (_("Operand to .save.f must be a positive 20-bit constant"));
3779
      e.X_add_number = 0;
3780
    }
3781
  add_unwind_entry (output_fr_mem (e.X_add_number), 0);
3782
}
3783
 
3784
static void
3785
dot_saveb (int dummy ATTRIBUTE_UNUSED)
3786
{
3787
  expressionS e;
3788
  unsigned brmask;
3789
  int sep;
3790
 
3791
  if (!in_prologue ("save.b"))
3792
    return;
3793
 
3794
  sep = parse_operand_and_eval (&e, ',');
3795
 
3796
  brmask = e.X_add_number;
3797
  if (e.X_op != O_constant
3798
      || e.X_add_number <= 0
3799
      || e.X_add_number > 0x1f)
3800
    {
3801
      as_bad (_("First operand to .save.b must be a positive 5-bit constant"));
3802
      brmask = 0;
3803
    }
3804
 
3805
  if (sep == ',')
3806
    {
3807
      unsigned reg;
3808
      int n = popcount (brmask);
3809
 
3810
      parse_operand_and_eval (&e, 0);
3811
      reg = e.X_add_number - REG_GR;
3812
      if (e.X_op != O_register || reg > 127)
3813
        {
3814
          as_bad (_("Second operand to .save.b must be a general register"));
3815
          reg = 0;
3816
        }
3817
      else if (reg > 128U - n)
3818
        {
3819
          as_bad (_("Second operand to .save.b must be the first of %d general registers"), n);
3820
          reg = 0;
3821
        }
3822
      add_unwind_entry (output_br_gr (brmask, reg), 0);
3823
    }
3824
  else
3825
    add_unwind_entry (output_br_mem (brmask), 0);
3826
}
3827
 
3828
static void
3829
dot_savegf (int dummy ATTRIBUTE_UNUSED)
3830
{
3831
  expressionS e1, e2;
3832
 
3833
  if (!in_prologue ("save.gf"))
3834
    return;
3835
 
3836
  if (parse_operand_and_eval (&e1, ',') == ',')
3837
    parse_operand_and_eval (&e2, 0);
3838
  else
3839
    e2.X_op = O_absent;
3840
 
3841
  if (e1.X_op != O_constant
3842
      || e1.X_add_number < 0
3843
      || e1.X_add_number > 0xf)
3844
    {
3845
      as_bad (_("First operand to .save.gf must be a non-negative 4-bit constant"));
3846
      e1.X_op = O_absent;
3847
      e1.X_add_number = 0;
3848
    }
3849
  if (e2.X_op != O_constant
3850
      || e2.X_add_number < 0
3851
      || e2.X_add_number > 0xfffff)
3852
    {
3853
      as_bad (_("Second operand to .save.gf must be a non-negative 20-bit constant"));
3854
      e2.X_op = O_absent;
3855
      e2.X_add_number = 0;
3856
    }
3857
  if (e1.X_op == O_constant
3858
      && e2.X_op == O_constant
3859
      && e1.X_add_number == 0
3860
      && e2.X_add_number == 0)
3861
    as_bad (_("Operands to .save.gf may not be both zero"));
3862
 
3863
  add_unwind_entry (output_frgr_mem (e1.X_add_number, e2.X_add_number), 0);
3864
}
3865
 
3866
static void
3867
dot_spill (int dummy ATTRIBUTE_UNUSED)
3868
{
3869
  expressionS e;
3870
 
3871
  if (!in_prologue ("spill"))
3872
    return;
3873
 
3874
  parse_operand_and_eval (&e, 0);
3875
 
3876
  if (e.X_op != O_constant)
3877
    {
3878
      as_bad (_("Operand to .spill must be a constant"));
3879
      e.X_add_number = 0;
3880
    }
3881
  add_unwind_entry (output_spill_base (e.X_add_number), 0);
3882
}
3883
 
3884
static void
3885
dot_spillreg (int pred)
3886
{
3887
  int sep;
3888
  unsigned int qp, ab, xy, reg, treg;
3889
  expressionS e;
3890
  const char * const po = pred ? "spillreg.p" : "spillreg";
3891
 
3892
  if (!in_procedure (po))
3893
    return;
3894
 
3895
  if (pred)
3896
    sep = parse_predicate_and_operand (&e, &qp, po);
3897
  else
3898
    {
3899
      sep = parse_operand_and_eval (&e, ',');
3900
      qp = 0;
3901
    }
3902
  convert_expr_to_ab_reg (&e, &ab, &reg, po, 1 + pred);
3903
 
3904
  if (sep == ',')
3905
    sep = parse_operand_and_eval (&e, ',');
3906
  else
3907
    e.X_op = O_absent;
3908
  convert_expr_to_xy_reg (&e, &xy, &treg, po, 2 + pred);
3909
 
3910
  add_unwind_entry (output_spill_reg (ab, reg, treg, xy, qp), sep);
3911
}
3912
 
3913
static void
3914
dot_spillmem (int psprel)
3915
{
3916
  expressionS e;
3917
  int pred = (psprel < 0), sep;
3918
  unsigned int qp, ab, reg;
3919
  const char * po;
3920
 
3921
  if (pred)
3922
    {
3923
      psprel = ~psprel;
3924
      po = psprel ? "spillpsp.p" : "spillsp.p";
3925
    }
3926
  else
3927
    po = psprel ? "spillpsp" : "spillsp";
3928
 
3929
  if (!in_procedure (po))
3930
    return;
3931
 
3932
  if (pred)
3933
    sep = parse_predicate_and_operand (&e, &qp, po);
3934
  else
3935
    {
3936
      sep = parse_operand_and_eval (&e, ',');
3937
      qp = 0;
3938
    }
3939
  convert_expr_to_ab_reg (&e, &ab, &reg, po, 1 + pred);
3940
 
3941
  if (sep == ',')
3942
    sep = parse_operand_and_eval (&e, ',');
3943
  else
3944
    e.X_op = O_absent;
3945
  if (e.X_op != O_constant)
3946
    {
3947
      as_bad (_("Operand %d to .%s must be a constant"), 2 + pred, po);
3948
      e.X_add_number = 0;
3949
    }
3950
 
3951
  if (psprel)
3952
    add_unwind_entry (output_spill_psprel (ab, reg, e.X_add_number, qp), sep);
3953
  else
3954
    add_unwind_entry (output_spill_sprel (ab, reg, e.X_add_number, qp), sep);
3955
}
3956
 
3957
static unsigned int
3958
get_saved_prologue_count (unsigned long lbl)
3959
{
3960
  label_prologue_count *lpc = unwind.saved_prologue_counts;
3961
 
3962
  while (lpc != NULL && lpc->label_number != lbl)
3963
    lpc = lpc->next;
3964
 
3965
  if (lpc != NULL)
3966
    return lpc->prologue_count;
3967
 
3968
  as_bad (_("Missing .label_state %ld"), lbl);
3969
  return 1;
3970
}
3971
 
3972
static void
3973
save_prologue_count (unsigned long lbl, unsigned int count)
3974
{
3975
  label_prologue_count *lpc = unwind.saved_prologue_counts;
3976
 
3977
  while (lpc != NULL && lpc->label_number != lbl)
3978
    lpc = lpc->next;
3979
 
3980
  if (lpc != NULL)
3981
    lpc->prologue_count = count;
3982
  else
3983
    {
3984
      label_prologue_count *new_lpc = xmalloc (sizeof (* new_lpc));
3985
 
3986
      new_lpc->next = unwind.saved_prologue_counts;
3987
      new_lpc->label_number = lbl;
3988
      new_lpc->prologue_count = count;
3989
      unwind.saved_prologue_counts = new_lpc;
3990
    }
3991
}
3992
 
3993
static void
3994
free_saved_prologue_counts ()
3995
{
3996
  label_prologue_count *lpc = unwind.saved_prologue_counts;
3997
  label_prologue_count *next;
3998
 
3999
  while (lpc != NULL)
4000
    {
4001
      next = lpc->next;
4002
      free (lpc);
4003
      lpc = next;
4004
    }
4005
 
4006
  unwind.saved_prologue_counts = NULL;
4007
}
4008
 
4009
static void
4010
dot_label_state (int dummy ATTRIBUTE_UNUSED)
4011
{
4012
  expressionS e;
4013
 
4014
  if (!in_body ("label_state"))
4015
    return;
4016
 
4017
  parse_operand_and_eval (&e, 0);
4018
  if (e.X_op == O_constant)
4019
    save_prologue_count (e.X_add_number, unwind.prologue_count);
4020
  else
4021
    {
4022
      as_bad (_("Operand to .label_state must be a constant"));
4023
      e.X_add_number = 0;
4024
    }
4025
  add_unwind_entry (output_label_state (e.X_add_number), 0);
4026
}
4027
 
4028
static void
4029
dot_copy_state (int dummy ATTRIBUTE_UNUSED)
4030
{
4031
  expressionS e;
4032
 
4033
  if (!in_body ("copy_state"))
4034
    return;
4035
 
4036
  parse_operand_and_eval (&e, 0);
4037
  if (e.X_op == O_constant)
4038
    unwind.prologue_count = get_saved_prologue_count (e.X_add_number);
4039
  else
4040
    {
4041
      as_bad (_("Operand to .copy_state must be a constant"));
4042
      e.X_add_number = 0;
4043
    }
4044
  add_unwind_entry (output_copy_state (e.X_add_number), 0);
4045
}
4046
 
4047
static void
4048
dot_unwabi (int dummy ATTRIBUTE_UNUSED)
4049
{
4050
  expressionS e1, e2;
4051
  unsigned char sep;
4052
 
4053
  if (!in_prologue ("unwabi"))
4054
    return;
4055
 
4056
  sep = parse_operand_and_eval (&e1, ',');
4057
  if (sep == ',')
4058
    parse_operand_and_eval (&e2, 0);
4059
  else
4060
    e2.X_op = O_absent;
4061
 
4062
  if (e1.X_op != O_constant)
4063
    {
4064
      as_bad (_("First operand to .unwabi must be a constant"));
4065
      e1.X_add_number = 0;
4066
    }
4067
 
4068
  if (e2.X_op != O_constant)
4069
    {
4070
      as_bad (_("Second operand to .unwabi must be a constant"));
4071
      e2.X_add_number = 0;
4072
    }
4073
 
4074
  add_unwind_entry (output_unwabi (e1.X_add_number, e2.X_add_number), 0);
4075
}
4076
 
4077
static void
4078
dot_personality (int dummy ATTRIBUTE_UNUSED)
4079
{
4080
  char *name, *p, c;
4081
  if (!in_procedure ("personality"))
4082
    return;
4083
  SKIP_WHITESPACE ();
4084
  name = input_line_pointer;
4085
  c = get_symbol_end ();
4086
  p = input_line_pointer;
4087
  unwind.personality_routine = symbol_find_or_make (name);
4088
  unwind.force_unwind_entry = 1;
4089
  *p = c;
4090
  SKIP_WHITESPACE ();
4091
  demand_empty_rest_of_line ();
4092
}
4093
 
4094
static void
4095
dot_proc (int dummy ATTRIBUTE_UNUSED)
4096
{
4097
  char *name, *p, c;
4098
  symbolS *sym;
4099
  proc_pending *pending, *last_pending;
4100
 
4101
  if (unwind.proc_pending.sym)
4102
    {
4103
      (md.unwind_check == unwind_check_warning
4104
       ? as_warn
4105
       : as_bad) (_("Missing .endp after previous .proc"));
4106
      while (unwind.proc_pending.next)
4107
        {
4108
          pending = unwind.proc_pending.next;
4109
          unwind.proc_pending.next = pending->next;
4110
          free (pending);
4111
        }
4112
    }
4113
  last_pending = NULL;
4114
 
4115
  /* Parse names of main and alternate entry points and mark them as
4116
     function symbols:  */
4117
  while (1)
4118
    {
4119
      SKIP_WHITESPACE ();
4120
      name = input_line_pointer;
4121
      c = get_symbol_end ();
4122
      p = input_line_pointer;
4123
      if (!*name)
4124
        as_bad (_("Empty argument of .proc"));
4125
      else
4126
        {
4127
          sym = symbol_find_or_make (name);
4128
          if (S_IS_DEFINED (sym))
4129
            as_bad (_("`%s' was already defined"), name);
4130
          else if (!last_pending)
4131
            {
4132
              unwind.proc_pending.sym = sym;
4133
              last_pending = &unwind.proc_pending;
4134
            }
4135
          else
4136
            {
4137
              pending = xmalloc (sizeof (*pending));
4138
              pending->sym = sym;
4139
              last_pending = last_pending->next = pending;
4140
            }
4141
          symbol_get_bfdsym (sym)->flags |= BSF_FUNCTION;
4142
        }
4143
      *p = c;
4144
      SKIP_WHITESPACE ();
4145
      if (*input_line_pointer != ',')
4146
        break;
4147
      ++input_line_pointer;
4148
    }
4149
  if (!last_pending)
4150
    {
4151
      unwind.proc_pending.sym = expr_build_dot ();
4152
      last_pending = &unwind.proc_pending;
4153
    }
4154
  last_pending->next = NULL;
4155
  demand_empty_rest_of_line ();
4156
  ia64_do_align (16);
4157
 
4158
  unwind.prologue = 0;
4159
  unwind.prologue_count = 0;
4160
  unwind.body = 0;
4161
  unwind.insn = 0;
4162
  unwind.list = unwind.tail = unwind.current_entry = NULL;
4163
  unwind.personality_routine = 0;
4164
}
4165
 
4166
static void
4167
dot_body (int dummy ATTRIBUTE_UNUSED)
4168
{
4169
  if (!in_procedure ("body"))
4170
    return;
4171
  if (!unwind.prologue && !unwind.body && unwind.insn)
4172
    as_warn (_("Initial .body should precede any instructions"));
4173
  check_pending_save ();
4174
 
4175
  unwind.prologue = 0;
4176
  unwind.prologue_mask = 0;
4177
  unwind.body = 1;
4178
 
4179
  add_unwind_entry (output_body (), 0);
4180
}
4181
 
4182
static void
4183
dot_prologue (int dummy ATTRIBUTE_UNUSED)
4184
{
4185
  unsigned mask = 0, grsave = 0;
4186
 
4187
  if (!in_procedure ("prologue"))
4188
    return;
4189
  if (unwind.prologue)
4190
    {
4191
      as_bad (_(".prologue within prologue"));
4192
      ignore_rest_of_line ();
4193
      return;
4194
    }
4195
  if (!unwind.body && unwind.insn)
4196
    as_warn (_("Initial .prologue should precede any instructions"));
4197
 
4198
  if (!is_it_end_of_statement ())
4199
    {
4200
      expressionS e;
4201
      int n, sep = parse_operand_and_eval (&e, ',');
4202
 
4203
      if (e.X_op != O_constant
4204
          || e.X_add_number < 0
4205
          || e.X_add_number > 0xf)
4206
        as_bad (_("First operand to .prologue must be a positive 4-bit constant"));
4207
      else if (e.X_add_number == 0)
4208
        as_warn (_("Pointless use of zero first operand to .prologue"));
4209
      else
4210
        mask = e.X_add_number;
4211
        n = popcount (mask);
4212
 
4213
      if (sep == ',')
4214
        parse_operand_and_eval (&e, 0);
4215
      else
4216
        e.X_op = O_absent;
4217
      if (e.X_op == O_constant
4218
          && e.X_add_number >= 0
4219
          && e.X_add_number < 128)
4220
        {
4221
          if (md.unwind_check == unwind_check_error)
4222
            as_warn (_("Using a constant as second operand to .prologue is deprecated"));
4223
          grsave = e.X_add_number;
4224
        }
4225
      else if (e.X_op != O_register
4226
               || (grsave = e.X_add_number - REG_GR) > 127)
4227
        {
4228
          as_bad (_("Second operand to .prologue must be a general register"));
4229
          grsave = 0;
4230
        }
4231
      else if (grsave > 128U - n)
4232
        {
4233
          as_bad (_("Second operand to .prologue must be the first of %d general registers"), n);
4234
          grsave = 0;
4235
        }
4236
 
4237
    }
4238
 
4239
  if (mask)
4240
    add_unwind_entry (output_prologue_gr (mask, grsave), 0);
4241
  else
4242
    add_unwind_entry (output_prologue (), 0);
4243
 
4244
  unwind.prologue = 1;
4245
  unwind.prologue_mask = mask;
4246
  unwind.prologue_gr = grsave;
4247
  unwind.body = 0;
4248
  ++unwind.prologue_count;
4249
}
4250
 
4251
static void
4252
dot_endp (int dummy ATTRIBUTE_UNUSED)
4253
{
4254
  expressionS e;
4255
  int bytes_per_address;
4256
  long where;
4257
  segT saved_seg;
4258
  subsegT saved_subseg;
4259
  proc_pending *pending;
4260
  int unwind_check = md.unwind_check;
4261
 
4262
  md.unwind_check = unwind_check_error;
4263
  if (!in_procedure ("endp"))
4264
    return;
4265
  md.unwind_check = unwind_check;
4266
 
4267
  if (unwind.saved_text_seg)
4268
    {
4269
      saved_seg = unwind.saved_text_seg;
4270
      saved_subseg = unwind.saved_text_subseg;
4271
      unwind.saved_text_seg = NULL;
4272
    }
4273
  else
4274
    {
4275
      saved_seg = now_seg;
4276
      saved_subseg = now_subseg;
4277
    }
4278
 
4279
  insn_group_break (1, 0, 0);
4280
 
4281
  /* If there wasn't a .handlerdata, we haven't generated an image yet.  */
4282
  if (!unwind.info)
4283
    generate_unwind_image (saved_seg);
4284
 
4285
  if (unwind.info || unwind.force_unwind_entry)
4286
    {
4287
      symbolS *proc_end;
4288
 
4289
      subseg_set (md.last_text_seg, 0);
4290
      proc_end = expr_build_dot ();
4291
 
4292
      start_unwind_section (saved_seg, SPECIAL_SECTION_UNWIND);
4293
 
4294
      /* Make sure that section has 4 byte alignment for ILP32 and
4295
         8 byte alignment for LP64.  */
4296
      record_alignment (now_seg, md.pointer_size_shift);
4297
 
4298
      /* Need space for 3 pointers for procedure start, procedure end,
4299
         and unwind info.  */
4300
      memset (frag_more (3 * md.pointer_size), 0, 3 * md.pointer_size);
4301
      where = frag_now_fix () - (3 * md.pointer_size);
4302
      bytes_per_address = bfd_arch_bits_per_address (stdoutput) / 8;
4303
 
4304
      /* Issue the values of  a) Proc Begin, b) Proc End, c) Unwind Record.  */
4305
      e.X_op = O_pseudo_fixup;
4306
      e.X_op_symbol = pseudo_func[FUNC_SEG_RELATIVE].u.sym;
4307
      e.X_add_number = 0;
4308
      if (!S_IS_LOCAL (unwind.proc_pending.sym)
4309
          && S_IS_DEFINED (unwind.proc_pending.sym))
4310
        e.X_add_symbol = symbol_temp_new (S_GET_SEGMENT (unwind.proc_pending.sym),
4311
                                          S_GET_VALUE (unwind.proc_pending.sym),
4312
                                          symbol_get_frag (unwind.proc_pending.sym));
4313
      else
4314
        e.X_add_symbol = unwind.proc_pending.sym;
4315
      ia64_cons_fix_new (frag_now, where, bytes_per_address, &e);
4316
 
4317
      e.X_op = O_pseudo_fixup;
4318
      e.X_op_symbol = pseudo_func[FUNC_SEG_RELATIVE].u.sym;
4319
      e.X_add_number = 0;
4320
      e.X_add_symbol = proc_end;
4321
      ia64_cons_fix_new (frag_now, where + bytes_per_address,
4322
                         bytes_per_address, &e);
4323
 
4324
      if (unwind.info)
4325
        {
4326
          e.X_op = O_pseudo_fixup;
4327
          e.X_op_symbol = pseudo_func[FUNC_SEG_RELATIVE].u.sym;
4328
          e.X_add_number = 0;
4329
          e.X_add_symbol = unwind.info;
4330
          ia64_cons_fix_new (frag_now, where + (bytes_per_address * 2),
4331
                             bytes_per_address, &e);
4332
        }
4333
    }
4334
  subseg_set (saved_seg, saved_subseg);
4335
 
4336
  /* Set symbol sizes.  */
4337
  pending = &unwind.proc_pending;
4338
  if (S_GET_NAME (pending->sym))
4339
    {
4340
      do
4341
        {
4342
          symbolS *sym = pending->sym;
4343
 
4344
          if (!S_IS_DEFINED (sym))
4345
            as_bad (_("`%s' was not defined within procedure"), S_GET_NAME (sym));
4346
          else if (S_GET_SIZE (sym) == 0
4347
                   && symbol_get_obj (sym)->size == NULL)
4348
            {
4349
              fragS *frag = symbol_get_frag (sym);
4350
 
4351
              if (frag)
4352
                {
4353
                  if (frag == frag_now && SEG_NORMAL (now_seg))
4354
                    S_SET_SIZE (sym, frag_now_fix () - S_GET_VALUE (sym));
4355
                  else
4356
                    {
4357
                      symbol_get_obj (sym)->size =
4358
                        (expressionS *) xmalloc (sizeof (expressionS));
4359
                      symbol_get_obj (sym)->size->X_op = O_subtract;
4360
                      symbol_get_obj (sym)->size->X_add_symbol
4361
                        = symbol_new (FAKE_LABEL_NAME, now_seg,
4362
                                      frag_now_fix (), frag_now);
4363
                      symbol_get_obj (sym)->size->X_op_symbol = sym;
4364
                      symbol_get_obj (sym)->size->X_add_number = 0;
4365
                    }
4366
                }
4367
            }
4368
        } while ((pending = pending->next) != NULL);
4369
    }
4370
 
4371
  /* Parse names of main and alternate entry points.  */
4372
  while (1)
4373
    {
4374
      char *name, *p, c;
4375
 
4376
      SKIP_WHITESPACE ();
4377
      name = input_line_pointer;
4378
      c = get_symbol_end ();
4379
      p = input_line_pointer;
4380
      if (!*name)
4381
        (md.unwind_check == unwind_check_warning
4382
         ? as_warn
4383
         : as_bad) (_("Empty argument of .endp"));
4384
      else
4385
        {
4386
          symbolS *sym = symbol_find (name);
4387
 
4388
          for (pending = &unwind.proc_pending; pending; pending = pending->next)
4389
            {
4390
              if (sym == pending->sym)
4391
                {
4392
                  pending->sym = NULL;
4393
                  break;
4394
                }
4395
            }
4396
          if (!sym || !pending)
4397
            as_warn (_("`%s' was not specified with previous .proc"), name);
4398
        }
4399
      *p = c;
4400
      SKIP_WHITESPACE ();
4401
      if (*input_line_pointer != ',')
4402
        break;
4403
      ++input_line_pointer;
4404
    }
4405
  demand_empty_rest_of_line ();
4406
 
4407
  /* Deliberately only checking for the main entry point here; the
4408
     language spec even says all arguments to .endp are ignored.  */
4409
  if (unwind.proc_pending.sym
4410
      && S_GET_NAME (unwind.proc_pending.sym)
4411
      && strcmp (S_GET_NAME (unwind.proc_pending.sym), FAKE_LABEL_NAME))
4412
    as_warn (_("`%s' should be an operand to this .endp"),
4413
             S_GET_NAME (unwind.proc_pending.sym));
4414
  while (unwind.proc_pending.next)
4415
    {
4416
      pending = unwind.proc_pending.next;
4417
      unwind.proc_pending.next = pending->next;
4418
      free (pending);
4419
    }
4420
  unwind.proc_pending.sym = unwind.info = NULL;
4421
}
4422
 
4423
static void
4424
dot_template (int template_val)
4425
{
4426
  CURR_SLOT.user_template = template_val;
4427
}
4428
 
4429
static void
4430
dot_regstk (int dummy ATTRIBUTE_UNUSED)
4431
{
4432
  int ins, locs, outs, rots;
4433
 
4434
  if (is_it_end_of_statement ())
4435
    ins = locs = outs = rots = 0;
4436
  else
4437
    {
4438
      ins = get_absolute_expression ();
4439
      if (*input_line_pointer++ != ',')
4440
        goto err;
4441
      locs = get_absolute_expression ();
4442
      if (*input_line_pointer++ != ',')
4443
        goto err;
4444
      outs = get_absolute_expression ();
4445
      if (*input_line_pointer++ != ',')
4446
        goto err;
4447
      rots = get_absolute_expression ();
4448
    }
4449
  set_regstack (ins, locs, outs, rots);
4450
  return;
4451
 
4452
 err:
4453
  as_bad (_("Comma expected"));
4454
  ignore_rest_of_line ();
4455
}
4456
 
4457
static void
4458
dot_rot (int type)
4459
{
4460
  offsetT num_regs;
4461
  valueT num_alloced = 0;
4462
  struct dynreg **drpp, *dr;
4463
  int ch, base_reg = 0;
4464
  char *name, *start;
4465
  size_t len;
4466
 
4467
  switch (type)
4468
    {
4469
    case DYNREG_GR: base_reg = REG_GR + 32; break;
4470
    case DYNREG_FR: base_reg = REG_FR + 32; break;
4471
    case DYNREG_PR: base_reg = REG_P + 16; break;
4472
    default: break;
4473
    }
4474
 
4475
  /* First, remove existing names from hash table.  */
4476
  for (dr = md.dynreg[type]; dr && dr->num_regs; dr = dr->next)
4477
    {
4478
      hash_delete (md.dynreg_hash, dr->name, FALSE);
4479
      /* FIXME: Free dr->name.  */
4480
      dr->num_regs = 0;
4481
    }
4482
 
4483
  drpp = &md.dynreg[type];
4484
  while (1)
4485
    {
4486
      start = input_line_pointer;
4487
      ch = get_symbol_end ();
4488
      len = strlen (ia64_canonicalize_symbol_name (start));
4489
      *input_line_pointer = ch;
4490
 
4491
      SKIP_WHITESPACE ();
4492
      if (*input_line_pointer != '[')
4493
        {
4494
          as_bad (_("Expected '['"));
4495
          goto err;
4496
        }
4497
      ++input_line_pointer;     /* skip '[' */
4498
 
4499
      num_regs = get_absolute_expression ();
4500
 
4501
      if (*input_line_pointer++ != ']')
4502
        {
4503
          as_bad (_("Expected ']'"));
4504
          goto err;
4505
        }
4506
      if (num_regs <= 0)
4507
        {
4508
          as_bad (_("Number of elements must be positive"));
4509
          goto err;
4510
        }
4511
      SKIP_WHITESPACE ();
4512
 
4513
      num_alloced += num_regs;
4514
      switch (type)
4515
        {
4516
        case DYNREG_GR:
4517
          if (num_alloced > md.rot.num_regs)
4518
            {
4519
              as_bad (_("Used more than the declared %d rotating registers"),
4520
                      md.rot.num_regs);
4521
              goto err;
4522
            }
4523
          break;
4524
        case DYNREG_FR:
4525
          if (num_alloced > 96)
4526
            {
4527
              as_bad (_("Used more than the available 96 rotating registers"));
4528
              goto err;
4529
            }
4530
          break;
4531
        case DYNREG_PR:
4532
          if (num_alloced > 48)
4533
            {
4534
              as_bad (_("Used more than the available 48 rotating registers"));
4535
              goto err;
4536
            }
4537
          break;
4538
 
4539
        default:
4540
          break;
4541
        }
4542
 
4543
      if (!*drpp)
4544
        {
4545
          *drpp = obstack_alloc (&notes, sizeof (*dr));
4546
          memset (*drpp, 0, sizeof (*dr));
4547
        }
4548
 
4549
      name = obstack_alloc (&notes, len + 1);
4550
      memcpy (name, start, len);
4551
      name[len] = '\0';
4552
 
4553
      dr = *drpp;
4554
      dr->name = name;
4555
      dr->num_regs = num_regs;
4556
      dr->base = base_reg;
4557
      drpp = &dr->next;
4558
      base_reg += num_regs;
4559
 
4560
      if (hash_insert (md.dynreg_hash, name, dr))
4561
        {
4562
          as_bad (_("Attempt to redefine register set `%s'"), name);
4563
          obstack_free (&notes, name);
4564
          goto err;
4565
        }
4566
 
4567
      if (*input_line_pointer != ',')
4568
        break;
4569
      ++input_line_pointer;     /* skip comma */
4570
      SKIP_WHITESPACE ();
4571
    }
4572
  demand_empty_rest_of_line ();
4573
  return;
4574
 
4575
 err:
4576
  ignore_rest_of_line ();
4577
}
4578
 
4579
static void
4580
dot_byteorder (int byteorder)
4581
{
4582
  segment_info_type *seginfo = seg_info (now_seg);
4583
 
4584
  if (byteorder == -1)
4585
    {
4586
      if (seginfo->tc_segment_info_data.endian == 0)
4587
        seginfo->tc_segment_info_data.endian = default_big_endian ? 1 : 2;
4588
      byteorder = seginfo->tc_segment_info_data.endian == 1;
4589
    }
4590
  else
4591
    seginfo->tc_segment_info_data.endian = byteorder ? 1 : 2;
4592
 
4593
  if (target_big_endian != byteorder)
4594
    {
4595
      target_big_endian = byteorder;
4596
      if (target_big_endian)
4597
        {
4598
          ia64_number_to_chars = number_to_chars_bigendian;
4599
          ia64_float_to_chars = ia64_float_to_chars_bigendian;
4600
        }
4601
      else
4602
        {
4603
          ia64_number_to_chars = number_to_chars_littleendian;
4604
          ia64_float_to_chars = ia64_float_to_chars_littleendian;
4605
        }
4606
    }
4607
}
4608
 
4609
static void
4610
dot_psr (int dummy ATTRIBUTE_UNUSED)
4611
{
4612
  char *option;
4613
  int ch;
4614
 
4615
  while (1)
4616
    {
4617
      option = input_line_pointer;
4618
      ch = get_symbol_end ();
4619
      if (strcmp (option, "lsb") == 0)
4620
        md.flags &= ~EF_IA_64_BE;
4621
      else if (strcmp (option, "msb") == 0)
4622
        md.flags |= EF_IA_64_BE;
4623
      else if (strcmp (option, "abi32") == 0)
4624
        md.flags &= ~EF_IA_64_ABI64;
4625
      else if (strcmp (option, "abi64") == 0)
4626
        md.flags |= EF_IA_64_ABI64;
4627
      else
4628
        as_bad (_("Unknown psr option `%s'"), option);
4629
      *input_line_pointer = ch;
4630
 
4631
      SKIP_WHITESPACE ();
4632
      if (*input_line_pointer != ',')
4633
        break;
4634
 
4635
      ++input_line_pointer;
4636
      SKIP_WHITESPACE ();
4637
    }
4638
  demand_empty_rest_of_line ();
4639
}
4640
 
4641
static void
4642
dot_ln (int dummy ATTRIBUTE_UNUSED)
4643
{
4644
  new_logical_line (0, get_absolute_expression ());
4645
  demand_empty_rest_of_line ();
4646
}
4647
 
4648
static void
4649
cross_section (int ref, void (*cons) (int), int ua)
4650
{
4651
  char *start, *end;
4652
  int saved_auto_align;
4653
  unsigned int section_count;
4654
 
4655
  SKIP_WHITESPACE ();
4656
  start = input_line_pointer;
4657
  if (*start == '"')
4658
    {
4659
      int len;
4660
      char *name;
4661
 
4662
      name = demand_copy_C_string (&len);
4663
      obstack_free(&notes, name);
4664
      if (!name)
4665
        {
4666
          ignore_rest_of_line ();
4667
          return;
4668
        }
4669
    }
4670
  else
4671
    {
4672
      char c = get_symbol_end ();
4673
 
4674
      if (input_line_pointer == start)
4675
        {
4676
          as_bad (_("Missing section name"));
4677
          ignore_rest_of_line ();
4678
          return;
4679
        }
4680
      *input_line_pointer = c;
4681
    }
4682
  end = input_line_pointer;
4683
  SKIP_WHITESPACE ();
4684
  if (*input_line_pointer != ',')
4685
    {
4686
      as_bad (_("Comma expected after section name"));
4687
      ignore_rest_of_line ();
4688
      return;
4689
    }
4690
  *end = '\0';
4691
  end = input_line_pointer + 1;         /* skip comma */
4692
  input_line_pointer = start;
4693
  md.keep_pending_output = 1;
4694
  section_count = bfd_count_sections(stdoutput);
4695
  obj_elf_section (0);
4696
  if (section_count != bfd_count_sections(stdoutput))
4697
    as_warn (_("Creating sections with .xdataN/.xrealN/.xstringZ is deprecated."));
4698
  input_line_pointer = end;
4699
  saved_auto_align = md.auto_align;
4700
  if (ua)
4701
    md.auto_align = 0;
4702
  (*cons) (ref);
4703
  if (ua)
4704
    md.auto_align = saved_auto_align;
4705
  obj_elf_previous (0);
4706
  md.keep_pending_output = 0;
4707
}
4708
 
4709
static void
4710
dot_xdata (int size)
4711
{
4712
  cross_section (size, cons, 0);
4713
}
4714
 
4715
/* Why doesn't float_cons() call md_cons_align() the way cons() does?  */
4716
 
4717
static void
4718
stmt_float_cons (int kind)
4719
{
4720
  size_t alignment;
4721
 
4722
  switch (kind)
4723
    {
4724
    case 'd':
4725
      alignment = 8;
4726
      break;
4727
 
4728
    case 'x':
4729
    case 'X':
4730
      alignment = 16;
4731
      break;
4732
 
4733
    case 'f':
4734
    default:
4735
      alignment = 4;
4736
      break;
4737
    }
4738
  ia64_do_align (alignment);
4739
  float_cons (kind);
4740
}
4741
 
4742
static void
4743
stmt_cons_ua (int size)
4744
{
4745
  int saved_auto_align = md.auto_align;
4746
 
4747
  md.auto_align = 0;
4748
  cons (size);
4749
  md.auto_align = saved_auto_align;
4750
}
4751
 
4752
static void
4753
dot_xfloat_cons (int kind)
4754
{
4755
  cross_section (kind, stmt_float_cons, 0);
4756
}
4757
 
4758
static void
4759
dot_xstringer (int zero)
4760
{
4761
  cross_section (zero, stringer, 0);
4762
}
4763
 
4764
static void
4765
dot_xdata_ua (int size)
4766
{
4767
  cross_section (size, cons, 1);
4768
}
4769
 
4770
static void
4771
dot_xfloat_cons_ua (int kind)
4772
{
4773
  cross_section (kind, float_cons, 1);
4774
}
4775
 
4776
/* .reg.val <regname>,value */
4777
 
4778
static void
4779
dot_reg_val (int dummy ATTRIBUTE_UNUSED)
4780
{
4781
  expressionS reg;
4782
 
4783
  expression_and_evaluate (&reg);
4784
  if (reg.X_op != O_register)
4785
    {
4786
      as_bad (_("Register name expected"));
4787
      ignore_rest_of_line ();
4788
    }
4789
  else if (*input_line_pointer++ != ',')
4790
    {
4791
      as_bad (_("Comma expected"));
4792
      ignore_rest_of_line ();
4793
    }
4794
  else
4795
    {
4796
      valueT value = get_absolute_expression ();
4797
      int regno = reg.X_add_number;
4798
      if (regno <= REG_GR || regno > REG_GR + 127)
4799
        as_warn (_("Register value annotation ignored"));
4800
      else
4801
        {
4802
          gr_values[regno - REG_GR].known = 1;
4803
          gr_values[regno - REG_GR].value = value;
4804
          gr_values[regno - REG_GR].path = md.path;
4805
        }
4806
    }
4807
  demand_empty_rest_of_line ();
4808
}
4809
 
4810
/*
4811
  .serialize.data
4812
  .serialize.instruction
4813
 */
4814
static void
4815
dot_serialize (int type)
4816
{
4817
  insn_group_break (0, 0, 0);
4818
  if (type)
4819
    instruction_serialization ();
4820
  else
4821
    data_serialization ();
4822
  insn_group_break (0, 0, 0);
4823
  demand_empty_rest_of_line ();
4824
}
4825
 
4826
/* select dv checking mode
4827
   .auto
4828
   .explicit
4829
   .default
4830
 
4831
   A stop is inserted when changing modes
4832
 */
4833
 
4834
static void
4835
dot_dv_mode (int type)
4836
{
4837
  if (md.manual_bundling)
4838
    as_warn (_("Directive invalid within a bundle"));
4839
 
4840
  if (type == 'E' || type == 'A')
4841
    md.mode_explicitly_set = 0;
4842
  else
4843
    md.mode_explicitly_set = 1;
4844
 
4845
  md.detect_dv = 1;
4846
  switch (type)
4847
    {
4848
    case 'A':
4849
    case 'a':
4850
      if (md.explicit_mode)
4851
        insn_group_break (1, 0, 0);
4852
      md.explicit_mode = 0;
4853
      break;
4854
    case 'E':
4855
    case 'e':
4856
      if (!md.explicit_mode)
4857
        insn_group_break (1, 0, 0);
4858
      md.explicit_mode = 1;
4859
      break;
4860
    default:
4861
    case 'd':
4862
      if (md.explicit_mode != md.default_explicit_mode)
4863
        insn_group_break (1, 0, 0);
4864
      md.explicit_mode = md.default_explicit_mode;
4865
      md.mode_explicitly_set = 0;
4866
      break;
4867
    }
4868
}
4869
 
4870
static void
4871
print_prmask (valueT mask)
4872
{
4873
  int regno;
4874
  char *comma = "";
4875
  for (regno = 0; regno < 64; regno++)
4876
    {
4877
      if (mask & ((valueT) 1 << regno))
4878
        {
4879
          fprintf (stderr, "%s p%d", comma, regno);
4880
          comma = ",";
4881
        }
4882
    }
4883
}
4884
 
4885
/*
4886
  .pred.rel.clear [p1 [,p2 [,...]]]     (also .pred.rel "clear" or @clear)
4887
  .pred.rel.imply p1, p2                (also .pred.rel "imply" or @imply)
4888
  .pred.rel.mutex p1, p2 [,...]         (also .pred.rel "mutex" or @mutex)
4889
  .pred.safe_across_calls p1 [, p2 [,...]]
4890
 */
4891
 
4892
static void
4893
dot_pred_rel (int type)
4894
{
4895
  valueT mask = 0;
4896
  int count = 0;
4897
  int p1 = -1, p2 = -1;
4898
 
4899
  if (type == 0)
4900
    {
4901
      if (*input_line_pointer == '"')
4902
        {
4903
          int len;
4904
          char *form = demand_copy_C_string (&len);
4905
 
