1 /* tc-ia64.c -- Assembler for the HP/Intel IA-64 architecture.
2 Copyright 1998, 1999, 2000, 2001, 2002, 2003, 2004, 2005, 2006
3 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 2, 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
54 #ifdef HAVE_LIMITS_H
55 #include <limits.h>
56 #endif
57
58 #define NELEMS(a) ((int) (sizeof (a)/sizeof ((a)[0])))
59
60 /* Some systems define MIN in, e.g., param.h. */
61 #undef MIN
62 #define MIN(a,b) ((a) < (b) ? (a) : (b))
63
64 #define NUM_SLOTS 4
65 #define PREV_SLOT md.slot[(md.curr_slot + NUM_SLOTS - 1) % NUM_SLOTS]
66 #define CURR_SLOT md.slot[md.curr_slot]
67
68 #define O_pseudo_fixup (O_max + 1)
69
70 enum special_section
71 {
72 /* IA-64 ABI section pseudo-ops. */
73 SPECIAL_SECTION_BSS = 0,
74 SPECIAL_SECTION_SBSS,
75 SPECIAL_SECTION_SDATA,
76 SPECIAL_SECTION_RODATA,
77 SPECIAL_SECTION_COMMENT,
78 SPECIAL_SECTION_UNWIND,
79 SPECIAL_SECTION_UNWIND_INFO,
80 /* HPUX specific section pseudo-ops. */
81 SPECIAL_SECTION_INIT_ARRAY,
82 SPECIAL_SECTION_FINI_ARRAY,
83 };
84
85 enum reloc_func
86 {
87 FUNC_DTP_MODULE,
88 FUNC_DTP_RELATIVE,
89 FUNC_FPTR_RELATIVE,
90 FUNC_GP_RELATIVE,
91 FUNC_LT_RELATIVE,
92 FUNC_LT_RELATIVE_X,
93 FUNC_PC_RELATIVE,
94 FUNC_PLT_RELATIVE,
95 FUNC_SEC_RELATIVE,
96 FUNC_SEG_RELATIVE,
97 FUNC_TP_RELATIVE,
98 FUNC_LTV_RELATIVE,
99 FUNC_LT_FPTR_RELATIVE,
100 FUNC_LT_DTP_MODULE,
101 FUNC_LT_DTP_RELATIVE,
102 FUNC_LT_TP_RELATIVE,
103 FUNC_IPLT_RELOC,
104 };
105
106 enum reg_symbol
107 {
108 REG_GR = 0,
109 REG_FR = (REG_GR + 128),
110 REG_AR = (REG_FR + 128),
111 REG_CR = (REG_AR + 128),
112 REG_P = (REG_CR + 128),
113 REG_BR = (REG_P + 64),
114 REG_IP = (REG_BR + 8),
115 REG_CFM,
116 REG_PR,
117 REG_PR_ROT,
118 REG_PSR,
119 REG_PSR_L,
120 REG_PSR_UM,
121 /* The following are pseudo-registers for use by gas only. */
122 IND_CPUID,
123 IND_DBR,
124 IND_DTR,
125 IND_ITR,
126 IND_IBR,
127 IND_MSR,
128 IND_PKR,
129 IND_PMC,
130 IND_PMD,
131 IND_RR,
132 /* The following pseudo-registers are used for unwind directives only: */
133 REG_PSP,
134 REG_PRIUNAT,
135 REG_NUM
136 };
137
138 enum dynreg_type
139 {
140 DYNREG_GR = 0, /* dynamic general purpose register */
141 DYNREG_FR, /* dynamic floating point register */
142 DYNREG_PR, /* dynamic predicate register */
143 DYNREG_NUM_TYPES
144 };
145
146 enum operand_match_result
147 {
148 OPERAND_MATCH,
149 OPERAND_OUT_OF_RANGE,
150 OPERAND_MISMATCH
151 };
152
153 /* On the ia64, we can't know the address of a text label until the
154 instructions are packed into a bundle. To handle this, we keep
155 track of the list of labels that appear in front of each
156 instruction. */
157 struct label_fix
158 {
159 struct label_fix *next;
160 struct symbol *sym;
161 bfd_boolean dw2_mark_labels;
162 };
163
164 /* This is the endianness of the current section. */
165 extern int target_big_endian;
166
167 /* This is the default endianness. */
168 static int default_big_endian = TARGET_BYTES_BIG_ENDIAN;
169
170 void (*ia64_number_to_chars) PARAMS ((char *, valueT, int));
171
172 static void ia64_float_to_chars_bigendian
173 PARAMS ((char *, LITTLENUM_TYPE *, int));
174 static void ia64_float_to_chars_littleendian
175 PARAMS ((char *, LITTLENUM_TYPE *, int));
176 static void (*ia64_float_to_chars)
177 PARAMS ((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 predicatable. */
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_PFS 64
370 #define AR_LC 65
371 #define AR_EC 66
372
373 static const struct
374 {
375 const char *name;
376 unsigned int regnum;
377 }
378 ar[] =
379 {
380 {"ar.k0", AR_K0}, {"ar.k1", AR_K0 + 1},
381 {"ar.k2", AR_K0 + 2}, {"ar.k3", AR_K0 + 3},
382 {"ar.k4", AR_K0 + 4}, {"ar.k5", AR_K0 + 5},
383 {"ar.k6", AR_K0 + 6}, {"ar.k7", AR_K7},
384 {"ar.rsc", AR_RSC}, {"ar.bsp", AR_BSP},
385 {"ar.bspstore", AR_BSPSTORE}, {"ar.rnat", AR_RNAT},
386 {"ar.fcr", AR_FCR}, {"ar.eflag", AR_EFLAG},
387 {"ar.csd", AR_CSD}, {"ar.ssd", AR_SSD},
388 {"ar.cflg", AR_CFLG}, {"ar.fsr", AR_FSR},
389 {"ar.fir", AR_FIR}, {"ar.fdr", AR_FDR},
390 {"ar.ccv", AR_CCV}, {"ar.unat", AR_UNAT},
391 {"ar.fpsr", AR_FPSR}, {"ar.itc", AR_ITC},
392 {"ar.pfs", AR_PFS}, {"ar.lc", AR_LC},
393 {"ar.ec", AR_EC},
394 };
395
396 /* control registers: */
397
398 #define CR_DCR 0
399 #define CR_ITM 1
400 #define CR_IVA 2
401 #define CR_PTA 8
402 #define CR_GPTA 9
403 #define CR_IPSR 16
404 #define CR_ISR 17
405 #define CR_IIP 19
406 #define CR_IFA 20
407 #define CR_ITIR 21
408 #define CR_IIPA 22
409 #define CR_IFS 23
410 #define CR_IIM 24
411 #define CR_IHA 25
412 #define CR_LID 64
413 #define CR_IVR 65
414 #define CR_TPR 66
415 #define CR_EOI 67
416 #define CR_IRR0 68
417 #define CR_IRR3 71
418 #define CR_ITV 72
419 #define CR_PMV 73
420 #define CR_CMCV 74
421 #define CR_LRR0 80
422 #define CR_LRR1 81
423
424 static const struct
425 {
426 const char *name;
427 unsigned int regnum;
428 }
429 cr[] =
430 {
431 {"cr.dcr", CR_DCR},
432 {"cr.itm", CR_ITM},
433 {"cr.iva", CR_IVA},
434 {"cr.pta", CR_PTA},
435 {"cr.gpta", CR_GPTA},
436 {"cr.ipsr", CR_IPSR},
437 {"cr.isr", CR_ISR},
438 {"cr.iip", CR_IIP},
439 {"cr.ifa", CR_IFA},
440 {"cr.itir", CR_ITIR},
441 {"cr.iipa", CR_IIPA},
442 {"cr.ifs", CR_IFS},
443 {"cr.iim", CR_IIM},
444 {"cr.iha", CR_IHA},
445 {"cr.lid", CR_LID},
446 {"cr.ivr", CR_IVR},
447 {"cr.tpr", CR_TPR},
448 {"cr.eoi", CR_EOI},
449 {"cr.irr0", CR_IRR0},
450 {"cr.irr1", CR_IRR0 + 1},
451 {"cr.irr2", CR_IRR0 + 2},
452 {"cr.irr3", CR_IRR3},
453 {"cr.itv", CR_ITV},
454 {"cr.pmv", CR_PMV},
455 {"cr.cmcv", CR_CMCV},
456 {"cr.lrr0", CR_LRR0},
457 {"cr.lrr1", CR_LRR1}
458 };
459
460 #define PSR_MFL 4
461 #define PSR_IC 13
462 #define PSR_DFL 18
463 #define PSR_CPL 32
464
465 static const struct const_desc
466 {
467 const char *name;
468 valueT value;
469 }
470 const_bits[] =
471 {
472 /* PSR constant masks: */
473
474 /* 0: reserved */
475 {"psr.be", ((valueT) 1) << 1},
476 {"psr.up", ((valueT) 1) << 2},
477 {"psr.ac", ((valueT) 1) << 3},
478 {"psr.mfl", ((valueT) 1) << 4},
479 {"psr.mfh", ((valueT) 1) << 5},
480 /* 6-12: reserved */
481 {"psr.ic", ((valueT) 1) << 13},
482 {"psr.i", ((valueT) 1) << 14},
483 {"psr.pk", ((valueT) 1) << 15},
484 /* 16: reserved */
485 {"psr.dt", ((valueT) 1) << 17},
486 {"psr.dfl", ((valueT) 1) << 18},
487 {"psr.dfh", ((valueT) 1) << 19},
488 {"psr.sp", ((valueT) 1) << 20},
489 {"psr.pp", ((valueT) 1) << 21},
490 {"psr.di", ((valueT) 1) << 22},
491 {"psr.si", ((valueT) 1) << 23},
492 {"psr.db", ((valueT) 1) << 24},
493 {"psr.lp", ((valueT) 1) << 25},
494 {"psr.tb", ((valueT) 1) << 26},
495 {"psr.rt", ((valueT) 1) << 27},
496 /* 28-31: reserved */
497 /* 32-33: cpl (current privilege level) */
498 {"psr.is", ((valueT) 1) << 34},
499 {"psr.mc", ((valueT) 1) << 35},
500 {"psr.it", ((valueT) 1) << 36},
501 {"psr.id", ((valueT) 1) << 37},
502 {"psr.da", ((valueT) 1) << 38},
503 {"psr.dd", ((valueT) 1) << 39},
504 {"psr.ss", ((valueT) 1) << 40},
505 /* 41-42: ri (restart instruction) */
506 {"psr.ed", ((valueT) 1) << 43},
507 {"psr.bn", ((valueT) 1) << 44},
508 };
509
510 /* indirect register-sets/memory: */
511
512 static const struct
513 {
514 const char *name;
515 unsigned int regnum;
516 }
517 indirect_reg[] =
518 {
519 { "CPUID", IND_CPUID },
520 { "cpuid", IND_CPUID },
521 { "dbr", IND_DBR },
522 { "dtr", IND_DTR },
523 { "itr", IND_ITR },
524 { "ibr", IND_IBR },
525 { "msr", IND_MSR },
526 { "pkr", IND_PKR },
527 { "pmc", IND_PMC },
528 { "pmd", IND_PMD },
529 { "rr", IND_RR },
530 };
531
532 /* Pseudo functions used to indicate relocation types (these functions
533 start with an at sign (@). */
534 static struct
535 {
536 const char *name;
537 enum pseudo_type
538 {
539 PSEUDO_FUNC_NONE,
540 PSEUDO_FUNC_RELOC,
541 PSEUDO_FUNC_CONST,
542 PSEUDO_FUNC_REG,
543 PSEUDO_FUNC_FLOAT
544 }
545 type;
546 union
547 {
548 unsigned long ival;
549 symbolS *sym;
550 }
551 u;
552 }
553 pseudo_func[] =
554 {
555 /* reloc pseudo functions (these must come first!): */
556 { "dtpmod", PSEUDO_FUNC_RELOC, { 0 } },
557 { "dtprel", PSEUDO_FUNC_RELOC, { 0 } },
558 { "fptr", PSEUDO_FUNC_RELOC, { 0 } },
559 { "gprel", PSEUDO_FUNC_RELOC, { 0 } },
560 { "ltoff", PSEUDO_FUNC_RELOC, { 0 } },
561 { "ltoffx", PSEUDO_FUNC_RELOC, { 0 } },
562 { "pcrel", PSEUDO_FUNC_RELOC, { 0 } },
563 { "pltoff", PSEUDO_FUNC_RELOC, { 0 } },
564 { "secrel", PSEUDO_FUNC_RELOC, { 0 } },
565 { "segrel", PSEUDO_FUNC_RELOC, { 0 } },
566 { "tprel", PSEUDO_FUNC_RELOC, { 0 } },
567 { "ltv", PSEUDO_FUNC_RELOC, { 0 } },
568 { NULL, 0, { 0 } }, /* placeholder for FUNC_LT_FPTR_RELATIVE */
569 { NULL, 0, { 0 } }, /* placeholder for FUNC_LT_DTP_MODULE */
570 { NULL, 0, { 0 } }, /* placeholder for FUNC_LT_DTP_RELATIVE */
571 { NULL, 0, { 0 } }, /* placeholder for FUNC_LT_TP_RELATIVE */
572 { "iplt", PSEUDO_FUNC_RELOC, { 0 } },
573
574 /* mbtype4 constants: */
575 { "alt", PSEUDO_FUNC_CONST, { 0xa } },
576 { "brcst", PSEUDO_FUNC_CONST, { 0x0 } },
577 { "mix", PSEUDO_FUNC_CONST, { 0x8 } },
578 { "rev", PSEUDO_FUNC_CONST, { 0xb } },
579 { "shuf", PSEUDO_FUNC_CONST, { 0x9 } },
580
581 /* fclass constants: */
582 { "nat", PSEUDO_FUNC_CONST, { 0x100 } },
583 { "qnan", PSEUDO_FUNC_CONST, { 0x080 } },
584 { "snan", PSEUDO_FUNC_CONST, { 0x040 } },
585 { "pos", PSEUDO_FUNC_CONST, { 0x001 } },
586 { "neg", PSEUDO_FUNC_CONST, { 0x002 } },
587 { "zero", PSEUDO_FUNC_CONST, { 0x004 } },
588 { "unorm", PSEUDO_FUNC_CONST, { 0x008 } },
589 { "norm", PSEUDO_FUNC_CONST, { 0x010 } },
590 { "inf", PSEUDO_FUNC_CONST, { 0x020 } },
591
592 { "natval", PSEUDO_FUNC_CONST, { 0x100 } }, /* old usage */
593
594 /* hint constants: */
595 { "pause", PSEUDO_FUNC_CONST, { 0x0 } },
596
597 /* unwind-related constants: */
598 { "svr4", PSEUDO_FUNC_CONST, { ELFOSABI_NONE } },
599 { "hpux", PSEUDO_FUNC_CONST, { ELFOSABI_HPUX } },
600 { "nt", PSEUDO_FUNC_CONST, { 2 } }, /* conflicts w/ELFOSABI_NETBSD */
601 { "linux", PSEUDO_FUNC_CONST, { ELFOSABI_LINUX } },
602 { "freebsd", PSEUDO_FUNC_CONST, { ELFOSABI_FREEBSD } },
603 { "openvms", PSEUDO_FUNC_CONST, { ELFOSABI_OPENVMS } },
604 { "nsk", PSEUDO_FUNC_CONST, { ELFOSABI_NSK } },
605
606 /* unwind-related registers: */
607 { "priunat",PSEUDO_FUNC_REG, { REG_PRIUNAT } }
608 };
609
610 /* 41-bit nop opcodes (one per unit): */
611 static const bfd_vma nop[IA64_NUM_UNITS] =
612 {
613 0x0000000000LL, /* NIL => break 0 */
614 0x0008000000LL, /* I-unit nop */
615 0x0008000000LL, /* M-unit nop */
616 0x4000000000LL, /* B-unit nop */
617 0x0008000000LL, /* F-unit nop */
618 0x0000000000LL, /* L-"unit" nop immediate */
619 0x0008000000LL, /* X-unit nop */
620 };
621
622 /* Can't be `const' as it's passed to input routines (which have the
623 habit of setting temporary sentinels. */
624 static char special_section_name[][20] =
625 {
626 {".bss"}, {".sbss"}, {".sdata"}, {".rodata"}, {".comment"},
627 {".IA_64.unwind"}, {".IA_64.unwind_info"},
628 {".init_array"}, {".fini_array"}
629 };
630
631 /* The best template for a particular sequence of up to three
632 instructions: */
633 #define N IA64_NUM_TYPES
634 static unsigned char best_template[N][N][N];
635 #undef N
636
637 /* Resource dependencies currently in effect */
638 static struct rsrc {
639 int depind; /* dependency index */
640 const struct ia64_dependency *dependency; /* actual dependency */
641 unsigned specific:1, /* is this a specific bit/regno? */
642 link_to_qp_branch:1; /* will a branch on the same QP clear it?*/
643 int index; /* specific regno/bit within dependency */
644 int note; /* optional qualifying note (0 if none) */
645 #define STATE_NONE 0
646 #define STATE_STOP 1
647 #define STATE_SRLZ 2
648 int insn_srlz; /* current insn serialization state */
649 int data_srlz; /* current data serialization state */
650 int qp_regno; /* qualifying predicate for this usage */
651 char *file; /* what file marked this dependency */
652 unsigned int line; /* what line marked this dependency */
653 struct mem_offset mem_offset; /* optional memory offset hint */
654 enum { CMP_NONE, CMP_OR, CMP_AND } cmp_type; /* OR or AND compare? */
655 int path; /* corresponding code entry index */
656 } *regdeps = NULL;
657 static int regdepslen = 0;
658 static int regdepstotlen = 0;
659 static const char *dv_mode[] = { "RAW", "WAW", "WAR" };
660 static const char *dv_sem[] = { "none", "implied", "impliedf",
661 "data", "instr", "specific", "stop", "other" };
662 static const char *dv_cmp_type[] = { "none", "OR", "AND" };
663
664 /* Current state of PR mutexation */
665 static struct qpmutex {
666 valueT prmask;
667 int path;
668 } *qp_mutexes = NULL; /* QP mutex bitmasks */
669 static int qp_mutexeslen = 0;
670 static int qp_mutexestotlen = 0;
671 static valueT qp_safe_across_calls = 0;
672
673 /* Current state of PR implications */
674 static struct qp_imply {
675 unsigned p1:6;
676 unsigned p2:6;
677 unsigned p2_branched:1;
678 int path;
679 } *qp_implies = NULL;
680 static int qp_implieslen = 0;
681 static int qp_impliestotlen = 0;
682
683 /* Keep track of static GR values so that indirect register usage can
684 sometimes be tracked. */
685 static struct gr {
686 unsigned known:1;
687 int path;
688 valueT value;
689 } gr_values[128] = {
690 {
691 1,
692 #ifdef INT_MAX
693 INT_MAX,
694 #else
695 (((1 << (8 * sizeof(gr_values->path) - 2)) - 1) << 1) + 1,
696 #endif
697 0
698 }
699 };
700
701 /* Remember the alignment frag. */
702 static fragS *align_frag;
703
704 /* These are the routines required to output the various types of
705 unwind records. */
706
707 /* A slot_number is a frag address plus the slot index (0-2). We use the
708 frag address here so that if there is a section switch in the middle of
709 a function, then instructions emitted to a different section are not
710 counted. Since there may be more than one frag for a function, this
711 means we also need to keep track of which frag this address belongs to
712 so we can compute inter-frag distances. This also nicely solves the
713 problem with nops emitted for align directives, which can't easily be
714 counted, but can easily be derived from frag sizes. */
715
716 typedef struct unw_rec_list {
717 unwind_record r;
718 unsigned long slot_number;
719 fragS *slot_frag;
720 struct unw_rec_list *next;
721 } unw_rec_list;
722
723 #define SLOT_NUM_NOT_SET (unsigned)-1
724
725 /* Linked list of saved prologue counts. A very poor
726 implementation of a map from label numbers to prologue counts. */
727 typedef struct label_prologue_count
728 {
729 struct label_prologue_count *next;
730 unsigned long label_number;
731 unsigned int prologue_count;
732 } label_prologue_count;
733
734 typedef struct proc_pending
735 {
736 symbolS *sym;
737 struct proc_pending *next;
738 } proc_pending;
739
740 static struct
741 {
742 /* Maintain a list of unwind entries for the current function. */
743 unw_rec_list *list;
744 unw_rec_list *tail;
745
746 /* Any unwind entires that should be attached to the current slot
747 that an insn is being constructed for. */
748 unw_rec_list *current_entry;
749
750 /* These are used to create the unwind table entry for this function. */
751 proc_pending proc_pending;
752 symbolS *info; /* pointer to unwind info */
753 symbolS *personality_routine;
754 segT saved_text_seg;
755 subsegT saved_text_subseg;
756 unsigned int force_unwind_entry : 1; /* force generation of unwind entry? */
757
758 /* TRUE if processing unwind directives in a prologue region. */
759 unsigned int prologue : 1;
760 unsigned int prologue_mask : 4;
761 unsigned int prologue_gr : 7;
762 unsigned int body : 1;
763 unsigned int insn : 1;
764 unsigned int prologue_count; /* number of .prologues seen so far */
765 /* Prologue counts at previous .label_state directives. */
766 struct label_prologue_count * saved_prologue_counts;
767
768 /* List of split up .save-s. */
769 unw_p_record *pending_saves;
770 } unwind;
771
772 /* The input value is a negated offset from psp, and specifies an address
773 psp - offset. The encoded value is psp + 16 - (4 * offset). Thus we
774 must add 16 and divide by 4 to get the encoded value. */
775
776 #define ENCODED_PSP_OFFSET(OFFSET) (((OFFSET) + 16) / 4)
777
778 typedef void (*vbyte_func) PARAMS ((int, char *, char *));
779
780 /* Forward declarations: */
781 static void set_section PARAMS ((char *name));
782 static unsigned int set_regstack PARAMS ((unsigned int, unsigned int,
783 unsigned int, unsigned int));
784 static void dot_align (int);
785 static void dot_radix PARAMS ((int));
786 static void dot_special_section PARAMS ((int));
787 static void dot_proc PARAMS ((int));
788 static void dot_fframe PARAMS ((int));
789 static void dot_vframe PARAMS ((int));
790 static void dot_vframesp PARAMS ((int));
791 static void dot_save PARAMS ((int));
792 static void dot_restore PARAMS ((int));
793 static void dot_restorereg PARAMS ((int));
794 static void dot_handlerdata PARAMS ((int));
795 static void dot_unwentry PARAMS ((int));
796 static void dot_altrp PARAMS ((int));
797 static void dot_savemem PARAMS ((int));
798 static void dot_saveg PARAMS ((int));
799 static void dot_savef PARAMS ((int));
800 static void dot_saveb PARAMS ((int));
801 static void dot_savegf PARAMS ((int));
802 static void dot_spill PARAMS ((int));
803 static void dot_spillreg PARAMS ((int));
804 static void dot_spillmem PARAMS ((int));
805 static void dot_label_state PARAMS ((int));
806 static void dot_copy_state PARAMS ((int));
807 static void dot_unwabi PARAMS ((int));
808 static void dot_personality PARAMS ((int));
809 static void dot_body PARAMS ((int));
810 static void dot_prologue PARAMS ((int));
811 static void dot_endp PARAMS ((int));
812 static void dot_template PARAMS ((int));
813 static void dot_regstk PARAMS ((int));
814 static void dot_rot PARAMS ((int));
815 static void dot_byteorder PARAMS ((int));
816 static void dot_psr PARAMS ((int));
817 static void dot_alias PARAMS ((int));
818 static void dot_ln PARAMS ((int));
819 static void cross_section PARAMS ((int ref, void (*cons) PARAMS((int)), int ua));
820 static void dot_xdata PARAMS ((int));
821 static void stmt_float_cons PARAMS ((int));
822 static void stmt_cons_ua PARAMS ((int));
823 static void dot_xfloat_cons PARAMS ((int));
824 static void dot_xstringer PARAMS ((int));
825 static void dot_xdata_ua PARAMS ((int));
826 static void dot_xfloat_cons_ua PARAMS ((int));
827 static void print_prmask PARAMS ((valueT mask));
828 static void dot_pred_rel PARAMS ((int));
829 static void dot_reg_val PARAMS ((int));
830 static void dot_serialize PARAMS ((int));
831 static void dot_dv_mode PARAMS ((int));
832 static void dot_entry PARAMS ((int));
833 static void dot_mem_offset PARAMS ((int));
834 static void add_unwind_entry PARAMS((unw_rec_list *, int));
835 static symbolS *declare_register PARAMS ((const char *name, unsigned int regnum));
836 static void declare_register_set PARAMS ((const char *, unsigned int, unsigned int));
837 static unsigned int operand_width PARAMS ((enum ia64_opnd));
838 static enum operand_match_result operand_match PARAMS ((const struct ia64_opcode *idesc,
839 int index,
840 expressionS *e));
841 static int parse_operand PARAMS ((expressionS *, int));
842 static struct ia64_opcode * parse_operands PARAMS ((struct ia64_opcode *));
843 static void build_insn PARAMS ((struct slot *, bfd_vma *));
844 static void emit_one_bundle PARAMS ((void));
845 static void fix_insn PARAMS ((fixS *, const struct ia64_operand *, valueT));
846 static bfd_reloc_code_real_type ia64_gen_real_reloc_type PARAMS ((struct symbol *sym,
847 bfd_reloc_code_real_type r_type));
848 static void insn_group_break PARAMS ((int, int, int));
849 static void mark_resource PARAMS ((struct ia64_opcode *, const struct ia64_dependency *,
850 struct rsrc *, int depind, int path));
851 static void add_qp_mutex PARAMS((valueT mask));
852 static void add_qp_imply PARAMS((int p1, int p2));
853 static void clear_qp_branch_flag PARAMS((valueT mask));
854 static void clear_qp_mutex PARAMS((valueT mask));
855 static void clear_qp_implies PARAMS((valueT p1_mask, valueT p2_mask));
856 static int has_suffix_p PARAMS((const char *, const char *));
857 static void clear_register_values PARAMS ((void));
858 static void print_dependency PARAMS ((const char *action, int depind));
859 static void instruction_serialization PARAMS ((void));
860 static void data_serialization PARAMS ((void));
861 static void remove_marked_resource PARAMS ((struct rsrc *));
862 static int is_conditional_branch PARAMS ((struct ia64_opcode *));
863 static int is_taken_branch PARAMS ((struct ia64_opcode *));
864 static int is_interruption_or_rfi PARAMS ((struct ia64_opcode *));
865 static int depends_on PARAMS ((int, struct ia64_opcode *));
866 static int specify_resource PARAMS ((const struct ia64_dependency *,
867 struct ia64_opcode *, int, struct rsrc [], int, int));
868 static int check_dv PARAMS((struct ia64_opcode *idesc));
869 static void check_dependencies PARAMS((struct ia64_opcode *));
870 static void mark_resources PARAMS((struct ia64_opcode *));
871 static void update_dependencies PARAMS((struct ia64_opcode *));
872 static void note_register_values PARAMS((struct ia64_opcode *));
873 static int qp_mutex PARAMS ((int, int, int));
874 static int resources_match PARAMS ((struct rsrc *, struct ia64_opcode *, int, int, int));
875 static void output_vbyte_mem PARAMS ((int, char *, char *));
876 static void count_output PARAMS ((int, char *, char *));
877 static void output_R1_format PARAMS ((vbyte_func, unw_record_type, int));
878 static void output_R2_format PARAMS ((vbyte_func, int, int, unsigned long));
879 static void output_R3_format PARAMS ((vbyte_func, unw_record_type, unsigned long));
880 static void output_P1_format PARAMS ((vbyte_func, int));
881 static void output_P2_format PARAMS ((vbyte_func, int, int));
882 static void output_P3_format PARAMS ((vbyte_func, unw_record_type, int));
883 static void output_P4_format PARAMS ((vbyte_func, unsigned char *, unsigned long));
884 static void output_P5_format PARAMS ((vbyte_func, int, unsigned long));
885 static void output_P6_format PARAMS ((vbyte_func, unw_record_type, int));
886 static void output_P7_format PARAMS ((vbyte_func, unw_record_type, unsigned long, unsigned long));
887 static void output_P8_format PARAMS ((vbyte_func, unw_record_type, unsigned long));
888 static void output_P9_format PARAMS ((vbyte_func, int, int));
889 static void output_P10_format PARAMS ((vbyte_func, int, int));
890 static void output_B1_format PARAMS ((vbyte_func, unw_record_type, unsigned long));
891 static void output_B2_format PARAMS ((vbyte_func, unsigned long, unsigned long));
892 static void output_B3_format PARAMS ((vbyte_func, unsigned long, unsigned long));
893 static void output_B4_format PARAMS ((vbyte_func, unw_record_type, unsigned long));
894 static char format_ab_reg PARAMS ((int, int));
895 static void output_X1_format PARAMS ((vbyte_func, unw_record_type, int, int, unsigned long,
896 unsigned long));
897 static void output_X2_format PARAMS ((vbyte_func, int, int, int, int, int, unsigned long));
898 static void output_X3_format PARAMS ((vbyte_func, unw_record_type, int, int, int, unsigned long,
899 unsigned long));
900 static void output_X4_format PARAMS ((vbyte_func, int, int, int, int, int, int, unsigned long));
901 static unw_rec_list *output_endp PARAMS ((void));
902 static unw_rec_list *output_prologue PARAMS ((void));
903 static unw_rec_list *output_prologue_gr PARAMS ((unsigned int, unsigned int));
904 static unw_rec_list *output_body PARAMS ((void));
905 static unw_rec_list *output_mem_stack_f PARAMS ((unsigned int));
906 static unw_rec_list *output_mem_stack_v PARAMS ((void));
907 static unw_rec_list *output_psp_gr PARAMS ((unsigned int));
908 static unw_rec_list *output_psp_sprel PARAMS ((unsigned int));
909 static unw_rec_list *output_rp_when PARAMS ((void));
910 static unw_rec_list *output_rp_gr PARAMS ((unsigned int));
911 static unw_rec_list *output_rp_br PARAMS ((unsigned int));
912 static unw_rec_list *output_rp_psprel PARAMS ((unsigned int));
913 static unw_rec_list *output_rp_sprel PARAMS ((unsigned int));
914 static unw_rec_list *output_pfs_when PARAMS ((void));
915 static unw_rec_list *output_pfs_gr PARAMS ((unsigned int));
916 static unw_rec_list *output_pfs_psprel PARAMS ((unsigned int));
917 static unw_rec_list *output_pfs_sprel PARAMS ((unsigned int));
918 static unw_rec_list *output_preds_when PARAMS ((void));
919 static unw_rec_list *output_preds_gr PARAMS ((unsigned int));
920 static unw_rec_list *output_preds_psprel PARAMS ((unsigned int));
921 static unw_rec_list *output_preds_sprel PARAMS ((unsigned int));
922 static unw_rec_list *output_fr_mem PARAMS ((unsigned int));
923 static unw_rec_list *output_frgr_mem PARAMS ((unsigned int, unsigned int));
924 static unw_rec_list *output_gr_gr PARAMS ((unsigned int, unsigned int));
925 static unw_rec_list *output_gr_mem PARAMS ((unsigned int));
926 static unw_rec_list *output_br_mem PARAMS ((unsigned int));
927 static unw_rec_list *output_br_gr PARAMS ((unsigned int, unsigned int));
928 static unw_rec_list *output_spill_base PARAMS ((unsigned int));
929 static unw_rec_list *output_unat_when PARAMS ((void));
930 static unw_rec_list *output_unat_gr PARAMS ((unsigned int));
931 static unw_rec_list *output_unat_psprel PARAMS ((unsigned int));
932 static unw_rec_list *output_unat_sprel PARAMS ((unsigned int));
933 static unw_rec_list *output_lc_when PARAMS ((void));
934 static unw_rec_list *output_lc_gr PARAMS ((unsigned int));
935 static unw_rec_list *output_lc_psprel PARAMS ((unsigned int));
936 static unw_rec_list *output_lc_sprel PARAMS ((unsigned int));
937 static unw_rec_list *output_fpsr_when PARAMS ((void));
938 static unw_rec_list *output_fpsr_gr PARAMS ((unsigned int));
939 static unw_rec_list *output_fpsr_psprel PARAMS ((unsigned int));
940 static unw_rec_list *output_fpsr_sprel PARAMS ((unsigned int));
941 static unw_rec_list *output_priunat_when_gr PARAMS ((void));
942 static unw_rec_list *output_priunat_when_mem PARAMS ((void));
943 static unw_rec_list *output_priunat_gr PARAMS ((unsigned int));
944 static unw_rec_list *output_priunat_psprel PARAMS ((unsigned int));
945 static unw_rec_list *output_priunat_sprel PARAMS ((unsigned int));
946 static unw_rec_list *output_bsp_when PARAMS ((void));
947 static unw_rec_list *output_bsp_gr PARAMS ((unsigned int));
948 static unw_rec_list *output_bsp_psprel PARAMS ((unsigned int));
949 static unw_rec_list *output_bsp_sprel PARAMS ((unsigned int));
950 static unw_rec_list *output_bspstore_when PARAMS ((void));
951 static unw_rec_list *output_bspstore_gr PARAMS ((unsigned int));
952 static unw_rec_list *output_bspstore_psprel PARAMS ((unsigned int));
953 static unw_rec_list *output_bspstore_sprel PARAMS ((unsigned int));
954 static unw_rec_list *output_rnat_when PARAMS ((void));
955 static unw_rec_list *output_rnat_gr PARAMS ((unsigned int));
956 static unw_rec_list *output_rnat_psprel PARAMS ((unsigned int));
957 static unw_rec_list *output_rnat_sprel PARAMS ((unsigned int));
958 static unw_rec_list *output_unwabi PARAMS ((unsigned long, unsigned long));
959 static unw_rec_list *output_epilogue PARAMS ((unsigned long));
960 static unw_rec_list *output_label_state PARAMS ((unsigned long));
961 static unw_rec_list *output_copy_state PARAMS ((unsigned long));
962 static unw_rec_list *output_spill_psprel PARAMS ((unsigned int, unsigned int, unsigned int,
963 unsigned int));
964 static unw_rec_list *output_spill_sprel PARAMS ((unsigned int, unsigned int, unsigned int,
965 unsigned int));
966 static unw_rec_list *output_spill_reg PARAMS ((unsigned int, unsigned int, unsigned int,
967 unsigned int, unsigned int));
968 static void process_one_record PARAMS ((unw_rec_list *, vbyte_func));
969 static void process_unw_records PARAMS ((unw_rec_list *, vbyte_func));
970 static int calc_record_size PARAMS ((unw_rec_list *));
971 static void set_imask PARAMS ((unw_rec_list *, unsigned long, unsigned long, unsigned int));
972 static unsigned long slot_index PARAMS ((unsigned long, fragS *,
973 unsigned long, fragS *,
974 int));
975 static unw_rec_list *optimize_unw_records PARAMS ((unw_rec_list *));
976 static void fixup_unw_records PARAMS ((unw_rec_list *, int));
977 static int parse_predicate_and_operand PARAMS ((expressionS *, unsigned *, const char *));
978 static void convert_expr_to_ab_reg PARAMS ((const expressionS *, unsigned int *, unsigned int *, const char *, int));
979 static void convert_expr_to_xy_reg PARAMS ((const expressionS *, unsigned int *, unsigned int *, const char *, int));
980 static unsigned int get_saved_prologue_count PARAMS ((unsigned long));
981 static void save_prologue_count PARAMS ((unsigned long, unsigned int));
982 static void free_saved_prologue_counts PARAMS ((void));
983
984 /* Determine if application register REGNUM resides only in the integer
985 unit (as opposed to the memory unit). */
986 static int
ar_is_only_in_integer_unit(int reg)987 ar_is_only_in_integer_unit (int reg)
988 {
989 reg -= REG_AR;
990 return reg >= 64 && reg <= 111;
991 }
992
993 /* Determine if application register REGNUM resides only in the memory
994 unit (as opposed to the integer unit). */
995 static int
ar_is_only_in_memory_unit(int reg)996 ar_is_only_in_memory_unit (int reg)
997 {
998 reg -= REG_AR;
999 return reg >= 0 && reg <= 47;
1000 }
1001
1002 /* Switch to section NAME and create section if necessary. It's
1003 rather ugly that we have to manipulate input_line_pointer but I
1004 don't see any other way to accomplish the same thing without
1005 changing obj-elf.c (which may be the Right Thing, in the end). */
1006 static void
set_section(name)1007 set_section (name)
1008 char *name;
1009 {
1010 char *saved_input_line_pointer;
1011
1012 saved_input_line_pointer = input_line_pointer;
1013 input_line_pointer = name;
1014 obj_elf_section (0);
1015 input_line_pointer = saved_input_line_pointer;
1016 }
1017
1018 /* Map 's' to SHF_IA_64_SHORT. */
1019
1020 int
ia64_elf_section_letter(letter,ptr_msg)1021 ia64_elf_section_letter (letter, ptr_msg)
1022 int letter;
1023 char **ptr_msg;
1024 {
1025 if (letter == 's')
1026 return SHF_IA_64_SHORT;
1027 else if (letter == 'o')
1028 return SHF_LINK_ORDER;
1029
1030 *ptr_msg = _("Bad .section directive: want a,o,s,w,x,M,S,G,T in string");
1031 return -1;
1032 }
1033
1034 /* Map SHF_IA_64_SHORT to SEC_SMALL_DATA. */
1035
1036 flagword
ia64_elf_section_flags(flags,attr,type)1037 ia64_elf_section_flags (flags, attr, type)
1038 flagword flags;
1039 int attr, type ATTRIBUTE_UNUSED;
1040 {
1041 if (attr & SHF_IA_64_SHORT)
1042 flags |= SEC_SMALL_DATA;
1043 return flags;
1044 }
1045
1046 int
ia64_elf_section_type(str,len)1047 ia64_elf_section_type (str, len)
1048 const char *str;
1049 size_t len;
1050 {
1051 #define STREQ(s) ((len == sizeof (s) - 1) && (strncmp (str, s, sizeof (s) - 1) == 0))
1052
1053 if (STREQ (ELF_STRING_ia64_unwind_info))
1054 return SHT_PROGBITS;
1055
1056 if (STREQ (ELF_STRING_ia64_unwind_info_once))
1057 return SHT_PROGBITS;
1058
1059 if (STREQ (ELF_STRING_ia64_unwind))
1060 return SHT_IA_64_UNWIND;
1061
1062 if (STREQ (ELF_STRING_ia64_unwind_once))
1063 return SHT_IA_64_UNWIND;
1064
1065 if (STREQ ("unwind"))
1066 return SHT_IA_64_UNWIND;
1067
1068 return -1;
1069 #undef STREQ
1070 }
1071
1072 static unsigned int
set_regstack(ins,locs,outs,rots)1073 set_regstack (ins, locs, outs, rots)
1074 unsigned int ins, locs, outs, rots;
1075 {
1076 /* Size of frame. */
1077 unsigned int sof;
1078
1079 sof = ins + locs + outs;
1080 if (sof > 96)
1081 {
1082 as_bad ("Size of frame exceeds maximum of 96 registers");
1083 return 0;
1084 }
1085 if (rots > sof)
1086 {
1087 as_warn ("Size of rotating registers exceeds frame size");
1088 return 0;
1089 }
1090 md.in.base = REG_GR + 32;
1091 md.loc.base = md.in.base + ins;
1092 md.out.base = md.loc.base + locs;
1093
1094 md.in.num_regs = ins;
1095 md.loc.num_regs = locs;
1096 md.out.num_regs = outs;
1097 md.rot.num_regs = rots;
1098 return sof;
1099 }
1100
1101 void
ia64_flush_insns()1102 ia64_flush_insns ()
1103 {
1104 struct label_fix *lfix;
1105 segT saved_seg;
1106 subsegT saved_subseg;
1107 unw_rec_list *ptr;
1108 bfd_boolean mark;
1109
1110 if (!md.last_text_seg)
1111 return;
1112
1113 saved_seg = now_seg;
1114 saved_subseg = now_subseg;
1115
1116 subseg_set (md.last_text_seg, 0);
1117
1118 while (md.num_slots_in_use > 0)
1119 emit_one_bundle (); /* force out queued instructions */
1120
1121 /* In case there are labels following the last instruction, resolve
1122 those now. */
1123 mark = FALSE;
1124 for (lfix = CURR_SLOT.label_fixups; lfix; lfix = lfix->next)
1125 {
1126 symbol_set_value_now (lfix->sym);
1127 mark |= lfix->dw2_mark_labels;
1128 }
1129 if (mark)
1130 {
1131 dwarf2_where (&CURR_SLOT.debug_line);
1132 CURR_SLOT.debug_line.flags |= DWARF2_FLAG_BASIC_BLOCK;
1133 dwarf2_gen_line_info (frag_now_fix (), &CURR_SLOT.debug_line);
1134 }
1135 CURR_SLOT.label_fixups = 0;
1136
1137 for (lfix = CURR_SLOT.tag_fixups; lfix; lfix = lfix->next)
1138 symbol_set_value_now (lfix->sym);
1139 CURR_SLOT.tag_fixups = 0;
1140
1141 /* In case there are unwind directives following the last instruction,
1142 resolve those now. We only handle prologue, body, and endp directives
1143 here. Give an error for others. */
1144 for (ptr = unwind.current_entry; ptr; ptr = ptr->next)
1145 {
1146 switch (ptr->r.type)
1147 {
1148 case prologue:
1149 case prologue_gr:
1150 case body:
1151 case endp:
1152 ptr->slot_number = (unsigned long) frag_more (0);
1153 ptr->slot_frag = frag_now;
1154 break;
1155
1156 /* Allow any record which doesn't have a "t" field (i.e.,
1157 doesn't relate to a particular instruction). */
1158 case unwabi:
1159 case br_gr:
1160 case copy_state:
1161 case fr_mem:
1162 case frgr_mem:
1163 case gr_gr:
1164 case gr_mem:
1165 case label_state:
1166 case rp_br:
1167 case spill_base:
1168 case spill_mask:
1169 /* nothing */
1170 break;
1171
1172 default:
1173 as_bad (_("Unwind directive not followed by an instruction."));
1174 break;
1175 }
1176 }
1177 unwind.current_entry = NULL;
1178
1179 subseg_set (saved_seg, saved_subseg);
1180
1181 if (md.qp.X_op == O_register)
1182 as_bad ("qualifying predicate not followed by instruction");
1183 }
1184
1185 static void
ia64_do_align(int nbytes)1186 ia64_do_align (int nbytes)
1187 {
1188 char *saved_input_line_pointer = input_line_pointer;
1189
1190 input_line_pointer = "";
1191 s_align_bytes (nbytes);
1192 input_line_pointer = saved_input_line_pointer;
1193 }
1194
1195 void
ia64_cons_align(nbytes)1196 ia64_cons_align (nbytes)
1197 int nbytes;
1198 {
1199 if (md.auto_align)
1200 {
1201 char *saved_input_line_pointer = input_line_pointer;
1202 input_line_pointer = "";
1203 s_align_bytes (nbytes);
1204 input_line_pointer = saved_input_line_pointer;
1205 }
1206 }
1207
1208 /* Output COUNT bytes to a memory location. */
1209 static char *vbyte_mem_ptr = NULL;
1210
1211 void
output_vbyte_mem(count,ptr,comment)1212 output_vbyte_mem (count, ptr, comment)
1213 int count;
1214 char *ptr;
1215 char *comment ATTRIBUTE_UNUSED;
1216 {
1217 int x;
1218 if (vbyte_mem_ptr == NULL)
1219 abort ();
1220
1221 if (count == 0)
1222 return;
1223 for (x = 0; x < count; x++)
1224 *(vbyte_mem_ptr++) = ptr[x];
1225 }
1226
1227 /* Count the number of bytes required for records. */
1228 static int vbyte_count = 0;
1229 void
count_output(count,ptr,comment)1230 count_output (count, ptr, comment)
1231 int count;
1232 char *ptr ATTRIBUTE_UNUSED;
1233 char *comment ATTRIBUTE_UNUSED;
1234 {
1235 vbyte_count += count;
1236 }
1237
1238 static void
output_R1_format(f,rtype,rlen)1239 output_R1_format (f, rtype, rlen)
1240 vbyte_func f;
1241 unw_record_type rtype;
1242 int rlen;
1243 {
1244 int r = 0;
1245 char byte;
1246 if (rlen > 0x1f)
1247 {
1248 output_R3_format (f, rtype, rlen);
1249 return;
1250 }
1251
1252 if (rtype == body)
1253 r = 1;
1254 else if (rtype != prologue)
1255 as_bad ("record type is not valid");
1256
1257 byte = UNW_R1 | (r << 5) | (rlen & 0x1f);
1258 (*f) (1, &byte, NULL);
1259 }
1260
1261 static void
output_R2_format(f,mask,grsave,rlen)1262 output_R2_format (f, mask, grsave, rlen)
1263 vbyte_func f;
1264 int mask, grsave;
1265 unsigned long rlen;
1266 {
1267 char bytes[20];
1268 int count = 2;
1269 mask = (mask & 0x0f);
1270 grsave = (grsave & 0x7f);
1271
1272 bytes[0] = (UNW_R2 | (mask >> 1));
1273 bytes[1] = (((mask & 0x01) << 7) | grsave);
1274 count += output_leb128 (bytes + 2, rlen, 0);
1275 (*f) (count, bytes, NULL);
1276 }
1277
1278 static void
output_R3_format(f,rtype,rlen)1279 output_R3_format (f, rtype, rlen)
1280 vbyte_func f;
1281 unw_record_type rtype;
1282 unsigned long rlen;
1283 {
1284 int r = 0, count;
1285 char bytes[20];
1286 if (rlen <= 0x1f)
1287 {
1288 output_R1_format (f, rtype, rlen);
1289 return;
1290 }
1291
1292 if (rtype == body)
1293 r = 1;
1294 else if (rtype != prologue)
1295 as_bad ("record type is not valid");
1296 bytes[0] = (UNW_R3 | r);
1297 count = output_leb128 (bytes + 1, rlen, 0);
1298 (*f) (count + 1, bytes, NULL);
1299 }
1300
1301 static void
output_P1_format(f,brmask)1302 output_P1_format (f, brmask)
1303 vbyte_func f;
1304 int brmask;
1305 {
1306 char byte;
1307 byte = UNW_P1 | (brmask & 0x1f);
1308 (*f) (1, &byte, NULL);
1309 }
1310
1311 static void
output_P2_format(f,brmask,gr)1312 output_P2_format (f, brmask, gr)
1313 vbyte_func f;
1314 int brmask;
1315 int gr;
1316 {
1317 char bytes[2];
1318 brmask = (brmask & 0x1f);
1319 bytes[0] = UNW_P2 | (brmask >> 1);
1320 bytes[1] = (((brmask & 1) << 7) | gr);
1321 (*f) (2, bytes, NULL);
1322 }
1323
1324 static void
output_P3_format(f,rtype,reg)1325 output_P3_format (f, rtype, reg)
1326 vbyte_func f;
1327 unw_record_type rtype;
1328 int reg;
1329 {
1330 char bytes[2];
1331 int r = 0;
1332 reg = (reg & 0x7f);
1333 switch (rtype)
1334 {
1335 case psp_gr:
1336 r = 0;
1337 break;
1338 case rp_gr:
1339 r = 1;
1340 break;
1341 case pfs_gr:
1342 r = 2;
1343 break;
1344 case preds_gr:
1345 r = 3;
1346 break;
1347 case unat_gr:
1348 r = 4;
1349 break;
1350 case lc_gr:
1351 r = 5;
1352 break;
1353 case rp_br:
1354 r = 6;
1355 break;
1356 case rnat_gr:
1357 r = 7;
1358 break;
1359 case bsp_gr:
1360 r = 8;
1361 break;
1362 case bspstore_gr:
1363 r = 9;
1364 break;
1365 case fpsr_gr:
1366 r = 10;
1367 break;
1368 case priunat_gr:
1369 r = 11;
1370 break;
1371 default:
1372 as_bad ("Invalid record type for P3 format.");
1373 }
1374 bytes[0] = (UNW_P3 | (r >> 1));
1375 bytes[1] = (((r & 1) << 7) | reg);
1376 (*f) (2, bytes, NULL);
1377 }
1378
1379 static void
output_P4_format(f,imask,imask_size)1380 output_P4_format (f, imask, imask_size)
1381 vbyte_func f;
1382 unsigned char *imask;
1383 unsigned long imask_size;
1384 {
1385 imask[0] = UNW_P4;
1386 (*f) (imask_size, (char *) imask, NULL);
1387 }
1388
1389 static void
output_P5_format(f,grmask,frmask)1390 output_P5_format (f, grmask, frmask)
1391 vbyte_func f;
1392 int grmask;
1393 unsigned long frmask;
1394 {
1395 char bytes[4];
1396 grmask = (grmask & 0x0f);
1397
1398 bytes[0] = UNW_P5;
1399 bytes[1] = ((grmask << 4) | ((frmask & 0x000f0000) >> 16));
1400 bytes[2] = ((frmask & 0x0000ff00) >> 8);
1401 bytes[3] = (frmask & 0x000000ff);
1402 (*f) (4, bytes, NULL);
1403 }
1404
1405 static void
output_P6_format(f,rtype,rmask)1406 output_P6_format (f, rtype, rmask)
1407 vbyte_func f;
1408 unw_record_type rtype;
1409 int rmask;
1410 {
1411 char byte;
1412 int r = 0;
1413
1414 if (rtype == gr_mem)
1415 r = 1;
1416 else if (rtype != fr_mem)
1417 as_bad ("Invalid record type for format P6");
1418 byte = (UNW_P6 | (r << 4) | (rmask & 0x0f));
1419 (*f) (1, &byte, NULL);
1420 }
1421
1422 static void
output_P7_format(f,rtype,w1,w2)1423 output_P7_format (f, rtype, w1, w2)
1424 vbyte_func f;
1425 unw_record_type rtype;
1426 unsigned long w1;
1427 unsigned long w2;
1428 {
1429 char bytes[20];
1430 int count = 1;
1431 int r = 0;
1432 count += output_leb128 (bytes + 1, w1, 0);
1433 switch (rtype)
1434 {
1435 case mem_stack_f:
1436 r = 0;
1437 count += output_leb128 (bytes + count, w2 >> 4, 0);
1438 break;
1439 case mem_stack_v:
1440 r = 1;
1441 break;
1442 case spill_base:
1443 r = 2;
1444 break;
1445 case psp_sprel:
1446 r = 3;
1447 break;
1448 case rp_when:
1449 r = 4;
1450 break;
1451 case rp_psprel:
1452 r = 5;
1453 break;
1454 case pfs_when:
1455 r = 6;
1456 break;
1457 case pfs_psprel:
1458 r = 7;
1459 break;
1460 case preds_when:
1461 r = 8;
1462 break;
1463 case preds_psprel:
1464 r = 9;
1465 break;
1466 case lc_when:
1467 r = 10;
1468 break;
1469 case lc_psprel:
1470 r = 11;
1471 break;
1472 case unat_when:
1473 r = 12;
1474 break;
1475 case unat_psprel:
1476 r = 13;
1477 break;
1478 case fpsr_when:
1479 r = 14;
1480 break;
1481 case fpsr_psprel:
1482 r = 15;
1483 break;
1484 default:
1485 break;
1486 }
1487 bytes[0] = (UNW_P7 | r);
1488 (*f) (count, bytes, NULL);
1489 }
1490
1491 static void
output_P8_format(f,rtype,t)1492 output_P8_format (f, rtype, t)
1493 vbyte_func f;
1494 unw_record_type rtype;
1495 unsigned long t;
1496 {
1497 char bytes[20];
1498 int r = 0;
1499 int count = 2;
1500 bytes[0] = UNW_P8;
1501 switch (rtype)
1502 {
1503 case rp_sprel:
1504 r = 1;
1505 break;
1506 case pfs_sprel:
1507 r = 2;
1508 break;
1509 case preds_sprel:
1510 r = 3;
1511 break;
1512 case lc_sprel:
1513 r = 4;
1514 break;
1515 case unat_sprel:
1516 r = 5;
1517 break;
1518 case fpsr_sprel:
1519 r = 6;
1520 break;
1521 case bsp_when:
1522 r = 7;
1523 break;
1524 case bsp_psprel:
1525 r = 8;
1526 break;
1527 case bsp_sprel:
1528 r = 9;
1529 break;
1530 case bspstore_when:
1531 r = 10;
1532 break;
1533 case bspstore_psprel:
1534 r = 11;
1535 break;
1536 case bspstore_sprel:
1537 r = 12;
1538 break;
1539 case rnat_when:
1540 r = 13;
1541 break;
1542 case rnat_psprel:
1543 r = 14;
1544 break;
1545 case rnat_sprel:
1546 r = 15;
1547 break;
1548 case priunat_when_gr:
1549 r = 16;
1550 break;
1551 case priunat_psprel:
1552 r = 17;
1553 break;
1554 case priunat_sprel:
1555 r = 18;
1556 break;
1557 case priunat_when_mem:
1558 r = 19;
1559 break;
1560 default:
1561 break;
1562 }
1563 bytes[1] = r;
1564 count += output_leb128 (bytes + 2, t, 0);