4906
          if (strcmp (form, "mutex") == 0)
4907
            type = 'm';
4908
          else if (strcmp (form, "clear") == 0)
4909
            type = 'c';
4910
          else if (strcmp (form, "imply") == 0)
4911
            type = 'i';
4912
          obstack_free (&notes, form);
4913
        }
4914
      else if (*input_line_pointer == '@')
4915
        {
4916
          char *form = ++input_line_pointer;
4917
          char c = get_symbol_end();
4918
 
4919
          if (strcmp (form, "mutex") == 0)
4920
            type = 'm';
4921
          else if (strcmp (form, "clear") == 0)
4922
            type = 'c';
4923
          else if (strcmp (form, "imply") == 0)
4924
            type = 'i';
4925
          *input_line_pointer = c;
4926
        }
4927
      else
4928
        {
4929
          as_bad (_("Missing predicate relation type"));
4930
          ignore_rest_of_line ();
4931
          return;
4932
        }
4933
      if (type == 0)
4934
        {
4935
          as_bad (_("Unrecognized predicate relation type"));
4936
          ignore_rest_of_line ();
4937
          return;
4938
        }
4939
      if (*input_line_pointer == ',')
4940
        ++input_line_pointer;
4941
      SKIP_WHITESPACE ();
4942
    }
4943
 
4944
  while (1)
4945
    {
4946
      valueT bits = 1;
4947
      int sep, regno;
4948
      expressionS pr, *pr1, *pr2;
4949
 
4950
      sep = parse_operand_and_eval (&pr, ',');
4951
      if (pr.X_op == O_register
4952
          && pr.X_add_number >= REG_P
4953
          && pr.X_add_number <= REG_P + 63)
4954
        {
4955
          regno = pr.X_add_number - REG_P;
4956
          bits <<= regno;
4957
          count++;
4958
          if (p1 == -1)
4959
            p1 = regno;
4960
          else if (p2 == -1)
4961
            p2 = regno;
4962
        }
4963
      else if (type != 'i'
4964
          && pr.X_op == O_subtract
4965
          && (pr1 = symbol_get_value_expression (pr.X_add_symbol))
4966
          && pr1->X_op == O_register
4967
          && pr1->X_add_number >= REG_P
4968
          && pr1->X_add_number <= REG_P + 63
4969
          && (pr2 = symbol_get_value_expression (pr.X_op_symbol))
4970
          && pr2->X_op == O_register
4971
          && pr2->X_add_number >= REG_P
4972
          && pr2->X_add_number <= REG_P + 63)
4973
        {
4974
          /* It's a range.  */
4975
          int stop;
4976
 
4977
          regno = pr1->X_add_number - REG_P;
4978
          stop = pr2->X_add_number - REG_P;
4979
          if (regno >= stop)
4980
            {
4981
              as_bad (_("Bad register range"));
4982
              ignore_rest_of_line ();
4983
              return;
4984
            }
4985
          bits = ((bits << stop) << 1) - (bits << regno);
4986
          count += stop - regno + 1;
4987
        }
4988
      else
4989
        {
4990
          as_bad (_("Predicate register expected"));
4991
          ignore_rest_of_line ();
4992
          return;
4993
        }
4994
      if (mask & bits)
4995
        as_warn (_("Duplicate predicate register ignored"));
4996
      mask |= bits;
4997
      if (sep != ',')
4998
        break;
4999
    }
5000
 
5001
  switch (type)
5002
    {
5003
    case 'c':
5004
      if (count == 0)
5005
        mask = ~(valueT) 0;
5006
      clear_qp_mutex (mask);
5007
      clear_qp_implies (mask, (valueT) 0);
5008
      break;
5009
    case 'i':
5010
      if (count != 2 || p1 == -1 || p2 == -1)
5011
        as_bad (_("Predicate source and target required"));
5012
      else if (p1 == 0 || p2 == 0)
5013
        as_bad (_("Use of p0 is not valid in this context"));
5014
      else
5015
        add_qp_imply (p1, p2);
5016
      break;
5017
    case 'm':
5018
      if (count < 2)
5019
        {
5020
          as_bad (_("At least two PR arguments expected"));
5021
          break;
5022
        }
5023
      else if (mask & 1)
5024
        {
5025
          as_bad (_("Use of p0 is not valid in this context"));
5026
          break;
5027
        }
5028
      add_qp_mutex (mask);
5029
      break;
5030
    case 's':
5031
      /* note that we don't override any existing relations */
5032
      if (count == 0)
5033
        {
5034
          as_bad (_("At least one PR argument expected"));
5035
          break;
5036
        }
5037
      if (md.debug_dv)
5038
        {
5039
          fprintf (stderr, "Safe across calls: ");
5040
          print_prmask (mask);
5041
          fprintf (stderr, "\n");
5042
        }
5043
      qp_safe_across_calls = mask;
5044
      break;
5045
    }
5046
  demand_empty_rest_of_line ();
5047
}
5048
 
5049
/* .entry label [, label [, ...]]
5050
   Hint to DV code that the given labels are to be considered entry points.
5051
   Otherwise, only global labels are considered entry points.  */
5052
 
5053
static void
5054
dot_entry (int dummy ATTRIBUTE_UNUSED)
5055
{
5056
  const char *err;
5057
  char *name;
5058
  int c;
5059
  symbolS *symbolP;
5060
 
5061
  do
5062
    {
5063
      name = input_line_pointer;
5064
      c = get_symbol_end ();
5065
      symbolP = symbol_find_or_make (name);
5066
 
5067
      err = hash_insert (md.entry_hash, S_GET_NAME (symbolP), (void *) symbolP);
5068
      if (err)
5069
        as_fatal (_("Inserting \"%s\" into entry hint table failed: %s"),
5070
                  name, err);
5071
 
5072
      *input_line_pointer = c;
5073
      SKIP_WHITESPACE ();
5074
      c = *input_line_pointer;
5075
      if (c == ',')
5076
        {
5077
          input_line_pointer++;
5078
          SKIP_WHITESPACE ();
5079
          if (*input_line_pointer == '\n')
5080
            c = '\n';
5081
        }
5082
    }
5083
  while (c == ',');
5084
 
5085
  demand_empty_rest_of_line ();
5086
}
5087
 
5088
/* .mem.offset offset, base
5089
   "base" is used to distinguish between offsets from a different base.  */
5090
 
5091
static void
5092
dot_mem_offset (int dummy ATTRIBUTE_UNUSED)
5093
{
5094
  md.mem_offset.hint = 1;
5095
  md.mem_offset.offset = get_absolute_expression ();
5096
  if (*input_line_pointer != ',')
5097
    {
5098
      as_bad (_("Comma expected"));
5099
      ignore_rest_of_line ();
5100
      return;
5101
    }
5102
  ++input_line_pointer;
5103
  md.mem_offset.base = get_absolute_expression ();
5104
  demand_empty_rest_of_line ();
5105
}
5106
 
5107
/* ia64-specific pseudo-ops:  */
5108
const pseudo_typeS md_pseudo_table[] =
5109
  {
5110
    { "radix", dot_radix, 0 },
5111
    { "lcomm", s_lcomm_bytes, 1 },
5112
    { "loc", dot_loc, 0 },
5113
    { "bss", dot_special_section, SPECIAL_SECTION_BSS },
5114
    { "sbss", dot_special_section, SPECIAL_SECTION_SBSS },
5115
    { "sdata", dot_special_section, SPECIAL_SECTION_SDATA },
5116
    { "rodata", dot_special_section, SPECIAL_SECTION_RODATA },
5117
    { "comment", dot_special_section, SPECIAL_SECTION_COMMENT },
5118
    { "ia_64.unwind", dot_special_section, SPECIAL_SECTION_UNWIND },
5119
    { "ia_64.unwind_info", dot_special_section, SPECIAL_SECTION_UNWIND_INFO },
5120
    { "init_array", dot_special_section, SPECIAL_SECTION_INIT_ARRAY },
5121
    { "fini_array", dot_special_section, SPECIAL_SECTION_FINI_ARRAY },
5122
    { "proc", dot_proc, 0 },
5123
    { "body", dot_body, 0 },
5124
    { "prologue", dot_prologue, 0 },
5125
    { "endp", dot_endp, 0 },
5126
 
5127
    { "fframe", dot_fframe, 0 },
5128
    { "vframe", dot_vframe, 0 },
5129
    { "vframesp", dot_vframesp, 0 },
5130
    { "vframepsp", dot_vframesp, 1 },
5131
    { "save", dot_save, 0 },
5132
    { "restore", dot_restore, 0 },
5133
    { "restorereg", dot_restorereg, 0 },
5134
    { "restorereg.p", dot_restorereg, 1 },
5135
    { "handlerdata", dot_handlerdata, 0 },
5136
    { "unwentry", dot_unwentry, 0 },
5137
    { "altrp", dot_altrp, 0 },
5138
    { "savesp", dot_savemem, 0 },
5139
    { "savepsp", dot_savemem, 1 },
5140
    { "save.g", dot_saveg, 0 },
5141
    { "save.f", dot_savef, 0 },
5142
    { "save.b", dot_saveb, 0 },
5143
    { "save.gf", dot_savegf, 0 },
5144
    { "spill", dot_spill, 0 },
5145
    { "spillreg", dot_spillreg, 0 },
5146
    { "spillsp", dot_spillmem, 0 },
5147
    { "spillpsp", dot_spillmem, 1 },
5148
    { "spillreg.p", dot_spillreg, 1 },
5149
    { "spillsp.p", dot_spillmem, ~0 },
5150
    { "spillpsp.p", dot_spillmem, ~1 },
5151
    { "label_state", dot_label_state, 0 },
5152
    { "copy_state", dot_copy_state, 0 },
5153
    { "unwabi", dot_unwabi, 0 },
5154
    { "personality", dot_personality, 0 },
5155
    { "mii", dot_template, 0x0 },
5156
    { "mli", dot_template, 0x2 }, /* old format, for compatibility */
5157
    { "mlx", dot_template, 0x2 },
5158
    { "mmi", dot_template, 0x4 },
5159
    { "mfi", dot_template, 0x6 },
5160
    { "mmf", dot_template, 0x7 },
5161
    { "mib", dot_template, 0x8 },
5162
    { "mbb", dot_template, 0x9 },
5163
    { "bbb", dot_template, 0xb },
5164
    { "mmb", dot_template, 0xc },
5165
    { "mfb", dot_template, 0xe },
5166
    { "align", dot_align, 0 },
5167
    { "regstk", dot_regstk, 0 },
5168
    { "rotr", dot_rot, DYNREG_GR },
5169
    { "rotf", dot_rot, DYNREG_FR },
5170
    { "rotp", dot_rot, DYNREG_PR },
5171
    { "lsb", dot_byteorder, 0 },
5172
    { "msb", dot_byteorder, 1 },
5173
    { "psr", dot_psr, 0 },
5174
    { "alias", dot_alias, 0 },
5175
    { "secalias", dot_alias, 1 },
5176
    { "ln", dot_ln, 0 },         /* source line info (for debugging) */
5177
 
5178
    { "xdata1", dot_xdata, 1 },
5179
    { "xdata2", dot_xdata, 2 },
5180
    { "xdata4", dot_xdata, 4 },
5181
    { "xdata8", dot_xdata, 8 },
5182
    { "xdata16", dot_xdata, 16 },
5183
    { "xreal4", dot_xfloat_cons, 'f' },
5184
    { "xreal8", dot_xfloat_cons, 'd' },
5185
    { "xreal10", dot_xfloat_cons, 'x' },
5186
    { "xreal16", dot_xfloat_cons, 'X' },
5187
    { "xstring", dot_xstringer, 8 + 0 },
5188
    { "xstringz", dot_xstringer, 8 + 1 },
5189
 
5190
    /* unaligned versions:  */
5191
    { "xdata2.ua", dot_xdata_ua, 2 },
5192
    { "xdata4.ua", dot_xdata_ua, 4 },
5193
    { "xdata8.ua", dot_xdata_ua, 8 },
5194
    { "xdata16.ua", dot_xdata_ua, 16 },
5195
    { "xreal4.ua", dot_xfloat_cons_ua, 'f' },
5196
    { "xreal8.ua", dot_xfloat_cons_ua, 'd' },
5197
    { "xreal10.ua", dot_xfloat_cons_ua, 'x' },
5198
    { "xreal16.ua", dot_xfloat_cons_ua, 'X' },
5199
 
5200
    /* annotations/DV checking support */
5201
    { "entry", dot_entry, 0 },
5202
    { "mem.offset", dot_mem_offset, 0 },
5203
    { "pred.rel", dot_pred_rel, 0 },
5204
    { "pred.rel.clear", dot_pred_rel, 'c' },
5205
    { "pred.rel.imply", dot_pred_rel, 'i' },
5206
    { "pred.rel.mutex", dot_pred_rel, 'm' },
5207
    { "pred.safe_across_calls", dot_pred_rel, 's' },
5208
    { "reg.val", dot_reg_val, 0 },
5209
    { "serialize.data", dot_serialize, 0 },
5210
    { "serialize.instruction", dot_serialize, 1 },
5211
    { "auto", dot_dv_mode, 'a' },
5212
    { "explicit", dot_dv_mode, 'e' },
5213
    { "default", dot_dv_mode, 'd' },
5214
 
5215
    /* ??? These are needed to make gas/testsuite/gas/elf/ehopt.s work.
5216
       IA-64 aligns data allocation pseudo-ops by default, so we have to
5217
       tell it that these ones are supposed to be unaligned.  Long term,
5218
       should rewrite so that only IA-64 specific data allocation pseudo-ops
5219
       are aligned by default.  */
5220
    {"2byte", stmt_cons_ua, 2},
5221
    {"4byte", stmt_cons_ua, 4},
5222
    {"8byte", stmt_cons_ua, 8},
5223
 
5224
    { NULL, 0, 0 }
5225
  };
5226
 
5227
static const struct pseudo_opcode
5228
  {
5229
    const char *name;
5230
    void (*handler) (int);
5231
    int arg;
5232
  }
5233
pseudo_opcode[] =
5234
  {
5235
    /* these are more like pseudo-ops, but don't start with a dot */
5236
    { "data1", cons, 1 },
5237
    { "data2", cons, 2 },
5238
    { "data4", cons, 4 },
5239
    { "data8", cons, 8 },
5240
    { "data16", cons, 16 },
5241
    { "real4", stmt_float_cons, 'f' },
5242
    { "real8", stmt_float_cons, 'd' },
5243
    { "real10", stmt_float_cons, 'x' },
5244
    { "real16", stmt_float_cons, 'X' },
5245
    { "string", stringer, 8 + 0 },
5246
    { "stringz", stringer, 8 + 1 },
5247
 
5248
    /* unaligned versions:  */
5249
    { "data2.ua", stmt_cons_ua, 2 },
5250
    { "data4.ua", stmt_cons_ua, 4 },
5251
    { "data8.ua", stmt_cons_ua, 8 },
5252
    { "data16.ua", stmt_cons_ua, 16 },
5253
    { "real4.ua", float_cons, 'f' },
5254
    { "real8.ua", float_cons, 'd' },
5255
    { "real10.ua", float_cons, 'x' },
5256
    { "real16.ua", float_cons, 'X' },
5257
  };
5258
 
5259
/* Declare a register by creating a symbol for it and entering it in
5260
   the symbol table.  */
5261
 
5262
static symbolS *
5263
declare_register (const char *name, unsigned int regnum)
5264
{
5265
  const char *err;
5266
  symbolS *sym;
5267
 
5268
  sym = symbol_create (name, reg_section, regnum, &zero_address_frag);
5269
 
5270
  err = hash_insert (md.reg_hash, S_GET_NAME (sym), (void *) sym);
5271
  if (err)
5272
    as_fatal ("Inserting \"%s\" into register table failed: %s",
5273
              name, err);
5274
 
5275
  return sym;
5276
}
5277
 
5278
static void
5279
declare_register_set (const char *prefix,
5280
                      unsigned int num_regs,
5281
                      unsigned int base_regnum)
5282
{
5283
  char name[8];
5284
  unsigned int i;
5285
 
5286
  for (i = 0; i < num_regs; ++i)
5287
    {
5288
      snprintf (name, sizeof (name), "%s%u", prefix, i);
5289
      declare_register (name, base_regnum + i);
5290
    }
5291
}
5292
 
5293
static unsigned int
5294
operand_width (enum ia64_opnd opnd)
5295
{
5296
  const struct ia64_operand *odesc = &elf64_ia64_operands[opnd];
5297
  unsigned int bits = 0;
5298
  int i;
5299
 
5300
  bits = 0;
5301
  for (i = 0; i < NELEMS (odesc->field) && odesc->field[i].bits; ++i)
5302
    bits += odesc->field[i].bits;
5303
 
5304
  return bits;
5305
}
5306
 
5307
static enum operand_match_result
5308
operand_match (const struct ia64_opcode *idesc, int index, expressionS *e)
5309
{
5310
  enum ia64_opnd opnd = idesc->operands[index];
5311
  int bits, relocatable = 0;
5312
  struct insn_fix *fix;
5313
  bfd_signed_vma val;
5314
 
5315
  switch (opnd)
5316
    {
5317
      /* constants:  */
5318
 
5319
    case IA64_OPND_AR_CCV:
5320
      if (e->X_op == O_register && e->X_add_number == REG_AR + 32)
5321
        return OPERAND_MATCH;
5322
      break;
5323
 
5324
    case IA64_OPND_AR_CSD:
5325
      if (e->X_op == O_register && e->X_add_number == REG_AR + 25)
5326
        return OPERAND_MATCH;
5327
      break;
5328
 
5329
    case IA64_OPND_AR_PFS:
5330
      if (e->X_op == O_register && e->X_add_number == REG_AR + 64)
5331
        return OPERAND_MATCH;
5332
      break;
5333
 
5334
    case IA64_OPND_GR0:
5335
      if (e->X_op == O_register && e->X_add_number == REG_GR + 0)
5336
        return OPERAND_MATCH;
5337
      break;
5338
 
5339
    case IA64_OPND_IP:
5340
      if (e->X_op == O_register && e->X_add_number == REG_IP)
5341
        return OPERAND_MATCH;
5342
      break;
5343
 
5344
    case IA64_OPND_PR:
5345
      if (e->X_op == O_register && e->X_add_number == REG_PR)
5346
        return OPERAND_MATCH;
5347
      break;
5348
 
5349
    case IA64_OPND_PR_ROT:
5350
      if (e->X_op == O_register && e->X_add_number == REG_PR_ROT)
5351
        return OPERAND_MATCH;
5352
      break;
5353
 
5354
    case IA64_OPND_PSR:
5355
      if (e->X_op == O_register && e->X_add_number == REG_PSR)
5356
        return OPERAND_MATCH;
5357
      break;
5358
 
5359
    case IA64_OPND_PSR_L:
5360
      if (e->X_op == O_register && e->X_add_number == REG_PSR_L)
5361
        return OPERAND_MATCH;
5362
      break;
5363
 
5364
    case IA64_OPND_PSR_UM:
5365
      if (e->X_op == O_register && e->X_add_number == REG_PSR_UM)
5366
        return OPERAND_MATCH;
5367
      break;
5368
 
5369
    case IA64_OPND_C1:
5370
      if (e->X_op == O_constant)
5371
        {
5372
          if (e->X_add_number == 1)
5373
            return OPERAND_MATCH;
5374
          else
5375
            return OPERAND_OUT_OF_RANGE;
5376
        }
5377
      break;
5378
 
5379
    case IA64_OPND_C8:
5380
      if (e->X_op == O_constant)
5381
        {
5382
          if (e->X_add_number == 8)
5383
            return OPERAND_MATCH;
5384
          else
5385
            return OPERAND_OUT_OF_RANGE;
5386
        }
5387
      break;
5388
 
5389
    case IA64_OPND_C16:
5390
      if (e->X_op == O_constant)
5391
        {
5392
          if (e->X_add_number == 16)
5393
            return OPERAND_MATCH;
5394
          else
5395
            return OPERAND_OUT_OF_RANGE;
5396
        }
5397
      break;
5398
 
5399
      /* register operands:  */
5400
 
5401
    case IA64_OPND_AR3:
5402
      if (e->X_op == O_register && e->X_add_number >= REG_AR
5403
          && e->X_add_number < REG_AR + 128)
5404
        return OPERAND_MATCH;
5405
      break;
5406
 
5407
    case IA64_OPND_B1:
5408
    case IA64_OPND_B2:
5409
      if (e->X_op == O_register && e->X_add_number >= REG_BR
5410
          && e->X_add_number < REG_BR + 8)
5411
        return OPERAND_MATCH;
5412
      break;
5413
 
5414
    case IA64_OPND_CR3:
5415
      if (e->X_op == O_register && e->X_add_number >= REG_CR
5416
          && e->X_add_number < REG_CR + 128)
5417
        return OPERAND_MATCH;
5418
      break;
5419
 
5420
    case IA64_OPND_F1:
5421
    case IA64_OPND_F2:
5422
    case IA64_OPND_F3:
5423
    case IA64_OPND_F4:
5424
      if (e->X_op == O_register && e->X_add_number >= REG_FR
5425
          && e->X_add_number < REG_FR + 128)
5426
        return OPERAND_MATCH;
5427
      break;
5428
 
5429
    case IA64_OPND_P1:
5430
    case IA64_OPND_P2:
5431
      if (e->X_op == O_register && e->X_add_number >= REG_P
5432
          && e->X_add_number < REG_P + 64)
5433
        return OPERAND_MATCH;
5434
      break;
5435
 
5436
    case IA64_OPND_R1:
5437
    case IA64_OPND_R2:
5438
    case IA64_OPND_R3:
5439
      if (e->X_op == O_register && e->X_add_number >= REG_GR
5440
          && e->X_add_number < REG_GR + 128)
5441
        return OPERAND_MATCH;
5442
      break;
5443
 
5444
    case IA64_OPND_R3_2:
5445
      if (e->X_op == O_register && e->X_add_number >= REG_GR)
5446
        {
5447
          if (e->X_add_number < REG_GR + 4)
5448
            return OPERAND_MATCH;
5449
          else if (e->X_add_number < REG_GR + 128)
5450
            return OPERAND_OUT_OF_RANGE;
5451
        }
5452
      break;
5453
 
5454
      /* indirect operands:  */
5455
    case IA64_OPND_CPUID_R3:
5456
    case IA64_OPND_DBR_R3:
5457
    case IA64_OPND_DTR_R3:
5458
    case IA64_OPND_ITR_R3:
5459
    case IA64_OPND_IBR_R3:
5460
    case IA64_OPND_MSR_R3:
5461
    case IA64_OPND_PKR_R3:
5462
    case IA64_OPND_PMC_R3:
5463
    case IA64_OPND_PMD_R3:
5464
    case IA64_OPND_RR_R3:
5465
      if (e->X_op == O_index && e->X_op_symbol
5466
          && (S_GET_VALUE (e->X_op_symbol) - IND_CPUID
5467
              == opnd - IA64_OPND_CPUID_R3))
5468
        return OPERAND_MATCH;
5469
      break;
5470
 
5471
    case IA64_OPND_MR3:
5472
      if (e->X_op == O_index && !e->X_op_symbol)
5473
        return OPERAND_MATCH;
5474
      break;
5475
 
5476
      /* immediate operands:  */
5477
    case IA64_OPND_CNT2a:
5478
    case IA64_OPND_LEN4:
5479
    case IA64_OPND_LEN6:
5480
      bits = operand_width (idesc->operands[index]);
5481
      if (e->X_op == O_constant)
5482
        {
5483
          if ((bfd_vma) (e->X_add_number - 1) < ((bfd_vma) 1 << bits))
5484
            return OPERAND_MATCH;
5485
          else
5486
            return OPERAND_OUT_OF_RANGE;
5487
        }
5488
      break;
5489
 
5490
    case IA64_OPND_CNT2b:
5491
      if (e->X_op == O_constant)
5492
        {
5493
          if ((bfd_vma) (e->X_add_number - 1) < 3)
5494
            return OPERAND_MATCH;
5495
          else
5496
            return OPERAND_OUT_OF_RANGE;
5497
        }
5498
      break;
5499
 
5500
    case IA64_OPND_CNT2c:
5501
      val = e->X_add_number;
5502
      if (e->X_op == O_constant)
5503
        {
5504
          if ((val == 0 || val == 7 || val == 15 || val == 16))
5505
            return OPERAND_MATCH;
5506
          else
5507
            return OPERAND_OUT_OF_RANGE;
5508
        }
5509
      break;
5510
 
5511
    case IA64_OPND_SOR:
5512
      /* SOR must be an integer multiple of 8 */
5513
      if (e->X_op == O_constant && e->X_add_number & 0x7)
5514
        return OPERAND_OUT_OF_RANGE;
5515
    case IA64_OPND_SOF:
5516
    case IA64_OPND_SOL:
5517
      if (e->X_op == O_constant)
5518
        {
5519
          if ((bfd_vma) e->X_add_number <= 96)
5520
            return OPERAND_MATCH;
5521
          else
5522
            return OPERAND_OUT_OF_RANGE;
5523
        }
5524
      break;
5525
 
5526
    case IA64_OPND_IMMU62:
5527
      if (e->X_op == O_constant)
5528
        {
5529
          if ((bfd_vma) e->X_add_number < ((bfd_vma) 1 << 62))
5530
            return OPERAND_MATCH;
5531
          else
5532
            return OPERAND_OUT_OF_RANGE;
5533
        }
5534
      else
5535
        {
5536
          /* FIXME -- need 62-bit relocation type */
5537
          as_bad (_("62-bit relocation not yet implemented"));
5538
        }
5539
      break;
5540
 
5541
    case IA64_OPND_IMMU64:
5542
      if (e->X_op == O_symbol || e->X_op == O_pseudo_fixup
5543
          || e->X_op == O_subtract)
5544
        {
5545
          fix = CURR_SLOT.fixup + CURR_SLOT.num_fixups;
5546
          fix->code = BFD_RELOC_IA64_IMM64;
5547
          if (e->X_op != O_subtract)
5548
            {
5549
              fix->code = ia64_gen_real_reloc_type (e->X_op_symbol, fix->code);
5550
              if (e->X_op == O_pseudo_fixup)
5551
                e->X_op = O_symbol;
5552
            }
5553
 
5554
          fix->opnd = idesc->operands[index];
5555
          fix->expr = *e;
5556
          fix->is_pcrel = 0;
5557
          ++CURR_SLOT.num_fixups;
5558
          return OPERAND_MATCH;
5559
        }
5560
      else if (e->X_op == O_constant)
5561
        return OPERAND_MATCH;
5562
      break;
5563
 
5564
    case IA64_OPND_IMMU5b:
5565
      if (e->X_op == O_constant)
5566
        {
5567
          val = e->X_add_number;
5568
          if (val >= 32 && val <= 63)
5569
            return OPERAND_MATCH;
5570
          else
5571
            return OPERAND_OUT_OF_RANGE;
5572
        }
5573
      break;
5574
 
5575
    case IA64_OPND_CCNT5:
5576
    case IA64_OPND_CNT5:
5577
    case IA64_OPND_CNT6:
5578
    case IA64_OPND_CPOS6a:
5579
    case IA64_OPND_CPOS6b:
5580
    case IA64_OPND_CPOS6c:
5581
    case IA64_OPND_IMMU2:
5582
    case IA64_OPND_IMMU7a:
5583
    case IA64_OPND_IMMU7b:
5584
    case IA64_OPND_IMMU21:
5585
    case IA64_OPND_IMMU24:
5586
    case IA64_OPND_MBTYPE4:
5587
    case IA64_OPND_MHTYPE8:
5588
    case IA64_OPND_POS6:
5589
      bits = operand_width (idesc->operands[index]);
5590
      if (e->X_op == O_constant)
5591
        {
5592
          if ((bfd_vma) e->X_add_number < ((bfd_vma) 1 << bits))
5593
            return OPERAND_MATCH;
5594
          else
5595
            return OPERAND_OUT_OF_RANGE;
5596
        }
5597
      break;
5598
 
5599
    case IA64_OPND_IMMU9:
5600
      bits = operand_width (idesc->operands[index]);
5601
      if (e->X_op == O_constant)
5602
        {
5603
          if ((bfd_vma) e->X_add_number < ((bfd_vma) 1 << bits))
5604
            {
5605
              int lobits = e->X_add_number & 0x3;
5606
              if (((bfd_vma) e->X_add_number & 0x3C) != 0 && lobits == 0)
5607
                e->X_add_number |= (bfd_vma) 0x3;
5608
              return OPERAND_MATCH;
5609
            }
5610
          else
5611
            return OPERAND_OUT_OF_RANGE;
5612
        }
5613
      break;
5614
 
5615
    case IA64_OPND_IMM44:
5616
      /* least 16 bits must be zero */
5617
      if ((e->X_add_number & 0xffff) != 0)
5618
        /* XXX technically, this is wrong: we should not be issuing warning
5619
           messages until we're sure this instruction pattern is going to
5620
           be used! */
5621
        as_warn (_("lower 16 bits of mask ignored"));
5622
 
5623
      if (e->X_op == O_constant)
5624
        {
5625
          if (((e->X_add_number >= 0
5626
                && (bfd_vma) e->X_add_number < ((bfd_vma) 1 << 44))
5627
               || (e->X_add_number < 0
5628
                   && (bfd_vma) -e->X_add_number <= ((bfd_vma) 1 << 44))))
5629
            {
5630
              /* sign-extend */
5631
              if (e->X_add_number >= 0
5632
                  && (e->X_add_number & ((bfd_vma) 1 << 43)) != 0)
5633
                {
5634
                  e->X_add_number |= ~(((bfd_vma) 1 << 44) - 1);
5635
                }
5636
              return OPERAND_MATCH;
5637
            }
5638
          else
5639
            return OPERAND_OUT_OF_RANGE;
5640
        }
5641
      break;
5642
 
5643
    case IA64_OPND_IMM17:
5644
      /* bit 0 is a don't care (pr0 is hardwired to 1) */
5645
      if (e->X_op == O_constant)
5646
        {
5647
          if (((e->X_add_number >= 0
5648
                && (bfd_vma) e->X_add_number < ((bfd_vma) 1 << 17))
5649
               || (e->X_add_number < 0
5650
                   && (bfd_vma) -e->X_add_number <= ((bfd_vma) 1 << 17))))
5651
            {
5652
              /* sign-extend */
5653
              if (e->X_add_number >= 0
5654
                  && (e->X_add_number & ((bfd_vma) 1 << 16)) != 0)
5655
                {
5656
                  e->X_add_number |= ~(((bfd_vma) 1 << 17) - 1);
5657
                }
5658
              return OPERAND_MATCH;
5659
            }
5660
          else
5661
            return OPERAND_OUT_OF_RANGE;
5662
        }
5663
      break;
5664
 
5665
    case IA64_OPND_IMM14:
5666
    case IA64_OPND_IMM22:
5667
      relocatable = 1;
5668
    case IA64_OPND_IMM1:
5669
    case IA64_OPND_IMM8:
5670
    case IA64_OPND_IMM8U4:
5671
    case IA64_OPND_IMM8M1:
5672
    case IA64_OPND_IMM8M1U4:
5673
    case IA64_OPND_IMM8M1U8:
5674
    case IA64_OPND_IMM9a:
5675
    case IA64_OPND_IMM9b:
5676
      bits = operand_width (idesc->operands[index]);
5677
      if (relocatable && (e->X_op == O_symbol
5678
                          || e->X_op == O_subtract
5679
                          || e->X_op == O_pseudo_fixup))
5680
        {
5681
          fix = CURR_SLOT.fixup + CURR_SLOT.num_fixups;
5682
 
5683
          if (idesc->operands[index] == IA64_OPND_IMM14)
5684
            fix->code = BFD_RELOC_IA64_IMM14;
5685
          else
5686
            fix->code = BFD_RELOC_IA64_IMM22;
5687
 
5688
          if (e->X_op != O_subtract)
5689
            {
5690
              fix->code = ia64_gen_real_reloc_type (e->X_op_symbol, fix->code);
5691
              if (e->X_op == O_pseudo_fixup)
5692
                e->X_op = O_symbol;
5693
            }
5694
 
5695
          fix->opnd = idesc->operands[index];
5696
          fix->expr = *e;
5697
          fix->is_pcrel = 0;
5698
          ++CURR_SLOT.num_fixups;
5699
          return OPERAND_MATCH;
5700
        }
5701
      else if (e->X_op != O_constant
5702
               && ! (e->X_op == O_big && opnd == IA64_OPND_IMM8M1U8))
5703
        return OPERAND_MISMATCH;
5704
 
5705
      if (opnd == IA64_OPND_IMM8M1U4)
5706
        {
5707
          /* Zero is not valid for unsigned compares that take an adjusted
5708
             constant immediate range.  */
5709
          if (e->X_add_number == 0)
5710
            return OPERAND_OUT_OF_RANGE;
5711
 
5712
          /* Sign-extend 32-bit unsigned numbers, so that the following range
5713
             checks will work.  */
5714
          val = e->X_add_number;
5715
          if (((val & (~(bfd_vma) 0 << 32)) == 0)
5716
              && ((val & ((bfd_vma) 1 << 31)) != 0))
5717
            val = ((val << 32) >> 32);
5718
 
5719
          /* Check for 0x100000000.  This is valid because
5720
             0x100000000-1 is the same as ((uint32_t) -1).  */
5721
          if (val == ((bfd_signed_vma) 1 << 32))
5722
            return OPERAND_MATCH;
5723
 
5724
          val = val - 1;
5725
        }
5726
      else if (opnd == IA64_OPND_IMM8M1U8)
5727
        {
5728
          /* Zero is not valid for unsigned compares that take an adjusted
5729
             constant immediate range.  */
5730
          if (e->X_add_number == 0)
5731
            return OPERAND_OUT_OF_RANGE;
5732
 
5733
          /* Check for 0x10000000000000000.  */
5734
          if (e->X_op == O_big)
5735
            {
5736
              if (generic_bignum[0] == 0
5737
                  && generic_bignum[1] == 0
5738
                  && generic_bignum[2] == 0
5739
                  && generic_bignum[3] == 0
5740
                  && generic_bignum[4] == 1)
5741
                return OPERAND_MATCH;
5742
              else
5743
                return OPERAND_OUT_OF_RANGE;
5744
            }
5745
          else
5746
            val = e->X_add_number - 1;
5747
        }
5748
      else if (opnd == IA64_OPND_IMM8M1)
5749
        val = e->X_add_number - 1;
5750
      else if (opnd == IA64_OPND_IMM8U4)
5751
        {
5752
          /* Sign-extend 32-bit unsigned numbers, so that the following range
5753
             checks will work.  */
5754
          val = e->X_add_number;
5755
          if (((val & (~(bfd_vma) 0 << 32)) == 0)
5756
              && ((val & ((bfd_vma) 1 << 31)) != 0))
5757
            val = ((val << 32) >> 32);
5758
        }
5759
      else
5760
        val = e->X_add_number;
5761
 
5762
      if ((val >= 0 && (bfd_vma) val < ((bfd_vma) 1 << (bits - 1)))
5763
          || (val < 0 && (bfd_vma) -val <= ((bfd_vma) 1 << (bits - 1))))
5764
        return OPERAND_MATCH;
5765
      else
5766
        return OPERAND_OUT_OF_RANGE;
5767
 
5768
    case IA64_OPND_INC3:
5769
      /* +/- 1, 4, 8, 16 */
5770
      val = e->X_add_number;
5771
      if (val < 0)
5772
        val = -val;
5773
      if (e->X_op == O_constant)
5774
        {
5775
          if ((val == 1 || val == 4 || val == 8 || val == 16))
5776
            return OPERAND_MATCH;
5777
          else
5778
            return OPERAND_OUT_OF_RANGE;
5779
        }
5780
      break;
5781
 
5782
    case IA64_OPND_TGT25:
5783
    case IA64_OPND_TGT25b:
5784
    case IA64_OPND_TGT25c:
5785
    case IA64_OPND_TGT64:
5786
      if (e->X_op == O_symbol)
5787
        {
5788
          fix = CURR_SLOT.fixup + CURR_SLOT.num_fixups;
5789
          if (opnd == IA64_OPND_TGT25)
5790
            fix->code = BFD_RELOC_IA64_PCREL21F;
5791
          else if (opnd == IA64_OPND_TGT25b)
5792
            fix->code = BFD_RELOC_IA64_PCREL21M;
5793
          else if (opnd == IA64_OPND_TGT25c)
5794
            fix->code = BFD_RELOC_IA64_PCREL21B;
5795
          else if (opnd == IA64_OPND_TGT64)
5796
            fix->code = BFD_RELOC_IA64_PCREL60B;
5797
          else
5798
            abort ();
5799
 
5800
          fix->code = ia64_gen_real_reloc_type (e->X_op_symbol, fix->code);
5801
          fix->opnd = idesc->operands[index];
5802
          fix->expr = *e;
5803
          fix->is_pcrel = 1;
5804
          ++CURR_SLOT.num_fixups;
5805
          return OPERAND_MATCH;
5806
        }
5807
    case IA64_OPND_TAG13:
5808
    case IA64_OPND_TAG13b:
5809
      switch (e->X_op)
5810
        {
5811
        case O_constant:
5812
          return OPERAND_MATCH;
5813
 
5814
        case O_symbol:
5815
          fix = CURR_SLOT.fixup + CURR_SLOT.num_fixups;
5816
          /* There are no external relocs for TAG13/TAG13b fields, so we
5817
             create a dummy reloc.  This will not live past md_apply_fix.  */
5818
          fix->code = BFD_RELOC_UNUSED;
5819
          fix->code = ia64_gen_real_reloc_type (e->X_op_symbol, fix->code);
5820
          fix->opnd = idesc->operands[index];
5821
          fix->expr = *e;
5822
          fix->is_pcrel = 1;
5823
          ++CURR_SLOT.num_fixups;
5824
          return OPERAND_MATCH;
5825
 
5826
        default:
5827
          break;
5828
        }
5829
      break;
5830
 
5831
    case IA64_OPND_LDXMOV:
5832
      fix = CURR_SLOT.fixup + CURR_SLOT.num_fixups;
5833
      fix->code = BFD_RELOC_IA64_LDXMOV;
5834
      fix->opnd = idesc->operands[index];
5835
      fix->expr = *e;
5836
      fix->is_pcrel = 0;
5837
      ++CURR_SLOT.num_fixups;
5838
      return OPERAND_MATCH;
5839
 
5840
    default:
5841
      break;
5842
    }
5843
  return OPERAND_MISMATCH;
5844
}
5845
 
5846
static int
5847
parse_operand (expressionS *e, int more)
5848
{
5849
  int sep = '\0';
5850
 
5851
  memset (e, 0, sizeof (*e));
5852
  e->X_op = O_absent;
5853
  SKIP_WHITESPACE ();
5854
  expression (e);
5855
  sep = *input_line_pointer;
5856
  if (more && (sep == ',' || sep == more))
5857
    ++input_line_pointer;
5858
  return sep;
5859
}
5860
 
5861
static int
5862
parse_operand_and_eval (expressionS *e, int more)
5863
{
5864
  int sep = parse_operand (e, more);
5865
  resolve_expression (e);
5866
  return sep;
5867
}
5868
 
5869
static int
5870
parse_operand_maybe_eval (expressionS *e, int more, enum ia64_opnd op)
5871
{
5872
  int sep = parse_operand (e, more);
5873
  switch (op)
5874
    {
5875
    case IA64_OPND_IMM14:
5876
    case IA64_OPND_IMM22:
5877
    case IA64_OPND_IMMU64:
5878
    case IA64_OPND_TGT25:
5879
    case IA64_OPND_TGT25b:
5880
    case IA64_OPND_TGT25c:
5881
    case IA64_OPND_TGT64:
5882
    case IA64_OPND_TAG13:
5883
    case IA64_OPND_TAG13b:
5884
    case IA64_OPND_LDXMOV:
5885
      break;
5886
    default:
5887
      resolve_expression (e);
5888
      break;
5889
    }
5890
  return sep;
5891
}
5892
 
5893
/* Returns the next entry in the opcode table that matches the one in
5894
   IDESC, and frees the entry in IDESC.  If no matching entry is
5895
   found, NULL is returned instead.  */
5896
 
5897
static struct ia64_opcode *
5898
get_next_opcode (struct ia64_opcode *idesc)
5899
{
5900
  struct ia64_opcode *next = ia64_find_next_opcode (idesc);
5901
  ia64_free_opcode (idesc);
5902
  return next;
5903
}
5904
 
5905
/* Parse the operands for the opcode and find the opcode variant that
5906
   matches the specified operands, or NULL if no match is possible.  */
5907
 
5908
static struct ia64_opcode *
5909
parse_operands (struct ia64_opcode *idesc)
5910
{
5911
  int i = 0, highest_unmatched_operand, num_operands = 0, num_outputs = 0;
5912
  int error_pos, out_of_range_pos, curr_out_of_range_pos, sep = 0;
5913
  int reg1, reg2;
5914
  char reg_class;
5915
  enum ia64_opnd expected_operand = IA64_OPND_NIL;
5916
  enum operand_match_result result;
5917
  char mnemonic[129];
5918
  char *first_arg = 0, *end, *saved_input_pointer;
5919
  unsigned int sof;
5920
 
5921
  gas_assert (strlen (idesc->name) <= 128);
5922
 
5923
  strcpy (mnemonic, idesc->name);
5924
  if (idesc->operands[2] == IA64_OPND_SOF
5925
      || idesc->operands[1] == IA64_OPND_SOF)
5926
    {
5927
      /* To make the common idiom "alloc loc?=ar.pfs,0,1,0,0" work, we
5928
         can't parse the first operand until we have parsed the
5929
         remaining operands of the "alloc" instruction.  */
5930
      SKIP_WHITESPACE ();
5931
      first_arg = input_line_pointer;
5932
      end = strchr (input_line_pointer, '=');
5933
      if (!end)
5934
        {
5935
          as_bad (_("Expected separator `='"));
5936
          return 0;
5937
        }
5938
      input_line_pointer = end + 1;
5939
      ++i;
5940
      ++num_outputs;
5941
    }
5942
 
5943
  for (; ; ++i)
5944
    {
5945
      if (i < NELEMS (CURR_SLOT.opnd))
5946
        {
5947
          sep = parse_operand_maybe_eval (CURR_SLOT.opnd + i, '=',
5948
                                          idesc->operands[i]);
5949
          if (CURR_SLOT.opnd[i].X_op == O_absent)
5950
            break;
5951
        }
5952
      else
5953
        {
5954
          expressionS dummy;
5955
 
5956
          sep = parse_operand (&dummy, '=');
5957
          if (dummy.X_op == O_absent)
5958
            break;
5959
        }
5960
 
5961
      ++num_operands;
5962
 
5963
      if (sep != '=' && sep != ',')
5964
        break;
5965
 
5966
      if (sep == '=')
5967
        {
5968
          if (num_outputs > 0)
5969
            as_bad (_("Duplicate equal sign (=) in instruction"));
5970
          else
5971
            num_outputs = i + 1;
5972
        }
5973
    }
5974
  if (sep != '\0')
5975
    {
5976
      as_bad (_("Illegal operand separator `%c'"), sep);
5977
      return 0;
5978
    }
5979
 
5980
  if (idesc->operands[2] == IA64_OPND_SOF
5981
      || idesc->operands[1] == IA64_OPND_SOF)
5982
    {
5983
      /* Map alloc r1=ar.pfs,i,l,o,r to alloc r1=ar.pfs,(i+l+o),(i+l),r.
5984
         Note, however, that due to that mapping operand numbers in error
5985
         messages for any of the constant operands will not be correct.  */
5986
      know (strcmp (idesc->name, "alloc") == 0);
5987
      /* The first operand hasn't been parsed/initialized, yet (but
5988
         num_operands intentionally doesn't account for that).  */
5989
      i = num_operands > 4 ? 2 : 1;
5990
#define FORCE_CONST(n) (CURR_SLOT.opnd[n].X_op == O_constant \
5991
                        ? CURR_SLOT.opnd[n].X_add_number \
5992
                        : 0)
5993
      sof = set_regstack (FORCE_CONST(i),
5994
                          FORCE_CONST(i + 1),
5995
                          FORCE_CONST(i + 2),
5996
                          FORCE_CONST(i + 3));
5997
#undef FORCE_CONST
5998
 
5999
      /* now we can parse the first arg:  */
6000
      saved_input_pointer = input_line_pointer;
6001
      input_line_pointer = first_arg;
6002
      sep = parse_operand_maybe_eval (CURR_SLOT.opnd + 0, '=',
6003
                                      idesc->operands[0]);
6004
      if (sep != '=')
6005
        --num_outputs;  /* force error */
6006
      input_line_pointer = saved_input_pointer;
6007
 
6008
      CURR_SLOT.opnd[i].X_add_number = sof;
6009
      if (CURR_SLOT.opnd[i + 1].X_op == O_constant
6010
          && CURR_SLOT.opnd[i + 2].X_op == O_constant)
6011
        CURR_SLOT.opnd[i + 1].X_add_number
6012
          = sof - CURR_SLOT.opnd[i + 2].X_add_number;
6013
      else
6014
        CURR_SLOT.opnd[i + 1].X_op = O_illegal;
6015
      CURR_SLOT.opnd[i + 2] = CURR_SLOT.opnd[i + 3];
6016
    }
6017
 
6018
  highest_unmatched_operand = -4;
6019
  curr_out_of_range_pos = -1;
6020
  error_pos = 0;
6021
  for (; idesc; idesc = get_next_opcode (idesc))
6022
    {
6023
      if (num_outputs != idesc->num_outputs)
6024
        continue;               /* mismatch in # of outputs */
6025
      if (highest_unmatched_operand < 0)
6026
        highest_unmatched_operand |= 1;
6027
      if (num_operands > NELEMS (idesc->operands)
6028
          || (num_operands < NELEMS (idesc->operands)
6029
           && idesc->operands[num_operands])
6030
          || (num_operands > 0 && !idesc->operands[num_operands - 1]))
6031
        continue;               /* mismatch in number of arguments */
6032
      if (highest_unmatched_operand < 0)
6033
        highest_unmatched_operand |= 2;
6034
 
6035
      CURR_SLOT.num_fixups = 0;
6036
 
6037
      /* Try to match all operands.  If we see an out-of-range operand,
6038
         then continue trying to match the rest of the operands, since if
6039
         the rest match, then this idesc will give the best error message.  */
6040
 
6041
      out_of_range_pos = -1;
6042
      for (i = 0; i < num_operands && idesc->operands[i]; ++i)
6043
        {
6044
          result = operand_match (idesc, i, CURR_SLOT.opnd + i);
6045
          if (result != OPERAND_MATCH)
6046
            {
6047
              if (result != OPERAND_OUT_OF_RANGE)
6048
                break;
6049
              if (out_of_range_pos < 0)
6050
                /* remember position of the first out-of-range operand: */
6051
                out_of_range_pos = i;
6052
            }
6053
        }
6054
 
6055
      /* If we did not match all operands, or if at least one operand was
6056
         out-of-range, then this idesc does not match.  Keep track of which
6057
         idesc matched the most operands before failing.  If we have two
6058
         idescs that failed at the same position, and one had an out-of-range
6059
         operand, then prefer the out-of-range operand.  Thus if we have
6060
         "add r0=0x1000000,r1" we get an error saying the constant is out
6061
         of range instead of an error saying that the constant should have been
6062
         a register.  */
6063
 
6064
      if (i != num_operands || out_of_range_pos >= 0)
6065
        {
6066
          if (i > highest_unmatched_operand
6067
              || (i == highest_unmatched_operand
6068
                  && out_of_range_pos > curr_out_of_range_pos))
6069
            {
6070
              highest_unmatched_operand = i;
6071
              if (out_of_range_pos >= 0)
6072
                {
6073
                  expected_operand = idesc->operands[out_of_range_pos];
6074
                  error_pos = out_of_range_pos;
6075
                }
6076
              else
6077
                {
6078
                  expected_operand = idesc->operands[i];
6079
                  error_pos = i;
6080
                }
6081
              curr_out_of_range_pos = out_of_range_pos;
6082
            }
6083
          continue;
6084
        }
6085
 
6086
      break;
6087
    }
6088
  if (!idesc)
6089
    {
6090
      if (expected_operand)
6091
        as_bad (_("Operand %u of `%s' should be %s"),
6092
                error_pos + 1, mnemonic,
6093
                elf64_ia64_operands[expected_operand].desc);
6094
      else if (highest_unmatched_operand < 0 && !(highest_unmatched_operand & 1))
6095
        as_bad (_("Wrong number of output operands"));
6096
      else if (highest_unmatched_operand < 0 && !(highest_unmatched_operand & 2))
6097
        as_bad (_("Wrong number of input operands"));
6098
      else
6099
        as_bad (_("Operand mismatch"));
6100
      return 0;
6101
    }
6102
 
6103
  /* Check that the instruction doesn't use
6104
     - r0, f0, or f1 as output operands
6105
     - the same predicate twice as output operands
6106
     - r0 as address of a base update load or store
6107
     - the same GR as output and address of a base update load
6108
     - two even- or two odd-numbered FRs as output operands of a floating
6109
       point parallel load.
6110
     At most two (conflicting) output (or output-like) operands can exist,
6111
     (floating point parallel loads have three outputs, but the base register,
6112
     if updated, cannot conflict with the actual outputs).  */
6113
  reg2 = reg1 = -1;
6114
  for (i = 0; i < num_operands; ++i)
6115
    {
6116
      int regno = 0;
6117
 
6118
      reg_class = 0;
6119
      switch (idesc->operands[i])
6120
        {
6121
        case IA64_OPND_R1:
6122
        case IA64_OPND_R2:
6123
        case IA64_OPND_R3:
6124
          if (i < num_outputs)
6125
            {
6126
              if (CURR_SLOT.opnd[i].X_add_number == REG_GR)
6127
                reg_class = 'r';
6128
              else if (reg1 < 0)
6129
                reg1 = CURR_SLOT.opnd[i].X_add_number;
6130
              else if (reg2 < 0)
6131
                reg2 = CURR_SLOT.opnd[i].X_add_number;
6132
            }
6133
          break;
6134
        case IA64_OPND_P1:
6135
        case IA64_OPND_P2:
6136
          if (i < num_outputs)
6137
            {
6138
              if (reg1 < 0)
6139
                reg1 = CURR_SLOT.opnd[i].X_add_number;
6140
              else if (reg2 < 0)
6141
                reg2 = CURR_SLOT.opnd[i].X_add_number;
6142
            }
6143
          break;
6144
        case IA64_OPND_F1:
6145
        case IA64_OPND_F2:
6146
        case IA64_OPND_F3:
6147
        case IA64_OPND_F4:
6148
          if (i < num_outputs)
6149
            {
6150
              if (CURR_SLOT.opnd[i].X_add_number >= REG_FR
6151
                  && CURR_SLOT.opnd[i].X_add_number <= REG_FR + 1)
6152
                {
6153
                  reg_class = 'f';
6154
                  regno = CURR_SLOT.opnd[i].X_add_number - REG_FR;
6155
                }
6156
              else if (reg1 < 0)
6157
                reg1 = CURR_SLOT.opnd[i].X_add_number;
6158
              else if (reg2 < 0)
6159
                reg2 = CURR_SLOT.opnd[i].X_add_number;
6160
            }
6161
          break;
6162
        case IA64_OPND_MR3:
6163
          if (idesc->flags & IA64_OPCODE_POSTINC)
6164
            {
6165
              if (CURR_SLOT.opnd[i].X_add_number == REG_GR)
6166
                reg_class = 'm';
6167
              else if (reg1 < 0)
6168
                reg1 = CURR_SLOT.opnd[i].X_add_number;
6169
              else if (reg2 < 0)
6170
                reg2 = CURR_SLOT.opnd[i].X_add_number;
6171
            }
6172
          break;
6173
        default:
6174
          break;
6175
        }
6176
      switch (reg_class)
6177
        {
6178
        case 0:
6179
          break;
6180
        default:
6181
          as_warn (_("Invalid use of `%c%d' as output operand"), reg_class, regno);
6182
          break;
6183
        case 'm':
6184
          as_warn (_("Invalid use of `r%d' as base update address operand"), regno);
6185
          break;
6186
        }
6187
    }
6188
  if (reg1 == reg2)
6189
    {
6190
      if (reg1 >= REG_GR && reg1 <= REG_GR + 127)
6191
        {
6192
          reg1 -= REG_GR;
6193
          reg_class = 'r';
6194
        }
6195
      else if (reg1 >= REG_P && reg1 <= REG_P + 63)
6196
        {
6197
          reg1 -= REG_P;
6198
          reg_class = 'p';
6199
        }
6200
      else if (reg1 >= REG_FR && reg1 <= REG_FR + 127)
6201
        {
6202
          reg1 -= REG_FR;
6203
          reg_class = 'f';
6204
        }
6205
      else
6206
        reg_class = 0;
6207
      if (reg_class)
6208
        as_warn (_("Invalid duplicate use of `%c%d'"), reg_class, reg1);
6209
    }
6210
  else if (((reg1 >= REG_FR && reg1 <= REG_FR + 31
6211
             && reg2 >= REG_FR && reg2 <= REG_FR + 31)
6212
            || (reg1 >= REG_FR + 32 && reg1 <= REG_FR + 127
6213
             && reg2 >= REG_FR + 32 && reg2 <= REG_FR + 127))
6214
           && ! ((reg1 ^ reg2) & 1))
6215
    as_warn (_("Invalid simultaneous use of `f%d' and `f%d'"),
6216
             reg1 - REG_FR, reg2 - REG_FR);
6217
  else if ((reg1 >= REG_FR && reg1 <= REG_FR + 31
6218
            && reg2 >= REG_FR + 32 && reg2 <= REG_FR + 127)
6219
           || (reg1 >= REG_FR + 32 && reg1 <= REG_FR + 127
6220
            && reg2 >= REG_FR && reg2 <= REG_FR + 31))
6221
    as_warn (_("Dangerous simultaneous use of `f%d' and `f%d'"),
6222
             reg1 - REG_FR, reg2 - REG_FR);
6223
  return idesc;
6224
}
6225
 
6226
static void
6227
build_insn (struct slot *slot, bfd_vma *insnp)
6228
{
6229
  const struct ia64_operand *odesc, *o2desc;
6230
  struct ia64_opcode *idesc = slot->idesc;
6231
  bfd_vma insn;
6232
  bfd_signed_vma val;
6233
  const char *err;
6234
  int i;
6235
 
6236
  insn = idesc->opcode | slot->qp_regno;
6237
 
6238
  for (i = 0; i < NELEMS (idesc->operands) && idesc->operands[i]; ++i)
6239
    {
6240
      if (slot->opnd[i].X_op == O_register
6241
          || slot->opnd[i].X_op == O_constant
6242
          || slot->opnd[i].X_op == O_index)
6243
        val = slot->opnd[i].X_add_number;
6244
      else if (slot->opnd[i].X_op == O_big)
6245
        {
6246
          /* This must be the value 0x10000000000000000.  */
6247
          gas_assert (idesc->operands[i] == IA64_OPND_IMM8M1U8);
6248
          val = 0;
6249
        }
6250
      else
6251
        val = 0;
6252
 
6253
      switch (idesc->operands[i])
6254
        {
6255
        case IA64_OPND_IMMU64:
6256
          *insnp++ = (val >> 22) & 0x1ffffffffffLL;
6257
          insn |= (((val & 0x7f) << 13) | (((val >> 7) & 0x1ff) << 27)
6258
                   | (((val >> 16) & 0x1f) << 22) | (((val >> 21) & 0x1) << 21)
6259
                   | (((val >> 63) & 0x1) << 36));
6260
          continue;
6261
 
6262
        case IA64_OPND_IMMU62:
6263
          val &= 0x3fffffffffffffffULL;
6264
          if (val != slot->opnd[i].X_add_number)
6265
            as_warn (_("Value truncated to 62 bits"));
6266
          *insnp++ = (val >> 21) & 0x1ffffffffffLL;
6267
          insn |= (((val & 0xfffff) << 6) | (((val >> 20) & 0x1) << 36));
6268
          continue;
6269
 
6270
        case IA64_OPND_TGT64:
6271
          val >>= 4;
6272
          *insnp++ = ((val >> 20) & 0x7fffffffffLL) << 2;
6273
          insn |= ((((val >> 59) & 0x1) << 36)
6274
                   | (((val >> 0) & 0xfffff) << 13));
6275
          continue;
6276
 
6277
        case IA64_OPND_AR3:
6278
          val -= REG_AR;
6279
          break;
6280
 
6281
        case IA64_OPND_B1:
6282
        case IA64_OPND_B2:
6283
          val -= REG_BR;
6284
          break;
6285
 
6286
        case IA64_OPND_CR3:
6287
          val -= REG_CR;
6288
          break;
6289
 
6290
        case IA64_OPND_F1:
6291
        case IA64_OPND_F2:
6292
        case IA64_OPND_F3:
6293
        case IA64_OPND_F4:
6294
          val -= REG_FR;
6295
          break;
6296
 
6297
        case IA64_OPND_P1:
6298
        case IA64_OPND_P2:
6299
          val -= REG_P;
6300
          break;
6301
 
6302
        case IA64_OPND_R1:
6303
        case IA64_OPND_R2:
6304
        case IA64_OPND_R3:
6305
        case IA64_OPND_R3_2:
6306
        case IA64_OPND_CPUID_R3:
6307
        case IA64_OPND_DBR_R3:
6308
        case IA64_OPND_DTR_R3:
6309
        case IA64_OPND_ITR_R3:
6310
        case IA64_OPND_IBR_R3:
6311
        case IA64_OPND_MR3:
6312
        case IA64_OPND_MSR_R3:
6313
        case IA64_OPND_PKR_R3:
6314
        case IA64_OPND_PMC_R3:
6315
        case IA64_OPND_PMD_R3:
6316
        case IA64_OPND_RR_R3:
6317
          val -= REG_GR;
6318
          break;
6319
 
6320
        default:
6321
          break;
6322
        }
6323
 
6324
      odesc = elf64_ia64_operands + idesc->operands[i];
6325
      err = (*odesc->insert) (odesc, val, &insn);
6326
      if (err)
6327
        as_bad_where (slot->src_file, slot->src_line,
6328
                      _("Bad operand value: %s"), err);
6329
      if (idesc->flags & IA64_OPCODE_PSEUDO)
6330
        {
6331
          if ((idesc->flags & IA64_OPCODE_F2_EQ_F3)
6332
              && odesc == elf64_ia64_operands + IA64_OPND_F3)
6333
            {
6334
              o2desc = elf64_ia64_operands + IA64_OPND_F2;
6335
              (*o2desc->insert) (o2desc, val, &insn);
6336
            }
6337
          if ((idesc->flags & IA64_OPCODE_LEN_EQ_64MCNT)
6338
              && (odesc == elf64_ia64_operands + IA64_OPND_CPOS6a
6339
                  || odesc == elf64_ia64_operands + IA64_OPND_POS6))
6340
            {
6341
              o2desc = elf64_ia64_operands + IA64_OPND_LEN6;
6342
              (*o2desc->insert) (o2desc, 64 - val, &insn);
6343
            }
6344
        }
6345
    }
6346
  *insnp = insn;
6347
}
6348
 
6349
static void
6350
emit_one_bundle (void)
6351
{
6352
  int manual_bundling_off = 0, manual_bundling = 0;
6353
  enum ia64_unit required_unit, insn_unit = 0;
6354
  enum ia64_insn_type type[3], insn_type;
6355
  unsigned int template_val, orig_template;
6356
  bfd_vma insn[3] = { -1, -1, -1 };
6357
  struct ia64_opcode *idesc;
6358
  int end_of_insn_group = 0, user_template = -1;
6359
  int n, i, j, first, curr, last_slot;
6360
  bfd_vma t0 = 0, t1 = 0;
6361
  struct label_fix *lfix;
6362
  bfd_boolean mark_label;
6363
  struct insn_fix *ifix;
6364
  char mnemonic[16];
6365
  fixS *fix;
6366
  char *f;
6367
  int addr_mod;
6368
 
6369
  first = (md.curr_slot + NUM_SLOTS - md.num_slots_in_use) % NUM_SLOTS;
6370
  know (first >= 0 && first < NUM_SLOTS);
6371
  n = MIN (3, md.num_slots_in_use);
6372
 
6373
  /* Determine template: user user_template if specified, best match
6374
     otherwise:  */
6375
 
6376
  if (md.slot[first].user_template >= 0)
6377
    user_template = template_val = md.slot[first].user_template;
6378
  else
6379
    {
6380
      /* Auto select appropriate template.  */
6381
      memset (type, 0, sizeof (type));
6382
      curr = first;
6383
      for (i = 0; i < n; ++i)
6384
        {
6385
          if (md.slot[curr].label_fixups && i != 0)
6386
            break;
6387
          type[i] = md.slot[curr].idesc->type;
6388
          curr = (curr + 1) % NUM_SLOTS;
6389
        }
6390
      template_val = best_template[type[0]][type[1]][type[2]];
6391
    }
6392
 
6393
  /* initialize instructions with appropriate nops:  */
6394
  for (i = 0; i < 3; ++i)
6395
    insn[i] = nop[ia64_templ_desc[template_val].exec_unit[i]];
6396
 
6397
  f = frag_more (16);
6398
 
6399
  /* Check to see if this bundle is at an offset that is a multiple of 16-bytes
6400
     from the start of the frag.  */
6401
  addr_mod = frag_now_fix () & 15;
6402
  if (frag_now->has_code && frag_now->insn_addr != addr_mod)
6403
    as_bad (_("instruction address is not a multiple of 16"));
6404
  frag_now->insn_addr = addr_mod;
6405
  frag_now->has_code = 1;
6406
 
6407
  /* now fill in slots with as many insns as possible:  */
6408
  curr = first;
6409
  idesc = md.slot[curr].idesc;
6410
  end_of_insn_group = 0;
6411
  last_slot = -1;
6412
  for (i = 0; i < 3 && md.num_slots_in_use > 0; ++i)
6413
    {
6414
      /* If we have unwind records, we may need to update some now.  */
6415
      unw_rec_list *ptr = md.slot[curr].unwind_record;
6416
      unw_rec_list *end_ptr = NULL;
6417
 
6418
      if (ptr)
6419
        {
6420
          /* Find the last prologue/body record in the list for the current
6421
             insn, and set the slot number for all records up to that point.
6422
             This needs to be done now, because prologue/body records refer to
6423
             the current point, not the point after the instruction has been
6424
             issued.  This matters because there may have been nops emitted
6425
             meanwhile.  Any non-prologue non-body record followed by a
6426
             prologue/body record must also refer to the current point.  */
6427
          unw_rec_list *last_ptr;
6428
 
6429
          for (j = 1; end_ptr == NULL && j < md.num_slots_in_use; ++j)
6430
            end_ptr = md.slot[(curr + j) % NUM_SLOTS].unwind_record;
6431
          for (last_ptr = NULL; ptr != end_ptr; ptr = ptr->next)
6432
            if (ptr->r.type == prologue || ptr->r.type == prologue_gr
6433
                || ptr->r.type == body)
6434
              last_ptr = ptr;
6435
          if (last_ptr)
6436
            {
6437
              /* Make last_ptr point one after the last prologue/body
6438
                 record.  */
6439
              last_ptr = last_ptr->next;
6440
              for (ptr = md.slot[curr].unwind_record; ptr != last_ptr;
6441
                   ptr = ptr->next)
6442
                {
6443
                  ptr->slot_number = (unsigned long) f + i;
6444
                  ptr->slot_frag = frag_now;
6445
                }
6446
              /* Remove the initialized records, so that we won't accidentally
6447
                 update them again if we insert a nop and continue.  */
6448
              md.slot[curr].unwind_record = last_ptr;
6449
            }
6450
        }
6451
 
6452
      manual_bundling_off = md.slot[curr].manual_bundling_off;
6453
      if (md.slot[curr].manual_bundling_on)
6454
        {
6455
          if (curr == first)
6456
            manual_bundling = 1;
6457
          else
6458
          break; /* Need to start a new bundle.  */
6459
        }
6460
 
6461
      /* If this instruction specifies a template, then it must be the first
6462
         instruction of a bundle.  */
6463
      if (curr != first && md.slot[curr].user_template >= 0)
6464
        break;
6465
 
6466
      if (idesc->flags & IA64_OPCODE_SLOT2)
6467
        {
6468
          if (manual_bundling && !manual_bundling_off)
6469
            {
6470
              as_bad_where (md.slot[curr].src_file, md.slot[curr].src_line,
6471
                            _("`%s' must be last in bundle"), idesc->name);
6472
              if (i < 2)
6473
                manual_bundling = -1; /* Suppress meaningless post-loop errors.  */
6474
            }
6475
          i = 2;
6476
        }
6477
      if (idesc->flags & IA64_OPCODE_LAST)
6478
        {
6479
          int required_slot;
6480
          unsigned int required_template;
6481
 
6482
          /* If we need a stop bit after an M slot, our only choice is
6483
             template 5 (M;;MI).  If we need a stop bit after a B
6484
             slot, our only choice is to place it at the end of the
6485
             bundle, because the only available templates are MIB,
6486
             MBB, BBB, MMB, and MFB.  We don't handle anything other
6487
             than M and B slots because these are the only kind of
6488
             instructions that can have the IA64_OPCODE_LAST bit set.  */
6489
          required_template = template_val;
6490
          switch (idesc->type)
6491
            {
6492
            case IA64_TYPE_M:
6493
              required_slot = 0;
6494
              required_template = 5;
6495
              break;
6496
 
6497
            case IA64_TYPE_B:
6498
              required_slot = 2;
6499
              break;
6500
 
6501
            default:
6502
              as_bad_where (md.slot[curr].src_file, md.slot[curr].src_line,
6503
                            _("Internal error: don't know how to force %s to end of instruction group"),
6504
                            idesc->name);
6505
              required_slot = i;
6506
              break;
6507
            }
6508
          if (manual_bundling
6509
              && (i > required_slot
6510
                  || (required_slot == 2 && !manual_bundling_off)
6511
                  || (user_template >= 0
6512
                      /* Changing from MMI to M;MI is OK.  */
6513
                      && (template_val ^ required_template) > 1)))
6514
            {
6515
              as_bad_where (md.slot[curr].src_file, md.slot[curr].src_line,
6516
                            _("`%s' must be last in instruction group"),
6517
                            idesc->name);
6518
              if (i < 2 && required_slot == 2 && !manual_bundling_off)
6519
                manual_bundling = -1; /* Suppress meaningless post-loop errors.  */
6520
            }
6521
          if (required_slot < i)
6522
            /* Can't fit this instruction.  */
6523
            break;
6524
 
6525
          i = required_slot;
6526
          if (required_template != template_val)
6527
            {
6528
              /* If we switch the template, we need to reset the NOPs
6529
                 after slot i.  The slot-types of the instructions ahead
6530
                 of i never change, so we don't need to worry about
6531
                 changing NOPs in front of this slot.  */
6532
              for (j = i; j < 3; ++j)
6533
                insn[j] = nop[ia64_templ_desc[required_template].exec_unit[j]];
6534
 
6535
              /* We just picked a template that includes the stop bit in the
6536
                 middle, so we don't need another one emitted later.  */
6537
              md.slot[curr].end_of_insn_group = 0;
6538
            }
6539
          template_val = required_template;
6540
        }
6541
      if (curr != first && md.slot[curr].label_fixups)
6542
        {
6543
          if (manual_bundling)
6544
            {
6545
              as_bad_where (md.slot[curr].src_file, md.slot[curr].src_line,
6546
                            _("Label must be first in a bundle"));
6547
              manual_bundling = -1; /* Suppress meaningless post-loop errors.  */
6548
            }
6549
          /* This insn must go into the first slot of a bundle.  */
6550
          break;
6551
        }
6552
 
6553
      if (end_of_insn_group && md.num_slots_in_use >= 1)
6554
        {
6555
          /* We need an instruction group boundary in the middle of a
6556
             bundle.  See if we can switch to an other template with
6557
             an appropriate boundary.  */
6558
 
6559
          orig_template = template_val;
6560
          if (i == 1 && (user_template == 4
6561
                         || (user_template < 0
6562
                             && (ia64_templ_desc[template_val].exec_unit[0]
6563
                                 == IA64_UNIT_M))))
6564
            {
6565
              template_val = 5;
6566
              end_of_insn_group = 0;
6567
            }
6568
          else if (i == 2 && (user_template == 0
6569
                              || (user_template < 0
6570
                                  && (ia64_templ_desc[template_val].exec_unit[1]
6571
                                      == IA64_UNIT_I)))
6572
                   /* This test makes sure we don't switch the template if
6573
                      the next instruction is one that needs to be first in
6574
                      an instruction group.  Since all those instructions are
6575
                      in the M group, there is no way such an instruction can
6576
                      fit in this bundle even if we switch the template.  The
6577
                      reason we have to check for this is that otherwise we
6578
                      may end up generating "MI;;I M.." which has the deadly
6579
                      effect that the second M instruction is no longer the
6580
                      first in the group! --davidm 99/12/16  */
6581
                   && (idesc->flags & IA64_OPCODE_FIRST) == 0)
6582
            {
6583
              template_val = 1;
6584
              end_of_insn_group = 0;
6585
            }
6586
          else if (i == 1
6587
                   && user_template == 0
6588
                   && !(idesc->flags & IA64_OPCODE_FIRST))
6589
            /* Use the next slot.  */
6590
            continue;
6591
          else if (curr != first)
6592
            /* can't fit this insn */
6593
            break;
6594
 
6595
          if (template_val != orig_template)
6596
            /* if we switch the template, we need to reset the NOPs
6597
               after slot i.  The slot-types of the instructions ahead
6598
               of i never change, so we don't need to worry about
6599
               changing NOPs in front of this slot.  */
6600
            for (j = i; j < 3; ++j)
6601
              insn[j] = nop[ia64_templ_desc[template_val].exec_unit[j]];
6602
        }
6603
      required_unit = ia64_templ_desc[template_val].exec_unit[i];
6604
 
6605
      /* resolve dynamic opcodes such as "break", "hint", and "nop":  */
6606
      if (idesc->type == IA64_TYPE_DYN)
6607
        {
6608
          enum ia64_opnd opnd1, opnd2;
6609
 
6610
          if ((strcmp (idesc->name, "nop") == 0)
6611
              || (strcmp (idesc->name, "break") == 0))
6612
            insn_unit = required_unit;
6613
          else if (strcmp (idesc->name, "hint") == 0)
6614
            {
6615
              insn_unit = required_unit;
6616
              if (required_unit == IA64_UNIT_B)
6617
                {
6618
                  switch (md.hint_b)
6619
                    {
6620
                    case hint_b_ok:
6621
                      break;
6622
                    case hint_b_warning:
6623
                      as_warn (_("hint in B unit may be treated as nop"));
6624
                      break;
6625
                    case hint_b_error:
6626
                      /* When manual bundling is off and there is no
6627
                         user template, we choose a different unit so
6628
                         that hint won't go into the current slot. We
6629
                         will fill the current bundle with nops and
6630
                         try to put hint into the next bundle.  */
6631
                      if (!manual_bundling && user_template < 0)
6632
                        insn_unit = IA64_UNIT_I;
6633
                      else
6634
                        as_bad (_("hint in B unit can't be used"));
6635
                      break;
6636
                    }
6637
                }
6638
            }
6639
          else if (strcmp (idesc->name, "chk.s") == 0
6640
              || strcmp (idesc->name, "mov") == 0)
6641
            {
6642
              insn_unit = IA64_UNIT_M;
6643
              if (required_unit == IA64_UNIT_I
6644
                  || (required_unit == IA64_UNIT_F && template_val == 6))
6645
                insn_unit = IA64_UNIT_I;
6646
            }
6647
          else
6648
            as_fatal (_("emit_one_bundle: unexpected dynamic op"));
6649
 
6650
          snprintf (mnemonic, sizeof (mnemonic), "%s.%c",
6651
                    idesc->name, "?imbfxx"[insn_unit]);
6652
          opnd1 = idesc->operands[0];
6653
          opnd2 = idesc->operands[1];
6654
          ia64_free_opcode (idesc);
6655
          idesc = ia64_find_opcode (mnemonic);
6656
          /* moves to/from ARs have collisions */
6657
          if (opnd1 == IA64_OPND_AR3 || opnd2 == IA64_OPND_AR3)
6658
            {
6659
              while (idesc != NULL
6660
                     && (idesc->operands[0] != opnd1
6661
                         || idesc->operands[1] != opnd2))
6662
                idesc = get_next_opcode (idesc);
6663
            }
6664
          md.slot[curr].idesc = idesc;
6665
        }
6666
      else
6667
        {
6668
          insn_type = idesc->type;
6669
          insn_unit = IA64_UNIT_NIL;
6670
          switch (insn_type)
6671
            {
6672
            case IA64_TYPE_A:
6673
              if (required_unit == IA64_UNIT_I || required_unit == IA64_UNIT_M)
6674
                insn_unit = required_unit;
6675
              break;
6676
            case IA64_TYPE_X: insn_unit = IA64_UNIT_L; break;
6677
            case IA64_TYPE_I: insn_unit = IA64_UNIT_I; break;
6678
            case IA64_TYPE_M: insn_unit = IA64_UNIT_M; break;
6679
            case IA64_TYPE_B: insn_unit = IA64_UNIT_B; break;
6680
            case IA64_TYPE_F: insn_unit = IA64_UNIT_F; break;
6681
            default:                                   break;
6682
            }
6683
        }
6684
 
6685
      if (insn_unit != required_unit)
6686
        continue;               /* Try next slot.  */
6687
 
6688
      /* Now is a good time to fix up the labels for this insn.  */
6689
      mark_label = FALSE;
6690
      for (lfix = md.slot[curr].label_fixups; lfix; lfix = lfix->next)
6691
        {
6692
          S_SET_VALUE (lfix->sym, frag_now_fix () - 16);
6693
          symbol_set_frag (lfix->sym, frag_now);
6694
          mark_label |= lfix->dw2_mark_labels;
6695
        }
6696
      for (lfix = md.slot[curr].tag_fixups; lfix; lfix = lfix->next)
6697
        {
6698
          S_SET_VALUE (lfix->sym, frag_now_fix () - 16 + i);
6699
          symbol_set_frag (lfix->sym, frag_now);
6700
        }
6701
 
6702
      if (debug_type == DEBUG_DWARF2
6703
          || md.slot[curr].loc_directive_seen
6704
          || mark_label)
6705
        {
6706
          bfd_vma addr = frag_now->fr_address + frag_now_fix () - 16 + i;
6707
 
6708
          md.slot[curr].loc_directive_seen = 0;
6709
          if (mark_label)
6710
            md.slot[curr].debug_line.flags |= DWARF2_FLAG_BASIC_BLOCK;
6711
 
6712
          dwarf2_gen_line_info (addr, &md.slot[curr].debug_line);
6713
        }
6714
 
6715
      build_insn (md.slot + curr, insn + i);
6716
 
6717
      ptr = md.slot[curr].unwind_record;
6718
      if (ptr)
6719
        {
6720
          /* Set slot numbers for all remaining unwind records belonging to the
6721
             current insn.  There can not be any prologue/body unwind records
6722
             here.  */
6723
          for (; ptr != end_ptr; ptr = ptr->next)
6724
            {
6725
              ptr->slot_number = (unsigned long) f + i;
6726
              ptr->slot_frag = frag_now;
6727
            }
6728
          md.slot[curr].unwind_record = NULL;
6729
        }
6730
 
6731
      if (required_unit == IA64_UNIT_L)
6732
        {
6733
          know (i == 1);
6734
          /* skip one slot for long/X-unit instructions */
6735
          ++i;
6736
        }
6737
      --md.num_slots_in_use;
6738
      last_slot = i;
6739
 
6740
      for (j = 0; j < md.slot[curr].num_fixups; ++j)
6741
        {
6742
          ifix = md.slot[curr].fixup + j;
6743
          fix = fix_new_exp (frag_now, frag_now_fix () - 16 + i, 8,
6744
                             &ifix->expr, ifix->is_pcrel, ifix->code);
6745
          fix->tc_fix_data.opnd = ifix->opnd;
6746
          fix->fx_file = md.slot[curr].src_file;
6747
          fix->fx_line = md.slot[curr].src_line;
6748
        }
6749
 
6750
      end_of_insn_group = md.slot[curr].end_of_insn_group;
6751
 
6752
      /* clear slot:  */
6753
      ia64_free_opcode (md.slot[curr].idesc);
6754
      memset (md.slot + curr, 0, sizeof (md.slot[curr]));
6755
      md.slot[curr].user_template = -1;
6756
 
6757
      if (manual_bundling_off)
6758
        {
6759
          manual_bundling = 0;
6760
          break;
6761
        }
6762
      curr = (curr + 1) % NUM_SLOTS;
6763
      idesc = md.slot[curr].idesc;
6764
    }
6765
 
6766
  /* A user template was specified, but the first following instruction did
6767
     not fit.  This can happen with or without manual bundling.  */
6768
  if (md.num_slots_in_use > 0 && last_slot < 0)
6769
    {
6770
      as_bad_where (md.slot[curr].src_file, md.slot[curr].src_line,
6771
                    _("`%s' does not fit into %s template"),
6772
                    idesc->name, ia64_templ_desc[template_val].name);
6773
      /* Drop first insn so we don't livelock.  */
6774
      --md.num_slots_in_use;
6775
      know (curr == first);
6776
      ia64_free_opcode (md.slot[curr].idesc);
6777
      memset (md.slot + curr, 0, sizeof (md.slot[curr]));
6778
      md.slot[curr].user_template = -1;
6779
    }
6780
  else if (manual_bundling > 0)
6781
    {
6782
      if (md.num_slots_in_use > 0)
6783
        {
6784
          if (last_slot >= 2)
6785
            as_bad_where (md.slot[curr].src_file, md.slot[curr].src_line,
6786
                          _("`%s' does not fit into bundle"), idesc->name);
6787
          else
6788
            {
6789
              const char *where;
6790
 