1565 (*f) (count, bytes, NULL);
1566 }
1567
1568 static void
output_P9_format(f,grmask,gr)1569 output_P9_format (f, grmask, gr)
1570 vbyte_func f;
1571 int grmask;
1572 int gr;
1573 {
1574 char bytes[3];
1575 bytes[0] = UNW_P9;
1576 bytes[1] = (grmask & 0x0f);
1577 bytes[2] = (gr & 0x7f);
1578 (*f) (3, bytes, NULL);
1579 }
1580
1581 static void
output_P10_format(f,abi,context)1582 output_P10_format (f, abi, context)
1583 vbyte_func f;
1584 int abi;
1585 int context;
1586 {
1587 char bytes[3];
1588 bytes[0] = UNW_P10;
1589 bytes[1] = (abi & 0xff);
1590 bytes[2] = (context & 0xff);
1591 (*f) (3, bytes, NULL);
1592 }
1593
1594 static void
output_B1_format(f,rtype,label)1595 output_B1_format (f, rtype, label)
1596 vbyte_func f;
1597 unw_record_type rtype;
1598 unsigned long label;
1599 {
1600 char byte;
1601 int r = 0;
1602 if (label > 0x1f)
1603 {
1604 output_B4_format (f, rtype, label);
1605 return;
1606 }
1607 if (rtype == copy_state)
1608 r = 1;
1609 else if (rtype != label_state)
1610 as_bad ("Invalid record type for format B1");
1611
1612 byte = (UNW_B1 | (r << 5) | (label & 0x1f));
1613 (*f) (1, &byte, NULL);
1614 }
1615
1616 static void
output_B2_format(f,ecount,t)1617 output_B2_format (f, ecount, t)
1618 vbyte_func f;
1619 unsigned long ecount;
1620 unsigned long t;
1621 {
1622 char bytes[20];
1623 int count = 1;
1624 if (ecount > 0x1f)
1625 {
1626 output_B3_format (f, ecount, t);
1627 return;
1628 }
1629 bytes[0] = (UNW_B2 | (ecount & 0x1f));
1630 count += output_leb128 (bytes + 1, t, 0);
1631 (*f) (count, bytes, NULL);
1632 }
1633
1634 static void
output_B3_format(f,ecount,t)1635 output_B3_format (f, ecount, t)
1636 vbyte_func f;
1637 unsigned long ecount;
1638 unsigned long t;
1639 {
1640 char bytes[20];
1641 int count = 1;
1642 if (ecount <= 0x1f)
1643 {
1644 output_B2_format (f, ecount, t);
1645 return;
1646 }
1647 bytes[0] = UNW_B3;
1648 count += output_leb128 (bytes + 1, t, 0);
1649 count += output_leb128 (bytes + count, ecount, 0);
1650 (*f) (count, bytes, NULL);
1651 }
1652
1653 static void
output_B4_format(f,rtype,label)1654 output_B4_format (f, rtype, label)
1655 vbyte_func f;
1656 unw_record_type rtype;
1657 unsigned long label;
1658 {
1659 char bytes[20];
1660 int r = 0;
1661 int count = 1;
1662 if (label <= 0x1f)
1663 {
1664 output_B1_format (f, rtype, label);
1665 return;
1666 }
1667
1668 if (rtype == copy_state)
1669 r = 1;
1670 else if (rtype != label_state)
1671 as_bad ("Invalid record type for format B1");
1672
1673 bytes[0] = (UNW_B4 | (r << 3));
1674 count += output_leb128 (bytes + 1, label, 0);
1675 (*f) (count, bytes, NULL);
1676 }
1677
1678 static char
format_ab_reg(ab,reg)1679 format_ab_reg (ab, reg)
1680 int ab;
1681 int reg;
1682 {
1683 int ret;
1684 ab = (ab & 3);
1685 reg = (reg & 0x1f);
1686 ret = (ab << 5) | reg;
1687 return ret;
1688 }
1689
1690 static void
output_X1_format(f,rtype,ab,reg,t,w1)1691 output_X1_format (f, rtype, ab, reg, t, w1)
1692 vbyte_func f;
1693 unw_record_type rtype;
1694 int ab, reg;
1695 unsigned long t;
1696 unsigned long w1;
1697 {
1698 char bytes[20];
1699 int r = 0;
1700 int count = 2;
1701 bytes[0] = UNW_X1;
1702
1703 if (rtype == spill_sprel)
1704 r = 1;
1705 else if (rtype != spill_psprel)
1706 as_bad ("Invalid record type for format X1");
1707 bytes[1] = ((r << 7) | format_ab_reg (ab, reg));
1708 count += output_leb128 (bytes + 2, t, 0);
1709 count += output_leb128 (bytes + count, w1, 0);
1710 (*f) (count, bytes, NULL);
1711 }
1712
1713 static void
output_X2_format(f,ab,reg,x,y,treg,t)1714 output_X2_format (f, ab, reg, x, y, treg, t)
1715 vbyte_func f;
1716 int ab, reg;
1717 int x, y, treg;
1718 unsigned long t;
1719 {
1720 char bytes[20];
1721 int count = 3;
1722 bytes[0] = UNW_X2;
1723 bytes[1] = (((x & 1) << 7) | format_ab_reg (ab, reg));
1724 bytes[2] = (((y & 1) << 7) | (treg & 0x7f));
1725 count += output_leb128 (bytes + 3, t, 0);
1726 (*f) (count, bytes, NULL);
1727 }
1728
1729 static void
output_X3_format(f,rtype,qp,ab,reg,t,w1)1730 output_X3_format (f, rtype, qp, ab, reg, t, w1)
1731 vbyte_func f;
1732 unw_record_type rtype;
1733 int qp;
1734 int ab, reg;
1735 unsigned long t;
1736 unsigned long w1;
1737 {
1738 char bytes[20];
1739 int r = 0;
1740 int count = 3;
1741 bytes[0] = UNW_X3;
1742
1743 if (rtype == spill_sprel_p)
1744 r = 1;
1745 else if (rtype != spill_psprel_p)
1746 as_bad ("Invalid record type for format X3");
1747 bytes[1] = ((r << 7) | (qp & 0x3f));
1748 bytes[2] = format_ab_reg (ab, reg);
1749 count += output_leb128 (bytes + 3, t, 0);
1750 count += output_leb128 (bytes + count, w1, 0);
1751 (*f) (count, bytes, NULL);
1752 }
1753
1754 static void
output_X4_format(f,qp,ab,reg,x,y,treg,t)1755 output_X4_format (f, qp, ab, reg, x, y, treg, t)
1756 vbyte_func f;
1757 int qp;
1758 int ab, reg;
1759 int x, y, treg;
1760 unsigned long t;
1761 {
1762 char bytes[20];
1763 int count = 4;
1764 bytes[0] = UNW_X4;
1765 bytes[1] = (qp & 0x3f);
1766 bytes[2] = (((x & 1) << 7) | format_ab_reg (ab, reg));
1767 bytes[3] = (((y & 1) << 7) | (treg & 0x7f));
1768 count += output_leb128 (bytes + 4, t, 0);
1769 (*f) (count, bytes, NULL);
1770 }
1771
1772 /* This function checks whether there are any outstanding .save-s and
1773 discards them if so. */
1774
1775 static void
check_pending_save(void)1776 check_pending_save (void)
1777 {
1778 if (unwind.pending_saves)
1779 {
1780 unw_rec_list *cur, *prev;
1781
1782 as_warn ("Previous .save incomplete");
1783 for (cur = unwind.list, prev = NULL; cur; )
1784 if (&cur->r.record.p == unwind.pending_saves)
1785 {
1786 if (prev)
1787 prev->next = cur->next;
1788 else
1789 unwind.list = cur->next;
1790 if (cur == unwind.tail)
1791 unwind.tail = prev;
1792 if (cur == unwind.current_entry)
1793 unwind.current_entry = cur->next;
1794 /* Don't free the first discarded record, it's being used as
1795 terminator for (currently) br_gr and gr_gr processing, and
1796 also prevents leaving a dangling pointer to it in its
1797 predecessor. */
1798 cur->r.record.p.grmask = 0;
1799 cur->r.record.p.brmask = 0;
1800 cur->r.record.p.frmask = 0;
1801 prev = cur->r.record.p.next;
1802 cur->r.record.p.next = NULL;
1803 cur = prev;
1804 break;
1805 }
1806 else
1807 {
1808 prev = cur;
1809 cur = cur->next;
1810 }
1811 while (cur)
1812 {
1813 prev = cur;
1814 cur = cur->r.record.p.next;
1815 free (prev);
1816 }
1817 unwind.pending_saves = NULL;
1818 }
1819 }
1820
1821 /* This function allocates a record list structure, and initializes fields. */
1822
1823 static unw_rec_list *
alloc_record(unw_record_type t)1824 alloc_record (unw_record_type t)
1825 {
1826 unw_rec_list *ptr;
1827 ptr = xmalloc (sizeof (*ptr));
1828 memset (ptr, 0, sizeof (*ptr));
1829 ptr->slot_number = SLOT_NUM_NOT_SET;
1830 ptr->r.type = t;
1831 return ptr;
1832 }
1833
1834 /* Dummy unwind record used for calculating the length of the last prologue or
1835 body region. */
1836
1837 static unw_rec_list *
output_endp()1838 output_endp ()
1839 {
1840 unw_rec_list *ptr = alloc_record (endp);
1841 return ptr;
1842 }
1843
1844 static unw_rec_list *
output_prologue()1845 output_prologue ()
1846 {
1847 unw_rec_list *ptr = alloc_record (prologue);
1848 memset (&ptr->r.record.r.mask, 0, sizeof (ptr->r.record.r.mask));
1849 return ptr;
1850 }
1851
1852 static unw_rec_list *
output_prologue_gr(saved_mask,reg)1853 output_prologue_gr (saved_mask, reg)
1854 unsigned int saved_mask;
1855 unsigned int reg;
1856 {
1857 unw_rec_list *ptr = alloc_record (prologue_gr);
1858 memset (&ptr->r.record.r.mask, 0, sizeof (ptr->r.record.r.mask));
1859 ptr->r.record.r.grmask = saved_mask;
1860 ptr->r.record.r.grsave = reg;
1861 return ptr;
1862 }
1863
1864 static unw_rec_list *
output_body()1865 output_body ()
1866 {
1867 unw_rec_list *ptr = alloc_record (body);
1868 return ptr;
1869 }
1870
1871 static unw_rec_list *
output_mem_stack_f(size)1872 output_mem_stack_f (size)
1873 unsigned int size;
1874 {
1875 unw_rec_list *ptr = alloc_record (mem_stack_f);
1876 ptr->r.record.p.size = size;
1877 return ptr;
1878 }
1879
1880 static unw_rec_list *
output_mem_stack_v()1881 output_mem_stack_v ()
1882 {
1883 unw_rec_list *ptr = alloc_record (mem_stack_v);
1884 return ptr;
1885 }
1886
1887 static unw_rec_list *
output_psp_gr(gr)1888 output_psp_gr (gr)
1889 unsigned int gr;
1890 {
1891 unw_rec_list *ptr = alloc_record (psp_gr);
1892 ptr->r.record.p.r.gr = gr;
1893 return ptr;
1894 }
1895
1896 static unw_rec_list *
output_psp_sprel(offset)1897 output_psp_sprel (offset)
1898 unsigned int offset;
1899 {
1900 unw_rec_list *ptr = alloc_record (psp_sprel);
1901 ptr->r.record.p.off.sp = offset / 4;
1902 return ptr;
1903 }
1904
1905 static unw_rec_list *
output_rp_when()1906 output_rp_when ()
1907 {
1908 unw_rec_list *ptr = alloc_record (rp_when);
1909 return ptr;
1910 }
1911
1912 static unw_rec_list *
output_rp_gr(gr)1913 output_rp_gr (gr)
1914 unsigned int gr;
1915 {
1916 unw_rec_list *ptr = alloc_record (rp_gr);
1917 ptr->r.record.p.r.gr = gr;
1918 return ptr;
1919 }
1920
1921 static unw_rec_list *
output_rp_br(br)1922 output_rp_br (br)
1923 unsigned int br;
1924 {
1925 unw_rec_list *ptr = alloc_record (rp_br);
1926 ptr->r.record.p.r.br = br;
1927 return ptr;
1928 }
1929
1930 static unw_rec_list *
output_rp_psprel(offset)1931 output_rp_psprel (offset)
1932 unsigned int offset;
1933 {
1934 unw_rec_list *ptr = alloc_record (rp_psprel);
1935 ptr->r.record.p.off.psp = ENCODED_PSP_OFFSET (offset);
1936 return ptr;
1937 }
1938
1939 static unw_rec_list *
output_rp_sprel(offset)1940 output_rp_sprel (offset)
1941 unsigned int offset;
1942 {
1943 unw_rec_list *ptr = alloc_record (rp_sprel);
1944 ptr->r.record.p.off.sp = offset / 4;
1945 return ptr;
1946 }
1947
1948 static unw_rec_list *
output_pfs_when()1949 output_pfs_when ()
1950 {
1951 unw_rec_list *ptr = alloc_record (pfs_when);
1952 return ptr;
1953 }
1954
1955 static unw_rec_list *
output_pfs_gr(gr)1956 output_pfs_gr (gr)
1957 unsigned int gr;
1958 {
1959 unw_rec_list *ptr = alloc_record (pfs_gr);
1960 ptr->r.record.p.r.gr = gr;
1961 return ptr;
1962 }
1963
1964 static unw_rec_list *
output_pfs_psprel(offset)1965 output_pfs_psprel (offset)
1966 unsigned int offset;
1967 {
1968 unw_rec_list *ptr = alloc_record (pfs_psprel);
1969 ptr->r.record.p.off.psp = ENCODED_PSP_OFFSET (offset);
1970 return ptr;
1971 }
1972
1973 static unw_rec_list *
output_pfs_sprel(offset)1974 output_pfs_sprel (offset)
1975 unsigned int offset;
1976 {
1977 unw_rec_list *ptr = alloc_record (pfs_sprel);
1978 ptr->r.record.p.off.sp = offset / 4;
1979 return ptr;
1980 }
1981
1982 static unw_rec_list *
output_preds_when()1983 output_preds_when ()
1984 {
1985 unw_rec_list *ptr = alloc_record (preds_when);
1986 return ptr;
1987 }
1988
1989 static unw_rec_list *
output_preds_gr(gr)1990 output_preds_gr (gr)
1991 unsigned int gr;
1992 {
1993 unw_rec_list *ptr = alloc_record (preds_gr);
1994 ptr->r.record.p.r.gr = gr;
1995 return ptr;
1996 }
1997
1998 static unw_rec_list *
output_preds_psprel(offset)1999 output_preds_psprel (offset)
2000 unsigned int offset;
2001 {
2002 unw_rec_list *ptr = alloc_record (preds_psprel);
2003 ptr->r.record.p.off.psp = ENCODED_PSP_OFFSET (offset);
2004 return ptr;
2005 }
2006
2007 static unw_rec_list *
output_preds_sprel(offset)2008 output_preds_sprel (offset)
2009 unsigned int offset;
2010 {
2011 unw_rec_list *ptr = alloc_record (preds_sprel);
2012 ptr->r.record.p.off.sp = offset / 4;
2013 return ptr;
2014 }
2015
2016 static unw_rec_list *
output_fr_mem(mask)2017 output_fr_mem (mask)
2018 unsigned int mask;
2019 {
2020 unw_rec_list *ptr = alloc_record (fr_mem);
2021 unw_rec_list *cur = ptr;
2022
2023 ptr->r.record.p.frmask = mask;
2024 unwind.pending_saves = &ptr->r.record.p;
2025 for (;;)
2026 {
2027 unw_rec_list *prev = cur;
2028
2029 /* Clear least significant set bit. */
2030 mask &= ~(mask & (~mask + 1));
2031 if (!mask)
2032 return ptr;
2033 cur = alloc_record (fr_mem);
2034 cur->r.record.p.frmask = mask;
2035 /* Retain only least significant bit. */
2036 prev->r.record.p.frmask ^= mask;
2037 prev->r.record.p.next = cur;
2038 }
2039 }
2040
2041 static unw_rec_list *
output_frgr_mem(gr_mask,fr_mask)2042 output_frgr_mem (gr_mask, fr_mask)
2043 unsigned int gr_mask;
2044 unsigned int fr_mask;
2045 {
2046 unw_rec_list *ptr = alloc_record (frgr_mem);
2047 unw_rec_list *cur = ptr;
2048
2049 unwind.pending_saves = &cur->r.record.p;
2050 cur->r.record.p.frmask = fr_mask;
2051 while (fr_mask)
2052 {
2053 unw_rec_list *prev = cur;
2054
2055 /* Clear least significant set bit. */
2056 fr_mask &= ~(fr_mask & (~fr_mask + 1));
2057 if (!gr_mask && !fr_mask)
2058 return ptr;
2059 cur = alloc_record (frgr_mem);
2060 cur->r.record.p.frmask = fr_mask;
2061 /* Retain only least significant bit. */
2062 prev->r.record.p.frmask ^= fr_mask;
2063 prev->r.record.p.next = cur;
2064 }
2065 cur->r.record.p.grmask = gr_mask;
2066 for (;;)
2067 {
2068 unw_rec_list *prev = cur;
2069
2070 /* Clear least significant set bit. */
2071 gr_mask &= ~(gr_mask & (~gr_mask + 1));
2072 if (!gr_mask)
2073 return ptr;
2074 cur = alloc_record (frgr_mem);
2075 cur->r.record.p.grmask = gr_mask;
2076 /* Retain only least significant bit. */
2077 prev->r.record.p.grmask ^= gr_mask;
2078 prev->r.record.p.next = cur;
2079 }
2080 }
2081
2082 static unw_rec_list *
output_gr_gr(mask,reg)2083 output_gr_gr (mask, reg)
2084 unsigned int mask;
2085 unsigned int reg;
2086 {
2087 unw_rec_list *ptr = alloc_record (gr_gr);
2088 unw_rec_list *cur = ptr;
2089
2090 ptr->r.record.p.grmask = mask;
2091 ptr->r.record.p.r.gr = reg;
2092 unwind.pending_saves = &ptr->r.record.p;
2093 for (;;)
2094 {
2095 unw_rec_list *prev = cur;
2096
2097 /* Clear least significant set bit. */
2098 mask &= ~(mask & (~mask + 1));
2099 if (!mask)
2100 return ptr;
2101 cur = alloc_record (gr_gr);
2102 cur->r.record.p.grmask = mask;
2103 /* Indicate this record shouldn't be output. */
2104 cur->r.record.p.r.gr = REG_NUM;
2105 /* Retain only least significant bit. */
2106 prev->r.record.p.grmask ^= mask;
2107 prev->r.record.p.next = cur;
2108 }
2109 }
2110
2111 static unw_rec_list *
output_gr_mem(mask)2112 output_gr_mem (mask)
2113 unsigned int mask;
2114 {
2115 unw_rec_list *ptr = alloc_record (gr_mem);
2116 unw_rec_list *cur = ptr;
2117
2118 ptr->r.record.p.grmask = mask;
2119 unwind.pending_saves = &ptr->r.record.p;
2120 for (;;)
2121 {
2122 unw_rec_list *prev = cur;
2123
2124 /* Clear least significant set bit. */
2125 mask &= ~(mask & (~mask + 1));
2126 if (!mask)
2127 return ptr;
2128 cur = alloc_record (gr_mem);
2129 cur->r.record.p.grmask = mask;
2130 /* Retain only least significant bit. */
2131 prev->r.record.p.grmask ^= mask;
2132 prev->r.record.p.next = cur;
2133 }
2134 }
2135
2136 static unw_rec_list *
output_br_mem(unsigned int mask)2137 output_br_mem (unsigned int mask)
2138 {
2139 unw_rec_list *ptr = alloc_record (br_mem);
2140 unw_rec_list *cur = ptr;
2141
2142 ptr->r.record.p.brmask = mask;
2143 unwind.pending_saves = &ptr->r.record.p;
2144 for (;;)
2145 {
2146 unw_rec_list *prev = cur;
2147
2148 /* Clear least significant set bit. */
2149 mask &= ~(mask & (~mask + 1));
2150 if (!mask)
2151 return ptr;
2152 cur = alloc_record (br_mem);
2153 cur->r.record.p.brmask = mask;
2154 /* Retain only least significant bit. */
2155 prev->r.record.p.brmask ^= mask;
2156 prev->r.record.p.next = cur;
2157 }
2158 }
2159
2160 static unw_rec_list *
output_br_gr(mask,reg)2161 output_br_gr (mask, reg)
2162 unsigned int mask;
2163 unsigned int reg;
2164 {
2165 unw_rec_list *ptr = alloc_record (br_gr);
2166 unw_rec_list *cur = ptr;
2167
2168 ptr->r.record.p.brmask = mask;
2169 ptr->r.record.p.r.gr = reg;
2170 unwind.pending_saves = &ptr->r.record.p;
2171 for (;;)
2172 {
2173 unw_rec_list *prev = cur;
2174
2175 /* Clear least significant set bit. */
2176 mask &= ~(mask & (~mask + 1));
2177 if (!mask)
2178 return ptr;
2179 cur = alloc_record (br_gr);
2180 cur->r.record.p.brmask = mask;
2181 /* Indicate this record shouldn't be output. */
2182 cur->r.record.p.r.gr = REG_NUM;
2183 /* Retain only least significant bit. */
2184 prev->r.record.p.brmask ^= mask;
2185 prev->r.record.p.next = cur;
2186 }
2187 }
2188
2189 static unw_rec_list *
output_spill_base(offset)2190 output_spill_base (offset)
2191 unsigned int offset;
2192 {
2193 unw_rec_list *ptr = alloc_record (spill_base);
2194 ptr->r.record.p.off.psp = ENCODED_PSP_OFFSET (offset);
2195 return ptr;
2196 }
2197
2198 static unw_rec_list *
output_unat_when()2199 output_unat_when ()
2200 {
2201 unw_rec_list *ptr = alloc_record (unat_when);
2202 return ptr;
2203 }
2204
2205 static unw_rec_list *
output_unat_gr(gr)2206 output_unat_gr (gr)
2207 unsigned int gr;
2208 {
2209 unw_rec_list *ptr = alloc_record (unat_gr);
2210 ptr->r.record.p.r.gr = gr;
2211 return ptr;
2212 }
2213
2214 static unw_rec_list *
output_unat_psprel(offset)2215 output_unat_psprel (offset)
2216 unsigned int offset;
2217 {
2218 unw_rec_list *ptr = alloc_record (unat_psprel);
2219 ptr->r.record.p.off.psp = ENCODED_PSP_OFFSET (offset);
2220 return ptr;
2221 }
2222
2223 static unw_rec_list *
output_unat_sprel(offset)2224 output_unat_sprel (offset)
2225 unsigned int offset;
2226 {
2227 unw_rec_list *ptr = alloc_record (unat_sprel);
2228 ptr->r.record.p.off.sp = offset / 4;
2229 return ptr;
2230 }
2231
2232 static unw_rec_list *
output_lc_when()2233 output_lc_when ()
2234 {
2235 unw_rec_list *ptr = alloc_record (lc_when);
2236 return ptr;
2237 }
2238
2239 static unw_rec_list *
output_lc_gr(gr)2240 output_lc_gr (gr)
2241 unsigned int gr;
2242 {
2243 unw_rec_list *ptr = alloc_record (lc_gr);
2244 ptr->r.record.p.r.gr = gr;
2245 return ptr;
2246 }
2247
2248 static unw_rec_list *
output_lc_psprel(offset)2249 output_lc_psprel (offset)
2250 unsigned int offset;
2251 {
2252 unw_rec_list *ptr = alloc_record (lc_psprel);
2253 ptr->r.record.p.off.psp = ENCODED_PSP_OFFSET (offset);
2254 return ptr;
2255 }
2256
2257 static unw_rec_list *
output_lc_sprel(offset)2258 output_lc_sprel (offset)
2259 unsigned int offset;
2260 {
2261 unw_rec_list *ptr = alloc_record (lc_sprel);
2262 ptr->r.record.p.off.sp = offset / 4;
2263 return ptr;
2264 }
2265
2266 static unw_rec_list *
output_fpsr_when()2267 output_fpsr_when ()
2268 {
2269 unw_rec_list *ptr = alloc_record (fpsr_when);
2270 return ptr;
2271 }
2272
2273 static unw_rec_list *
output_fpsr_gr(gr)2274 output_fpsr_gr (gr)
2275 unsigned int gr;
2276 {
2277 unw_rec_list *ptr = alloc_record (fpsr_gr);
2278 ptr->r.record.p.r.gr = gr;
2279 return ptr;
2280 }
2281
2282 static unw_rec_list *
output_fpsr_psprel(offset)2283 output_fpsr_psprel (offset)
2284 unsigned int offset;
2285 {
2286 unw_rec_list *ptr = alloc_record (fpsr_psprel);
2287 ptr->r.record.p.off.psp = ENCODED_PSP_OFFSET (offset);
2288 return ptr;
2289 }
2290
2291 static unw_rec_list *
output_fpsr_sprel(offset)2292 output_fpsr_sprel (offset)
2293 unsigned int offset;
2294 {
2295 unw_rec_list *ptr = alloc_record (fpsr_sprel);
2296 ptr->r.record.p.off.sp = offset / 4;
2297 return ptr;
2298 }
2299
2300 static unw_rec_list *
output_priunat_when_gr()2301 output_priunat_when_gr ()
2302 {
2303 unw_rec_list *ptr = alloc_record (priunat_when_gr);
2304 return ptr;
2305 }
2306
2307 static unw_rec_list *
output_priunat_when_mem()2308 output_priunat_when_mem ()
2309 {
2310 unw_rec_list *ptr = alloc_record (priunat_when_mem);
2311 return ptr;
2312 }
2313
2314 static unw_rec_list *
output_priunat_gr(gr)2315 output_priunat_gr (gr)
2316 unsigned int gr;
2317 {
2318 unw_rec_list *ptr = alloc_record (priunat_gr);
2319 ptr->r.record.p.r.gr = gr;
2320 return ptr;
2321 }
2322
2323 static unw_rec_list *
output_priunat_psprel(offset)2324 output_priunat_psprel (offset)
2325 unsigned int offset;
2326 {
2327 unw_rec_list *ptr = alloc_record (priunat_psprel);
2328 ptr->r.record.p.off.psp = ENCODED_PSP_OFFSET (offset);
2329 return ptr;
2330 }
2331
2332 static unw_rec_list *
output_priunat_sprel(offset)2333 output_priunat_sprel (offset)
2334 unsigned int offset;
2335 {
2336 unw_rec_list *ptr = alloc_record (priunat_sprel);
2337 ptr->r.record.p.off.sp = offset / 4;
2338 return ptr;
2339 }
2340
2341 static unw_rec_list *
output_bsp_when()2342 output_bsp_when ()
2343 {
2344 unw_rec_list *ptr = alloc_record (bsp_when);
2345 return ptr;
2346 }
2347
2348 static unw_rec_list *
output_bsp_gr(gr)2349 output_bsp_gr (gr)
2350 unsigned int gr;
2351 {
2352 unw_rec_list *ptr = alloc_record (bsp_gr);
2353 ptr->r.record.p.r.gr = gr;
2354 return ptr;
2355 }
2356
2357 static unw_rec_list *
output_bsp_psprel(offset)2358 output_bsp_psprel (offset)
2359 unsigned int offset;
2360 {
2361 unw_rec_list *ptr = alloc_record (bsp_psprel);
2362 ptr->r.record.p.off.psp = ENCODED_PSP_OFFSET (offset);
2363 return ptr;
2364 }
2365
2366 static unw_rec_list *
output_bsp_sprel(offset)2367 output_bsp_sprel (offset)
2368 unsigned int offset;
2369 {
2370 unw_rec_list *ptr = alloc_record (bsp_sprel);
2371 ptr->r.record.p.off.sp = offset / 4;
2372 return ptr;
2373 }
2374
2375 static unw_rec_list *
output_bspstore_when()2376 output_bspstore_when ()
2377 {
2378 unw_rec_list *ptr = alloc_record (bspstore_when);
2379 return ptr;
2380 }
2381
2382 static unw_rec_list *
output_bspstore_gr(gr)2383 output_bspstore_gr (gr)
2384 unsigned int gr;
2385 {
2386 unw_rec_list *ptr = alloc_record (bspstore_gr);
2387 ptr->r.record.p.r.gr = gr;
2388 return ptr;
2389 }
2390
2391 static unw_rec_list *
output_bspstore_psprel(offset)2392 output_bspstore_psprel (offset)
2393 unsigned int offset;
2394 {
2395 unw_rec_list *ptr = alloc_record (bspstore_psprel);
2396 ptr->r.record.p.off.psp = ENCODED_PSP_OFFSET (offset);
2397 return ptr;
2398 }
2399
2400 static unw_rec_list *
output_bspstore_sprel(offset)2401 output_bspstore_sprel (offset)
2402 unsigned int offset;
2403 {
2404 unw_rec_list *ptr = alloc_record (bspstore_sprel);
2405 ptr->r.record.p.off.sp = offset / 4;
2406 return ptr;
2407 }
2408
2409 static unw_rec_list *
output_rnat_when()2410 output_rnat_when ()
2411 {
2412 unw_rec_list *ptr = alloc_record (rnat_when);
2413 return ptr;
2414 }
2415
2416 static unw_rec_list *
output_rnat_gr(gr)2417 output_rnat_gr (gr)
2418 unsigned int gr;
2419 {
2420 unw_rec_list *ptr = alloc_record (rnat_gr);
2421 ptr->r.record.p.r.gr = gr;
2422 return ptr;
2423 }
2424
2425 static unw_rec_list *
output_rnat_psprel(offset)2426 output_rnat_psprel (offset)
2427 unsigned int offset;
2428 {
2429 unw_rec_list *ptr = alloc_record (rnat_psprel);
2430 ptr->r.record.p.off.psp = ENCODED_PSP_OFFSET (offset);
2431 return ptr;
2432 }
2433
2434 static unw_rec_list *
output_rnat_sprel(offset)2435 output_rnat_sprel (offset)
2436 unsigned int offset;
2437 {
2438 unw_rec_list *ptr = alloc_record (rnat_sprel);
2439 ptr->r.record.p.off.sp = offset / 4;
2440 return ptr;
2441 }
2442
2443 static unw_rec_list *
output_unwabi(abi,context)2444 output_unwabi (abi, context)
2445 unsigned long abi;
2446 unsigned long context;
2447 {
2448 unw_rec_list *ptr = alloc_record (unwabi);
2449 ptr->r.record.p.abi = abi;
2450 ptr->r.record.p.context = context;
2451 return ptr;
2452 }
2453
2454 static unw_rec_list *
output_epilogue(unsigned long ecount)2455 output_epilogue (unsigned long ecount)
2456 {
2457 unw_rec_list *ptr = alloc_record (epilogue);
2458 ptr->r.record.b.ecount = ecount;
2459 return ptr;
2460 }
2461
2462 static unw_rec_list *
output_label_state(unsigned long label)2463 output_label_state (unsigned long label)
2464 {
2465 unw_rec_list *ptr = alloc_record (label_state);
2466 ptr->r.record.b.label = label;
2467 return ptr;
2468 }
2469
2470 static unw_rec_list *
output_copy_state(unsigned long label)2471 output_copy_state (unsigned long label)
2472 {
2473 unw_rec_list *ptr = alloc_record (copy_state);
2474 ptr->r.record.b.label = label;
2475 return ptr;
2476 }
2477
2478 static unw_rec_list *
output_spill_psprel(ab,reg,offset,predicate)2479 output_spill_psprel (ab, reg, offset, predicate)
2480 unsigned int ab;
2481 unsigned int reg;
2482 unsigned int offset;
2483 unsigned int predicate;
2484 {
2485 unw_rec_list *ptr = alloc_record (predicate ? spill_psprel_p : spill_psprel);
2486 ptr->r.record.x.ab = ab;
2487 ptr->r.record.x.reg = reg;
2488 ptr->r.record.x.where.pspoff = ENCODED_PSP_OFFSET (offset);
2489 ptr->r.record.x.qp = predicate;
2490 return ptr;
2491 }
2492
2493 static unw_rec_list *
output_spill_sprel(ab,reg,offset,predicate)2494 output_spill_sprel (ab, reg, offset, predicate)
2495 unsigned int ab;
2496 unsigned int reg;
2497 unsigned int offset;
2498 unsigned int predicate;
2499 {
2500 unw_rec_list *ptr = alloc_record (predicate ? spill_sprel_p : spill_sprel);
2501 ptr->r.record.x.ab = ab;
2502 ptr->r.record.x.reg = reg;
2503 ptr->r.record.x.where.spoff = offset / 4;
2504 ptr->r.record.x.qp = predicate;
2505 return ptr;
2506 }
2507
2508 static unw_rec_list *
output_spill_reg(ab,reg,targ_reg,xy,predicate)2509 output_spill_reg (ab, reg, targ_reg, xy, predicate)
2510 unsigned int ab;
2511 unsigned int reg;
2512 unsigned int targ_reg;
2513 unsigned int xy;
2514 unsigned int predicate;
2515 {
2516 unw_rec_list *ptr = alloc_record (predicate ? spill_reg_p : spill_reg);
2517 ptr->r.record.x.ab = ab;
2518 ptr->r.record.x.reg = reg;
2519 ptr->r.record.x.where.reg = targ_reg;
2520 ptr->r.record.x.xy = xy;
2521 ptr->r.record.x.qp = predicate;
2522 return ptr;
2523 }
2524
2525 /* Given a unw_rec_list process the correct format with the
2526 specified function. */
2527
2528 static void
process_one_record(ptr,f)2529 process_one_record (ptr, f)
2530 unw_rec_list *ptr;
2531 vbyte_func f;
2532 {
2533 unsigned int fr_mask, gr_mask;
2534
2535 switch (ptr->r.type)
2536 {
2537 /* This is a dummy record that takes up no space in the output. */
2538 case endp:
2539 break;
2540
2541 case gr_mem:
2542 case fr_mem:
2543 case br_mem:
2544 case frgr_mem:
2545 /* These are taken care of by prologue/prologue_gr. */
2546 break;
2547
2548 case prologue_gr:
2549 case prologue:
2550 if (ptr->r.type == prologue_gr)
2551 output_R2_format (f, ptr->r.record.r.grmask,
2552 ptr->r.record.r.grsave, ptr->r.record.r.rlen);
2553 else
2554 output_R1_format (f, ptr->r.type, ptr->r.record.r.rlen);
2555
2556 /* Output descriptor(s) for union of register spills (if any). */
2557 gr_mask = ptr->r.record.r.mask.gr_mem;
2558 fr_mask = ptr->r.record.r.mask.fr_mem;
2559 if (fr_mask)
2560 {
2561 if ((fr_mask & ~0xfUL) == 0)
2562 output_P6_format (f, fr_mem, fr_mask);
2563 else
2564 {
2565 output_P5_format (f, gr_mask, fr_mask);
2566 gr_mask = 0;
2567 }
2568 }
2569 if (gr_mask)
2570 output_P6_format (f, gr_mem, gr_mask);
2571 if (ptr->r.record.r.mask.br_mem)
2572 output_P1_format (f, ptr->r.record.r.mask.br_mem);
2573
2574 /* output imask descriptor if necessary: */
2575 if (ptr->r.record.r.mask.i)
2576 output_P4_format (f, ptr->r.record.r.mask.i,
2577 ptr->r.record.r.imask_size);
2578 break;
2579
2580 case body:
2581 output_R1_format (f, ptr->r.type, ptr->r.record.r.rlen);
2582 break;
2583 case mem_stack_f:
2584 case mem_stack_v:
2585 output_P7_format (f, ptr->r.type, ptr->r.record.p.t,
2586 ptr->r.record.p.size);
2587 break;
2588 case psp_gr:
2589 case rp_gr:
2590 case pfs_gr:
2591 case preds_gr:
2592 case unat_gr:
2593 case lc_gr:
2594 case fpsr_gr:
2595 case priunat_gr:
2596 case bsp_gr:
2597 case bspstore_gr:
2598 case rnat_gr:
2599 output_P3_format (f, ptr->r.type, ptr->r.record.p.r.gr);
2600 break;
2601 case rp_br:
2602 output_P3_format (f, rp_br, ptr->r.record.p.r.br);
2603 break;
2604 case psp_sprel:
2605 output_P7_format (f, psp_sprel, ptr->r.record.p.off.sp, 0);
2606 break;
2607 case rp_when:
2608 case pfs_when:
2609 case preds_when:
2610 case unat_when:
2611 case lc_when:
2612 case fpsr_when:
2613 output_P7_format (f, ptr->r.type, ptr->r.record.p.t, 0);
2614 break;
2615 case rp_psprel:
2616 case pfs_psprel:
2617 case preds_psprel:
2618 case unat_psprel:
2619 case lc_psprel:
2620 case fpsr_psprel:
2621 case spill_base:
2622 output_P7_format (f, ptr->r.type, ptr->r.record.p.off.psp, 0);
2623 break;
2624 case rp_sprel:
2625 case pfs_sprel:
2626 case preds_sprel:
2627 case unat_sprel:
2628 case lc_sprel:
2629 case fpsr_sprel:
2630 case priunat_sprel:
2631 case bsp_sprel:
2632 case bspstore_sprel:
2633 case rnat_sprel:
2634 output_P8_format (f, ptr->r.type, ptr->r.record.p.off.sp);
2635 break;
2636 case gr_gr:
2637 if (ptr->r.record.p.r.gr < REG_NUM)
2638 {
2639 const unw_rec_list *cur = ptr;
2640
2641 gr_mask = cur->r.record.p.grmask;
2642 while ((cur = cur->r.record.p.next) != NULL)
2643 gr_mask |= cur->r.record.p.grmask;
2644 output_P9_format (f, gr_mask, ptr->r.record.p.r.gr);
2645 }
2646 break;
2647 case br_gr:
2648 if (ptr->r.record.p.r.gr < REG_NUM)
2649 {
2650 const unw_rec_list *cur = ptr;
2651
2652 gr_mask = cur->r.record.p.brmask;
2653 while ((cur = cur->r.record.p.next) != NULL)
2654 gr_mask |= cur->r.record.p.brmask;
2655 output_P2_format (f, gr_mask, ptr->r.record.p.r.gr);
2656 }
2657 break;
2658 case spill_mask:
2659 as_bad ("spill_mask record unimplemented.");
2660 break;
2661 case priunat_when_gr:
2662 case priunat_when_mem:
2663 case bsp_when:
2664 case bspstore_when:
2665 case rnat_when:
2666 output_P8_format (f, ptr->r.type, ptr->r.record.p.t);
2667 break;
2668 case priunat_psprel:
2669 case bsp_psprel:
2670 case bspstore_psprel:
2671 case rnat_psprel:
2672 output_P8_format (f, ptr->r.type, ptr->r.record.p.off.psp);
2673 break;
2674 case unwabi:
2675 output_P10_format (f, ptr->r.record.p.abi, ptr->r.record.p.context);
2676 break;
2677 case epilogue:
2678 output_B3_format (f, ptr->r.record.b.ecount, ptr->r.record.b.t);
2679 break;
2680 case label_state:
2681 case copy_state:
2682 output_B4_format (f, ptr->r.type, ptr->r.record.b.label);
2683 break;
2684 case spill_psprel:
2685 output_X1_format (f, ptr->r.type, ptr->r.record.x.ab,
2686 ptr->r.record.x.reg, ptr->r.record.x.t,
2687 ptr->r.record.x.where.pspoff);
2688 break;
2689 case spill_sprel:
2690 output_X1_format (f, ptr->r.type, ptr->r.record.x.ab,
2691 ptr->r.record.x.reg, ptr->r.record.x.t,
2692 ptr->r.record.x.where.spoff);
2693 break;
2694 case spill_reg:
2695 output_X2_format (f, ptr->r.record.x.ab, ptr->r.record.x.reg,
2696 ptr->r.record.x.xy >> 1, ptr->r.record.x.xy,
2697 ptr->r.record.x.where.reg, ptr->r.record.x.t);
2698 break;
2699 case spill_psprel_p:
2700 output_X3_format (f, ptr->r.type, ptr->r.record.x.qp,
2701 ptr->r.record.x.ab, ptr->r.record.x.reg,
2702 ptr->r.record.x.t, ptr->r.record.x.where.pspoff);
2703 break;
2704 case spill_sprel_p:
2705 output_X3_format (f, ptr->r.type, ptr->r.record.x.qp,
2706 ptr->r.record.x.ab, ptr->r.record.x.reg,
2707 ptr->r.record.x.t, ptr->r.record.x.where.spoff);
2708 break;
2709 case spill_reg_p:
2710 output_X4_format (f, ptr->r.record.x.qp, ptr->r.record.x.ab,
2711 ptr->r.record.x.reg, ptr->r.record.x.xy >> 1,
2712 ptr->r.record.x.xy, ptr->r.record.x.where.reg,
2713 ptr->r.record.x.t);
2714 break;
2715 default:
2716 as_bad ("record_type_not_valid");
2717 break;
2718 }
2719 }
2720
2721 /* Given a unw_rec_list list, process all the records with
2722 the specified function. */
2723 static void
process_unw_records(list,f)2724 process_unw_records (list, f)
2725 unw_rec_list *list;
2726 vbyte_func f;
2727 {
2728 unw_rec_list *ptr;
2729 for (ptr = list; ptr; ptr = ptr->next)
2730 process_one_record (ptr, f);
2731 }
2732
2733 /* Determine the size of a record list in bytes. */
2734 static int
calc_record_size(list)2735 calc_record_size (list)
2736 unw_rec_list *list;
2737 {
2738 vbyte_count = 0;
2739 process_unw_records (list, count_output);
2740 return vbyte_count;
2741 }
2742
2743 /* Return the number of bits set in the input value.
2744 Perhaps this has a better place... */
2745 #if __GNUC__ > 3 || (__GNUC__ == 3 && __GNUC_MINOR__ >= 4)
2746 # define popcount __builtin_popcount
2747 #else
2748 static int
popcount(unsigned x)2749 popcount (unsigned x)
2750 {
2751 static const unsigned char popcnt[16] =
2752 {
2753 0, 1, 1, 2,
2754 1, 2, 2, 3,
2755 1, 2, 2, 3,
2756 2, 3, 3, 4
2757 };
2758
2759 if (x < NELEMS (popcnt))
2760 return popcnt[x];
2761 return popcnt[x % NELEMS (popcnt)] + popcount (x / NELEMS (popcnt));
2762 }
2763 #endif
2764
2765 /* Update IMASK bitmask to reflect the fact that one or more registers
2766 of type TYPE are saved starting at instruction with index T. If N
2767 bits are set in REGMASK, it is assumed that instructions T through
2768 T+N-1 save these registers.
2769
2770 TYPE values:
2771 0: no save
2772 1: instruction saves next fp reg
2773 2: instruction saves next general reg
2774 3: instruction saves next branch reg */
2775 static void
set_imask(region,regmask,t,type)2776 set_imask (region, regmask, t, type)
2777 unw_rec_list *region;
2778 unsigned long regmask;
2779 unsigned long t;
2780 unsigned int type;
2781 {
2782 unsigned char *imask;
2783 unsigned long imask_size;
2784 unsigned int i;
2785 int pos;
2786
2787 imask = region->r.record.r.mask.i;
2788 imask_size = region->r.record.r.imask_size;
2789 if (!imask)
2790 {
2791 imask_size = (region->r.record.r.rlen * 2 + 7) / 8 + 1;
2792 imask = xmalloc (imask_size);
2793 memset (imask, 0, imask_size);
2794
2795 region->r.record.r.imask_size = imask_size;
2796 region->r.record.r.mask.i = imask;
2797 }
2798
2799 i = (t / 4) + 1;
2800 pos = 2 * (3 - t % 4);
2801 while (regmask)
2802 {
2803 if (i >= imask_size)
2804 {
2805 as_bad ("Ignoring attempt to spill beyond end of region");
2806 return;
2807 }
2808
2809 imask[i] |= (type & 0x3) << pos;
2810
2811 regmask &= (regmask - 1);
2812 pos -= 2;
2813 if (pos < 0)
2814 {
2815 pos = 0;
2816 ++i;
2817 }
2818 }
2819 }
2820
2821 /* Return the number of instruction slots from FIRST_ADDR to SLOT_ADDR.
2822 SLOT_FRAG is the frag containing SLOT_ADDR, and FIRST_FRAG is the frag
2823 containing FIRST_ADDR. If BEFORE_RELAX, then we use worst-case estimates
2824 for frag sizes. */
2825
2826 unsigned long
slot_index(slot_addr,slot_frag,first_addr,first_frag,before_relax)2827 slot_index (slot_addr, slot_frag, first_addr, first_frag, before_relax)
2828 unsigned long slot_addr;
2829 fragS *slot_frag;
2830 unsigned long first_addr;
2831 fragS *first_frag;
2832 int before_relax;
2833 {
2834 unsigned long index = 0;
2835
2836 /* First time we are called, the initial address and frag are invalid. */
2837 if (first_addr == 0)
2838 return 0;
2839
2840 /* If the two addresses are in different frags, then we need to add in
2841 the remaining size of this frag, and then the entire size of intermediate
2842 frags. */
2843 while (slot_frag != first_frag)
2844 {
2845 unsigned long start_addr = (unsigned long) &first_frag->fr_literal;
2846
2847 if (! before_relax)
2848 {
2849 /* We can get the final addresses only during and after
2850 relaxation. */
2851 if (first_frag->fr_next && first_frag->fr_next->fr_address)
2852 index += 3 * ((first_frag->fr_next->fr_address
2853 - first_frag->fr_address
2854 - first_frag->fr_fix) >> 4);
2855 }
2856 else
2857 /* We don't know what the final addresses will be. We try our
2858 best to estimate. */
2859 switch (first_frag->fr_type)
2860 {
2861 default:
2862 break;
2863
2864 case rs_space:
2865 as_fatal ("only constant space allocation is supported");
2866 break;
2867
2868 case rs_align:
2869 case rs_align_code:
2870 case rs_align_test:
2871 /* Take alignment into account. Assume the worst case
2872 before relaxation. */
2873 index += 3 * ((1 << first_frag->fr_offset) >> 4);
2874 break;
2875
2876 case rs_org:
2877 if (first_frag->fr_symbol)
2878 {
2879 as_fatal ("only constant offsets are supported");
2880 break;
2881 }
2882 case rs_fill:
2883 index += 3 * (first_frag->fr_offset >> 4);
2884 break;
2885 }
2886
2887 /* Add in the full size of the frag converted to instruction slots. */
2888 index += 3 * (first_frag->fr_fix >> 4);
2889 /* Subtract away the initial part before first_addr. */
2890 index -= (3 * ((first_addr >> 4) - (start_addr >> 4))
2891 + ((first_addr & 0x3) - (start_addr & 0x3)));
2892
2893 /* Move to the beginning of the next frag. */
2894 first_frag = first_frag->fr_next;
2895 first_addr = (unsigned long) &first_frag->fr_literal;
2896
2897 /* This can happen if there is section switching in the middle of a
2898 function, causing the frag chain for the function to be broken.
2899 It is too difficult to recover safely from this problem, so we just
2900 exit with an error. */
2901 if (first_frag == NULL)
2902 as_fatal ("Section switching in code is not supported.");
2903 }
2904
2905 /* Add in the used part of the last frag. */
2906 index += (3 * ((slot_addr >> 4) - (first_addr >> 4))
2907 + ((slot_addr & 0x3) - (first_addr & 0x3)));
2908 return index;
2909 }
2910
2911 /* Optimize unwind record directives. */
2912
2913 static unw_rec_list *
optimize_unw_records(list)2914 optimize_unw_records (list)
2915 unw_rec_list *list;
2916 {
2917 if (!list)
2918 return NULL;
2919
2920 /* If the only unwind record is ".prologue" or ".prologue" followed
2921 by ".body", then we can optimize the unwind directives away. */
2922 if (list->r.type == prologue
2923 && (list->next->r.type == endp
2924 || (list->next->r.type == body && list->next->next->r.type == endp)))
2925 return NULL;
2926
2927 return list;
2928 }
2929
2930 /* Given a complete record list, process any records which have
2931 unresolved fields, (ie length counts for a prologue). After
2932 this has been run, all necessary information should be available
2933 within each record to generate an image. */
2934
2935 static void
fixup_unw_records(list,before_relax)2936 fixup_unw_records (list, before_relax)
2937 unw_rec_list *list;
2938 int before_relax;
2939 {
2940 unw_rec_list *ptr, *region = 0;
2941 unsigned long first_addr = 0, rlen = 0, t;
2942 fragS *first_frag = 0;
2943
2944 for (ptr = list; ptr; ptr = ptr->next)
2945 {
2946 if (ptr->slot_number == SLOT_NUM_NOT_SET)
2947 as_bad (" Insn slot not set in unwind record.");
2948 t = slot_index (ptr->slot_number, ptr->slot_frag,
2949 first_addr, first_frag, before_relax);
2950 switch (ptr->r.type)
2951 {
2952 case prologue:
2953 case prologue_gr:
2954 case body:
2955 {
2956 unw_rec_list *last;
2957 int size;
2958 unsigned long last_addr = 0;
2959 fragS *last_frag = NULL;
2960
2961 first_addr = ptr->slot_number;
2962 first_frag = ptr->slot_frag;
2963 /* Find either the next body/prologue start, or the end of
2964 the function, and determine the size of the region. */
2965 for (last = ptr->next; last != NULL; last = last->next)
2966 if (last->r.type == prologue || last->r.type == prologue_gr
2967 || last->r.type == body || last->r.type == endp)
2968 {
2969 last_addr = last->slot_number;
2970 last_frag = last->slot_frag;
2971 break;
2972 }
2973 size = slot_index (last_addr, last_frag, first_addr, first_frag,
2974 before_relax);
2975 rlen = ptr->r.record.r.rlen = size;
2976 if (ptr->r.type == body)
2977 /* End of region. */
2978 region = 0;
2979 else
2980 region = ptr;
2981 break;
2982 }
2983 case epilogue:
2984 if (t < rlen)
2985 ptr->r.record.b.t = rlen - 1 - t;
2986 else
2987 /* This happens when a memory-stack-less procedure uses a
2988 ".restore sp" directive at the end of a region to pop
2989 the frame state. */
2990 ptr->r.record.b.t = 0;
2991 break;
2992
2993 case mem_stack_f:
2994 case mem_stack_v:
2995 case rp_when:
2996 case pfs_when:
2997 case preds_when:
2998 case unat_when:
2999 case lc_when:
3000 case fpsr_when:
3001 case priunat_when_gr:
3002 case priunat_when_mem:
3003 case bsp_when:
3004 case bspstore_when:
3005 case rnat_when:
3006 ptr->r.record.p.t = t;
3007 break;
3008
3009 case spill_reg:
3010 case spill_sprel:
3011 case spill_psprel:
3012 case spill_reg_p:
3013 case spill_sprel_p:
3014 case spill_psprel_p:
3015 ptr->r.record.x.t = t;
3016 break;
3017
3018 case frgr_mem:
3019 if (!region)
3020 {
3021 as_bad ("frgr_mem record before region record!");
3022 return;
3023 }
3024 region->r.record.r.mask.fr_mem |= ptr->r.record.p.frmask;
3025 region->r.record.r.mask.gr_mem |= ptr->r.record.p.grmask;
3026 set_imask (region, ptr->r.record.p.frmask, t, 1);
3027 set_imask (region, ptr->r.record.p.grmask, t, 2);
3028 break;
3029 case fr_mem:
3030 if (!region)
3031 {
3032 as_bad ("fr_mem record before region record!");
3033 return;
3034 }
3035 region->r.record.r.mask.fr_mem |= ptr->r.record.p.frmask;
3036 set_imask (region, ptr->r.record.p.frmask, t, 1);
3037 break;
3038 case gr_mem:
3039 if (!region)
3040 {
3041 as_bad ("gr_mem record before region record!");
3042 return;
3043 }
3044 region->r.record.r.mask.gr_mem |= ptr->r.record.p.grmask;
3045 set_imask (region, ptr->r.record.p.grmask, t, 2);
3046 break;
3047 case br_mem:
3048 if (!region)
3049 {
3050 as_bad ("br_mem record before region record!");
3051 return;
3052 }
3053 region->r.record.r.mask.br_mem |= ptr->r.record.p.brmask;
3054 set_imask (region, ptr->r.record.p.brmask, t, 3);
3055 break;
3056
3057 case gr_gr:
3058 if (!region)
3059 {
3060 as_bad ("gr_gr record before region record!");
3061 return;
3062 }
3063 set_imask (region, ptr->r.record.p.grmask, t, 2);
3064 break;
3065 case br_gr:
3066 if (!region)
3067 {
3068 as_bad ("br_gr record before region record!");
3069 return;
3070 }
3071 set_imask (region, ptr->r.record.p.brmask, t, 3);
3072 break;
3073
3074 default:
3075 break;
3076 }
3077 }
3078 }
3079
3080 /* Estimate the size of a frag before relaxing. We only have one type of frag
3081 to handle here, which is the unwind info frag. */
3082
3083 int
ia64_estimate_size_before_relax(fragS * frag,asection * segtype ATTRIBUTE_UNUSED)3084 ia64_estimate_size_before_relax (fragS *frag,
3085 asection *segtype ATTRIBUTE_UNUSED)
3086 {
3087 unw_rec_list *list;
3088 int len, size, pad;
3089
3090 /* ??? This code is identical to the first part of ia64_convert_frag. */
3091 list = (unw_rec_list *) frag->fr_opcode;
3092 fixup_unw_records (list, 0);
3093
3094 len = calc_record_size (list);
3095 /* pad to pointer-size boundary. */
3096 pad = len % md.pointer_size;
3097 if (pad != 0)
3098 len += md.pointer_size - pad;
3099 /* Add 8 for the header. */
3100 size = len + 8;
3101 /* Add a pointer for the personality offset. */
3102 if (frag->fr_offset)
3103 size += md.pointer_size;
3104
3105 /* fr_var carries the max_chars that we created the fragment with.