6791
              if (template_val == 2)
6792
                where = "X slot";
6793
              else if (last_slot == 0)
6794
                where = "slots 2 or 3";
6795
              else
6796
                where = "slot 3";
6797
              as_bad_where (md.slot[curr].src_file, md.slot[curr].src_line,
6798
                            _("`%s' can't go in %s of %s template"),
6799
                            idesc->name, where, ia64_templ_desc[template_val].name);
6800
            }
6801
        }
6802
      else
6803
        as_bad_where (md.slot[curr].src_file, md.slot[curr].src_line,
6804
                      _("Missing '}' at end of file"));
6805
    }
6806
 
6807
  know (md.num_slots_in_use < NUM_SLOTS);
6808
 
6809
  t0 = end_of_insn_group | (template_val << 1) | (insn[0] << 5) | (insn[1] << 46);
6810
  t1 = ((insn[1] >> 18) & 0x7fffff) | (insn[2] << 23);
6811
 
6812
  number_to_chars_littleendian (f + 0, t0, 8);
6813
  number_to_chars_littleendian (f + 8, t1, 8);
6814
}
6815
 
6816
int
6817
md_parse_option (int c, char *arg)
6818
{
6819
 
6820
  switch (c)
6821
    {
6822
    /* Switches from the Intel assembler.  */
6823
    case 'm':
6824
      if (strcmp (arg, "ilp64") == 0
6825
          || strcmp (arg, "lp64") == 0
6826
          || strcmp (arg, "p64") == 0)
6827
        {
6828
          md.flags |= EF_IA_64_ABI64;
6829
        }
6830
      else if (strcmp (arg, "ilp32") == 0)
6831
        {
6832
          md.flags &= ~EF_IA_64_ABI64;
6833
        }
6834
      else if (strcmp (arg, "le") == 0)
6835
        {
6836
          md.flags &= ~EF_IA_64_BE;
6837
          default_big_endian = 0;
6838
        }
6839
      else if (strcmp (arg, "be") == 0)
6840
        {
6841
          md.flags |= EF_IA_64_BE;
6842
          default_big_endian = 1;
6843
        }
6844
      else if (strncmp (arg, "unwind-check=", 13) == 0)
6845
        {
6846
          arg += 13;
6847
          if (strcmp (arg, "warning") == 0)
6848
            md.unwind_check = unwind_check_warning;
6849
          else if (strcmp (arg, "error") == 0)
6850
            md.unwind_check = unwind_check_error;
6851
          else
6852
            return 0;
6853
        }
6854
      else if (strncmp (arg, "hint.b=", 7) == 0)
6855
        {
6856
          arg += 7;
6857
          if (strcmp (arg, "ok") == 0)
6858
            md.hint_b = hint_b_ok;
6859
          else if (strcmp (arg, "warning") == 0)
6860
            md.hint_b = hint_b_warning;
6861
          else if (strcmp (arg, "error") == 0)
6862
            md.hint_b = hint_b_error;
6863
          else
6864
            return 0;
6865
        }
6866
      else if (strncmp (arg, "tune=", 5) == 0)
6867
        {
6868
          arg += 5;
6869
          if (strcmp (arg, "itanium1") == 0)
6870
            md.tune = itanium1;
6871
          else if (strcmp (arg, "itanium2") == 0)
6872
            md.tune = itanium2;
6873
          else
6874
            return 0;
6875
        }
6876
      else
6877
        return 0;
6878
      break;
6879
 
6880
    case 'N':
6881
      if (strcmp (arg, "so") == 0)
6882
        {
6883
          /* Suppress signon message.  */
6884
        }
6885
      else if (strcmp (arg, "pi") == 0)
6886
        {
6887
          /* Reject privileged instructions.  FIXME */
6888
        }
6889
      else if (strcmp (arg, "us") == 0)
6890
        {
6891
          /* Allow union of signed and unsigned range.  FIXME */
6892
        }
6893
      else if (strcmp (arg, "close_fcalls") == 0)
6894
        {
6895
          /* Do not resolve global function calls.  */
6896
        }
6897
      else
6898
        return 0;
6899
      break;
6900
 
6901
    case 'C':
6902
      /* temp[="prefix"]  Insert temporary labels into the object file
6903
                          symbol table prefixed by "prefix".
6904
                          Default prefix is ":temp:".
6905
       */
6906
      break;
6907
 
6908
    case 'a':
6909
      /* indirect=<tgt> Assume unannotated indirect branches behavior
6910
                        according to <tgt> --
6911
                        exit:   branch out from the current context (default)
6912
                        labels: all labels in context may be branch targets
6913
       */
6914
      if (strncmp (arg, "indirect=", 9) != 0)
6915
        return 0;
6916
      break;
6917
 
6918
    case 'x':
6919
      /* -X conflicts with an ignored option, use -x instead */
6920
      md.detect_dv = 1;
6921
      if (!arg || strcmp (arg, "explicit") == 0)
6922
        {
6923
          /* set default mode to explicit */
6924
          md.default_explicit_mode = 1;
6925
          break;
6926
        }
6927
      else if (strcmp (arg, "auto") == 0)
6928
        {
6929
          md.default_explicit_mode = 0;
6930
        }
6931
      else if (strcmp (arg, "none") == 0)
6932
        {
6933
          md.detect_dv = 0;
6934
        }
6935
      else if (strcmp (arg, "debug") == 0)
6936
        {
6937
          md.debug_dv = 1;
6938
        }
6939
      else if (strcmp (arg, "debugx") == 0)
6940
        {
6941
          md.default_explicit_mode = 1;
6942
          md.debug_dv = 1;
6943
        }
6944
      else if (strcmp (arg, "debugn") == 0)
6945
        {
6946
          md.debug_dv = 1;
6947
          md.detect_dv = 0;
6948
        }
6949
      else
6950
        {
6951
          as_bad (_("Unrecognized option '-x%s'"), arg);
6952
        }
6953
      break;
6954
 
6955
    case 'S':
6956
      /* nops           Print nops statistics.  */
6957
      break;
6958
 
6959
    /* GNU specific switches for gcc.  */
6960
    case OPTION_MCONSTANT_GP:
6961
      md.flags |= EF_IA_64_CONS_GP;
6962
      break;
6963
 
6964
    case OPTION_MAUTO_PIC:
6965
      md.flags |= EF_IA_64_NOFUNCDESC_CONS_GP;
6966
      break;
6967
 
6968
    default:
6969
      return 0;
6970
    }
6971
 
6972
  return 1;
6973
}
6974
 
6975
void
6976
md_show_usage (FILE *stream)
6977
{
6978
  fputs (_("\
6979
IA-64 options:\n\
6980
  --mconstant-gp          mark output file as using the constant-GP model\n\
6981
                          (sets ELF header flag EF_IA_64_CONS_GP)\n\
6982
  --mauto-pic             mark output file as using the constant-GP model\n\
6983
                          without function descriptors (sets ELF header flag\n\
6984
                          EF_IA_64_NOFUNCDESC_CONS_GP)\n\
6985
  -milp32|-milp64|-mlp64|-mp64  select data model (default -mlp64)\n\
6986
  -mle | -mbe             select little- or big-endian byte order (default -mle)\n\
6987
  -mtune=[itanium1|itanium2]\n\
6988
                          tune for a specific CPU (default -mtune=itanium2)\n\
6989
  -munwind-check=[warning|error]\n\
6990
                          unwind directive check (default -munwind-check=warning)\n\
6991
  -mhint.b=[ok|warning|error]\n\
6992
                          hint.b check (default -mhint.b=error)\n\
6993
  -x | -xexplicit         turn on dependency violation checking\n\
6994
  -xauto                  automagically remove dependency violations (default)\n\
6995
  -xnone                  turn off dependency violation checking\n\
6996
  -xdebug                 debug dependency violation checker\n\
6997
  -xdebugn                debug dependency violation checker but turn off\n\
6998
                          dependency violation checking\n\
6999
  -xdebugx                debug dependency violation checker and turn on\n\
7000
                          dependency violation checking\n"),
7001
        stream);
7002
}
7003
 
7004
void
7005
ia64_after_parse_args (void)
7006
{
7007
  if (debug_type == DEBUG_STABS)
7008
    as_fatal (_("--gstabs is not supported for ia64"));
7009
}
7010
 
7011
/* Return true if TYPE fits in TEMPL at SLOT.  */
7012
 
7013
static int
7014
match (int templ, int type, int slot)
7015
{
7016
  enum ia64_unit unit;
7017
  int result;
7018
 
7019
  unit = ia64_templ_desc[templ].exec_unit[slot];
7020
  switch (type)
7021
    {
7022
    case IA64_TYPE_DYN: result = 1; break; /* for nop and break */
7023
    case IA64_TYPE_A:
7024
      result = (unit == IA64_UNIT_I || unit == IA64_UNIT_M);
7025
      break;
7026
    case IA64_TYPE_X:   result = (unit == IA64_UNIT_L); break;
7027
    case IA64_TYPE_I:   result = (unit == IA64_UNIT_I); break;
7028
    case IA64_TYPE_M:   result = (unit == IA64_UNIT_M); break;
7029
    case IA64_TYPE_B:   result = (unit == IA64_UNIT_B); break;
7030
    case IA64_TYPE_F:   result = (unit == IA64_UNIT_F); break;
7031
    default:            result = 0; break;
7032
    }
7033
  return result;
7034
}
7035
 
7036
/* For Itanium 1, add a bit of extra goodness if a nop of type F or B would fit
7037
   in TEMPL at SLOT.  For Itanium 2, add a bit of extra goodness if a nop of
7038
   type M or I would fit in TEMPL at SLOT.  */
7039
 
7040
static inline int
7041
extra_goodness (int templ, int slot)
7042
{
7043
  switch (md.tune)
7044
    {
7045
    case itanium1:
7046
      if (slot == 1 && match (templ, IA64_TYPE_F, slot))
7047
        return 2;
7048
      else if (slot == 2 && match (templ, IA64_TYPE_B, slot))
7049
        return 1;
7050
      else
7051
        return 0;
7052
      break;
7053
    case itanium2:
7054
      if (match (templ, IA64_TYPE_M, slot)
7055
          || match (templ, IA64_TYPE_I, slot))
7056
        /* Favor M- and I-unit NOPs.  We definitely want to avoid
7057
           F-unit and B-unit may cause split-issue or less-than-optimal
7058
           branch-prediction.  */
7059
        return 2;
7060
      else
7061
        return 0;
7062
      break;
7063
    default:
7064
      abort ();
7065
      return 0;
7066
    }
7067
}
7068
 
7069
/* This function is called once, at assembler startup time.  It sets
7070
   up all the tables, etc. that the MD part of the assembler will need
7071
   that can be determined before arguments are parsed.  */
7072
void
7073
md_begin (void)
7074
{
7075
  int i, j, k, t, goodness, best, ok;
7076
  const char *err;
7077
  char name[8];
7078
 
7079
  md.auto_align = 1;
7080
  md.explicit_mode = md.default_explicit_mode;
7081
 
7082
  bfd_set_section_alignment (stdoutput, text_section, 4);
7083
 
7084
  /* Make sure function pointers get initialized.  */
7085
  target_big_endian = -1;
7086
  dot_byteorder (default_big_endian);
7087
 
7088
  alias_hash = hash_new ();
7089
  alias_name_hash = hash_new ();
7090
  secalias_hash = hash_new ();
7091
  secalias_name_hash = hash_new ();
7092
 
7093
  pseudo_func[FUNC_DTP_MODULE].u.sym =
7094
    symbol_new (".<dtpmod>", undefined_section, FUNC_DTP_MODULE,
7095
                &zero_address_frag);
7096
 
7097
  pseudo_func[FUNC_DTP_RELATIVE].u.sym =
7098
    symbol_new (".<dtprel>", undefined_section, FUNC_DTP_RELATIVE,
7099
                &zero_address_frag);
7100
 
7101
  pseudo_func[FUNC_FPTR_RELATIVE].u.sym =
7102
    symbol_new (".<fptr>", undefined_section, FUNC_FPTR_RELATIVE,
7103
                &zero_address_frag);
7104
 
7105
  pseudo_func[FUNC_GP_RELATIVE].u.sym =
7106
    symbol_new (".<gprel>", undefined_section, FUNC_GP_RELATIVE,
7107
                &zero_address_frag);
7108
 
7109
  pseudo_func[FUNC_LT_RELATIVE].u.sym =
7110
    symbol_new (".<ltoff>", undefined_section, FUNC_LT_RELATIVE,
7111
                &zero_address_frag);
7112
 
7113
  pseudo_func[FUNC_LT_RELATIVE_X].u.sym =
7114
    symbol_new (".<ltoffx>", undefined_section, FUNC_LT_RELATIVE_X,
7115
                &zero_address_frag);
7116
 
7117
  pseudo_func[FUNC_PC_RELATIVE].u.sym =
7118
    symbol_new (".<pcrel>", undefined_section, FUNC_PC_RELATIVE,
7119
                &zero_address_frag);
7120
 
7121
  pseudo_func[FUNC_PLT_RELATIVE].u.sym =
7122
    symbol_new (".<pltoff>", undefined_section, FUNC_PLT_RELATIVE,
7123
                &zero_address_frag);
7124
 
7125
  pseudo_func[FUNC_SEC_RELATIVE].u.sym =
7126
    symbol_new (".<secrel>", undefined_section, FUNC_SEC_RELATIVE,
7127
                &zero_address_frag);
7128
 
7129
  pseudo_func[FUNC_SEG_RELATIVE].u.sym =
7130
    symbol_new (".<segrel>", undefined_section, FUNC_SEG_RELATIVE,
7131
                &zero_address_frag);
7132
 
7133
  pseudo_func[FUNC_TP_RELATIVE].u.sym =
7134
    symbol_new (".<tprel>", undefined_section, FUNC_TP_RELATIVE,
7135
                &zero_address_frag);
7136
 
7137
  pseudo_func[FUNC_LTV_RELATIVE].u.sym =
7138
    symbol_new (".<ltv>", undefined_section, FUNC_LTV_RELATIVE,
7139
                &zero_address_frag);
7140
 
7141
  pseudo_func[FUNC_LT_FPTR_RELATIVE].u.sym =
7142
    symbol_new (".<ltoff.fptr>", undefined_section, FUNC_LT_FPTR_RELATIVE,
7143
                &zero_address_frag);
7144
 
7145
  pseudo_func[FUNC_LT_DTP_MODULE].u.sym =
7146
    symbol_new (".<ltoff.dtpmod>", undefined_section, FUNC_LT_DTP_MODULE,
7147
                &zero_address_frag);
7148
 
7149
  pseudo_func[FUNC_LT_DTP_RELATIVE].u.sym =
7150
    symbol_new (".<ltoff.dptrel>", undefined_section, FUNC_LT_DTP_RELATIVE,
7151
                &zero_address_frag);
7152
 
7153
  pseudo_func[FUNC_LT_TP_RELATIVE].u.sym =
7154
    symbol_new (".<ltoff.tprel>", undefined_section, FUNC_LT_TP_RELATIVE,
7155
                &zero_address_frag);
7156
 
7157
  pseudo_func[FUNC_IPLT_RELOC].u.sym =
7158
    symbol_new (".<iplt>", undefined_section, FUNC_IPLT_RELOC,
7159
                &zero_address_frag);
7160
 
7161
 if (md.tune != itanium1)
7162
   {
7163
     /* Convert MFI NOPs bundles into MMI NOPs bundles.  */
7164
     le_nop[0] = 0x8;
7165
     le_nop_stop[0] = 0x9;
7166
   }
7167
 
7168
  /* Compute the table of best templates.  We compute goodness as a
7169
     base 4 value, in which each match counts for 3.  Match-failures
7170
     result in NOPs and we use extra_goodness() to pick the execution
7171
     units that are best suited for issuing the NOP.  */
7172
  for (i = 0; i < IA64_NUM_TYPES; ++i)
7173
    for (j = 0; j < IA64_NUM_TYPES; ++j)
7174
      for (k = 0; k < IA64_NUM_TYPES; ++k)
7175
        {
7176
          best = 0;
7177
          for (t = 0; t < NELEMS (ia64_templ_desc); ++t)
7178
            {
7179
              goodness = 0;
7180
              if (match (t, i, 0))
7181
                {
7182
                  if (match (t, j, 1))
7183
                    {
7184
                      if ((t == 2 && j == IA64_TYPE_X) || match (t, k, 2))
7185
                        goodness = 3 + 3 + 3;
7186
                      else
7187
                        goodness = 3 + 3 + extra_goodness (t, 2);
7188
                    }
7189
                  else if (match (t, j, 2))
7190
                    goodness = 3 + 3 + extra_goodness (t, 1);
7191
                  else
7192
                    {
7193
                      goodness = 3;
7194
                      goodness += extra_goodness (t, 1);
7195
                      goodness += extra_goodness (t, 2);
7196
                    }
7197
                }
7198
              else if (match (t, i, 1))
7199
                {
7200
                  if ((t == 2 && i == IA64_TYPE_X) || match (t, j, 2))
7201
                    goodness = 3 + 3;
7202
                  else
7203
                    goodness = 3 + extra_goodness (t, 2);
7204
                }
7205
              else if (match (t, i, 2))
7206
                goodness = 3 + extra_goodness (t, 1);
7207
 
7208
              if (goodness > best)
7209
                {
7210
                  best = goodness;
7211
                  best_template[i][j][k] = t;
7212
                }
7213
            }
7214
        }
7215
 
7216
#ifdef DEBUG_TEMPLATES
7217
  /* For debugging changes to the best_template calculations.  We don't care
7218
     about combinations with invalid instructions, so start the loops at 1.  */
7219
  for (i = 0; i < IA64_NUM_TYPES; ++i)
7220
    for (j = 0; j < IA64_NUM_TYPES; ++j)
7221
      for (k = 0; k < IA64_NUM_TYPES; ++k)
7222
        {
7223
          char type_letter[IA64_NUM_TYPES] = { 'n', 'a', 'i', 'm', 'b', 'f',
7224
                                               'x', 'd' };
7225
          fprintf (stderr, "%c%c%c %s\n", type_letter[i], type_letter[j],
7226
                   type_letter[k],
7227
                   ia64_templ_desc[best_template[i][j][k]].name);
7228
        }
7229
#endif
7230
 
7231
  for (i = 0; i < NUM_SLOTS; ++i)
7232
    md.slot[i].user_template = -1;
7233
 
7234
  md.pseudo_hash = hash_new ();
7235
  for (i = 0; i < NELEMS (pseudo_opcode); ++i)
7236
    {
7237
      err = hash_insert (md.pseudo_hash, pseudo_opcode[i].name,
7238
                         (void *) (pseudo_opcode + i));
7239
      if (err)
7240
        as_fatal (_("ia64.md_begin: can't hash `%s': %s"),
7241
                  pseudo_opcode[i].name, err);
7242
    }
7243
 
7244
  md.reg_hash = hash_new ();
7245
  md.dynreg_hash = hash_new ();
7246
  md.const_hash = hash_new ();
7247
  md.entry_hash = hash_new ();
7248
 
7249
  /* general registers:  */
7250
  declare_register_set ("r", 128, REG_GR);
7251
  declare_register ("gp", REG_GR +  1);
7252
  declare_register ("sp", REG_GR + 12);
7253
  declare_register ("tp", REG_GR + 13);
7254
  declare_register_set ("ret", 4, REG_GR + 8);
7255
 
7256
  /* floating point registers:  */
7257
  declare_register_set ("f", 128, REG_FR);
7258
  declare_register_set ("farg", 8, REG_FR + 8);
7259
  declare_register_set ("fret", 8, REG_FR + 8);
7260
 
7261
  /* branch registers:  */
7262
  declare_register_set ("b", 8, REG_BR);
7263
  declare_register ("rp", REG_BR + 0);
7264
 
7265
  /* predicate registers:  */
7266
  declare_register_set ("p", 64, REG_P);
7267
  declare_register ("pr", REG_PR);
7268
  declare_register ("pr.rot", REG_PR_ROT);
7269
 
7270
  /* application registers:  */
7271
  declare_register_set ("ar", 128, REG_AR);
7272
  for (i = 0; i < NELEMS (ar); ++i)
7273
    declare_register (ar[i].name, REG_AR + ar[i].regnum);
7274
 
7275
  /* control registers:  */
7276
  declare_register_set ("cr", 128, REG_CR);
7277
  for (i = 0; i < NELEMS (cr); ++i)
7278
    declare_register (cr[i].name, REG_CR + cr[i].regnum);
7279
 
7280
  declare_register ("ip", REG_IP);
7281
  declare_register ("cfm", REG_CFM);
7282
  declare_register ("psr", REG_PSR);
7283
  declare_register ("psr.l", REG_PSR_L);
7284
  declare_register ("psr.um", REG_PSR_UM);
7285
 
7286
  for (i = 0; i < NELEMS (indirect_reg); ++i)
7287
    {
7288
      unsigned int regnum = indirect_reg[i].regnum;
7289
 
7290
      md.indregsym[regnum - IND_CPUID] = declare_register (indirect_reg[i].name, regnum);
7291
    }
7292
 
7293
  /* pseudo-registers used to specify unwind info:  */
7294
  declare_register ("psp", REG_PSP);
7295
 
7296
  for (i = 0; i < NELEMS (const_bits); ++i)
7297
    {
7298
      err = hash_insert (md.const_hash, const_bits[i].name,
7299
                         (void *) (const_bits + i));
7300
      if (err)
7301
        as_fatal (_("Inserting \"%s\" into constant hash table failed: %s"),
7302
                  name, err);
7303
    }
7304
 
7305
  /* Set the architecture and machine depending on defaults and command line
7306
     options.  */
7307
  if (md.flags & EF_IA_64_ABI64)
7308
    ok = bfd_set_arch_mach (stdoutput, bfd_arch_ia64, bfd_mach_ia64_elf64);
7309
  else
7310
    ok = bfd_set_arch_mach (stdoutput, bfd_arch_ia64, bfd_mach_ia64_elf32);
7311
 
7312
  if (! ok)
7313
     as_warn (_("Could not set architecture and machine"));
7314
 
7315
  /* Set the pointer size and pointer shift size depending on md.flags */
7316
 
7317
  if (md.flags & EF_IA_64_ABI64)
7318
    {
7319
      md.pointer_size = 8;         /* pointers are 8 bytes */
7320
      md.pointer_size_shift = 3;   /* alignment is 8 bytes = 2^2 */
7321
    }
7322
  else
7323
    {
7324
      md.pointer_size = 4;         /* pointers are 4 bytes */
7325
      md.pointer_size_shift = 2;   /* alignment is 4 bytes = 2^2 */
7326
    }
7327
 
7328
  md.mem_offset.hint = 0;
7329
  md.path = 0;
7330
  md.maxpaths = 0;
7331
  md.entry_labels = NULL;
7332
}
7333
 
7334
/* Set the default options in md.  Cannot do this in md_begin because
7335
   that is called after md_parse_option which is where we set the
7336
   options in md based on command line options.  */
7337
 
7338
void
7339
ia64_init (int argc ATTRIBUTE_UNUSED, char **argv ATTRIBUTE_UNUSED)
7340
{
7341
  md.flags = MD_FLAGS_DEFAULT;
7342
#ifndef TE_VMS
7343
  /* Don't turn on dependency checking for VMS, doesn't work.  */
7344
  md.detect_dv = 1;
7345
#endif
7346
  /* FIXME: We should change it to unwind_check_error someday.  */
7347
  md.unwind_check = unwind_check_warning;
7348
  md.hint_b = hint_b_error;
7349
  md.tune = itanium2;
7350
}
7351
 
7352
/* Return a string for the target object file format.  */
7353
 
7354
const char *
7355
ia64_target_format (void)
7356
{
7357
  if (OUTPUT_FLAVOR == bfd_target_elf_flavour)
7358
    {
7359
      if (md.flags & EF_IA_64_BE)
7360
        {
7361
          if (md.flags & EF_IA_64_ABI64)
7362
#if defined(TE_AIX50)
7363
            return "elf64-ia64-aix-big";
7364
#elif defined(TE_HPUX)
7365
            return "elf64-ia64-hpux-big";
7366
#else
7367
            return "elf64-ia64-big";
7368
#endif
7369
          else
7370
#if defined(TE_AIX50)
7371
            return "elf32-ia64-aix-big";
7372
#elif defined(TE_HPUX)
7373
            return "elf32-ia64-hpux-big";
7374
#else
7375
            return "elf32-ia64-big";
7376
#endif
7377
        }
7378
      else
7379
        {
7380
          if (md.flags & EF_IA_64_ABI64)
7381
#if defined (TE_AIX50)
7382
            return "elf64-ia64-aix-little";
7383
#elif defined (TE_VMS)
7384
          {
7385
            md.flags |= EF_IA_64_ARCHVER_1;
7386
            return "elf64-ia64-vms";
7387
          }
7388
#else
7389
            return "elf64-ia64-little";
7390
#endif
7391
          else
7392
#ifdef TE_AIX50
7393
            return "elf32-ia64-aix-little";
7394
#else
7395
            return "elf32-ia64-little";
7396
#endif
7397
        }
7398
    }
7399
  else
7400
    return "unknown-format";
7401
}
7402
 
7403
void
7404
ia64_end_of_source (void)
7405
{
7406
  /* terminate insn group upon reaching end of file:  */
7407
  insn_group_break (1, 0, 0);
7408
 
7409
  /* emits slots we haven't written yet:  */
7410
  ia64_flush_insns ();
7411
 
7412
  bfd_set_private_flags (stdoutput, md.flags);
7413
 
7414
  md.mem_offset.hint = 0;
7415
}
7416
 
7417
void
7418
ia64_start_line (void)
7419
{
7420
  static int first;
7421
 
7422
  if (!first) {
7423
    /* Make sure we don't reference input_line_pointer[-1] when that's
7424
       not valid.  */
7425
    first = 1;
7426
    return;
7427
  }
7428
 
7429
  if (md.qp.X_op == O_register)
7430
    as_bad (_("qualifying predicate not followed by instruction"));
7431
  md.qp.X_op = O_absent;
7432
 
7433
  if (ignore_input ())
7434
    return;
7435
 
7436
  if (input_line_pointer[0] == ';' && input_line_pointer[-1] == ';')
7437
    {
7438
      if (md.detect_dv && !md.explicit_mode)
7439
        {
7440
          static int warned;
7441
 
7442
          if (!warned)
7443
            {
7444
              warned = 1;
7445
              as_warn (_("Explicit stops are ignored in auto mode"));
7446
            }
7447
        }
7448
      else
7449
        insn_group_break (1, 0, 0);
7450
    }
7451
  else if (input_line_pointer[-1] == '{')
7452
    {
7453
      if (md.manual_bundling)
7454
        as_warn (_("Found '{' when manual bundling is already turned on"));
7455
      else
7456
        CURR_SLOT.manual_bundling_on = 1;
7457
      md.manual_bundling = 1;
7458
 
7459
      /* Bundling is only acceptable in explicit mode
7460
         or when in default automatic mode.  */
7461
      if (md.detect_dv && !md.explicit_mode)
7462
        {
7463
          if (!md.mode_explicitly_set
7464
              && !md.default_explicit_mode)
7465
            dot_dv_mode ('E');
7466
          else
7467
            as_warn (_("Found '{' after explicit switch to automatic mode"));
7468
        }
7469
    }
7470
  else if (input_line_pointer[-1] == '}')
7471
    {
7472
      if (!md.manual_bundling)
7473
        as_warn (_("Found '}' when manual bundling is off"));
7474
      else
7475
        PREV_SLOT.manual_bundling_off = 1;
7476
      md.manual_bundling = 0;
7477
 
7478
      /* switch back to automatic mode, if applicable */
7479
      if (md.detect_dv
7480
          && md.explicit_mode
7481
          && !md.mode_explicitly_set
7482
          && !md.default_explicit_mode)
7483
        dot_dv_mode ('A');
7484
    }
7485
}
7486
 
7487
/* This is a hook for ia64_frob_label, so that it can distinguish tags from
7488
   labels.  */
7489
static int defining_tag = 0;
7490
 
7491
int
7492
ia64_unrecognized_line (int ch)
7493
{
7494
  switch (ch)
7495
    {
7496
    case '(':
7497
      expression_and_evaluate (&md.qp);
7498
      if (*input_line_pointer++ != ')')
7499
        {
7500
          as_bad (_("Expected ')'"));
7501
          return 0;
7502
        }
7503
      if (md.qp.X_op != O_register)
7504
        {
7505
          as_bad (_("Qualifying predicate expected"));
7506
          return 0;
7507
        }
7508
      if (md.qp.X_add_number < REG_P || md.qp.X_add_number >= REG_P + 64)
7509
        {
7510
          as_bad (_("Predicate register expected"));
7511
          return 0;
7512
        }
7513
      return 1;
7514
 
7515
    case '[':
7516
      {
7517
        char *s;
7518
        char c;
7519
        symbolS *tag;
7520
        int temp;
7521
 
7522
        if (md.qp.X_op == O_register)
7523
          {
7524
            as_bad (_("Tag must come before qualifying predicate."));
7525
            return 0;
7526
          }
7527
 
7528
        /* This implements just enough of read_a_source_file in read.c to
7529
           recognize labels.  */
7530
        if (is_name_beginner (*input_line_pointer))
7531
          {
7532
            s = input_line_pointer;
7533
            c = get_symbol_end ();
7534
          }
7535
        else if (LOCAL_LABELS_FB
7536
                 && ISDIGIT (*input_line_pointer))
7537
          {
7538
            temp = 0;
7539
            while (ISDIGIT (*input_line_pointer))
7540
              temp = (temp * 10) + *input_line_pointer++ - '0';
7541
            fb_label_instance_inc (temp);
7542
            s = fb_label_name (temp, 0);
7543
            c = *input_line_pointer;
7544
          }
7545
        else
7546
          {
7547
            s = NULL;
7548
            c = '\0';
7549
          }
7550
        if (c != ':')
7551
          {
7552
            /* Put ':' back for error messages' sake.  */
7553
            *input_line_pointer++ = ':';
7554
            as_bad (_("Expected ':'"));
7555
            return 0;
7556
          }
7557
 
7558
        defining_tag = 1;
7559
        tag = colon (s);
7560
        defining_tag = 0;
7561
        /* Put ':' back for error messages' sake.  */
7562
        *input_line_pointer++ = ':';
7563
        if (*input_line_pointer++ != ']')
7564
          {
7565
            as_bad (_("Expected ']'"));
7566
            return 0;
7567
          }
7568
        if (! tag)
7569
          {
7570
            as_bad (_("Tag name expected"));
7571
            return 0;
7572
          }
7573
        return 1;
7574
      }
7575
 
7576
    default:
7577
      break;
7578
    }
7579
 
7580
  /* Not a valid line.  */
7581
  return 0;
7582
}
7583
 
7584
void
7585
ia64_frob_label (struct symbol *sym)
7586
{
7587
  struct label_fix *fix;
7588
 
7589
  /* Tags need special handling since they are not bundle breaks like
7590
     labels.  */
7591
  if (defining_tag)
7592
    {
7593
      fix = obstack_alloc (&notes, sizeof (*fix));
7594
      fix->sym = sym;
7595
      fix->next = CURR_SLOT.tag_fixups;
7596
      fix->dw2_mark_labels = FALSE;
7597
      CURR_SLOT.tag_fixups = fix;
7598
 
7599
      return;
7600
    }
7601
 
7602
  if (bfd_get_section_flags (stdoutput, now_seg) & SEC_CODE)
7603
    {
7604
      md.last_text_seg = now_seg;
7605
      fix = obstack_alloc (&notes, sizeof (*fix));
7606
      fix->sym = sym;
7607
      fix->next = CURR_SLOT.label_fixups;
7608
      fix->dw2_mark_labels = dwarf2_loc_mark_labels;
7609
      CURR_SLOT.label_fixups = fix;
7610
 
7611
      /* Keep track of how many code entry points we've seen.  */
7612
      if (md.path == md.maxpaths)
7613
        {
7614
          md.maxpaths += 20;
7615
          md.entry_labels = (const char **)
7616
            xrealloc ((void *) md.entry_labels,
7617
                      md.maxpaths * sizeof (char *));
7618
        }
7619
      md.entry_labels[md.path++] = S_GET_NAME (sym);
7620
    }
7621
}
7622
 
7623
#ifdef TE_HPUX
7624
/* The HP-UX linker will give unresolved symbol errors for symbols
7625
   that are declared but unused.  This routine removes declared,
7626
   unused symbols from an object.  */
7627
int
7628
ia64_frob_symbol (struct symbol *sym)
7629
{
7630
  if ((S_GET_SEGMENT (sym) == &bfd_und_section && ! symbol_used_p (sym) &&
7631
       ELF_ST_VISIBILITY (S_GET_OTHER (sym)) == STV_DEFAULT)
7632
      || (S_GET_SEGMENT (sym) == &bfd_abs_section
7633
          && ! S_IS_EXTERNAL (sym)))
7634
    return 1;
7635
  return 0;
7636
}
7637
#endif
7638
 
7639
void
7640
ia64_flush_pending_output (void)
7641
{
7642
  if (!md.keep_pending_output
7643
      && bfd_get_section_flags (stdoutput, now_seg) & SEC_CODE)
7644
    {
7645
      /* ??? This causes many unnecessary stop bits to be emitted.
7646
         Unfortunately, it isn't clear if it is safe to remove this.  */
7647
      insn_group_break (1, 0, 0);
7648
      ia64_flush_insns ();
7649
    }
7650
}
7651
 
7652
/* Do ia64-specific expression optimization.  All that's done here is
7653
   to transform index expressions that are either due to the indexing
7654
   of rotating registers or due to the indexing of indirect register
7655
   sets.  */
7656
int
7657
ia64_optimize_expr (expressionS *l, operatorT op, expressionS *r)
7658
{
7659
  if (op != O_index)
7660
    return 0;
7661
  resolve_expression (l);
7662
  if (l->X_op == O_register)
7663
    {
7664
      unsigned num_regs = l->X_add_number >> 16;
7665
 
7666
      resolve_expression (r);
7667
      if (num_regs)
7668
        {
7669
          /* Left side is a .rotX-allocated register.  */
7670
          if (r->X_op != O_constant)
7671
            {
7672
              as_bad (_("Rotating register index must be a non-negative constant"));
7673
              r->X_add_number = 0;
7674
            }
7675
          else if ((valueT) r->X_add_number >= num_regs)
7676
            {
7677
              as_bad (_("Index out of range 0..%u"), num_regs - 1);
7678
              r->X_add_number = 0;
7679
            }
7680
          l->X_add_number = (l->X_add_number & 0xffff) + r->X_add_number;
7681
          return 1;
7682
        }
7683
      else if (l->X_add_number >= IND_CPUID && l->X_add_number <= IND_RR)
7684
        {
7685
          if (r->X_op != O_register
7686
              || r->X_add_number < REG_GR
7687
              || r->X_add_number > REG_GR + 127)
7688
            {
7689
              as_bad (_("Indirect register index must be a general register"));
7690
              r->X_add_number = REG_GR;
7691
            }
7692
          l->X_op = O_index;
7693
          l->X_op_symbol = md.indregsym[l->X_add_number - IND_CPUID];
7694
          l->X_add_number = r->X_add_number;
7695
          return 1;
7696
        }
7697
    }
7698
  as_bad (_("Index can only be applied to rotating or indirect registers"));
7699
  /* Fall back to some register use of which has as little as possible
7700
     side effects, to minimize subsequent error messages.  */
7701
  l->X_op = O_register;
7702
  l->X_add_number = REG_GR + 3;
7703
  return 1;
7704
}
7705
 
7706
int
7707
ia64_parse_name (char *name, expressionS *e, char *nextcharP)
7708
{
7709
  struct const_desc *cdesc;
7710
  struct dynreg *dr = 0;
7711
  unsigned int idx;
7712
  struct symbol *sym;
7713
  char *end;
7714
 
7715
  if (*name == '@')
7716
    {
7717
      enum pseudo_type pseudo_type = PSEUDO_FUNC_NONE;
7718
 
7719
      /* Find what relocation pseudo-function we're dealing with.  */
7720
      for (idx = 0; idx < NELEMS (pseudo_func); ++idx)
7721
        if (pseudo_func[idx].name
7722
            && pseudo_func[idx].name[0] == name[1]
7723
            && strcmp (pseudo_func[idx].name + 1, name + 2) == 0)
7724
          {
7725
            pseudo_type = pseudo_func[idx].type;
7726
            break;
7727
          }
7728
      switch (pseudo_type)
7729
        {
7730
        case PSEUDO_FUNC_RELOC:
7731
          end = input_line_pointer;
7732
          if (*nextcharP != '(')
7733
            {
7734
              as_bad (_("Expected '('"));
7735
              break;
7736
            }
7737
          /* Skip '('.  */
7738
          ++input_line_pointer;
7739
          expression (e);
7740
          if (*input_line_pointer != ')')
7741
            {
7742
              as_bad (_("Missing ')'"));
7743
              goto done;
7744
            }
7745
          /* Skip ')'.  */
7746
          ++input_line_pointer;
7747
          if (e->X_op != O_symbol)
7748
            {
7749
              if (e->X_op != O_pseudo_fixup)
7750
                {
7751
                  as_bad (_("Not a symbolic expression"));
7752
                  goto done;
7753
                }
7754
              if (idx != FUNC_LT_RELATIVE)
7755
                {
7756
                  as_bad (_("Illegal combination of relocation functions"));
7757
                  goto done;
7758
                }
7759
              switch (S_GET_VALUE (e->X_op_symbol))
7760
                {
7761
                case FUNC_FPTR_RELATIVE:
7762
                  idx = FUNC_LT_FPTR_RELATIVE; break;
7763
                case FUNC_DTP_MODULE:
7764
                  idx = FUNC_LT_DTP_MODULE; break;
7765
                case FUNC_DTP_RELATIVE:
7766
                  idx = FUNC_LT_DTP_RELATIVE; break;
7767
                case FUNC_TP_RELATIVE:
7768
                  idx = FUNC_LT_TP_RELATIVE; break;
7769
                default:
7770
                  as_bad (_("Illegal combination of relocation functions"));
7771
                  goto done;
7772
                }
7773
            }
7774
          /* Make sure gas doesn't get rid of local symbols that are used
7775
             in relocs.  */
7776
          e->X_op = O_pseudo_fixup;
7777
          e->X_op_symbol = pseudo_func[idx].u.sym;
7778
        done:
7779
          *nextcharP = *input_line_pointer;
7780
          break;
7781
 
7782
        case PSEUDO_FUNC_CONST:
7783
          e->X_op = O_constant;
7784
          e->X_add_number = pseudo_func[idx].u.ival;
7785
          break;
7786
 
7787
        case PSEUDO_FUNC_REG:
7788
          e->X_op = O_register;
7789
          e->X_add_number = pseudo_func[idx].u.ival;
7790
          break;
7791
 
7792
        default:
7793
          return 0;
7794
        }
7795
      return 1;
7796
    }
7797
 
7798
  /* first see if NAME is a known register name:  */
7799
  sym = hash_find (md.reg_hash, name);
7800
  if (sym)
7801
    {
7802
      e->X_op = O_register;
7803
      e->X_add_number = S_GET_VALUE (sym);
7804
      return 1;
7805
    }
7806
 
7807
  cdesc = hash_find (md.const_hash, name);
7808
  if (cdesc)
7809
    {
7810
      e->X_op = O_constant;
7811
      e->X_add_number = cdesc->value;
7812
      return 1;
7813
    }
7814
 
7815
  /* check for inN, locN, or outN:  */
7816
  idx = 0;
7817
  switch (name[0])
7818
    {
7819
    case 'i':
7820
      if (name[1] == 'n' && ISDIGIT (name[2]))
7821
        {
7822
          dr = &md.in;
7823
          idx = 2;
7824
        }
7825
      break;
7826
 
7827
    case 'l':
7828
      if (name[1] == 'o' && name[2] == 'c' && ISDIGIT (name[3]))
7829
        {
7830
          dr = &md.loc;
7831
          idx = 3;
7832
        }
7833
      break;
7834
 
7835
    case 'o':
7836
      if (name[1] == 'u' && name[2] == 't' && ISDIGIT (name[3]))
7837
        {
7838
          dr = &md.out;
7839
          idx = 3;
7840
        }
7841
      break;
7842
 
7843
    default:
7844
      break;
7845
    }
7846
 
7847
  /* Ignore register numbers with leading zeroes, except zero itself.  */
7848
  if (dr && (name[idx] != '0' || name[idx + 1] == '\0'))
7849
    {
7850
      unsigned long regnum;
7851
 
7852
      /* The name is inN, locN, or outN; parse the register number.  */
7853
      regnum = strtoul (name + idx, &end, 10);
7854
      if (end > name + idx && *end == '\0' && regnum < 96)
7855
        {
7856
          if (regnum >= dr->num_regs)
7857
            {
7858
              if (!dr->num_regs)
7859
                as_bad (_("No current frame"));
7860
              else
7861
                as_bad (_("Register number out of range 0..%u"),
7862
                        dr->num_regs - 1);
7863
              regnum = 0;
7864
            }
7865
          e->X_op = O_register;
7866
          e->X_add_number = dr->base + regnum;
7867
          return 1;
7868
        }
7869
    }
7870
 
7871
  end = alloca (strlen (name) + 1);
7872
  strcpy (end, name);
7873
  name = ia64_canonicalize_symbol_name (end);
7874
  if ((dr = hash_find (md.dynreg_hash, name)))
7875
    {
7876
      /* We've got ourselves the name of a rotating register set.
7877
         Store the base register number in the low 16 bits of
7878
         X_add_number and the size of the register set in the top 16
7879
         bits.  */
7880
      e->X_op = O_register;
7881
      e->X_add_number = dr->base | (dr->num_regs << 16);
7882
      return 1;
7883
    }
7884
  return 0;
7885
}
7886
 
7887
/* Remove the '#' suffix that indicates a symbol as opposed to a register.  */
7888
 
7889
char *
7890
ia64_canonicalize_symbol_name (char *name)
7891
{
7892
  size_t len = strlen (name), full = len;
7893
 
7894
  while (len > 0 && name[len - 1] == '#')
7895
    --len;
7896
  if (len <= 0)
7897
    {
7898
      if (full > 0)
7899
        as_bad (_("Standalone `#' is illegal"));
7900
    }
7901
  else if (len < full - 1)
7902
    as_warn (_("Redundant `#' suffix operators"));
7903
  name[len] = '\0';
7904
  return name;
7905
}
7906
 
7907
/* Return true if idesc is a conditional branch instruction.  This excludes
7908
   the modulo scheduled branches, and br.ia.  Mod-sched branches are excluded
7909
   because they always read/write resources regardless of the value of the
7910
   qualifying predicate.  br.ia must always use p0, and hence is always
7911
   taken.  Thus this function returns true for branches which can fall
7912
   through, and which use no resources if they do fall through.  */
7913
 
7914
static int
7915
is_conditional_branch (struct ia64_opcode *idesc)
7916
{
7917
  /* br is a conditional branch.  Everything that starts with br. except
7918
     br.ia, br.c{loop,top,exit}, and br.w{top,exit} is a conditional branch.
7919
     Everything that starts with brl is a conditional branch.  */
7920
  return (idesc->name[0] == 'b' && idesc->name[1] == 'r'
7921
          && (idesc->name[2] == '\0'
7922
              || (idesc->name[2] == '.' && idesc->name[3] != 'i'
7923
                  && idesc->name[3] != 'c' && idesc->name[3] != 'w')
7924
              || idesc->name[2] == 'l'
7925
              /* br.cond, br.call, br.clr  */
7926
              || (idesc->name[2] == '.' && idesc->name[3] == 'c'
7927
                  && (idesc->name[4] == 'a' || idesc->name[4] == 'o'
7928
                      || (idesc->name[4] == 'l' && idesc->name[5] == 'r')))));
7929
}
7930
 
7931
/* Return whether the given opcode is a taken branch.  If there's any doubt,
7932
   returns zero.  */
7933
 
7934
static int
7935
is_taken_branch (struct ia64_opcode *idesc)
7936
{
7937
  return ((is_conditional_branch (idesc) && CURR_SLOT.qp_regno == 0)
7938
          || strncmp (idesc->name, "br.ia", 5) == 0);
7939
}
7940
 
7941
/* Return whether the given opcode is an interruption or rfi.  If there's any
7942
   doubt, returns zero.  */
7943
 
7944
static int
7945
is_interruption_or_rfi (struct ia64_opcode *idesc)
7946
{
7947
  if (strcmp (idesc->name, "rfi") == 0)
7948
    return 1;
7949
  return 0;
7950
}
7951
 
7952
/* Returns the index of the given dependency in the opcode's list of chks, or
7953
   -1 if there is no dependency.  */
7954
 
7955
static int
7956
depends_on (int depind, struct ia64_opcode *idesc)
7957
{
7958
  int i;
7959
  const struct ia64_opcode_dependency *dep = idesc->dependencies;
7960
  for (i = 0; i < dep->nchks; i++)
7961
    {
7962
      if (depind == DEP (dep->chks[i]))
7963
        return i;
7964
    }
7965
  return -1;
7966
}
7967
 
7968
/* Determine a set of specific resources used for a particular resource
7969
   class.  Returns the number of specific resources identified  For those
7970
   cases which are not determinable statically, the resource returned is
7971
   marked nonspecific.
7972
 
7973
   Meanings of value in 'NOTE':
7974
   1) only read/write when the register number is explicitly encoded in the
7975
   insn.
7976
   2) only read CFM when accessing a rotating GR, FR, or PR.  mov pr only
7977
   accesses CFM when qualifying predicate is in the rotating region.
7978
   3) general register value is used to specify an indirect register; not
7979
   determinable statically.
7980
   4) only read the given resource when bits 7:0 of the indirect index
7981
   register value does not match the register number of the resource; not
7982
   determinable statically.
7983
   5) all rules are implementation specific.
7984
   6) only when both the index specified by the reader and the index specified
7985
   by the writer have the same value in bits 63:61; not determinable
7986
   statically.
7987
   7) only access the specified resource when the corresponding mask bit is
7988
   set
7989
   8) PSR.dfh is only read when these insns reference FR32-127.  PSR.dfl is
7990
   only read when these insns reference FR2-31
7991
   9) PSR.mfl is only written when these insns write FR2-31.  PSR.mfh is only
7992
   written when these insns write FR32-127
7993
   10) The PSR.bn bit is only accessed when one of GR16-31 is specified in the
7994
   instruction
7995
   11) The target predicates are written independently of PR[qp], but source
7996
   registers are only read if PR[qp] is true.  Since the state of PR[qp]
7997
   cannot statically be determined, all source registers are marked used.
7998
   12) This insn only reads the specified predicate register when that
7999
   register is the PR[qp].
8000
   13) This reference to ld-c only applies to the GR whose value is loaded
8001
   with data returned from memory, not the post-incremented address register.
8002
   14) The RSE resource includes the implementation-specific RSE internal
8003
   state resources.  At least one (and possibly more) of these resources are
8004
   read by each instruction listed in IC:rse-readers.  At least one (and
8005
   possibly more) of these resources are written by each insn listed in
8006
   IC:rse-writers.
8007
   15+16) Represents reserved instructions, which the assembler does not
8008
   generate.
8009
   17) CR[TPR] has a RAW dependency only between mov-to-CR-TPR and
8010
   mov-to-PSR-l or ssm instructions that set PSR.i, PSR.pp or PSR.up.
8011
 
8012
   Memory resources (i.e. locations in memory) are *not* marked or tracked by
8013
   this code; there are no dependency violations based on memory access.
8014
*/
8015
 
8016
#define MAX_SPECS 256
8017
#define DV_CHK 1
8018
#define DV_REG 0
8019
 
8020
static int
8021
specify_resource (const struct ia64_dependency *dep,
8022
                  struct ia64_opcode *idesc,
8023
                  /* is this a DV chk or a DV reg? */
8024
                  int type,
8025
                  /* returned specific resources */
8026
                  struct rsrc specs[MAX_SPECS],
8027
                  /* resource note for this insn's usage */
8028
                  int note,
8029
                  /* which execution path to examine */
8030
                  int path)
8031
{
8032
  int count = 0;
8033
  int i;
8034
  int rsrc_write = 0;
8035
  struct rsrc tmpl;
8036
 
8037
  if (dep->mode == IA64_DV_WAW
8038
      || (dep->mode == IA64_DV_RAW && type == DV_REG)
8039
      || (dep->mode == IA64_DV_WAR && type == DV_CHK))
8040
    rsrc_write = 1;
8041
 
8042
  /* template for any resources we identify */
8043
  tmpl.dependency = dep;
8044
  tmpl.note = note;
8045
  tmpl.insn_srlz = tmpl.data_srlz = 0;
8046
  tmpl.qp_regno = CURR_SLOT.qp_regno;
8047
  tmpl.link_to_qp_branch = 1;
8048
  tmpl.mem_offset.hint = 0;
8049
  tmpl.mem_offset.offset = 0;
8050
  tmpl.mem_offset.base = 0;
8051
  tmpl.specific = 1;
8052
  tmpl.index = -1;
8053
  tmpl.cmp_type = CMP_NONE;
8054
  tmpl.depind = 0;
8055
  tmpl.file = NULL;
8056
  tmpl.line = 0;
8057
  tmpl.path = 0;
8058
 
8059
#define UNHANDLED \
8060
as_warn (_("Unhandled dependency %s for %s (%s), note %d"), \
8061
dep->name, idesc->name, (rsrc_write?"write":"read"), note)
8062
#define KNOWN(REG) (gr_values[REG].known && gr_values[REG].path >= path)
8063
 
8064
  /* we don't need to track these */
8065
  if (dep->semantics == IA64_DVS_NONE)
8066
    return 0;
8067
 
8068
  switch (dep->specifier)
8069
    {
8070
    case IA64_RS_AR_K:
8071
      if (note == 1)
8072
        {
8073
          if (idesc->operands[!rsrc_write] == IA64_OPND_AR3)
8074
            {
8075
              int regno = CURR_SLOT.opnd[!rsrc_write].X_add_number - REG_AR;
8076
              if (regno >= 0 && regno <= 7)
8077
                {
8078
                  specs[count] = tmpl;
8079
                  specs[count++].index = regno;
8080
                }
8081
            }
8082
        }
8083
      else if (note == 0)
8084
        {
8085
          for (i = 0; i < 8; i++)
8086
            {
8087
              specs[count] = tmpl;
8088
              specs[count++].index = i;
8089
            }
8090
        }
8091
      else
8092
        {
8093
          UNHANDLED;
8094
        }
8095
      break;
8096
 
8097
    case IA64_RS_AR_UNAT:
8098
      /* This is a mov =AR or mov AR= instruction.  */
8099
      if (idesc->operands[!rsrc_write] == IA64_OPND_AR3)
8100
        {
8101
          int regno = CURR_SLOT.opnd[!rsrc_write].X_add_number - REG_AR;
8102
          if (regno == AR_UNAT)
8103
            {
8104
              specs[count++] = tmpl;
8105
            }
8106
        }
8107
      else
8108
        {
8109
          /* This is a spill/fill, or other instruction that modifies the
8110
             unat register.  */
8111
 
8112
          /* Unless we can determine the specific bits used, mark the whole
8113
             thing; bits 8:3 of the memory address indicate the bit used in
8114
             UNAT.  The .mem.offset hint may be used to eliminate a small
8115
             subset of conflicts.  */
8116
          specs[count] = tmpl;
8117
          if (md.mem_offset.hint)
8118
            {
8119
              if (md.debug_dv)
8120
                fprintf (stderr, "  Using hint for spill/fill\n");
8121
              /* The index isn't actually used, just set it to something
8122
                 approximating the bit index.  */
8123
              specs[count].index = (md.mem_offset.offset >> 3) & 0x3F;
8124
              specs[count].mem_offset.hint = 1;
8125
              specs[count].mem_offset.offset = md.mem_offset.offset;
8126
              specs[count++].mem_offset.base = md.mem_offset.base;
8127
            }
8128
          else
8129
            {
8130
              specs[count++].specific = 0;
8131
            }
8132
        }
8133
      break;
8134
 
8135
    case IA64_RS_AR:
8136
      if (note == 1)
8137
        {
8138
          if (idesc->operands[!rsrc_write] == IA64_OPND_AR3)
8139
            {
8140
              int regno = CURR_SLOT.opnd[!rsrc_write].X_add_number - REG_AR;
8141
              if ((regno >= 8 && regno <= 15)
8142
                  || (regno >= 20 && regno <= 23)
8143
                  || (regno >= 31 && regno <= 39)
8144
                  || (regno >= 41 && regno <= 47)
8145
                  || (regno >= 67 && regno <= 111))
8146
                {
8147
                  specs[count] = tmpl;
8148
                  specs[count++].index = regno;
8149
                }
8150
            }
8151
        }
8152
      else
8153
        {
8154
          UNHANDLED;
8155
        }
8156
      break;
8157
 
8158
    case IA64_RS_ARb:
8159
      if (note == 1)
8160
        {
8161
          if (idesc->operands[!rsrc_write] == IA64_OPND_AR3)
8162
            {
8163
              int regno = CURR_SLOT.opnd[!rsrc_write].X_add_number - REG_AR;
8164
              if ((regno >= 48 && regno <= 63)
8165
                  || (regno >= 112 && regno <= 127))
8166
                {
8167
                  specs[count] = tmpl;
8168
                  specs[count++].index = regno;
8169
                }
8170
            }
8171
        }
8172
      else if (note == 0)
8173
        {
8174
          for (i = 48; i < 64; i++)
8175
            {
8176
              specs[count] = tmpl;
8177
              specs[count++].index = i;
8178
            }
8179
          for (i = 112; i < 128; i++)
8180
            {
8181
              specs[count] = tmpl;
8182
              specs[count++].index = i;
8183
            }
8184
        }
8185
      else
8186
        {
8187
          UNHANDLED;
8188
        }
8189
      break;
8190
 
8191
    case IA64_RS_BR:
8192
      if (note != 1)
8193
        {
8194
          UNHANDLED;
8195
        }
8196
      else
8197
        {
8198
          if (rsrc_write)
8199
            {
8200
              for (i = 0; i < idesc->num_outputs; i++)
8201
                if (idesc->operands[i] == IA64_OPND_B1
8202
                    || idesc->operands[i] == IA64_OPND_B2)
8203
                  {
8204
                    specs[count] = tmpl;
8205
                    specs[count++].index =
8206
                      CURR_SLOT.opnd[i].X_add_number - REG_BR;
8207
                  }
8208
            }
8209
          else
8210
            {
8211
              for (i = idesc->num_outputs; i < NELEMS (idesc->operands); i++)
8212
                if (idesc->operands[i] == IA64_OPND_B1
8213
                    || idesc->operands[i] == IA64_OPND_B2)
8214
                  {
8215
                    specs[count] = tmpl;
8216
                    specs[count++].index =
8217
                      CURR_SLOT.opnd[i].X_add_number - REG_BR;
8218
                  }
8219
            }
8220
        }
8221
      break;
8222
 
8223
    case IA64_RS_CPUID: /* four or more registers */
8224
      if (note == 3)
8225
        {
8226
          if (idesc->operands[!rsrc_write] == IA64_OPND_CPUID_R3)
8227
            {
8228
              int regno = CURR_SLOT.opnd[!rsrc_write].X_add_number - REG_GR;
8229
              if (regno >= 0 && regno < NELEMS (gr_values)
8230
                  && KNOWN (regno))
8231
                {
8232
                  specs[count] = tmpl;
8233
                  specs[count++].index = gr_values[regno].value & 0xFF;
8234
                }
8235
              else
8236
                {
8237
                  specs[count] = tmpl;
8238
                  specs[count++].specific = 0;
8239
                }
8240
            }
8241
        }
8242
      else
8243
        {
8244
          UNHANDLED;
8245
        }
8246
      break;
8247
 
8248
    case IA64_RS_DBR: /* four or more registers */
8249
      if (note == 3)
8250
        {
8251
          if (idesc->operands[!rsrc_write] == IA64_OPND_DBR_R3)
8252
            {
8253
              int regno = CURR_SLOT.opnd[!rsrc_write].X_add_number - REG_GR;
8254
              if (regno >= 0 && regno < NELEMS (gr_values)
8255
                  && KNOWN (regno))
8256
                {
8257
                  specs[count] = tmpl;
8258
                  specs[count++].index = gr_values[regno].value & 0xFF;
8259
                }
8260
              else
8261
                {
8262
                  specs[count] = tmpl;
8263
                  specs[count++].specific = 0;
8264
                }
8265
            }
8266
        }
8267
      else if (note == 0 && !rsrc_write)
8268
        {
8269
          specs[count] = tmpl;
8270
          specs[count++].specific = 0;
8271
        }
8272
      else
8273
        {
8274
          UNHANDLED;
8275
        }
8276
      break;
8277
 
8278
    case IA64_RS_IBR: /* four or more registers */
8279
      if (note == 3)
8280
        {
8281
          if (idesc->operands[!rsrc_write] == IA64_OPND_IBR_R3)
8282
            {
8283
              int regno = CURR_SLOT.opnd[!rsrc_write].X_add_number - REG_GR;
8284
              if (regno >= 0 && regno < NELEMS (gr_values)
8285
                  && KNOWN (regno))
8286
                {
8287
                  specs[count] = tmpl;
8288
                  specs[count++].index = gr_values[regno].value & 0xFF;
8289
                }
8290
              else
8291
                {
8292
                  specs[count] = tmpl;
8293
                  specs[count++].specific = 0;
8294
                }
8295
            }
8296
        }
8297
      else
8298
        {
8299
          UNHANDLED;
8300
        }
8301
      break;
8302
 
8303
    case IA64_RS_MSR:
8304
      if (note == 5)
8305
        {
8306
          /* These are implementation specific.  Force all references to
8307
             conflict with all other references.  */
8308
          specs[count] = tmpl;
8309
          specs[count++].specific = 0;
8310
        }
8311
      else
8312
        {
8313
          UNHANDLED;
8314
        }
8315
      break;
8316
 
8317
    case IA64_RS_PKR: /* 16 or more registers */
8318
      if (note == 3 || note == 4)
8319
        {
8320
          if (idesc->operands[!rsrc_write] == IA64_OPND_PKR_R3)
8321
            {
8322
              int regno = CURR_SLOT.opnd[!rsrc_write].X_add_number - REG_GR;
8323
              if (regno >= 0 && regno < NELEMS (gr_values)
8324
                  && KNOWN (regno))
8325
                {
8326
                  if (note == 3)
8327
                    {
8328
                      specs[count] = tmpl;
8329
                      specs[count++].index = gr_values[regno].value & 0xFF;
8330
                    }
8331
                  else
8332
                    for (i = 0; i < NELEMS (gr_values); i++)
8333
                      {
8334
                        /* Uses all registers *except* the one in R3.  */
8335
                        if ((unsigned)i != (gr_values[regno].value & 0xFF))
8336
                          {
8337
                            specs[count] = tmpl;
8338
                            specs[count++].index = i;
8339
                          }
8340
                      }
8341
                }
8342
              else
8343
                {
8344
                  specs[count] = tmpl;
8345
                  specs[count++].specific = 0;
8346
                }
8347
            }
8348
        }
8349
      else if (note == 0)
8350
        {
8351
          /* probe et al.  */
8352
          specs[count] = tmpl;
8353
          specs[count++].specific = 0;
8354
        }
8355
      break;
8356
 
8357
    case IA64_RS_PMC: /* four or more registers */
8358
      if (note == 3)
8359
        {
8360
          if (idesc->operands[!rsrc_write] == IA64_OPND_PMC_R3
8361
              || (!rsrc_write && idesc->operands[1] == IA64_OPND_PMD_R3))
8362
 
8363
            {
8364
              int index = ((idesc->operands[1] == IA64_OPND_R3 && !rsrc_write)
8365
                           ? 1 : !rsrc_write);
8366
              int regno = CURR_SLOT.opnd[index].X_add_number - REG_GR;
8367
              if (regno >= 0 && regno < NELEMS (gr_values)
8368
                  && KNOWN (regno))
8369
                {
8370
                  specs[count] = tmpl;
8371
                  specs[count++].index = gr_values[regno].value & 0xFF;
8372
                }
8373
              else
8374
                {
8375
                  specs[count] = tmpl;
8376
                  specs[count++].specific = 0;
8377
                }
8378
            }
8379
        }
8380
      else
8381
        {
8382
          UNHANDLED;
8383
        }
8384
      break;
8385
 
8386
    case IA64_RS_PMD: /* four or more registers */
8387
      if (note == 3)
8388
        {
8389
          if (idesc->operands[!rsrc_write] == IA64_OPND_PMD_R3)
8390
            {
8391
              int regno = CURR_SLOT.opnd[!rsrc_write].X_add_number - REG_GR;
8392
              if (regno >= 0 && regno < NELEMS (gr_values)
8393
                  && KNOWN (regno))
8394
                {
8395
                  specs[count] = tmpl;
8396
                  specs[count++].index = gr_values[regno].value & 0xFF;
8397
                }
8398
              else
8399
                {
8400
                  specs[count] = tmpl;
8401
                  specs[count++].specific = 0;
8402
                }
8403
            }
8404
        }
8405
      else
8406
        {
8407
          UNHANDLED;
8408
        }
8409
      break;
8410
 
8411
    case IA64_RS_RR: /* eight registers */
8412
      if (note == 6)
8413
        {
8414
          if (idesc->operands[!rsrc_write] == IA64_OPND_RR_R3)
8415
            {
8416
              int regno = CURR_SLOT.opnd[!rsrc_write].X_add_number - REG_GR;
8417
              if (regno >= 0 && regno < NELEMS (gr_values)
8418
                  && KNOWN (regno))
8419
                {
8420
                  specs[count] = tmpl;
8421
                  specs[count++].index = (gr_values[regno].value >> 61) & 0x7;
8422
                }
8423
              else
8424
                {
8425
                  specs[count] = tmpl;
8426
                  specs[count++].specific = 0;
8427
                }
8428
            }
8429
        }
8430
      else if (note == 0 && !rsrc_write)
8431
        {
8432
          specs[count] = tmpl;
8433
          specs[count++].specific = 0;
8434
        }
8435
      else
8436
        {
8437
          UNHANDLED;
8438
        }
8439
      break;
8440
 
8441
    case IA64_RS_CR_IRR:
8442
      if (note == 0)
8443
        {
8444
          /* handle mov-from-CR-IVR; it's a read that writes CR[IRR] */
8445
          int regno = CURR_SLOT.opnd[1].X_add_number - REG_CR;
8446
          if (rsrc_write
8447
              && idesc->operands[1] == IA64_OPND_CR3
8448
              && regno == CR_IVR)
8449
            {
8450
              for (i = 0; i < 4; i++)
8451
                {
8452
                  specs[count] = tmpl;
8453
                  specs[count++].index = CR_IRR0 + i;
8454
                }
8455
            }
8456
        }
8457
      else if (note == 1)
8458
        {
8459
          int regno = CURR_SLOT.opnd[!rsrc_write].X_add_number - REG_CR;
8460
          if (idesc->operands[!rsrc_write] == IA64_OPND_CR3
8461
              && regno >= CR_IRR0
8462
              && regno <= CR_IRR3)
8463
            {
8464
              specs[count] = tmpl;
8465
              specs[count++].index = regno;
8466
            }
8467
        }
8468
      else
8469
        {
8470
          UNHANDLED;
8471
        }
8472
      break;
8473
 
8474
    case IA64_RS_CR_IIB:
8475
      if (note != 0)
8476
        {
8477
          UNHANDLED;
8478
        }
8479
      else
8480
        {
8481
          int regno = CURR_SLOT.opnd[!rsrc_write].X_add_number - REG_CR;
8482
          if (idesc->operands[!rsrc_write] == IA64_OPND_CR3
8483
              && (regno == CR_IIB0 || regno == CR_IIB1))
8484
            {
8485
              specs[count] = tmpl;
8486
              specs[count++].index = regno;
8487
            }
8488
        }
8489
      break;
8490
 
8491
    case IA64_RS_CR_LRR:
8492
      if (note != 1)
8493
        {
8494
          UNHANDLED;
8495
        }
8496
      else
8497
        {
8498
          int regno = CURR_SLOT.opnd[!rsrc_write].X_add_number - REG_CR;
8499
          if (idesc->operands[!rsrc_write] == IA64_OPND_CR3
8500
              && (regno == CR_LRR0 || regno == CR_LRR1))
8501
            {
8502
              specs[count] = tmpl;
8503
              specs[count++].index = regno;
8504
            }
8505
        }
8506
      break;
8507
 
8508
    case IA64_RS_CR:
8509
      if (note == 1)
8510
        {
8511
          if (idesc->operands[!rsrc_write] == IA64_OPND_CR3)
8512
            {
8513
              specs[count] = tmpl;
8514
              specs[count++].index =
8515
                CURR_SLOT.opnd[!rsrc_write].X_add_number - REG_CR;
8516
            }
8517
        }
8518
      else
8519
        {
8520
          UNHANDLED;
8521
        }
8522
      break;
8523
 
8524
    case IA64_RS_FR:
8525
    case IA64_RS_FRb:
8526
      if (note != 1)
8527
        {
8528
          UNHANDLED;
8529
        }
8530
      else if (rsrc_write)
8531
        {
8532
          if (dep->specifier == IA64_RS_FRb
8533
              && idesc->operands[0] == IA64_OPND_F1)
8534
            {
8535
              specs[count] = tmpl;
8536
              specs[count++].index = CURR_SLOT.opnd[0].X_add_number - REG_FR;
8537
            }
8538
        }
8539
      else
8540
        {
8541
          for (i = idesc->num_outputs; i < NELEMS (idesc->operands); i++)
8542
            {
8543
              if (idesc->operands[i] == IA64_OPND_F2
8544
                  || idesc->operands[i] == IA64_OPND_F3
8545
                  || idesc->operands[i] == IA64_OPND_F4)
8546
                {
8547
                  specs[count] = tmpl;
8548
                  specs[count++].index =
8549
                    CURR_SLOT.opnd[i].X_add_number - REG_FR;
8550
                }
8551
            }
8552
        }
8553
      break;
8554
 
8555
    case IA64_RS_GR:
8556
      if (note == 13)
8557
        {
8558
          /* This reference applies only to the GR whose value is loaded with
8559
             data returned from memory.  */
8560
          specs[count] = tmpl;
8561
          specs[count++].index = CURR_SLOT.opnd[0].X_add_number - REG_GR;
8562
        }
8563
      else if (note == 1)
8564
        {
8565
          if (rsrc_write)
8566
            {
8567
              for (i = 0; i < idesc->num_outputs; i++)
8568
                if (idesc->operands[i] == IA64_OPND_R1
8569
                    || idesc->operands[i] == IA64_OPND_R2
8570
                    || idesc->operands[i] == IA64_OPND_R3)
8571
                  {
8572
                    specs[count] = tmpl;
8573
                    specs[count++].index =
8574
                      CURR_SLOT.opnd[i].X_add_number - REG_GR;
8575
                  }
8576
              if (idesc->flags & IA64_OPCODE_POSTINC)
8577
                for (i = 0; i < NELEMS (idesc->operands); i++)
8578
                  if (idesc->operands[i] == IA64_OPND_MR3)
8579
                    {
8580
                      specs[count] = tmpl;
8581
                      specs[count++].index =
8582
                        CURR_SLOT.opnd[i].X_add_number - REG_GR;
8583
                    }
8584
            }
8585
          else
8586
            {
8587
              /* Look for anything that reads a GR.  */
8588
              for (i = 0; i < NELEMS (idesc->operands); i++)
8589
                {
8590
                  if (idesc->operands[i] == IA64_OPND_MR3
8591
                      || idesc->operands[i] == IA64_OPND_CPUID_R3
8592
                      || idesc->operands[i] == IA64_OPND_DBR_R3
8593
                      || idesc->operands[i] == IA64_OPND_IBR_R3
8594
                      || idesc->operands[i] == IA64_OPND_MSR_R3
8595
                      || idesc->operands[i] == IA64_OPND_PKR_R3
8596
                      || idesc->operands[i] == IA64_OPND_PMC_R3
8597
                      || idesc->operands[i] == IA64_OPND_PMD_R3
8598
                      || idesc->operands[i] == IA64_OPND_RR_R3
8599
                      || ((i >= idesc->num_outputs)
8600
                          && (idesc->operands[i] == IA64_OPND_R1
8601
                              || idesc->operands[i] == IA64_OPND_R2
8602
                              || idesc->operands[i] == IA64_OPND_R3
8603
                              /* addl source register.  */
8604
                              || idesc->operands[i] == IA64_OPND_R3_2)))
8605
                    {
8606
                      specs[count] = tmpl;
8607
                      specs[count++].index =
8608
                        CURR_SLOT.opnd[i].X_add_number - REG_GR;
8609
                    }
8610
                }
8611
            }
8612
        }
8613
      else
8614
        {
8615
          UNHANDLED;
8616
        }
8617
      break;
8618
 
8619
      /* This is the same as IA64_RS_PRr, except that the register range is
8620
         from 1 - 15, and there are no rotating register reads/writes here.  */
8621
    case IA64_RS_PR:
8622
      if (note == 0)
8623
        {
8624
          for (i = 1; i < 16; i++)
8625
            {
8626
              specs[count] = tmpl;
8627
              specs[count++].index = i;
8628
            }
8629
        }
8630
      else if (note == 7)
8631
        {
8632
          valueT mask = 0;
8633
          /* Mark only those registers indicated by the mask.  */
8634
          if (rsrc_write)
8635
            {
8636
              mask = CURR_SLOT.opnd[2].X_add_number;
8637
              for (i = 1; i < 16; i++)
8638
                if (mask & ((valueT) 1 << i))
8639
                  {
8640
                    specs[count] = tmpl;
8641
                    specs[count++].index = i;
8642
                  }
8643
            }
8644
          else
8645
            {
8646
              UNHANDLED;
8647
            }
8648
        }
8649
      else if (note == 11) /* note 11 implies note 1 as well */
8650
        {
8651
          if (rsrc_write)
8652
            {
8653
              for (i = 0; i < idesc->num_outputs; i++)
8654
                {
8655
                  if (idesc->operands[i] == IA64_OPND_P1
8656
                      || idesc->operands[i] == IA64_OPND_P2)
8657
                    {
8658
                      int regno = CURR_SLOT.opnd[i].X_add_number - REG_P;
8659
                      if (regno >= 1 && regno < 16)
8660
                        {
8661
                          specs[count] = tmpl;
8662
                          specs[count++].index = regno;
8663
                        }
8664
                    }
8665
                }
8666
            }
8667
          else
8668
            {
8669
              UNHANDLED;
8670
            }
8671
        }
8672
      else if (note == 12)
8673
        {
8674
          if (CURR_SLOT.qp_regno >= 1 && CURR_SLOT.qp_regno < 16)
8675
            {
8676
              specs[count] = tmpl;
8677
              specs[count++].index = CURR_SLOT.qp_regno;
8678
            }
8679
        }
8680
      else if (note == 1)
8681
        {
8682
          if (rsrc_write)
8683
            {
8684
              int p1 = CURR_SLOT.opnd[0].X_add_number - REG_P;
8685
              int p2 = CURR_SLOT.opnd[1].X_add_number - REG_P;
8686
              int or_andcm = strstr (idesc->name, "or.andcm") != NULL;
8687
              int and_orcm = strstr (idesc->name, "and.orcm") != NULL;
8688
 
8689
              if ((idesc->operands[0] == IA64_OPND_P1
8690
                   || idesc->operands[0] == IA64_OPND_P2)
8691
                  && p1 >= 1 && p1 < 16)
8692
                {
8693
                  specs[count] = tmpl;
8694
                  specs[count].cmp_type =
8695
                    (or_andcm ? CMP_OR : (and_orcm ? CMP_AND : CMP_NONE));
8696
                  specs[count++].index = p1;
8697
                }
8698
              if ((idesc->operands[1] == IA64_OPND_P1
8699
                   || idesc->operands[1] == IA64_OPND_P2)
8700
                  && p2 >= 1 && p2 < 16)
8701
                {
8702
                  specs[count] = tmpl;
8703
                  specs[count].cmp_type =
8704
                    (or_andcm ? CMP_AND : (and_orcm ? CMP_OR : CMP_NONE));
8705
                  specs[count++].index = p2;
8706
                }
8707
            }
8708
          else
8709
            {
8710
              if (CURR_SLOT.qp_regno >= 1 && CURR_SLOT.qp_regno < 16)
8711
                {
8712
                  specs[count] = tmpl;
8713
                  specs[count++].index = CURR_SLOT.qp_regno;
8714
                }
8715
              if (idesc->operands[1] == IA64_OPND_PR)
8716
                {
8717
                  for (i = 1; i < 16; i++)
8718
                    {
8719
                      specs[count] = tmpl;
8720
                      specs[count++].index = i;
8721
                    }
8722
                }
8723
            }
8724
        }
8725
      else
8726
        {
8727
          UNHANDLED;
8728
        }
8729
      break;
8730
 
8731
      /* This is the general case for PRs.  IA64_RS_PR and IA64_RS_PR63 are
8732
         simplified cases of this.  */
8733
    case IA64_RS_PRr:
8734
      if (note == 0)
8735
        {
8736
          for (i = 16; i < 63; i++)
8737
            {
8738
              specs[count] = tmpl;
8739
              specs[count++].index = i;
8740
            }
8741
        }
8742
      else if (note == 7)
8743
        {
8744
          valueT mask = 0;
8745
          /* Mark only those registers indicated by the mask.  */
8746
          if (rsrc_write
8747
              && idesc->operands[0] == IA64_OPND_PR)
8748
            {
8749
              mask = CURR_SLOT.opnd[2].X_add_number;
8750
              if (mask & ((valueT) 1 << 16))
8751
                for (i = 16; i < 63; i++)
8752
                  {
8753
                    specs[count] = tmpl;
8754
                    specs[count++].index = i;
8755
                  }
8756
            }
8757
          else if (rsrc_write
8758
                   && idesc->operands[0] == IA64_OPND_PR_ROT)
8759
            {
8760
              for (i = 16; i < 63; i++)
8761
                {
8762
                  specs[count] = tmpl;
8763
                  specs[count++].index = i;
8764
                }
8765
            }
8766
          else
8767
            {
8768
              UNHANDLED;
8769
            }
8770
        }
8771
      else if (note == 11) /* note 11 implies note 1 as well */
8772
        {
8773
          if (rsrc_write)
8774
            {
8775
              for (i = 0; i < idesc->num_outputs; i++)
8776
                {
8777
                  if (idesc->operands[i] == IA64_OPND_P1
8778
                      || idesc->operands[i] == IA64_OPND_P2)
8779
                    {
8780
                      int regno = CURR_SLOT.opnd[i].X_add_number - REG_P;
8781
                      if (regno >= 16 && regno < 63)
8782
                        {
8783
                          specs[count] = tmpl;
8784
                          specs[count++].index = regno;
8785
                        }
8786
                    }
8787
                }
8788
            }
8789
          else
8790
            {
8791
              UNHANDLED;
8792
            }
8793
        }
8794
      else if (note == 12)
8795
        {
8796
          if (CURR_SLOT.qp_regno >= 16 && CURR_SLOT.qp_regno < 63)
8797
            {
8798
              specs[count] = tmpl;
8799
              specs[count++].index = CURR_SLOT.qp_regno;
8800
            }
8801
        }
8802
      else if (note == 1)
8803
        {
8804
          if (rsrc_write)
8805
            {
8806
              int p1 = CURR_SLOT.opnd[0].X_add_number - REG_P;
8807
              int p2 = CURR_SLOT.opnd[1].X_add_number - REG_P;
8808
              int or_andcm = strstr (idesc->name, "or.andcm") != NULL;
8809
              int and_orcm = strstr (idesc->name, "and.orcm") != NULL;
8810
 
8811
              if ((idesc->operands[0] == IA64_OPND_P1
8812
                   || idesc->operands[0] == IA64_OPND_P2)
8813
                  && p1 >= 16 && p1 < 63)
8814
                {
8815
                  specs[count] = tmpl;
8816
                  specs[count].cmp_type =
8817
                    (or_andcm ? CMP_OR : (and_orcm ? CMP_AND : CMP_NONE));
8818
                  specs[count++].index = p1;
8819
                }
8820
              if ((idesc->operands[1] == IA64_OPND_P1
8821
                   || idesc->operands[1] == IA64_OPND_P2)
8822
                  && p2 >= 16 && p2 < 63)
8823
                {
8824
                  specs[count] = tmpl;
8825
                  specs[count].cmp_type =
8826
                    (or_andcm ? CMP_AND : (and_orcm ? CMP_OR : CMP_NONE));
8827
                  specs[count++].index = p2;
8828
                }
8829
            }
8830
          else
8831
            {
8832
              if (CURR_SLOT.qp_regno >= 16 && CURR_SLOT.qp_regno < 63)
8833
                {
8834
                  specs[count] = tmpl;
8835
                  specs[count++].index = CURR_SLOT.qp_regno;
8836
                }
8837
              if (idesc->operands[1] == IA64_OPND_PR)
8838
                {
8839
                  for (i = 16; i < 63; i++)
8840
                    {
8841
                      specs[count] = tmpl;
8842
                      specs[count++].index = i;
8843
                    }
8844
                }
8845
            }
8846
        }
8847
      else
8848
        {
8849
          UNHANDLED;
8850
        }
8851
      break;
8852
 