3106 We must, of course, have allocated enough memory earlier. */
3107 assert (frag->fr_var >= size);
3108
3109 return frag->fr_fix + size;
3110 }
3111
3112 /* This function converts a rs_machine_dependent variant frag into a
3113 normal fill frag with the unwind image from the the record list. */
3114 void
ia64_convert_frag(fragS * frag)3115 ia64_convert_frag (fragS *frag)
3116 {
3117 unw_rec_list *list;
3118 int len, size, pad;
3119 valueT flag_value;
3120
3121 /* ??? This code is identical to ia64_estimate_size_before_relax. */
3122 list = (unw_rec_list *) frag->fr_opcode;
3123 fixup_unw_records (list, 0);
3124
3125 len = calc_record_size (list);
3126 /* pad to pointer-size boundary. */
3127 pad = len % md.pointer_size;
3128 if (pad != 0)
3129 len += md.pointer_size - pad;
3130 /* Add 8 for the header. */
3131 size = len + 8;
3132 /* Add a pointer for the personality offset. */
3133 if (frag->fr_offset)
3134 size += md.pointer_size;
3135
3136 /* fr_var carries the max_chars that we created the fragment with.
3137 We must, of course, have allocated enough memory earlier. */
3138 assert (frag->fr_var >= size);
3139
3140 /* Initialize the header area. fr_offset is initialized with
3141 unwind.personality_routine. */
3142 if (frag->fr_offset)
3143 {
3144 if (md.flags & EF_IA_64_ABI64)
3145 flag_value = (bfd_vma) 3 << 32;
3146 else
3147 /* 32-bit unwind info block. */
3148 flag_value = (bfd_vma) 0x1003 << 32;
3149 }
3150 else
3151 flag_value = 0;
3152
3153 md_number_to_chars (frag->fr_literal,
3154 (((bfd_vma) 1 << 48) /* Version. */
3155 | flag_value /* U & E handler flags. */
3156 | (len / md.pointer_size)), /* Length. */
3157 8);
3158
3159 /* Skip the header. */
3160 vbyte_mem_ptr = frag->fr_literal + 8;
3161 process_unw_records (list, output_vbyte_mem);
3162
3163 /* Fill the padding bytes with zeros. */
3164 if (pad != 0)
3165 md_number_to_chars (frag->fr_literal + len + 8 - md.pointer_size + pad, 0,
3166 md.pointer_size - pad);
3167
3168 frag->fr_fix += size;
3169 frag->fr_type = rs_fill;
3170 frag->fr_var = 0;
3171 frag->fr_offset = 0;
3172 }
3173
3174 static int
parse_predicate_and_operand(e,qp,po)3175 parse_predicate_and_operand (e, qp, po)
3176 expressionS * e;
3177 unsigned * qp;
3178 const char * po;
3179 {
3180 int sep = parse_operand (e, ',');
3181
3182 *qp = e->X_add_number - REG_P;
3183 if (e->X_op != O_register || *qp > 63)
3184 {
3185 as_bad ("First operand to .%s must be a predicate", po);
3186 *qp = 0;
3187 }
3188 else if (*qp == 0)
3189 as_warn ("Pointless use of p0 as first operand to .%s", po);
3190 if (sep == ',')
3191 sep = parse_operand (e, ',');
3192 else
3193 e->X_op = O_absent;
3194 return sep;
3195 }
3196
3197 static void
convert_expr_to_ab_reg(e,ab,regp,po,n)3198 convert_expr_to_ab_reg (e, ab, regp, po, n)
3199 const expressionS *e;
3200 unsigned int *ab;
3201 unsigned int *regp;
3202 const char * po;
3203 int n;
3204 {
3205 unsigned int reg = e->X_add_number;
3206
3207 *ab = *regp = 0; /* Anything valid is good here. */
3208
3209 if (e->X_op != O_register)
3210 reg = REG_GR; /* Anything invalid is good here. */
3211
3212 if (reg >= (REG_GR + 4) && reg <= (REG_GR + 7))
3213 {
3214 *ab = 0;
3215 *regp = reg - REG_GR;
3216 }
3217 else if ((reg >= (REG_FR + 2) && reg <= (REG_FR + 5))
3218 || (reg >= (REG_FR + 16) && reg <= (REG_FR + 31)))
3219 {
3220 *ab = 1;
3221 *regp = reg - REG_FR;
3222 }
3223 else if (reg >= (REG_BR + 1) && reg <= (REG_BR + 5))
3224 {
3225 *ab = 2;
3226 *regp = reg - REG_BR;
3227 }
3228 else
3229 {
3230 *ab = 3;
3231 switch (reg)
3232 {
3233 case REG_PR: *regp = 0; break;
3234 case REG_PSP: *regp = 1; break;
3235 case REG_PRIUNAT: *regp = 2; break;
3236 case REG_BR + 0: *regp = 3; break;
3237 case REG_AR + AR_BSP: *regp = 4; break;
3238 case REG_AR + AR_BSPSTORE: *regp = 5; break;
3239 case REG_AR + AR_RNAT: *regp = 6; break;
3240 case REG_AR + AR_UNAT: *regp = 7; break;
3241 case REG_AR + AR_FPSR: *regp = 8; break;
3242 case REG_AR + AR_PFS: *regp = 9; break;
3243 case REG_AR + AR_LC: *regp = 10; break;
3244
3245 default:
3246 as_bad ("Operand %d to .%s must be a preserved register", n, po);
3247 break;
3248 }
3249 }
3250 }
3251
3252 static void
convert_expr_to_xy_reg(e,xy,regp,po,n)3253 convert_expr_to_xy_reg (e, xy, regp, po, n)
3254 const expressionS *e;
3255 unsigned int *xy;
3256 unsigned int *regp;
3257 const char * po;
3258 int n;
3259 {
3260 unsigned int reg = e->X_add_number;
3261
3262 *xy = *regp = 0; /* Anything valid is good here. */
3263
3264 if (e->X_op != O_register)
3265 reg = REG_GR; /* Anything invalid is good here. */
3266
3267 if (reg >= (REG_GR + 1) && reg <= (REG_GR + 127))
3268 {
3269 *xy = 0;
3270 *regp = reg - REG_GR;
3271 }
3272 else if (reg >= (REG_FR + 2) && reg <= (REG_FR + 127))
3273 {
3274 *xy = 1;
3275 *regp = reg - REG_FR;
3276 }
3277 else if (reg >= REG_BR && reg <= (REG_BR + 7))
3278 {
3279 *xy = 2;
3280 *regp = reg - REG_BR;
3281 }
3282 else
3283 as_bad ("Operand %d to .%s must be a writable register", n, po);
3284 }
3285
3286 static void
dot_align(int arg)3287 dot_align (int arg)
3288 {
3289 /* The current frag is an alignment frag. */
3290 align_frag = frag_now;
3291 s_align_bytes (arg);
3292 }
3293
3294 static void
dot_radix(dummy)3295 dot_radix (dummy)
3296 int dummy ATTRIBUTE_UNUSED;
3297 {
3298 char *radix;
3299 int ch;
3300
3301 SKIP_WHITESPACE ();
3302
3303 if (is_it_end_of_statement ())
3304 return;
3305 radix = input_line_pointer;
3306 ch = get_symbol_end ();
3307 ia64_canonicalize_symbol_name (radix);
3308 if (strcasecmp (radix, "C"))
3309 as_bad ("Radix `%s' unsupported or invalid", radix);
3310 *input_line_pointer = ch;
3311 demand_empty_rest_of_line ();
3312 }
3313
3314 /* Helper function for .loc directives. If the assembler is not generating
3315 line number info, then we need to remember which instructions have a .loc
3316 directive, and only call dwarf2_gen_line_info for those instructions. */
3317
3318 static void
dot_loc(int x)3319 dot_loc (int x)
3320 {
3321 CURR_SLOT.loc_directive_seen = 1;
3322 dwarf2_directive_loc (x);
3323 }
3324
3325 /* .sbss, .bss etc. are macros that expand into ".section SECNAME". */
3326 static void
dot_special_section(which)3327 dot_special_section (which)
3328 int which;
3329 {
3330 set_section ((char *) special_section_name[which]);
3331 }
3332
3333 /* Return -1 for warning and 0 for error. */
3334
3335 static int
unwind_diagnostic(const char * region,const char * directive)3336 unwind_diagnostic (const char * region, const char *directive)
3337 {
3338 if (md.unwind_check == unwind_check_warning)
3339 {
3340 as_warn (".%s outside of %s", directive, region);
3341 return -1;
3342 }
3343 else
3344 {
3345 as_bad (".%s outside of %s", directive, region);
3346 ignore_rest_of_line ();
3347 return 0;
3348 }
3349 }
3350
3351 /* Return 1 if a directive is in a procedure, -1 if a directive isn't in
3352 a procedure but the unwind directive check is set to warning, 0 if
3353 a directive isn't in a procedure and the unwind directive check is set
3354 to error. */
3355
3356 static int
in_procedure(const char * directive)3357 in_procedure (const char *directive)
3358 {
3359 if (unwind.proc_pending.sym
3360 && (!unwind.saved_text_seg || strcmp (directive, "endp") == 0))
3361 return 1;
3362 return unwind_diagnostic ("procedure", directive);
3363 }
3364
3365 /* Return 1 if a directive is in a prologue, -1 if a directive isn't in
3366 a prologue but the unwind directive check is set to warning, 0 if
3367 a directive isn't in a prologue and the unwind directive check is set
3368 to error. */
3369
3370 static int
in_prologue(const char * directive)3371 in_prologue (const char *directive)
3372 {
3373 int in = in_procedure (directive);
3374
3375 if (in > 0 && !unwind.prologue)
3376 in = unwind_diagnostic ("prologue", directive);
3377 check_pending_save ();
3378 return in;
3379 }
3380
3381 /* Return 1 if a directive is in a body, -1 if a directive isn't in
3382 a body but the unwind directive check is set to warning, 0 if
3383 a directive isn't in a body and the unwind directive check is set
3384 to error. */
3385
3386 static int
in_body(const char * directive)3387 in_body (const char *directive)
3388 {
3389 int in = in_procedure (directive);
3390
3391 if (in > 0 && !unwind.body)
3392 in = unwind_diagnostic ("body region", directive);
3393 return in;
3394 }
3395
3396 static void
add_unwind_entry(ptr,sep)3397 add_unwind_entry (ptr, sep)
3398 unw_rec_list *ptr;
3399 int sep;
3400 {
3401 if (ptr)
3402 {
3403 if (unwind.tail)
3404 unwind.tail->next = ptr;
3405 else
3406 unwind.list = ptr;
3407 unwind.tail = ptr;
3408
3409 /* The current entry can in fact be a chain of unwind entries. */
3410 if (unwind.current_entry == NULL)
3411 unwind.current_entry = ptr;
3412 }
3413
3414 /* The current entry can in fact be a chain of unwind entries. */
3415 if (unwind.current_entry == NULL)
3416 unwind.current_entry = ptr;
3417
3418 if (sep == ',')
3419 {
3420 /* Parse a tag permitted for the current directive. */
3421 int ch;
3422
3423 SKIP_WHITESPACE ();
3424 ch = get_symbol_end ();
3425 /* FIXME: For now, just issue a warning that this isn't implemented. */
3426 {
3427 static int warned;
3428
3429 if (!warned)
3430 {
3431 warned = 1;
3432 as_warn ("Tags on unwind pseudo-ops aren't supported, yet");
3433 }
3434 }
3435 *input_line_pointer = ch;
3436 }
3437 if (sep != NOT_A_CHAR)
3438 demand_empty_rest_of_line ();
3439 }
3440
3441 static void
dot_fframe(dummy)3442 dot_fframe (dummy)
3443 int dummy ATTRIBUTE_UNUSED;
3444 {
3445 expressionS e;
3446 int sep;
3447
3448 if (!in_prologue ("fframe"))
3449 return;
3450
3451 sep = parse_operand (&e, ',');
3452
3453 if (e.X_op != O_constant)
3454 {
3455 as_bad ("First operand to .fframe must be a constant");
3456 e.X_add_number = 0;
3457 }
3458 add_unwind_entry (output_mem_stack_f (e.X_add_number), sep);
3459 }
3460
3461 static void
dot_vframe(dummy)3462 dot_vframe (dummy)
3463 int dummy ATTRIBUTE_UNUSED;
3464 {
3465 expressionS e;
3466 unsigned reg;
3467 int sep;
3468
3469 if (!in_prologue ("vframe"))
3470 return;
3471
3472 sep = parse_operand (&e, ',');
3473 reg = e.X_add_number - REG_GR;
3474 if (e.X_op != O_register || reg > 127)
3475 {
3476 as_bad ("First operand to .vframe must be a general register");
3477 reg = 0;
3478 }
3479 add_unwind_entry (output_mem_stack_v (), sep);
3480 if (! (unwind.prologue_mask & 2))
3481 add_unwind_entry (output_psp_gr (reg), NOT_A_CHAR);
3482 else if (reg != unwind.prologue_gr
3483 + (unsigned) popcount (unwind.prologue_mask & (-2 << 1)))
3484 as_warn ("Operand of .vframe contradicts .prologue");
3485 }
3486
3487 static void
dot_vframesp(psp)3488 dot_vframesp (psp)
3489 int psp;
3490 {
3491 expressionS e;
3492 int sep;
3493
3494 if (psp)
3495 as_warn (".vframepsp is meaningless, assuming .vframesp was meant");
3496
3497 if (!in_prologue ("vframesp"))
3498 return;
3499
3500 sep = parse_operand (&e, ',');
3501 if (e.X_op != O_constant)
3502 {
3503 as_bad ("Operand to .vframesp must be a constant (sp-relative offset)");
3504 e.X_add_number = 0;
3505 }
3506 add_unwind_entry (output_mem_stack_v (), sep);
3507 add_unwind_entry (output_psp_sprel (e.X_add_number), NOT_A_CHAR);
3508 }
3509
3510 static void
dot_save(dummy)3511 dot_save (dummy)
3512 int dummy ATTRIBUTE_UNUSED;
3513 {
3514 expressionS e1, e2;
3515 unsigned reg1, reg2;
3516 int sep;
3517
3518 if (!in_prologue ("save"))
3519 return;
3520
3521 sep = parse_operand (&e1, ',');
3522 if (sep == ',')
3523 sep = parse_operand (&e2, ',');
3524 else
3525 e2.X_op = O_absent;
3526
3527 reg1 = e1.X_add_number;
3528 /* Make sure its a valid ar.xxx reg, OR its br0, aka 'rp'. */
3529 if (e1.X_op != O_register)
3530 {
3531 as_bad ("First operand to .save not a register");
3532 reg1 = REG_PR; /* Anything valid is good here. */
3533 }
3534 reg2 = e2.X_add_number - REG_GR;
3535 if (e2.X_op != O_register || reg2 > 127)
3536 {
3537 as_bad ("Second operand to .save not a valid register");
3538 reg2 = 0;
3539 }
3540 switch (reg1)
3541 {
3542 case REG_AR + AR_BSP:
3543 add_unwind_entry (output_bsp_when (), sep);
3544 add_unwind_entry (output_bsp_gr (reg2), NOT_A_CHAR);
3545 break;
3546 case REG_AR + AR_BSPSTORE:
3547 add_unwind_entry (output_bspstore_when (), sep);
3548 add_unwind_entry (output_bspstore_gr (reg2), NOT_A_CHAR);
3549 break;
3550 case REG_AR + AR_RNAT:
3551 add_unwind_entry (output_rnat_when (), sep);
3552 add_unwind_entry (output_rnat_gr (reg2), NOT_A_CHAR);
3553 break;
3554 case REG_AR + AR_UNAT:
3555 add_unwind_entry (output_unat_when (), sep);
3556 add_unwind_entry (output_unat_gr (reg2), NOT_A_CHAR);
3557 break;
3558 case REG_AR + AR_FPSR:
3559 add_unwind_entry (output_fpsr_when (), sep);
3560 add_unwind_entry (output_fpsr_gr (reg2), NOT_A_CHAR);
3561 break;
3562 case REG_AR + AR_PFS:
3563 add_unwind_entry (output_pfs_when (), sep);
3564 if (! (unwind.prologue_mask & 4))
3565 add_unwind_entry (output_pfs_gr (reg2), NOT_A_CHAR);
3566 else if (reg2 != unwind.prologue_gr
3567 + (unsigned) popcount (unwind.prologue_mask & (-4 << 1)))
3568 as_warn ("Second operand of .save contradicts .prologue");
3569 break;
3570 case REG_AR + AR_LC:
3571 add_unwind_entry (output_lc_when (), sep);
3572 add_unwind_entry (output_lc_gr (reg2), NOT_A_CHAR);
3573 break;
3574 case REG_BR:
3575 add_unwind_entry (output_rp_when (), sep);
3576 if (! (unwind.prologue_mask & 8))
3577 add_unwind_entry (output_rp_gr (reg2), NOT_A_CHAR);
3578 else if (reg2 != unwind.prologue_gr)
3579 as_warn ("Second operand of .save contradicts .prologue");
3580 break;
3581 case REG_PR:
3582 add_unwind_entry (output_preds_when (), sep);
3583 if (! (unwind.prologue_mask & 1))
3584 add_unwind_entry (output_preds_gr (reg2), NOT_A_CHAR);
3585 else if (reg2 != unwind.prologue_gr
3586 + (unsigned) popcount (unwind.prologue_mask & (-1 << 1)))
3587 as_warn ("Second operand of .save contradicts .prologue");
3588 break;
3589 case REG_PRIUNAT:
3590 add_unwind_entry (output_priunat_when_gr (), sep);
3591 add_unwind_entry (output_priunat_gr (reg2), NOT_A_CHAR);
3592 break;
3593 default:
3594 as_bad ("First operand to .save not a valid register");
3595 add_unwind_entry (NULL, sep);
3596 break;
3597 }
3598 }
3599
3600 static void
dot_restore(dummy)3601 dot_restore (dummy)
3602 int dummy ATTRIBUTE_UNUSED;
3603 {
3604 expressionS e1;
3605 unsigned long ecount; /* # of _additional_ regions to pop */
3606 int sep;
3607
3608 if (!in_body ("restore"))
3609 return;
3610
3611 sep = parse_operand (&e1, ',');
3612 if (e1.X_op != O_register || e1.X_add_number != REG_GR + 12)
3613 as_bad ("First operand to .restore must be stack pointer (sp)");
3614
3615 if (sep == ',')
3616 {
3617 expressionS e2;
3618
3619 sep = parse_operand (&e2, ',');
3620 if (e2.X_op != O_constant || e2.X_add_number < 0)
3621 {
3622 as_bad ("Second operand to .restore must be a constant >= 0");
3623 e2.X_add_number = 0;
3624 }
3625 ecount = e2.X_add_number;
3626 }
3627 else
3628 ecount = unwind.prologue_count - 1;
3629
3630 if (ecount >= unwind.prologue_count)
3631 {
3632 as_bad ("Epilogue count of %lu exceeds number of nested prologues (%u)",
3633 ecount + 1, unwind.prologue_count);
3634 ecount = 0;
3635 }
3636
3637 add_unwind_entry (output_epilogue (ecount), sep);
3638
3639 if (ecount < unwind.prologue_count)
3640 unwind.prologue_count -= ecount + 1;
3641 else
3642 unwind.prologue_count = 0;
3643 }
3644
3645 static void
dot_restorereg(pred)3646 dot_restorereg (pred)
3647 int pred;
3648 {
3649 unsigned int qp, ab, reg;
3650 expressionS e;
3651 int sep;
3652 const char * const po = pred ? "restorereg.p" : "restorereg";
3653
3654 if (!in_procedure (po))
3655 return;
3656
3657 if (pred)
3658 sep = parse_predicate_and_operand (&e, &qp, po);
3659 else
3660 {
3661 sep = parse_operand (&e, ',');
3662 qp = 0;
3663 }
3664 convert_expr_to_ab_reg (&e, &ab, ®, po, 1 + pred);
3665
3666 add_unwind_entry (output_spill_reg (ab, reg, 0, 0, qp), sep);
3667 }
3668
3669 static char *special_linkonce_name[] =
3670 {
3671 ".gnu.linkonce.ia64unw.", ".gnu.linkonce.ia64unwi."
3672 };
3673
3674 static void
start_unwind_section(const segT text_seg,int sec_index)3675 start_unwind_section (const segT text_seg, int sec_index)
3676 {
3677 /*
3678 Use a slightly ugly scheme to derive the unwind section names from
3679 the text section name:
3680
3681 text sect. unwind table sect.
3682 name: name: comments:
3683 ---------- ----------------- --------------------------------
3684 .text .IA_64.unwind
3685 .text.foo .IA_64.unwind.text.foo
3686 .foo .IA_64.unwind.foo
3687 .gnu.linkonce.t.foo
3688 .gnu.linkonce.ia64unw.foo
3689 _info .IA_64.unwind_info gas issues error message (ditto)
3690 _infoFOO .IA_64.unwind_infoFOO gas issues error message (ditto)
3691
3692 This mapping is done so that:
3693
3694 (a) An object file with unwind info only in .text will use
3695 unwind section names .IA_64.unwind and .IA_64.unwind_info.
3696 This follows the letter of the ABI and also ensures backwards
3697 compatibility with older toolchains.
3698
3699 (b) An object file with unwind info in multiple text sections
3700 will use separate unwind sections for each text section.
3701 This allows us to properly set the "sh_info" and "sh_link"
3702 fields in SHT_IA_64_UNWIND as required by the ABI and also
3703 lets GNU ld support programs with multiple segments
3704 containing unwind info (as might be the case for certain
3705 embedded applications).
3706
3707 (c) An error is issued if there would be a name clash.
3708 */
3709
3710 const char *text_name, *sec_text_name;
3711 char *sec_name;
3712 const char *prefix = special_section_name [sec_index];
3713 const char *suffix;
3714 size_t prefix_len, suffix_len, sec_name_len;
3715
3716 sec_text_name = segment_name (text_seg);
3717 text_name = sec_text_name;
3718 if (strncmp (text_name, "_info", 5) == 0)
3719 {
3720 as_bad ("Illegal section name `%s' (causes unwind section name clash)",
3721 text_name);
3722 ignore_rest_of_line ();
3723 return;
3724 }
3725 if (strcmp (text_name, ".text") == 0)
3726 text_name = "";
3727
3728 /* Build the unwind section name by appending the (possibly stripped)
3729 text section name to the unwind prefix. */
3730 suffix = text_name;
3731 if (strncmp (text_name, ".gnu.linkonce.t.",
3732 sizeof (".gnu.linkonce.t.") - 1) == 0)
3733 {
3734 prefix = special_linkonce_name [sec_index - SPECIAL_SECTION_UNWIND];
3735 suffix += sizeof (".gnu.linkonce.t.") - 1;
3736 }
3737
3738 prefix_len = strlen (prefix);
3739 suffix_len = strlen (suffix);
3740 sec_name_len = prefix_len + suffix_len;
3741 sec_name = alloca (sec_name_len + 1);
3742 memcpy (sec_name, prefix, prefix_len);
3743 memcpy (sec_name + prefix_len, suffix, suffix_len);
3744 sec_name [sec_name_len] = '\0';
3745
3746 /* Handle COMDAT group. */
3747 if ((text_seg->flags & SEC_LINK_ONCE) != 0
3748 && (elf_section_flags (text_seg) & SHF_GROUP) != 0)
3749 {
3750 char *section;
3751 size_t len, group_name_len;
3752 const char *group_name = elf_group_name (text_seg);
3753
3754 if (group_name == NULL)
3755 {
3756 as_bad ("Group section `%s' has no group signature",
3757 sec_text_name);
3758 ignore_rest_of_line ();
3759 return;
3760 }
3761 /* We have to construct a fake section directive. */
3762 group_name_len = strlen (group_name);
3763 len = (sec_name_len
3764 + 16 /* ,"aG",@progbits, */
3765 + group_name_len /* ,group_name */
3766 + 7); /* ,comdat */
3767
3768 section = alloca (len + 1);
3769 memcpy (section, sec_name, sec_name_len);
3770 memcpy (section + sec_name_len, ",\"aG\",@progbits,", 16);
3771 memcpy (section + sec_name_len + 16, group_name, group_name_len);
3772 memcpy (section + len - 7, ",comdat", 7);
3773 section [len] = '\0';
3774 set_section (section);
3775 }
3776 else
3777 {
3778 set_section (sec_name);
3779 bfd_set_section_flags (stdoutput, now_seg,
3780 SEC_LOAD | SEC_ALLOC | SEC_READONLY);
3781 }
3782
3783 elf_linked_to_section (now_seg) = text_seg;
3784 }
3785
3786 static void
generate_unwind_image(const segT text_seg)3787 generate_unwind_image (const segT text_seg)
3788 {
3789 int size, pad;
3790 unw_rec_list *list;
3791
3792 /* Mark the end of the unwind info, so that we can compute the size of the
3793 last unwind region. */
3794 add_unwind_entry (output_endp (), NOT_A_CHAR);
3795
3796 /* Force out pending instructions, to make sure all unwind records have
3797 a valid slot_number field. */
3798 ia64_flush_insns ();
3799
3800 /* Generate the unwind record. */
3801 list = optimize_unw_records (unwind.list);
3802 fixup_unw_records (list, 1);
3803 size = calc_record_size (list);
3804
3805 if (size > 0 || unwind.force_unwind_entry)
3806 {
3807 unwind.force_unwind_entry = 0;
3808 /* pad to pointer-size boundary. */
3809 pad = size % md.pointer_size;
3810 if (pad != 0)
3811 size += md.pointer_size - pad;
3812 /* Add 8 for the header. */
3813 size += 8;
3814 /* Add a pointer for the personality offset. */
3815 if (unwind.personality_routine)
3816 size += md.pointer_size;
3817 }
3818
3819 /* If there are unwind records, switch sections, and output the info. */
3820 if (size != 0)
3821 {
3822 expressionS exp;
3823 bfd_reloc_code_real_type reloc;
3824
3825 start_unwind_section (text_seg, SPECIAL_SECTION_UNWIND_INFO);
3826
3827 /* Make sure the section has 4 byte alignment for ILP32 and
3828 8 byte alignment for LP64. */
3829 frag_align (md.pointer_size_shift, 0, 0);
3830 record_alignment (now_seg, md.pointer_size_shift);
3831
3832 /* Set expression which points to start of unwind descriptor area. */
3833 unwind.info = expr_build_dot ();
3834
3835 frag_var (rs_machine_dependent, size, size, 0, 0,
3836 (offsetT) (long) unwind.personality_routine,
3837 (char *) list);
3838
3839 /* Add the personality address to the image. */
3840 if (unwind.personality_routine != 0)
3841 {
3842 exp.X_op = O_symbol;
3843 exp.X_add_symbol = unwind.personality_routine;
3844 exp.X_add_number = 0;
3845
3846 if (md.flags & EF_IA_64_BE)
3847 {
3848 if (md.flags & EF_IA_64_ABI64)
3849 reloc = BFD_RELOC_IA64_LTOFF_FPTR64MSB;
3850 else
3851 reloc = BFD_RELOC_IA64_LTOFF_FPTR32MSB;
3852 }
3853 else
3854 {
3855 if (md.flags & EF_IA_64_ABI64)
3856 reloc = BFD_RELOC_IA64_LTOFF_FPTR64LSB;
3857 else
3858 reloc = BFD_RELOC_IA64_LTOFF_FPTR32LSB;
3859 }
3860
3861 fix_new_exp (frag_now, frag_now_fix () - md.pointer_size,
3862 md.pointer_size, &exp, 0, reloc);
3863 unwind.personality_routine = 0;
3864 }
3865 }
3866
3867 free_saved_prologue_counts ();
3868 unwind.list = unwind.tail = unwind.current_entry = NULL;
3869 }
3870
3871 static void
dot_handlerdata(dummy)3872 dot_handlerdata (dummy)
3873 int dummy ATTRIBUTE_UNUSED;
3874 {
3875 if (!in_procedure ("handlerdata"))
3876 return;
3877 unwind.force_unwind_entry = 1;
3878
3879 /* Remember which segment we're in so we can switch back after .endp */
3880 unwind.saved_text_seg = now_seg;
3881 unwind.saved_text_subseg = now_subseg;
3882
3883 /* Generate unwind info into unwind-info section and then leave that
3884 section as the currently active one so dataXX directives go into
3885 the language specific data area of the unwind info block. */
3886 generate_unwind_image (now_seg);
3887 demand_empty_rest_of_line ();
3888 }
3889
3890 static void
dot_unwentry(dummy)3891 dot_unwentry (dummy)
3892 int dummy ATTRIBUTE_UNUSED;
3893 {
3894 if (!in_procedure ("unwentry"))
3895 return;
3896 unwind.force_unwind_entry = 1;
3897 demand_empty_rest_of_line ();
3898 }
3899
3900 static void
dot_altrp(dummy)3901 dot_altrp (dummy)
3902 int dummy ATTRIBUTE_UNUSED;
3903 {
3904 expressionS e;
3905 unsigned reg;
3906
3907 if (!in_prologue ("altrp"))
3908 return;
3909
3910 parse_operand (&e, 0);
3911 reg = e.X_add_number - REG_BR;
3912 if (e.X_op != O_register || reg > 7)
3913 {
3914 as_bad ("First operand to .altrp not a valid branch register");
3915 reg = 0;
3916 }
3917 add_unwind_entry (output_rp_br (reg), 0);
3918 }
3919
3920 static void
dot_savemem(psprel)3921 dot_savemem (psprel)
3922 int psprel;
3923 {
3924 expressionS e1, e2;
3925 int sep;
3926 int reg1, val;
3927 const char * const po = psprel ? "savepsp" : "savesp";
3928
3929 if (!in_prologue (po))
3930 return;
3931
3932 sep = parse_operand (&e1, ',');
3933 if (sep == ',')
3934 sep = parse_operand (&e2, ',');
3935 else
3936 e2.X_op = O_absent;
3937
3938 reg1 = e1.X_add_number;
3939 val = e2.X_add_number;
3940
3941 /* Make sure its a valid ar.xxx reg, OR its br0, aka 'rp'. */
3942 if (e1.X_op != O_register)
3943 {
3944 as_bad ("First operand to .%s not a register", po);
3945 reg1 = REG_PR; /* Anything valid is good here. */
3946 }
3947 if (e2.X_op != O_constant)
3948 {
3949 as_bad ("Second operand to .%s not a constant", po);
3950 val = 0;
3951 }
3952
3953 switch (reg1)
3954 {
3955 case REG_AR + AR_BSP:
3956 add_unwind_entry (output_bsp_when (), sep);
3957 add_unwind_entry ((psprel
3958 ? output_bsp_psprel
3959 : output_bsp_sprel) (val), NOT_A_CHAR);
3960 break;
3961 case REG_AR + AR_BSPSTORE:
3962 add_unwind_entry (output_bspstore_when (), sep);
3963 add_unwind_entry ((psprel
3964 ? output_bspstore_psprel
3965 : output_bspstore_sprel) (val), NOT_A_CHAR);
3966 break;
3967 case REG_AR + AR_RNAT:
3968 add_unwind_entry (output_rnat_when (), sep);
3969 add_unwind_entry ((psprel
3970 ? output_rnat_psprel
3971 : output_rnat_sprel) (val), NOT_A_CHAR);
3972 break;
3973 case REG_AR + AR_UNAT:
3974 add_unwind_entry (output_unat_when (), sep);
3975 add_unwind_entry ((psprel
3976 ? output_unat_psprel
3977 : output_unat_sprel) (val), NOT_A_CHAR);
3978 break;
3979 case REG_AR + AR_FPSR:
3980 add_unwind_entry (output_fpsr_when (), sep);
3981 add_unwind_entry ((psprel
3982 ? output_fpsr_psprel
3983 : output_fpsr_sprel) (val), NOT_A_CHAR);
3984 break;
3985 case REG_AR + AR_PFS:
3986 add_unwind_entry (output_pfs_when (), sep);
3987 add_unwind_entry ((psprel
3988 ? output_pfs_psprel
3989 : output_pfs_sprel) (val), NOT_A_CHAR);
3990 break;
3991 case REG_AR + AR_LC:
3992 add_unwind_entry (output_lc_when (), sep);
3993 add_unwind_entry ((psprel
3994 ? output_lc_psprel
3995 : output_lc_sprel) (val), NOT_A_CHAR);
3996 break;
3997 case REG_BR:
3998 add_unwind_entry (output_rp_when (), sep);
3999 add_unwind_entry ((psprel
4000 ? output_rp_psprel
4001 : output_rp_sprel) (val), NOT_A_CHAR);
4002 break;
4003 case REG_PR:
4004 add_unwind_entry (output_preds_when (), sep);
4005 add_unwind_entry ((psprel
4006 ? output_preds_psprel
4007 : output_preds_sprel) (val), NOT_A_CHAR);
4008 break;
4009 case REG_PRIUNAT:
4010 add_unwind_entry (output_priunat_when_mem (), sep);
4011 add_unwind_entry ((psprel
4012 ? output_priunat_psprel
4013 : output_priunat_sprel) (val), NOT_A_CHAR);
4014 break;
4015 default:
4016 as_bad ("First operand to .%s not a valid register", po);
4017 add_unwind_entry (NULL, sep);
4018 break;
4019 }
4020 }
4021
4022 static void
dot_saveg(dummy)4023 dot_saveg (dummy)
4024 int dummy ATTRIBUTE_UNUSED;
4025 {
4026 expressionS e;
4027 unsigned grmask;
4028 int sep;
4029
4030 if (!in_prologue ("save.g"))
4031 return;
4032
4033 sep = parse_operand (&e, ',');
4034
4035 grmask = e.X_add_number;
4036 if (e.X_op != O_constant
4037 || e.X_add_number <= 0
4038 || e.X_add_number > 0xf)
4039 {
4040 as_bad ("First operand to .save.g must be a positive 4-bit constant");
4041 grmask = 0;
4042 }
4043
4044 if (sep == ',')
4045 {
4046 unsigned reg;
4047 int n = popcount (grmask);
4048
4049 parse_operand (&e, 0);
4050 reg = e.X_add_number - REG_GR;
4051 if (e.X_op != O_register || reg > 127)
4052 {
4053 as_bad ("Second operand to .save.g must be a general register");
4054 reg = 0;
4055 }
4056 else if (reg > 128U - n)
4057 {
4058 as_bad ("Second operand to .save.g must be the first of %d general registers", n);
4059 reg = 0;
4060 }
4061 add_unwind_entry (output_gr_gr (grmask, reg), 0);
4062 }
4063 else
4064 add_unwind_entry (output_gr_mem (grmask), 0);
4065 }
4066
4067 static void
dot_savef(dummy)4068 dot_savef (dummy)
4069 int dummy ATTRIBUTE_UNUSED;
4070 {
4071 expressionS e;
4072
4073 if (!in_prologue ("save.f"))
4074 return;
4075
4076 parse_operand (&e, 0);
4077
4078 if (e.X_op != O_constant
4079 || e.X_add_number <= 0
4080 || e.X_add_number > 0xfffff)
4081 {
4082 as_bad ("Operand to .save.f must be a positive 20-bit constant");
4083 e.X_add_number = 0;
4084 }
4085 add_unwind_entry (output_fr_mem (e.X_add_number), 0);
4086 }
4087
4088 static void
dot_saveb(dummy)4089 dot_saveb (dummy)
4090 int dummy ATTRIBUTE_UNUSED;
4091 {
4092 expressionS e;
4093 unsigned brmask;
4094 int sep;
4095
4096 if (!in_prologue ("save.b"))
4097 return;
4098
4099 sep = parse_operand (&e, ',');
4100
4101 brmask = e.X_add_number;
4102 if (e.X_op != O_constant
4103 || e.X_add_number <= 0
4104 || e.X_add_number > 0x1f)
4105 {
4106 as_bad ("First operand to .save.b must be a positive 5-bit constant");
4107 brmask = 0;
4108 }
4109
4110 if (sep == ',')
4111 {
4112 unsigned reg;
4113 int n = popcount (brmask);
4114
4115 parse_operand (&e, 0);
4116 reg = e.X_add_number - REG_GR;
4117 if (e.X_op != O_register || reg > 127)
4118 {
4119 as_bad ("Second operand to .save.b must be a general register");
4120 reg = 0;
4121 }
4122 else if (reg > 128U - n)
4123 {
4124 as_bad ("Second operand to .save.b must be the first of %d general registers", n);
4125 reg = 0;
4126 }
4127 add_unwind_entry (output_br_gr (brmask, reg), 0);
4128 }
4129 else
4130 add_unwind_entry (output_br_mem (brmask), 0);
4131 }
4132
4133 static void
dot_savegf(dummy)4134 dot_savegf (dummy)
4135 int dummy ATTRIBUTE_UNUSED;
4136 {
4137 expressionS e1, e2;
4138
4139 if (!in_prologue ("save.gf"))
4140 return;
4141
4142 if (parse_operand (&e1, ',') == ',')
4143 parse_operand (&e2, 0);
4144 else
4145 e2.X_op = O_absent;
4146
4147 if (e1.X_op != O_constant
4148 || e1.X_add_number < 0
4149 || e1.X_add_number > 0xf)
4150 {
4151 as_bad ("First operand to .save.gf must be a non-negative 4-bit constant");
4152 e1.X_op = O_absent;
4153 e1.X_add_number = 0;
4154 }
4155 if (e2.X_op != O_constant
4156 || e2.X_add_number < 0
4157 || e2.X_add_number > 0xfffff)
4158 {
4159 as_bad ("Second operand to .save.gf must be a non-negative 20-bit constant");
4160 e2.X_op = O_absent;
4161 e2.X_add_number = 0;
4162 }
4163 if (e1.X_op == O_constant
4164 && e2.X_op == O_constant
4165 && e1.X_add_number == 0
4166 && e2.X_add_number == 0)
4167 as_bad ("Operands to .save.gf may not be both zero");
4168
4169 add_unwind_entry (output_frgr_mem (e1.X_add_number, e2.X_add_number), 0);
4170 }
4171
4172 static void
dot_spill(dummy)4173 dot_spill (dummy)
4174 int dummy ATTRIBUTE_UNUSED;
4175 {
4176 expressionS e;
4177
4178 if (!in_prologue ("spill"))
4179 return;
4180
4181 parse_operand (&e, 0);
4182
4183 if (e.X_op != O_constant)
4184 {
4185 as_bad ("Operand to .spill must be a constant");
4186 e.X_add_number = 0;
4187 }
4188 add_unwind_entry (output_spill_base (e.X_add_number), 0);
4189 }
4190
4191 static void
dot_spillreg(pred)4192 dot_spillreg (pred)
4193 int pred;
4194 {
4195 int sep;
4196 unsigned int qp, ab, xy, reg, treg;
4197 expressionS e;
4198 const char * const po = pred ? "spillreg.p" : "spillreg";
4199
4200 if (!in_procedure (po))
4201 return;
4202
4203 if (pred)
4204 sep = parse_predicate_and_operand (&e, &qp, po);
4205 else
4206 {
4207 sep = parse_operand (&e, ',');
4208 qp = 0;
4209 }
4210 convert_expr_to_ab_reg (&e, &ab, ®, po, 1 + pred);
4211
4212 if (sep == ',')
4213 sep = parse_operand (&e, ',');
4214 else
4215 e.X_op = O_absent;
4216 convert_expr_to_xy_reg (&e, &xy, &treg, po, 2 + pred);
4217
4218 add_unwind_entry (output_spill_reg (ab, reg, treg, xy, qp), sep);
4219 }
4220
4221 static void
dot_spillmem(psprel)4222 dot_spillmem (psprel)
4223 int psprel;
4224 {
4225 expressionS e;
4226 int pred = (psprel < 0), sep;
4227 unsigned int qp, ab, reg;
4228 const char * po;
4229
4230 if (pred)
4231 {
4232 psprel = ~psprel;
4233 po = psprel ? "spillpsp.p" : "spillsp.p";
4234 }
4235 else
4236 po = psprel ? "spillpsp" : "spillsp";
4237
4238 if (!in_procedure (po))
4239 return;
4240
4241 if (pred)
4242 sep = parse_predicate_and_operand (&e, &qp, po);
4243 else
4244 {
4245 sep = parse_operand (&e, ',');
4246 qp = 0;
4247 }
4248 convert_expr_to_ab_reg (&e, &ab, ®, po, 1 + pred);
4249
4250 if (sep == ',')
4251 sep = parse_operand (&e, ',');
4252 else
4253 e.X_op = O_absent;
4254 if (e.X_op != O_constant)
4255 {
4256 as_bad ("Operand %d to .%s must be a constant", 2 + pred, po);
4257 e.X_add_number = 0;
4258 }
4259
4260 if (psprel)
4261 add_unwind_entry (output_spill_psprel (ab, reg, e.X_add_number, qp), sep);
4262 else
4263 add_unwind_entry (output_spill_sprel (ab, reg, e.X_add_number, qp), sep);
4264 }
4265
4266 static unsigned int
get_saved_prologue_count(lbl)4267 get_saved_prologue_count (lbl)
4268 unsigned long lbl;
4269 {
4270 label_prologue_count *lpc = unwind.saved_prologue_counts;
4271
4272 while (lpc != NULL && lpc->label_number != lbl)
4273 lpc = lpc->next;
4274
4275 if (lpc != NULL)
4276 return lpc->prologue_count;
4277
4278 as_bad ("Missing .label_state %ld", lbl);
4279 return 1;
4280 }
4281
4282 static void
save_prologue_count(lbl,count)4283 save_prologue_count (lbl, count)
4284 unsigned long lbl;
4285 unsigned int count;
4286 {
4287 label_prologue_count *lpc = unwind.saved_prologue_counts;
4288
4289 while (lpc != NULL && lpc->label_number != lbl)
4290 lpc = lpc->next;
4291
4292 if (lpc != NULL)
4293 lpc->prologue_count = count;
4294 else
4295 {
4296 label_prologue_count *new_lpc = xmalloc (sizeof (* new_lpc));
4297
4298 new_lpc->next = unwind.saved_prologue_counts;
4299 new_lpc->label_number = lbl;
4300 new_lpc->prologue_count = count;
4301 unwind.saved_prologue_counts = new_lpc;
4302 }
4303 }
4304
4305 static void
free_saved_prologue_counts()4306 free_saved_prologue_counts ()
4307 {
4308 label_prologue_count *lpc = unwind.saved_prologue_counts;
4309 label_prologue_count *next;
4310
4311 while (lpc != NULL)
4312 {
4313 next = lpc->next;
4314 free (lpc);
4315 lpc = next;
4316 }
4317
4318 unwind.saved_prologue_counts = NULL;
4319 }
4320
4321 static void
dot_label_state(dummy)4322 dot_label_state (dummy)
4323 int dummy ATTRIBUTE_UNUSED;
4324 {
4325 expressionS e;
4326
4327 if (!in_body ("label_state"))
4328 return;
4329
4330 parse_operand (&e, 0);
4331 if (e.X_op == O_constant)
4332 save_prologue_count (e.X_add_number, unwind.prologue_count);
4333 else
4334 {
4335 as_bad ("Operand to .label_state must be a constant");
4336 e.X_add_number = 0;
4337 }
4338 add_unwind_entry (output_label_state (e.X_add_number), 0);
4339 }
4340
4341 static void
dot_copy_state(dummy)4342 dot_copy_state (dummy)
4343 int dummy ATTRIBUTE_UNUSED;
4344 {
4345 expressionS e;
4346
4347 if (!in_body ("copy_state"))
4348 return;
4349
4350 parse_operand (&e, 0);
4351 if (e.X_op == O_constant)
4352 unwind.prologue_count = get_saved_prologue_count (e.X_add_number);
4353 else
4354 {
4355 as_bad ("Operand to .copy_state must be a constant");
4356 e.X_add_number = 0;
4357 }
4358 add_unwind_entry (output_copy_state (e.X_add_number), 0);
4359 }
4360
4361 static void
dot_unwabi(dummy)4362 dot_unwabi (dummy)
4363 int dummy ATTRIBUTE_UNUSED;
4364 {
4365 expressionS e1, e2;
4366 unsigned char sep;
4367
4368 if (!in_prologue ("unwabi"))
4369 return;
4370
4371 sep = parse_operand (&e1, ',');
4372 if (sep == ',')
4373 parse_operand (&e2, 0);
4374 else
4375 e2.X_op = O_absent;
4376
4377 if (e1.X_op != O_constant)
4378 {
4379 as_bad ("First operand to .unwabi must be a constant");
4380 e1.X_add_number = 0;
4381 }
4382
4383 if (e2.X_op != O_constant)
4384 {
4385 as_bad ("Second operand to .unwabi must be a constant");
4386 e2.X_add_number = 0;
4387 }
4388
4389 add_unwind_entry (output_unwabi (e1.X_add_number, e2.X_add_number), 0);
4390 }
4391
4392 static void
dot_personality(dummy)4393 dot_personality (dummy)
4394 int dummy ATTRIBUTE_UNUSED;
4395 {
4396 char *name, *p, c;
4397 if (!in_procedure ("personality"))
4398 return;
4399 SKIP_WHITESPACE ();
4400 name = input_line_pointer;
4401 c = get_symbol_end ();
4402 p = input_line_pointer;
4403 unwind.personality_routine = symbol_find_or_make (name);
4404 unwind.force_unwind_entry = 1;
4405 *p = c;
4406 SKIP_WHITESPACE ();
4407 demand_empty_rest_of_line ();
4408 }
4409
4410 static void
dot_proc(dummy)4411 dot_proc (dummy)
4412 int dummy ATTRIBUTE_UNUSED;
4413 {
4414 char *name, *p, c;
4415 symbolS *sym;
4416 proc_pending *pending, *last_pending;
4417
4418 if (unwind.proc_pending.sym)
4419 {
4420 (md.unwind_check == unwind_check_warning
4421 ? as_warn
4422 : as_bad) ("Missing .endp after previous .proc");
4423 while (unwind.proc_pending.next)
4424 {
4425 pending = unwind.proc_pending.next;
4426 unwind.proc_pending.next = pending->next;
4427 free (pending);
4428 }
4429 }
4430 last_pending = NULL;
4431
4432 /* Parse names of main and alternate entry points and mark them as
4433 function symbols: */
4434 while (1)
4435 {
4436 SKIP_WHITESPACE ();
4437 name = input_line_pointer;
4438 c = get_symbol_end ();
4439 p = input_line_pointer;
4440 if (!*name)
4441 as_bad ("Empty argument of .proc");
4442 else
4443 {
4444 sym = symbol_find_or_make (name);
4445 if (S_IS_DEFINED (sym))
4446 as_bad ("`%s' was already defined", name);
4447 else if (!last_pending)
4448 {
4449 unwind.proc_pending.sym = sym;
4450 last_pending = &unwind.proc_pending;
4451 }
4452 else
4453 {
4454 pending = xmalloc (sizeof (*pending));
4455 pending->sym = sym;
4456 last_pending = last_pending->next = pending;
4457 }
4458 symbol_get_bfdsym (sym)->flags |= BSF_FUNCTION;
4459 }
4460 *p = c;
4461 SKIP_WHITESPACE ();
4462 if (*input_line_pointer != ',')
4463 break;
4464 ++input_line_pointer;
4465 }
4466 if (!last_pending)
4467 {
4468 unwind.proc_pending.sym = expr_build_dot ();
4469 last_pending = &unwind.proc_pending;
4470 }
4471 last_pending->next = NULL;
4472 demand_empty_rest_of_line ();
4473 ia64_do_align (16);
4474
4475 unwind.prologue = 0;
4476 unwind.prologue_count = 0;
4477 unwind.body = 0;
4478 unwind.insn = 0;
4479 unwind.list = unwind.tail = unwind.current_entry = NULL;
4480 unwind.personality_routine = 0;
4481 }
4482
4483 static void
dot_body(dummy)4484 dot_body (dummy)
4485 int dummy ATTRIBUTE_UNUSED;
4486 {
4487 if (!in_procedure ("body"))
4488 return;
4489 if (!unwind.prologue && !unwind.body && unwind.insn)
4490 as_warn ("Initial .body should precede any instructions");
4491 check_pending_save ();
4492
4493 unwind.prologue = 0;
4494 unwind.prologue_mask = 0;
4495 unwind.body = 1;
4496
4497 add_unwind_entry (output_body (), 0);
4498 }
4499
4500 static void
dot_prologue(dummy)4501 dot_prologue (dummy)
4502 int dummy ATTRIBUTE_UNUSED;
4503 {
4504 unsigned mask = 0, grsave = 0;
4505
4506 if (!in_procedure ("prologue"))
4507 return;
4508 if (unwind.prologue)
4509 {
4510 as_bad (".prologue within prologue");
4511 ignore_rest_of_line ();
4512 return;
4513 }
4514 if (!unwind.body && unwind.insn)
4515 as_warn ("Initial .prologue should precede any instructions");
4516
4517 if (!is_it_end_of_statement ())
4518 {
4519 expressionS e;
4520 int n, sep = parse_operand (&e, ',');
4521
4522 if (e.X_op != O_constant
4523 || e.X_add_number < 0
4524 || e.X_add_number > 0xf)
4525 as_bad ("First operand to .prologue must be a positive 4-bit constant");
4526 else if (e.X_add_number == 0)
4527 as_warn ("Pointless use of zero first operand to .prologue");
4528 else
4529 mask = e.X_add_number;
4530 n = popcount (mask);
4531
4532 if (sep == ',')
4533 parse_operand (&e, 0);
4534 else
4535 e.X_op = O_absent;
4536 if (e.X_op == O_constant
4537 && e.X_add_number >= 0
4538 && e.X_add_number < 128)
4539 {
4540 if (md.unwind_check == unwind_check_error)
4541 as_warn ("Using a constant as second operand to .prologue is deprecated");
4542 grsave = e.X_add_number;
4543 }
4544 else if (e.X_op != O_register
4545 || (grsave = e.X_add_number - REG_GR) > 127)
4546 {
4547 as_bad ("Second operand to .prologue must be a general register");
4548 grsave = 0;
4549 }
4550 else if (grsave > 128U - n)
4551 {
4552 as_bad ("Second operand to .prologue must be the first of %d general registers", n);
4553 grsave = 0;
4554 }
4555
4556 }
4557
4558 if (mask)
4559 add_unwind_entry (output_prologue_gr (mask, grsave), 0);
4560 else
4561 add_unwind_entry (output_prologue (), 0);
4562
4563 unwind.prologue = 1;
4564 unwind.prologue_mask = mask;
4565 unwind.prologue_gr = grsave;
4566 unwind.body = 0;
4567 ++unwind.prologue_count;
4568 }
4569
4570 static void
dot_endp(dummy)4571 dot_endp (dummy)
4572 int dummy ATTRIBUTE_UNUSED;
4573 {
4574 expressionS e;
4575 int bytes_per_address;
4576 long where;
4577 segT saved_seg;
4578 subsegT saved_subseg;
4579 proc_pending *pending;
4580 int unwind_check = md.unwind_check;
4581
4582 md.unwind_check = unwind_check_error;
4583 if (!in_procedure ("endp"))
4584 return;
4585 md.unwind_check = unwind_check;
4586
4587 if (unwind.saved_text_seg)
4588 {
4589 saved_seg = unwind.saved_text_seg;
4590 saved_subseg = unwind.saved_text_subseg;
4591 unwind.saved_text_seg = NULL;
4592 }
4593 else
4594 {
4595 saved_seg = now_seg;
4596 saved_subseg = now_subseg;
4597 }
4598
4599 insn_group_break (1, 0, 0);
4600
4601 /* If there wasn't a .handlerdata, we haven't generated an image yet. */
4602 if (!unwind.info)
4603 generate_unwind_image (saved_seg);
4604
4605 if (unwind.info || unwind.force_unwind_entry)
4606 {
4607 symbolS *proc_end;
4608
4609 subseg_set (md.last_text_seg, 0);
4610 proc_end = expr_build_dot ();
4611
4612 start_unwind_section (saved_seg, SPECIAL_SECTION_UNWIND);
4613
4614 /* Make sure that section has 4 byte alignment for ILP32 and
4615 8 byte alignment for LP64. */
4616 record_alignment (now_seg, md.pointer_size_shift);
4617
4618 /* Need space for 3 pointers for procedure start, procedure end,
4619 and unwind info. */
4620 memset (frag_more (3 * md.pointer_size), 0, 3 * md.pointer_size);
4621 where = frag_now_fix () - (3 * md.pointer_size);
4622 bytes_per_address = bfd_arch_bits_per_address (stdoutput) / 8;
4623
4624 /* Issue the values of a) Proc Begin, b) Proc End, c) Unwind Record. */
4625 e.X_op = O_pseudo_fixup;
4626 e.X_op_symbol = pseudo_func[FUNC_SEG_RELATIVE].u.sym;
4627 e.X_add_number = 0;
4628 if (!S_IS_LOCAL (unwind.proc_pending.sym)
4629 && S_IS_DEFINED (unwind.proc_pending.sym))
4630 e.X_add_symbol = symbol_temp_new (S_GET_SEGMENT (unwind.proc_pending.sym),
4631 S_GET_VALUE (unwind.proc_pending.sym),
4632 symbol_get_frag (unwind.proc_pending.sym));
4633 else
4634 e.X_add_symbol = unwind.proc_pending.sym;
4635 ia64_cons_fix_new (frag_now, where, bytes_per_address, &e);
4636
4637 e.X_op = O_pseudo_fixup;
4638 e.X_op_symbol = pseudo_func[FUNC_SEG_RELATIVE].u.sym;
4639 e.X_add_number = 0;
4640 e.X_add_symbol = proc_end;
4641 ia64_cons_fix_new (frag_now, where + bytes_per_address,
4642 bytes_per_address, &e);
4643
4644 if (unwind.info)
4645 {
4646 e.X_op = O_pseudo_fixup;
4647 e.X_op_symbol = pseudo_func[FUNC_SEG_RELATIVE].u.sym;
4648 e.X_add_number = 0;
4649 e.X_add_symbol = unwind.info;
4650 ia64_cons_fix_new (frag_now, where + (bytes_per_address * 2),
4651 bytes_per_address, &e);
4652 }
4653 }
4654 subseg_set (saved_seg, saved_subseg);
4655
4656 /* Set symbol sizes. */
4657 pending = &unwind.proc_pending;
4658 if (S_GET_NAME (pending->sym))
4659 {
4660 do
4661 {
4662 symbolS *sym = pending->sym;
4663
4664 if (!S_IS_DEFINED (sym))
4665 as_bad ("`%s' was not defined within procedure", S_GET_NAME (sym));
4666 else if (S_GET_SIZE (sym) == 0
4667 && symbol_get_obj (sym)->size == NULL)
4668 {
4669 fragS *frag = symbol_get_frag (sym);
4670
4671 if (frag)
4672 {
4673 if (frag == frag_now && SEG_NORMAL (now_seg))
4674 S_SET_SIZE (sym, frag_now_fix () - S_GET_VALUE (sym));
4675 else
4676 {
4677 symbol_get_obj (sym)->size =
4678 (expressionS *) xmalloc (sizeof (expressionS));
4679 symbol_get_obj (sym)->size->X_op = O_subtract;
4680 symbol_get_obj (sym)->size->X_add_symbol
4681 = symbol_new (FAKE_LABEL_NAME, now_seg,
4682 frag_now_fix (), frag_now);
4683 symbol_get_obj (sym)->size->X_op_symbol = sym;
4684 symbol_get_obj (sym)->size->X_add_number = 0;
4685 }
4686 }
4687 }
4688 } while ((pending = pending->next) != NULL);
4689 }
4690
4691 /* Parse names of main and alternate entry points. */
4692 while (1)
4693 {
4694 char *name, *p, c;
4695
4696 SKIP_WHITESPACE ();
4697 name = input_line_pointer;
4698 c = get_symbol_end ();
4699 p = input_line_pointer;
4700 if (!*name)
4701 (md.unwind_check == unwind_check_warning
4702 ? as_warn
4703 : as_bad) ("Empty argument of .endp");
4704 else
4705 {
4706 symbolS *sym = symbol_find (name);
4707
4708 for (pending = &unwind.proc_pending; pending; pending = pending->next)
4709 {
4710 if (sym == pending->sym)
4711 {
4712 pending->sym = NULL;
4713 break;
4714 }
4715 }
4716 if (!sym || !pending)
4717 as_warn ("`%s' was not specified with previous .proc", name);
4718 }
4719 *p = c;
4720 SKIP_WHITESPACE ();
4721 if (*input_line_pointer != ',')
4722 break;
4723 ++input_line_pointer;
4724 }
4725 demand_empty_rest_of_line ();
4726
4727 /* Deliberately only checking for the main entry point here; the
4728 language spec even says all arguments to .endp are ignored. */
4729 if (unwind.proc_pending.sym
4730 && S_GET_NAME (unwind.proc_pending.sym)
4731 && strcmp (S_GET_NAME (unwind.proc_pending.sym), FAKE_LABEL_NAME))
4732 as_warn ("`%s' should be an operand to this .endp",
4733 S_GET_NAME (unwind.proc_pending.sym));
4734 while (unwind.proc_pending.next)
4735 {
4736 pending = unwind.proc_pending.next;
4737 unwind.proc_pending.next = pending->next;
4738 free (pending);
4739 }
4740 unwind.proc_pending.sym = unwind.info = NULL;
4741 }
4742
4743 static void
dot_template(template)4744 dot_template (template)
4745 int template;
4746 {
4747 CURR_SLOT.user_template = template;
4748 }
4749
4750 static void
dot_regstk(dummy)4751 dot_regstk (dummy)
4752 int dummy ATTRIBUTE_UNUSED;
4753 {
4754 int ins, locs, outs, rots;
4755
4756 if (is_it_end_of_statement ())
4757 ins = locs = outs = rots = 0;
4758 else
4759 {
4760 ins = get_absolute_expression ();
4761 if (*input_line_pointer++ != ',')
4762 goto err;
4763 locs = get_absolute_expression ();
4764 if (*input_line_pointer++ != ',')
4765 goto err;
4766 outs = get_absolute_expression ();
4767 if (*input_line_pointer++ != ',')
4768 goto err;
4769 rots = get_absolute_expression ();
4770 }
4771 set_regstack (ins, locs, outs, rots);
4772 return;
4773
4774 err:
4775 as_bad ("Comma expected");
4776 ignore_rest_of_line ();
4777 }
4778
4779 static void
dot_rot(type)4780 dot_rot (type)
4781 int type;
4782 {
4783 offsetT num_regs;
4784 valueT num_alloced = 0;
4785 struct dynreg **drpp, *dr;
4786 int ch, base_reg = 0;
4787 char *name, *start;
4788 size_t len;
4789
4790 switch (type)
4791 {
4792 case DYNREG_GR: base_reg = REG_GR + 32; break;
4793 case DYNREG_FR: base_reg = REG_FR + 32; break;
4794 case DYNREG_PR: base_reg = REG_P + 16; break;
4795 default: break;
4796 }
4797
4798 /* First, remove existing names from hash table. */
4799 for (dr = md.dynreg[type]; dr && dr->num_regs; dr = dr->next)
4800 {
4801 hash_delete (md.dynreg_hash, dr->name);
4802 /* FIXME: Free dr->name. */
4803 dr->num_regs = 0;
4804 }
4805
4806 drpp = &md.dynreg[type];
4807 while (1)
4808 {
4809 start = input_line_pointer;
4810 ch = get_symbol_end ();
4811 len = strlen (ia64_canonicalize_symbol_name (start));
4812 *input_line_pointer = ch;
4813
4814 SKIP_WHITESPACE ();
4815 if (*input_line_pointer != '[')
4816 {
4817 as_bad ("Expected '['");
4818 goto err;
4819 }
4820 ++input_line_pointer; /* skip '[' */
4821
4822 num_regs = get_absolute_expression ();
4823
4824 if (*input_line_pointer++ != ']')
4825 {
4826 as_bad ("Expected ']'");
4827 goto err;
4828 }
4829 if (num_regs <= 0)
4830 {
4831 as_bad ("Number of elements must be positive");
4832 goto err;
4833 }
4834 SKIP_WHITESPACE ();
4835
4836 num_alloced += num_regs;
4837 switch (type)
4838 {
4839 case DYNREG_GR:
4840 if (num_alloced > md.rot.num_regs)
4841 {
4842 as_bad ("Used more than the declared %d rotating registers",
4843 md.rot.num_regs);
4844 goto err;
4845 }
4846 break;
4847 case DYNREG_FR:
4848 if (num_alloced > 96)
4849 {
4850 as_bad ("Used more than the available 96 rotating registers");
4851 goto err;
4852 }
4853 break;
4854 case DYNREG_PR:
4855 if (num_alloced > 48)
4856 {
4857 as_bad ("Used more than the available 48 rotating registers");
4858 goto err;
4859 }
4860 break;
4861
4862 default:
4863 break;
4864 }
4865
4866 if (!*drpp)
4867 {
4868 *drpp = obstack_alloc (¬es, sizeof (*dr));
4869 memset (*drpp, 0, sizeof (*dr));
4870 }
4871
4872 name = obstack_alloc (¬es, len + 1);
4873 memcpy (name, start, len);
4874 name[len] = '\0';
4875
4876 dr = *drpp;
4877 dr->name = name;
4878 dr->num_regs = num_regs;
4879 dr->base = base_reg;
4880 drpp = &dr->next;
4881 base_reg += num_regs;
4882
4883 if (hash_insert (md.dynreg_hash, name, dr))
4884 {
4885 as_bad ("Attempt to redefine register set `%s'", name);
4886 obstack_free (¬es, name);
4887 goto err;
4888 }
4889
4890 if (*input_line_pointer != ',')
4891 break;
4892 ++input_line_pointer; /* skip comma */
4893 SKIP_WHITESPACE ();
4894 }
4895 demand_empty_rest_of_line ();
4896 return;
4897
4898 err:
4899 ignore_rest_of_line ();
4900 }
4901
4902 static void
dot_byteorder(byteorder)4903 dot_byteorder (byteorder)
4904 int byteorder;
4905 {
4906 segment_info_type *seginfo = seg_info (now_seg);
4907
4908 if (byteorder == -1)
4909 {
4910 if (seginfo->tc_segment_info_data.endian == 0)
4911 seginfo->tc_segment_info_data.endian = default_big_endian ? 1 : 2;
4912 byteorder = seginfo->tc_segment_info_data.endian == 1;
4913 }
4914 else
4915 seginfo->tc_segment_info_data.endian = byteorder ? 1 : 2;
4916
4917 if (target_big_endian != byteorder)
4918 {
4919 target_big_endian = byteorder;
4920 if (target_big_endian)
4921 {
4922 ia64_number_to_chars = number_to_chars_bigendian;
4923 ia64_float_to_chars = ia64_float_to_chars_bigendian;
4924 }
4925 else
4926 {
4927 ia64_number_to_chars = number_to_chars_littleendian;
4928 ia64_float_to_chars = ia64_float_to_chars_littleendian;
4929 }
4930 }
4931 }
4932
4933 static void
dot_psr(dummy)4934 dot_psr (dummy)
4935 int dummy ATTRIBUTE_UNUSED;
4936 {
4937 char *option;
4938 int ch;
4939
4940 while (1)
4941 {
4942 option = input_line_pointer;
4943 ch = get_symbol_end ();
4944 if (strcmp (option, "lsb") == 0)
4945 md.flags &= ~EF_IA_64_BE;
4946 else if (strcmp (option, "msb") == 0)
4947 md.flags |= EF_IA_64_BE;
4948 else if (strcmp (option, "abi32") == 0)
4949 md.flags &= ~EF_IA_64_ABI64;
4950 else if (strcmp (option, "abi64") == 0)
4951 md.flags |= EF_IA_64_ABI64;
4952 else
4953 as_bad ("Unknown psr option `%s'", option);
4954 *input_line_pointer = ch;
4955
4956 SKIP_WHITESPACE ();
4957 if (*input_line_pointer != ',')
4958 break;
4959
4960 ++input_line_pointer;
4961 SKIP_WHITESPACE ();
4962 }
4963 demand_empty_rest_of_line ();
4964 }
4965
4966 static void
dot_ln(dummy)4967 dot_ln (dummy)
4968 int dummy ATTRIBUTE_UNUSED;
4969 {
4970 new_logical_line (0, get_absolute_expression ());
4971 demand_empty_rest_of_line ();
4972 }
4973
4974 static void
cross_section(ref,cons,ua)4975 cross_section (ref, cons, ua)
4976 int ref;
4977 void (*cons) PARAMS((int));
4978 int ua;
4979 {
4980 char *start, *end;
4981 int saved_auto_align;
4982 unsigned int section_count;
4983
4984 SKIP_WHITESPACE ();
4985 start = input_line_pointer;
4986 if (*start == '"')
4987 {
4988 int len;
4989 char *name;
4990
4991 name = demand_copy_C_string (&len);
4992 obstack_free(¬es, name);
4993 if (!name)
4994 {
4995 ignore_rest_of_line ();
4996 return;
4997 }
4998 }
4999 else
5000 {
5001 char c = get_symbol_end ();
5002
5003 if (input_line_pointer == start)
5004 {
5005 as_bad ("Missing section name");
5006 ignore_rest_of_line ();
5007 return;
5008 }
5009 *input_line_pointer = c;
5010 }
5011 end = input_line_pointer;
5012 SKIP_WHITESPACE ();
5013 if (*input_line_pointer != ',')
5014 {
5015 as_bad ("Comma expected after section name");
5016 ignore_rest_of_line ();
5017 return;
5018 }
5019 *end = '\0';
5020 end = input_line_pointer + 1; /* skip comma */
5021 input_line_pointer = start;
5022 md.keep_pending_output = 1;
5023 section_count = bfd_count_sections(stdoutput);
5024 obj_elf_section (0);
5025 if (section_count != bfd_count_sections(stdoutput))
5026 as_warn ("Creating sections with .xdataN/.xrealN/.xstringZ is deprecated.");
5027 input_line_pointer = end;
5028 saved_auto_align = md.auto_align;
5029 if (ua)
5030 md.auto_align = 0;
5031 (*cons) (ref);
5032 if (ua)
5033 md.auto_align = saved_auto_align;
5034 obj_elf_previous (0);
5035 md.keep_pending_output = 0;
5036 }
5037
5038 static void
dot_xdata(size)5039 dot_xdata (size)
5040 int size;
5041 {
5042 cross_section (size, cons, 0);
5043 }
5044
5045 /* Why doesn't float_cons() call md_cons_align() the way cons() does? */
5046
5047 static void
stmt_float_cons(kind)5048 stmt_float_cons (kind)
5049 int kind;
5050 {
5051 size_t alignment;
5052
5053 switch (kind)
5054 {
5055 case 'd':
5056 alignment = 8;
5057 break;
5058
5059 case 'x':
5060 case 'X':
5061 alignment = 16;
5062 break;
5063
5064 case 'f':
5065 default:
5066 alignment = 4;
5067 break;
5068 }
5069 ia64_do_align (alignment);
5070 float_cons (kind);
5071 }
5072
5073 static void
stmt_cons_ua(size)5074 stmt_cons_ua (size)
5075 int size;
5076 {
5077 int saved_auto_align = md.auto_align;
5078
5079 md.auto_align = 0;
5080 cons (size);
5081 md.auto_align = saved_auto_align;
5082 }
5083
5084 static void
dot_xfloat_cons(kind)5085 dot_xfloat_cons (kind)
5086 int kind;
5087 {
5088 cross_section (kind, stmt_float_cons, 0);
5089 }
5090
5091 static void
dot_xstringer(zero)5092 dot_xstringer (zero)
5093 int zero;
5094 {
5095 cross_section (zero, stringer, 0);
5096 }
5097
5098 static void
dot_xdata_ua(size)5099 dot_xdata_ua (size)
5100 int size;
5101 {
5102 cross_section (size, cons, 1);
5103 }
5104
5105 static void
dot_xfloat_cons_ua(kind)5106 dot_xfloat_cons_ua (kind)
5107 int kind;
5108 {
5109 cross_section (kind, float_cons, 1);
5110 }
5111
5112 /* .reg.val <regname>,value */
5113
5114 static void
dot_reg_val(dummy)5115 dot_reg_val (dummy)
5116 int dummy ATTRIBUTE_UNUSED;
5117 {
5118 expressionS reg;
5119
5120 expression_and_evaluate (®);
5121 if (reg.X_op != O_register)
5122 {
5123 as_bad (_("Register name expected"));
5124 ignore_rest_of_line ();
5125 }
5126 else if (*input_line_pointer++ != ',')
5127 {
5128 as_bad (_("Comma expected"));
5129 ignore_rest_of_line ();
5130 }
5131 else
5132 {
5133 valueT value = get_absolute_expression ();
5134 int regno = reg.X_add_number;
5135 if (regno <= REG_GR || regno > REG_GR + 127)
5136 as_warn (_("Register value annotation ignored"));
5137 else
5138 {
5139 gr_values[regno - REG_GR].known = 1;
5140 gr_values[regno - REG_GR].value = value;
5141 gr_values[regno - REG_GR].path = md.path;
5142 }
5143 }
5144 demand_empty_rest_of_line ();
5145 }
5146
5147 /*
5148 .serialize.data
5149 .serialize.instruction
5150 */
5151 static void
dot_serialize(type)5152 dot_serialize (type)
5153 int type;
5154 {
5155 insn_group_break (0, 0, 0);
5156 if (type)
5157 instruction_serialization ();
5158 else
5159 data_serialization ();
5160 insn_group_break (0, 0, 0);
5161 demand_empty_rest_of_line ();
5162 }
5163
5164 /* select dv checking mode
5165 .auto
5166 .explicit
5167 .default
5168
5169 A stop is inserted when changing modes
5170 */
5171
5172 static void
dot_dv_mode(type)5173 dot_dv_mode (type)
5174 int type;
5175 {
5176 if (md.manual_bundling)
5177 as_warn (_("Directive invalid within a bundle"));
5178
5179 if (type == 'E' || type == 'A')
5180 md.mode_explicitly_set = 0;
5181 else
5182 md.mode_explicitly_set = 1;
5183
5184 md.detect_dv = 1;
5185 switch (type)
5186 {
5187 case 'A':
5188 case 'a':
5189 if (md.explicit_mode)
5190 insn_group_break (1, 0, 0);
5191 md.explicit_mode = 0;
5192 break;
5193 case 'E':
5194 case 'e':
5195 if (!md.explicit_mode)
5196 insn_group_break (1, 0, 0);
5197 md.explicit_mode = 1;
5198 break;
5199 default:
5200 case 'd':
5201 if (md.explicit_mode != md.default_explicit_mode)
5202 insn_group_break (1, 0, 0);
5203 md.explicit_mode = md.default_explicit_mode;
5204 md.mode_explicitly_set = 0;
5205 break;
5206 }
5207 }
5208
5209 static void
print_prmask(mask)5210 print_prmask (mask)
5211 valueT mask;
5212 {
5213 int regno;
5214 char *comma = "";
5215 for (regno = 0; regno < 64; regno++)
5216 {
5217 if (mask & ((valueT) 1 << regno))
5218 {
5219 fprintf (stderr, "%s p%d", comma, regno);
5220 comma = ",";
5221 }
5222 }
5223 }
5224
5225 /*
5226 .pred.rel.clear [p1 [,p2 [,...]]] (also .pred.rel "clear" or @clear)
5227 .pred.rel.imply p1, p2 (also .pred.rel "imply" or @imply)
5228 .pred.rel.mutex p1, p2 [,...] (also .pred.rel "mutex" or @mutex)
5229 .pred.safe_across_calls p1 [, p2 [,...]]
5230 */
5231
5232 static void
dot_pred_rel(type)5233 dot_pred_rel (type)
5234 int type;
5235 {
5236 valueT mask = 0;
5237 int count = 0;
5238 int p1 = -1, p2 = -1;
5239
5240 if (type == 0)
5241 {
5242 if (*input_line_pointer == '"')
5243 {
5244 int len;
5245 char *form = demand_copy_C_string (&len);
5246
5247 if (strcmp (form, "mutex") == 0)
5248 type = 'm';
5249 else if (strcmp (form, "clear") == 0)
5250 type = 'c';
5251 else if (strcmp (form, "imply") == 0)
5252 type = 'i';
5253 obstack_free (¬es, form);
5254 }
5255 else if (*input_line_pointer == '@')
5256 {
5257 char *form = ++input_line_pointer;
5258 char c = get_symbol_end();
5259
5260 if (strcmp (form, "mutex") == 0)
5261 type = 'm';
5262 else if (strcmp (form, "clear") == 0)
5263 type = 'c';
5264 else if (strcmp (form, "imply") == 0)
5265 type = 'i';
5266 *input_line_pointer = c;
5267 }
5268 else
5269 {
5270 as_bad (_("Missing predicate relation type"));
5271 ignore_rest_of_line ();
5272 return;
5273 }
5274 if (type == 0)
5275 {
5276 as_bad (_("Unrecognized predicate relation type"));
5277 ignore_rest_of_line ();
5278 return;
5279 }
5280 if (*input_line_pointer == ',')
5281 ++input_line_pointer;
5282 SKIP_WHITESPACE ();
5283 }
5284
5285 SKIP_WHITESPACE ();
5286 while (1)
5287 {
5288 valueT bits = 1;
5289 int regno;
5290 expressionS pr, *pr1, *pr2;
5291
5292 expression_and_evaluate (&pr);
5293 if (pr.X_op == O_register
5294 && pr.X_add_number >= REG_P
5295 && pr.X_add_number <= REG_P + 63)
5296 {
5297 regno = pr.X_add_number - REG_P;
5298 bits <<= regno;
5299 count++;
5300 if (p1 == -1)
5301 p1 = regno;
5302 else if (p2 == -1)
5303 p2 = regno;
5304 }
5305 else if (type != 'i'
5306 && pr.X_op == O_subtract
5307 && (pr1 = symbol_get_value_expression (pr.X_add_symbol))
5308 && pr1->X_op == O_register
5309 && pr1->X_add_number >= REG_P
5310 && pr1->X_add_number <= REG_P + 63
5311 && (pr2 = symbol_get_value_expression (pr.X_op_symbol))
5312 && pr2->X_op == O_register
5313 && pr2->X_add_number >= REG_P
5314 && pr2->X_add_number <= REG_P + 63)
5315 {
5316 /* It's a range. */
5317 int stop;
5318
5319 regno = pr1->X_add_number - REG_P;
5320 stop = pr2->X_add_number - REG_P;
5321 if (regno >= stop)
5322 {
5323 as_bad (_("Bad register range"));
5324 ignore_rest_of_line ();
5325 return;
5326 }
5327 bits = ((bits << stop) << 1) - (bits << regno);
5328 count += stop - regno + 1;
5329 }
5330 else
5331 {
5332 as_bad (_("Predicate register expected"));
5333 ignore_rest_of_line ();
5334 return;
5335 }
5336 if (mask & bits)
5337 as_warn (_("Duplicate predicate register ignored"));
5338 mask |= bits;
5339 if (*input_line_pointer != ',')
5340 break;
5341 ++input_line_pointer;
5342 SKIP_WHITESPACE ();
5343 }
5344
5345 switch (type)
5346 {
5347 case 'c':
5348 if (count == 0)
5349 mask = ~(valueT) 0;
5350 clear_qp_mutex (mask);
5351 clear_qp_implies (mask, (valueT) 0);
5352 break;
5353 case 'i':
5354 if (count != 2 || p1 == -1 || p2 == -1)
5355 as_bad (_("Predicate source and target required"));
5356 else if (p1 == 0 || p2 == 0)
5357 as_bad (_("Use of p0 is not valid in this context"));
5358 else
5359 add_qp_imply (p1, p2);
5360 break;
5361 case 'm':
5362 if (count < 2)
5363 {
5364 as_bad (_("At least two PR arguments expected"));
5365 break;
5366 }
5367 else if (mask & 1)
5368 {
5369 as_bad (_("Use of p0 is not valid in this context"));
5370 break;
5371 }
5372 add_qp_mutex (mask);
5373 break;
5374 case 's':
5375 /* note that we don't override any existing relations */
5376 if (count == 0)
5377 {
5378 as_bad (_("At least one PR argument expected"));
5379 break;
5380 }
5381 if (md.debug_dv)
5382 {
5383 fprintf (stderr, "Safe across calls: ");
5384 print_prmask (mask);
5385 fprintf (stderr, "\n");
5386 }
5387 qp_safe_across_calls = mask;
5388 break;
5389 }
5390 demand_empty_rest_of_line ();
5391 }
5392
5393 /* .entry label [, label [, ...]]
5394 Hint to DV code that the given labels are to be considered entry points.
5395 Otherwise, only global labels are considered entry points. */
5396
5397 static void
dot_entry(dummy)5398 dot_entry (dummy)
5399 int dummy ATTRIBUTE_UNUSED;
5400 {
5401 const char *err;
5402 char *name;
5403 int c;
5404 symbolS *symbolP;
5405
5406 do
5407 {
5408 name = input_line_pointer;
5409 c = get_symbol_end ();
5410 symbolP = symbol_find_or_make (name);
5411
5412 err = hash_insert (md.entry_hash, S_GET_NAME (symbolP), (PTR) symbolP);
5413 if (err)
5414 as_fatal (_("Inserting \"%s\" into entry hint table failed: %s"),
5415 name, err);
5416
5417 *input_line_pointer = c;
5418 SKIP_WHITESPACE ();
5419 c = *input_line_pointer;
5420 if (c == ',')
5421 {
5422 input_line_pointer++;
5423 SKIP_WHITESPACE ();
5424 if (*input_line_pointer == '\n')
5425 c = '\n';
5426 }
5427 }
5428 while (c == ',');
5429
5430 demand_empty_rest_of_line ();
5431 }
5432
5433 /* .mem.offset offset, base
5434 "base" is used to distinguish between offsets from a different base. */
5435
5436 static void
dot_mem_offset(dummy)5437 dot_mem_offset (dummy)
5438 int dummy ATTRIBUTE_UNUSED;
5439 {
5440 md.mem_offset.hint = 1;
5441 md.mem_offset.offset = get_absolute_expression ();
5442 if (*input_line_pointer != ',')
5443 {
5444 as_bad (_("Comma expected"));
5445 ignore_rest_of_line ();
5446 return;
5447 }
5448 ++input_line_pointer;
5449 md.mem_offset.base = get_absolute_expression ();
5450 demand_empty_rest_of_line ();
5451 }
5452
5453 /* ia64-specific pseudo-ops: */
5454 const pseudo_typeS md_pseudo_table[] =
5455 {
5456 { "radix", dot_radix, 0 },
5457 { "lcomm", s_lcomm_bytes, 1 },
5458 { "loc", dot_loc, 0 },
5459 { "bss", dot_special_section, SPECIAL_SECTION_BSS },
5460 { "sbss", dot_special_section, SPECIAL_SECTION_SBSS },
5461 { "sdata", dot_special_section, SPECIAL_SECTION_SDATA },
5462 { "rodata", dot_special_section, SPECIAL_SECTION_RODATA },
5463 { "comment", dot_special_section, SPECIAL_SECTION_COMMENT },
5464 { "ia_64.unwind", dot_special_section, SPECIAL_SECTION_UNWIND },
5465 { "ia_64.unwind_info", dot_special_section, SPECIAL_SECTION_UNWIND_INFO },
5466 { "init_array", dot_special_section, SPECIAL_SECTION_INIT_ARRAY },
5467 { "fini_array", dot_special_section, SPECIAL_SECTION_FINI_ARRAY },
5468 { "proc", dot_proc, 0 },
5469 { "body", dot_body, 0 },
5470 { "prologue", dot_prologue, 0 },
5471 { "endp", dot_endp, 0 },
5472
5473 { "fframe", dot_fframe, 0 },
5474 { "vframe", dot_vframe, 0 },
5475 { "vframesp", dot_vframesp, 0 },
5476 { "vframepsp", dot_vframesp, 1 },
5477 { "save", dot_save, 0 },
5478 { "restore", dot_restore, 0 },
5479 { "restorereg", dot_restorereg, 0 },
5480 { "restorereg.p", dot_restorereg, 1 },
5481 { "handlerdata", dot_handlerdata, 0 },
5482 { "unwentry", dot_unwentry, 0 },
5483 { "altrp", dot_altrp, 0 },
5484 { "savesp", dot_savemem, 0 },
5485 { "savepsp", dot_savemem, 1 },
5486 { "save.g", dot_saveg, 0 },
5487 { "save.f", dot_savef, 0 },
5488 { "save.b", dot_saveb, 0 },
5489 { "save.gf", dot_savegf, 0 },
5490 { "spill", dot_spill, 0 },
5491 { "spillreg", dot_spillreg, 0 },
5492 { "spillsp", dot_spillmem, 0 },
5493 { "spillpsp", dot_spillmem, 1 },
5494 { "spillreg.p", dot_spillreg, 1 },
5495 { "spillsp.p", dot_spillmem, ~0 },
5496 { "spillpsp.p", dot_spillmem, ~1 },
5497 { "label_state", dot_label_state, 0 },
5498 { "copy_state", dot_copy_state, 0 },
5499 { "unwabi", dot_unwabi, 0 },
5500 { "personality", dot_personality, 0 },
5501 { "mii", dot_template, 0x0 },
5502 { "mli", dot_template, 0x2 }, /* old format, for compatibility */
5503 { "mlx", dot_template, 0x2 },
5504 { "mmi", dot_template, 0x4 },
5505 { "mfi", dot_template, 0x6 },
5506 { "mmf", dot_template, 0x7 },
5507 { "mib", dot_template, 0x8 },
5508 { "mbb", dot_template, 0x9 },
5509 { "bbb", dot_template, 0xb },
5510 { "mmb", dot_template, 0xc },
5511 { "mfb", dot_template, 0xe },
5512 { "align", dot_align, 0 },
5513 { "regstk", dot_regstk, 0 },
5514 { "rotr", dot_rot, DYNREG_GR },
5515 { "rotf", dot_rot, DYNREG_FR },
5516 { "rotp", dot_rot, DYNREG_PR },
5517 { "lsb", dot_byteorder, 0 },
5518 { "msb", dot_byteorder, 1 },
5519 { "psr", dot_psr, 0 },
5520 { "alias", dot_alias, 0 },
5521 { "secalias", dot_alias, 1 },
5522 { "ln", dot_ln, 0 }, /* source line info (for debugging) */
5523
5524 { "xdata1", dot_xdata, 1 },
5525 { "xdata2", dot_xdata, 2 },
5526 { "xdata4", dot_xdata, 4 },
5527 { "xdata8", dot_xdata, 8 },
5528 { "xdata16", dot_xdata, 16 },
5529 { "xreal4", dot_xfloat_cons, 'f' },
5530 { "xreal8", dot_xfloat_cons, 'd' },
5531 { "xreal10", dot_xfloat_cons, 'x' },
5532 { "xreal16", dot_xfloat_cons, 'X' },
5533 { "xstring", dot_xstringer, 0 },
5534 { "xstringz", dot_xstringer, 1 },
5535
5536 /* unaligned versions: */
5537 { "xdata2.ua", dot_xdata_ua, 2 },
5538 { "xdata4.ua", dot_xdata_ua, 4 },
5539 { "xdata8.ua", dot_xdata_ua, 8 },
5540 { "xdata16.ua", dot_xdata_ua, 16 },
5541 { "xreal4.ua", dot_xfloat_cons_ua, 'f' },
5542 { "xreal8.ua", dot_xfloat_cons_ua, 'd' },
5543 { "xreal10.ua", dot_xfloat_cons_ua, 'x' },
5544 { "xreal16.ua", dot_xfloat_cons_ua, 'X' },
5545
5546 /* annotations/DV checking support */
5547 { "entry", dot_entry, 0 },
5548 { "mem.offset", dot_mem_offset, 0 },
5549 { "pred.rel", dot_pred_rel, 0 },
5550 { "pred.rel.clear", dot_pred_rel, 'c' },
5551 { "pred.rel.imply", dot_pred_rel, 'i' },
5552 { "pred.rel.mutex", dot_pred_rel, 'm' },
5553 { "pred.safe_across_calls", dot_pred_rel, 's' },
5554 { "reg.val", dot_reg_val, 0 },
5555 { "serialize.data", dot_serialize, 0 },
5556 { "serialize.instruction", dot_serialize, 1 },
5557 { "auto", dot_dv_mode, 'a' },
5558 { "explicit", dot_dv_mode, 'e' },
5559 { "default", dot_dv_mode, 'd' },
5560
5561 /* ??? These are needed to make gas/testsuite/gas/elf/ehopt.s work.
5562 IA-64 aligns data allocation pseudo-ops by default, so we have to
5563 tell it that these ones are supposed to be unaligned. Long term,
5564 should rewrite so that only IA-64 specific data allocation pseudo-ops
5565 are aligned by default. */
5566 {"2byte", stmt_cons_ua, 2},
5567 {"4byte", stmt_cons_ua, 4},
5568 {"8byte", stmt_cons_ua, 8},
5569
5570 { NULL, 0, 0 }
5571 };
5572
5573 static const struct pseudo_opcode
5574 {
5575 const char *name;
5576 void (*handler) (int);
5577 int arg;
5578 }
5579 pseudo_opcode[] =
5580 {
5581 /* these are more like pseudo-ops, but don't start with a dot */
5582 { "data1", cons, 1 },
5583 { "data2", cons, 2 },
5584 { "data4", cons, 4 },
5585 { "data8", cons, 8 },
5586 { "data16", cons, 16 },
5587 { "real4", stmt_float_cons, 'f' },
5588 { "real8", stmt_float_cons, 'd' },
5589 { "real10", stmt_float_cons, 'x' },
5590 { "real16", stmt_float_cons, 'X' },
5591 { "string", stringer, 0 },
5592 { "stringz", stringer, 1 },
5593
5594 /* unaligned versions: */
5595 { "data2.ua", stmt_cons_ua, 2 },
5596 { "data4.ua", stmt_cons_ua, 4 },
5597 { "data8.ua", stmt_cons_ua, 8 },
5598 { "data16.ua", stmt_cons_ua, 16 },
5599 { "real4.ua", float_cons, 'f' },
5600 { "real8.ua", float_cons, 'd' },
5601 { "real10.ua", float_cons, 'x' },
5602 { "real16.ua", float_cons, 'X' },
5603 };
5604
5605 /* Declare a register by creating a symbol for it and entering it in
5606 the symbol table. */
5607
5608 static symbolS *
declare_register(name,regnum)5609 declare_register (name, regnum)
5610 const char *name;
5611 unsigned int regnum;
5612 {
5613 const char *err;
5614 symbolS *sym;
5615
5616 sym = symbol_create (name, reg_section, regnum, &zero_address_frag);
5617
5618 err = hash_insert (md.reg_hash, S_GET_NAME (sym), (PTR) sym);
5619 if (err)
5620 as_fatal ("Inserting \"%s\" into register table failed: %s",
5621 name, err);
5622
5623 return sym;
5624 }
5625
5626 static void
declare_register_set(prefix,num_regs,base_regnum)5627 declare_register_set (prefix, num_regs, base_regnum)
5628 const char *prefix;
5629 unsigned int num_regs;
5630 unsigned int base_regnum;
5631 {
5632 char name[8];
5633 unsigned int i;
5634
5635 for (i = 0; i < num_regs; ++i)
5636 {
5637 sprintf (name, "%s%u", prefix, i);
5638 declare_register (name, base_regnum + i);
5639 }
5640 }
5641
5642 static unsigned int
operand_width(opnd)5643 operand_width (opnd)
5644 enum ia64_opnd opnd;
5645 {
5646 const struct ia64_operand *odesc = &elf64_ia64_operands[opnd];
5647 unsigned int bits = 0;
5648 int i;
5649
5650 bits = 0;
5651 for (i = 0; i < NELEMS (odesc->field) && odesc->field[i].bits; ++i)
5652 bits += odesc->field[i].bits;
5653
5654 return bits;
5655 }
5656
5657 static enum operand_match_result
operand_match(idesc,index,e)5658 operand_match (idesc, index, e)
5659 const struct ia64_opcode *idesc;
5660 int index;
5661 expressionS *e;
5662 {
5663 enum ia64_opnd opnd = idesc->operands[index];
5664 int bits, relocatable = 0;
5665 struct insn_fix *fix;
5666 bfd_signed_vma val;
5667
5668 switch (opnd)
5669 {
5670 /* constants: */
5671
5672 case IA64_OPND_AR_CCV:
5673 if (e->X_op == O_register && e->X_add_number == REG_AR + 32)
5674 return OPERAND_MATCH;
5675 break;
5676
5677 case IA64_OPND_AR_CSD:
5678 if (e->X_op == O_register && e->X_add_number == REG_AR + 25)
5679 return OPERAND_MATCH;
5680 break;
5681
5682 case IA64_OPND_AR_PFS:
5683 if (e->X_op == O_register && e->X_add_number == REG_AR + 64)
5684 return OPERAND_MATCH;
5685 break;
5686
5687 case IA64_OPND_GR0:
5688 if (e->X_op == O_register && e->X_add_number == REG_GR + 0)
5689 return OPERAND_MATCH;
5690 break;
5691
5692 case IA64_OPND_IP:
5693 if (e->X_op == O_register && e->X_add_number == REG_IP)
5694 return OPERAND_MATCH;
5695 break;
5696
5697 case IA64_OPND_PR:
5698 if (e->X_op == O_register && e->X_add_number == REG_PR)
5699 return OPERAND_MATCH;
5700 break;
5701
5702 case IA64_OPND_PR_ROT:
5703 if (e->X_op == O_register && e->X_add_number == REG_PR_ROT)
5704 return OPERAND_MATCH;
5705 break;
5706
5707 case IA64_OPND_PSR:
5708 if (e->X_op == O_register && e->X_add_number == REG_PSR)
5709 return OPERAND_MATCH;
5710 break;
5711
5712 case IA64_OPND_PSR_L:
5713 if (e->X_op == O_register && e->X_add_number == REG_PSR_L)
5714 return OPERAND_MATCH;
5715 break;
5716
5717 case IA64_OPND_PSR_UM:
5718 if (e->X_op == O_register && e->X_add_number == REG_PSR_UM)
5719 return OPERAND_MATCH;
5720 break;
5721
5722 case IA64_OPND_C1:
5723 if (e->X_op == O_constant)
5724 {
5725 if (e->X_add_number == 1)
5726 return OPERAND_MATCH;
5727 else
5728 return OPERAND_OUT_OF_RANGE;
5729 }
5730 break;
5731
5732 case IA64_OPND_C8:
5733 if (e->X_op == O_constant)
5734 {
5735 if (e->X_add_number == 8)
5736 return OPERAND_MATCH;
5737 else
5738 return OPERAND_OUT_OF_RANGE;
5739 }
5740 break;
5741
5742 case IA64_OPND_C16:
5743 if (e->X_op == O_constant)
5744 {
5745 if (e->X_add_number == 16)
5746 return OPERAND_MATCH;
5747 else
5748 return OPERAND_OUT_OF_RANGE;
5749 }
5750 break;
5751
5752 /* register operands: */
5753
5754 case IA64_OPND_AR3:
5755 if (e->X_op == O_register && e->X_add_number >= REG_AR
5756 && e->X_add_number < REG_AR + 128)
5757 return OPERAND_MATCH;
5758 break;
5759
5760 case IA64_OPND_B1:
5761 case IA64_OPND_B2:
5762 if (e->X_op == O_register && e->X_add_number >= REG_BR
5763 && e->X_add_number < REG_BR + 8)
5764 return OPERAND_MATCH;
5765 break;
5766
5767 case IA64_OPND_CR3:
5768 if (e->X_op == O_register && e->X_add_number >= REG_CR
5769 && e->X_add_number < REG_CR + 128)
5770 return OPERAND_MATCH;
5771 break;
5772
5773 case IA64_OPND_F1:
5774 case IA64_OPND_F2:
5775 case IA64_OPND_F3:
5776 case IA64_OPND_F4:
5777 if (e->X_op == O_register && e->X_add_number >= REG_FR
5778 && e->X_add_number < REG_FR + 128)
5779 return OPERAND_MATCH;
5780 break;
5781
5782 case IA64_OPND_P1:
5783 case IA64_OPND_P2:
5784 if (e->X_op == O_register && e->X_add_number >= REG_P
5785 && e->X_add_number < REG_P + 64)
5786 return OPERAND_MATCH;
5787 break;
5788
5789 case IA64_OPND_R1:
5790 case IA64_OPND_R2:
5791 case IA64_OPND_R3:
5792 if (e->X_op == O_register && e->X_add_number >= REG_GR
5793 && e->X_add_number < REG_GR + 128)
5794 return OPERAND_MATCH;
5795 break;
5796
5797 case IA64_OPND_R3_2:
5798 if (e->X_op == O_register && e->X_add_number >= REG_GR)
5799 {
5800 if (e->X_add_number < REG_GR + 4)
5801 return OPERAND_MATCH;
5802 else if (e->X_add_number < REG_GR + 128)
5803 return OPERAND_OUT_OF_RANGE;
5804 }
5805 break;
5806
5807 /* indirect operands: */
5808 case IA64_OPND_CPUID_R3:
5809 case IA64_OPND_DBR_R3:
5810 case IA64_OPND_DTR_R3:
5811 case IA64_OPND_ITR_R3:
5812 case IA64_OPND_IBR_R3:
5813 case IA64_OPND_MSR_R3:
5814 case IA64_OPND_PKR_R3:
5815 case IA64_OPND_PMC_R3:
5816 case IA64_OPND_PMD_R3:
5817 case IA64_OPND_RR_R3:
5818 if (e->X_op == O_index && e->X_op_symbol
5819 && (S_GET_VALUE (e->X_op_symbol) - IND_CPUID
5820 == opnd - IA64_OPND_CPUID_R3))
5821 return OPERAND_MATCH;
5822 break;
5823
5824 case IA64_OPND_MR3:
5825 if (e->X_op == O_index && !e->X_op_symbol)
5826 return OPERAND_MATCH;
5827 break;
5828
5829 /* immediate operands: */
5830 case IA64_OPND_CNT2a:
5831 case IA64_OPND_LEN4:
5832 case IA64_OPND_LEN6:
5833 bits = operand_width (idesc->operands[index]);
5834 if (e->X_op == O_constant)
5835 {
5836 if ((bfd_vma) (e->X_add_number - 1) < ((bfd_vma) 1 << bits))
5837 return OPERAND_MATCH;
5838 else
5839 return OPERAND_OUT_OF_RANGE;
5840 }
5841 break;
5842
5843 case IA64_OPND_CNT2b:
5844 if (e->X_op == O_constant)
5845 {
5846 if ((bfd_vma) (e->X_add_number - 1) < 3)
5847 return OPERAND_MATCH;
5848 else
5849 return OPERAND_OUT_OF_RANGE;
5850 }
5851 break;
5852
5853 case IA64_OPND_CNT2c:
5854 val = e->X_add_number;
5855 if (e->X_op == O_constant)
5856 {
5857 if ((val == 0 || val == 7 || val == 15 || val == 16))
5858 return OPERAND_MATCH;
5859 else
5860 return OPERAND_OUT_OF_RANGE;
5861 }
5862 break;
5863
5864 case IA64_OPND_SOR:
5865 /* SOR must be an integer multiple of 8 */
5866 if (e->X_op == O_constant && e->X_add_number & 0x7)
5867 return OPERAND_OUT_OF_RANGE;
5868 case IA64_OPND_SOF:
5869 case IA64_OPND_SOL:
5870 if (e->X_op == O_constant)
5871 {
5872 if ((bfd_vma) e->X_add_number <= 96)
5873 return OPERAND_MATCH;
5874 else
5875 return OPERAND_OUT_OF_RANGE;
5876 }
5877 break;
5878
5879 case IA64_OPND_IMMU62:
5880 if (e->X_op == O_constant)
5881 {
5882 if ((bfd_vma) e->X_add_number < ((bfd_vma) 1 << 62))
5883 return OPERAND_MATCH;
5884 else
5885 return OPERAND_OUT_OF_RANGE;
5886 }
5887 else
5888 {
5889 /* FIXME -- need 62-bit relocation type */
5890 as_bad (_("62-bit relocation not yet implemented"));
5891 }
5892 break;
5893
5894 case IA64_OPND_IMMU64:
5895 if (e->X_op == O_symbol || e->X_op == O_pseudo_fixup
5896 || e->X_op == O_subtract)
5897 {
5898 fix = CURR_SLOT.fixup + CURR_SLOT.num_fixups;
5899 fix->code = BFD_RELOC_IA64_IMM64;
5900 if (e->X_op != O_subtract)
5901 {
5902 fix->code = ia64_gen_real_reloc_type (e->X_op_symbol, fix->code);
5903 if (e->X_op == O_pseudo_fixup)
5904 e->X_op = O_symbol;
5905 }
5906
5907 fix->opnd = idesc->operands[index];
5908 fix->expr = *e;
5909 fix->is_pcrel = 0;
5910 ++CURR_SLOT.num_fixups;
5911 return OPERAND_MATCH;
5912 }
5913 else if (e->X_op == O_constant)
5914 return OPERAND_MATCH;
5915 break;
5916
5917 case IA64_OPND_IMMU5b:
5918 if (e->X_op == O_constant)
5919 {
5920 val = e->X_add_number;
5921 if (val >= 32 && val <= 63)
5922 return OPERAND_MATCH;
5923 else
5924 return OPERAND_OUT_OF_RANGE;
5925 }
5926 break;
5927
5928 case IA64_OPND_CCNT5:
5929 case IA64_OPND_CNT5:
5930 case IA64_OPND_CNT6:
5931 case IA64_OPND_CPOS6a:
5932 case IA64_OPND_CPOS6b:
5933 case IA64_OPND_CPOS6c:
5934 case IA64_OPND_IMMU2:
5935 case IA64_OPND_IMMU7a:
5936 case IA64_OPND_IMMU7b:
5937 case IA64_OPND_IMMU21:
5938 case IA64_OPND_IMMU24:
5939 case IA64_OPND_MBTYPE4:
5940 case IA64_OPND_MHTYPE8:
5941 case IA64_OPND_POS6:
5942 bits = operand_width (idesc->operands[index]);
5943 if (e->X_op == O_constant)
5944 {
5945 if ((bfd_vma) e->X_add_number < ((bfd_vma) 1 << bits))
5946 return OPERAND_MATCH;
5947 else
5948 return OPERAND_OUT_OF_RANGE;
5949 }
5950 break;
5951
5952 case IA64_OPND_IMMU9:
5953 bits = operand_width (idesc->operands[index]);
5954 if (e->X_op == O_constant)
5955 {
5956 if ((bfd_vma) e->X_add_number < ((bfd_vma) 1 << bits))
5957 {
5958 int lobits = e->X_add_number & 0x3;
5959 if (((bfd_vma) e->X_add_number & 0x3C) != 0 && lobits == 0)
5960 e->X_add_number |= (bfd_vma) 0x3;
5961 return OPERAND_MATCH;
5962 }
5963 else
5964 return OPERAND_OUT_OF_RANGE;
5965 }
5966 break;
5967
5968 case IA64_OPND_IMM44:
5969 /* least 16 bits must be zero */
5970 if ((e->X_add_number & 0xffff) != 0)
5971 /* XXX technically, this is wrong: we should not be issuing warning
5972 messages until we're sure this instruction pattern is going to
5973 be used! */
5974 as_warn (_("lower 16 bits of mask ignored"));
5975
5976 if (e->X_op == O_constant)
5977 {
5978 if (((e->X_add_number >= 0
5979 && (bfd_vma) e->X_add_number < ((bfd_vma) 1 << 44))
5980 || (e->X_add_number < 0
5981 && (bfd_vma) -e->X_add_number <= ((bfd_vma) 1 << 44))))
5982 {
5983 /* sign-extend */
5984 if (e->X_add_number >= 0
5985 && (e->X_add_number & ((bfd_vma) 1 << 43)) != 0)
5986 {
5987 e->X_add_number |= ~(((bfd_vma) 1 << 44) - 1);
5988 }
5989 return OPERAND_MATCH;
5990 }
5991 else
5992 return OPERAND_OUT_OF_RANGE;
5993 }
5994 break;
5995
5996 case IA64_OPND_IMM17:
5997 /* bit 0 is a don't care (pr0 is hardwired to 1) */
5998 if (e->X_op == O_constant)
5999 {
6000 if (((e->X_add_number >= 0
6001 && (bfd_vma) e->X_add_number < ((bfd_vma) 1 << 17))
6002 || (e->X_add_number < 0
6003 && (bfd_vma) -e->X_add_number <= ((bfd_vma) 1 << 17))))
6004 {
6005 /* sign-extend */
6006 if (e->X_add_number >= 0
6007 && (e->X_add_number & ((bfd_vma) 1 << 16)) != 0)
6008 {
6009 e->X_add_number |= ~(((bfd_vma) 1 << 17) - 1);
6010 }
6011 return OPERAND_MATCH;
6012 }
6013 else
6014 return OPERAND_OUT_OF_RANGE;
6015 }
6016 break;
6017
6018 case IA64_OPND_IMM14:
6019 case IA64_OPND_IMM22:
6020 relocatable = 1;
6021 case IA64_OPND_IMM1:
6022 case IA64_OPND_IMM8:
6023 case IA64_OPND_IMM8U4:
6024 case IA64_OPND_IMM8M1:
6025 case IA64_OPND_IMM8M1U4:
6026 case IA64_OPND_IMM8M1U8:
6027 case IA64_OPND_IMM9a:
6028 case IA64_OPND_IMM9b:
6029 bits = operand_width (idesc->operands[index]);
6030 if (relocatable && (e->X_op == O_symbol
6031 || e->X_op == O_subtract
6032 || e->X_op == O_pseudo_fixup))
6033 {
6034 fix = CURR_SLOT.fixup + CURR_SLOT.num_fixups;
6035
6036 if (idesc->operands[index] == IA64_OPND_IMM14)
6037 fix->code = BFD_RELOC_IA64_IMM14;
6038 else
6039 fix->code = BFD_RELOC_IA64_IMM22;
6040
6041 if (e->X_op != O_subtract)
6042 {
6043 fix->code = ia64_gen_real_reloc_type (e->X_op_symbol, fix->code);
6044 if (e->X_op == O_pseudo_fixup)
6045 e->X_op = O_symbol;
6046 }
6047
6048 fix->opnd = idesc->operands[index];
6049 fix->expr = *e;
6050 fix->is_pcrel = 0;
6051 ++CURR_SLOT.num_fixups;
6052 return OPERAND_MATCH;
6053 }
6054 else if (e->X_op != O_constant
6055 && ! (e->X_op == O_big && opnd == IA64_OPND_IMM8M1U8))
6056 return OPERAND_MISMATCH;
6057
6058 if (opnd == IA64_OPND_IMM8M1U4)
6059 {
6060 /* Zero is not valid for unsigned compares that take an adjusted
6061 constant immediate range. */
6062 if (e->X_add_number == 0)
6063 return OPERAND_OUT_OF_RANGE;
6064
6065 /* Sign-extend 32-bit unsigned numbers, so that the following range
6066 checks will work. */
6067 val = e->X_add_number;
6068 if (((val & (~(bfd_vma) 0 << 32)) == 0)
6069 && ((val & ((bfd_vma) 1 << 31)) != 0))
6070 val = ((val << 32) >> 32);
6071
6072 /* Check for 0x100000000. This is valid because
6073 0x100000000-1 is the same as ((uint32_t) -1). */
6074 if (val == ((bfd_signed_vma) 1 << 32))
6075 return OPERAND_MATCH;
6076
6077 val = val - 1;
6078 }
6079 else if (opnd == IA64_OPND_IMM8M1U8)
6080 {
6081 /* Zero is not valid for unsigned compares that take an adjusted
6082 constant immediate range. */
6083 if (e->X_add_number == 0)
6084 return OPERAND_OUT_OF_RANGE;
6085
6086 /* Check for 0x10000000000000000. */
6087 if (e->X_op == O_big)
6088 {
6089 if (generic_bignum[0] == 0
6090 && generic_bignum[1] == 0
6091 && generic_bignum[2] == 0
6092 && generic_bignum[3] == 0
6093 && generic_bignum[4] == 1)
6094 return OPERAND_MATCH;
6095 else
6096 return OPERAND_OUT_OF_RANGE;
6097 }
6098 else
6099 val = e->X_add_number - 1;
6100 }
6101 else if (opnd == IA64_OPND_IMM8M1)
6102 val = e->X_add_number - 1;
6103 else if (opnd == IA64_OPND_IMM8U4)
6104 {
6105 /* Sign-extend 32-bit unsigned numbers, so that the following range
6106 checks will work. */
6107 val = e->X_add_number;
6108 if (((val & (~(bfd_vma) 0 << 32)) == 0)
6109 && ((val & ((bfd_vma) 1 << 31)) != 0))
6110 val = ((val << 32) >> 32);
6111 }
6112 else
6113 val = e->X_add_number;
6114
6115 if ((val >= 0 && (bfd_vma) val < ((bfd_vma) 1 << (bits - 1)))
6116 || (val < 0 && (bfd_vma) -val <= ((bfd_vma) 1 << (bits - 1))))
6117 return OPERAND_MATCH;
6118 else
6119 return OPERAND_OUT_OF_RANGE;
6120
6121 case IA64_OPND_INC3:
6122 /* +/- 1, 4, 8, 16 */
6123 val = e->X_add_number;
6124 if (val < 0)
6125 val = -val;
6126 if (e->X_op == O_constant)
6127 {
6128 if ((val == 1 || val == 4 || val == 8 || val == 16))
6129 return OPERAND_MATCH;
6130 else
6131 return OPERAND_OUT_OF_RANGE;
6132 }
6133 break;
6134
6135 case IA64_OPND_TGT25:
6136 case IA64_OPND_TGT25b:
6137 case IA64_OPND_TGT25c:
6138 case IA64_OPND_TGT64:
6139 if (e->X_op == O_symbol)
6140 {
6141 fix = CURR_SLOT.fixup + CURR_SLOT.num_fixups;
6142 if (opnd == IA64_OPND_TGT25)
6143 fix->code = BFD_RELOC_IA64_PCREL21F;
6144 else if (opnd == IA64_OPND_TGT25b)
6145 fix->code = BFD_RELOC_IA64_PCREL21M;
6146 else if (opnd == IA64_OPND_TGT25c)
6147 fix->code = BFD_RELOC_IA64_PCREL21B;
6148 else if (opnd == IA64_OPND_TGT64)
6149 fix->code = BFD_RELOC_IA64_PCREL60B;
6150 else
6151 abort ();
6152
6153 fix->code = ia64_gen_real_reloc_type (e->X_op_symbol, fix->code);
6154 fix->opnd = idesc->operands[index];
6155 fix->expr = *e;
6156 fix->is_pcrel = 1;
6157 ++CURR_SLOT.num_fixups;
6158 return OPERAND_MATCH;
6159 }
6160 case IA64_OPND_TAG13:
6161 case IA64_OPND_TAG13b:
6162 switch (e->X_op)
6163 {
6164 case O_constant:
6165 return OPERAND_MATCH;
6166
6167 case O_symbol:
6168 fix = CURR_SLOT.fixup + CURR_SLOT.num_fixups;
6169 /* There are no external relocs for TAG13/TAG13b fields, so we
6170 create a dummy reloc. This will not live past md_apply_fix. */
6171 fix->code = BFD_RELOC_UNUSED;
6172 fix->code = ia64_gen_real_reloc_type (e->X_op_symbol, fix->code);
6173 fix->opnd = idesc->operands[index];
6174 fix->expr = *e;
6175 fix->is_pcrel = 1;
6176 ++CURR_SLOT.num_fixups;
6177 return OPERAND_MATCH;
6178
6179 default:
6180 break;
6181 }
6182 break;
6183
6184 case IA64_OPND_LDXMOV:
6185 fix = CURR_SLOT.fixup + CURR_SLOT.num_fixups;
6186 fix->code = BFD_RELOC_IA64_LDXMOV;
6187 fix->opnd = idesc->operands[index];
6188 fix->expr = *e;
6189 fix->is_pcrel = 0;
6190 ++CURR_SLOT.num_fixups;
6191 return OPERAND_MATCH;
6192
6193 default:
6194 break;
6195 }
6196 return OPERAND_MISMATCH;
6197 }
6198
6199 static int
parse_operand(e,more)6200 parse_operand (e, more)
6201 expressionS *e;
6202 int more;
6203 {
6204 int sep = '\0';
6205
6206 memset (e, 0, sizeof (*e));
6207 e->X_op = O_absent;
6208 SKIP_WHITESPACE ();
6209 expression_and_evaluate (e);
6210 sep = *input_line_pointer;
6211 if (more && (sep == ',' || sep == more))
6212 ++input_line_pointer;
6213 return sep;
6214 }
6215
6216 /* Returns the next entry in the opcode table that matches the one in
6217 IDESC, and frees the entry in IDESC. If no matching entry is
6218 found, NULL is returned instead. */
6219
6220 static struct ia64_opcode *
get_next_opcode(struct ia64_opcode * idesc)6221 get_next_opcode (struct ia64_opcode *idesc)
6222 {
6223 struct ia64_opcode *next = ia64_find_next_opcode (idesc);
6224 ia64_free_opcode (idesc);
6225 return next;
6226 }
6227
6228 /* Parse the operands for the opcode and find the opcode variant that
6229 matches the specified operands, or NULL if no match is possible. */
6230
6231 static struct ia64_opcode *
parse_operands(idesc)6232 parse_operands (idesc)
6233 struct ia64_opcode *idesc;
6234 {
6235 int i = 0, highest_unmatched_operand, num_operands = 0, num_outputs = 0;
6236 int error_pos, out_of_range_pos, curr_out_of_range_pos, sep = 0;
6237 int reg1, reg2;
6238 char reg_class;
6239 enum ia64_opnd expected_operand = IA64_OPND_NIL;
6240 enum operand_match_result result;
6241 char mnemonic[129];
6242 char *first_arg = 0, *end, *saved_input_pointer;
6243 unsigned int sof;
6244
6245 assert (strlen (idesc->name) <= 128);
6246
6247 strcpy (mnemonic, idesc->name);
6248 if (idesc->operands[2] == IA64_OPND_SOF
6249 || idesc->operands[1] == IA64_OPND_SOF)
6250 {
6251 /* To make the common idiom "alloc loc?=ar.pfs,0,1,0,0" work, we
6252 can't parse the first operand until we have parsed the
6253 remaining operands of the "alloc" instruction. */
6254 SKIP_WHITESPACE ();
6255 first_arg = input_line_pointer;
6256 end = strchr (input_line_pointer, '=');
6257 if (!end)
6258 {
6259 as_bad ("Expected separator `='");
6260 return 0;
6261 }
6262 input_line_pointer = end + 1;
6263 ++i;
6264 ++num_outputs;
6265 }
6266
6267 for (; ; ++i)
6268 {
6269 if (i < NELEMS (CURR_SLOT.opnd))
6270 {
6271 sep = parse_operand (CURR_SLOT.opnd + i, '=');
6272 if (CURR_SLOT.opnd[i].X_op == O_absent)
6273 break;
6274 }
6275 else
6276 {
6277 expressionS dummy;
6278
6279 sep = parse_operand (&dummy, '=');
6280 if (dummy.X_op == O_absent)
6281 break;
6282 }
6283
6284 ++num_operands;
6285
6286 if (sep != '=' && sep != ',')
6287 break;
6288
6289 if (sep == '=')
6290 {
6291 if (num_outputs > 0)
6292 as_bad ("Duplicate equal sign (=) in instruction");
6293 else
6294 num_outputs = i + 1;
6295 }
6296 }
6297 if (sep != '\0')
6298 {
6299 as_bad ("Illegal operand separator `%c'", sep);
6300 return 0;
6301 }
6302
6303 if (idesc->operands[2] == IA64_OPND_SOF
6304 || idesc->operands[1] == IA64_OPND_SOF)
6305 {
6306 /* Map alloc r1=ar.pfs,i,l,o,r to alloc r1=ar.pfs,(i+l+o),(i+l),r.