8853
    case IA64_RS_PSR:
8854
      /* Verify that the instruction is using the PSR bit indicated in
8855
         dep->regindex.  */
8856
      if (note == 0)
8857
        {
8858
          if (idesc->operands[!rsrc_write] == IA64_OPND_PSR_UM)
8859
            {
8860
              if (dep->regindex < 6)
8861
                {
8862
                  specs[count++] = tmpl;
8863
                }
8864
            }
8865
          else if (idesc->operands[!rsrc_write] == IA64_OPND_PSR)
8866
            {
8867
              if (dep->regindex < 32
8868
                  || dep->regindex == 35
8869
                  || dep->regindex == 36
8870
                  || (!rsrc_write && dep->regindex == PSR_CPL))
8871
                {
8872
                  specs[count++] = tmpl;
8873
                }
8874
            }
8875
          else if (idesc->operands[!rsrc_write] == IA64_OPND_PSR_L)
8876
            {
8877
              if (dep->regindex < 32
8878
                  || dep->regindex == 35
8879
                  || dep->regindex == 36
8880
                  || (rsrc_write && dep->regindex == PSR_CPL))
8881
                {
8882
                  specs[count++] = tmpl;
8883
                }
8884
            }
8885
          else
8886
            {
8887
              /* Several PSR bits have very specific dependencies.  */
8888
              switch (dep->regindex)
8889
                {
8890
                default:
8891
                  specs[count++] = tmpl;
8892
                  break;
8893
                case PSR_IC:
8894
                  if (rsrc_write)
8895
                    {
8896
                      specs[count++] = tmpl;
8897
                    }
8898
                  else
8899
                    {
8900
                      /* Only certain CR accesses use PSR.ic */
8901
                      if (idesc->operands[0] == IA64_OPND_CR3
8902
                          || idesc->operands[1] == IA64_OPND_CR3)
8903
                        {
8904
                          int index =
8905
                            ((idesc->operands[0] == IA64_OPND_CR3)
8906
                             ? 0 : 1);
8907
                          int regno =
8908
                            CURR_SLOT.opnd[index].X_add_number - REG_CR;
8909
 
8910
                          switch (regno)
8911
                            {
8912
                            default:
8913
                              break;
8914
                            case CR_ITIR:
8915
                            case CR_IFS:
8916
                            case CR_IIM:
8917
                            case CR_IIP:
8918
                            case CR_IPSR:
8919
                            case CR_ISR:
8920
                            case CR_IFA:
8921
                            case CR_IHA:
8922
                            case CR_IIB0:
8923
                            case CR_IIB1:
8924
                            case CR_IIPA:
8925
                              specs[count++] = tmpl;
8926
                              break;
8927
                            }
8928
                        }
8929
                    }
8930
                  break;
8931
                case PSR_CPL:
8932
                  if (rsrc_write)
8933
                    {
8934
                      specs[count++] = tmpl;
8935
                    }
8936
                  else
8937
                    {
8938
                      /* Only some AR accesses use cpl */
8939
                      if (idesc->operands[0] == IA64_OPND_AR3
8940
                          || idesc->operands[1] == IA64_OPND_AR3)
8941
                        {
8942
                          int index =
8943
                            ((idesc->operands[0] == IA64_OPND_AR3)
8944
                             ? 0 : 1);
8945
                          int regno =
8946
                            CURR_SLOT.opnd[index].X_add_number - REG_AR;
8947
 
8948
                          if (regno == AR_ITC
8949
                              || regno == AR_RUC
8950
                              || (index == 0
8951
                                  && (regno == AR_RSC
8952
                                      || (regno >= AR_K0
8953
                                          && regno <= AR_K7))))
8954
                            {
8955
                              specs[count++] = tmpl;
8956
                            }
8957
                        }
8958
                      else
8959
                        {
8960
                          specs[count++] = tmpl;
8961
                        }
8962
                      break;
8963
                    }
8964
                }
8965
            }
8966
        }
8967
      else if (note == 7)
8968
        {
8969
          valueT mask = 0;
8970
          if (idesc->operands[0] == IA64_OPND_IMMU24)
8971
            {
8972
              mask = CURR_SLOT.opnd[0].X_add_number;
8973
            }
8974
          else
8975
            {
8976
              UNHANDLED;
8977
            }
8978
          if (mask & ((valueT) 1 << dep->regindex))
8979
            {
8980
              specs[count++] = tmpl;
8981
            }
8982
        }
8983
      else if (note == 8)
8984
        {
8985
          int min = dep->regindex == PSR_DFL ? 2 : 32;
8986
          int max = dep->regindex == PSR_DFL ? 31 : 127;
8987
          /* dfh is read on FR32-127; dfl is read on FR2-31 */
8988
          for (i = 0; i < NELEMS (idesc->operands); i++)
8989
            {
8990
              if (idesc->operands[i] == IA64_OPND_F1
8991
                  || idesc->operands[i] == IA64_OPND_F2
8992
                  || idesc->operands[i] == IA64_OPND_F3
8993
                  || idesc->operands[i] == IA64_OPND_F4)
8994
                {
8995
                  int reg = CURR_SLOT.opnd[i].X_add_number - REG_FR;
8996
                  if (reg >= min && reg <= max)
8997
                    {
8998
                      specs[count++] = tmpl;
8999
                    }
9000
                }
9001
            }
9002
        }
9003
      else if (note == 9)
9004
        {
9005
          int min = dep->regindex == PSR_MFL ? 2 : 32;
9006
          int max = dep->regindex == PSR_MFL ? 31 : 127;
9007
          /* mfh is read on writes to FR32-127; mfl is read on writes to
9008
             FR2-31 */
9009
          for (i = 0; i < idesc->num_outputs; i++)
9010
            {
9011
              if (idesc->operands[i] == IA64_OPND_F1)
9012
                {
9013
                  int reg = CURR_SLOT.opnd[i].X_add_number - REG_FR;
9014
                  if (reg >= min && reg <= max)
9015
                    {
9016
                      specs[count++] = tmpl;
9017
                    }
9018
                }
9019
            }
9020
        }
9021
      else if (note == 10)
9022
        {
9023
          for (i = 0; i < NELEMS (idesc->operands); i++)
9024
            {
9025
              if (idesc->operands[i] == IA64_OPND_R1
9026
                  || idesc->operands[i] == IA64_OPND_R2
9027
                  || idesc->operands[i] == IA64_OPND_R3)
9028
                {
9029
                  int regno = CURR_SLOT.opnd[i].X_add_number - REG_GR;
9030
                  if (regno >= 16 && regno <= 31)
9031
                    {
9032
                      specs[count++] = tmpl;
9033
                    }
9034
                }
9035
            }
9036
        }
9037
      else
9038
        {
9039
          UNHANDLED;
9040
        }
9041
      break;
9042
 
9043
    case IA64_RS_AR_FPSR:
9044
      if (idesc->operands[!rsrc_write] == IA64_OPND_AR3)
9045
        {
9046
          int regno = CURR_SLOT.opnd[!rsrc_write].X_add_number - REG_AR;
9047
          if (regno == AR_FPSR)
9048
            {
9049
              specs[count++] = tmpl;
9050
            }
9051
        }
9052
      else
9053
        {
9054
          specs[count++] = tmpl;
9055
        }
9056
      break;
9057
 
9058
    case IA64_RS_ARX:
9059
      /* Handle all AR[REG] resources */
9060
      if (note == 0 || note == 1)
9061
        {
9062
          int regno = CURR_SLOT.opnd[!rsrc_write].X_add_number - REG_AR;
9063
          if (idesc->operands[!rsrc_write] == IA64_OPND_AR3
9064
              && regno == dep->regindex)
9065
            {
9066
              specs[count++] = tmpl;
9067
            }
9068
          /* other AR[REG] resources may be affected by AR accesses */
9069
          else if (idesc->operands[0] == IA64_OPND_AR3)
9070
            {
9071
              /* AR[] writes */
9072
              regno = CURR_SLOT.opnd[0].X_add_number - REG_AR;
9073
              switch (dep->regindex)
9074
                {
9075
                default:
9076
                  break;
9077
                case AR_BSP:
9078
                case AR_RNAT:
9079
                  if (regno == AR_BSPSTORE)
9080
                    {
9081
                      specs[count++] = tmpl;
9082
                    }
9083
                case AR_RSC:
9084
                  if (!rsrc_write &&
9085
                      (regno == AR_BSPSTORE
9086
                       || regno == AR_RNAT))
9087
                    {
9088
                      specs[count++] = tmpl;
9089
                    }
9090
                  break;
9091
                }
9092
            }
9093
          else if (idesc->operands[1] == IA64_OPND_AR3)
9094
            {
9095
              /* AR[] reads */
9096
              regno = CURR_SLOT.opnd[1].X_add_number - REG_AR;
9097
              switch (dep->regindex)
9098
                {
9099
                default:
9100
                  break;
9101
                case AR_RSC:
9102
                  if (regno == AR_BSPSTORE || regno == AR_RNAT)
9103
                    {
9104
                      specs[count++] = tmpl;
9105
                    }
9106
                  break;
9107
                }
9108
            }
9109
          else
9110
            {
9111
              specs[count++] = tmpl;
9112
            }
9113
        }
9114
      else
9115
        {
9116
          UNHANDLED;
9117
        }
9118
      break;
9119
 
9120
    case IA64_RS_CRX:
9121
      /* Handle all CR[REG] resources.
9122
         ??? FIXME: The rule 17 isn't really handled correctly.   */
9123
      if (note == 0 || note == 1 || note == 17)
9124
        {
9125
          if (idesc->operands[!rsrc_write] == IA64_OPND_CR3)
9126
            {
9127
              int regno = CURR_SLOT.opnd[!rsrc_write].X_add_number - REG_CR;
9128
              if (regno == dep->regindex)
9129
                {
9130
                  specs[count++] = tmpl;
9131
                }
9132
              else if (!rsrc_write)
9133
                {
9134
                  /* Reads from CR[IVR] affect other resources.  */
9135
                  if (regno == CR_IVR)
9136
                    {
9137
                      if ((dep->regindex >= CR_IRR0
9138
                           && dep->regindex <= CR_IRR3)
9139
                          || dep->regindex == CR_TPR)
9140
                        {
9141
                          specs[count++] = tmpl;
9142
                        }
9143
                    }
9144
                }
9145
            }
9146
          else
9147
            {
9148
              specs[count++] = tmpl;
9149
            }
9150
        }
9151
      else
9152
        {
9153
          UNHANDLED;
9154
        }
9155
      break;
9156
 
9157
    case IA64_RS_INSERVICE:
9158
      /* look for write of EOI (67) or read of IVR (65) */
9159
      if ((idesc->operands[0] == IA64_OPND_CR3
9160
           && CURR_SLOT.opnd[0].X_add_number - REG_CR == CR_EOI)
9161
          || (idesc->operands[1] == IA64_OPND_CR3
9162
              && CURR_SLOT.opnd[1].X_add_number - REG_CR == CR_IVR))
9163
        {
9164
          specs[count++] = tmpl;
9165
        }
9166
      break;
9167
 
9168
    case IA64_RS_GR0:
9169
      if (note == 1)
9170
        {
9171
          specs[count++] = tmpl;
9172
        }
9173
      else
9174
        {
9175
          UNHANDLED;
9176
        }
9177
      break;
9178
 
9179
    case IA64_RS_CFM:
9180
      if (note != 2)
9181
        {
9182
          specs[count++] = tmpl;
9183
        }
9184
      else
9185
        {
9186
          /* Check if any of the registers accessed are in the rotating region.
9187
             mov to/from pr accesses CFM only when qp_regno is in the rotating
9188
             region */
9189
          for (i = 0; i < NELEMS (idesc->operands); i++)
9190
            {
9191
              if (idesc->operands[i] == IA64_OPND_R1
9192
                  || idesc->operands[i] == IA64_OPND_R2
9193
                  || idesc->operands[i] == IA64_OPND_R3)
9194
                {
9195
                  int num = CURR_SLOT.opnd[i].X_add_number - REG_GR;
9196
                  /* Assumes that md.rot.num_regs is always valid */
9197
                  if (md.rot.num_regs > 0
9198
                      && num > 31
9199
                      && num < 31 + md.rot.num_regs)
9200
                    {
9201
                      specs[count] = tmpl;
9202
                      specs[count++].specific = 0;
9203
                    }
9204
                }
9205
              else if (idesc->operands[i] == IA64_OPND_F1
9206
                       || idesc->operands[i] == IA64_OPND_F2
9207
                       || idesc->operands[i] == IA64_OPND_F3
9208
                       || idesc->operands[i] == IA64_OPND_F4)
9209
                {
9210
                  int num = CURR_SLOT.opnd[i].X_add_number - REG_FR;
9211
                  if (num > 31)
9212
                    {
9213
                      specs[count] = tmpl;
9214
                      specs[count++].specific = 0;
9215
                    }
9216
                }
9217
              else if (idesc->operands[i] == IA64_OPND_P1
9218
                       || idesc->operands[i] == IA64_OPND_P2)
9219
                {
9220
                  int num = CURR_SLOT.opnd[i].X_add_number - REG_P;
9221
                  if (num > 15)
9222
                    {
9223
                      specs[count] = tmpl;
9224
                      specs[count++].specific = 0;
9225
                    }
9226
                }
9227
            }
9228
          if (CURR_SLOT.qp_regno > 15)
9229
            {
9230
              specs[count] = tmpl;
9231
              specs[count++].specific = 0;
9232
            }
9233
        }
9234
      break;
9235
 
9236
      /* This is the same as IA64_RS_PRr, except simplified to account for
9237
         the fact that there is only one register.  */
9238
    case IA64_RS_PR63:
9239
      if (note == 0)
9240
        {
9241
          specs[count++] = tmpl;
9242
        }
9243
      else if (note == 7)
9244
        {
9245
          valueT mask = 0;
9246
          if (idesc->operands[2] == IA64_OPND_IMM17)
9247
            mask = CURR_SLOT.opnd[2].X_add_number;
9248
          if (mask & ((valueT) 1 << 63))
9249
            specs[count++] = tmpl;
9250
        }
9251
      else if (note == 11)
9252
        {
9253
          if ((idesc->operands[0] == IA64_OPND_P1
9254
               && CURR_SLOT.opnd[0].X_add_number - REG_P == 63)
9255
              || (idesc->operands[1] == IA64_OPND_P2
9256
                  && CURR_SLOT.opnd[1].X_add_number - REG_P == 63))
9257
            {
9258
              specs[count++] = tmpl;
9259
            }
9260
        }
9261
      else if (note == 12)
9262
        {
9263
          if (CURR_SLOT.qp_regno == 63)
9264
            {
9265
              specs[count++] = tmpl;
9266
            }
9267
        }
9268
      else if (note == 1)
9269
        {
9270
          if (rsrc_write)
9271
            {
9272
              int p1 = CURR_SLOT.opnd[0].X_add_number - REG_P;
9273
              int p2 = CURR_SLOT.opnd[1].X_add_number - REG_P;
9274
              int or_andcm = strstr (idesc->name, "or.andcm") != NULL;
9275
              int and_orcm = strstr (idesc->name, "and.orcm") != NULL;
9276
 
9277
              if (p1 == 63
9278
                  && (idesc->operands[0] == IA64_OPND_P1
9279
                      || idesc->operands[0] == IA64_OPND_P2))
9280
                {
9281
                  specs[count] = tmpl;
9282
                  specs[count++].cmp_type =
9283
                    (or_andcm ? CMP_OR : (and_orcm ? CMP_AND : CMP_NONE));
9284
                }
9285
              if (p2 == 63
9286
                  && (idesc->operands[1] == IA64_OPND_P1
9287
                      || idesc->operands[1] == IA64_OPND_P2))
9288
                {
9289
                  specs[count] = tmpl;
9290
                  specs[count++].cmp_type =
9291
                    (or_andcm ? CMP_AND : (and_orcm ? CMP_OR : CMP_NONE));
9292
                }
9293
            }
9294
          else
9295
            {
9296
              if (CURR_SLOT.qp_regno == 63)
9297
                {
9298
                  specs[count++] = tmpl;
9299
                }
9300
            }
9301
        }
9302
      else
9303
        {
9304
          UNHANDLED;
9305
        }
9306
      break;
9307
 
9308
    case IA64_RS_RSE:
9309
      /* FIXME we can identify some individual RSE written resources, but RSE
9310
         read resources have not yet been completely identified, so for now
9311
         treat RSE as a single resource */
9312
      if (strncmp (idesc->name, "mov", 3) == 0)
9313
        {
9314
          if (rsrc_write)
9315
            {
9316
              if (idesc->operands[0] == IA64_OPND_AR3
9317
                  && CURR_SLOT.opnd[0].X_add_number - REG_AR == AR_BSPSTORE)
9318
                {
9319
                  specs[count++] = tmpl;
9320
                }
9321
            }
9322
          else
9323
            {
9324
              if (idesc->operands[0] == IA64_OPND_AR3)
9325
                {
9326
                  if (CURR_SLOT.opnd[0].X_add_number - REG_AR == AR_BSPSTORE
9327
                      || CURR_SLOT.opnd[0].X_add_number - REG_AR == AR_RNAT)
9328
                    {
9329
                      specs[count++] = tmpl;
9330
                    }
9331
                }
9332
              else if (idesc->operands[1] == IA64_OPND_AR3)
9333
                {
9334
                  if (CURR_SLOT.opnd[1].X_add_number - REG_AR == AR_BSP
9335
                      || CURR_SLOT.opnd[1].X_add_number - REG_AR == AR_BSPSTORE
9336
                      || CURR_SLOT.opnd[1].X_add_number - REG_AR == AR_RNAT)
9337
                    {
9338
                      specs[count++] = tmpl;
9339
                    }
9340
                }
9341
            }
9342
        }
9343
      else
9344
        {
9345
          specs[count++] = tmpl;
9346
        }
9347
      break;
9348
 
9349
    case IA64_RS_ANY:
9350
      /* FIXME -- do any of these need to be non-specific? */
9351
      specs[count++] = tmpl;
9352
      break;
9353
 
9354
    default:
9355
      as_bad (_("Unrecognized dependency specifier %d\n"), dep->specifier);
9356
      break;
9357
    }
9358
 
9359
  return count;
9360
}
9361
 
9362
/* Clear branch flags on marked resources.  This breaks the link between the
9363
   QP of the marking instruction and a subsequent branch on the same QP.  */
9364
 
9365
static void
9366
clear_qp_branch_flag (valueT mask)
9367
{
9368
  int i;
9369
  for (i = 0; i < regdepslen; i++)
9370
    {
9371
      valueT bit = ((valueT) 1 << regdeps[i].qp_regno);
9372
      if ((bit & mask) != 0)
9373
        {
9374
          regdeps[i].link_to_qp_branch = 0;
9375
        }
9376
    }
9377
}
9378
 
9379
/* MASK contains 2 and only 2 PRs which are mutually exclusive.  Remove
9380
   any mutexes which contain one of the PRs and create new ones when
9381
   needed.  */
9382
 
9383
static int
9384
update_qp_mutex (valueT mask)
9385
{
9386
  int i;
9387
  int add = 0;
9388
 
9389
  i = 0;
9390
  while (i < qp_mutexeslen)
9391
    {
9392
      if ((qp_mutexes[i].prmask & mask) != 0)
9393
        {
9394
          /* If it destroys and creates the same mutex, do nothing.  */
9395
          if (qp_mutexes[i].prmask == mask
9396
              && qp_mutexes[i].path == md.path)
9397
            {
9398
              i++;
9399
              add = -1;
9400
            }
9401
          else
9402
            {
9403
              int keep = 0;
9404
 
9405
              if (md.debug_dv)
9406
                {
9407
                  fprintf (stderr, "  Clearing mutex relation");
9408
                  print_prmask (qp_mutexes[i].prmask);
9409
                  fprintf (stderr, "\n");
9410
                }
9411
 
9412
              /* Deal with the old mutex with more than 3+ PRs only if
9413
                 the new mutex on the same execution path with it.
9414
 
9415
                 FIXME: The 3+ mutex support is incomplete.
9416
                 dot_pred_rel () may be a better place to fix it.  */
9417
              if (qp_mutexes[i].path == md.path)
9418
                {
9419
                  /* If it is a proper subset of the mutex, create a
9420
                     new mutex.  */
9421
                  if (add == 0
9422
                      && (qp_mutexes[i].prmask & mask) == mask)
9423
                    add = 1;
9424
 
9425
                  qp_mutexes[i].prmask &= ~mask;
9426
                  if (qp_mutexes[i].prmask & (qp_mutexes[i].prmask - 1))
9427
                    {
9428
                      /* Modify the mutex if there are more than one
9429
                         PR left.  */
9430
                      keep = 1;
9431
                      i++;
9432
                    }
9433
                }
9434
 
9435
              if (keep == 0)
9436
                /* Remove the mutex.  */
9437
                qp_mutexes[i] = qp_mutexes[--qp_mutexeslen];
9438
            }
9439
        }
9440
      else
9441
        ++i;
9442
    }
9443
 
9444
  if (add == 1)
9445
    add_qp_mutex (mask);
9446
 
9447
  return add;
9448
}
9449
 
9450
/* Remove any mutexes which contain any of the PRs indicated in the mask.
9451
 
9452
   Any changes to a PR clears the mutex relations which include that PR.  */
9453
 
9454
static void
9455
clear_qp_mutex (valueT mask)
9456
{
9457
  int i;
9458
 
9459
  i = 0;
9460
  while (i < qp_mutexeslen)
9461
    {
9462
      if ((qp_mutexes[i].prmask & mask) != 0)
9463
        {
9464
          if (md.debug_dv)
9465
            {
9466
              fprintf (stderr, "  Clearing mutex relation");
9467
              print_prmask (qp_mutexes[i].prmask);
9468
              fprintf (stderr, "\n");
9469
            }
9470
          qp_mutexes[i] = qp_mutexes[--qp_mutexeslen];
9471
        }
9472
      else
9473
        ++i;
9474
    }
9475
}
9476
 
9477
/* Clear implies relations which contain PRs in the given masks.
9478
   P1_MASK indicates the source of the implies relation, while P2_MASK
9479
   indicates the implied PR.  */
9480
 
9481
static void
9482
clear_qp_implies (valueT p1_mask, valueT p2_mask)
9483
{
9484
  int i;
9485
 
9486
  i = 0;
9487
  while (i < qp_implieslen)
9488
    {
9489
      if ((((valueT) 1 << qp_implies[i].p1) & p1_mask) != 0
9490
          || (((valueT) 1 << qp_implies[i].p2) & p2_mask) != 0)
9491
        {
9492
          if (md.debug_dv)
9493
            fprintf (stderr, "Clearing implied relation PR%d->PR%d\n",
9494
                     qp_implies[i].p1, qp_implies[i].p2);
9495
          qp_implies[i] = qp_implies[--qp_implieslen];
9496
        }
9497
      else
9498
        ++i;
9499
    }
9500
}
9501
 
9502
/* Add the PRs specified to the list of implied relations.  */
9503
 
9504
static void
9505
add_qp_imply (int p1, int p2)
9506
{
9507
  valueT mask;
9508
  valueT bit;
9509
  int i;
9510
 
9511
  /* p0 is not meaningful here.  */
9512
  if (p1 == 0 || p2 == 0)
9513
    abort ();
9514
 
9515
  if (p1 == p2)
9516
    return;
9517
 
9518
  /* If it exists already, ignore it.  */
9519
  for (i = 0; i < qp_implieslen; i++)
9520
    {
9521
      if (qp_implies[i].p1 == p1
9522
          && qp_implies[i].p2 == p2
9523
          && qp_implies[i].path == md.path
9524
          && !qp_implies[i].p2_branched)
9525
        return;
9526
    }
9527
 
9528
  if (qp_implieslen == qp_impliestotlen)
9529
    {
9530
      qp_impliestotlen += 20;
9531
      qp_implies = (struct qp_imply *)
9532
        xrealloc ((void *) qp_implies,
9533
                  qp_impliestotlen * sizeof (struct qp_imply));
9534
    }
9535
  if (md.debug_dv)
9536
    fprintf (stderr, "  Registering PR%d implies PR%d\n", p1, p2);
9537
  qp_implies[qp_implieslen].p1 = p1;
9538
  qp_implies[qp_implieslen].p2 = p2;
9539
  qp_implies[qp_implieslen].path = md.path;
9540
  qp_implies[qp_implieslen++].p2_branched = 0;
9541
 
9542
  /* Add in the implied transitive relations; for everything that p2 implies,
9543
     make p1 imply that, too; for everything that implies p1, make it imply p2
9544
     as well.  */
9545
  for (i = 0; i < qp_implieslen; i++)
9546
    {
9547
      if (qp_implies[i].p1 == p2)
9548
        add_qp_imply (p1, qp_implies[i].p2);
9549
      if (qp_implies[i].p2 == p1)
9550
        add_qp_imply (qp_implies[i].p1, p2);
9551
    }
9552
  /* Add in mutex relations implied by this implies relation; for each mutex
9553
     relation containing p2, duplicate it and replace p2 with p1.  */
9554
  bit = (valueT) 1 << p1;
9555
  mask = (valueT) 1 << p2;
9556
  for (i = 0; i < qp_mutexeslen; i++)
9557
    {
9558
      if (qp_mutexes[i].prmask & mask)
9559
        add_qp_mutex ((qp_mutexes[i].prmask & ~mask) | bit);
9560
    }
9561
}
9562
 
9563
/* Add the PRs specified in the mask to the mutex list; this means that only
9564
   one of the PRs can be true at any time.  PR0 should never be included in
9565
   the mask.  */
9566
 
9567
static void
9568
add_qp_mutex (valueT mask)
9569
{
9570
  if (mask & 0x1)
9571
    abort ();
9572
 
9573
  if (qp_mutexeslen == qp_mutexestotlen)
9574
    {
9575
      qp_mutexestotlen += 20;
9576
      qp_mutexes = (struct qpmutex *)
9577
        xrealloc ((void *) qp_mutexes,
9578
                  qp_mutexestotlen * sizeof (struct qpmutex));
9579
    }
9580
  if (md.debug_dv)
9581
    {
9582
      fprintf (stderr, "  Registering mutex on");
9583
      print_prmask (mask);
9584
      fprintf (stderr, "\n");
9585
    }
9586
  qp_mutexes[qp_mutexeslen].path = md.path;
9587
  qp_mutexes[qp_mutexeslen++].prmask = mask;
9588
}
9589
 
9590
static int
9591
has_suffix_p (const char *name, const char *suffix)
9592
{
9593
  size_t namelen = strlen (name);
9594
  size_t sufflen = strlen (suffix);
9595
 
9596
  if (namelen <= sufflen)
9597
    return 0;
9598
  return strcmp (name + namelen - sufflen, suffix) == 0;
9599
}
9600
 
9601
static void
9602
clear_register_values (void)
9603
{
9604
  int i;
9605
  if (md.debug_dv)
9606
    fprintf (stderr, "  Clearing register values\n");
9607
  for (i = 1; i < NELEMS (gr_values); i++)
9608
    gr_values[i].known = 0;
9609
}
9610
 
9611
/* Keep track of register values/changes which affect DV tracking.
9612
 
9613
   optimization note: should add a flag to classes of insns where otherwise we
9614
   have to examine a group of strings to identify them.  */
9615
 
9616
static void
9617
note_register_values (struct ia64_opcode *idesc)
9618
{
9619
  valueT qp_changemask = 0;
9620
  int i;
9621
 
9622
  /* Invalidate values for registers being written to.  */
9623
  for (i = 0; i < idesc->num_outputs; i++)
9624
    {
9625
      if (idesc->operands[i] == IA64_OPND_R1
9626
          || idesc->operands[i] == IA64_OPND_R2
9627
          || idesc->operands[i] == IA64_OPND_R3)
9628
        {
9629
          int regno = CURR_SLOT.opnd[i].X_add_number - REG_GR;
9630
          if (regno > 0 && regno < NELEMS (gr_values))
9631
            gr_values[regno].known = 0;
9632
        }
9633
      else if (idesc->operands[i] == IA64_OPND_R3_2)
9634
        {
9635
          int regno = CURR_SLOT.opnd[i].X_add_number - REG_GR;
9636
          if (regno > 0 && regno < 4)
9637
            gr_values[regno].known = 0;
9638
        }
9639
      else if (idesc->operands[i] == IA64_OPND_P1
9640
               || idesc->operands[i] == IA64_OPND_P2)
9641
        {
9642
          int regno = CURR_SLOT.opnd[i].X_add_number - REG_P;
9643
          qp_changemask |= (valueT) 1 << regno;
9644
        }
9645
      else if (idesc->operands[i] == IA64_OPND_PR)
9646
        {
9647
          if (idesc->operands[2] & (valueT) 0x10000)
9648
            qp_changemask = ~(valueT) 0x1FFFF | idesc->operands[2];
9649
          else
9650
            qp_changemask = idesc->operands[2];
9651
          break;
9652
        }
9653
      else if (idesc->operands[i] == IA64_OPND_PR_ROT)
9654
        {
9655
          if (idesc->operands[1] & ((valueT) 1 << 43))
9656
            qp_changemask = -((valueT) 1 << 44) | idesc->operands[1];
9657
          else
9658
            qp_changemask = idesc->operands[1];
9659
          qp_changemask &= ~(valueT) 0xFFFF;
9660
          break;
9661
        }
9662
    }
9663
 
9664
  /* Always clear qp branch flags on any PR change.  */
9665
  /* FIXME there may be exceptions for certain compares.  */
9666
  clear_qp_branch_flag (qp_changemask);
9667
 
9668
  /* Invalidate rotating registers on insns which affect RRBs in CFM.  */
9669
  if (idesc->flags & IA64_OPCODE_MOD_RRBS)
9670
    {
9671
      qp_changemask |= ~(valueT) 0xFFFF;
9672
      if (strcmp (idesc->name, "clrrrb.pr") != 0)
9673
        {
9674
          for (i = 32; i < 32 + md.rot.num_regs; i++)
9675
            gr_values[i].known = 0;
9676
        }
9677
      clear_qp_mutex (qp_changemask);
9678
      clear_qp_implies (qp_changemask, qp_changemask);
9679
    }
9680
  /* After a call, all register values are undefined, except those marked
9681
     as "safe".  */
9682
  else if (strncmp (idesc->name, "br.call", 6) == 0
9683
           || strncmp (idesc->name, "brl.call", 7) == 0)
9684
    {
9685
      /* FIXME keep GR values which are marked as "safe_across_calls"  */
9686
      clear_register_values ();
9687
      clear_qp_mutex (~qp_safe_across_calls);
9688
      clear_qp_implies (~qp_safe_across_calls, ~qp_safe_across_calls);
9689
      clear_qp_branch_flag (~qp_safe_across_calls);
9690
    }
9691
  else if (is_interruption_or_rfi (idesc)
9692
           || is_taken_branch (idesc))
9693
    {
9694
      clear_register_values ();
9695
      clear_qp_mutex (~(valueT) 0);
9696
      clear_qp_implies (~(valueT) 0, ~(valueT) 0);
9697
    }
9698
  /* Look for mutex and implies relations.  */
9699
  else if ((idesc->operands[0] == IA64_OPND_P1
9700
            || idesc->operands[0] == IA64_OPND_P2)
9701
           && (idesc->operands[1] == IA64_OPND_P1
9702
               || idesc->operands[1] == IA64_OPND_P2))
9703
    {
9704
      int p1 = CURR_SLOT.opnd[0].X_add_number - REG_P;
9705
      int p2 = CURR_SLOT.opnd[1].X_add_number - REG_P;
9706
      valueT p1mask = (p1 != 0) ? (valueT) 1 << p1 : 0;
9707
      valueT p2mask = (p2 != 0) ? (valueT) 1 << p2 : 0;
9708
 
9709
      /* If both PRs are PR0, we can't really do anything.  */
9710
      if (p1 == 0 && p2 == 0)
9711
        {
9712
          if (md.debug_dv)
9713
            fprintf (stderr, "  Ignoring PRs due to inclusion of p0\n");
9714
        }
9715
      /* In general, clear mutexes and implies which include P1 or P2,
9716
         with the following exceptions.  */
9717
      else if (has_suffix_p (idesc->name, ".or.andcm")
9718
               || has_suffix_p (idesc->name, ".and.orcm"))
9719
        {
9720
          clear_qp_implies (p2mask, p1mask);
9721
        }
9722
      else if (has_suffix_p (idesc->name, ".andcm")
9723
               || has_suffix_p (idesc->name, ".and"))
9724
        {
9725
          clear_qp_implies (0, p1mask | p2mask);
9726
        }
9727
      else if (has_suffix_p (idesc->name, ".orcm")
9728
               || has_suffix_p (idesc->name, ".or"))
9729
        {
9730
          clear_qp_mutex (p1mask | p2mask);
9731
          clear_qp_implies (p1mask | p2mask, 0);
9732
        }
9733
      else
9734
        {
9735
          int added = 0;
9736
 
9737
          clear_qp_implies (p1mask | p2mask, p1mask | p2mask);
9738
 
9739
          /* If one of the PRs is PR0, we call clear_qp_mutex.  */
9740
          if (p1 == 0 || p2 == 0)
9741
            clear_qp_mutex (p1mask | p2mask);
9742
          else
9743
            added = update_qp_mutex (p1mask | p2mask);
9744
 
9745
          if (CURR_SLOT.qp_regno == 0
9746
              || has_suffix_p (idesc->name, ".unc"))
9747
            {
9748
              if (added == 0 && p1 && p2)
9749
                add_qp_mutex (p1mask | p2mask);
9750
              if (CURR_SLOT.qp_regno != 0)
9751
                {
9752
                  if (p1)
9753
                    add_qp_imply (p1, CURR_SLOT.qp_regno);
9754
                  if (p2)
9755
                    add_qp_imply (p2, CURR_SLOT.qp_regno);
9756
                }
9757
            }
9758
        }
9759
    }
9760
  /* Look for mov imm insns into GRs.  */
9761
  else if (idesc->operands[0] == IA64_OPND_R1
9762
           && (idesc->operands[1] == IA64_OPND_IMM22
9763
               || idesc->operands[1] == IA64_OPND_IMMU64)
9764
           && CURR_SLOT.opnd[1].X_op == O_constant
9765
           && (strcmp (idesc->name, "mov") == 0
9766
               || strcmp (idesc->name, "movl") == 0))
9767
    {
9768
      int regno = CURR_SLOT.opnd[0].X_add_number - REG_GR;
9769
      if (regno > 0 && regno < NELEMS (gr_values))
9770
        {
9771
          gr_values[regno].known = 1;
9772
          gr_values[regno].value = CURR_SLOT.opnd[1].X_add_number;
9773
          gr_values[regno].path = md.path;
9774
          if (md.debug_dv)
9775
            {
9776
              fprintf (stderr, "  Know gr%d = ", regno);
9777
              fprintf_vma (stderr, gr_values[regno].value);
9778
              fputs ("\n", stderr);
9779
            }
9780
        }
9781
    }
9782
  /* Look for dep.z imm insns.  */
9783
  else if (idesc->operands[0] == IA64_OPND_R1
9784
           && idesc->operands[1] == IA64_OPND_IMM8
9785
           && strcmp (idesc->name, "dep.z") == 0)
9786
    {
9787
      int regno = CURR_SLOT.opnd[0].X_add_number - REG_GR;
9788
      if (regno > 0 && regno < NELEMS (gr_values))
9789
        {
9790
          valueT value = CURR_SLOT.opnd[1].X_add_number;
9791
 
9792
          if (CURR_SLOT.opnd[3].X_add_number < 64)
9793
            value &= ((valueT)1 << CURR_SLOT.opnd[3].X_add_number) - 1;
9794
          value <<= CURR_SLOT.opnd[2].X_add_number;
9795
          gr_values[regno].known = 1;
9796
          gr_values[regno].value = value;
9797
          gr_values[regno].path = md.path;
9798
          if (md.debug_dv)
9799
            {
9800
              fprintf (stderr, "  Know gr%d = ", regno);
9801
              fprintf_vma (stderr, gr_values[regno].value);
9802
              fputs ("\n", stderr);
9803
            }
9804
        }
9805
    }
9806
  else
9807
    {
9808
      clear_qp_mutex (qp_changemask);
9809
      clear_qp_implies (qp_changemask, qp_changemask);
9810
    }
9811
}
9812
 
9813
/* Return whether the given predicate registers are currently mutex.  */
9814
 
9815
static int
9816
qp_mutex (int p1, int p2, int path)
9817
{
9818
  int i;
9819
  valueT mask;
9820
 
9821
  if (p1 != p2)
9822
    {
9823
      mask = ((valueT) 1 << p1) | (valueT) 1 << p2;
9824
      for (i = 0; i < qp_mutexeslen; i++)
9825
        {
9826
          if (qp_mutexes[i].path >= path
9827
              && (qp_mutexes[i].prmask & mask) == mask)
9828
            return 1;
9829
        }
9830
    }
9831
  return 0;
9832
}
9833
 
9834
/* Return whether the given resource is in the given insn's list of chks
9835
   Return 1 if the conflict is absolutely determined, 2 if it's a potential
9836
   conflict.  */
9837
 
9838
static int
9839
resources_match (struct rsrc *rs,
9840
                 struct ia64_opcode *idesc,
9841
                 int note,
9842
                 int qp_regno,
9843
                 int path)
9844
{
9845
  struct rsrc specs[MAX_SPECS];
9846
  int count;
9847
 
9848
  /* If the marked resource's qp_regno and the given qp_regno are mutex,
9849
     we don't need to check.  One exception is note 11, which indicates that
9850
     target predicates are written regardless of PR[qp].  */
9851
  if (qp_mutex (rs->qp_regno, qp_regno, path)
9852
      && note != 11)
9853
    return 0;
9854
 
9855
  count = specify_resource (rs->dependency, idesc, DV_CHK, specs, note, path);
9856
  while (count-- > 0)
9857
    {
9858
      /* UNAT checking is a bit more specific than other resources */
9859
      if (rs->dependency->specifier == IA64_RS_AR_UNAT
9860
          && specs[count].mem_offset.hint
9861
          && rs->mem_offset.hint)
9862
        {
9863
          if (rs->mem_offset.base == specs[count].mem_offset.base)
9864
            {
9865
              if (((rs->mem_offset.offset >> 3) & 0x3F) ==
9866
                  ((specs[count].mem_offset.offset >> 3) & 0x3F))
9867
                return 1;
9868
              else
9869
                continue;
9870
            }
9871
        }
9872
 