6307 Note, however, that due to that mapping operand numbers in error
6308 messages for any of the constant operands will not be correct. */
6309 know (strcmp (idesc->name, "alloc") == 0);
6310 /* The first operand hasn't been parsed/initialized, yet (but
6311 num_operands intentionally doesn't account for that). */
6312 i = num_operands > 4 ? 2 : 1;
6313 #define FORCE_CONST(n) (CURR_SLOT.opnd[n].X_op == O_constant \
6314 ? CURR_SLOT.opnd[n].X_add_number \
6315 : 0)
6316 sof = set_regstack (FORCE_CONST(i),
6317 FORCE_CONST(i + 1),
6318 FORCE_CONST(i + 2),
6319 FORCE_CONST(i + 3));
6320 #undef FORCE_CONST
6321
6322 /* now we can parse the first arg: */
6323 saved_input_pointer = input_line_pointer;
6324 input_line_pointer = first_arg;
6325 sep = parse_operand (CURR_SLOT.opnd + 0, '=');
6326 if (sep != '=')
6327 --num_outputs; /* force error */
6328 input_line_pointer = saved_input_pointer;
6329
6330 CURR_SLOT.opnd[i].X_add_number = sof;
6331 if (CURR_SLOT.opnd[i + 1].X_op == O_constant
6332 && CURR_SLOT.opnd[i + 2].X_op == O_constant)
6333 CURR_SLOT.opnd[i + 1].X_add_number
6334 = sof - CURR_SLOT.opnd[i + 2].X_add_number;
6335 else
6336 CURR_SLOT.opnd[i + 1].X_op = O_illegal;
6337 CURR_SLOT.opnd[i + 2] = CURR_SLOT.opnd[i + 3];
6338 }
6339
6340 highest_unmatched_operand = -4;
6341 curr_out_of_range_pos = -1;
6342 error_pos = 0;
6343 for (; idesc; idesc = get_next_opcode (idesc))
6344 {
6345 if (num_outputs != idesc->num_outputs)
6346 continue; /* mismatch in # of outputs */
6347 if (highest_unmatched_operand < 0)
6348 highest_unmatched_operand |= 1;
6349 if (num_operands > NELEMS (idesc->operands)
6350 || (num_operands < NELEMS (idesc->operands)
6351 && idesc->operands[num_operands])
6352 || (num_operands > 0 && !idesc->operands[num_operands - 1]))
6353 continue; /* mismatch in number of arguments */
6354 if (highest_unmatched_operand < 0)
6355 highest_unmatched_operand |= 2;
6356
6357 CURR_SLOT.num_fixups = 0;
6358
6359 /* Try to match all operands. If we see an out-of-range operand,
6360 then continue trying to match the rest of the operands, since if
6361 the rest match, then this idesc will give the best error message. */
6362
6363 out_of_range_pos = -1;
6364 for (i = 0; i < num_operands && idesc->operands[i]; ++i)
6365 {
6366 result = operand_match (idesc, i, CURR_SLOT.opnd + i);
6367 if (result != OPERAND_MATCH)
6368 {
6369 if (result != OPERAND_OUT_OF_RANGE)
6370 break;
6371 if (out_of_range_pos < 0)
6372 /* remember position of the first out-of-range operand: */
6373 out_of_range_pos = i;
6374 }
6375 }
6376
6377 /* If we did not match all operands, or if at least one operand was
6378 out-of-range, then this idesc does not match. Keep track of which
6379 idesc matched the most operands before failing. If we have two
6380 idescs that failed at the same position, and one had an out-of-range
6381 operand, then prefer the out-of-range operand. Thus if we have
6382 "add r0=0x1000000,r1" we get an error saying the constant is out
6383 of range instead of an error saying that the constant should have been
6384 a register. */
6385
6386 if (i != num_operands || out_of_range_pos >= 0)
6387 {
6388 if (i > highest_unmatched_operand
6389 || (i == highest_unmatched_operand
6390 && out_of_range_pos > curr_out_of_range_pos))
6391 {
6392 highest_unmatched_operand = i;
6393 if (out_of_range_pos >= 0)
6394 {
6395 expected_operand = idesc->operands[out_of_range_pos];
6396 error_pos = out_of_range_pos;
6397 }
6398 else
6399 {
6400 expected_operand = idesc->operands[i];
6401 error_pos = i;
6402 }
6403 curr_out_of_range_pos = out_of_range_pos;
6404 }
6405 continue;
6406 }
6407
6408 break;
6409 }
6410 if (!idesc)
6411 {
6412 if (expected_operand)
6413 as_bad ("Operand %u of `%s' should be %s",
6414 error_pos + 1, mnemonic,
6415 elf64_ia64_operands[expected_operand].desc);
6416 else if (highest_unmatched_operand < 0 && !(highest_unmatched_operand & 1))
6417 as_bad ("Wrong number of output operands");
6418 else if (highest_unmatched_operand < 0 && !(highest_unmatched_operand & 2))
6419 as_bad ("Wrong number of input operands");
6420 else
6421 as_bad ("Operand mismatch");
6422 return 0;
6423 }
6424
6425 /* Check that the instruction doesn't use
6426 - r0, f0, or f1 as output operands
6427 - the same predicate twice as output operands
6428 - r0 as address of a base update load or store
6429 - the same GR as output and address of a base update load
6430 - two even- or two odd-numbered FRs as output operands of a floating
6431 point parallel load.
6432 At most two (conflicting) output (or output-like) operands can exist,
6433 (floating point parallel loads have three outputs, but the base register,
6434 if updated, cannot conflict with the actual outputs). */
6435 reg2 = reg1 = -1;
6436 for (i = 0; i < num_operands; ++i)
6437 {
6438 int regno = 0;
6439
6440 reg_class = 0;
6441 switch (idesc->operands[i])
6442 {
6443 case IA64_OPND_R1:
6444 case IA64_OPND_R2:
6445 case IA64_OPND_R3:
6446 if (i < num_outputs)
6447 {
6448 if (CURR_SLOT.opnd[i].X_add_number == REG_GR)
6449 reg_class = 'r';
6450 else if (reg1 < 0)
6451 reg1 = CURR_SLOT.opnd[i].X_add_number;
6452 else if (reg2 < 0)
6453 reg2 = CURR_SLOT.opnd[i].X_add_number;
6454 }
6455 break;
6456 case IA64_OPND_P1:
6457 case IA64_OPND_P2:
6458 if (i < num_outputs)
6459 {
6460 if (reg1 < 0)
6461 reg1 = CURR_SLOT.opnd[i].X_add_number;
6462 else if (reg2 < 0)
6463 reg2 = CURR_SLOT.opnd[i].X_add_number;
6464 }
6465 break;
6466 case IA64_OPND_F1:
6467 case IA64_OPND_F2:
6468 case IA64_OPND_F3:
6469 case IA64_OPND_F4:
6470 if (i < num_outputs)
6471 {
6472 if (CURR_SLOT.opnd[i].X_add_number >= REG_FR
6473 && CURR_SLOT.opnd[i].X_add_number <= REG_FR + 1)
6474 {
6475 reg_class = 'f';
6476 regno = CURR_SLOT.opnd[i].X_add_number - REG_FR;
6477 }
6478 else if (reg1 < 0)
6479 reg1 = CURR_SLOT.opnd[i].X_add_number;
6480 else if (reg2 < 0)
6481 reg2 = CURR_SLOT.opnd[i].X_add_number;
6482 }
6483 break;
6484 case IA64_OPND_MR3:
6485 if (idesc->flags & IA64_OPCODE_POSTINC)
6486 {
6487 if (CURR_SLOT.opnd[i].X_add_number == REG_GR)
6488 reg_class = 'm';
6489 else if (reg1 < 0)
6490 reg1 = CURR_SLOT.opnd[i].X_add_number;
6491 else if (reg2 < 0)
6492 reg2 = CURR_SLOT.opnd[i].X_add_number;
6493 }
6494 break;
6495 default:
6496 break;
6497 }
6498 switch (reg_class)
6499 {
6500 case 0:
6501 break;
6502 default:
6503 as_warn ("Invalid use of `%c%d' as output operand", reg_class, regno);
6504 break;
6505 case 'm':
6506 as_warn ("Invalid use of `r%d' as base update address operand", regno);
6507 break;
6508 }
6509 }
6510 if (reg1 == reg2)
6511 {
6512 if (reg1 >= REG_GR && reg1 <= REG_GR + 127)
6513 {
6514 reg1 -= REG_GR;
6515 reg_class = 'r';
6516 }
6517 else if (reg1 >= REG_P && reg1 <= REG_P + 63)
6518 {
6519 reg1 -= REG_P;
6520 reg_class = 'p';
6521 }
6522 else if (reg1 >= REG_FR && reg1 <= REG_FR + 127)
6523 {
6524 reg1 -= REG_FR;
6525 reg_class = 'f';
6526 }
6527 else
6528 reg_class = 0;
6529 if (reg_class)
6530 as_warn ("Invalid duplicate use of `%c%d'", reg_class, reg1);
6531 }
6532 else if (((reg1 >= REG_FR && reg1 <= REG_FR + 31
6533 && reg2 >= REG_FR && reg2 <= REG_FR + 31)
6534 || (reg1 >= REG_FR + 32 && reg1 <= REG_FR + 127
6535 && reg2 >= REG_FR + 32 && reg2 <= REG_FR + 127))
6536 && ! ((reg1 ^ reg2) & 1))
6537 as_warn ("Invalid simultaneous use of `f%d' and `f%d'",
6538 reg1 - REG_FR, reg2 - REG_FR);
6539 else if ((reg1 >= REG_FR && reg1 <= REG_FR + 31
6540 && reg2 >= REG_FR + 32 && reg2 <= REG_FR + 127)
6541 || (reg1 >= REG_FR + 32 && reg1 <= REG_FR + 127
6542 && reg2 >= REG_FR && reg2 <= REG_FR + 31))
6543 as_warn ("Dangerous simultaneous use of `f%d' and `f%d'",
6544 reg1 - REG_FR, reg2 - REG_FR);
6545 return idesc;
6546 }
6547
6548 static void
build_insn(slot,insnp)6549 build_insn (slot, insnp)
6550 struct slot *slot;
6551 bfd_vma *insnp;
6552 {
6553 const struct ia64_operand *odesc, *o2desc;
6554 struct ia64_opcode *idesc = slot->idesc;
6555 bfd_vma insn;
6556 bfd_signed_vma val;
6557 const char *err;
6558 int i;
6559
6560 insn = idesc->opcode | slot->qp_regno;
6561
6562 for (i = 0; i < NELEMS (idesc->operands) && idesc->operands[i]; ++i)
6563 {
6564 if (slot->opnd[i].X_op == O_register
6565 || slot->opnd[i].X_op == O_constant
6566 || slot->opnd[i].X_op == O_index)
6567 val = slot->opnd[i].X_add_number;
6568 else if (slot->opnd[i].X_op == O_big)
6569 {
6570 /* This must be the value 0x10000000000000000. */
6571 assert (idesc->operands[i] == IA64_OPND_IMM8M1U8);
6572 val = 0;
6573 }
6574 else
6575 val = 0;
6576
6577 switch (idesc->operands[i])
6578 {
6579 case IA64_OPND_IMMU64:
6580 *insnp++ = (val >> 22) & 0x1ffffffffffLL;
6581 insn |= (((val & 0x7f) << 13) | (((val >> 7) & 0x1ff) << 27)
6582 | (((val >> 16) & 0x1f) << 22) | (((val >> 21) & 0x1) << 21)
6583 | (((val >> 63) & 0x1) << 36));
6584 continue;
6585
6586 case IA64_OPND_IMMU62:
6587 val &= 0x3fffffffffffffffULL;
6588 if (val != slot->opnd[i].X_add_number)
6589 as_warn (_("Value truncated to 62 bits"));
6590 *insnp++ = (val >> 21) & 0x1ffffffffffLL;
6591 insn |= (((val & 0xfffff) << 6) | (((val >> 20) & 0x1) << 36));
6592 continue;
6593
6594 case IA64_OPND_TGT64:
6595 val >>= 4;
6596 *insnp++ = ((val >> 20) & 0x7fffffffffLL) << 2;
6597 insn |= ((((val >> 59) & 0x1) << 36)
6598 | (((val >> 0) & 0xfffff) << 13));
6599 continue;
6600
6601 case IA64_OPND_AR3:
6602 val -= REG_AR;
6603 break;
6604
6605 case IA64_OPND_B1:
6606 case IA64_OPND_B2:
6607 val -= REG_BR;
6608 break;
6609
6610 case IA64_OPND_CR3:
6611 val -= REG_CR;
6612 break;
6613
6614 case IA64_OPND_F1:
6615 case IA64_OPND_F2:
6616 case IA64_OPND_F3:
6617 case IA64_OPND_F4:
6618 val -= REG_FR;
6619 break;
6620
6621 case IA64_OPND_P1:
6622 case IA64_OPND_P2:
6623 val -= REG_P;
6624 break;
6625
6626 case IA64_OPND_R1:
6627 case IA64_OPND_R2:
6628 case IA64_OPND_R3:
6629 case IA64_OPND_R3_2:
6630 case IA64_OPND_CPUID_R3:
6631 case IA64_OPND_DBR_R3:
6632 case IA64_OPND_DTR_R3:
6633 case IA64_OPND_ITR_R3:
6634 case IA64_OPND_IBR_R3:
6635 case IA64_OPND_MR3:
6636 case IA64_OPND_MSR_R3:
6637 case IA64_OPND_PKR_R3:
6638 case IA64_OPND_PMC_R3:
6639 case IA64_OPND_PMD_R3:
6640 case IA64_OPND_RR_R3:
6641 val -= REG_GR;
6642 break;
6643
6644 default:
6645 break;
6646 }
6647
6648 odesc = elf64_ia64_operands + idesc->operands[i];
6649 err = (*odesc->insert) (odesc, val, &insn);
6650 if (err)
6651 as_bad_where (slot->src_file, slot->src_line,
6652 "Bad operand value: %s", err);
6653 if (idesc->flags & IA64_OPCODE_PSEUDO)
6654 {
6655 if ((idesc->flags & IA64_OPCODE_F2_EQ_F3)
6656 && odesc == elf64_ia64_operands + IA64_OPND_F3)
6657 {
6658 o2desc = elf64_ia64_operands + IA64_OPND_F2;
6659 (*o2desc->insert) (o2desc, val, &insn);
6660 }
6661 if ((idesc->flags & IA64_OPCODE_LEN_EQ_64MCNT)
6662 && (odesc == elf64_ia64_operands + IA64_OPND_CPOS6a
6663 || odesc == elf64_ia64_operands + IA64_OPND_POS6))
6664 {
6665 o2desc = elf64_ia64_operands + IA64_OPND_LEN6;
6666 (*o2desc->insert) (o2desc, 64 - val, &insn);
6667 }
6668 }
6669 }
6670 *insnp = insn;
6671 }
6672
6673 static void
emit_one_bundle()6674 emit_one_bundle ()
6675 {
6676 int manual_bundling_off = 0, manual_bundling = 0;
6677 enum ia64_unit required_unit, insn_unit = 0;
6678 enum ia64_insn_type type[3], insn_type;
6679 unsigned int template, orig_template;
6680 bfd_vma insn[3] = { -1, -1, -1 };
6681 struct ia64_opcode *idesc;
6682 int end_of_insn_group = 0, user_template = -1;
6683 int n, i, j, first, curr, last_slot;
6684 bfd_vma t0 = 0, t1 = 0;
6685 struct label_fix *lfix;
6686 bfd_boolean mark_label;
6687 struct insn_fix *ifix;
6688 char mnemonic[16];
6689 fixS *fix;
6690 char *f;
6691 int addr_mod;
6692
6693 first = (md.curr_slot + NUM_SLOTS - md.num_slots_in_use) % NUM_SLOTS;
6694 know (first >= 0 & first < NUM_SLOTS);
6695 n = MIN (3, md.num_slots_in_use);
6696
6697 /* Determine template: user user_template if specified, best match
6698 otherwise: */
6699
6700 if (md.slot[first].user_template >= 0)
6701 user_template = template = md.slot[first].user_template;
6702 else
6703 {
6704 /* Auto select appropriate template. */
6705 memset (type, 0, sizeof (type));
6706 curr = first;
6707 for (i = 0; i < n; ++i)
6708 {
6709 if (md.slot[curr].label_fixups && i != 0)
6710 break;
6711 type[i] = md.slot[curr].idesc->type;
6712 curr = (curr + 1) % NUM_SLOTS;
6713 }
6714 template = best_template[type[0]][type[1]][type[2]];
6715 }
6716
6717 /* initialize instructions with appropriate nops: */
6718 for (i = 0; i < 3; ++i)
6719 insn[i] = nop[ia64_templ_desc[template].exec_unit[i]];
6720
6721 f = frag_more (16);
6722
6723 /* Check to see if this bundle is at an offset that is a multiple of 16-bytes
6724 from the start of the frag. */
6725 addr_mod = frag_now_fix () & 15;
6726 if (frag_now->has_code && frag_now->insn_addr != addr_mod)
6727 as_bad (_("instruction address is not a multiple of 16"));
6728 frag_now->insn_addr = addr_mod;
6729 frag_now->has_code = 1;
6730
6731 /* now fill in slots with as many insns as possible: */
6732 curr = first;
6733 idesc = md.slot[curr].idesc;
6734 end_of_insn_group = 0;
6735 last_slot = -1;
6736 for (i = 0; i < 3 && md.num_slots_in_use > 0; ++i)
6737 {
6738 /* If we have unwind records, we may need to update some now. */
6739 unw_rec_list *ptr = md.slot[curr].unwind_record;
6740 unw_rec_list *end_ptr = NULL;
6741
6742 if (ptr)
6743 {
6744 /* Find the last prologue/body record in the list for the current
6745 insn, and set the slot number for all records up to that point.
6746 This needs to be done now, because prologue/body records refer to
6747 the current point, not the point after the instruction has been
6748 issued. This matters because there may have been nops emitted
6749 meanwhile. Any non-prologue non-body record followed by a
6750 prologue/body record must also refer to the current point. */
6751 unw_rec_list *last_ptr;
6752
6753 for (j = 1; end_ptr == NULL && j < md.num_slots_in_use; ++j)
6754 end_ptr = md.slot[(curr + j) % NUM_SLOTS].unwind_record;
6755 for (last_ptr = NULL; ptr != end_ptr; ptr = ptr->next)
6756 if (ptr->r.type == prologue || ptr->r.type == prologue_gr
6757 || ptr->r.type == body)
6758 last_ptr = ptr;
6759 if (last_ptr)
6760 {
6761 /* Make last_ptr point one after the last prologue/body
6762 record. */
6763 last_ptr = last_ptr->next;
6764 for (ptr = md.slot[curr].unwind_record; ptr != last_ptr;
6765 ptr = ptr->next)
6766 {
6767 ptr->slot_number = (unsigned long) f + i;
6768 ptr->slot_frag = frag_now;
6769 }
6770 /* Remove the initialized records, so that we won't accidentally
6771 update them again if we insert a nop and continue. */
6772 md.slot[curr].unwind_record = last_ptr;
6773 }
6774 }
6775
6776 manual_bundling_off = md.slot[curr].manual_bundling_off;
6777 if (md.slot[curr].manual_bundling_on)
6778 {
6779 if (curr == first)
6780 manual_bundling = 1;
6781 else
6782 break; /* Need to start a new bundle. */
6783 }
6784
6785 /* If this instruction specifies a template, then it must be the first
6786 instruction of a bundle. */
6787 if (curr != first && md.slot[curr].user_template >= 0)
6788 break;
6789
6790 if (idesc->flags & IA64_OPCODE_SLOT2)
6791 {
6792 if (manual_bundling && !manual_bundling_off)
6793 {
6794 as_bad_where (md.slot[curr].src_file, md.slot[curr].src_line,
6795 "`%s' must be last in bundle", idesc->name);
6796 if (i < 2)
6797 manual_bundling = -1; /* Suppress meaningless post-loop errors. */
6798 }
6799 i = 2;
6800 }
6801 if (idesc->flags & IA64_OPCODE_LAST)
6802 {
6803 int required_slot;
6804 unsigned int required_template;
6805
6806 /* If we need a stop bit after an M slot, our only choice is
6807 template 5 (M;;MI). If we need a stop bit after a B
6808 slot, our only choice is to place it at the end of the
6809 bundle, because the only available templates are MIB,
6810 MBB, BBB, MMB, and MFB. We don't handle anything other
6811 than M and B slots because these are the only kind of
6812 instructions that can have the IA64_OPCODE_LAST bit set. */
6813 required_template = template;
6814 switch (idesc->type)
6815 {
6816 case IA64_TYPE_M:
6817 required_slot = 0;
6818 required_template = 5;
6819 break;
6820
6821 case IA64_TYPE_B:
6822 required_slot = 2;
6823 break;
6824
6825 default:
6826 as_bad_where (md.slot[curr].src_file, md.slot[curr].src_line,
6827 "Internal error: don't know how to force %s to end"
6828 "of instruction group", idesc->name);
6829 required_slot = i;
6830 break;
6831 }
6832 if (manual_bundling
6833 && (i > required_slot
6834 || (required_slot == 2 && !manual_bundling_off)
6835 || (user_template >= 0
6836 /* Changing from MMI to M;MI is OK. */
6837 && (template ^ required_template) > 1)))
6838 {
6839 as_bad_where (md.slot[curr].src_file, md.slot[curr].src_line,
6840 "`%s' must be last in instruction group",
6841 idesc->name);
6842 if (i < 2 && required_slot == 2 && !manual_bundling_off)
6843 manual_bundling = -1; /* Suppress meaningless post-loop errors. */
6844 }
6845 if (required_slot < i)
6846 /* Can't fit this instruction. */
6847 break;
6848
6849 i = required_slot;
6850 if (required_template != template)
6851 {
6852 /* If we switch the template, we need to reset the NOPs
6853 after slot i. The slot-types of the instructions ahead
6854 of i never change, so we don't need to worry about
6855 changing NOPs in front of this slot. */
6856 for (j = i; j < 3; ++j)
6857 insn[j] = nop[ia64_templ_desc[required_template].exec_unit[j]];
6858
6859 /* We just picked a template that includes the stop bit in the
6860 middle, so we don't need another one emitted later. */
6861 md.slot[curr].end_of_insn_group = 0;
6862 }
6863 template = required_template;
6864 }
6865 if (curr != first && md.slot[curr].label_fixups)
6866 {
6867 if (manual_bundling)
6868 {
6869 as_bad_where (md.slot[curr].src_file, md.slot[curr].src_line,
6870 "Label must be first in a bundle");
6871 manual_bundling = -1; /* Suppress meaningless post-loop errors. */
6872 }
6873 /* This insn must go into the first slot of a bundle. */
6874 break;
6875 }
6876
6877 if (end_of_insn_group && md.num_slots_in_use >= 1)
6878 {
6879 /* We need an instruction group boundary in the middle of a
6880 bundle. See if we can switch to an other template with
6881 an appropriate boundary. */
6882
6883 orig_template = template;
6884 if (i == 1 && (user_template == 4
6885 || (user_template < 0
6886 && (ia64_templ_desc[template].exec_unit[0]
6887 == IA64_UNIT_M))))
6888 {
6889 template = 5;
6890 end_of_insn_group = 0;
6891 }
6892 else if (i == 2 && (user_template == 0
6893 || (user_template < 0
6894 && (ia64_templ_desc[template].exec_unit[1]
6895 == IA64_UNIT_I)))
6896 /* This test makes sure we don't switch the template if
6897 the next instruction is one that needs to be first in
6898 an instruction group. Since all those instructions are
6899 in the M group, there is no way such an instruction can
6900 fit in this bundle even if we switch the template. The
6901 reason we have to check for this is that otherwise we
6902 may end up generating "MI;;I M.." which has the deadly
6903 effect that the second M instruction is no longer the
6904 first in the group! --davidm 99/12/16 */
6905 && (idesc->flags & IA64_OPCODE_FIRST) == 0)
6906 {
6907 template = 1;
6908 end_of_insn_group = 0;
6909 }
6910 else if (i == 1
6911 && user_template == 0
6912 && !(idesc->flags & IA64_OPCODE_FIRST))
6913 /* Use the next slot. */
6914 continue;
6915 else if (curr != first)
6916 /* can't fit this insn */
6917 break;
6918
6919 if (template != orig_template)
6920 /* if we switch the template, we need to reset the NOPs
6921 after slot i. The slot-types of the instructions ahead
6922 of i never change, so we don't need to worry about
6923 changing NOPs in front of this slot. */
6924 for (j = i; j < 3; ++j)
6925 insn[j] = nop[ia64_templ_desc[template].exec_unit[j]];
6926 }
6927 required_unit = ia64_templ_desc[template].exec_unit[i];
6928
6929 /* resolve dynamic opcodes such as "break", "hint", and "nop": */
6930 if (idesc->type == IA64_TYPE_DYN)
6931 {
6932 enum ia64_opnd opnd1, opnd2;
6933
6934 if ((strcmp (idesc->name, "nop") == 0)
6935 || (strcmp (idesc->name, "break") == 0))
6936 insn_unit = required_unit;
6937 else if (strcmp (idesc->name, "hint") == 0)
6938 {
6939 insn_unit = required_unit;
6940 if (required_unit == IA64_UNIT_B)
6941 {
6942 switch (md.hint_b)
6943 {
6944 case hint_b_ok:
6945 break;
6946 case hint_b_warning:
6947 as_warn ("hint in B unit may be treated as nop");
6948 break;
6949 case hint_b_error:
6950 /* When manual bundling is off and there is no
6951 user template, we choose a different unit so
6952 that hint won't go into the current slot. We
6953 will fill the current bundle with nops and
6954 try to put hint into the next bundle. */
6955 if (!manual_bundling && user_template < 0)
6956 insn_unit = IA64_UNIT_I;
6957 else
6958 as_bad ("hint in B unit can't be used");
6959 break;
6960 }
6961 }
6962 }
6963 else if (strcmp (idesc->name, "chk.s") == 0
6964 || strcmp (idesc->name, "mov") == 0)
6965 {
6966 insn_unit = IA64_UNIT_M;
6967 if (required_unit == IA64_UNIT_I
6968 || (required_unit == IA64_UNIT_F && template == 6))
6969 insn_unit = IA64_UNIT_I;
6970 }
6971 else
6972 as_fatal ("emit_one_bundle: unexpected dynamic op");
6973
6974 sprintf (mnemonic, "%s.%c", idesc->name, "?imbfxx"[insn_unit]);
6975 opnd1 = idesc->operands[0];
6976 opnd2 = idesc->operands[1];
6977 ia64_free_opcode (idesc);
6978 idesc = ia64_find_opcode (mnemonic);
6979 /* moves to/from ARs have collisions */
6980 if (opnd1 == IA64_OPND_AR3 || opnd2 == IA64_OPND_AR3)
6981 {
6982 while (idesc != NULL
6983 && (idesc->operands[0] != opnd1
6984 || idesc->operands[1] != opnd2))
6985 idesc = get_next_opcode (idesc);
6986 }
6987 md.slot[curr].idesc = idesc;
6988 }
6989 else
6990 {
6991 insn_type = idesc->type;
6992 insn_unit = IA64_UNIT_NIL;
6993 switch (insn_type)
6994 {
6995 case IA64_TYPE_A:
6996 if (required_unit == IA64_UNIT_I || required_unit == IA64_UNIT_M)
6997 insn_unit = required_unit;
6998 break;
6999 case IA64_TYPE_X: insn_unit = IA64_UNIT_L; break;
7000 case IA64_TYPE_I: insn_unit = IA64_UNIT_I; break;
7001 case IA64_TYPE_M: insn_unit = IA64_UNIT_M; break;
7002 case IA64_TYPE_B: insn_unit = IA64_UNIT_B; break;
7003 case IA64_TYPE_F: insn_unit = IA64_UNIT_F; break;
7004 default: break;
7005 }
7006 }
7007
7008 if (insn_unit != required_unit)
7009 continue; /* Try next slot. */
7010
7011 /* Now is a good time to fix up the labels for this insn. */
7012 mark_label = FALSE;
7013 for (lfix = md.slot[curr].label_fixups; lfix; lfix = lfix->next)
7014 {
7015 S_SET_VALUE (lfix->sym, frag_now_fix () - 16);
7016 symbol_set_frag (lfix->sym, frag_now);
7017 mark_label |= lfix->dw2_mark_labels;
7018 }
7019 for (lfix = md.slot[curr].tag_fixups; lfix; lfix = lfix->next)
7020 {
7021 S_SET_VALUE (lfix->sym, frag_now_fix () - 16 + i);
7022 symbol_set_frag (lfix->sym, frag_now);
7023 }
7024
7025 if (debug_type == DEBUG_DWARF2
7026 || md.slot[curr].loc_directive_seen
7027 || mark_label)
7028 {
7029 bfd_vma addr = frag_now->fr_address + frag_now_fix () - 16 + i;
7030
7031 md.slot[curr].loc_directive_seen = 0;
7032 if (mark_label)
7033 md.slot[curr].debug_line.flags |= DWARF2_FLAG_BASIC_BLOCK;
7034
7035 dwarf2_gen_line_info (addr, &md.slot[curr].debug_line);
7036 }
7037
7038 build_insn (md.slot + curr, insn + i);
7039
7040 ptr = md.slot[curr].unwind_record;
7041 if (ptr)
7042 {
7043 /* Set slot numbers for all remaining unwind records belonging to the
7044 current insn. There can not be any prologue/body unwind records
7045 here. */
7046 for (; ptr != end_ptr; ptr = ptr->next)
7047 {
7048 ptr->slot_number = (unsigned long) f + i;
7049 ptr->slot_frag = frag_now;
7050 }
7051 md.slot[curr].unwind_record = NULL;
7052 }
7053
7054 if (required_unit == IA64_UNIT_L)
7055 {
7056 know (i == 1);
7057 /* skip one slot for long/X-unit instructions */
7058 ++i;
7059 }
7060 --md.num_slots_in_use;
7061 last_slot = i;
7062
7063 for (j = 0; j < md.slot[curr].num_fixups; ++j)
7064 {
7065 ifix = md.slot[curr].fixup + j;
7066 fix = fix_new_exp (frag_now, frag_now_fix () - 16 + i, 8,
7067 &ifix->expr, ifix->is_pcrel, ifix->code);
7068 fix->tc_fix_data.opnd = ifix->opnd;
7069 fix->fx_plt = (fix->fx_r_type == BFD_RELOC_IA64_PLTOFF22);
7070 fix->fx_file = md.slot[curr].src_file;
7071 fix->fx_line = md.slot[curr].src_line;
7072 }
7073
7074 end_of_insn_group = md.slot[curr].end_of_insn_group;
7075
7076 /* clear slot: */
7077 ia64_free_opcode (md.slot[curr].idesc);
7078 memset (md.slot + curr, 0, sizeof (md.slot[curr]));
7079 md.slot[curr].user_template = -1;
7080
7081 if (manual_bundling_off)
7082 {
7083 manual_bundling = 0;
7084 break;
7085 }
7086 curr = (curr + 1) % NUM_SLOTS;
7087 idesc = md.slot[curr].idesc;
7088 }
7089
7090 /* A user template was specified, but the first following instruction did
7091 not fit. This can happen with or without manual bundling. */
7092 if (md.num_slots_in_use > 0 && last_slot < 0)
7093 {
7094 as_bad_where (md.slot[curr].src_file, md.slot[curr].src_line,
7095 "`%s' does not fit into %s template",
7096 idesc->name, ia64_templ_desc[template].name);
7097 /* Drop first insn so we don't livelock. */
7098 --md.num_slots_in_use;
7099 know (curr == first);
7100 ia64_free_opcode (md.slot[curr].idesc);
7101 memset (md.slot + curr, 0, sizeof (md.slot[curr]));
7102 md.slot[curr].user_template = -1;
7103 }
7104 else if (manual_bundling > 0)
7105 {
7106 if (md.num_slots_in_use > 0)
7107 {
7108 if (last_slot >= 2)
7109 as_bad_where (md.slot[curr].src_file, md.slot[curr].src_line,
7110 "`%s' does not fit into bundle", idesc->name);
7111 else
7112 {
7113 const char *where;
7114
7115 if (template == 2)
7116 where = "X slot";
7117 else if (last_slot == 0)
7118 where = "slots 2 or 3";
7119 else
7120 where = "slot 3";
7121 as_bad_where (md.slot[curr].src_file, md.slot[curr].src_line,
7122 "`%s' can't go in %s of %s template",
7123 idesc->name, where, ia64_templ_desc[template].name);
7124 }
7125 }
7126 else
7127 as_bad_where (md.slot[curr].src_file, md.slot[curr].src_line,
7128 "Missing '}' at end of file");
7129 }
7130
7131 know (md.num_slots_in_use < NUM_SLOTS);
7132
7133 t0 = end_of_insn_group | (template << 1) | (insn[0] << 5) | (insn[1] << 46);
7134 t1 = ((insn[1] >> 18) & 0x7fffff) | (insn[2] << 23);
7135
7136 number_to_chars_littleendian (f + 0, t0, 8);
7137 number_to_chars_littleendian (f + 8, t1, 8);
7138 }
7139
7140 int
md_parse_option(c,arg)7141 md_parse_option (c, arg)
7142 int c;
7143 char *arg;
7144 {
7145
7146 switch (c)
7147 {
7148 /* Switches from the Intel assembler. */
7149 case 'm':
7150 if (strcmp (arg, "ilp64") == 0
7151 || strcmp (arg, "lp64") == 0
7152 || strcmp (arg, "p64") == 0)
7153 {
7154 md.flags |= EF_IA_64_ABI64;
7155 }
7156 else if (strcmp (arg, "ilp32") == 0)
7157 {
7158 md.flags &= ~EF_IA_64_ABI64;
7159 }
7160 else if (strcmp (arg, "le") == 0)
7161 {
7162 md.flags &= ~EF_IA_64_BE;
7163 default_big_endian = 0;
7164 }
7165 else if (strcmp (arg, "be") == 0)
7166 {
7167 md.flags |= EF_IA_64_BE;
7168 default_big_endian = 1;
7169 }
7170 else if (strncmp (arg, "unwind-check=", 13) == 0)
7171 {
7172 arg += 13;
7173 if (strcmp (arg, "warning") == 0)
7174 md.unwind_check = unwind_check_warning;
7175 else if (strcmp (arg, "error") == 0)
7176 md.unwind_check = unwind_check_error;
7177 else
7178 return 0;
7179 }
7180 else if (strncmp (arg, "hint.b=", 7) == 0)
7181 {
7182 arg += 7;
7183 if (strcmp (arg, "ok") == 0)
7184 md.hint_b = hint_b_ok;
7185 else if (strcmp (arg, "warning") == 0)
7186 md.hint_b = hint_b_warning;
7187 else if (strcmp (arg, "error") == 0)
7188 md.hint_b = hint_b_error;
7189 else
7190 return 0;
7191 }
7192 else if (strncmp (arg, "tune=", 5) == 0)
7193 {
7194 arg += 5;
7195 if (strcmp (arg, "itanium1") == 0)
7196 md.tune = itanium1;
7197 else if (strcmp (arg, "itanium2") == 0)
7198 md.tune = itanium2;
7199 else
7200 return 0;
7201 }
7202 else
7203 return 0;
7204 break;
7205
7206 case 'N':
7207 if (strcmp (arg, "so") == 0)
7208 {
7209 /* Suppress signon message. */
7210 }
7211 else if (strcmp (arg, "pi") == 0)
7212 {
7213 /* Reject privileged instructions. FIXME */
7214 }
7215 else if (strcmp (arg, "us") == 0)
7216 {
7217 /* Allow union of signed and unsigned range. FIXME */
7218 }
7219 else if (strcmp (arg, "close_fcalls") == 0)
7220 {
7221 /* Do not resolve global function calls. */
7222 }
7223 else
7224 return 0;
7225 break;
7226
7227 case 'C':
7228 /* temp[="prefix"] Insert temporary labels into the object file
7229 symbol table prefixed by "prefix".