9873
      /* Skip apparent PR write conflicts where both writes are an AND or both
9874
         writes are an OR.  */
9875
      if (rs->dependency->specifier == IA64_RS_PR
9876
          || rs->dependency->specifier == IA64_RS_PRr
9877
          || rs->dependency->specifier == IA64_RS_PR63)
9878
        {
9879
          if (specs[count].cmp_type != CMP_NONE
9880
              && specs[count].cmp_type == rs->cmp_type)
9881
            {
9882
              if (md.debug_dv)
9883
                fprintf (stderr, "  %s on parallel compare allowed (PR%d)\n",
9884
                         dv_mode[rs->dependency->mode],
9885
                         rs->dependency->specifier != IA64_RS_PR63 ?
9886
                         specs[count].index : 63);
9887
              continue;
9888
            }
9889
          if (md.debug_dv)
9890
            fprintf (stderr,
9891
                     "  %s on parallel compare conflict %s vs %s on PR%d\n",
9892
                     dv_mode[rs->dependency->mode],
9893
                     dv_cmp_type[rs->cmp_type],
9894
                     dv_cmp_type[specs[count].cmp_type],
9895
                     rs->dependency->specifier != IA64_RS_PR63 ?
9896
                     specs[count].index : 63);
9897
 
9898
        }
9899
 
9900
      /* If either resource is not specific, conservatively assume a conflict
9901
       */
9902
      if (!specs[count].specific || !rs->specific)
9903
        return 2;
9904
      else if (specs[count].index == rs->index)
9905
        return 1;
9906
    }
9907
 
9908
  return 0;
9909
}
9910
 
9911
/* Indicate an instruction group break; if INSERT_STOP is non-zero, then
9912
   insert a stop to create the break.  Update all resource dependencies
9913
   appropriately.  If QP_REGNO is non-zero, only apply the break to resources
9914
   which use the same QP_REGNO and have the link_to_qp_branch flag set.
9915
   If SAVE_CURRENT is non-zero, don't affect resources marked by the current
9916
   instruction.  */
9917
 
9918
static void
9919
insn_group_break (int insert_stop, int qp_regno, int save_current)
9920
{
9921
  int i;
9922
 
9923
  if (insert_stop && md.num_slots_in_use > 0)
9924
    PREV_SLOT.end_of_insn_group = 1;
9925
 
9926
  if (md.debug_dv)
9927
    {
9928
      fprintf (stderr, "  Insn group break%s",
9929
               (insert_stop ? " (w/stop)" : ""));
9930
      if (qp_regno != 0)
9931
        fprintf (stderr, " effective for QP=%d", qp_regno);
9932
      fprintf (stderr, "\n");
9933
    }
9934
 
9935
  i = 0;
9936
  while (i < regdepslen)
9937
    {
9938
      const struct ia64_dependency *dep = regdeps[i].dependency;
9939
 
9940
      if (qp_regno != 0
9941
          && regdeps[i].qp_regno != qp_regno)
9942
        {
9943
          ++i;
9944
          continue;
9945
        }
9946
 
9947
      if (save_current
9948
          && CURR_SLOT.src_file == regdeps[i].file
9949
          && CURR_SLOT.src_line == regdeps[i].line)
9950
        {
9951
          ++i;
9952
          continue;
9953
        }
9954
 
9955
      /* clear dependencies which are automatically cleared by a stop, or
9956
         those that have reached the appropriate state of insn serialization */
9957
      if (dep->semantics == IA64_DVS_IMPLIED
9958
          || dep->semantics == IA64_DVS_IMPLIEDF
9959
          || regdeps[i].insn_srlz == STATE_SRLZ)
9960
        {
9961
          print_dependency ("Removing", i);
9962
          regdeps[i] = regdeps[--regdepslen];
9963
        }
9964
      else
9965
        {
9966
          if (dep->semantics == IA64_DVS_DATA
9967
              || dep->semantics == IA64_DVS_INSTR
9968
              || dep->semantics == IA64_DVS_SPECIFIC)
9969
            {
9970
              if (regdeps[i].insn_srlz == STATE_NONE)
9971
                regdeps[i].insn_srlz = STATE_STOP;
9972
              if (regdeps[i].data_srlz == STATE_NONE)
9973
                regdeps[i].data_srlz = STATE_STOP;
9974
            }
9975
          ++i;
9976
        }
9977
    }
9978
}
9979
 
9980
/* Add the given resource usage spec to the list of active dependencies.  */
9981
 
9982
static void
9983
mark_resource (struct ia64_opcode *idesc ATTRIBUTE_UNUSED,
9984
               const struct ia64_dependency *dep ATTRIBUTE_UNUSED,
9985
               struct rsrc *spec,
9986
               int depind,
9987
               int path)
9988
{
9989
  if (regdepslen == regdepstotlen)
9990
    {
9991
      regdepstotlen += 20;
9992
      regdeps = (struct rsrc *)
9993
        xrealloc ((void *) regdeps,
9994
                  regdepstotlen * sizeof (struct rsrc));
9995
    }
9996
 
9997
  regdeps[regdepslen] = *spec;
9998
  regdeps[regdepslen].depind = depind;
9999
  regdeps[regdepslen].path = path;
10000
  regdeps[regdepslen].file = CURR_SLOT.src_file;
10001
  regdeps[regdepslen].line = CURR_SLOT.src_line;
10002
 
10003
  print_dependency ("Adding", regdepslen);
10004
 
10005
  ++regdepslen;
10006
}
10007
 
10008
static void
10009
print_dependency (const char *action, int depind)
10010
{
10011
  if (md.debug_dv)
10012
    {
10013
      fprintf (stderr, "  %s %s '%s'",
10014
               action, dv_mode[(regdeps[depind].dependency)->mode],
10015
               (regdeps[depind].dependency)->name);
10016
      if (regdeps[depind].specific && regdeps[depind].index >= 0)
10017
        fprintf (stderr, " (%d)", regdeps[depind].index);
10018
      if (regdeps[depind].mem_offset.hint)
10019
        {
10020
          fputs (" ", stderr);
10021
          fprintf_vma (stderr, regdeps[depind].mem_offset.base);
10022
          fputs ("+", stderr);
10023
          fprintf_vma (stderr, regdeps[depind].mem_offset.offset);
10024
        }
10025
      fprintf (stderr, "\n");
10026
    }
10027
}
10028
 
10029
static void
10030
instruction_serialization (void)
10031
{
10032
  int i;
10033
  if (md.debug_dv)
10034
    fprintf (stderr, "  Instruction serialization\n");
10035
  for (i = 0; i < regdepslen; i++)
10036
    if (regdeps[i].insn_srlz == STATE_STOP)
10037
      regdeps[i].insn_srlz = STATE_SRLZ;
10038
}
10039
 
10040
static void
10041
data_serialization (void)
10042
{
10043
  int i = 0;
10044
  if (md.debug_dv)
10045
    fprintf (stderr, "  Data serialization\n");
10046
  while (i < regdepslen)
10047
    {
10048
      if (regdeps[i].data_srlz == STATE_STOP
10049
          /* Note: as of 991210, all "other" dependencies are cleared by a
10050
             data serialization.  This might change with new tables */
10051
          || (regdeps[i].dependency)->semantics == IA64_DVS_OTHER)
10052
        {
10053
          print_dependency ("Removing", i);
10054
          regdeps[i] = regdeps[--regdepslen];
10055
        }
10056
      else
10057
        ++i;
10058
    }
10059
}
10060
 
10061
/* Insert stops and serializations as needed to avoid DVs.  */
10062
 
10063
static void
10064
remove_marked_resource (struct rsrc *rs)
10065
{
10066
  switch (rs->dependency->semantics)
10067
    {
10068
    case IA64_DVS_SPECIFIC:
10069
      if (md.debug_dv)
10070
        fprintf (stderr, "Implementation-specific, assume worst case...\n");
10071
      /* ...fall through...  */
10072
    case IA64_DVS_INSTR:
10073
      if (md.debug_dv)
10074
        fprintf (stderr, "Inserting instr serialization\n");
10075
      if (rs->insn_srlz < STATE_STOP)
10076
        insn_group_break (1, 0, 0);
10077
      if (rs->insn_srlz < STATE_SRLZ)
10078
        {
10079
          struct slot oldslot = CURR_SLOT;
10080
          /* Manually jam a srlz.i insn into the stream */
10081
          memset (&CURR_SLOT, 0, sizeof (CURR_SLOT));
10082
          CURR_SLOT.user_template = -1;
10083
          CURR_SLOT.idesc = ia64_find_opcode ("srlz.i");
10084
          instruction_serialization ();
10085
          md.curr_slot = (md.curr_slot + 1) % NUM_SLOTS;
10086
          if (++md.num_slots_in_use >= NUM_SLOTS)
10087
            emit_one_bundle ();
10088
          CURR_SLOT = oldslot;
10089
        }
10090
      insn_group_break (1, 0, 0);
10091
      break;
10092
    case IA64_DVS_OTHER: /* as of rev2 (991220) of the DV tables, all
10093
                            "other" types of DV are eliminated
10094
                            by a data serialization */
10095
    case IA64_DVS_DATA:
10096
      if (md.debug_dv)
10097
        fprintf (stderr, "Inserting data serialization\n");
10098
      if (rs->data_srlz < STATE_STOP)
10099
        insn_group_break (1, 0, 0);
10100
      {
10101
        struct slot oldslot = CURR_SLOT;
10102
        /* Manually jam a srlz.d insn into the stream */
10103
        memset (&CURR_SLOT, 0, sizeof (CURR_SLOT));
10104
        CURR_SLOT.user_template = -1;
10105
        CURR_SLOT.idesc = ia64_find_opcode ("srlz.d");
10106
        data_serialization ();
10107
        md.curr_slot = (md.curr_slot + 1) % NUM_SLOTS;
10108
        if (++md.num_slots_in_use >= NUM_SLOTS)
10109
          emit_one_bundle ();
10110
        CURR_SLOT = oldslot;
10111
      }
10112
      break;
10113
    case IA64_DVS_IMPLIED:
10114
    case IA64_DVS_IMPLIEDF:
10115
      if (md.debug_dv)
10116
        fprintf (stderr, "Inserting stop\n");
10117
      insn_group_break (1, 0, 0);
10118
      break;
10119
    default:
10120
      break;
10121
    }
10122
}
10123
 
10124
/* Check the resources used by the given opcode against the current dependency
10125
   list.
10126
 
10127
   The check is run once for each execution path encountered.  In this case,
10128
   a unique execution path is the sequence of instructions following a code
10129
   entry point, e.g. the following has three execution paths, one starting
10130
   at L0, one at L1, and one at L2.
10131
 
10132
   L0:     nop
10133
   L1:     add
10134
   L2:     add
10135
   br.ret
10136
*/
10137
 
10138
static void
10139
check_dependencies (struct ia64_opcode *idesc)
10140
{
10141
  const struct ia64_opcode_dependency *opdeps = idesc->dependencies;
10142
  int path;
10143
  int i;
10144
 
10145
  /* Note that the number of marked resources may change within the
10146
     loop if in auto mode.  */
10147
  i = 0;
10148
  while (i < regdepslen)
10149
    {
10150
      struct rsrc *rs = &regdeps[i];
10151
      const struct ia64_dependency *dep = rs->dependency;
10152
      int chkind;
10153
      int note;
10154
      int start_over = 0;
10155
 
10156
      if (dep->semantics == IA64_DVS_NONE
10157
          || (chkind = depends_on (rs->depind, idesc)) == -1)
10158
        {
10159
          ++i;
10160
          continue;
10161
        }
10162
 
10163
      note = NOTE (opdeps->chks[chkind]);
10164
 
10165
      /* Check this resource against each execution path seen thus far.  */
10166
      for (path = 0; path <= md.path; path++)
10167
        {
10168
          int matchtype;
10169
 
10170
          /* If the dependency wasn't on the path being checked, ignore it.  */
10171
          if (rs->path < path)
10172
            continue;
10173
 
10174
          /* If the QP for this insn implies a QP which has branched, don't
10175
             bother checking.  Ed. NOTE: I don't think this check is terribly
10176
             useful; what's the point of generating code which will only be
10177
             reached if its QP is zero?
10178
             This code was specifically inserted to handle the following code,
10179
             based on notes from Intel's DV checking code, where p1 implies p2.
10180
 
10181
                  mov r4 = 2
10182
             (p2) br.cond L
10183
             (p1) mov r4 = 7
10184
          */
10185
          if (CURR_SLOT.qp_regno != 0)
10186
            {
10187
              int skip = 0;
10188
              int implies;
10189
              for (implies = 0; implies < qp_implieslen; implies++)
10190
                {
10191
                  if (qp_implies[implies].path >= path
10192
                      && qp_implies[implies].p1 == CURR_SLOT.qp_regno
10193
                      && qp_implies[implies].p2_branched)
10194
                    {
10195
                      skip = 1;
10196
                      break;
10197
                    }
10198
                }
10199
              if (skip)
10200
                continue;
10201
            }
10202
 
10203
          if ((matchtype = resources_match (rs, idesc, note,
10204
                                            CURR_SLOT.qp_regno, path)) != 0)
10205
            {
10206
              char msg[1024];
10207
              char pathmsg[256] = "";
10208
              char indexmsg[256] = "";
10209
              int certain = (matchtype == 1 && CURR_SLOT.qp_regno == 0);
10210
 
10211
              if (path != 0)
10212
                snprintf (pathmsg, sizeof (pathmsg),
10213
                          " when entry is at label '%s'",
10214
                         md.entry_labels[path - 1]);
10215
              if (matchtype == 1 && rs->index >= 0)
10216
                snprintf (indexmsg, sizeof (indexmsg),
10217
                          ", specific resource number is %d",
10218
                         rs->index);
10219
              snprintf (msg, sizeof (msg),
10220
                        "Use of '%s' %s %s dependency '%s' (%s)%s%s",
10221
                       idesc->name,
10222
                       (certain ? "violates" : "may violate"),
10223
                       dv_mode[dep->mode], dep->name,
10224
                       dv_sem[dep->semantics],
10225
                       pathmsg, indexmsg);
10226
 
10227
              if (md.explicit_mode)
10228
                {
10229
                  as_warn ("%s", msg);
10230
                  if (path < md.path)
10231
                    as_warn (_("Only the first path encountering the conflict is reported"));
10232
                  as_warn_where (rs->file, rs->line,
10233
                                 _("This is the location of the conflicting usage"));
10234
                  /* Don't bother checking other paths, to avoid duplicating
10235
                     the same warning */
10236
                  break;
10237
                }
10238
              else
10239
                {
10240
                  if (md.debug_dv)
10241
                    fprintf (stderr, "%s @ %s:%d\n", msg, rs->file, rs->line);
10242
 
10243
                  remove_marked_resource (rs);
10244
 
10245
                  /* since the set of dependencies has changed, start over */
10246
                  /* FIXME -- since we're removing dvs as we go, we
10247
                     probably don't really need to start over...  */
10248
                  start_over = 1;
10249
                  break;
10250
                }
10251
            }
10252
        }
10253
      if (start_over)
10254
        i = 0;
10255
      else
10256
        ++i;
10257
    }
10258
}
10259
 
10260
/* Register new dependencies based on the given opcode.  */
10261
 
10262
static void
10263
mark_resources (struct ia64_opcode *idesc)
10264
{
10265
  int i;
10266
  const struct ia64_opcode_dependency *opdeps = idesc->dependencies;
10267
  int add_only_qp_reads = 0;
10268
 
10269
  /* A conditional branch only uses its resources if it is taken; if it is
10270
     taken, we stop following that path.  The other branch types effectively
10271
     *always* write their resources.  If it's not taken, register only QP
10272
     reads.  */
10273
  if (is_conditional_branch (idesc) || is_interruption_or_rfi (idesc))
10274
    {
10275
      add_only_qp_reads = 1;
10276
    }
10277
 
10278
  if (md.debug_dv)
10279
    fprintf (stderr, "Registering '%s' resource usage\n", idesc->name);
10280
 
10281
  for (i = 0; i < opdeps->nregs; i++)
10282
    {
10283
      const struct ia64_dependency *dep;
10284
      struct rsrc specs[MAX_SPECS];
10285
      int note;
10286
      int path;
10287
      int count;
10288
 
10289
      dep = ia64_find_dependency (opdeps->regs[i]);
10290
      note = NOTE (opdeps->regs[i]);
10291
 
10292
      if (add_only_qp_reads
10293
          && !(dep->mode == IA64_DV_WAR
10294
               && (dep->specifier == IA64_RS_PR
10295
                   || dep->specifier == IA64_RS_PRr
10296
                   || dep->specifier == IA64_RS_PR63)))
10297
        continue;
10298
 
10299
      count = specify_resource (dep, idesc, DV_REG, specs, note, md.path);
10300
 
10301
      while (count-- > 0)
10302
        {
10303
          mark_resource (idesc, dep, &specs[count],
10304
                         DEP (opdeps->regs[i]), md.path);
10305
        }
10306
 
10307
      /* The execution path may affect register values, which may in turn
10308
         affect which indirect-access resources are accessed.  */
10309
      switch (dep->specifier)
10310
        {
10311
        default:
10312
          break;
10313
        case IA64_RS_CPUID:
10314
        case IA64_RS_DBR:
10315
        case IA64_RS_IBR:
10316
        case IA64_RS_MSR:
10317
        case IA64_RS_PKR:
10318
        case IA64_RS_PMC:
10319
        case IA64_RS_PMD:
10320
        case IA64_RS_RR:
10321
          for (path = 0; path < md.path; path++)
10322
            {
10323
              count = specify_resource (dep, idesc, DV_REG, specs, note, path);
10324
              while (count-- > 0)
10325
                mark_resource (idesc, dep, &specs[count],
10326
                               DEP (opdeps->regs[i]), path);
10327
            }
10328
          break;
10329
        }
10330
    }
10331
}
10332
 
10333
/* Remove dependencies when they no longer apply.  */
10334
 
10335
static void
10336
update_dependencies (struct ia64_opcode *idesc)
10337
{
10338
  int i;
10339
 
10340
  if (strcmp (idesc->name, "srlz.i") == 0)
10341
    {
10342
      instruction_serialization ();
10343
    }
10344
  else if (strcmp (idesc->name, "srlz.d") == 0)
10345
    {
10346
      data_serialization ();
10347
    }
10348
  else if (is_interruption_or_rfi (idesc)
10349
           || is_taken_branch (idesc))
10350
    {
10351
      /* Although technically the taken branch doesn't clear dependencies
10352
         which require a srlz.[id], we don't follow the branch; the next
10353
         instruction is assumed to start with a clean slate.  */
10354
      regdepslen = 0;
10355
      md.path = 0;
10356
    }
10357
  else if (is_conditional_branch (idesc)
10358
           && CURR_SLOT.qp_regno != 0)
10359
    {
10360
      int is_call = strstr (idesc->name, ".call") != NULL;
10361
 
10362
      for (i = 0; i < qp_implieslen; i++)
10363
        {
10364
          /* If the conditional branch's predicate is implied by the predicate
10365
             in an existing dependency, remove that dependency.  */
10366
          if (qp_implies[i].p2 == CURR_SLOT.qp_regno)
10367
            {
10368
              int depind = 0;
10369
              /* Note that this implied predicate takes a branch so that if
10370
                 a later insn generates a DV but its predicate implies this
10371
                 one, we can avoid the false DV warning.  */
10372
              qp_implies[i].p2_branched = 1;
10373
              while (depind < regdepslen)
10374
                {
10375
                  if (regdeps[depind].qp_regno == qp_implies[i].p1)
10376
                    {
10377
                      print_dependency ("Removing", depind);
10378
                      regdeps[depind] = regdeps[--regdepslen];
10379
                    }
10380
                  else
10381
                    ++depind;
10382
                }
10383
            }
10384
        }
10385
      /* Any marked resources which have this same predicate should be
10386
         cleared, provided that the QP hasn't been modified between the
10387
         marking instruction and the branch.  */
10388
      if (is_call)
10389
        {
10390
          insn_group_break (0, CURR_SLOT.qp_regno, 1);
10391
        }
10392
      else
10393
        {
10394
          i = 0;
10395
          while (i < regdepslen)
10396
            {
10397
              if (regdeps[i].qp_regno == CURR_SLOT.qp_regno
10398
                  && regdeps[i].link_to_qp_branch
10399
                  && (regdeps[i].file != CURR_SLOT.src_file
10400
                      || regdeps[i].line != CURR_SLOT.src_line))
10401
                {
10402
                  /* Treat like a taken branch */
10403
                  print_dependency ("Removing", i);
10404
                  regdeps[i] = regdeps[--regdepslen];
10405
                }
10406
              else
10407
                ++i;
10408
            }
10409
        }
10410
    }
10411
}
10412
 
10413
/* Examine the current instruction for dependency violations.  */
10414
 
10415
static int
10416
check_dv (struct ia64_opcode *idesc)
10417
{
10418
  if (md.debug_dv)
10419
    {
10420
      fprintf (stderr, "Checking %s for violations (line %d, %d/%d)\n",
10421
               idesc->name, CURR_SLOT.src_line,
10422
               idesc->dependencies->nchks,
10423
               idesc->dependencies->nregs);
10424
    }
10425
 
10426
  /* Look through the list of currently marked resources; if the current
10427
     instruction has the dependency in its chks list which uses that resource,
10428
     check against the specific resources used.  */
10429
  check_dependencies (idesc);
10430
 
10431
  /* Look up the instruction's regdeps (RAW writes, WAW writes, and WAR reads),
10432
     then add them to the list of marked resources.  */
10433
  mark_resources (idesc);
10434
 
10435
  /* There are several types of dependency semantics, and each has its own
10436
     requirements for being cleared
10437
 
10438
     Instruction serialization (insns separated by interruption, rfi, or
10439
     writer + srlz.i + reader, all in separate groups) clears DVS_INSTR.
10440
 
10441
     Data serialization (instruction serialization, or writer + srlz.d +
10442
     reader, where writer and srlz.d are in separate groups) clears
10443
     DVS_DATA. (This also clears DVS_OTHER, but that is not guaranteed to
10444
     always be the case).
10445
 
10446
     Instruction group break (groups separated by stop, taken branch,
10447
     interruption or rfi) clears DVS_IMPLIED and DVS_IMPLIEDF.
10448
   */
10449
  update_dependencies (idesc);
10450
 
10451
  /* Sometimes, knowing a register value allows us to avoid giving a false DV
10452
     warning.  Keep track of as many as possible that are useful.  */
10453
  note_register_values (idesc);
10454
 
10455
  /* We don't need or want this anymore.  */
10456
  md.mem_offset.hint = 0;
10457
 
10458
  return 0;
10459
}
10460
 
10461
/* Translate one line of assembly.  Pseudo ops and labels do not show
10462
   here.  */
10463
void
10464
md_assemble (char *str)
10465
{
10466
  char *saved_input_line_pointer, *mnemonic;
10467
  const struct pseudo_opcode *pdesc;
10468
  struct ia64_opcode *idesc;
10469
  unsigned char qp_regno;
10470
  unsigned int flags;
10471
  int ch;
10472
 
10473
  saved_input_line_pointer = input_line_pointer;
10474
  input_line_pointer = str;
10475
 
10476
  /* extract the opcode (mnemonic):  */
10477
 
10478
  mnemonic = input_line_pointer;
10479
  ch = get_symbol_end ();
10480
  pdesc = (struct pseudo_opcode *) hash_find (md.pseudo_hash, mnemonic);
10481
  if (pdesc)
10482
    {
10483
      *input_line_pointer = ch;
10484
      (*pdesc->handler) (pdesc->arg);
10485
      goto done;
10486
    }
10487
 
10488
  /* Find the instruction descriptor matching the arguments.  */
10489
 
10490
  idesc = ia64_find_opcode (mnemonic);
10491
  *input_line_pointer = ch;
10492
  if (!idesc)
10493
    {
10494
      as_bad (_("Unknown opcode `%s'"), mnemonic);
10495
      goto done;
10496
    }
10497
 
10498
  idesc = parse_operands (idesc);
10499
  if (!idesc)
10500
    goto done;
10501
 
10502
  /* Handle the dynamic ops we can handle now:  */
10503
  if (idesc->type == IA64_TYPE_DYN)
10504
    {
10505
      if (strcmp (idesc->name, "add") == 0)
10506
        {
10507
          if (CURR_SLOT.opnd[2].X_op == O_register
10508
              && CURR_SLOT.opnd[2].X_add_number < 4)
10509
            mnemonic = "addl";
10510
          else
10511
            mnemonic = "adds";
10512
          ia64_free_opcode (idesc);
10513
          idesc = ia64_find_opcode (mnemonic);
10514
        }
10515
      else if (strcmp (idesc->name, "mov") == 0)
10516
        {
10517
          enum ia64_opnd opnd1, opnd2;
10518
          int rop;
10519
 
10520
          opnd1 = idesc->operands[0];
10521
          opnd2 = idesc->operands[1];
10522
          if (opnd1 == IA64_OPND_AR3)
10523
            rop = 0;
10524
          else if (opnd2 == IA64_OPND_AR3)
10525
            rop = 1;
10526
          else
10527
            abort ();
10528
          if (CURR_SLOT.opnd[rop].X_op == O_register)
10529
            {
10530
              if (ar_is_only_in_integer_unit (CURR_SLOT.opnd[rop].X_add_number))
10531
                mnemonic = "mov.i";
10532
              else if (ar_is_only_in_memory_unit (CURR_SLOT.opnd[rop].X_add_number))
10533
                mnemonic = "mov.m";
10534
              else
10535
                rop = -1;
10536
            }
10537
          else
10538
            abort ();
10539
          if (rop >= 0)
10540
            {
10541
              ia64_free_opcode (idesc);
10542
              idesc = ia64_find_opcode (mnemonic);
10543
              while (idesc != NULL
10544
                     && (idesc->operands[0] != opnd1
10545
                         || idesc->operands[1] != opnd2))
10546
                idesc = get_next_opcode (idesc);
10547
            }
10548
        }
10549
    }
10550
  else if (strcmp (idesc->name, "mov.i") == 0
10551
           || strcmp (idesc->name, "mov.m") == 0)
10552
    {
10553
      enum ia64_opnd opnd1, opnd2;
10554
      int rop;
10555
 
10556
      opnd1 = idesc->operands[0];
10557
      opnd2 = idesc->operands[1];
10558
      if (opnd1 == IA64_OPND_AR3)
10559
        rop = 0;
10560
      else if (opnd2 == IA64_OPND_AR3)
10561
        rop = 1;
10562
      else
10563
        abort ();
10564
      if (CURR_SLOT.opnd[rop].X_op == O_register)
10565
        {
10566
          char unit = 'a';
10567
          if (ar_is_only_in_integer_unit (CURR_SLOT.opnd[rop].X_add_number))
10568
            unit = 'i';
10569
          else if (ar_is_only_in_memory_unit (CURR_SLOT.opnd[rop].X_add_number))
10570
            unit = 'm';
10571
          if (unit != 'a' && unit != idesc->name [4])
10572
            as_bad (_("AR %d can only be accessed by %c-unit"),
10573
                    (int) (CURR_SLOT.opnd[rop].X_add_number - REG_AR),
10574
                    TOUPPER (unit));
10575
        }
10576
    }
10577
  else if (strcmp (idesc->name, "hint.b") == 0)
10578
    {
10579
      switch (md.hint_b)
10580
        {
10581
        case hint_b_ok:
10582
          break;
10583
        case hint_b_warning:
10584
          as_warn (_("hint.b may be treated as nop"));
10585
          break;
10586
        case hint_b_error:
10587
          as_bad (_("hint.b shouldn't be used"));
10588
          break;
10589
        }
10590
    }
10591
 
10592
  qp_regno = 0;
10593
  if (md.qp.X_op == O_register)
10594
    {
10595
      qp_regno = md.qp.X_add_number - REG_P;
10596
      md.qp.X_op = O_absent;
10597
    }
10598
 
10599
  flags = idesc->flags;
10600
 
10601
  if ((flags & IA64_OPCODE_FIRST) != 0)
10602
    {
10603
      /* The alignment frag has to end with a stop bit only if the
10604
         next instruction after the alignment directive has to be
10605
         the first instruction in an instruction group.  */
10606
      if (align_frag)
10607
        {
10608
          while (align_frag->fr_type != rs_align_code)
10609
            {
10610
              align_frag = align_frag->fr_next;
10611
              if (!align_frag)
10612
                break;
10613
            }
10614
          /* align_frag can be NULL if there are directives in
10615
             between.  */
10616
          if (align_frag && align_frag->fr_next == frag_now)
10617
            align_frag->tc_frag_data = 1;
10618
        }
10619
 
10620
      insn_group_break (1, 0, 0);
10621
    }
10622
  align_frag = NULL;
10623
 
10624
  if ((flags & IA64_OPCODE_NO_PRED) != 0 && qp_regno != 0)
10625
    {
10626
      as_bad (_("`%s' cannot be predicated"), idesc->name);
10627
      goto done;
10628
    }
10629
 
10630
  /* Build the instruction.  */
10631
  CURR_SLOT.qp_regno = qp_regno;
10632
  CURR_SLOT.idesc = idesc;
10633
  as_where (&CURR_SLOT.src_file, &CURR_SLOT.src_line);
10634
  dwarf2_where (&CURR_SLOT.debug_line);
10635
  dwarf2_consume_line_info ();
10636
 
10637
  /* Add unwind entries, if there are any.  */
10638
  if (unwind.current_entry)
10639
    {
10640
      CURR_SLOT.unwind_record = unwind.current_entry;
10641
      unwind.current_entry = NULL;
10642
    }
10643
  if (unwind.pending_saves)
10644
    {
10645
      if (unwind.pending_saves->next)
10646
        {
10647
          /* Attach the next pending save to the next slot so that its
10648
             slot number will get set correctly.  */
10649
          add_unwind_entry (unwind.pending_saves->next, NOT_A_CHAR);
10650
          unwind.pending_saves = &unwind.pending_saves->next->r.record.p;
10651
        }
10652
      else
10653
        unwind.pending_saves = NULL;
10654
    }
10655
  if (unwind.proc_pending.sym && S_IS_DEFINED (unwind.proc_pending.sym))
10656
    unwind.insn = 1;
10657
 
10658
  /* Check for dependency violations.  */
10659
  if (md.detect_dv)
10660
    check_dv (idesc);
10661
 
10662
  md.curr_slot = (md.curr_slot + 1) % NUM_SLOTS;
10663
  if (++md.num_slots_in_use >= NUM_SLOTS)
10664
    emit_one_bundle ();
10665
 
10666
  if ((flags & IA64_OPCODE_LAST) != 0)
10667
    insn_group_break (1, 0, 0);
10668
 
10669
  md.last_text_seg = now_seg;
10670
 
10671
 done:
10672
  input_line_pointer = saved_input_line_pointer;
10673
}
10674
 
10675
/* Called when symbol NAME cannot be found in the symbol table.
10676
   Should be used for dynamic valued symbols only.  */
10677
 
10678
symbolS *
10679
md_undefined_symbol (char *name ATTRIBUTE_UNUSED)
10680
{
10681
  return 0;
10682
}
10683
 
10684
/* Called for any expression that can not be recognized.  When the
10685
   function is called, `input_line_pointer' will point to the start of
10686
   the expression.  */
10687
 
10688
void
10689
md_operand (expressionS *e)
10690
{
10691
  switch (*input_line_pointer)
10692
    {
10693
    case '[':
10694
      ++input_line_pointer;
10695
      expression_and_evaluate (e);
10696
      if (*input_line_pointer != ']')
10697
        {
10698
          as_bad (_("Closing bracket missing"));
10699
          goto err;
10700
        }
10701
      else
10702
        {
10703
          if (e->X_op != O_register
10704
              || e->X_add_number < REG_GR
10705
              || e->X_add_number > REG_GR + 127)
10706
            {
10707
              as_bad (_("Index must be a general register"));
10708
              e->X_add_number = REG_GR;
10709
            }
10710
 
10711
          ++input_line_pointer;
10712
          e->X_op = O_index;
10713
        }
10714
      break;
10715
 
10716
    default:
10717
      break;
10718
    }
10719
  return;
10720
 
10721
 err:
10722
  ignore_rest_of_line ();
10723
}
10724
 
10725
/* Return 1 if it's OK to adjust a reloc by replacing the symbol with
10726
   a section symbol plus some offset.  For relocs involving @fptr(),
10727
   directives we don't want such adjustments since we need to have the
10728
   original symbol's name in the reloc.  */
10729
int
10730
ia64_fix_adjustable (fixS *fix)
10731
{
10732
  /* Prevent all adjustments to global symbols */
10733
  if (S_IS_EXTERNAL (fix->fx_addsy) || S_IS_WEAK (fix->fx_addsy))
10734
    return 0;
10735
 
10736
  switch (fix->fx_r_type)
10737
    {
10738
    case BFD_RELOC_IA64_FPTR64I:
10739
    case BFD_RELOC_IA64_FPTR32MSB:
10740
    case BFD_RELOC_IA64_FPTR32LSB:
10741
    case BFD_RELOC_IA64_FPTR64MSB:
10742
    case BFD_RELOC_IA64_FPTR64LSB:
10743
    case BFD_RELOC_IA64_LTOFF_FPTR22:
10744
    case BFD_RELOC_IA64_LTOFF_FPTR64I:
10745
      return 0;
10746
    default:
10747
      break;
10748
    }
10749
 
10750
  return 1;
10751
}
10752
 
10753
int
10754
ia64_force_relocation (fixS *fix)
10755
{
10756
  switch (fix->fx_r_type)
10757
    {
10758
    case BFD_RELOC_IA64_FPTR64I:
10759
    case BFD_RELOC_IA64_FPTR32MSB:
10760
    case BFD_RELOC_IA64_FPTR32LSB:
10761
    case BFD_RELOC_IA64_FPTR64MSB:
10762
    case BFD_RELOC_IA64_FPTR64LSB:
10763
 
10764
    case BFD_RELOC_IA64_LTOFF22:
10765
    case BFD_RELOC_IA64_LTOFF64I:
10766
    case BFD_RELOC_IA64_LTOFF_FPTR22:
10767
    case BFD_RELOC_IA64_LTOFF_FPTR64I:
10768
    case BFD_RELOC_IA64_PLTOFF22:
10769
    case BFD_RELOC_IA64_PLTOFF64I:
10770
    case BFD_RELOC_IA64_PLTOFF64MSB:
10771
    case BFD_RELOC_IA64_PLTOFF64LSB:
10772
 
10773
    case BFD_RELOC_IA64_LTOFF22X:
10774
    case BFD_RELOC_IA64_LDXMOV:
10775
      return 1;
10776
 
10777
    default:
10778
      break;
10779
    }
10780
 
10781
  return generic_force_reloc (fix);
10782
}
10783
 
10784
/* Decide from what point a pc-relative relocation is relative to,
10785
   relative to the pc-relative fixup.  Er, relatively speaking.  */
10786
long
10787
ia64_pcrel_from_section (fixS *fix, segT sec)
10788
{
10789
  unsigned long off = fix->fx_frag->fr_address + fix->fx_where;
10790
 
10791
  if (bfd_get_section_flags (stdoutput, sec) & SEC_CODE)
10792
    off &= ~0xfUL;
10793
 
10794
  return off;
10795
}
10796
 
10797
 
10798
/* Used to emit section-relative relocs for the dwarf2 debug data.  */
10799
void
10800
ia64_dwarf2_emit_offset (symbolS *symbol, unsigned int size)
10801
{
10802
  expressionS expr;
10803
 
10804
  expr.X_op = O_pseudo_fixup;
10805
  expr.X_op_symbol = pseudo_func[FUNC_SEC_RELATIVE].u.sym;
10806
  expr.X_add_number = 0;
10807
  expr.X_add_symbol = symbol;
10808
  emit_expr (&expr, size);
10809
}
10810
 
10811
/* This is called whenever some data item (not an instruction) needs a
10812
   fixup.  We pick the right reloc code depending on the byteorder
10813
   currently in effect.  */
10814
void
10815
ia64_cons_fix_new (fragS *f, int where, int nbytes, expressionS *exp)
10816
{
10817
  bfd_reloc_code_real_type code;
10818
  fixS *fix;
10819
 
10820
  switch (nbytes)
10821
    {
10822
      /* There are no reloc for 8 and 16 bit quantities, but we allow
10823
         them here since they will work fine as long as the expression
10824
         is fully defined at the end of the pass over the source file.  */
10825
    case 1: code = BFD_RELOC_8; break;
10826
    case 2: code = BFD_RELOC_16; break;
10827
    case 4:
10828
      if (target_big_endian)
10829
        code = BFD_RELOC_IA64_DIR32MSB;
10830
      else
10831
        code = BFD_RELOC_IA64_DIR32LSB;
10832
      break;
10833
 
10834
    case 8:
10835
      /* In 32-bit mode, data8 could mean function descriptors too.  */
10836
      if (exp->X_op == O_pseudo_fixup
10837
          && exp->X_op_symbol
10838
          && S_GET_VALUE (exp->X_op_symbol) == FUNC_IPLT_RELOC
10839
          && !(md.flags & EF_IA_64_ABI64))
10840
        {
10841
          if (target_big_endian)
10842
            code = BFD_RELOC_IA64_IPLTMSB;
10843
          else
10844
            code = BFD_RELOC_IA64_IPLTLSB;
10845
          exp->X_op = O_symbol;
10846
          break;
10847
        }
10848
      else
10849
        {
10850
          if (target_big_endian)
10851
            code = BFD_RELOC_IA64_DIR64MSB;
10852
          else
10853
            code = BFD_RELOC_IA64_DIR64LSB;
10854
          break;
10855
        }
10856
 
10857
    case 16:
10858
      if (exp->X_op == O_pseudo_fixup
10859
          && exp->X_op_symbol
10860
          && S_GET_VALUE (exp->X_op_symbol) == FUNC_IPLT_RELOC)
10861
        {
10862
          if (target_big_endian)
10863
            code = BFD_RELOC_IA64_IPLTMSB;
10864
          else
10865
            code = BFD_RELOC_IA64_IPLTLSB;
10866
          exp->X_op = O_symbol;
10867
          break;
10868
        }
10869
      /* FALLTHRU */
10870
 
10871
    default:
10872
      as_bad (_("Unsupported fixup size %d"), nbytes);
10873
      ignore_rest_of_line ();
10874
      return;
10875
    }
10876
 
10877
  if (exp->X_op == O_pseudo_fixup)
10878
    {
10879
      exp->X_op = O_symbol;
10880
      code = ia64_gen_real_reloc_type (exp->X_op_symbol, code);
10881
      /* ??? If code unchanged, unsupported.  */
10882
    }
10883
 
10884
  fix = fix_new_exp (f, where, nbytes, exp, 0, code);
10885
  /* We need to store the byte order in effect in case we're going
10886
     to fix an 8 or 16 bit relocation (for which there no real
10887
     relocs available).  See md_apply_fix().  */
10888
  fix->tc_fix_data.bigendian = target_big_endian;
10889
}
10890
 
10891
/* Return the actual relocation we wish to associate with the pseudo
10892
   reloc described by SYM and R_TYPE.  SYM should be one of the
10893
   symbols in the pseudo_func array, or NULL.  */
10894
 
10895
static bfd_reloc_code_real_type
10896
ia64_gen_real_reloc_type (struct symbol *sym, bfd_reloc_code_real_type r_type)
10897
{
10898
  bfd_reloc_code_real_type newr = 0;
10899
  const char *type = NULL, *suffix = "";
10900
 
10901
  if (sym == NULL)
10902
    {
10903
      return r_type;
10904
    }
10905
 
10906
  switch (S_GET_VALUE (sym))
10907
    {
10908
    case FUNC_FPTR_RELATIVE:
10909
      switch (r_type)
10910
        {
10911
        case BFD_RELOC_IA64_IMM64:      newr = BFD_RELOC_IA64_FPTR64I; break;
10912
        case BFD_RELOC_IA64_DIR32MSB:   newr = BFD_RELOC_IA64_FPTR32MSB; break;
10913
        case BFD_RELOC_IA64_DIR32LSB:   newr = BFD_RELOC_IA64_FPTR32LSB; break;
10914
        case BFD_RELOC_IA64_DIR64MSB:   newr = BFD_RELOC_IA64_FPTR64MSB; break;
10915
        case BFD_RELOC_IA64_DIR64LSB:   newr = BFD_RELOC_IA64_FPTR64LSB; break;
10916
        default:                        type = "FPTR"; break;
10917
        }
10918
      break;
10919
 
10920
    case FUNC_GP_RELATIVE:
10921
      switch (r_type)
10922
        {
10923
        case BFD_RELOC_IA64_IMM22:      newr = BFD_RELOC_IA64_GPREL22; break;
10924
        case BFD_RELOC_IA64_IMM64:      newr = BFD_RELOC_IA64_GPREL64I; break;
10925
        case BFD_RELOC_IA64_DIR32MSB:   newr = BFD_RELOC_IA64_GPREL32MSB; break;
10926
        case BFD_RELOC_IA64_DIR32LSB:   newr = BFD_RELOC_IA64_GPREL32LSB; break;
10927
        case BFD_RELOC_IA64_DIR64MSB:   newr = BFD_RELOC_IA64_GPREL64MSB; break;
10928
        case BFD_RELOC_IA64_DIR64LSB:   newr = BFD_RELOC_IA64_GPREL64LSB; break;
10929
        default:                        type = "GPREL"; break;
10930
        }
10931
      break;
10932
 
10933
    case FUNC_LT_RELATIVE:
10934
      switch (r_type)
10935
        {
10936
        case BFD_RELOC_IA64_IMM22:      newr = BFD_RELOC_IA64_LTOFF22; break;
10937
        case BFD_RELOC_IA64_IMM64:      newr = BFD_RELOC_IA64_LTOFF64I; break;
10938
        default:                        type = "LTOFF"; break;
10939
        }
10940
      break;
10941
 
10942
    case FUNC_LT_RELATIVE_X:
10943
      switch (r_type)
10944
        {
10945
        case BFD_RELOC_IA64_IMM22:      newr = BFD_RELOC_IA64_LTOFF22X; break;
10946
        default:                        type = "LTOFF"; suffix = "X"; break;
10947
        }
10948
      break;
10949
 
10950
    case FUNC_PC_RELATIVE:
10951
      switch (r_type)
10952
        {
10953
        case BFD_RELOC_IA64_IMM22:      newr = BFD_RELOC_IA64_PCREL22; break;
10954
        case BFD_RELOC_IA64_IMM64:      newr = BFD_RELOC_IA64_PCREL64I; break;
10955
        case BFD_RELOC_IA64_DIR32MSB:   newr = BFD_RELOC_IA64_PCREL32MSB; break;
10956
        case BFD_RELOC_IA64_DIR32LSB:   newr = BFD_RELOC_IA64_PCREL32LSB; break;
10957
        case BFD_RELOC_IA64_DIR64MSB:   newr = BFD_RELOC_IA64_PCREL64MSB; break;
10958
        case BFD_RELOC_IA64_DIR64LSB:   newr = BFD_RELOC_IA64_PCREL64LSB; break;
10959
        default:                        type = "PCREL"; break;
10960
        }
10961
      break;
10962
 
10963
    case FUNC_PLT_RELATIVE:
10964
      switch (r_type)
10965
        {
10966
        case BFD_RELOC_IA64_IMM22:      newr = BFD_RELOC_IA64_PLTOFF22; break;
10967
        case BFD_RELOC_IA64_IMM64:      newr = BFD_RELOC_IA64_PLTOFF64I; break;
10968
        case BFD_RELOC_IA64_DIR64MSB:   newr = BFD_RELOC_IA64_PLTOFF64MSB;break;
10969
        case BFD_RELOC_IA64_DIR64LSB:   newr = BFD_RELOC_IA64_PLTOFF64LSB;break;
10970
        default:                        type = "PLTOFF"; break;
10971
        }
10972
      break;
10973
 
10974
    case FUNC_SEC_RELATIVE:
10975
      switch (r_type)
10976
        {
10977
        case BFD_RELOC_IA64_DIR32MSB:   newr = BFD_RELOC_IA64_SECREL32MSB;break;
10978
        case BFD_RELOC_IA64_DIR32LSB:   newr = BFD_RELOC_IA64_SECREL32LSB;break;
10979
        case BFD_RELOC_IA64_DIR64MSB:   newr = BFD_RELOC_IA64_SECREL64MSB;break;
10980
        case BFD_RELOC_IA64_DIR64LSB:   newr = BFD_RELOC_IA64_SECREL64LSB;break;
10981
        default:                        type = "SECREL"; break;
10982
        }
10983
      break;
10984
 
10985
    case FUNC_SEG_RELATIVE:
10986
      switch (r_type)
10987
        {
10988
        case BFD_RELOC_IA64_DIR32MSB:   newr = BFD_RELOC_IA64_SEGREL32MSB;break;
10989
        case BFD_RELOC_IA64_DIR32LSB:   newr = BFD_RELOC_IA64_SEGREL32LSB;break;
10990
        case BFD_RELOC_IA64_DIR64MSB:   newr = BFD_RELOC_IA64_SEGREL64MSB;break;
10991
        case BFD_RELOC_IA64_DIR64LSB:   newr = BFD_RELOC_IA64_SEGREL64LSB;break;
10992
        default:                        type = "SEGREL"; break;
10993
        }
10994
      break;
10995
 
10996
    case FUNC_LTV_RELATIVE:
10997
      switch (r_type)
10998
        {
10999
        case BFD_RELOC_IA64_DIR32MSB:   newr = BFD_RELOC_IA64_LTV32MSB; break;
11000
        case BFD_RELOC_IA64_DIR32LSB:   newr = BFD_RELOC_IA64_LTV32LSB; break;
11001
        case BFD_RELOC_IA64_DIR64MSB:   newr = BFD_RELOC_IA64_LTV64MSB; break;
11002
        case BFD_RELOC_IA64_DIR64LSB:   newr = BFD_RELOC_IA64_LTV64LSB; break;
11003
        default:                        type = "LTV"; break;
11004
        }
11005
      break;
11006
 
11007
    case FUNC_LT_FPTR_RELATIVE:
11008
      switch (r_type)
11009
        {
11010
        case BFD_RELOC_IA64_IMM22:
11011
          newr = BFD_RELOC_IA64_LTOFF_FPTR22; break;
11012
        case BFD_RELOC_IA64_IMM64:
11013
          newr = BFD_RELOC_IA64_LTOFF_FPTR64I; break;
11014
        case BFD_RELOC_IA64_DIR32MSB:
11015
          newr = BFD_RELOC_IA64_LTOFF_FPTR32MSB; break;
11016
        case BFD_RELOC_IA64_DIR32LSB:
11017
          newr = BFD_RELOC_IA64_LTOFF_FPTR32LSB; break;
11018
        case BFD_RELOC_IA64_DIR64MSB:
11019
          newr = BFD_RELOC_IA64_LTOFF_FPTR64MSB; break;
11020
        case BFD_RELOC_IA64_DIR64LSB:
11021
          newr = BFD_RELOC_IA64_LTOFF_FPTR64LSB; break;
11022
        default:
11023
          type = "LTOFF_FPTR"; break;
11024
        }
11025
      break;
11026
 
11027
    case FUNC_TP_RELATIVE:
11028
      switch (r_type)
11029
        {
11030
        case BFD_RELOC_IA64_IMM14:      newr = BFD_RELOC_IA64_TPREL14; break;
11031
        case BFD_RELOC_IA64_IMM22:      newr = BFD_RELOC_IA64_TPREL22; break;
11032
        case BFD_RELOC_IA64_IMM64:      newr = BFD_RELOC_IA64_TPREL64I; break;
11033
        case BFD_RELOC_IA64_DIR64MSB:   newr = BFD_RELOC_IA64_TPREL64MSB; break;
11034
        case BFD_RELOC_IA64_DIR64LSB:   newr = BFD_RELOC_IA64_TPREL64LSB; break;
11035
        default:                        type = "TPREL"; break;
11036
        }
11037
      break;
11038
 
11039
    case FUNC_LT_TP_RELATIVE:
11040
      switch (r_type)
11041
        {
11042
        case BFD_RELOC_IA64_IMM22:
11043
          newr = BFD_RELOC_IA64_LTOFF_TPREL22; break;
11044
        default:
11045
          type = "LTOFF_TPREL"; break;
11046
        }
11047
      break;
11048
 
11049
    case FUNC_DTP_MODULE:
11050
      switch (r_type)
11051
        {
11052
        case BFD_RELOC_IA64_DIR64MSB:
11053
          newr = BFD_RELOC_IA64_DTPMOD64MSB; break;
11054
        case BFD_RELOC_IA64_DIR64LSB:
11055
          newr = BFD_RELOC_IA64_DTPMOD64LSB; break;
11056
        default:
11057
          type = "DTPMOD"; break;
11058
        }
11059
      break;
11060
 
11061
    case FUNC_LT_DTP_MODULE:
11062
      switch (r_type)
11063
        {
11064
        case BFD_RELOC_IA64_IMM22:
11065
          newr = BFD_RELOC_IA64_LTOFF_DTPMOD22; break;
11066
        default:
11067
          type = "LTOFF_DTPMOD"; break;
11068
        }
11069
      break;
11070
 
11071
    case FUNC_DTP_RELATIVE:
11072
      switch (r_type)
11073
        {
11074
        case BFD_RELOC_IA64_DIR32MSB:
11075
          newr = BFD_RELOC_IA64_DTPREL32MSB; break;
11076
        case BFD_RELOC_IA64_DIR32LSB:
11077
          newr = BFD_RELOC_IA64_DTPREL32LSB; break;
11078
        case BFD_RELOC_IA64_DIR64MSB:
11079
          newr = BFD_RELOC_IA64_DTPREL64MSB; break;
11080
        case BFD_RELOC_IA64_DIR64LSB:
11081
          newr = BFD_RELOC_IA64_DTPREL64LSB; break;
11082
        case BFD_RELOC_IA64_IMM14:
11083
          newr = BFD_RELOC_IA64_DTPREL14; break;
11084
        case BFD_RELOC_IA64_IMM22:
11085
          newr = BFD_RELOC_IA64_DTPREL22; break;
11086
        case BFD_RELOC_IA64_IMM64:
11087
          newr = BFD_RELOC_IA64_DTPREL64I; break;
11088
        default:
11089
          type = "DTPREL"; break;
11090
        }
11091
      break;
11092
 
11093
    case FUNC_LT_DTP_RELATIVE:
11094
      switch (r_type)
11095
        {
11096
        case BFD_RELOC_IA64_IMM22:
11097
          newr = BFD_RELOC_IA64_LTOFF_DTPREL22; break;
11098
        default:
11099
          type = "LTOFF_DTPREL"; break;
11100
        }
11101
      break;
11102
 
11103
    case FUNC_IPLT_RELOC:
11104
      switch (r_type)
11105
        {
11106
        case BFD_RELOC_IA64_IPLTMSB:    return r_type;
11107
        case BFD_RELOC_IA64_IPLTLSB:    return r_type;
11108
        default:                        type = "IPLT"; break;
11109
        }
11110
      break;
11111
 
11112
    default:
11113
      abort ();
11114
    }
11115
 
11116
  if (newr)
11117
    return newr;
11118
  else
11119
    {
11120
      int width;
11121
 
11122
      if (!type)
11123
        abort ();
11124
      switch (r_type)
11125
        {
11126
        case BFD_RELOC_IA64_DIR32MSB: width = 32; suffix = "MSB"; break;
11127
        case BFD_RELOC_IA64_DIR32LSB: width = 32; suffix = "LSB"; break;
11128
        case BFD_RELOC_IA64_DIR64MSB: width = 64; suffix = "MSB"; break;
11129
        case BFD_RELOC_IA64_DIR64LSB: width = 64; suffix = "LSB"; break;
11130
        case BFD_RELOC_UNUSED:        width = 13; break;
11131
        case BFD_RELOC_IA64_IMM14:    width = 14; break;
11132
        case BFD_RELOC_IA64_IMM22:    width = 22; break;
11133
        case BFD_RELOC_IA64_IMM64:    width = 64; suffix = "I"; break;
11134
        default:                      abort ();
11135
        }
11136
 
11137
      /* This should be an error, but since previously there wasn't any
11138
         diagnostic here, don't make it fail because of this for now.  */
11139
      as_warn (_("Cannot express %s%d%s relocation"), type, width, suffix);
11140
      return r_type;
11141
    }
11142
}
11143
 
11144
/* Here is where generate the appropriate reloc for pseudo relocation
11145
   functions.  */
11146
void
11147
ia64_validate_fix (fixS *fix)
11148
{
11149
  switch (fix->fx_r_type)
11150
    {
11151
    case BFD_RELOC_IA64_FPTR64I:
11152
    case BFD_RELOC_IA64_FPTR32MSB:
11153
    case BFD_RELOC_IA64_FPTR64LSB:
11154
    case BFD_RELOC_IA64_LTOFF_FPTR22:
11155
    case BFD_RELOC_IA64_LTOFF_FPTR64I:
11156
      if (fix->fx_offset != 0)
11157
        as_bad_where (fix->fx_file, fix->fx_line,
11158
                      _("No addend allowed in @fptr() relocation"));
11159
      break;
11160
    default:
11161
      break;
11162
    }
11163
}
11164
 
11165
static void
11166
fix_insn (fixS *fix, const struct ia64_operand *odesc, valueT value)
11167
{
11168
  bfd_vma insn[3], t0, t1, control_bits;
11169
  const char *err;
11170
  char *fixpos;
11171
  long slot;
11172
 
11173
  slot = fix->fx_where & 0x3;
11174
  fixpos = fix->fx_frag->fr_literal + (fix->fx_where - slot);
11175
 
11176
  /* Bundles are always in little-endian byte order */
11177
  t0 = bfd_getl64 (fixpos);
11178
  t1 = bfd_getl64 (fixpos + 8);
11179
  control_bits = t0 & 0x1f;
11180
  insn[0] = (t0 >>  5) & 0x1ffffffffffLL;
11181
  insn[1] = ((t0 >> 46) & 0x3ffff) | ((t1 & 0x7fffff) << 18);
11182
  insn[2] = (t1 >> 23) & 0x1ffffffffffLL;
11183
 
11184
  err = NULL;
11185
  if (odesc - elf64_ia64_operands == IA64_OPND_IMMU64)
11186
    {
11187
      insn[1] = (value >> 22) & 0x1ffffffffffLL;
11188
      insn[2] |= (((value & 0x7f) << 13)
11189
                  | (((value >> 7) & 0x1ff) << 27)
11190
                  | (((value >> 16) & 0x1f) << 22)
11191
                  | (((value >> 21) & 0x1) << 21)
11192
                  | (((value >> 63) & 0x1) << 36));
11193
    }
11194
  else if (odesc - elf64_ia64_operands == IA64_OPND_IMMU62)
11195
    {
11196
      if (value & ~0x3fffffffffffffffULL)
11197
        err = _("integer operand out of range");
11198
      insn[1] = (value >> 21) & 0x1ffffffffffLL;
11199
      insn[2] |= (((value & 0xfffff) << 6) | (((value >> 20) & 0x1) << 36));
11200
    }
11201
  else if (odesc - elf64_ia64_operands == IA64_OPND_TGT64)
11202
    {
11203
      value >>= 4;
11204
      insn[1] = ((value >> 20) & 0x7fffffffffLL) << 2;
11205
      insn[2] |= ((((value >> 59) & 0x1) << 36)
11206
                  | (((value >> 0) & 0xfffff) << 13));
11207
    }
11208
  else
11209
    err = (*odesc->insert) (odesc, value, insn + slot);
11210
 
11211
  if (err)
11212
    as_bad_where (fix->fx_file, fix->fx_line, "%s", err);
11213
 
11214
  t0 = control_bits | (insn[0] << 5) | (insn[1] << 46);
11215
  t1 = ((insn[1] >> 18) & 0x7fffff) | (insn[2] << 23);
11216
  number_to_chars_littleendian (fixpos + 0, t0, 8);
11217
  number_to_chars_littleendian (fixpos + 8, t1, 8);
11218
}
11219
 
11220
/* Attempt to simplify or even eliminate a fixup.  The return value is
11221
   ignored; perhaps it was once meaningful, but now it is historical.
11222
   To indicate that a fixup has been eliminated, set FIXP->FX_DONE.
11223
 
11224
   If fixp->fx_addsy is non-NULL, we'll have to generate a reloc entry
11225
   (if possible).  */
11226
 
11227
void
11228
md_apply_fix (fixS *fix, valueT *valP, segT seg ATTRIBUTE_UNUSED)
11229
{
11230
  char *fixpos;
11231
  valueT value = *valP;
11232
 
11233
  fixpos = fix->fx_frag->fr_literal + fix->fx_where;
11234
 
11235
  if (fix->fx_pcrel)
11236
    {
11237
    switch (fix->fx_r_type)
11238
      {
11239
      case BFD_RELOC_IA64_PCREL21B: break;
11240
      case BFD_RELOC_IA64_PCREL21BI: break;
11241
      case BFD_RELOC_IA64_PCREL21F: break;
11242
      case BFD_RELOC_IA64_PCREL21M: break;
11243
      case BFD_RELOC_IA64_PCREL60B: break;
11244
      case BFD_RELOC_IA64_PCREL22: break;
11245
      case BFD_RELOC_IA64_PCREL64I: break;
11246
      case BFD_RELOC_IA64_PCREL32MSB: break;
11247
      case BFD_RELOC_IA64_PCREL32LSB: break;
11248
      case BFD_RELOC_IA64_PCREL64MSB: break;
11249
      case BFD_RELOC_IA64_PCREL64LSB: break;
11250
      default:
11251
        fix->fx_r_type = ia64_gen_real_reloc_type (pseudo_func[FUNC_PC_RELATIVE].u.sym,
11252
                                               fix->fx_r_type);
11253
        break;
11254
      }
11255
    }
11256
  if (fix->fx_addsy)
11257
    {
11258
      switch (fix->fx_r_type)
11259
        {
11260
        case BFD_RELOC_UNUSED:
11261
          /* This must be a TAG13 or TAG13b operand.  There are no external
11262
             relocs defined for them, so we must give an error.  */
11263
          as_bad_where (fix->fx_file, fix->fx_line,
11264
                        _("%s must have a constant value"),
11265
                        elf64_ia64_operands[fix->tc_fix_data.opnd].desc);
11266
          fix->fx_done = 1;
11267
          return;
11268
 
11269
        case BFD_RELOC_IA64_TPREL14:
11270
        case BFD_RELOC_IA64_TPREL22:
11271
        case BFD_RELOC_IA64_TPREL64I:
11272
        case BFD_RELOC_IA64_LTOFF_TPREL22:
11273
        case BFD_RELOC_IA64_LTOFF_DTPMOD22:
11274
        case BFD_RELOC_IA64_DTPREL14:
11275
        case BFD_RELOC_IA64_DTPREL22:
11276
        case BFD_RELOC_IA64_DTPREL64I:
11277
        case BFD_RELOC_IA64_LTOFF_DTPREL22:
11278
          S_SET_THREAD_LOCAL (fix->fx_addsy);
11279
          break;
11280
 
11281
        default:
11282
          break;
11283
        }
11284
    }
11285
  else if (fix->tc_fix_data.opnd == IA64_OPND_NIL)
11286
    {
11287
      if (fix->tc_fix_data.bigendian)
11288
        number_to_chars_bigendian (fixpos, value, fix->fx_size);
11289
      else
11290
        number_to_chars_littleendian (fixpos, value, fix->fx_size);
11291
      fix->fx_done = 1;
11292
    }
11293
  else
11294
    {
11295
      fix_insn (fix, elf64_ia64_operands + fix->tc_fix_data.opnd, value);
11296
      fix->fx_done = 1;
11297
    }
11298
}
11299
 
11300
/* Generate the BFD reloc to be stuck in the object file from the
11301
   fixup used internally in the assembler.  */
11302
 
11303
arelent *
11304
tc_gen_reloc (asection *sec ATTRIBUTE_UNUSED, fixS *fixp)
11305
{
11306
  arelent *reloc;
11307
 
11308
  reloc = xmalloc (sizeof (*reloc));
11309
  reloc->sym_ptr_ptr = (asymbol **) xmalloc (sizeof (asymbol *));
11310
  *reloc->sym_ptr_ptr = symbol_get_bfdsym (fixp->fx_addsy);
11311
  reloc->address = fixp->fx_frag->fr_address + fixp->fx_where;
11312
  reloc->addend = fixp->fx_offset;
11313
  reloc->howto = bfd_reloc_type_lookup (stdoutput, fixp->fx_r_type);
11314
 
11315
  if (!reloc->howto)
11316
    {
11317
      as_bad_where (fixp->fx_file, fixp->fx_line,
11318
                    _("Cannot represent %s relocation in object file"),
11319
                    bfd_get_reloc_code_name (fixp->fx_r_type));
11320
      free (reloc);
11321
      return NULL;
11322
    }
11323
  return reloc;
11324
}
11325
 
11326
/* Turn a string in input_line_pointer into a floating point constant
11327
   of type TYPE, and store the appropriate bytes in *LIT.  The number
11328
   of LITTLENUMS emitted is stored in *SIZE.  An error message is
11329
   returned, or NULL on OK.  */
11330
 
11331
#define MAX_LITTLENUMS 5
11332
 
11333
char *
11334
md_atof (int type, char *lit, int *size)
11335
{
11336
  LITTLENUM_TYPE words[MAX_LITTLENUMS];
11337
  char *t;
11338
  int prec;
11339
 
11340
  switch (type)
11341
    {
11342
      /* IEEE floats */
11343
    case 'f':
11344
    case 'F':
11345
    case 's':
11346
    case 'S':
11347
      prec = 2;
11348
      break;
11349
 
11350
    case 'd':
11351
    case 'D':
11352
    case 'r':
11353
    case 'R':
11354
      prec = 4;
11355
      break;
11356
 
11357
    case 'x':
11358
    case 'X':
11359
    case 'p':
11360
    case 'P':
11361
      prec = 5;
11362
      break;
11363
 
11364
    default:
11365
      *size = 0;
11366
      return _("Unrecognized or unsupported floating point constant");
11367
    }
11368
  t = atof_ieee (input_line_pointer, type, words);
11369
  if (t)
11370
    input_line_pointer = t;
11371
 
11372
  (*ia64_float_to_chars) (lit, words, prec);
11373
 
11374
  if (type == 'X')
11375
    {
11376
      /* It is 10 byte floating point with 6 byte padding.  */
11377
      memset (&lit [10], 0, 6);
11378
      *size = 8 * sizeof (LITTLENUM_TYPE);
11379
    }
11380
  else
11381
    *size = prec * sizeof (LITTLENUM_TYPE);
11382
 
11383
  return NULL;
11384
}
11385
 
11386
/* Handle ia64 specific semantics of the align directive.  */
11387
 
11388
void
11389
ia64_md_do_align (int n ATTRIBUTE_UNUSED,
11390
                  const char *fill ATTRIBUTE_UNUSED,
11391
                  int len ATTRIBUTE_UNUSED,
11392
                  int max ATTRIBUTE_UNUSED)
11393
{
11394
  if (subseg_text_p (now_seg))
11395
    ia64_flush_insns ();
11396
}
11397
 
11398
/* This is called from HANDLE_ALIGN in write.c.  Fill in the contents
11399
   of an rs_align_code fragment.  */
11400
 
11401
void
11402
ia64_handle_align (fragS *fragp)
11403
{
11404
  int bytes;
11405
  char *p;
11406
  const unsigned char *nop;
11407
 
11408
  if (fragp->fr_type != rs_align_code)
11409
    return;
11410
 
11411
  /* Check if this frag has to end with a stop bit.  */
11412
  nop = fragp->tc_frag_data ? le_nop_stop : le_nop;
11413
 
11414
  bytes = fragp->fr_next->fr_address - fragp->fr_address - fragp->fr_fix;
11415
  p = fragp->fr_literal + fragp->fr_fix;
11416
 
11417
  /* If no paddings are needed, we check if we need a stop bit.  */
11418
  if (!bytes && fragp->tc_frag_data)
11419
    {
11420
      if (fragp->fr_fix < 16)
11421
#if 1
11422
        /* FIXME: It won't work with
11423
           .align 16
11424
           alloc r32=ar.pfs,1,2,4,0
11425
         */
11426
        ;
11427
#else
11428
        as_bad_where (fragp->fr_file, fragp->fr_line,
11429
                      _("Can't add stop bit to mark end of instruction group"));
11430
#endif
11431
      else
11432
        /* Bundles are always in little-endian byte order. Make sure
11433
           the previous bundle has the stop bit.  */
11434
        *(p - 16) |= 1;
11435
    }
11436
 
11437
  /* Make sure we are on a 16-byte boundary, in case someone has been
11438
     putting data into a text section.  */
11439
  if (bytes & 15)
11440
    {
11441
      int fix = bytes & 15;
11442
      memset (p, 0, fix);
11443
      p += fix;
11444
      bytes -= fix;
11445
      fragp->fr_fix += fix;
11446
    }
11447
 
11448
  /* Instruction bundles are always little-endian.  */
11449
  memcpy (p, nop, 16);
11450
  fragp->fr_var = 16;
11451
}
11452
 
11453
static void
11454
ia64_float_to_chars_bigendian (char *lit, LITTLENUM_TYPE *words,
11455
                               int prec)
11456
{
11457
  while (prec--)
11458
    {
11459
      number_to_chars_bigendian (lit, (long) (*words++),
11460
                                 sizeof (LITTLENUM_TYPE));
11461
      lit += sizeof (LITTLENUM_TYPE);
11462
    }
11463
}
11464
 
11465
static void
11466
ia64_float_to_chars_littleendian (char *lit, LITTLENUM_TYPE *words,
11467
                                  int prec)
11468
{
11469
  while (prec--)
11470
    {
11471
      number_to_chars_littleendian (lit, (long) (words[prec]),
11472
                                    sizeof (LITTLENUM_TYPE));
11473
      lit += sizeof (LITTLENUM_TYPE);
11474
    }
11475
}
11476
 
11477
void
11478
ia64_elf_section_change_hook (void)
11479
{
11480
  if (elf_section_type (now_seg) == SHT_IA_64_UNWIND
11481
      && elf_linked_to_section (now_seg) == NULL)
11482
    elf_linked_to_section (now_seg) = text_section;
11483
  dot_byteorder (-1);
11484
}
11485
 
11486
/* Check if a label should be made global.  */
11487
void
11488
ia64_check_label (symbolS *label)
11489
{
11490
  if (*input_line_pointer == ':')
11491
    {
11492
      S_SET_EXTERNAL (label);
11493
      input_line_pointer++;
11494
    }
11495
}
11496
 
11497
/* Used to remember where .alias and .secalias directives are seen. We
11498
   will rename symbol and section names when we are about to output
11499
   the relocatable file.  */
11500
struct alias
11501
{
11502
  char *file;           /* The file where the directive is seen.  */
11503
  unsigned int line;    /* The line number the directive is at.  */
11504
  const char *name;     /* The original name of the symbol.  */
11505
};
11506
 
11507
/* Called for .alias and .secalias directives. If SECTION is 1, it is
11508
   .secalias. Otherwise, it is .alias.  */
11509
static void
11510
dot_alias (int section)
11511
{
11512
  char *name, *alias;
11513
  char delim;
11514
  char *end_name;
11515
  int len;
11516
  const char *error_string;
11517
  struct alias *h;
11518
  const char *a;
11519
  struct hash_control *ahash, *nhash;
11520
  const char *kind;
11521
 
11522
  name = input_line_pointer;
11523
  delim = get_symbol_end ();
11524
  end_name = input_line_pointer;
11525
  *end_name = delim;
11526
 
11527
  if (name == end_name)
11528
    {
11529
      as_bad (_("expected symbol name"));
11530
      ignore_rest_of_line ();
11531
      return;
11532
    }
11533
 
11534
  SKIP_WHITESPACE ();
11535
 
11536
  if (*input_line_pointer != ',')
11537
    {
11538
      *end_name = 0;
11539
      as_bad (_("expected comma after \"%s\""), name);
11540
      *end_name = delim;
11541
      ignore_rest_of_line ();
11542
      return;
11543
    }
11544
 
11545
  input_line_pointer++;
11546
  *end_name = 0;
11547
  ia64_canonicalize_symbol_name (name);
11548
 
11549
  /* We call demand_copy_C_string to check if alias string is valid.
11550
     There should be a closing `"' and no `\0' in the string.  */
11551
  alias = demand_copy_C_string (&len);
11552
  if (alias == NULL)
11553
    {
11554
      ignore_rest_of_line ();
11555
      return;
11556
    }
11557
 
11558
  /* Make a copy of name string.  */
11559
  len = strlen (name) + 1;
11560
  obstack_grow (&notes, name, len);
11561
  name = obstack_finish (&notes);
11562
 
11563
  if (section)
11564
    {
11565
      kind = "section";
11566
      ahash = secalias_hash;
11567
      nhash = secalias_name_hash;
11568
    }
11569
  else
11570
    {
11571
      kind = "symbol";
11572
      ahash = alias_hash;
11573
      nhash = alias_name_hash;
11574
    }
11575
 
11576
  /* Check if alias has been used before.  */
11577
  h = (struct alias *) hash_find (ahash, alias);
11578
  if (h)
11579
    {
11580
      if (strcmp (h->name, name))
11581
        as_bad (_("`%s' is already the alias of %s `%s'"),
11582
                alias, kind, h->name);
11583
      goto out;
11584
    }
11585
 
11586
  /* Check if name already has an alias.  */
11587
  a = (const char *) hash_find (nhash, name);
11588
  if (a)
11589
    {
11590
      if (strcmp (a, alias))
11591
        as_bad (_("%s `%s' already has an alias `%s'"), kind, name, a);
11592
      goto out;
11593
    }
11594
 
11595
  h = (struct alias *) xmalloc (sizeof (struct alias));
11596
  as_where (&h->file, &h->line);
11597
  h->name = name;
11598
 
11599
  error_string = hash_jam (ahash, alias, (void *) h);
11600
  if (error_string)
11601
    {
11602
      as_fatal (_("inserting \"%s\" into %s alias hash table failed: %s"),
11603
                alias, kind, error_string);
11604
      goto out;
11605
    }
11606
 
11607
  error_string = hash_jam (nhash, name, (void *) alias);
11608
  if (error_string)
11609
    {
11610
      as_fatal (_("inserting \"%s\" into %s name hash table failed: %s"),
11611
                alias, kind, error_string);
11612
out:
11613
      obstack_free (&notes, name);
11614
      obstack_free (&notes, alias);
11615
    }
11616
 
11617
  demand_empty_rest_of_line ();
11618
}
11619
 
11620
/* It renames the original symbol name to its alias.  */
11621
static void
11622
do_alias (const char *alias, void *value)
11623
{
11624
  struct alias *h = (struct alias *) value;
11625
  symbolS *sym = symbol_find (h->name);
11626
 
11627
  if (sym == NULL)
11628
    {
11629
#ifdef TE_VMS
11630
      /* Uses .alias extensively to alias CRTL functions to same with
11631
         decc$ prefix. Sometimes function gets optimized away and a
11632
         warning results, which should be suppressed.  */
11633
      if (strncmp (alias, "decc$", 5) != 0)
11634
#endif
11635
        as_warn_where (h->file, h->line,
11636
                       _("symbol `%s' aliased to `%s' is not used"),
11637
                       h->name, alias);
11638
    }
11639
    else
11640
      S_SET_NAME (sym, (char *) alias);
11641
}
11642
 
11643
/* Called from write_object_file.  */
11644
void
11645
ia64_adjust_symtab (void)
11646
{
11647
  hash_traverse (alias_hash, do_alias);
11648
}
11649
 
11650
/* It renames the original section name to its alias.  */
11651
static void
11652
do_secalias (const char *alias, void *value)
11653
{
11654
  struct alias *h = (struct alias *) value;
11655
  segT sec = bfd_get_section_by_name (stdoutput, h->name);
11656
 
11657
  if (sec == NULL)
11658
    as_warn_where (h->file, h->line,
11659
                   _("section `%s' aliased to `%s' is not used"),
11660
                   h->name, alias);
11661
  else
11662
    sec->name = alias;
11663
}
11664
 
11665
/* Called from write_object_file.  */
11666
void
11667
ia64_frob_file (void)
11668
{
11669
  hash_traverse (secalias_hash, do_secalias);
11670
}
11671
 
11672
#ifdef TE_VMS
11673
#define NT_VMS_MHD 1
11674
#define NT_VMS_LNM 2
11675
 
11676
/* Integrity VMS 8.x identifies it's ELF modules with a standard ELF
11677
   .note section.  */
11678
 
11679
/* Manufacture a VMS-like time string.  */
11680
static void
11681
get_vms_time (char *Now)
11682
{
11683
  char *pnt;
11684
  time_t timeb;
11685
 
11686
  time (&timeb);
11687
  pnt = ctime (&timeb);
11688
  pnt[3] = 0;
11689
  pnt[7] = 0;
11690
  pnt[10] = 0;
11691
  pnt[16] = 0;
11692
  pnt[24] = 0;
11693
  sprintf (Now, "%2s-%3s-%s %s", pnt + 8, pnt + 4, pnt + 20, pnt + 11);
11694
}
11695
 
11696
void
11697
ia64_vms_note (void)
11698
{
11699
  char *p;
11700
  asection *seg = now_seg;
11701
  subsegT subseg = now_subseg;
11702
  Elf_Internal_Note i_note;
11703
  asection *secp = NULL;
11704
  char *bname;
11705
  char buf [256];
11706
  symbolS *sym;
11707
 
11708
  /* Create the .note section.  */
11709
 
11710
  secp = subseg_new (".note", 0);
11711
  bfd_set_section_flags (stdoutput,
11712
                         secp,
11713
                         SEC_HAS_CONTENTS | SEC_READONLY);
11714
 
11715
  /* Module header note.  */
11716
  bname = xstrdup (lbasename (out_file_name));
11717
  if ((p = strrchr (bname, '.')))
11718
    *p = '\0';
11719
 
11720
  i_note.namesz = 8;
11721
  i_note.descsz = 40 + strlen (bname);
11722
  i_note.type = NT_VMS_MHD;
11723
 
11724
  p = frag_more (sizeof (i_note.namesz));
11725
  number_to_chars_littleendian (p, i_note.namesz, 8);
11726
 
11727
  p = frag_more (sizeof (i_note.descsz));
11728
  number_to_chars_littleendian (p, i_note.descsz, 8);
11729
 
11730
  p = frag_more (sizeof (i_note.type));
11731
  number_to_chars_littleendian (p, i_note.type, 8);
11732
 
11733
  p = frag_more (8);
11734
  strcpy (p, "IPF/VMS");
11735
 
11736
  get_vms_time (buf);
11737
  p = frag_more (17);
11738
  strcpy (p, buf);
11739
 
11740
  p = frag_more (17);
11741
  strcpy (p, "24-FEB-2005 15:00");
11742
 
11743
  p = frag_more (strlen (bname) + 1);
11744
  strcpy (p, bname);
11745
  free (bname);
11746
 
11747
  p = frag_more (5);
11748
  strcpy (p, "V1.0");
11749
 
11750
  frag_align (3, 0, 0);
11751
 
11752
  /* Language processor name note.  */
11753
  sprintf (buf, "GNU assembler version %s (%s) using BFD version %s",
11754
           VERSION, TARGET_ALIAS, BFD_VERSION_STRING);
11755
 
11756
  i_note.namesz = 8;
11757
  i_note.descsz = 1 + strlen (buf);
11758
  i_note.type = NT_VMS_LNM;
11759
 
11760
  p = frag_more (sizeof (i_note.namesz));
11761
  number_to_chars_littleendian (p, i_note.namesz, 8);
11762
 
11763
  p = frag_more (sizeof (i_note.descsz));
11764
  number_to_chars_littleendian (p, i_note.descsz, 8);
11765
 
11766
  p = frag_more (sizeof (i_note.type));
11767
  number_to_chars_littleendian (p, i_note.type, 8);
11768
 
11769
  p = frag_more (8);
11770
  strcpy (p, "IPF/VMS");
11771
 
11772
  p = frag_more (strlen (buf) + 1);
11773
  strcpy (p, buf);
11774
 
11775
  frag_align (3, 0, 0);
11776
 
11777
  secp = subseg_new (".vms_display_name_info", 0);
11778
  bfd_set_section_flags (stdoutput,
11779
                         secp,
11780
                         SEC_HAS_CONTENTS | SEC_READONLY);
11781
 
11782
  /* This symbol should be passed on the command line and be variable
11783
     according to language.  */
11784
  sym = symbol_new ("__gnat_vms_display_name@gnat_demangler_rtl",
11785
                    absolute_section, 0, &zero_address_frag);
11786
  symbol_table_insert (sym);
11787
  symbol_get_bfdsym (sym)->flags |= BSF_DEBUGGING | BSF_DYNAMIC;
11788
 
11789
  p = frag_more (4);
11790
  /* Format 3 of VMS demangler Spec.  */
11791
  number_to_chars_littleendian (p, 3, 4);
11792
 
11793
  p = frag_more (4);
11794
  /* Place holder for symbol table index of above symbol.  */
11795
  number_to_chars_littleendian (p, -1, 4);
11796
 
11797
  frag_align (3, 0, 0);
11798
 
11799
  /* We probably can't restore the current segment, for there likely
11800
     isn't one yet...  */
11801
  if (seg && subseg)
11802
    subseg_set (seg, subseg);
11803
}
11804
 
11805
#endif /* TE_VMS */

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