7230 Default prefix is ":temp:".
7231 */
7232 break;
7233
7234 case 'a':
7235 /* indirect=<tgt> Assume unannotated indirect branches behavior
7236 according to <tgt> --
7237 exit: branch out from the current context (default)
7238 labels: all labels in context may be branch targets
7239 */
7240 if (strncmp (arg, "indirect=", 9) != 0)
7241 return 0;
7242 break;
7243
7244 case 'x':
7245 /* -X conflicts with an ignored option, use -x instead */
7246 md.detect_dv = 1;
7247 if (!arg || strcmp (arg, "explicit") == 0)
7248 {
7249 /* set default mode to explicit */
7250 md.default_explicit_mode = 1;
7251 break;
7252 }
7253 else if (strcmp (arg, "auto") == 0)
7254 {
7255 md.default_explicit_mode = 0;
7256 }
7257 else if (strcmp (arg, "none") == 0)
7258 {
7259 md.detect_dv = 0;
7260 }
7261 else if (strcmp (arg, "debug") == 0)
7262 {
7263 md.debug_dv = 1;
7264 }
7265 else if (strcmp (arg, "debugx") == 0)
7266 {
7267 md.default_explicit_mode = 1;
7268 md.debug_dv = 1;
7269 }
7270 else if (strcmp (arg, "debugn") == 0)
7271 {
7272 md.debug_dv = 1;
7273 md.detect_dv = 0;
7274 }
7275 else
7276 {
7277 as_bad (_("Unrecognized option '-x%s'"), arg);
7278 }
7279 break;
7280
7281 case 'S':
7282 /* nops Print nops statistics. */
7283 break;
7284
7285 /* GNU specific switches for gcc. */
7286 case OPTION_MCONSTANT_GP:
7287 md.flags |= EF_IA_64_CONS_GP;
7288 break;
7289
7290 case OPTION_MAUTO_PIC:
7291 md.flags |= EF_IA_64_NOFUNCDESC_CONS_GP;
7292 break;
7293
7294 default:
7295 return 0;
7296 }
7297
7298 return 1;
7299 }
7300
7301 void
md_show_usage(stream)7302 md_show_usage (stream)
7303 FILE *stream;
7304 {
7305 fputs (_("\
7306 IA-64 options:\n\
7307 --mconstant-gp mark output file as using the constant-GP model\n\
7308 (sets ELF header flag EF_IA_64_CONS_GP)\n\
7309 --mauto-pic mark output file as using the constant-GP model\n\
7310 without function descriptors (sets ELF header flag\n\
7311 EF_IA_64_NOFUNCDESC_CONS_GP)\n\
7312 -milp32|-milp64|-mlp64|-mp64 select data model (default -mlp64)\n\
7313 -mle | -mbe select little- or big-endian byte order (default -mle)\n\
7314 -mtune=[itanium1|itanium2]\n\
7315 tune for a specific CPU (default -mtune=itanium2)\n\
7316 -munwind-check=[warning|error]\n\
7317 unwind directive check (default -munwind-check=warning)\n\
7318 -mhint.b=[ok|warning|error]\n\
7319 hint.b check (default -mhint.b=error)\n\
7320 -x | -xexplicit turn on dependency violation checking\n\
7321 -xauto automagically remove dependency violations (default)\n\
7322 -xnone turn off dependency violation checking\n\
7323 -xdebug debug dependency violation checker\n\
7324 -xdebugn debug dependency violation checker but turn off\n\
7325 dependency violation checking\n\
7326 -xdebugx debug dependency violation checker and turn on\n\
7327 dependency violation checking\n"),
7328 stream);
7329 }
7330
7331 void
ia64_after_parse_args()7332 ia64_after_parse_args ()
7333 {
7334 if (debug_type == DEBUG_STABS)
7335 as_fatal (_("--gstabs is not supported for ia64"));
7336 }
7337
7338 /* Return true if TYPE fits in TEMPL at SLOT. */
7339
7340 static int
match(int templ,int type,int slot)7341 match (int templ, int type, int slot)
7342 {
7343 enum ia64_unit unit;
7344 int result;
7345
7346 unit = ia64_templ_desc[templ].exec_unit[slot];
7347 switch (type)
7348 {
7349 case IA64_TYPE_DYN: result = 1; break; /* for nop and break */
7350 case IA64_TYPE_A:
7351 result = (unit == IA64_UNIT_I || unit == IA64_UNIT_M);
7352 break;
7353 case IA64_TYPE_X: result = (unit == IA64_UNIT_L); break;
7354 case IA64_TYPE_I: result = (unit == IA64_UNIT_I); break;
7355 case IA64_TYPE_M: result = (unit == IA64_UNIT_M); break;
7356 case IA64_TYPE_B: result = (unit == IA64_UNIT_B); break;
7357 case IA64_TYPE_F: result = (unit == IA64_UNIT_F); break;
7358 default: result = 0; break;
7359 }
7360 return result;
7361 }
7362
7363 /* For Itanium 1, add a bit of extra goodness if a nop of type F or B would fit
7364 in TEMPL at SLOT. For Itanium 2, add a bit of extra goodness if a nop of
7365 type M or I would fit in TEMPL at SLOT. */
7366
7367 static inline int
extra_goodness(int templ,int slot)7368 extra_goodness (int templ, int slot)
7369 {
7370 switch (md.tune)
7371 {
7372 case itanium1:
7373 if (slot == 1 && match (templ, IA64_TYPE_F, slot))
7374 return 2;
7375 else if (slot == 2 && match (templ, IA64_TYPE_B, slot))
7376 return 1;
7377 else
7378 return 0;
7379 break;
7380 case itanium2:
7381 if (match (templ, IA64_TYPE_M, slot)
7382 || match (templ, IA64_TYPE_I, slot))
7383 /* Favor M- and I-unit NOPs. We definitely want to avoid
7384 F-unit and B-unit may cause split-issue or less-than-optimal
7385 branch-prediction. */
7386 return 2;
7387 else
7388 return 0;
7389 break;
7390 default:
7391 abort ();
7392 return 0;
7393 }
7394 }
7395
7396 /* This function is called once, at assembler startup time. It sets
7397 up all the tables, etc. that the MD part of the assembler will need
7398 that can be determined before arguments are parsed. */
7399 void
md_begin()7400 md_begin ()
7401 {
7402 int i, j, k, t, goodness, best, ok;
7403 const char *err;
7404 char name[8];
7405
7406 md.auto_align = 1;
7407 md.explicit_mode = md.default_explicit_mode;
7408
7409 bfd_set_section_alignment (stdoutput, text_section, 4);
7410
7411 /* Make sure function pointers get initialized. */
7412 target_big_endian = -1;
7413 dot_byteorder (default_big_endian);
7414
7415 alias_hash = hash_new ();
7416 alias_name_hash = hash_new ();
7417 secalias_hash = hash_new ();
7418 secalias_name_hash = hash_new ();
7419
7420 pseudo_func[FUNC_DTP_MODULE].u.sym =
7421 symbol_new (".<dtpmod>", undefined_section, FUNC_DTP_MODULE,
7422 &zero_address_frag);
7423
7424 pseudo_func[FUNC_DTP_RELATIVE].u.sym =
7425 symbol_new (".<dtprel>", undefined_section, FUNC_DTP_RELATIVE,
7426 &zero_address_frag);
7427
7428 pseudo_func[FUNC_FPTR_RELATIVE].u.sym =
7429 symbol_new (".<fptr>", undefined_section, FUNC_FPTR_RELATIVE,
7430 &zero_address_frag);
7431
7432 pseudo_func[FUNC_GP_RELATIVE].u.sym =
7433 symbol_new (".<gprel>", undefined_section, FUNC_GP_RELATIVE,
7434 &zero_address_frag);
7435
7436 pseudo_func[FUNC_LT_RELATIVE].u.sym =
7437 symbol_new (".<ltoff>", undefined_section, FUNC_LT_RELATIVE,
7438 &zero_address_frag);
7439
7440 pseudo_func[FUNC_LT_RELATIVE_X].u.sym =
7441 symbol_new (".<ltoffx>", undefined_section, FUNC_LT_RELATIVE_X,
7442 &zero_address_frag);
7443
7444 pseudo_func[FUNC_PC_RELATIVE].u.sym =
7445 symbol_new (".<pcrel>", undefined_section, FUNC_PC_RELATIVE,
7446 &zero_address_frag);
7447
7448 pseudo_func[FUNC_PLT_RELATIVE].u.sym =
7449 symbol_new (".<pltoff>", undefined_section, FUNC_PLT_RELATIVE,
7450 &zero_address_frag);
7451
7452 pseudo_func[FUNC_SEC_RELATIVE].u.sym =
7453 symbol_new (".<secrel>", undefined_section, FUNC_SEC_RELATIVE,
7454 &zero_address_frag);
7455
7456 pseudo_func[FUNC_SEG_RELATIVE].u.sym =
7457 symbol_new (".<segrel>", undefined_section, FUNC_SEG_RELATIVE,
7458 &zero_address_frag);
7459
7460 pseudo_func[FUNC_TP_RELATIVE].u.sym =
7461 symbol_new (".<tprel>", undefined_section, FUNC_TP_RELATIVE,
7462 &zero_address_frag);
7463
7464 pseudo_func[FUNC_LTV_RELATIVE].u.sym =
7465 symbol_new (".<ltv>", undefined_section, FUNC_LTV_RELATIVE,
7466 &zero_address_frag);
7467
7468 pseudo_func[FUNC_LT_FPTR_RELATIVE].u.sym =
7469 symbol_new (".<ltoff.fptr>", undefined_section, FUNC_LT_FPTR_RELATIVE,
7470 &zero_address_frag);
7471
7472 pseudo_func[FUNC_LT_DTP_MODULE].u.sym =
7473 symbol_new (".<ltoff.dtpmod>", undefined_section, FUNC_LT_DTP_MODULE,
7474 &zero_address_frag);
7475
7476 pseudo_func[FUNC_LT_DTP_RELATIVE].u.sym =
7477 symbol_new (".<ltoff.dptrel>", undefined_section, FUNC_LT_DTP_RELATIVE,
7478 &zero_address_frag);
7479
7480 pseudo_func[FUNC_LT_TP_RELATIVE].u.sym =
7481 symbol_new (".<ltoff.tprel>", undefined_section, FUNC_LT_TP_RELATIVE,
7482 &zero_address_frag);
7483
7484 pseudo_func[FUNC_IPLT_RELOC].u.sym =
7485 symbol_new (".<iplt>", undefined_section, FUNC_IPLT_RELOC,
7486 &zero_address_frag);
7487
7488 if (md.tune != itanium1)
7489 {
7490 /* Convert MFI NOPs bundles into MMI NOPs bundles. */
7491 le_nop[0] = 0x8;
7492 le_nop_stop[0] = 0x9;
7493 }
7494
7495 /* Compute the table of best templates. We compute goodness as a
7496 base 4 value, in which each match counts for 3. Match-failures
7497 result in NOPs and we use extra_goodness() to pick the execution
7498 units that are best suited for issuing the NOP. */
7499 for (i = 0; i < IA64_NUM_TYPES; ++i)
7500 for (j = 0; j < IA64_NUM_TYPES; ++j)
7501 for (k = 0; k < IA64_NUM_TYPES; ++k)
7502 {
7503 best = 0;
7504 for (t = 0; t < NELEMS (ia64_templ_desc); ++t)
7505 {
7506 goodness = 0;
7507 if (match (t, i, 0))
7508 {
7509 if (match (t, j, 1))
7510 {
7511 if ((t == 2 && j == IA64_TYPE_X) || match (t, k, 2))
7512 goodness = 3 + 3 + 3;
7513 else
7514 goodness = 3 + 3 + extra_goodness (t, 2);
7515 }
7516 else if (match (t, j, 2))
7517 goodness = 3 + 3 + extra_goodness (t, 1);
7518 else
7519 {
7520 goodness = 3;
7521 goodness += extra_goodness (t, 1);
7522 goodness += extra_goodness (t, 2);
7523 }
7524 }
7525 else if (match (t, i, 1))
7526 {
7527 if ((t == 2 && i == IA64_TYPE_X) || match (t, j, 2))
7528 goodness = 3 + 3;
7529 else
7530 goodness = 3 + extra_goodness (t, 2);
7531 }
7532 else if (match (t, i, 2))
7533 goodness = 3 + extra_goodness (t, 1);
7534
7535 if (goodness > best)
7536 {
7537 best = goodness;
7538 best_template[i][j][k] = t;
7539 }
7540 }
7541 }
7542
7543 #ifdef DEBUG_TEMPLATES
7544 /* For debugging changes to the best_template calculations. We don't care
7545 about combinations with invalid instructions, so start the loops at 1. */
7546 for (i = 0; i < IA64_NUM_TYPES; ++i)
7547 for (j = 0; j < IA64_NUM_TYPES; ++j)
7548 for (k = 0; k < IA64_NUM_TYPES; ++k)
7549 {
7550 char type_letter[IA64_NUM_TYPES] = { 'n', 'a', 'i', 'm', 'b', 'f',
7551 'x', 'd' };
7552 fprintf (stderr, "%c%c%c %s\n", type_letter[i], type_letter[j],
7553 type_letter[k],
7554 ia64_templ_desc[best_template[i][j][k]].name);
7555 }
7556 #endif
7557
7558 for (i = 0; i < NUM_SLOTS; ++i)
7559 md.slot[i].user_template = -1;
7560
7561 md.pseudo_hash = hash_new ();
7562 for (i = 0; i < NELEMS (pseudo_opcode); ++i)
7563 {
7564 err = hash_insert (md.pseudo_hash, pseudo_opcode[i].name,
7565 (void *) (pseudo_opcode + i));
7566 if (err)
7567 as_fatal ("ia64.md_begin: can't hash `%s': %s",
7568 pseudo_opcode[i].name, err);
7569 }
7570
7571 md.reg_hash = hash_new ();
7572 md.dynreg_hash = hash_new ();
7573 md.const_hash = hash_new ();
7574 md.entry_hash = hash_new ();
7575
7576 /* general registers: */
7577 declare_register_set ("r", 128, REG_GR);
7578 declare_register ("gp", REG_GR + 1);
7579 declare_register ("sp", REG_GR + 12);
7580 declare_register ("tp", REG_GR + 13);
7581 declare_register_set ("ret", 4, REG_GR + 8);
7582
7583 /* floating point registers: */
7584 declare_register_set ("f", 128, REG_FR);
7585 declare_register_set ("farg", 8, REG_FR + 8);
7586 declare_register_set ("fret", 8, REG_FR + 8);
7587
7588 /* branch registers: */
7589 declare_register_set ("b", 8, REG_BR);
7590 declare_register ("rp", REG_BR + 0);
7591
7592 /* predicate registers: */
7593 declare_register_set ("p", 64, REG_P);
7594 declare_register ("pr", REG_PR);
7595 declare_register ("pr.rot", REG_PR_ROT);
7596
7597 /* application registers: */
7598 declare_register_set ("ar", 128, REG_AR);
7599 for (i = 0; i < NELEMS (ar); ++i)
7600 declare_register (ar[i].name, REG_AR + ar[i].regnum);
7601
7602 /* control registers: */
7603 declare_register_set ("cr", 128, REG_CR);
7604 for (i = 0; i < NELEMS (cr); ++i)
7605 declare_register (cr[i].name, REG_CR + cr[i].regnum);
7606
7607 declare_register ("ip", REG_IP);
7608 declare_register ("cfm", REG_CFM);
7609 declare_register ("psr", REG_PSR);
7610 declare_register ("psr.l", REG_PSR_L);
7611 declare_register ("psr.um", REG_PSR_UM);
7612
7613 for (i = 0; i < NELEMS (indirect_reg); ++i)
7614 {
7615 unsigned int regnum = indirect_reg[i].regnum;
7616
7617 md.indregsym[regnum - IND_CPUID] = declare_register (indirect_reg[i].name, regnum);
7618 }
7619
7620 /* pseudo-registers used to specify unwind info: */
7621 declare_register ("psp", REG_PSP);
7622
7623 for (i = 0; i < NELEMS (const_bits); ++i)
7624 {
7625 err = hash_insert (md.const_hash, const_bits[i].name,
7626 (PTR) (const_bits + i));
7627 if (err)
7628 as_fatal ("Inserting \"%s\" into constant hash table failed: %s",
7629 name, err);
7630 }
7631
7632 /* Set the architecture and machine depending on defaults and command line
7633 options. */
7634 if (md.flags & EF_IA_64_ABI64)
7635 ok = bfd_set_arch_mach (stdoutput, bfd_arch_ia64, bfd_mach_ia64_elf64);
7636 else
7637 ok = bfd_set_arch_mach (stdoutput, bfd_arch_ia64, bfd_mach_ia64_elf32);
7638
7639 if (! ok)
7640 as_warn (_("Could not set architecture and machine"));
7641
7642 /* Set the pointer size and pointer shift size depending on md.flags */
7643
7644 if (md.flags & EF_IA_64_ABI64)
7645 {
7646 md.pointer_size = 8; /* pointers are 8 bytes */
7647 md.pointer_size_shift = 3; /* alignment is 8 bytes = 2^2 */
7648 }
7649 else
7650 {
7651 md.pointer_size = 4; /* pointers are 4 bytes */
7652 md.pointer_size_shift = 2; /* alignment is 4 bytes = 2^2 */
7653 }
7654
7655 md.mem_offset.hint = 0;
7656 md.path = 0;
7657 md.maxpaths = 0;
7658 md.entry_labels = NULL;
7659 }
7660
7661 /* Set the default options in md. Cannot do this in md_begin because
7662 that is called after md_parse_option which is where we set the
7663 options in md based on command line options. */
7664
7665 void
ia64_init(argc,argv)7666 ia64_init (argc, argv)
7667 int argc ATTRIBUTE_UNUSED;
7668 char **argv ATTRIBUTE_UNUSED;
7669 {
7670 md.flags = MD_FLAGS_DEFAULT;
7671 md.detect_dv = 1;
7672 /* FIXME: We should change it to unwind_check_error someday. */
7673 md.unwind_check = unwind_check_warning;
7674 md.hint_b = hint_b_error;
7675 md.tune = itanium2;
7676 }
7677
7678 /* Return a string for the target object file format. */
7679
7680 const char *
ia64_target_format()7681 ia64_target_format ()
7682 {
7683 if (OUTPUT_FLAVOR == bfd_target_elf_flavour)
7684 {
7685 if (md.flags & EF_IA_64_BE)
7686 {
7687 if (md.flags & EF_IA_64_ABI64)
7688 #if defined(TE_AIX50)
7689 return "elf64-ia64-aix-big";
7690 #elif defined(TE_HPUX)
7691 return "elf64-ia64-hpux-big";
7692 #else
7693 return "elf64-ia64-big";
7694 #endif
7695 else
7696 #if defined(TE_AIX50)
7697 return "elf32-ia64-aix-big";
7698 #elif defined(TE_HPUX)
7699 return "elf32-ia64-hpux-big";
7700 #else
7701 return "elf32-ia64-big";
7702 #endif
7703 }
7704 else
7705 {
7706 if (md.flags & EF_IA_64_ABI64)
7707 #ifdef TE_AIX50
7708 return "elf64-ia64-aix-little";
7709 #else
7710 return "elf64-ia64-little";
7711 #endif
7712 else
7713 #ifdef TE_AIX50
7714 return "elf32-ia64-aix-little";
7715 #else
7716 return "elf32-ia64-little";
7717 #endif
7718 }
7719 }
7720 else
7721 return "unknown-format";
7722 }
7723
7724 void
ia64_end_of_source()7725 ia64_end_of_source ()
7726 {
7727 /* terminate insn group upon reaching end of file: */
7728 insn_group_break (1, 0, 0);
7729
7730 /* emits slots we haven't written yet: */
7731 ia64_flush_insns ();
7732
7733 bfd_set_private_flags (stdoutput, md.flags);
7734
7735 md.mem_offset.hint = 0;
7736 }
7737
7738 void
ia64_start_line()7739 ia64_start_line ()
7740 {
7741 static int first;
7742
7743 if (!first) {
7744 /* Make sure we don't reference input_line_pointer[-1] when that's
7745 not valid. */
7746 first = 1;
7747 return;
7748 }
7749
7750 if (md.qp.X_op == O_register)
7751 as_bad ("qualifying predicate not followed by instruction");
7752 md.qp.X_op = O_absent;
7753
7754 if (ignore_input ())
7755 return;
7756
7757 if (input_line_pointer[0] == ';' && input_line_pointer[-1] == ';')
7758 {
7759 if (md.detect_dv && !md.explicit_mode)
7760 {
7761 static int warned;
7762
7763 if (!warned)
7764 {
7765 warned = 1;
7766 as_warn (_("Explicit stops are ignored in auto mode"));
7767 }
7768 }
7769 else
7770 insn_group_break (1, 0, 0);
7771 }
7772 else if (input_line_pointer[-1] == '{')
7773 {
7774 if (md.manual_bundling)
7775 as_warn ("Found '{' when manual bundling is already turned on");
7776 else
7777 CURR_SLOT.manual_bundling_on = 1;
7778 md.manual_bundling = 1;
7779
7780 /* Bundling is only acceptable in explicit mode
7781 or when in default automatic mode. */
7782 if (md.detect_dv && !md.explicit_mode)
7783 {
7784 if (!md.mode_explicitly_set
7785 && !md.default_explicit_mode)
7786 dot_dv_mode ('E');
7787 else
7788 as_warn (_("Found '{' after explicit switch to automatic mode"));
7789 }
7790 }
7791 else if (input_line_pointer[-1] == '}')
7792 {
7793 if (!md.manual_bundling)
7794 as_warn ("Found '}' when manual bundling is off");
7795 else
7796 PREV_SLOT.manual_bundling_off = 1;
7797 md.manual_bundling = 0;
7798
7799 /* switch back to automatic mode, if applicable */
7800 if (md.detect_dv
7801 && md.explicit_mode
7802 && !md.mode_explicitly_set
7803 && !md.default_explicit_mode)
7804 dot_dv_mode ('A');
7805 }
7806 }
7807
7808 /* This is a hook for ia64_frob_label, so that it can distinguish tags from
7809 labels. */
7810 static int defining_tag = 0;
7811
7812 int
ia64_unrecognized_line(ch)7813 ia64_unrecognized_line (ch)
7814 int ch;
7815 {
7816 switch (ch)
7817 {
7818 case '(':
7819 expression_and_evaluate (&md.qp);
7820 if (*input_line_pointer++ != ')')
7821 {
7822 as_bad ("Expected ')'");
7823 return 0;
7824 }
7825 if (md.qp.X_op != O_register)
7826 {
7827 as_bad ("Qualifying predicate expected");
7828 return 0;
7829 }
7830 if (md.qp.X_add_number < REG_P || md.qp.X_add_number >= REG_P + 64)
7831 {
7832 as_bad ("Predicate register expected");
7833 return 0;
7834 }
7835 return 1;
7836
7837 case '[':
7838 {
7839 char *s;
7840 char c;
7841 symbolS *tag;
7842 int temp;
7843
7844 if (md.qp.X_op == O_register)
7845 {
7846 as_bad ("Tag must come before qualifying predicate.");
7847 return 0;
7848 }
7849
7850 /* This implements just enough of read_a_source_file in read.c to
7851 recognize labels. */
7852 if (is_name_beginner (*input_line_pointer))
7853 {
7854 s = input_line_pointer;
7855 c = get_symbol_end ();
7856 }
7857 else if (LOCAL_LABELS_FB
7858 && ISDIGIT (*input_line_pointer))
7859 {
7860 temp = 0;
7861 while (ISDIGIT (*input_line_pointer))
7862 temp = (temp * 10) + *input_line_pointer++ - '0';
7863 fb_label_instance_inc (temp);
7864 s = fb_label_name (temp, 0);
7865 c = *input_line_pointer;
7866 }
7867 else
7868 {
7869 s = NULL;
7870 c = '\0';
7871 }
7872 if (c != ':')
7873 {
7874 /* Put ':' back for error messages' sake. */
7875 *input_line_pointer++ = ':';
7876 as_bad ("Expected ':'");
7877 return 0;
7878 }
7879
7880 defining_tag = 1;
7881 tag = colon (s);
7882 defining_tag = 0;
7883 /* Put ':' back for error messages' sake. */
7884 *input_line_pointer++ = ':';
7885 if (*input_line_pointer++ != ']')
7886 {
7887 as_bad ("Expected ']'");
7888 return 0;
7889 }
7890 if (! tag)
7891 {
7892 as_bad ("Tag name expected");
7893 return 0;
7894 }
7895 return 1;
7896 }
7897
7898 default:
7899 break;
7900 }
7901
7902 /* Not a valid line. */
7903 return 0;
7904 }
7905
7906 void
ia64_frob_label(sym)7907 ia64_frob_label (sym)
7908 struct symbol *sym;
7909 {
7910 struct label_fix *fix;
7911
7912 /* Tags need special handling since they are not bundle breaks like
7913 labels. */
7914 if (defining_tag)
7915 {
7916 fix = obstack_alloc (¬es, sizeof (*fix));
7917 fix->sym = sym;
7918 fix->next = CURR_SLOT.tag_fixups;
7919 fix->dw2_mark_labels = FALSE;
7920 CURR_SLOT.tag_fixups = fix;
7921
7922 return;
7923 }
7924
7925 if (bfd_get_section_flags (stdoutput, now_seg) & SEC_CODE)
7926 {
7927 md.last_text_seg = now_seg;
7928 fix = obstack_alloc (¬es, sizeof (*fix));
7929 fix->sym = sym;
7930 fix->next = CURR_SLOT.label_fixups;
7931 fix->dw2_mark_labels = dwarf2_loc_mark_labels;
7932 CURR_SLOT.label_fixups = fix;
7933
7934 /* Keep track of how many code entry points we've seen. */
7935 if (md.path == md.maxpaths)
7936 {
7937 md.maxpaths += 20;
7938 md.entry_labels = (const char **)
7939 xrealloc ((void *) md.entry_labels,
7940 md.maxpaths * sizeof (char *));
7941 }
7942 md.entry_labels[md.path++] = S_GET_NAME (sym);
7943 }
7944 }
7945
7946 #ifdef TE_HPUX
7947 /* The HP-UX linker will give unresolved symbol errors for symbols
7948 that are declared but unused. This routine removes declared,
7949 unused symbols from an object. */
7950 int
ia64_frob_symbol(sym)7951 ia64_frob_symbol (sym)
7952 struct symbol *sym;
7953 {
7954 if ((S_GET_SEGMENT (sym) == &bfd_und_section && ! symbol_used_p (sym) &&
7955 ELF_ST_VISIBILITY (S_GET_OTHER (sym)) == STV_DEFAULT)
7956 || (S_GET_SEGMENT (sym) == &bfd_abs_section
7957 && ! S_IS_EXTERNAL (sym)))
7958 return 1;
7959 return 0;
7960 }
7961 #endif
7962
7963 void
ia64_flush_pending_output()7964 ia64_flush_pending_output ()
7965 {
7966 if (!md.keep_pending_output
7967 && bfd_get_section_flags (stdoutput, now_seg) & SEC_CODE)
7968 {
7969 /* ??? This causes many unnecessary stop bits to be emitted.
7970 Unfortunately, it isn't clear if it is safe to remove this. */
7971 insn_group_break (1, 0, 0);
7972 ia64_flush_insns ();
7973 }
7974 }
7975
7976 /* Do ia64-specific expression optimization. All that's done here is
7977 to transform index expressions that are either due to the indexing
7978 of rotating registers or due to the indexing of indirect register
7979 sets. */
7980 int
ia64_optimize_expr(l,op,r)7981 ia64_optimize_expr (l, op, r)
7982 expressionS *l;
7983 operatorT op;
7984 expressionS *r;
7985 {
7986 if (op != O_index)
7987 return 0;
7988 resolve_expression (l);
7989 if (l->X_op == O_register)
7990 {
7991 unsigned num_regs = l->X_add_number >> 16;
7992
7993 resolve_expression (r);
7994 if (num_regs)
7995 {
7996 /* Left side is a .rotX-allocated register. */
7997 if (r->X_op != O_constant)
7998 {
7999 as_bad ("Rotating register index must be a non-negative constant");
8000 r->X_add_number = 0;
8001 }
8002 else if ((valueT) r->X_add_number >= num_regs)
8003 {
8004 as_bad ("Index out of range 0..%u", num_regs - 1);
8005 r->X_add_number = 0;
8006 }
8007 l->X_add_number = (l->X_add_number & 0xffff) + r->X_add_number;
8008 return 1;
8009 }
8010 else if (l->X_add_number >= IND_CPUID && l->X_add_number <= IND_RR)
8011 {
8012 if (r->X_op != O_register
8013 || r->X_add_number < REG_GR
8014 || r->X_add_number > REG_GR + 127)
8015 {
8016 as_bad ("Indirect register index must be a general register");
8017 r->X_add_number = REG_GR;
8018 }
8019 l->X_op = O_index;
8020 l->X_op_symbol = md.indregsym[l->X_add_number - IND_CPUID];
8021 l->X_add_number = r->X_add_number;
8022 return 1;
8023 }
8024 }
8025 as_bad ("Index can only be applied to rotating or indirect registers");
8026 /* Fall back to some register use of which has as little as possible
8027 side effects, to minimize subsequent error messages. */
8028 l->X_op = O_register;
8029 l->X_add_number = REG_GR + 3;
8030 return 1;
8031 }
8032
8033 int
ia64_parse_name(name,e,nextcharP)8034 ia64_parse_name (name, e, nextcharP)
8035 char *name;
8036 expressionS *e;
8037 char *nextcharP;
8038 {
8039 struct const_desc *cdesc;
8040 struct dynreg *dr = 0;
8041 unsigned int idx;
8042 struct symbol *sym;
8043 char *end;
8044
8045 if (*name == '@')
8046 {
8047 enum pseudo_type pseudo_type = PSEUDO_FUNC_NONE;
8048
8049 /* Find what relocation pseudo-function we're dealing with. */
8050 for (idx = 0; idx < NELEMS (pseudo_func); ++idx)
8051 if (pseudo_func[idx].name
8052 && pseudo_func[idx].name[0] == name[1]
8053 && strcmp (pseudo_func[idx].name + 1, name + 2) == 0)
8054 {
8055 pseudo_type = pseudo_func[idx].type;
8056 break;
8057 }
8058 switch (pseudo_type)
8059 {
8060 case PSEUDO_FUNC_RELOC:
8061 end = input_line_pointer;
8062 if (*nextcharP != '(')
8063 {
8064 as_bad ("Expected '('");
8065 break;
8066 }
8067 /* Skip '('. */
8068 ++input_line_pointer;
8069 expression (e);
8070 if (*input_line_pointer != ')')
8071 {
8072 as_bad ("Missing ')'");
8073 goto done;
8074 }
8075 /* Skip ')'. */
8076 ++input_line_pointer;
8077 if (e->X_op != O_symbol)
8078 {
8079 if (e->X_op != O_pseudo_fixup)
8080 {
8081 as_bad ("Not a symbolic expression");
8082 goto done;
8083 }
8084 if (idx != FUNC_LT_RELATIVE)
8085 {
8086 as_bad ("Illegal combination of relocation functions");
8087 goto done;
8088 }
8089 switch (S_GET_VALUE (e->X_op_symbol))
8090 {
8091 case FUNC_FPTR_RELATIVE:
8092 idx = FUNC_LT_FPTR_RELATIVE; break;
8093 case FUNC_DTP_MODULE:
8094 idx = FUNC_LT_DTP_MODULE; break;
8095 case FUNC_DTP_RELATIVE:
8096 idx = FUNC_LT_DTP_RELATIVE; break;
8097 case FUNC_TP_RELATIVE:
8098 idx = FUNC_LT_TP_RELATIVE; break;
8099 default:
8100 as_bad ("Illegal combination of relocation functions");
8101 goto done;
8102 }
8103 }
8104 /* Make sure gas doesn't get rid of local symbols that are used
8105 in relocs. */
8106 e->X_op = O_pseudo_fixup;
8107 e->X_op_symbol = pseudo_func[idx].u.sym;
8108 done:
8109 *nextcharP = *input_line_pointer;
8110 break;
8111
8112 case PSEUDO_FUNC_CONST:
8113 e->X_op = O_constant;
8114 e->X_add_number = pseudo_func[idx].u.ival;
8115 break;
8116
8117 case PSEUDO_FUNC_REG:
8118 e->X_op = O_register;
8119 e->X_add_number = pseudo_func[idx].u.ival;
8120 break;
8121
8122 default:
8123 return 0;
8124 }
8125 return 1;
8126 }
8127
8128 /* first see if NAME is a known register name: */
8129 sym = hash_find (md.reg_hash, name);
8130 if (sym)
8131 {
8132 e->X_op = O_register;
8133 e->X_add_number = S_GET_VALUE (sym);
8134 return 1;
8135 }
8136
8137 cdesc = hash_find (md.const_hash, name);
8138 if (cdesc)
8139 {
8140 e->X_op = O_constant;
8141 e->X_add_number = cdesc->value;
8142 return 1;
8143 }
8144
8145 /* check for inN, locN, or outN: */
8146 idx = 0;
8147 switch (name[0])
8148 {
8149 case 'i':
8150 if (name[1] == 'n' && ISDIGIT (name[2]))
8151 {
8152 dr = &md.in;
8153 idx = 2;
8154 }
8155 break;
8156
8157 case 'l':
8158 if (name[1] == 'o' && name[2] == 'c' && ISDIGIT (name[3]))
8159 {
8160 dr = &md.loc;
8161 idx = 3;
8162 }
8163 break;
8164
8165 case 'o':
8166 if (name[1] == 'u' && name[2] == 't' && ISDIGIT (name[3]))
8167 {
8168 dr = &md.out;
8169 idx = 3;
8170 }
8171 break;
8172
8173 default:
8174 break;
8175 }
8176
8177 /* Ignore register numbers with leading zeroes, except zero itself. */
8178 if (dr && (name[idx] != '0' || name[idx + 1] == '\0'))
8179 {
8180 unsigned long regnum;
8181
8182 /* The name is inN, locN, or outN; parse the register number. */
8183 regnum = strtoul (name + idx, &end, 10);
8184 if (end > name + idx && *end == '\0' && regnum < 96)
8185 {
8186 if (regnum >= dr->num_regs)
8187 {
8188 if (!dr->num_regs)
8189 as_bad ("No current frame");
8190 else
8191 as_bad ("Register number out of range 0..%u",
8192 dr->num_regs - 1);
8193 regnum = 0;
8194 }
8195 e->X_op = O_register;
8196 e->X_add_number = dr->base + regnum;
8197 return 1;
8198 }
8199 }
8200
8201 end = alloca (strlen (name) + 1);
8202 strcpy (end, name);
8203 name = ia64_canonicalize_symbol_name (end);
8204 if ((dr = hash_find (md.dynreg_hash, name)))
8205 {
8206 /* We've got ourselves the name of a rotating register set.
8207 Store the base register number in the low 16 bits of
8208 X_add_number and the size of the register set in the top 16
8209 bits. */
8210 e->X_op = O_register;
8211 e->X_add_number = dr->base | (dr->num_regs << 16);
8212 return 1;
8213 }
8214 return 0;
8215 }
8216
8217 /* Remove the '#' suffix that indicates a symbol as opposed to a register. */
8218
8219 char *
ia64_canonicalize_symbol_name(name)8220 ia64_canonicalize_symbol_name (name)
8221 char *name;
8222 {
8223 size_t len = strlen (name), full = len;
8224
8225 while (len > 0 && name[len - 1] == '#')
8226 --len;
8227 if (len <= 0)
8228 {
8229 if (full > 0)
8230 as_bad ("Standalone `#' is illegal");
8231 }
8232 else if (len < full - 1)
8233 as_warn ("Redundant `#' suffix operators");
8234 name[len] = '\0';
8235 return name;
8236 }
8237
8238 /* Return true if idesc is a conditional branch instruction. This excludes
8239 the modulo scheduled branches, and br.ia. Mod-sched branches are excluded
8240 because they always read/write resources regardless of the value of the
8241 qualifying predicate. br.ia must always use p0, and hence is always
8242 taken. Thus this function returns true for branches which can fall
8243 through, and which use no resources if they do fall through. */
8244
8245 static int
is_conditional_branch(idesc)8246 is_conditional_branch (idesc)
8247 struct ia64_opcode *idesc;
8248 {
8249 /* br is a conditional branch. Everything that starts with br. except
8250 br.ia, br.c{loop,top,exit}, and br.w{top,exit} is a conditional branch.
8251 Everything that starts with brl is a conditional branch. */
8252 return (idesc->name[0] == 'b' && idesc->name[1] == 'r'
8253 && (idesc->name[2] == '\0'
8254 || (idesc->name[2] == '.' && idesc->name[3] != 'i'
8255 && idesc->name[3] != 'c' && idesc->name[3] != 'w')
8256 || idesc->name[2] == 'l'
8257 /* br.cond, br.call, br.clr */
8258 || (idesc->name[2] == '.' && idesc->name[3] == 'c'
8259 && (idesc->name[4] == 'a' || idesc->name[4] == 'o'
8260 || (idesc->name[4] == 'l' && idesc->name[5] == 'r')))));
8261 }
8262
8263 /* Return whether the given opcode is a taken branch. If there's any doubt,
8264 returns zero. */
8265
8266 static int
is_taken_branch(idesc)8267 is_taken_branch (idesc)
8268 struct ia64_opcode *idesc;
8269 {
8270 return ((is_conditional_branch (idesc) && CURR_SLOT.qp_regno == 0)
8271 || strncmp (idesc->name, "br.ia", 5) == 0);
8272 }
8273
8274 /* Return whether the given opcode is an interruption or rfi. If there's any
8275 doubt, returns zero. */
8276
8277 static int
is_interruption_or_rfi(idesc)8278 is_interruption_or_rfi (idesc)
8279 struct ia64_opcode *idesc;
8280 {
8281 if (strcmp (idesc->name, "rfi") == 0)
8282 return 1;
8283 return 0;
8284 }
8285
8286 /* Returns the index of the given dependency in the opcode's list of chks, or
8287 -1 if there is no dependency. */
8288
8289 static int
depends_on(depind,idesc)8290 depends_on (depind, idesc)
8291 int depind;
8292 struct ia64_opcode *idesc;
8293 {
8294 int i;
8295 const struct ia64_opcode_dependency *dep = idesc->dependencies;
8296 for (i = 0; i < dep->nchks; i++)
8297 {
8298 if (depind == DEP (dep->chks[i]))
8299 return i;
8300 }
8301 return -1;
8302 }
8303
8304 /* Determine a set of specific resources used for a particular resource
8305 class. Returns the number of specific resources identified For those
8306 cases which are not determinable statically, the resource returned is
8307 marked nonspecific.
8308
8309 Meanings of value in 'NOTE':
8310 1) only read/write when the register number is explicitly encoded in the
8311 insn.
8312 2) only read CFM when accessing a rotating GR, FR, or PR. mov pr only
8313 accesses CFM when qualifying predicate is in the rotating region.
8314 3) general register value is used to specify an indirect register; not
8315 determinable statically.
8316 4) only read the given resource when bits 7:0 of the indirect index
8317 register value does not match the register number of the resource; not
8318 determinable statically.
8319 5) all rules are implementation specific.
8320 6) only when both the index specified by the reader and the index specified
8321 by the writer have the same value in bits 63:61; not determinable
8322 statically.
8323 7) only access the specified resource when the corresponding mask bit is
8324 set
8325 8) PSR.dfh is only read when these insns reference FR32-127. PSR.dfl is
8326 only read when these insns reference FR2-31
8327 9) PSR.mfl is only written when these insns write FR2-31. PSR.mfh is only
8328 written when these insns write FR32-127
8329 10) The PSR.bn bit is only accessed when one of GR16-31 is specified in the
8330 instruction
8331 11) The target predicates are written independently of PR[qp], but source
8332 registers are only read if PR[qp] is true. Since the state of PR[qp]
8333 cannot statically be determined, all source registers are marked used.
8334 12) This insn only reads the specified predicate register when that
8335 register is the PR[qp].
8336 13) This reference to ld-c only applies to teh GR whose value is loaded
8337 with data returned from memory, not the post-incremented address register.
8338 14) The RSE resource includes the implementation-specific RSE internal
8339 state resources. At least one (and possibly more) of these resources are
8340 read by each instruction listed in IC:rse-readers. At least one (and
8341 possibly more) of these resources are written by each insn listed in
8342 IC:rse-writers.
8343 15+16) Represents reserved instructions, which the assembler does not
8344 generate.
8345 17) CR[TPR] has a RAW dependency only between mov-to-CR-TPR and
8346 mov-to-PSR-l or ssm instructions that set PSR.i, PSR.pp or PSR.up.
8347
8348 Memory resources (i.e. locations in memory) are *not* marked or tracked by
8349 this code; there are no dependency violations based on memory access.
8350 */
8351
8352 #define MAX_SPECS 256
8353 #define DV_CHK 1
8354 #define DV_REG 0
8355
8356 static int
specify_resource(dep,idesc,type,specs,note,path)8357 specify_resource (dep, idesc, type, specs, note, path)
8358 const struct ia64_dependency *dep;
8359 struct ia64_opcode *idesc;
8360 int type; /* is this a DV chk or a DV reg? */
8361 struct rsrc specs[MAX_SPECS]; /* returned specific resources */
8362 int note; /* resource note for this insn's usage */
8363 int path; /* which execution path to examine */
8364 {
8365 int count = 0;
8366 int i;
8367 int rsrc_write = 0;
8368 struct rsrc tmpl;
8369
8370 if (dep->mode == IA64_DV_WAW
8371 || (dep->mode == IA64_DV_RAW && type == DV_REG)
8372 || (dep->mode == IA64_DV_WAR && type == DV_CHK))
8373 rsrc_write = 1;
8374
8375 /* template for any resources we identify */
8376 tmpl.dependency = dep;
8377 tmpl.note = note;
8378 tmpl.insn_srlz = tmpl.data_srlz = 0;
8379 tmpl.qp_regno = CURR_SLOT.qp_regno;
8380 tmpl.link_to_qp_branch = 1;
8381 tmpl.mem_offset.hint = 0;
8382 tmpl.mem_offset.offset = 0;
8383 tmpl.mem_offset.base = 0;
8384 tmpl.specific = 1;
8385 tmpl.index = -1;
8386 tmpl.cmp_type = CMP_NONE;
8387 tmpl.depind = 0;
8388 tmpl.file = NULL;
8389 tmpl.line = 0;
8390 tmpl.path = 0;
8391
8392 #define UNHANDLED \
8393 as_warn (_("Unhandled dependency %s for %s (%s), note %d"), \
8394 dep->name, idesc->name, (rsrc_write?"write":"read"), note)
8395 #define KNOWN(REG) (gr_values[REG].known && gr_values[REG].path >= path)
8396
8397 /* we don't need to track these */
8398 if (dep->semantics == IA64_DVS_NONE)
8399 return 0;
8400
8401 switch (dep->specifier)
8402 {
8403 case IA64_RS_AR_K:
8404 if (note == 1)
8405 {
8406 if (idesc->operands[!rsrc_write] == IA64_OPND_AR3)
8407 {
8408 int regno = CURR_SLOT.opnd[!rsrc_write].X_add_number - REG_AR;
8409 if (regno >= 0 && regno <= 7)
8410 {
8411 specs[count] = tmpl;
8412 specs[count++].index = regno;
8413 }
8414 }
8415 }
8416 else if (note == 0)
8417 {
8418 for (i = 0; i < 8; i++)
8419 {
8420 specs[count] = tmpl;
8421 specs[count++].index = i;
8422 }
8423 }
8424 else
8425 {
8426 UNHANDLED;
8427 }
8428 break;
8429
8430 case IA64_RS_AR_UNAT:
8431 /* This is a mov =AR or mov AR= instruction. */
8432 if (idesc->operands[!rsrc_write] == IA64_OPND_AR3)
8433 {
8434 int regno = CURR_SLOT.opnd[!rsrc_write].X_add_number - REG_AR;
8435 if (regno == AR_UNAT)
8436 {
8437 specs[count++] = tmpl;
8438 }
8439 }
8440 else
8441 {
8442 /* This is a spill/fill, or other instruction that modifies the
8443 unat register. */
8444
8445 /* Unless we can determine the specific bits used, mark the whole
8446 thing; bits 8:3 of the memory address indicate the bit used in
8447 UNAT. The .mem.offset hint may be used to eliminate a small
8448 subset of conflicts. */
8449 specs[count] = tmpl;
8450 if (md.mem_offset.hint)
8451 {
8452 if (md.debug_dv)
8453 fprintf (stderr, " Using hint for spill/fill\n");
8454 /* The index isn't actually used, just set it to something
8455 approximating the bit index. */
8456 specs[count].index = (md.mem_offset.offset >> 3) & 0x3F;
8457 specs[count].mem_offset.hint = 1;
8458 specs[count].mem_offset.offset = md.mem_offset.offset;
8459 specs[count++].mem_offset.base = md.mem_offset.base;
8460 }
8461 else
8462 {
8463 specs[count++].specific = 0;
8464 }
8465 }
8466 break;
8467
8468 case IA64_RS_AR:
8469 if (note == 1)
8470 {
8471 if (idesc->operands[!rsrc_write] == IA64_OPND_AR3)
8472 {
8473 int regno = CURR_SLOT.opnd[!rsrc_write].X_add_number - REG_AR;
8474 if ((regno >= 8 && regno <= 15)
8475 || (regno >= 20 && regno <= 23)
8476 || (regno >= 31 && regno <= 39)
8477 || (regno >= 41 && regno <= 47)
8478 || (regno >= 67 && regno <= 111))
8479 {
8480 specs[count] = tmpl;
8481 specs[count++].index = regno;
8482 }
8483 }
8484 }
8485 else
8486 {
8487 UNHANDLED;
8488 }
8489 break;
8490
8491 case IA64_RS_ARb:
8492 if (note == 1)
8493 {
8494 if (idesc->operands[!rsrc_write] == IA64_OPND_AR3)
8495 {
8496 int regno = CURR_SLOT.opnd[!rsrc_write].X_add_number - REG_AR;
8497 if ((regno >= 48 && regno <= 63)
8498 || (regno >= 112 && regno <= 127))
8499 {
8500 specs[count] = tmpl;
8501 specs[count++].index = regno;
8502 }
8503 }
8504 }
8505 else if (note == 0)
8506 {
8507 for (i = 48; i < 64; i++)
8508 {
8509 specs[count] = tmpl;
8510 specs[count++].index = i;
8511 }
8512 for (i = 112; i < 128; i++)
8513 {
8514 specs[count] = tmpl;
8515 specs[count++].index = i;
8516 }
8517 }
8518 else
8519 {
8520 UNHANDLED;
8521 }
8522 break;
8523
8524 case IA64_RS_BR:
8525 if (note != 1)
8526 {
8527 UNHANDLED;
8528 }
8529 else
8530 {
8531 if (rsrc_write)
8532 {
8533 for (i = 0; i < idesc->num_outputs; i++)
8534 if (idesc->operands[i] == IA64_OPND_B1
8535 || idesc->operands[i] == IA64_OPND_B2)
8536 {
8537 specs[count] = tmpl;
8538 specs[count++].index =
8539 CURR_SLOT.opnd[i].X_add_number - REG_BR;
8540 }
8541 }
8542 else
8543 {
8544 for (i = idesc->num_outputs; i < NELEMS (idesc->operands); i++)
8545 if (idesc->operands[i] == IA64_OPND_B1
8546 || idesc->operands[i] == IA64_OPND_B2)
8547 {
8548 specs[count] = tmpl;
8549 specs[count++].index =
8550 CURR_SLOT.opnd[i].X_add_number - REG_BR;
8551 }
8552 }
8553 }
8554 break;
8555
8556 case IA64_RS_CPUID: /* four or more registers */
8557 if (note == 3)
8558 {
8559 if (idesc->operands[!rsrc_write] == IA64_OPND_CPUID_R3)
8560 {
8561 int regno = CURR_SLOT.opnd[!rsrc_write].X_add_number - REG_GR;
8562 if (regno >= 0 && regno < NELEMS (gr_values)
8563 && KNOWN (regno))
8564 {
8565 specs[count] = tmpl;
8566 specs[count++].index = gr_values[regno].value & 0xFF;
8567 }
8568 else
8569 {
8570 specs[count] = tmpl;
8571 specs[count++].specific = 0;
8572 }
8573 }
8574 }
8575 else
8576 {
8577 UNHANDLED;
8578 }
8579 break;
8580
8581 case IA64_RS_DBR: /* four or more registers */
8582 if (note == 3)
8583 {
8584 if (idesc->operands[!rsrc_write] == IA64_OPND_DBR_R3)
8585 {
8586 int regno = CURR_SLOT.opnd[!rsrc_write].X_add_number - REG_GR;
8587 if (regno >= 0 && regno < NELEMS (gr_values)
8588 && KNOWN (regno))
8589 {
8590 specs[count] = tmpl;
8591 specs[count++].index = gr_values[regno].value & 0xFF;
8592 }
8593 else
8594 {
8595 specs[count] = tmpl;
8596 specs[count++].specific = 0;
8597 }
8598 }
8599 }
8600 else if (note == 0 && !rsrc_write)
8601 {
8602 specs[count] = tmpl;
8603 specs[count++].specific = 0;
8604 }
8605 else
8606 {
8607 UNHANDLED;
8608 }
8609 break;
8610
8611 case IA64_RS_IBR: /* four or more registers */
8612 if (note == 3)
8613 {
8614 if (idesc->operands[!rsrc_write] == IA64_OPND_IBR_R3)
8615 {
8616 int regno = CURR_SLOT.opnd[!rsrc_write].X_add_number - REG_GR;
8617 if (regno >= 0 && regno < NELEMS (gr_values)
8618 && KNOWN (regno))
8619 {
8620 specs[count] = tmpl;
8621 specs[count++].index = gr_values[regno].value & 0xFF;
8622 }
8623 else
8624 {
8625 specs[count] = tmpl;
8626 specs[count++].specific = 0;
8627 }
8628 }
8629 }
8630 else
8631 {
8632 UNHANDLED;
8633 }
8634 break;
8635
8636 case IA64_RS_MSR:
8637 if (note == 5)
8638 {
8639 /* These are implementation specific. Force all references to
8640 conflict with all other references. */
8641 specs[count] = tmpl;
8642 specs[count++].specific = 0;
8643 }
8644 else
8645 {
8646 UNHANDLED;
8647 }
8648 break;
8649
8650 case IA64_RS_PKR: /* 16 or more registers */
8651 if (note == 3 || note == 4)
8652 {
8653 if (idesc->operands[!rsrc_write] == IA64_OPND_PKR_R3)
8654 {
8655 int regno = CURR_SLOT.opnd[!rsrc_write].X_add_number - REG_GR;
8656 if (regno >= 0 && regno < NELEMS (gr_values)
8657 && KNOWN (regno))
8658 {
8659 if (note == 3)
8660 {
8661 specs[count] = tmpl;
8662 specs[count++].index = gr_values[regno].value & 0xFF;
8663 }
8664 else
8665 for (i = 0; i < NELEMS (gr_values); i++)
8666 {
8667 /* Uses all registers *except* the one in R3. */
8668 if ((unsigned)i != (gr_values[regno].value & 0xFF))
8669 {
8670 specs[count] = tmpl;
8671 specs[count++].index = i;
8672 }
8673 }
8674 }
8675 else
8676 {
8677 specs[count] = tmpl;
8678 specs[count++].specific = 0;
8679 }
8680 }
8681 }
8682 else if (note == 0)
8683 {
8684 /* probe et al. */
8685 specs[count] = tmpl;
8686 specs[count++].specific = 0;
8687 }
8688 break;
8689
8690 case IA64_RS_PMC: /* four or more registers */
8691 if (note == 3)
8692 {
8693 if (idesc->operands[!rsrc_write] == IA64_OPND_PMC_R3
8694 || (!rsrc_write && idesc->operands[1] == IA64_OPND_PMD_R3))
8695
8696 {
8697 int index = ((idesc->operands[1] == IA64_OPND_R3 && !rsrc_write)
8698 ? 1 : !rsrc_write);
8699 int regno = CURR_SLOT.opnd[index].X_add_number - REG_GR;
8700 if (regno >= 0 && regno < NELEMS (gr_values)
8701 && KNOWN (regno))
8702 {
8703 specs[count] = tmpl;
8704 specs[count++].index = gr_values[regno].value & 0xFF;
8705 }
8706 else
8707 {
8708 specs[count] = tmpl;
8709 specs[count++].specific = 0;
8710 }
8711 }
8712 }
8713 else
8714 {
8715 UNHANDLED;
8716 }
8717 break;
8718
8719 case IA64_RS_PMD: /* four or more registers */
8720 if (note == 3)
8721 {
8722 if (idesc->operands[!rsrc_write] == IA64_OPND_PMD_R3)
8723 {
8724 int regno = CURR_SLOT.opnd[!rsrc_write].X_add_number - REG_GR;
8725 if (regno >= 0 && regno < NELEMS (gr_values)
8726 && KNOWN (regno))
8727 {
8728 specs[count] = tmpl;
8729 specs[count++].index = gr_values[regno].value & 0xFF;
8730 }
8731 else
8732 {
8733 specs[count] = tmpl;
8734 specs[count++].specific = 0;
8735 }
8736 }
8737 }
8738 else
8739 {
8740 UNHANDLED;
8741 }
8742 break;
8743
8744 case IA64_RS_RR: /* eight registers */
8745 if (note == 6)
8746 {
8747 if (idesc->operands[!rsrc_write] == IA64_OPND_RR_R3)
8748 {
8749 int regno = CURR_SLOT.opnd[!rsrc_write].X_add_number - REG_GR;
8750 if (regno >= 0 && regno < NELEMS (gr_values)
8751 && KNOWN (regno))
8752 {
8753 specs[count] = tmpl;
8754 specs[count++].index = (gr_values[regno].value >> 61) & 0x7;
8755 }
8756 else
8757 {
8758 specs[count] = tmpl;
8759 specs[count++].specific = 0;
8760 }
8761 }
8762 }
8763 else if (note == 0 && !rsrc_write)
8764 {
8765 specs[count] = tmpl;
8766 specs[count++].specific = 0;
8767 }
8768 else
8769 {
8770 UNHANDLED;
8771 }
8772 break;
8773
8774 case IA64_RS_CR_IRR:
8775 if (note == 0)
8776 {
8777 /* handle mov-from-CR-IVR; it's a read that writes CR[IRR] */
8778 int regno = CURR_SLOT.opnd[1].X_add_number - REG_CR;
8779 if (rsrc_write
8780 && idesc->operands[1] == IA64_OPND_CR3
8781 && regno == CR_IVR)
8782 {
8783 for (i = 0; i < 4; i++)
8784 {
8785 specs[count] = tmpl;
8786 specs[count++].index = CR_IRR0 + i;
8787 }
8788 }
8789 }
8790 else if (note == 1)
8791 {
8792 int regno = CURR_SLOT.opnd[!rsrc_write].X_add_number - REG_CR;
8793 if (idesc->operands[!rsrc_write] == IA64_OPND_CR3
8794 && regno >= CR_IRR0
8795 && regno <= CR_IRR3)
8796 {
8797 specs[count] = tmpl;
8798 specs[count++].index = regno;
8799 }
8800 }
8801 else
8802 {
8803 UNHANDLED;
8804 }
8805 break;
8806
8807 case IA64_RS_CR_LRR:
8808 if (note != 1)
8809 {
8810 UNHANDLED;
8811 }
8812 else
8813 {
8814 int regno = CURR_SLOT.opnd[!rsrc_write].X_add_number - REG_CR;
8815 if (idesc->operands[!rsrc_write] == IA64_OPND_CR3
8816 && (regno == CR_LRR0 || regno == CR_LRR1))
8817 {
8818 specs[count] = tmpl;
8819 specs[count++].index = regno;
8820 }
8821 }
8822 break;
8823
8824 case IA64_RS_CR:
8825 if (note == 1)
8826 {
8827 if (idesc->operands[!rsrc_write] == IA64_OPND_CR3)
8828 {
8829 specs[count] = tmpl;
8830 specs[count++].index =
8831 CURR_SLOT.opnd[!rsrc_write].X_add_number - REG_CR;
8832 }
8833 }
8834 else
8835 {
8836 UNHANDLED;
8837 }
8838 break;
8839
8840 case IA64_RS_FR:
8841 case IA64_RS_FRb:
8842 if (note != 1)
8843 {
8844 UNHANDLED;
8845 }
8846 else if (rsrc_write)
8847 {
8848 if (dep->specifier == IA64_RS_FRb
8849 && idesc->operands[0] == IA64_OPND_F1)
8850 {
8851 specs[count] = tmpl;
8852 specs[count++].index = CURR_SLOT.opnd[0].X_add_number - REG_FR;
8853 }
8854 }
8855 else
8856 {
8857 for (i = idesc->num_outputs; i < NELEMS (idesc->operands); i++)
8858 {
8859 if (idesc->operands[i] == IA64_OPND_F2
8860 || idesc->operands[i] == IA64_OPND_F3
8861 || idesc->operands[i] == IA64_OPND_F4)
8862 {
8863 specs[count] = tmpl;
8864 specs[count++].index =
8865 CURR_SLOT.opnd[i].X_add_number - REG_FR;
8866 }
8867 }
8868 }
8869 break;
8870
8871 case IA64_RS_GR:
8872 if (note == 13)
8873 {
8874 /* This reference applies only to the GR whose value is loaded with
8875 data returned from memory. */
8876 specs[count] = tmpl;
8877 specs[count++].index = CURR_SLOT.opnd[0].X_add_number - REG_GR;
8878 }
8879 else if (note == 1)
8880 {
8881 if (rsrc_write)
8882 {
8883 for (i = 0; i < idesc->num_outputs; i++)
8884 if (idesc->operands[i] == IA64_OPND_R1
8885 || idesc->operands[i] == IA64_OPND_R2
8886 || idesc->operands[i] == IA64_OPND_R3)
8887 {
8888 specs[count] = tmpl;
8889 specs[count++].index =
8890 CURR_SLOT.opnd[i].X_add_number - REG_GR;
8891 }
8892 if (idesc->flags & IA64_OPCODE_POSTINC)
8893 for (i = 0; i < NELEMS (idesc->operands); i++)
8894 if (idesc->operands[i] == IA64_OPND_MR3)
8895 {
8896 specs[count] = tmpl;
8897 specs[count++].index =
8898 CURR_SLOT.opnd[i].X_add_number - REG_GR;
8899 }
8900 }
8901 else
8902 {
8903 /* Look for anything that reads a GR. */
8904 for (i = 0; i < NELEMS (idesc->operands); i++)
8905 {
8906 if (idesc->operands[i] == IA64_OPND_MR3
8907 || idesc->operands[i] == IA64_OPND_CPUID_R3
8908 || idesc->operands[i] == IA64_OPND_DBR_R3
8909 || idesc->operands[i] == IA64_OPND_IBR_R3
8910 || idesc->operands[i] == IA64_OPND_MSR_R3
8911 || idesc->operands[i] == IA64_OPND_PKR_R3
8912 || idesc->operands[i] == IA64_OPND_PMC_R3
8913 || idesc->operands[i] == IA64_OPND_PMD_R3
8914 || idesc->operands[i] == IA64_OPND_RR_R3
8915 || ((i >= idesc->num_outputs)
8916 && (idesc->operands[i] == IA64_OPND_R1
8917 || idesc->operands[i] == IA64_OPND_R2
8918 || idesc->operands[i] == IA64_OPND_R3
8919 /* addl source register. */
8920 || idesc->operands[i] == IA64_OPND_R3_2)))
8921 {
8922 specs[count] = tmpl;
8923 specs[count++].index =
8924 CURR_SLOT.opnd[i].X_add_number - REG_GR;
8925 }
8926 }
8927 }
8928 }
8929 else
8930 {
8931 UNHANDLED;
8932 }
8933 break;
8934
8935 /* This is the same as IA64_RS_PRr, except that the register range is
8936 from 1 - 15, and there are no rotating register reads/writes here. */
8937 case IA64_RS_PR:
8938 if (note == 0)
8939 {
8940 for (i = 1; i < 16; i++)
8941 {
8942 specs[count] = tmpl;
8943 specs[count++].index = i;
8944 }
8945 }
8946 else if (note == 7)
8947 {
8948 valueT mask = 0;
8949 /* Mark only those registers indicated by the mask. */
8950 if (rsrc_write)
8951 {
8952 mask = CURR_SLOT.opnd[2].X_add_number;
8953 for (i = 1; i < 16; i++)
8954 if (mask & ((valueT) 1 << i))
8955 {
8956 specs[count] = tmpl;
8957 specs[count++].index = i;
8958 }
8959 }
8960 else
8961 {
8962 UNHANDLED;
8963 }
8964 }
8965 else if (note == 11) /* note 11 implies note 1 as well */
8966 {
8967 if (rsrc_write)
8968 {
8969 for (i = 0; i < idesc->num_outputs; i++)
8970 {
8971 if (idesc->operands[i] == IA64_OPND_P1
8972 || idesc->operands[i] == IA64_OPND_P2)
8973 {
8974 int regno = CURR_SLOT.opnd[i].X_add_number - REG_P;
8975 if (regno >= 1 && regno < 16)
8976 {
8977 specs[count] = tmpl;
8978 specs[count++].index = regno;
8979 }
8980 }
8981 }
8982 }
8983 else
8984 {
8985 UNHANDLED;
8986 }
8987 }
8988 else if (note == 12)
8989 {
8990 if (CURR_SLOT.qp_regno >= 1 && CURR_SLOT.qp_regno < 16)
8991 {
8992 specs[count] = tmpl;
8993 specs[count++].index = CURR_SLOT.qp_regno;
8994 }
8995 }
8996 else if (note == 1)
8997 {
8998 if (rsrc_write)
8999 {
9000 int p1 = CURR_SLOT.opnd[0].X_add_number - REG_P;
9001 int p2 = CURR_SLOT.opnd[1].X_add_number - REG_P;
9002 int or_andcm = strstr (idesc->name, "or.andcm") != NULL;
9003 int and_orcm = strstr (idesc->name, "and.orcm") != NULL;
9004
9005 if ((idesc->operands[0] == IA64_OPND_P1
9006 || idesc->operands[0] == IA64_OPND_P2)
9007 && p1 >= 1 && p1 < 16)
9008 {
9009 specs[count] = tmpl;
9010 specs[count].cmp_type =
9011 (or_andcm ? CMP_OR : (and_orcm ? CMP_AND : CMP_NONE));
9012 specs[count++].index = p1;
9013 }
9014 if ((idesc->operands[1] == IA64_OPND_P1
9015 || idesc->operands[1] == IA64_OPND_P2)
9016 && p2 >= 1 && p2 < 16)
9017 {
9018 specs[count] = tmpl;
9019 specs[count].cmp_type =
9020 (or_andcm ? CMP_AND : (and_orcm ? CMP_OR : CMP_NONE));
9021 specs[count++].index = p2;
9022 }
9023 }
9024 else
9025 {
9026 if (CURR_SLOT.qp_regno >= 1 && CURR_SLOT.qp_regno < 16)
9027 {
9028 specs[count] = tmpl;
9029 specs[count++].index = CURR_SLOT.qp_regno;
9030 }
9031 if (idesc->operands[1] == IA64_OPND_PR)
9032 {
9033 for (i = 1; i < 16; i++)
9034 {
9035 specs[count] = tmpl;
9036 specs[count++].index = i;
9037 }
9038 }
9039 }
9040 }
9041 else
9042 {
9043 UNHANDLED;
9044 }
9045 break;
9046
9047 /* This is the general case for PRs. IA64_RS_PR and IA64_RS_PR63 are
9048 simplified cases of this. */
9049 case IA64_RS_PRr:
9050 if (note == 0)
9051 {
9052 for (i = 16; i < 63; i++)
9053 {
9054 specs[count] = tmpl;
9055 specs[count++].index = i;
9056 }
9057 }
9058 else if (note == 7)
9059 {
9060 valueT mask = 0;
9061 /* Mark only those registers indicated by the mask. */
9062 if (rsrc_write
9063 && idesc->operands[0] == IA64_OPND_PR)
9064 {
9065 mask = CURR_SLOT.opnd[2].X_add_number;
9066 if (mask & ((valueT) 1 << 16))
9067 for (i = 16; i < 63; i++)
9068 {
9069 specs[count] = tmpl;
9070 specs[count++].index = i;
9071 }
9072 }
9073 else if (rsrc_write
9074 && idesc->operands[0] == IA64_OPND_PR_ROT)
9075 {
9076 for (i = 16; i < 63; i++)
9077 {
9078 specs[count] = tmpl;
9079 specs[count++].index = i;
9080 }
9081 }
9082 else
9083 {
9084 UNHANDLED;
9085 }
9086 }
9087 else if (note == 11) /* note 11 implies note 1 as well */
9088 {
9089 if (rsrc_write)
9090 {
9091 for (i = 0; i < idesc->num_outputs; i++)
9092 {
9093 if (idesc->operands[i] == IA64_OPND_P1
9094 || idesc->operands[i] == IA64_OPND_P2)
9095 {
9096 int regno = CURR_SLOT.opnd[i].X_add_number - REG_P;
9097 if (regno >= 16 && regno < 63)
9098 {
9099 specs[count] = tmpl;
9100 specs[count++].index = regno;
9101 }
9102 }
9103 }
9104 }
9105 else
9106 {
9107 UNHANDLED;
9108 }
9109 }
9110 else if (note == 12)
9111 {
9112 if (CURR_SLOT.qp_regno >= 16 && CURR_SLOT.qp_regno < 63)
9113 {
9114 specs[count] = tmpl;
9115 specs[count++].index = CURR_SLOT.qp_regno;
9116 }
9117 }
9118 else if (note == 1)
9119 {
9120 if (rsrc_write)
9121 {
9122 int p1 = CURR_SLOT.opnd[0].X_add_number - REG_P;
9123 int p2 = CURR_SLOT.opnd[1].X_add_number - REG_P;
9124 int or_andcm = strstr (idesc->name, "or.andcm") != NULL;
9125 int and_orcm = strstr (idesc->name, "and.orcm") != NULL;
9126
9127 if ((idesc->operands[0] == IA64_OPND_P1
9128 || idesc->operands[0] == IA64_OPND_P2)
9129 && p1 >= 16 && p1 < 63)
9130 {
9131 specs[count] = tmpl;
9132 specs[count].cmp_type =
9133 (or_andcm ? CMP_OR : (and_orcm ? CMP_AND : CMP_NONE));
9134 specs[count++].index = p1;
9135 }
9136 if ((idesc->operands[1] == IA64_OPND_P1
9137 || idesc->operands[1] == IA64_OPND_P2)
9138 && p2 >= 16 && p2 < 63)
9139 {
9140 specs[count] = tmpl;
9141 specs[count].cmp_type =
9142 (or_andcm ? CMP_AND : (and_orcm ? CMP_OR : CMP_NONE));
9143 specs[count++].index = p2;
9144 }
9145 }
9146 else
9147 {
9148 if (CURR_SLOT.qp_regno >= 16 && CURR_SLOT.qp_regno < 63)
9149 {
9150 specs[count] = tmpl;
9151 specs[count++].index = CURR_SLOT.qp_regno;
9152 }
9153 if (idesc->operands[1] == IA64_OPND_PR)
9154 {
9155 for (i = 16; i < 63; i++)
9156 {
9157 specs[count] = tmpl;
9158 specs[count++].index = i;
9159 }
9160 }
9161 }
9162 }
9163 else
9164 {
9165 UNHANDLED;
9166 }
9167 break;
9168
9169 case IA64_RS_PSR:
9170 /* Verify that the instruction is using the PSR bit indicated in
9171 dep->regindex. */
9172 if (note == 0)
9173 {
9174 if (idesc->operands[!rsrc_write] == IA64_OPND_PSR_UM)
9175 {
9176 if (dep->regindex < 6)
9177 {
9178 specs[count++] = tmpl;
9179 }
9180 }
9181 else if (idesc->operands[!rsrc_write] == IA64_OPND_PSR)
9182 {
9183 if (dep->regindex < 32
9184 || dep->regindex == 35
9185 || dep->regindex == 36
9186 || (!rsrc_write && dep->regindex == PSR_CPL))
9187 {
9188 specs[count++] = tmpl;
9189 }
9190 }
9191 else if (idesc->operands[!rsrc_write] == IA64_OPND_PSR_L)
9192 {
9193 if (dep->regindex < 32
9194 || dep->regindex == 35
9195 || dep->regindex == 36
9196 || (rsrc_write && dep->regindex == PSR_CPL))
9197 {
9198 specs[count++] = tmpl;
9199 }
9200 }
9201 else
9202 {
9203 /* Several PSR bits have very specific dependencies. */
9204 switch (dep->regindex)
9205 {
9206 default:
9207 specs[count++] = tmpl;
9208 break;
9209 case PSR_IC:
9210 if (rsrc_write)
9211 {
9212 specs[count++] = tmpl;
9213 }
9214 else
9215 {
9216 /* Only certain CR accesses use PSR.ic */
9217 if (idesc->operands[0] == IA64_OPND_CR3
9218 || idesc->operands[1] == IA64_OPND_CR3)
9219 {
9220 int index =
9221 ((idesc->operands[0] == IA64_OPND_CR3)
9222 ? 0 : 1);
9223 int regno =
9224 CURR_SLOT.opnd[index].X_add_number - REG_CR;
9225
9226 switch (regno)
9227 {
9228 default:
9229 break;
9230 case CR_ITIR:
9231 case CR_IFS:
9232 case CR_IIM:
9233 case CR_IIP:
9234 case CR_IPSR:
9235 case CR_ISR:
9236 case CR_IFA:
9237 case CR_IHA:
9238 case CR_IIPA:
9239 specs[count++] = tmpl;
9240 break;
9241 }
9242 }
9243 }
9244 break;
9245 case PSR_CPL:
9246 if (rsrc_write)
9247 {
9248 specs[count++] = tmpl;
9249 }
9250 else
9251 {
9252 /* Only some AR accesses use cpl */
9253 if (idesc->operands[0] == IA64_OPND_AR3
9254 || idesc->operands[1] == IA64_OPND_AR3)
9255 {
9256 int index =
9257 ((idesc->operands[0] == IA64_OPND_AR3)
9258 ? 0 : 1);
9259 int regno =
9260 CURR_SLOT.opnd[index].X_add_number - REG_AR;
9261
9262 if (regno == AR_ITC
9263 || (index == 0
9264 && (regno == AR_ITC
9265 || regno == AR_RSC
9266 || (regno >= AR_K0
9267 && regno <= AR_K7))))
9268 {
9269 specs[count++] = tmpl;
9270 }
9271 }
9272 else
9273 {
9274 specs[count++] = tmpl;
9275 }
9276 break;
9277 }
9278 }
9279 }
9280 }
9281 else if (note == 7)
9282 {
9283 valueT mask = 0;
9284 if (idesc->operands[0] == IA64_OPND_IMMU24)
9285 {
9286 mask = CURR_SLOT.opnd[0].X_add_number;
9287 }
9288 else
9289 {
9290 UNHANDLED;
9291 }
9292 if (mask & ((valueT) 1 << dep->regindex))
9293 {
9294 specs[count++] = tmpl;
9295 }
9296 }
9297 else if (note == 8)
9298 {
9299 int min = dep->regindex == PSR_DFL ? 2 : 32;
9300 int max = dep->regindex == PSR_DFL ? 31 : 127;
9301 /* dfh is read on FR32-127; dfl is read on FR2-31 */
9302 for (i = 0; i < NELEMS (idesc->operands); i++)
9303 {
9304 if (idesc->operands[i] == IA64_OPND_F1
9305 || idesc->operands[i] == IA64_OPND_F2
9306 || idesc->operands[i] == IA64_OPND_F3
9307 || idesc->operands[i] == IA64_OPND_F4)
9308 {
9309 int reg = CURR_SLOT.opnd[i].X_add_number - REG_FR;
9310 if (reg >= min && reg <= max)
9311 {
9312 specs[count++] = tmpl;
9313 }
9314 }
9315 }
9316 }
9317 else if (note == 9)
9318 {
9319 int min = dep->regindex == PSR_MFL ? 2 : 32;
9320 int max = dep->regindex == PSR_MFL ? 31 : 127;
9321 /* mfh is read on writes to FR32-127; mfl is read on writes to
9322 FR2-31 */
9323 for (i = 0; i < idesc->num_outputs; i++)
9324 {
9325 if (idesc->operands[i] == IA64_OPND_F1)
9326 {
9327 int reg = CURR_SLOT.opnd[i].X_add_number - REG_FR;
9328 if (reg >= min && reg <= max)
9329 {
9330 specs[count++] = tmpl;
9331 }
9332 }
9333 }
9334 }
9335 else if (note == 10)
9336 {
9337 for (i = 0; i < NELEMS (idesc->operands); i++)
9338 {
9339 if (idesc->operands[i] == IA64_OPND_R1
9340 || idesc->operands[i] == IA64_OPND_R2
9341 || idesc->operands[i] == IA64_OPND_R3)
9342 {
9343 int regno = CURR_SLOT.opnd[i].X_add_number - REG_GR;
9344 if (regno >= 16 && regno <= 31)
9345 {
9346 specs[count++] = tmpl;
9347 }
9348 }
9349 }
9350 }
9351 else
9352 {
9353 UNHANDLED;
9354 }
9355 break;
9356
9357 case IA64_RS_AR_FPSR:
9358 if (idesc->operands[!rsrc_write] == IA64_OPND_AR3)
9359 {
9360 int regno = CURR_SLOT.opnd[!rsrc_write].X_add_number - REG_AR;
9361 if (regno == AR_FPSR)
9362 {
9363 specs[count++] = tmpl;
9364 }
9365 }
9366 else
9367 {
9368 specs[count++] = tmpl;
9369 }
9370 break;
9371
9372 case IA64_RS_ARX:
9373 /* Handle all AR[REG] resources */
9374 if (note == 0 || note == 1)
9375 {
9376 int regno = CURR_SLOT.opnd[!rsrc_write].X_add_number - REG_AR;
9377 if (idesc->operands[!rsrc_write] == IA64_OPND_AR3
9378 && regno == dep->regindex)
9379 {
9380 specs[count++] = tmpl;
9381 }
9382 /* other AR[REG] resources may be affected by AR accesses */
9383 else if (idesc->operands[0] == IA64_OPND_AR3)
9384 {
9385 /* AR[] writes */
9386 regno = CURR_SLOT.opnd[0].X_add_number - REG_AR;
9387 switch (dep->regindex)
9388 {
9389 default:
9390 break;
9391 case AR_BSP:
9392 case AR_RNAT:
9393 if (regno == AR_BSPSTORE)
9394 {
9395 specs[count++] = tmpl;
9396 }
9397 case AR_RSC:
9398 if (!rsrc_write &&
9399 (regno == AR_BSPSTORE
9400 || regno == AR_RNAT))
9401 {
9402 specs[count++] = tmpl;
9403 }
9404 break;
9405 }
9406 }
9407 else if (idesc->operands[1] == IA64_OPND_AR3)
9408 {
9409 /* AR[] reads */
9410 regno = CURR_SLOT.opnd[1].X_add_number - REG_AR;
9411 switch (dep->regindex)
9412 {
9413 default:
9414 break;
9415 case AR_RSC:
9416 if (regno == AR_BSPSTORE || regno == AR_RNAT)
9417 {
9418 specs[count++] = tmpl;
9419 }
9420 break;
9421 }
9422 }
9423 else
9424 {
9425 specs[count++] = tmpl;
9426 }
9427 }
9428 else
9429 {
9430 UNHANDLED;
9431 }
9432 break;
9433
9434 case IA64_RS_CRX:
9435 /* Handle all CR[REG] resources.
9436 ??? FIXME: The rule 17 isn't really handled correctly. */
9437 if (note == 0 || note == 1 || note == 17)
9438 {
9439 if (idesc->operands[!rsrc_write] == IA64_OPND_CR3)
9440 {
9441 int regno = CURR_SLOT.opnd[!rsrc_write].X_add_number - REG_CR;
9442 if (regno == dep->regindex)
9443 {
9444 specs[count++] = tmpl;
9445 }
9446 else if (!rsrc_write)
9447 {
9448 /* Reads from CR[IVR] affect other resources. */
9449 if (regno == CR_IVR)
9450 {
9451 if ((dep->regindex >= CR_IRR0
9452 && dep->regindex <= CR_IRR3)
9453 || dep->regindex == CR_TPR)
9454 {
9455 specs[count++] = tmpl;
9456 }
9457 }
9458 }
9459 }
9460 else
9461 {
9462 specs[count++] = tmpl;
9463 }
9464 }
9465 else
9466 {
9467 UNHANDLED;
9468 }
9469 break;
9470
9471 case IA64_RS_INSERVICE:
9472 /* look for write of EOI (67) or read of IVR (65) */
9473 if ((idesc->operands[0] == IA64_OPND_CR3
9474 && CURR_SLOT.opnd[0].X_add_number - REG_CR == CR_EOI)
9475 || (idesc->operands[1] == IA64_OPND_CR3
9476 && CURR_SLOT.opnd[1].X_add_number - REG_CR == CR_IVR))
9477 {
9478 specs[count++] = tmpl;
9479 }
9480 break;
9481
9482 case IA64_RS_GR0:
9483 if (note == 1)
9484 {
9485 specs[count++] = tmpl;
9486 }
9487 else
9488 {
9489 UNHANDLED;
9490 }
9491 break;
9492
9493 case IA64_RS_CFM:
9494 if (note != 2)
9495 {
9496 specs[count++] = tmpl;
9497 }
9498 else
9499 {
9500 /* Check if any of the registers accessed are in the rotating region.
9501 mov to/from pr accesses CFM only when qp_regno is in the rotating
9502 region */
9503 for (i = 0; i < NELEMS (idesc->operands); i++)
9504 {
9505 if (idesc->operands[i] == IA64_OPND_R1
9506 || idesc->operands[i] == IA64_OPND_R2
9507 || idesc->operands[i] == IA64_OPND_R3)
9508 {
9509 int num = CURR_SLOT.opnd[i].X_add_number - REG_GR;
9510 /* Assumes that md.rot.num_regs is always valid */
9511 if (md.rot.num_regs > 0
9512 && num > 31
9513 && num < 31 + md.rot.num_regs)
9514 {
9515 specs[count] = tmpl;
9516 specs[count++].specific = 0;
9517 }
9518 }
9519 else if (idesc->operands[i] == IA64_OPND_F1
9520 || idesc->operands[i] == IA64_OPND_F2
9521 || idesc->operands[i] == IA64_OPND_F3
9522 || idesc->operands[i] == IA64_OPND_F4)
9523 {
9524 int num = CURR_SLOT.opnd[i].X_add_number - REG_FR;
9525 if (num > 31)
9526 {
9527 specs[count] = tmpl;
9528 specs[count++].specific = 0;
9529 }
9530 }
9531 else if (idesc->operands[i] == IA64_OPND_P1
9532 || idesc->operands[i] == IA64_OPND_P2)
9533 {
9534 int num = CURR_SLOT.opnd[i].X_add_number - REG_P;
9535 if (num > 15)
9536 {
9537 specs[count] = tmpl;
9538 specs[count++].specific = 0;
9539 }
9540 }
9541 }
9542 if (CURR_SLOT.qp_regno > 15)
9543 {
9544 specs[count] = tmpl;
9545 specs[count++].specific = 0;
9546 }
9547 }
9548 break;
9549
9550 /* This is the same as IA64_RS_PRr, except simplified to account for
9551 the fact that there is only one register. */
9552 case IA64_RS_PR63:
9553 if (note == 0)
9554 {
9555 specs[count++] = tmpl;
9556 }
9557 else if (note == 7)
9558 {
9559 valueT mask = 0;
9560 if (idesc->operands[2] == IA64_OPND_IMM17)
9561 mask = CURR_SLOT.opnd[2].X_add_number;
9562 if (mask & ((valueT) 1 << 63))
9563 specs[count++] = tmpl;
9564 }
9565 else if (note == 11)
9566 {
9567 if ((idesc->operands[0] == IA64_OPND_P1
9568 && CURR_SLOT.opnd[0].X_add_number - REG_P == 63)
9569 || (idesc->operands[1] == IA64_OPND_P2
9570 && CURR_SLOT.opnd[1].X_add_number - REG_P == 63))
9571 {
9572 specs[count++] = tmpl;
9573 }
9574 }
9575 else if (note == 12)
9576 {
9577 if (CURR_SLOT.qp_regno == 63)
9578 {
9579 specs[count++] = tmpl;
9580 }
9581 }
9582 else if (note == 1)
9583 {
9584 if (rsrc_write)
9585 {
9586 int p1 = CURR_SLOT.opnd[0].X_add_number - REG_P;
9587 int p2 = CURR_SLOT.opnd[1].X_add_number - REG_P;
9588 int or_andcm = strstr (idesc->name, "or.andcm") != NULL;
9589 int and_orcm = strstr (idesc->name, "and.orcm") != NULL;
9590
9591 if (p1 == 63
9592 && (idesc->operands[0] == IA64_OPND_P1
9593 || idesc->operands[0] == IA64_OPND_P2))
9594 {
9595 specs[count] = tmpl;
9596 specs[count++].cmp_type =
9597 (or_andcm ? CMP_OR : (and_orcm ? CMP_AND : CMP_NONE));
9598 }
9599 if (p2 == 63
9600 && (idesc->operands[1] == IA64_OPND_P1
9601 || idesc->operands[1] == IA64_OPND_P2))
9602 {
9603 specs[count] = tmpl;
9604 specs[count++].cmp_type =
9605 (or_andcm ? CMP_AND : (and_orcm ? CMP_OR : CMP_NONE));
9606 }
9607 }
9608 else
9609 {
9610 if (CURR_SLOT.qp_regno == 63)
9611 {
9612 specs[count++] = tmpl;
9613 }
9614 }
9615 }
9616 else
9617 {
9618 UNHANDLED;
9619 }
9620 break;
9621
9622 case IA64_RS_RSE:
9623 /* FIXME we can identify some individual RSE written resources, but RSE
9624 read resources have not yet been completely identified, so for now
9625 treat RSE as a single resource */
9626 if (strncmp (idesc->name, "mov", 3) == 0)
9627 {
9628 if (rsrc_write)
9629 {
9630 if (idesc->operands[0] == IA64_OPND_AR3
9631 && CURR_SLOT.opnd[0].X_add_number - REG_AR == AR_BSPSTORE)
9632 {
9633 specs[count++] = tmpl;
9634 }
9635 }
9636 else
9637 {
9638 if (idesc->operands[0] == IA64_OPND_AR3)
9639 {
9640 if (CURR_SLOT.opnd[0].X_add_number - REG_AR == AR_BSPSTORE
9641 || CURR_SLOT.opnd[0].X_add_number - REG_AR == AR_RNAT)
9642 {
9643 specs[count++] = tmpl;
9644 }
9645 }
9646 else if (idesc->operands[1] == IA64_OPND_AR3)
9647 {
9648 if (CURR_SLOT.opnd[1].X_add_number - REG_AR == AR_BSP
9649 || CURR_SLOT.opnd[1].X_add_number - REG_AR == AR_BSPSTORE
9650 || CURR_SLOT.opnd[1].X_add_number - REG_AR == AR_RNAT)
9651 {
9652 specs[count++] = tmpl;
9653 }
9654 }
9655 }
9656 }
9657 else
9658 {
9659 specs[count++] = tmpl;
9660 }
9661 break;
9662
9663 case IA64_RS_ANY:
9664 /* FIXME -- do any of these need to be non-specific? */
9665 specs[count++] = tmpl;
9666 break;
9667
9668 default:
9669 as_bad (_("Unrecognized dependency specifier %d\n"), dep->specifier);
9670 break;
9671 }
9672
9673 return count;
9674 }
9675
9676 /* Clear branch flags on marked resources. This breaks the link between the
9677 QP of the marking instruction and a subsequent branch on the same QP. */
9678
9679 static void
clear_qp_branch_flag(mask)9680 clear_qp_branch_flag (mask)
9681 valueT mask;
9682 {
9683 int i;
9684 for (i = 0; i < regdepslen; i++)
9685 {
9686 valueT bit = ((valueT) 1 << regdeps[i].qp_regno);
9687 if ((bit & mask) != 0)
9688 {
9689 regdeps[i].link_to_qp_branch = 0;
9690 }
9691 }
9692 }
9693
9694 /* MASK contains 2 and only 2 PRs which are mutually exclusive. Remove
9695 any mutexes which contain one of the PRs and create new ones when
9696 needed. */
9697
9698 static int
update_qp_mutex(valueT mask)9699 update_qp_mutex (valueT mask)
9700 {
9701 int i;
9702 int add = 0;
9703
9704 i = 0;
9705 while (i < qp_mutexeslen)
9706 {
9707 if ((qp_mutexes[i].prmask & mask) != 0)
9708 {
9709 /* If it destroys and creates the same mutex, do nothing. */
9710 if (qp_mutexes[i].prmask == mask
9711 && qp_mutexes[i].path == md.path)
9712 {
9713 i++;
9714 add = -1;
9715 }
9716 else
9717 {
9718 int keep = 0;
9719
9720 if (md.debug_dv)
9721 {
9722 fprintf (stderr, " Clearing mutex relation");
9723 print_prmask (qp_mutexes[i].prmask);
9724 fprintf (stderr, "\n");
9725 }
9726
9727 /* Deal with the old mutex with more than 3+ PRs only if
9728 the new mutex on the same execution path with it.
9729
9730 FIXME: The 3+ mutex support is incomplete.
9731 dot_pred_rel () may be a better place to fix it. */
9732 if (qp_mutexes[i].path == md.path)
9733 {
9734 /* If it is a proper subset of the mutex, create a
9735 new mutex. */
9736 if (add == 0
9737 && (qp_mutexes[i].prmask & mask) == mask)
9738 add = 1;
9739
9740 qp_mutexes[i].prmask &= ~mask;
9741 if (qp_mutexes[i].prmask & (qp_mutexes[i].prmask - 1))
9742 {
9743 /* Modify the mutex if there are more than one
9744 PR left. */
9745 keep = 1;
9746 i++;
9747 }
9748 }
9749
9750 if (keep == 0)
9751 /* Remove the mutex. */
9752 qp_mutexes[i] = qp_mutexes[--qp_mutexeslen];
9753 }
9754 }
9755 else
9756 ++i;
9757 }
9758
9759 if (add == 1)
9760 add_qp_mutex (mask);
9761
9762 return add;
9763 }
9764
9765 /* Remove any mutexes which contain any of the PRs indicated in the mask.
9766
9767 Any changes to a PR clears the mutex relations which include that PR. */
9768
9769 static void
clear_qp_mutex(mask)9770 clear_qp_mutex (mask)
9771 valueT mask;
9772 {
9773 int i;
9774
9775 i = 0;
9776 while (i < qp_mutexeslen)
9777 {
9778 if ((qp_mutexes[i].prmask & mask) != 0)
9779 {
9780 if (md.debug_dv)
9781 {
9782 fprintf (stderr, " Clearing mutex relation");
9783 print_prmask (qp_mutexes[i].prmask);
9784 fprintf (stderr, "\n");
9785 }
9786 qp_mutexes[i] = qp_mutexes[--qp_mutexeslen];
9787 }
9788 else
9789 ++i;
9790 }
9791 }
9792
9793 /* Clear implies relations which contain PRs in the given masks.
9794 P1_MASK indicates the source of the implies relation, while P2_MASK
9795 indicates the implied PR. */
9796
9797 static void
clear_qp_implies(p1_mask,p2_mask)9798 clear_qp_implies (p1_mask, p2_mask)
9799 valueT p1_mask;
9800 valueT p2_mask;
9801 {
9802 int i;
9803
9804 i = 0;
9805 while (i < qp_implieslen)
9806 {
9807 if ((((valueT) 1 << qp_implies[i].p1) & p1_mask) != 0
9808 || (((valueT) 1 << qp_implies[i].p2) & p2_mask) != 0)
9809 {
9810 if (md.debug_dv)
9811 fprintf (stderr, "Clearing implied relation PR%d->PR%d\n",
9812 qp_implies[i].p1, qp_implies[i].p2);
9813 qp_implies[i] = qp_implies[--qp_implieslen];
9814 }
9815 else
9816 ++i;
9817 }
9818 }
9819
9820 /* Add the PRs specified to the list of implied relations. */
9821
9822 static void
add_qp_imply(p1,p2)9823 add_qp_imply (p1, p2)
9824 int p1, p2;
9825 {
9826 valueT mask;
9827 valueT bit;
9828 int i;
9829
9830 /* p0 is not meaningful here. */
9831 if (p1 == 0 || p2 == 0)
9832 abort ();
9833
9834 if (p1 == p2)
9835 return;
9836
9837 /* If it exists already, ignore it. */
9838 for (i = 0; i < qp_implieslen; i++)
9839 {
9840 if (qp_implies[i].p1 == p1
9841 && qp_implies[i].p2 == p2
9842 && qp_implies[i].path == md.path
9843 && !qp_implies[i].p2_branched)
9844 return;
9845 }
9846
9847 if (qp_implieslen == qp_impliestotlen)
9848 {
9849 qp_impliestotlen += 20;
9850 qp_implies = (struct qp_imply *)
9851 xrealloc ((void *) qp_implies,
9852 qp_impliestotlen * sizeof (struct qp_imply));
9853 }
9854 if (md.debug_dv)
9855 fprintf (stderr, " Registering PR%d implies PR%d\n", p1, p2);
9856 qp_implies[qp_implieslen].p1 = p1;
9857 qp_implies[qp_implieslen].p2 = p2;
9858 qp_implies[qp_implieslen].path = md.path;
9859 qp_implies[qp_implieslen++].p2_branched = 0;
9860
9861 /* Add in the implied transitive relations; for everything that p2 implies,
9862 make p1 imply that, too; for everything that implies p1, make it imply p2
9863 as well. */
9864 for (i = 0; i < qp_implieslen; i++)
9865 {
9866 if (qp_implies[i].p1 == p2)
9867 add_qp_imply (p1, qp_implies[i].p2);
9868 if (qp_implies[i].p2 == p1)
9869 add_qp_imply (qp_implies[i].p1, p2);
9870 }
9871 /* Add in mutex relations implied by this implies relation; for each mutex
9872 relation containing p2, duplicate it and replace p2 with p1. */
9873 bit = (valueT) 1 << p1;
9874 mask = (valueT) 1 << p2;
9875 for (i = 0; i < qp_mutexeslen; i++)
9876 {
9877 if (qp_mutexes[i].prmask & mask)
9878 add_qp_mutex ((qp_mutexes[i].prmask & ~mask) | bit);
9879 }
9880 }
9881
9882 /* Add the PRs specified in the mask to the mutex list; this means that only
9883 one of the PRs can be true at any time. PR0 should never be included in
9884 the mask. */
9885
9886 static void
add_qp_mutex(mask)9887 add_qp_mutex (mask)
9888 valueT mask;
9889 {
9890 if (mask & 0x1)
9891 abort ();
9892
9893 if (qp_mutexeslen == qp_mutexestotlen)
9894 {
9895 qp_mutexestotlen += 20;
9896 qp_mutexes = (struct qpmutex *)
9897 xrealloc ((void *) qp_mutexes,
9898 qp_mutexestotlen * sizeof (struct qpmutex));
9899 }
9900 if (md.debug_dv)
9901 {
9902 fprintf (stderr, " Registering mutex on");
9903 print_prmask (mask);
9904 fprintf (stderr, "\n");
9905 }
9906 qp_mutexes[qp_mutexeslen].path = md.path;
9907 qp_mutexes[qp_mutexeslen++].prmask = mask;
9908 }
9909
9910 static int
has_suffix_p(name,suffix)9911 has_suffix_p (name, suffix)
9912 const char *name;
9913 const char *suffix;
9914 {
9915 size_t namelen = strlen (name);
9916 size_t sufflen = strlen (suffix);
9917
9918 if (namelen <= sufflen)
9919 return 0;
9920 return strcmp (name + namelen - sufflen, suffix) == 0;
9921 }
9922
9923 static void
clear_register_values()9924 clear_register_values ()
9925 {
9926 int i;
9927 if (md.debug_dv)
9928 fprintf (stderr, " Clearing register values\n");
9929 for (i = 1; i < NELEMS (gr_values); i++)
9930 gr_values[i].known = 0;
9931 }
9932
9933 /* Keep track of register values/changes which affect DV tracking.
9934
9935 optimization note: should add a flag to classes of insns where otherwise we
9936 have to examine a group of strings to identify them. */
9937
9938 static void
note_register_values(idesc)9939 note_register_values (idesc)
9940 struct ia64_opcode *idesc;
9941 {
9942 valueT qp_changemask = 0;
9943 int i;
9944
9945 /* Invalidate values for registers being written to. */
9946 for (i = 0; i < idesc->num_outputs; i++)
9947 {
9948 if (idesc->operands[i] == IA64_OPND_R1
9949 || idesc->operands[i] == IA64_OPND_R2
9950 || idesc->operands[i] == IA64_OPND_R3)
9951 {
9952 int regno = CURR_SLOT.opnd[i].X_add_number - REG_GR;
9953 if (regno > 0 && regno < NELEMS (gr_values))
9954 gr_values[regno].known = 0;
9955 }
9956 else if (idesc->operands[i] == IA64_OPND_R3_2)
9957 {
9958 int regno = CURR_SLOT.opnd[i].X_add_number - REG_GR;
9959 if (regno > 0 && regno < 4)
9960 gr_values[regno].known = 0;
9961 }
9962 else if (idesc->operands[i] == IA64_OPND_P1
9963 || idesc->operands[i] == IA64_OPND_P2)
9964 {
9965 int regno = CURR_SLOT.opnd[i].X_add_number - REG_P;
9966 qp_changemask |= (valueT) 1 << regno;
9967 }
9968 else if (idesc->operands[i] == IA64_OPND_PR)
9969 {
9970 if (idesc->operands[2] & (valueT) 0x10000)
9971 qp_changemask = ~(valueT) 0x1FFFF | idesc->operands[2];
9972 else
9973 qp_changemask = idesc->operands[2];
9974 break;
9975 }
9976 else if (idesc->operands[i] == IA64_OPND_PR_ROT)
9977 {
9978 if (idesc->operands[1] & ((valueT) 1 << 43))
9979 qp_changemask = -((valueT) 1 << 44) | idesc->operands[1];
9980 else
9981 qp_changemask = idesc->operands[1];
9982 qp_changemask &= ~(valueT) 0xFFFF;
9983 break;
9984 }
9985 }
9986
9987 /* Always clear qp branch flags on any PR change. */
9988 /* FIXME there may be exceptions for certain compares. */
9989 clear_qp_branch_flag (qp_changemask);
9990
9991 /* Invalidate rotating registers on insns which affect RRBs in CFM. */
9992 if (idesc->flags & IA64_OPCODE_MOD_RRBS)
9993 {
9994 qp_changemask |= ~(valueT) 0xFFFF;
9995 if (strcmp (idesc->name, "clrrrb.pr") != 0)
9996 {
9997 for (i = 32; i < 32 + md.rot.num_regs; i++)
9998 gr_values[i].known = 0;
9999 }
10000 clear_qp_mutex (qp_changemask);
10001 clear_qp_implies (qp_changemask, qp_changemask);
10002 }
10003 /* After a call, all register values are undefined, except those marked
10004 as "safe". */
10005 else if (strncmp (idesc->name, "br.call", 6) == 0
10006 || strncmp (idesc->name, "brl.call", 7) == 0)
10007 {
10008 /* FIXME keep GR values which are marked as "safe_across_calls" */
10009 clear_register_values ();
10010 clear_qp_mutex (~qp_safe_across_calls);
10011 clear_qp_implies (~qp_safe_across_calls, ~qp_safe_across_calls);
10012 clear_qp_branch_flag (~qp_safe_across_calls);
10013 }
10014 else if (is_interruption_or_rfi (idesc)
10015 || is_taken_branch (idesc))
10016 {
10017 clear_register_values ();
10018 clear_qp_mutex (~(valueT) 0);
10019 clear_qp_implies (~(valueT) 0, ~(valueT) 0);
10020 }
10021 /* Look for mutex and implies relations. */
10022 else if ((idesc->operands[0] == IA64_OPND_P1
10023 || idesc->operands[0] == IA64_OPND_P2)
10024 && (idesc->operands[1] == IA64_OPND_P1
10025 || idesc->operands[1] == IA64_OPND_P2))
10026 {
10027 int p1 = CURR_SLOT.opnd[0].X_add_number - REG_P;
10028 int p2 = CURR_SLOT.opnd[1].X_add_number - REG_P;
10029 valueT p1mask = (p1 != 0) ? (valueT) 1 << p1 : 0;
10030 valueT p2mask = (p2 != 0) ? (valueT) 1 << p2 : 0;
10031
10032 /* If both PRs are PR0, we can't really do anything. */
10033 if (p1 == 0 && p2 == 0)
10034 {
10035 if (md.debug_dv)
10036 fprintf (stderr, " Ignoring PRs due to inclusion of p0\n");
10037 }
10038 /* In general, clear mutexes and implies which include P1 or P2,
10039 with the following exceptions. */
10040 else if (has_suffix_p (idesc->name, ".or.andcm")
10041 || has_suffix_p (idesc->name, ".and.orcm"))
10042 {
10043 clear_qp_implies (p2mask, p1mask);
10044 }
10045 else if (has_suffix_p (idesc->name, ".andcm")
10046 || has_suffix_p (idesc->name, ".and"))
10047 {
10048 clear_qp_implies (0, p1mask | p2mask);
10049 }
10050 else if (has_suffix_p (idesc->name, ".orcm")
10051 || has_suffix_p (idesc->name, ".or"))
10052 {
10053 clear_qp_mutex (p1mask | p2mask);
10054 clear_qp_implies (p1mask | p2mask, 0);
10055 }
10056 else
10057 {
10058 int added = 0;
10059
10060 clear_qp_implies (p1mask | p2mask, p1mask | p2mask);
10061
10062 /* If one of the PRs is PR0, we call clear_qp_mutex. */
10063 if (p1 == 0 || p2 == 0)
10064 clear_qp_mutex (p1mask | p2mask);
10065 else
10066 added = update_qp_mutex (p1mask | p2mask);
10067
10068 if (CURR_SLOT.qp_regno == 0
10069 || has_suffix_p (idesc->name, ".unc"))
10070 {
10071 if (added == 0 && p1 && p2)
10072 add_qp_mutex (p1mask | p2mask);
10073 if (CURR_SLOT.qp_regno != 0)
10074 {
10075 if (p1)
10076 add_qp_imply (p1, CURR_SLOT.qp_regno);
10077 if (p2)
10078 add_qp_imply (p2, CURR_SLOT.qp_regno);
10079 }
10080 }
10081 }
10082 }
10083 /* Look for mov imm insns into GRs. */
10084 else if (idesc->operands[0] == IA64_OPND_R1
10085 && (idesc->operands[1] == IA64_OPND_IMM22
10086 || idesc->operands[1] == IA64_OPND_IMMU64)
10087 && CURR_SLOT.opnd[1].X_op == O_constant
10088 && (strcmp (idesc->name, "mov") == 0
10089 || strcmp (idesc->name, "movl") == 0))
10090 {
10091 int regno = CURR_SLOT.opnd[0].X_add_number - REG_GR;
10092 if (regno > 0 && regno < NELEMS (gr_values))
10093 {
10094 gr_values[regno].known = 1;
10095 gr_values[regno].value = CURR_SLOT.opnd[1].X_add_number;
10096 gr_values[regno].path = md.path;
10097 if (md.debug_dv)
10098 {
10099 fprintf (stderr, " Know gr%d = ", regno);
10100 fprintf_vma (stderr, gr_values[regno].value);
10101 fputs ("\n", stderr);
10102 }
10103 }
10104 }
10105 /* Look for dep.z imm insns. */
10106 else if (idesc->operands[0] == IA64_OPND_R1
10107 && idesc->operands[1] == IA64_OPND_IMM8
10108 && strcmp (idesc->name, "dep.z") == 0)
10109 {
10110 int regno = CURR_SLOT.opnd[0].X_add_number - REG_GR;
10111 if (regno > 0 && regno < NELEMS (gr_values))
10112 {
10113 valueT value = CURR_SLOT.opnd[1].X_add_number;
10114
10115 if (CURR_SLOT.opnd[3].X_add_number < 64)
10116 value &= ((valueT)1 << CURR_SLOT.opnd[3].X_add_number) - 1;
10117 value <<= CURR_SLOT.opnd[2].X_add_number;
10118 gr_values[regno].known = 1;
10119 gr_values[regno].value = value;
10120 gr_values[regno].path = md.path;
10121 if (md.debug_dv)
10122 {
10123 fprintf (stderr, " Know gr%d = ", regno);
10124 fprintf_vma (stderr, gr_values[regno].value);
10125 fputs ("\n", stderr);
10126 }
10127 }
10128 }
10129 else
10130 {
10131 clear_qp_mutex (qp_changemask);
10132 clear_qp_implies (qp_changemask, qp_changemask);
10133 }
10134 }
10135
10136 /* Return whether the given predicate registers are currently mutex. */
10137
10138 static int
qp_mutex(p1,p2,path)10139 qp_mutex (p1, p2, path)
10140 int p1;
10141 int p2;
10142 int path;
10143 {
10144 int i;
10145 valueT mask;
10146
10147 if (p1 != p2)
10148 {
10149 mask = ((valueT) 1 << p1) | (valueT) 1 << p2;
10150 for (i = 0; i < qp_mutexeslen; i++)
10151 {
10152 if (qp_mutexes[i].path >= path
10153 && (qp_mutexes[i].prmask & mask) == mask)
10154 return 1;
10155 }
10156 }
10157 return 0;
10158 }
10159
10160 /* Return whether the given resource is in the given insn's list of chks
10161 Return 1 if the conflict is absolutely determined, 2 if it's a potential
10162 conflict. */
10163
10164 static int
resources_match(rs,idesc,note,qp_regno,path)10165 resources_match (rs, idesc, note, qp_regno, path)
10166 struct rsrc *rs;
10167 struct ia64_opcode *idesc;
10168 int note;
10169 int qp_regno;
10170 int path;
10171 {
10172 struct rsrc specs[MAX_SPECS];
10173 int count;
10174
10175 /* If the marked resource's qp_regno and the given qp_regno are mutex,
10176 we don't need to check. One exception is note 11, which indicates that
10177 target predicates are written regardless of PR[qp]. */
10178 if (qp_mutex (rs->qp_regno, qp_regno, path)
10179 && note != 11)
10180 return 0;
10181
10182 count = specify_resource (rs->dependency, idesc, DV_CHK, specs, note, path);
10183 while (count-- > 0)
10184 {
10185 /* UNAT checking is a bit more specific than other resources */
10186 if (rs->dependency->specifier == IA64_RS_AR_UNAT
10187 && specs[count].mem_offset.hint
10188 && rs->mem_offset.hint)
10189 {
10190 if (rs->mem_offset.base == specs[count].mem_offset.base)
10191 {
10192 if (((rs->mem_offset.offset >> 3) & 0x3F) ==
10193 ((specs[count].mem_offset.offset >> 3) & 0x3F))
10194 return 1;
10195 else
10196 continue;
10197 }
10198 }
10199
10200 /* Skip apparent PR write conflicts where both writes are an AND or both
10201 writes are an OR. */
10202 if (rs->dependency->specifier == IA64_RS_PR
10203 || rs->dependency->specifier == IA64_RS_PRr
10204 || rs->dependency->specifier == IA64_RS_PR63)
10205 {
10206 if (specs[count].cmp_type != CMP_NONE
10207 && specs[count].cmp_type == rs->cmp_type)
10208 {
10209 if (md.debug_dv)
10210 fprintf (stderr, " %s on parallel compare allowed (PR%d)\n",
10211 dv_mode[rs->dependency->mode],
10212 rs->dependency->specifier != IA64_RS_PR63 ?
10213 specs[count].index : 63);
10214 continue;
10215 }
10216 if (md.debug_dv)
10217 fprintf (stderr,
10218 " %s on parallel compare conflict %s vs %s on PR%d\n",
10219 dv_mode[rs->dependency->mode],
10220 dv_cmp_type[rs->cmp_type],
10221 dv_cmp_type[specs[count].cmp_type],
10222 rs->dependency->specifier != IA64_RS_PR63 ?
10223 specs[count].index : 63);
10224
10225 }
10226
10227 /* If either resource is not specific, conservatively assume a conflict
10228 */
10229 if (!specs[count].specific || !rs->specific)
10230 return 2;
10231 else if (specs[count].index == rs->index)
10232 return 1;
10233 }
10234
10235 return 0;
10236 }
10237
10238 /* Indicate an instruction group break; if INSERT_STOP is non-zero, then
10239 insert a stop to create the break. Update all resource dependencies
10240 appropriately. If QP_REGNO is non-zero, only apply the break to resources
10241 which use the same QP_REGNO and have the link_to_qp_branch flag set.
10242 If SAVE_CURRENT is non-zero, don't affect resources marked by the current
10243 instruction. */
10244
10245 static void
insn_group_break(insert_stop,qp_regno,save_current)10246 insn_group_break (insert_stop, qp_regno, save_current)
10247 int insert_stop;
10248 int qp_regno;
10249 int save_current;
10250 {
10251 int i;
10252
10253 if (insert_stop && md.num_slots_in_use > 0)
10254 PREV_SLOT.end_of_insn_group = 1;
10255
10256 if (md.debug_dv)
10257 {
10258 fprintf (stderr, " Insn group break%s",
10259 (insert_stop ? " (w/stop)" : ""));
10260 if (qp_regno != 0)
10261 fprintf (stderr, " effective for QP=%d", qp_regno);
10262 fprintf (stderr, "\n");
10263 }
10264
10265 i = 0;
10266 while (i < regdepslen)
10267 {
10268 const struct ia64_dependency *dep = regdeps[i].dependency;
10269
10270 if (qp_regno != 0
10271 && regdeps[i].qp_regno != qp_regno)
10272 {
10273 ++i;
10274 continue;
10275 }
10276
10277 if (save_current
10278 && CURR_SLOT.src_file == regdeps[i].file
10279 && CURR_SLOT.src_line == regdeps[i].line)
10280 {
10281 ++i;
10282 continue;
10283 }
10284
10285 /* clear dependencies which are automatically cleared by a stop, or
10286 those that have reached the appropriate state of insn serialization */
10287 if (dep->semantics == IA64_DVS_IMPLIED
10288 || dep->semantics == IA64_DVS_IMPLIEDF
10289 || regdeps[i].insn_srlz == STATE_SRLZ)
10290 {
10291 print_dependency ("Removing", i);
10292 regdeps[i] = regdeps[--regdepslen];
10293 }
10294 else
10295 {
10296 if (dep->semantics == IA64_DVS_DATA
10297 || dep->semantics == IA64_DVS_INSTR
10298 || dep->semantics == IA64_DVS_SPECIFIC)
10299 {
10300 if (regdeps[i].insn_srlz == STATE_NONE)
10301 regdeps[i].insn_srlz = STATE_STOP;
10302 if (regdeps[i].data_srlz == STATE_NONE)
10303 regdeps[i].data_srlz = STATE_STOP;
10304 }
10305 ++i;
10306 }
10307 }
10308 }
10309
10310 /* Add the given resource usage spec to the list of active dependencies. */
10311
10312 static void
mark_resource(idesc,dep,spec,depind,path)10313 mark_resource (idesc, dep, spec, depind, path)
10314 struct ia64_opcode *idesc ATTRIBUTE_UNUSED;
10315 const struct ia64_dependency *dep ATTRIBUTE_UNUSED;
10316 struct rsrc *spec;
10317 int depind;
10318 int path;
10319 {
10320 if (regdepslen == regdepstotlen)
10321 {
10322 regdepstotlen += 20;
10323 regdeps = (struct rsrc *)
10324 xrealloc ((void *) regdeps,
10325 regdepstotlen * sizeof (struct rsrc));
10326 }
10327
10328 regdeps[regdepslen] = *spec;
10329 regdeps[regdepslen].depind = depind;
10330 regdeps[regdepslen].path = path;
10331 regdeps[regdepslen].file = CURR_SLOT.src_file;
10332 regdeps[regdepslen].line = CURR_SLOT.src_line;
10333
10334 print_dependency ("Adding", regdepslen);
10335
10336 ++regdepslen;
10337 }
10338
10339 static void
print_dependency(action,depind)10340 print_dependency (action, depind)
10341 const char *action;
10342 int depind;
10343 {
10344 if (md.debug_dv)
10345 {
10346 fprintf (stderr, " %s %s '%s'",
10347 action, dv_mode[(regdeps[depind].dependency)->mode],
10348 (regdeps[depind].dependency)->name);
10349 if (regdeps[depind].specific && regdeps[depind].index >= 0)
10350 fprintf (stderr, " (%d)", regdeps[depind].index);
10351 if (regdeps[depind].mem_offset.hint)
10352 {
10353 fputs (" ", stderr);
10354 fprintf_vma (stderr, regdeps[depind].mem_offset.base);
10355 fputs ("+", stderr);
10356 fprintf_vma (stderr, regdeps[depind].mem_offset.offset);
10357 }
10358 fprintf (stderr, "\n");
10359 }
10360 }
10361
10362 static void
instruction_serialization()10363 instruction_serialization ()
10364 {
10365 int i;
10366 if (md.debug_dv)
10367 fprintf (stderr, " Instruction serialization\n");
10368 for (i = 0; i < regdepslen; i++)
10369 if (regdeps[i].insn_srlz == STATE_STOP)
10370 regdeps[i].insn_srlz = STATE_SRLZ;
10371 }
10372
10373 static void
data_serialization()10374 data_serialization ()
10375 {
10376 int i = 0;
10377 if (md.debug_dv)
10378 fprintf (stderr, " Data serialization\n");
10379 while (i < regdepslen)
10380 {
10381 if (regdeps[i].data_srlz == STATE_STOP
10382 /* Note: as of 991210, all "other" dependencies are cleared by a
10383 data serialization. This might change with new tables */
10384 || (regdeps[i].dependency)->semantics == IA64_DVS_OTHER)
10385 {
10386 print_dependency ("Removing", i);
10387 regdeps[i] = regdeps[--regdepslen];
10388 }
10389 else
10390 ++i;
10391 }
10392 }
10393
10394 /* Insert stops and serializations as needed to avoid DVs. */
10395
10396 static void
remove_marked_resource(rs)10397 remove_marked_resource (rs)
10398 struct rsrc *rs;
10399 {
10400 switch (rs->dependency->semantics)
10401 {
10402 case IA64_DVS_SPECIFIC:
10403 if (md.debug_dv)
10404 fprintf (stderr, "Implementation-specific, assume worst case...\n");
10405 /* ...fall through... */
10406 case IA64_DVS_INSTR:
10407 if (md.debug_dv)
10408 fprintf (stderr, "Inserting instr serialization\n");
10409 if (rs->insn_srlz < STATE_STOP)
10410 insn_group_break (1, 0, 0);
10411 if (rs->insn_srlz < STATE_SRLZ)
10412 {
10413 struct slot oldslot = CURR_SLOT;
10414 /* Manually jam a srlz.i insn into the stream */
10415 memset (&CURR_SLOT, 0, sizeof (CURR_SLOT));
10416 CURR_SLOT.user_template = -1;
10417 CURR_SLOT.idesc = ia64_find_opcode ("srlz.i");
10418 instruction_serialization ();
10419 md.curr_slot = (md.curr_slot + 1) % NUM_SLOTS;
10420 if (++md.num_slots_in_use >= NUM_SLOTS)
10421 emit_one_bundle ();
10422 CURR_SLOT = oldslot;
10423 }
10424 insn_group_break (1, 0, 0);
10425 break;
10426 case IA64_DVS_OTHER: /* as of rev2 (991220) of the DV tables, all
10427 "other" types of DV are eliminated
10428 by a data serialization */
10429 case IA64_DVS_DATA:
10430 if (md.debug_dv)
10431 fprintf (stderr, "Inserting data serialization\n");
10432 if (rs->data_srlz < STATE_STOP)
10433 insn_group_break (1, 0, 0);
10434 {
10435 struct slot oldslot = CURR_SLOT;
10436 /* Manually jam a srlz.d insn into the stream */
10437 memset (&CURR_SLOT, 0, sizeof (CURR_SLOT));
10438 CURR_SLOT.user_template = -1;
10439 CURR_SLOT.idesc = ia64_find_opcode ("srlz.d");
10440 data_serialization ();
10441 md.curr_slot = (md.curr_slot + 1) % NUM_SLOTS;
10442 if (++md.num_slots_in_use >= NUM_SLOTS)
10443 emit_one_bundle ();
10444 CURR_SLOT = oldslot;
10445 }
10446 break;
10447 case IA64_DVS_IMPLIED:
10448 case IA64_DVS_IMPLIEDF:
10449 if (md.debug_dv)
10450 fprintf (stderr, "Inserting stop\n");
10451 insn_group_break (1, 0, 0);
10452 break;
10453 default:
10454 break;
10455 }
10456 }
10457
10458 /* Check the resources used by the given opcode against the current dependency
10459 list.
10460
10461 The check is run once for each execution path encountered. In this case,
10462 a unique execution path is the sequence of instructions following a code
10463 entry point, e.g. the following has three execution paths, one starting
10464 at L0, one at L1, and one at L2.
10465
10466 L0: nop
10467 L1: add
10468 L2: add
10469 br.ret
10470 */
10471
10472 static void
check_dependencies(idesc)10473 check_dependencies (idesc)
10474 struct ia64_opcode *idesc;
10475 {
10476 const struct ia64_opcode_dependency *opdeps = idesc->dependencies;
10477 int path;
10478 int i;
10479
10480 /* Note that the number of marked resources may change within the
10481 loop if in auto mode. */
10482 i = 0;
10483 while (i < regdepslen)
10484 {
10485 struct rsrc *rs = ®deps[i];
10486 const struct ia64_dependency *dep = rs->dependency;
10487 int chkind;
10488 int note;
10489 int start_over = 0;
10490
10491 if (dep->semantics == IA64_DVS_NONE
10492 || (chkind = depends_on (rs->depind, idesc)) == -1)
10493 {
10494 ++i;
10495 continue;
10496 }
10497
10498 note = NOTE (opdeps->chks[chkind]);
10499
10500 /* Check this resource against each execution path seen thus far. */
10501 for (path = 0; path <= md.path; path++)
10502 {
10503 int matchtype;
10504
10505 /* If the dependency wasn't on the path being checked, ignore it. */
10506 if (rs->path < path)
10507 continue;
10508
10509 /* If the QP for this insn implies a QP which has branched, don't
10510 bother checking. Ed. NOTE: I don't think this check is terribly
10511 useful; what's the point of generating code which will only be
10512 reached if its QP is zero?
10513 This code was specifically inserted to handle the following code,
10514 based on notes from Intel's DV checking code, where p1 implies p2.
10515
10516 mov r4 = 2
10517 (p2) br.cond L
10518 (p1) mov r4 = 7
10519 */
10520 if (CURR_SLOT.qp_regno != 0)
10521 {
10522 int skip = 0;
10523 int implies;
10524 for (implies = 0; implies < qp_implieslen; implies++)
10525 {
10526 if (qp_implies[implies].path >= path
10527 && qp_implies[implies].p1 == CURR_SLOT.qp_regno
10528 && qp_implies[implies].p2_branched)
10529 {
10530 skip = 1;
10531 break;
10532 }
10533 }
10534 if (skip)
10535 continue;
10536 }
10537
10538 if ((matchtype = resources_match (rs, idesc, note,
10539 CURR_SLOT.qp_regno, path)) != 0)
10540 {
10541 char msg[1024];
10542 char pathmsg[256] = "";
10543 char indexmsg[256] = "";
10544 int certain = (matchtype == 1 && CURR_SLOT.qp_regno == 0);
10545
10546 if (path != 0)
10547 sprintf (pathmsg, " when entry is at label '%s'",
10548 md.entry_labels[path - 1]);
10549 if (matchtype == 1 && rs->index >= 0)
10550 sprintf (indexmsg, ", specific resource number is %d",
10551 rs->index);
10552 sprintf (msg, "Use of '%s' %s %s dependency '%s' (%s)%s%s",
10553 idesc->name,
10554 (certain ? "violates" : "may violate"),
10555 dv_mode[dep->mode], dep->name,
10556 dv_sem[dep->semantics],
10557 pathmsg, indexmsg);
10558
10559 if (md.explicit_mode)
10560 {
10561 as_warn ("%s", msg);
10562 if (path < md.path)
10563 as_warn (_("Only the first path encountering the conflict "
10564 "is reported"));
10565 as_warn_where (rs->file, rs->line,
10566 _("This is the location of the "
10567 "conflicting usage"));
10568 /* Don't bother checking other paths, to avoid duplicating
10569 the same warning */
10570 break;
10571 }
10572 else
10573 {
10574 if (md.debug_dv)
10575 fprintf (stderr, "%s @ %s:%d\n", msg, rs->file, rs->line);
10576
10577 remove_marked_resource (rs);
10578
10579 /* since the set of dependencies has changed, start over */
10580 /* FIXME -- since we're removing dvs as we go, we
10581 probably don't really need to start over... */
10582 start_over = 1;
10583 break;
10584 }
10585 }
10586 }
10587 if (start_over)
10588 i = 0;
10589 else
10590 ++i;
10591 }
10592 }
10593
10594 /* Register new dependencies based on the given opcode. */
10595
10596 static void
mark_resources(idesc)10597 mark_resources (idesc)
10598 struct ia64_opcode *idesc;
10599 {
10600 int i;
10601 const struct ia64_opcode_dependency *opdeps = idesc->dependencies;
10602 int add_only_qp_reads = 0;
10603
10604 /* A conditional branch only uses its resources if it is taken; if it is
10605 taken, we stop following that path. The other branch types effectively
10606 *always* write their resources. If it's not taken, register only QP
10607 reads. */
10608 if (is_conditional_branch (idesc) || is_interruption_or_rfi (idesc))
10609 {
10610 add_only_qp_reads = 1;
10611 }
10612
10613 if (md.debug_dv)
10614 fprintf (stderr, "Registering '%s' resource usage\n", idesc->name);
10615
10616 for (i = 0; i < opdeps->nregs; i++)
10617 {
10618 const struct ia64_dependency *dep;
10619 struct rsrc specs[MAX_SPECS];
10620 int note;
10621 int path;
10622 int count;
10623
10624 dep = ia64_find_dependency (opdeps->regs[i]);
10625 note = NOTE (opdeps->regs[i]);
10626
10627 if (add_only_qp_reads
10628 && !(dep->mode == IA64_DV_WAR
10629 && (dep->specifier == IA64_RS_PR
10630 || dep->specifier == IA64_RS_PRr
10631 || dep->specifier == IA64_RS_PR63)))
10632 continue;
10633
10634 count = specify_resource (dep, idesc, DV_REG, specs, note, md.path);
10635
10636 while (count-- > 0)
10637 {
10638 mark_resource (idesc, dep, &specs[count],
10639 DEP (opdeps->regs[i]), md.path);
10640 }
10641
10642 /* The execution path may affect register values, which may in turn
10643 affect which indirect-access resources are accessed. */
10644 switch (dep->specifier)
10645 {
10646 default:
10647 break;
10648 case IA64_RS_CPUID:
10649 case IA64_RS_DBR:
10650 case IA64_RS_IBR:
10651 case IA64_RS_MSR:
10652 case IA64_RS_PKR:
10653 case IA64_RS_PMC:
10654 case IA64_RS_PMD:
10655 case IA64_RS_RR:
10656 for (path = 0; path < md.path; path++)
10657 {
10658 count = specify_resource (dep, idesc, DV_REG, specs, note, path);
10659 while (count-- > 0)
10660 mark_resource (idesc, dep, &specs[count],
10661 DEP (opdeps->regs[i]), path);
10662 }
10663 break;
10664 }
10665 }
10666 }
10667
10668 /* Remove dependencies when they no longer apply. */
10669
10670 static void
update_dependencies(idesc)10671 update_dependencies (idesc)
10672 struct ia64_opcode *idesc;
10673 {
10674 int i;
10675
10676 if (strcmp (idesc->name, "srlz.i") == 0)
10677 {
10678 instruction_serialization ();
10679 }
10680 else if (strcmp (idesc->name, "srlz.d") == 0)
10681 {
10682 data_serialization ();
10683 }
10684 else if (is_interruption_or_rfi (idesc)
10685 || is_taken_branch (idesc))
10686 {
10687 /* Although technically the taken branch doesn't clear dependencies
10688 which require a srlz.[id], we don't follow the branch; the next
10689 instruction is assumed to start with a clean slate. */
10690 regdepslen = 0;
10691 md.path = 0;
10692 }
10693 else if (is_conditional_branch (idesc)
10694 && CURR_SLOT.qp_regno != 0)
10695 {
10696 int is_call = strstr (idesc->name, ".call") != NULL;
10697
10698 for (i = 0; i < qp_implieslen; i++)
10699 {
10700 /* If the conditional branch's predicate is implied by the predicate
10701 in an existing dependency, remove that dependency. */
10702 if (qp_implies[i].p2 == CURR_SLOT.qp_regno)
10703 {
10704 int depind = 0;
10705 /* Note that this implied predicate takes a branch so that if
10706 a later insn generates a DV but its predicate implies this
10707 one, we can avoid the false DV warning. */
10708 qp_implies[i].p2_branched = 1;
10709 while (depind < regdepslen)
10710 {
10711 if (regdeps[depind].qp_regno == qp_implies[i].p1)
10712 {
10713 print_dependency ("Removing", depind);
10714 regdeps[depind] = regdeps[--regdepslen];
10715 }
10716 else
10717 ++depind;
10718 }
10719 }
10720 }
10721 /* Any marked resources which have this same predicate should be
10722 cleared, provided that the QP hasn't been modified between the
10723 marking instruction and the branch. */
10724 if (is_call)
10725 {
10726 insn_group_break (0, CURR_SLOT.qp_regno, 1);
10727 }
10728 else
10729 {
10730 i = 0;
10731 while (i < regdepslen)
10732 {
10733 if (regdeps[i].qp_regno == CURR_SLOT.qp_regno
10734 && regdeps[i].link_to_qp_branch
10735 && (regdeps[i].file != CURR_SLOT.src_file
10736 || regdeps[i].line != CURR_SLOT.src_line))
10737 {
10738 /* Treat like a taken branch */
10739 print_dependency ("Removing", i);
10740 regdeps[i] = regdeps[--regdepslen];
10741 }
10742 else
10743 ++i;
10744 }
10745 }
10746 }
10747 }
10748
10749 /* Examine the current instruction for dependency violations. */
10750
10751 static int
check_dv(idesc)10752 check_dv (idesc)
10753 struct ia64_opcode *idesc;
10754 {
10755 if (md.debug_dv)
10756 {
10757 fprintf (stderr, "Checking %s for violations (line %d, %d/%d)\n",
10758 idesc->name, CURR_SLOT.src_line,
10759 idesc->dependencies->nchks,
10760 idesc->dependencies->nregs);
10761 }
10762
10763 /* Look through the list of currently marked resources; if the current
10764 instruction has the dependency in its chks list which uses that resource,
10765 check against the specific resources used. */
10766 check_dependencies (idesc);
10767
10768 /* Look up the instruction's regdeps (RAW writes, WAW writes, and WAR reads),
10769 then add them to the list of marked resources. */
10770 mark_resources (idesc);
10771
10772 /* There are several types of dependency semantics, and each has its own
10773 requirements for being cleared
10774
10775 Instruction serialization (insns separated by interruption, rfi, or
10776 writer + srlz.i + reader, all in separate groups) clears DVS_INSTR.
10777
10778 Data serialization (instruction serialization, or writer + srlz.d +
10779 reader, where writer and srlz.d are in separate groups) clears
10780 DVS_DATA. (This also clears DVS_OTHER, but that is not guaranteed to
10781 always be the case).
10782
10783 Instruction group break (groups separated by stop, taken branch,
10784 interruption or rfi) clears DVS_IMPLIED and DVS_IMPLIEDF.
10785 */
10786 update_dependencies (idesc);
10787
10788 /* Sometimes, knowing a register value allows us to avoid giving a false DV
10789 warning. Keep track of as many as possible that are useful. */
10790 note_register_values (idesc);
10791
10792 /* We don't need or want this anymore. */
10793 md.mem_offset.hint = 0;
10794
10795 return 0;
10796 }
10797
10798 /* Translate one line of assembly. Pseudo ops and labels do not show
10799 here. */
10800 void
md_assemble(str)10801 md_assemble (str)
10802 char *str;
10803 {
10804 char *saved_input_line_pointer, *mnemonic;
10805 const struct pseudo_opcode *pdesc;
10806 struct ia64_opcode *idesc;
10807 unsigned char qp_regno;
10808 unsigned int flags;
10809 int ch;
10810
10811 saved_input_line_pointer = input_line_pointer;
10812 input_line_pointer = str;
10813
10814 /* extract the opcode (mnemonic): */
10815
10816 mnemonic = input_line_pointer;
10817 ch = get_symbol_end ();
10818 pdesc = (struct pseudo_opcode *) hash_find (md.pseudo_hash, mnemonic);
10819 if (pdesc)
10820 {
10821 *input_line_pointer = ch;
10822 (*pdesc->handler) (pdesc->arg);
10823 goto done;
10824 }
10825
10826 /* Find the instruction descriptor matching the arguments. */
10827
10828 idesc = ia64_find_opcode (mnemonic);
10829 *input_line_pointer = ch;
10830 if (!idesc)
10831 {
10832 as_bad ("Unknown opcode `%s'", mnemonic);
10833 goto done;
10834 }
10835
10836 idesc = parse_operands (idesc);
10837 if (!idesc)
10838 goto done;
10839
10840 /* Handle the dynamic ops we can handle now: */
10841 if (idesc->type == IA64_TYPE_DYN)
10842 {
10843 if (strcmp (idesc->name, "add") == 0)
10844 {
10845 if (CURR_SLOT.opnd[2].X_op == O_register
10846 && CURR_SLOT.opnd[2].X_add_number < 4)
10847 mnemonic = "addl";
10848 else
10849 mnemonic = "adds";
10850 ia64_free_opcode (idesc);
10851 idesc = ia64_find_opcode (mnemonic);
10852 }
10853 else if (strcmp (idesc->name, "mov") == 0)
10854 {
10855 enum ia64_opnd opnd1, opnd2;
10856 int rop;
10857
10858 opnd1 = idesc->operands[0];
10859 opnd2 = idesc->operands[1];
10860 if (opnd1 == IA64_OPND_AR3)
10861 rop = 0;
10862 else if (opnd2 == IA64_OPND_AR3)
10863 rop = 1;
10864 else
10865 abort ();
10866 if (CURR_SLOT.opnd[rop].X_op == O_register)
10867 {
10868 if (ar_is_only_in_integer_unit (CURR_SLOT.opnd[rop].X_add_number))
10869 mnemonic = "mov.i";
10870 else if (ar_is_only_in_memory_unit (CURR_SLOT.opnd[rop].X_add_number))
10871 mnemonic = "mov.m";
10872 else
10873 rop = -1;
10874 }
10875 else
10876 abort ();
10877 if (rop >= 0)
10878 {
10879 ia64_free_opcode (idesc);
10880 idesc = ia64_find_opcode (mnemonic);
10881 while (idesc != NULL
10882 && (idesc->operands[0] != opnd1
10883 || idesc->operands[1] != opnd2))
10884 idesc = get_next_opcode (idesc);
10885 }
10886 }
10887 }
10888 else if (strcmp (idesc->name, "mov.i") == 0
10889 || strcmp (idesc->name, "mov.m") == 0)
10890 {
10891 enum ia64_opnd opnd1, opnd2;
10892 int rop;
10893
10894 opnd1 = idesc->operands[0];
10895 opnd2 = idesc->operands[1];
10896 if (opnd1 == IA64_OPND_AR3)
10897 rop = 0;
10898 else if (opnd2 == IA64_OPND_AR3)
10899 rop = 1;
10900 else
10901 abort ();
10902 if (CURR_SLOT.opnd[rop].X_op == O_register)
10903 {
10904 char unit = 'a';
10905 if (ar_is_only_in_integer_unit (CURR_SLOT.opnd[rop].X_add_number))
10906 unit = 'i';
10907 else if (ar_is_only_in_memory_unit (CURR_SLOT.opnd[rop].X_add_number))
10908 unit = 'm';
10909 if (unit != 'a' && unit != idesc->name [4])
10910 as_bad ("AR %d can only be accessed by %c-unit",
10911 (int) (CURR_SLOT.opnd[rop].X_add_number - REG_AR),
10912 TOUPPER (unit));
10913 }
10914 }
10915 else if (strcmp (idesc->name, "hint.b") == 0)
10916 {
10917 switch (md.hint_b)
10918 {
10919 case hint_b_ok:
10920 break;
10921 case hint_b_warning:
10922 as_warn ("hint.b may be treated as nop");
10923 break;
10924 case hint_b_error:
10925 as_bad ("hint.b shouldn't be used");
10926 break;
10927 }
10928 }
10929
10930 qp_regno = 0;
10931 if (md.qp.X_op == O_register)
10932 {
10933 qp_regno = md.qp.X_add_number - REG_P;
10934 md.qp.X_op = O_absent;
10935 }
10936
10937 flags = idesc->flags;
10938
10939 if ((flags & IA64_OPCODE_FIRST) != 0)
10940 {
10941 /* The alignment frag has to end with a stop bit only if the
10942 next instruction after the alignment directive has to be
10943 the first instruction in an instruction group. */
10944 if (align_frag)
10945 {
10946 while (align_frag->fr_type != rs_align_code)
10947 {
10948 align_frag = align_frag->fr_next;
10949 if (!align_frag)
10950 break;
10951 }
10952 /* align_frag can be NULL if there are directives in
10953 between. */
10954 if (align_frag && align_frag->fr_next == frag_now)
10955 align_frag->tc_frag_data = 1;
10956 }
10957
10958 insn_group_break (1, 0, 0);
10959 }
10960 align_frag = NULL;
10961
10962 if ((flags & IA64_OPCODE_NO_PRED) != 0 && qp_regno != 0)
10963 {
10964 as_bad ("`%s' cannot be predicated", idesc->name);
10965 goto done;
10966 }
10967
10968 /* Build the instruction. */
10969 CURR_SLOT.qp_regno = qp_regno;
10970 CURR_SLOT.idesc = idesc;
10971 as_where (&CURR_SLOT.src_file, &CURR_SLOT.src_line);
10972 dwarf2_where (&CURR_SLOT.debug_line);
10973
10974 /* Add unwind entries, if there are any. */
10975 if (unwind.current_entry)
10976 {
10977 CURR_SLOT.unwind_record = unwind.current_entry;
10978 unwind.current_entry = NULL;
10979 }
10980 if (unwind.pending_saves)
10981 {
10982 if (unwind.pending_saves->next)
10983 {
10984 /* Attach the next pending save to the next slot so that its
10985 slot number will get set correctly. */
10986 add_unwind_entry (unwind.pending_saves->next, NOT_A_CHAR);
10987 unwind.pending_saves = &unwind.pending_saves->next->r.record.p;
10988 }
10989 else
10990 unwind.pending_saves = NULL;
10991 }
10992 if (unwind.proc_pending.sym && S_IS_DEFINED (unwind.proc_pending.sym))
10993 unwind.insn = 1;
10994
10995 /* Check for dependency violations. */
10996 if (md.detect_dv)
10997 check_dv (idesc);
10998
10999 md.curr_slot = (md.curr_slot + 1) % NUM_SLOTS;
11000 if (++md.num_slots_in_use >= NUM_SLOTS)
11001 emit_one_bundle ();
11002
11003 if ((flags & IA64_OPCODE_LAST) != 0)
11004 insn_group_break (1, 0, 0);
11005
11006 md.last_text_seg = now_seg;
11007
11008 done:
11009 input_line_pointer = saved_input_line_pointer;
11010 }
11011
11012 /* Called when symbol NAME cannot be found in the symbol table.
11013 Should be used for dynamic valued symbols only. */
11014
11015 symbolS *
md_undefined_symbol(name)11016 md_undefined_symbol (name)
11017 char *name ATTRIBUTE_UNUSED;
11018 {
11019 return 0;
11020 }
11021
11022 /* Called for any expression that can not be recognized. When the
11023 function is called, `input_line_pointer' will point to the start of
11024 the expression. */
11025
11026 void
md_operand(e)11027 md_operand (e)
11028 expressionS *e;
11029 {
11030 switch (*input_line_pointer)
11031 {
11032 case '[':
11033 ++input_line_pointer;
11034 expression_and_evaluate (e);
11035 if (*input_line_pointer != ']')
11036 {
11037 as_bad ("Closing bracket missing");
11038 goto err;
11039 }
11040 else
11041 {
11042 if (e->X_op != O_register
11043 || e->X_add_number < REG_GR
11044 || e->X_add_number > REG_GR + 127)
11045 {
11046 as_bad ("Index must be a general register");
11047 e->X_add_number = REG_GR;
11048 }
11049
11050 ++input_line_pointer;
11051 e->X_op = O_index;
11052 }
11053 break;
11054
11055 default:
11056 break;
11057 }
11058 return;
11059
11060 err:
11061 ignore_rest_of_line ();
11062 }
11063
11064 /* Return 1 if it's OK to adjust a reloc by replacing the symbol with
11065 a section symbol plus some offset. For relocs involving @fptr(),
11066 directives we don't want such adjustments since we need to have the
11067 original symbol's name in the reloc. */
11068 int
ia64_fix_adjustable(fix)11069 ia64_fix_adjustable (fix)
11070 fixS *fix;
11071 {
11072 /* Prevent all adjustments to global symbols */
11073 if (S_IS_EXTERNAL (fix->fx_addsy) || S_IS_WEAK (fix->fx_addsy))
11074 return 0;
11075
11076 switch (fix->fx_r_type)
11077 {
11078 case BFD_RELOC_IA64_FPTR64I:
11079 case BFD_RELOC_IA64_FPTR32MSB:
11080 case BFD_RELOC_IA64_FPTR32LSB:
11081 case BFD_RELOC_IA64_FPTR64MSB:
11082 case BFD_RELOC_IA64_FPTR64LSB:
11083 case BFD_RELOC_IA64_LTOFF_FPTR22:
11084 case BFD_RELOC_IA64_LTOFF_FPTR64I:
11085 return 0;
11086 default:
11087 break;
11088 }
11089
11090 return 1;
11091 }
11092
11093 int
ia64_force_relocation(fix)11094 ia64_force_relocation (fix)
11095 fixS *fix;
11096 {
11097 switch (fix->fx_r_type)
11098 {
11099 case BFD_RELOC_IA64_FPTR64I:
11100 case BFD_RELOC_IA64_FPTR32MSB:
11101 case BFD_RELOC_IA64_FPTR32LSB:
11102 case BFD_RELOC_IA64_FPTR64MSB:
11103 case BFD_RELOC_IA64_FPTR64LSB:
11104
11105 case BFD_RELOC_IA64_LTOFF22:
11106 case BFD_RELOC_IA64_LTOFF64I:
11107 case BFD_RELOC_IA64_LTOFF_FPTR22:
11108 case BFD_RELOC_IA64_LTOFF_FPTR64I:
11109 case BFD_RELOC_IA64_PLTOFF22:
11110 case BFD_RELOC_IA64_PLTOFF64I:
11111 case BFD_RELOC_IA64_PLTOFF64MSB:
11112 case BFD_RELOC_IA64_PLTOFF64LSB:
11113
11114 case BFD_RELOC_IA64_LTOFF22X:
11115 case BFD_RELOC_IA64_LDXMOV:
11116 return 1;
11117
11118 default:
11119 break;
11120 }
11121
11122 return generic_force_reloc (fix);
11123 }
11124
11125 /* Decide from what point a pc-relative relocation is relative to,
11126 relative to the pc-relative fixup. Er, relatively speaking. */
11127 long
ia64_pcrel_from_section(fix,sec)11128 ia64_pcrel_from_section (fix, sec)
11129 fixS *fix;
11130 segT sec;
11131 {
11132 unsigned long off = fix->fx_frag->fr_address + fix->fx_where;
11133
11134 if (bfd_get_section_flags (stdoutput, sec) & SEC_CODE)
11135 off &= ~0xfUL;
11136
11137 return off;
11138 }
11139
11140
11141 /* Used to emit section-relative relocs for the dwarf2 debug data. */
11142 void
ia64_dwarf2_emit_offset(symbolS * symbol,unsigned int size)11143 ia64_dwarf2_emit_offset (symbolS *symbol, unsigned int size)
11144 {
11145 expressionS expr;
11146
11147 expr.X_op = O_pseudo_fixup;
11148 expr.X_op_symbol = pseudo_func[FUNC_SEC_RELATIVE].u.sym;
11149 expr.X_add_number = 0;
11150 expr.X_add_symbol = symbol;
11151 emit_expr (&expr, size);
11152 }
11153
11154 /* This is called whenever some data item (not an instruction) needs a
11155 fixup. We pick the right reloc code depending on the byteorder
11156 currently in effect. */
11157 void
ia64_cons_fix_new(f,where,nbytes,exp)11158 ia64_cons_fix_new (f, where, nbytes, exp)
11159 fragS *f;
11160 int where;
11161 int nbytes;
11162 expressionS *exp;
11163 {
11164 bfd_reloc_code_real_type code;
11165 fixS *fix;
11166
11167 switch (nbytes)
11168 {
11169 /* There are no reloc for 8 and 16 bit quantities, but we allow
11170 them here since they will work fine as long as the expression
11171 is fully defined at the end of the pass over the source file. */
11172 case 1: code = BFD_RELOC_8; break;
11173 case 2: code = BFD_RELOC_16; break;
11174 case 4:
11175 if (target_big_endian)
11176 code = BFD_RELOC_IA64_DIR32MSB;
11177 else
11178 code = BFD_RELOC_IA64_DIR32LSB;
11179 break;
11180
11181 case 8:
11182 /* In 32-bit mode, data8 could mean function descriptors too. */
11183 if (exp->X_op == O_pseudo_fixup
11184 && exp->X_op_symbol
11185 && S_GET_VALUE (exp->X_op_symbol) == FUNC_IPLT_RELOC
11186 && !(md.flags & EF_IA_64_ABI64))
11187 {
11188 if (target_big_endian)
11189 code = BFD_RELOC_IA64_IPLTMSB;
11190 else
11191 code = BFD_RELOC_IA64_IPLTLSB;
11192 exp->X_op = O_symbol;
11193 break;
11194 }
11195 else
11196 {
11197 if (target_big_endian)
11198 code = BFD_RELOC_IA64_DIR64MSB;
11199 else
11200 code = BFD_RELOC_IA64_DIR64LSB;
11201 break;
11202 }
11203
11204 case 16:
11205 if (exp->X_op == O_pseudo_fixup
11206 && exp->X_op_symbol
11207 && S_GET_VALUE (exp->X_op_symbol) == FUNC_IPLT_RELOC)
11208 {
11209 if (target_big_endian)
11210 code = BFD_RELOC_IA64_IPLTMSB;
11211 else
11212 code = BFD_RELOC_IA64_IPLTLSB;
11213 exp->X_op = O_symbol;
11214 break;
11215 }
11216 /* FALLTHRU */
11217
11218 default:
11219 as_bad ("Unsupported fixup size %d", nbytes);
11220 ignore_rest_of_line ();
11221 return;
11222 }
11223
11224 if (exp->X_op == O_pseudo_fixup)
11225 {
11226 exp->X_op = O_symbol;
11227 code = ia64_gen_real_reloc_type (exp->X_op_symbol, code);
11228 /* ??? If code unchanged, unsupported. */
11229 }
11230
11231 fix = fix_new_exp (f, where, nbytes, exp, 0, code);
11232 /* We need to store the byte order in effect in case we're going
11233 to fix an 8 or 16 bit relocation (for which there no real
11234 relocs available). See md_apply_fix(). */
11235 fix->tc_fix_data.bigendian = target_big_endian;
11236 }
11237
11238 /* Return the actual relocation we wish to associate with the pseudo
11239 reloc described by SYM and R_TYPE. SYM should be one of the
11240 symbols in the pseudo_func array, or NULL. */
11241
11242 static bfd_reloc_code_real_type
ia64_gen_real_reloc_type(sym,r_type)11243 ia64_gen_real_reloc_type (sym, r_type)
11244 struct symbol *sym;
11245 bfd_reloc_code_real_type r_type;
11246 {
11247 bfd_reloc_code_real_type new = 0;
11248 const char *type = NULL, *suffix = "";
11249
11250 if (sym == NULL)
11251 {
11252 return r_type;
11253 }
11254
11255 switch (S_GET_VALUE (sym))
11256 {
11257 case FUNC_FPTR_RELATIVE:
11258 switch (r_type)
11259 {
11260 case BFD_RELOC_IA64_IMM64: new = BFD_RELOC_IA64_FPTR64I; break;
11261 case BFD_RELOC_IA64_DIR32MSB: new = BFD_RELOC_IA64_FPTR32MSB; break;
11262 case BFD_RELOC_IA64_DIR32LSB: new = BFD_RELOC_IA64_FPTR32LSB; break;
11263 case BFD_RELOC_IA64_DIR64MSB: new = BFD_RELOC_IA64_FPTR64MSB; break;
11264 case BFD_RELOC_IA64_DIR64LSB: new = BFD_RELOC_IA64_FPTR64LSB; break;
11265 default: type = "FPTR"; break;
11266 }
11267 break;
11268
11269 case FUNC_GP_RELATIVE:
11270 switch (r_type)
11271 {
11272 case BFD_RELOC_IA64_IMM22: new = BFD_RELOC_IA64_GPREL22; break;
11273 case BFD_RELOC_IA64_IMM64: new = BFD_RELOC_IA64_GPREL64I; break;
11274 case BFD_RELOC_IA64_DIR32MSB: new = BFD_RELOC_IA64_GPREL32MSB; break;
11275 case BFD_RELOC_IA64_DIR32LSB: new = BFD_RELOC_IA64_GPREL32LSB; break;
11276 case BFD_RELOC_IA64_DIR64MSB: new = BFD_RELOC_IA64_GPREL64MSB; break;
11277 case BFD_RELOC_IA64_DIR64LSB: new = BFD_RELOC_IA64_GPREL64LSB; break;
11278 default: type = "GPREL"; break;
11279 }
11280 break;
11281
11282 case FUNC_LT_RELATIVE:
11283 switch (r_type)
11284 {
11285 case BFD_RELOC_IA64_IMM22: new = BFD_RELOC_IA64_LTOFF22; break;
11286 case BFD_RELOC_IA64_IMM64: new = BFD_RELOC_IA64_LTOFF64I; break;
11287 default: type = "LTOFF"; break;
11288 }
11289 break;
11290
11291 case FUNC_LT_RELATIVE_X:
11292 switch (r_type)
11293 {
11294 case BFD_RELOC_IA64_IMM22: new = BFD_RELOC_IA64_LTOFF22X; break;
11295 default: type = "LTOFF"; suffix = "X"; break;
11296 }
11297 break;
11298
11299 case FUNC_PC_RELATIVE:
11300 switch (r_type)
11301 {
11302 case BFD_RELOC_IA64_IMM22: new = BFD_RELOC_IA64_PCREL22; break;
11303 case BFD_RELOC_IA64_IMM64: new = BFD_RELOC_IA64_PCREL64I; break;
11304 case BFD_RELOC_IA64_DIR32MSB: new = BFD_RELOC_IA64_PCREL32MSB; break;
11305 case BFD_RELOC_IA64_DIR32LSB: new = BFD_RELOC_IA64_PCREL32LSB; break;
11306 case BFD_RELOC_IA64_DIR64MSB: new = BFD_RELOC_IA64_PCREL64MSB; break;
11307 case BFD_RELOC_IA64_DIR64LSB: new = BFD_RELOC_IA64_PCREL64LSB; break;
11308 default: type = "PCREL"; break;
11309 }
11310 break;
11311
11312 case FUNC_PLT_RELATIVE:
11313 switch (r_type)
11314 {
11315 case BFD_RELOC_IA64_IMM22: new = BFD_RELOC_IA64_PLTOFF22; break;
11316 case BFD_RELOC_IA64_IMM64: new = BFD_RELOC_IA64_PLTOFF64I; break;
11317 case BFD_RELOC_IA64_DIR64MSB: new = BFD_RELOC_IA64_PLTOFF64MSB;break;
11318 case BFD_RELOC_IA64_DIR64LSB: new = BFD_RELOC_IA64_PLTOFF64LSB;break;
11319 default: type = "PLTOFF"; break;
11320 }
11321 break;
11322
11323 case FUNC_SEC_RELATIVE:
11324 switch (r_type)
11325 {
11326 case BFD_RELOC_IA64_DIR32MSB: new = BFD_RELOC_IA64_SECREL32MSB;break;
11327 case BFD_RELOC_IA64_DIR32LSB: new = BFD_RELOC_IA64_SECREL32LSB;break;
11328 case BFD_RELOC_IA64_DIR64MSB: new = BFD_RELOC_IA64_SECREL64MSB;break;
11329 case BFD_RELOC_IA64_DIR64LSB: new = BFD_RELOC_IA64_SECREL64LSB;break;
11330 default: type = "SECREL"; break;
11331 }
11332 break;
11333
11334 case FUNC_SEG_RELATIVE:
11335 switch (r_type)
11336 {
11337 case BFD_RELOC_IA64_DIR32MSB: new = BFD_RELOC_IA64_SEGREL32MSB;break;
11338 case BFD_RELOC_IA64_DIR32LSB: new = BFD_RELOC_IA64_SEGREL32LSB;break;
11339 case BFD_RELOC_IA64_DIR64MSB: new = BFD_RELOC_IA64_SEGREL64MSB;break;
11340 case BFD_RELOC_IA64_DIR64LSB: new = BFD_RELOC_IA64_SEGREL64LSB;break;
11341 default: type = "SEGREL"; break;
11342 }
11343 break;
11344
11345 case FUNC_LTV_RELATIVE:
11346 switch (r_type)
11347 {
11348 case BFD_RELOC_IA64_DIR32MSB: new = BFD_RELOC_IA64_LTV32MSB; break;
11349 case BFD_RELOC_IA64_DIR32LSB: new = BFD_RELOC_IA64_LTV32LSB; break;
11350 case BFD_RELOC_IA64_DIR64MSB: new = BFD_RELOC_IA64_LTV64MSB; break;
11351 case BFD_RELOC_IA64_DIR64LSB: new = BFD_RELOC_IA64_LTV64LSB; break;
11352 default: type = "LTV"; break;
11353 }
11354 break;
11355
11356 case FUNC_LT_FPTR_RELATIVE:
11357 switch (r_type)
11358 {
11359 case BFD_RELOC_IA64_IMM22:
11360 new = BFD_RELOC_IA64_LTOFF_FPTR22; break;
11361 case BFD_RELOC_IA64_IMM64:
11362 new = BFD_RELOC_IA64_LTOFF_FPTR64I; break;
11363 case BFD_RELOC_IA64_DIR32MSB:
11364 new = BFD_RELOC_IA64_LTOFF_FPTR32MSB; break;
11365 case BFD_RELOC_IA64_DIR32LSB:
11366 new = BFD_RELOC_IA64_LTOFF_FPTR32LSB; break;
11367 case BFD_RELOC_IA64_DIR64MSB:
11368 new = BFD_RELOC_IA64_LTOFF_FPTR64MSB; break;
11369 case BFD_RELOC_IA64_DIR64LSB:
11370 new = BFD_RELOC_IA64_LTOFF_FPTR64LSB; break;
11371 default:
11372 type = "LTOFF_FPTR"; break;
11373 }
11374 break;
11375
11376 case FUNC_TP_RELATIVE:
11377 switch (r_type)
11378 {
11379 case BFD_RELOC_IA64_IMM14: new = BFD_RELOC_IA64_TPREL14; break;
11380 case BFD_RELOC_IA64_IMM22: new = BFD_RELOC_IA64_TPREL22; break;
11381 case BFD_RELOC_IA64_IMM64: new = BFD_RELOC_IA64_TPREL64I; break;
11382 case BFD_RELOC_IA64_DIR64MSB: new = BFD_RELOC_IA64_TPREL64MSB; break;
11383 case BFD_RELOC_IA64_DIR64LSB: new = BFD_RELOC_IA64_TPREL64LSB; break;
11384 default: type = "TPREL"; break;
11385 }
11386 break;
11387
11388 case FUNC_LT_TP_RELATIVE:
11389 switch (r_type)
11390 {
11391 case BFD_RELOC_IA64_IMM22:
11392 new = BFD_RELOC_IA64_LTOFF_TPREL22; break;
11393 default:
11394 type = "LTOFF_TPREL"; break;
11395 }
11396 break;
11397
11398 case FUNC_DTP_MODULE:
11399 switch (r_type)
11400 {
11401 case BFD_RELOC_IA64_DIR64MSB:
11402 new = BFD_RELOC_IA64_DTPMOD64MSB; break;
11403 case BFD_RELOC_IA64_DIR64LSB:
11404 new = BFD_RELOC_IA64_DTPMOD64LSB; break;
11405 default:
11406 type = "DTPMOD"; break;
11407 }
11408 break;
11409
11410 case FUNC_LT_DTP_MODULE:
11411 switch (r_type)
11412 {
11413 case BFD_RELOC_IA64_IMM22:
11414 new = BFD_RELOC_IA64_LTOFF_DTPMOD22; break;
11415 default:
11416 type = "LTOFF_DTPMOD"; break;
11417 }
11418 break;
11419
11420 case FUNC_DTP_RELATIVE:
11421 switch (r_type)
11422 {
11423 case BFD_RELOC_IA64_DIR32MSB:
11424 new = BFD_RELOC_IA64_DTPREL32MSB; break;
11425 case BFD_RELOC_IA64_DIR32LSB:
11426 new = BFD_RELOC_IA64_DTPREL32LSB; break;
11427 case BFD_RELOC_IA64_DIR64MSB:
11428 new = BFD_RELOC_IA64_DTPREL64MSB; break;
11429 case BFD_RELOC_IA64_DIR64LSB:
11430 new = BFD_RELOC_IA64_DTPREL64LSB; break;
11431 case BFD_RELOC_IA64_IMM14:
11432 new = BFD_RELOC_IA64_DTPREL14; break;
11433 case BFD_RELOC_IA64_IMM22:
11434 new = BFD_RELOC_IA64_DTPREL22; break;
11435 case BFD_RELOC_IA64_IMM64:
11436 new = BFD_RELOC_IA64_DTPREL64I; break;
11437 default:
11438 type = "DTPREL"; break;
11439 }
11440 break;
11441
11442 case FUNC_LT_DTP_RELATIVE:
11443 switch (r_type)
11444 {
11445 case BFD_RELOC_IA64_IMM22:
11446 new = BFD_RELOC_IA64_LTOFF_DTPREL22; break;
11447 default:
11448 type = "LTOFF_DTPREL"; break;
11449 }
11450 break;
11451
11452 case FUNC_IPLT_RELOC:
11453 switch (r_type)
11454 {
11455 case BFD_RELOC_IA64_IPLTMSB: return r_type;
11456 case BFD_RELOC_IA64_IPLTLSB: return r_type;
11457 default: type = "IPLT"; break;
11458 }
11459 break;
11460
11461 default:
11462 abort ();
11463 }
11464
11465 if (new)
11466 return new;
11467 else
11468 {
11469 int width;
11470
11471 if (!type)
11472 abort ();
11473 switch (r_type)
11474 {
11475 case BFD_RELOC_IA64_DIR32MSB: width = 32; suffix = "MSB"; break;
11476 case BFD_RELOC_IA64_DIR32LSB: width = 32; suffix = "LSB"; break;
11477 case BFD_RELOC_IA64_DIR64MSB: width = 64; suffix = "MSB"; break;
11478 case BFD_RELOC_IA64_DIR64LSB: width = 64; suffix = "LSB"; break;
11479 case BFD_RELOC_UNUSED: width = 13; break;
11480 case BFD_RELOC_IA64_IMM14: width = 14; break;
11481 case BFD_RELOC_IA64_IMM22: width = 22; break;
11482 case BFD_RELOC_IA64_IMM64: width = 64; suffix = "I"; break;
11483 default: abort ();
11484 }
11485
11486 /* This should be an error, but since previously there wasn't any
11487 diagnostic here, dont't make it fail because of this for now. */
11488 as_warn ("Cannot express %s%d%s relocation", type, width, suffix);
11489 return r_type;
11490 }
11491 }
11492
11493 /* Here is where generate the appropriate reloc for pseudo relocation
11494 functions. */
11495 void
ia64_validate_fix(fix)11496 ia64_validate_fix (fix)
11497 fixS *fix;
11498 {
11499 switch (fix->fx_r_type)
11500 {
11501 case BFD_RELOC_IA64_FPTR64I:
11502 case BFD_RELOC_IA64_FPTR32MSB:
11503 case BFD_RELOC_IA64_FPTR64LSB:
11504 case BFD_RELOC_IA64_LTOFF_FPTR22:
11505 case BFD_RELOC_IA64_LTOFF_FPTR64I:
11506 if (fix->fx_offset != 0)
11507 as_bad_where (fix->fx_file, fix->fx_line,
11508 "No addend allowed in @fptr() relocation");
11509 break;
11510 default:
11511 break;
11512 }
11513 }
11514
11515 static void
fix_insn(fix,odesc,value)11516 fix_insn (fix, odesc, value)
11517 fixS *fix;
11518 const struct ia64_operand *odesc;
11519 valueT value;
11520 {
11521 bfd_vma insn[3], t0, t1, control_bits;
11522 const char *err;
11523 char *fixpos;
11524 long slot;
11525
11526 slot = fix->fx_where & 0x3;
11527 fixpos = fix->fx_frag->fr_literal + (fix->fx_where - slot);
11528
11529 /* Bundles are always in little-endian byte order */
11530 t0 = bfd_getl64 (fixpos);
11531 t1 = bfd_getl64 (fixpos + 8);
11532 control_bits = t0 & 0x1f;
11533 insn[0] = (t0 >> 5) & 0x1ffffffffffLL;
11534 insn[1] = ((t0 >> 46) & 0x3ffff) | ((t1 & 0x7fffff) << 18);
11535 insn[2] = (t1 >> 23) & 0x1ffffffffffLL;
11536
11537 err = NULL;
11538 if (odesc - elf64_ia64_operands == IA64_OPND_IMMU64)
11539 {
11540 insn[1] = (value >> 22) & 0x1ffffffffffLL;
11541 insn[2] |= (((value & 0x7f) << 13)
11542 | (((value >> 7) & 0x1ff) << 27)
11543 | (((value >> 16) & 0x1f) << 22)
11544 | (((value >> 21) & 0x1) << 21)
11545 | (((value >> 63) & 0x1) << 36));
11546 }
11547 else if (odesc - elf64_ia64_operands == IA64_OPND_IMMU62)
11548 {
11549 if (value & ~0x3fffffffffffffffULL)
11550 err = "integer operand out of range";
11551 insn[1] = (value >> 21) & 0x1ffffffffffLL;
11552 insn[2] |= (((value & 0xfffff) << 6) | (((value >> 20) & 0x1) << 36));
11553 }
11554 else if (odesc - elf64_ia64_operands == IA64_OPND_TGT64)
11555 {
11556 value >>= 4;
11557 insn[1] = ((value >> 20) & 0x7fffffffffLL) << 2;
11558 insn[2] |= ((((value >> 59) & 0x1) << 36)
11559 | (((value >> 0) & 0xfffff) << 13));
11560 }
11561 else
11562 err = (*odesc->insert) (odesc, value, insn + slot);
11563
11564 if (err)
11565 as_bad_where (fix->fx_file, fix->fx_line, err);
11566
11567 t0 = control_bits | (insn[0] << 5) | (insn[1] << 46);
11568 t1 = ((insn[1] >> 18) & 0x7fffff) | (insn[2] << 23);
11569 number_to_chars_littleendian (fixpos + 0, t0, 8);
11570 number_to_chars_littleendian (fixpos + 8, t1, 8);
11571 }
11572
11573 /* Attempt to simplify or even eliminate a fixup. The return value is
11574 ignored; perhaps it was once meaningful, but now it is historical.
11575 To indicate that a fixup has been eliminated, set FIXP->FX_DONE.
11576
11577 If fixp->fx_addsy is non-NULL, we'll have to generate a reloc entry
11578 (if possible). */
11579
11580 void
md_apply_fix(fix,valP,seg)11581 md_apply_fix (fix, valP, seg)
11582 fixS *fix;
11583 valueT *valP;
11584 segT seg ATTRIBUTE_UNUSED;
11585 {
11586 char *fixpos;
11587 valueT value = *valP;
11588
11589 fixpos = fix->fx_frag->fr_literal + fix->fx_where;
11590
11591 if (fix->fx_pcrel)
11592 {
11593 switch (fix->fx_r_type)
11594 {
11595 case BFD_RELOC_IA64_PCREL21B: break;
11596 case BFD_RELOC_IA64_PCREL21BI: break;
11597 case BFD_RELOC_IA64_PCREL21F: break;
11598 case BFD_RELOC_IA64_PCREL21M: break;
11599 case BFD_RELOC_IA64_PCREL60B: break;
11600 case BFD_RELOC_IA64_PCREL22: break;
11601 case BFD_RELOC_IA64_PCREL64I: break;
11602 case BFD_RELOC_IA64_PCREL32MSB: break;
11603 case BFD_RELOC_IA64_PCREL32LSB: break;
11604 case BFD_RELOC_IA64_PCREL64MSB: break;
11605 case BFD_RELOC_IA64_PCREL64LSB: break;
11606 default:
11607 fix->fx_r_type = ia64_gen_real_reloc_type (pseudo_func[FUNC_PC_RELATIVE].u.sym,
11608 fix->fx_r_type);
11609 break;
11610 }
11611 }
11612 if (fix->fx_addsy)
11613 {
11614 switch (fix->fx_r_type)
11615 {
11616 case BFD_RELOC_UNUSED:
11617 /* This must be a TAG13 or TAG13b operand. There are no external
11618 relocs defined for them, so we must give an error. */
11619 as_bad_where (fix->fx_file, fix->fx_line,
11620 "%s must have a constant value",
11621 elf64_ia64_operands[fix->tc_fix_data.opnd].desc);
11622 fix->fx_done = 1;
11623 return;
11624
11625 case BFD_RELOC_IA64_TPREL14:
11626 case BFD_RELOC_IA64_TPREL22:
11627 case BFD_RELOC_IA64_TPREL64I:
11628 case BFD_RELOC_IA64_LTOFF_TPREL22:
11629 case BFD_RELOC_IA64_LTOFF_DTPMOD22:
11630 case BFD_RELOC_IA64_DTPREL14:
11631 case BFD_RELOC_IA64_DTPREL22:
11632 case BFD_RELOC_IA64_DTPREL64I:
11633 case BFD_RELOC_IA64_LTOFF_DTPREL22:
11634 S_SET_THREAD_LOCAL (fix->fx_addsy);
11635 break;
11636
11637 default:
11638 break;
11639 }
11640 }
11641 else if (fix->tc_fix_data.opnd == IA64_OPND_NIL)
11642 {
11643 if (fix->tc_fix_data.bigendian)
11644 number_to_chars_bigendian (fixpos, value, fix->fx_size);
11645 else
11646 number_to_chars_littleendian (fixpos, value, fix->fx_size);
11647 fix->fx_done = 1;
11648 }
11649 else
11650 {
11651 fix_insn (fix, elf64_ia64_operands + fix->tc_fix_data.opnd, value);
11652 fix->fx_done = 1;
11653 }
11654 }
11655
11656 /* Generate the BFD reloc to be stuck in the object file from the
11657 fixup used internally in the assembler. */
11658
11659 arelent *
tc_gen_reloc(sec,fixp)11660 tc_gen_reloc (sec, fixp)
11661 asection *sec ATTRIBUTE_UNUSED;
11662 fixS *fixp;
11663 {
11664 arelent *reloc;
11665
11666 reloc = xmalloc (sizeof (*reloc));
11667 reloc->sym_ptr_ptr = (asymbol **) xmalloc (sizeof (asymbol *));
11668 *reloc->sym_ptr_ptr = symbol_get_bfdsym (fixp->fx_addsy);
11669 reloc->address = fixp->fx_frag->fr_address + fixp->fx_where;
11670 reloc->addend = fixp->fx_offset;
11671 reloc->howto = bfd_reloc_type_lookup (stdoutput, fixp->fx_r_type);
11672
11673 if (!reloc->howto)
11674 {
11675 as_bad_where (fixp->fx_file, fixp->fx_line,
11676 "Cannot represent %s relocation in object file",
11677 bfd_get_reloc_code_name (fixp->fx_r_type));
11678 }
11679 return reloc;
11680 }
11681
11682 /* Turn a string in input_line_pointer into a floating point constant
11683 of type TYPE, and store the appropriate bytes in *LIT. The number
11684 of LITTLENUMS emitted is stored in *SIZE. An error message is
11685 returned, or NULL on OK. */
11686
11687 #define MAX_LITTLENUMS 5
11688
11689 char *
md_atof(type,lit,size)11690 md_atof (type, lit, size)
11691 int type;
11692 char *lit;
11693 int *size;
11694 {
11695 LITTLENUM_TYPE words[MAX_LITTLENUMS];
11696 char *t;
11697 int prec;
11698
11699 switch (type)
11700 {
11701 /* IEEE floats */
11702 case 'f':
11703 case 'F':
11704 case 's':
11705 case 'S':
11706 prec = 2;
11707 break;
11708
11709 case 'd':
11710 case 'D':
11711 case 'r':
11712 case 'R':
11713 prec = 4;
11714 break;
11715
11716 case 'x':
11717 case 'X':
11718 case 'p':
11719 case 'P':
11720 prec = 5;
11721 break;
11722
11723 default:
11724 *size = 0;
11725 return "Bad call to MD_ATOF()";
11726 }
11727 t = atof_ieee (input_line_pointer, type, words);
11728 if (t)
11729 input_line_pointer = t;
11730
11731 (*ia64_float_to_chars) (lit, words, prec);
11732
11733 if (type == 'X')
11734 {
11735 /* It is 10 byte floating point with 6 byte padding. */
11736 memset (&lit [10], 0, 6);
11737 *size = 8 * sizeof (LITTLENUM_TYPE);
11738 }
11739 else
11740 *size = prec * sizeof (LITTLENUM_TYPE);
11741
11742 return 0;
11743 }
11744
11745 /* Handle ia64 specific semantics of the align directive. */
11746
11747 void
ia64_md_do_align(n,fill,len,max)11748 ia64_md_do_align (n, fill, len, max)
11749 int n ATTRIBUTE_UNUSED;
11750 const char *fill ATTRIBUTE_UNUSED;
11751 int len ATTRIBUTE_UNUSED;
11752 int max ATTRIBUTE_UNUSED;
11753 {
11754 if (subseg_text_p (now_seg))
11755 ia64_flush_insns ();
11756 }
11757
11758 /* This is called from HANDLE_ALIGN in write.c. Fill in the contents
11759 of an rs_align_code fragment. */
11760
11761 void
ia64_handle_align(fragp)11762 ia64_handle_align (fragp)
11763 fragS *fragp;
11764 {
11765 int bytes;
11766 char *p;
11767 const unsigned char *nop;
11768
11769 if (fragp->fr_type != rs_align_code)
11770 return;
11771
11772 /* Check if this frag has to end with a stop bit. */
11773 nop = fragp->tc_frag_data ? le_nop_stop : le_nop;
11774
11775 bytes = fragp->fr_next->fr_address - fragp->fr_address - fragp->fr_fix;
11776 p = fragp->fr_literal + fragp->fr_fix;
11777
11778 /* If no paddings are needed, we check if we need a stop bit. */
11779 if (!bytes && fragp->tc_frag_data)
11780 {
11781 if (fragp->fr_fix < 16)
11782 #if 1
11783 /* FIXME: It won't work with
11784 .align 16
11785 alloc r32=ar.pfs,1,2,4,0
11786 */
11787 ;
11788 #else
11789 as_bad_where (fragp->fr_file, fragp->fr_line,
11790 _("Can't add stop bit to mark end of instruction group"));
11791 #endif
11792 else
11793 /* Bundles are always in little-endian byte order. Make sure
11794 the previous bundle has the stop bit. */
11795 *(p - 16) |= 1;
11796 }
11797
11798 /* Make sure we are on a 16-byte boundary, in case someone has been
11799 putting data into a text section. */
11800 if (bytes & 15)
11801 {
11802 int fix = bytes & 15;
11803 memset (p, 0, fix);
11804 p += fix;
11805 bytes -= fix;
11806 fragp->fr_fix += fix;
11807 }
11808
11809 /* Instruction bundles are always little-endian. */
11810 memcpy (p, nop, 16);
11811 fragp->fr_var = 16;
11812 }
11813
11814 static void
ia64_float_to_chars_bigendian(char * lit,LITTLENUM_TYPE * words,int prec)11815 ia64_float_to_chars_bigendian (char *lit, LITTLENUM_TYPE *words,
11816 int prec)
11817 {
11818 while (prec--)
11819 {
11820 number_to_chars_bigendian (lit, (long) (*words++),
11821 sizeof (LITTLENUM_TYPE));
11822 lit += sizeof (LITTLENUM_TYPE);
11823 }
11824 }
11825
11826 static void
ia64_float_to_chars_littleendian(char * lit,LITTLENUM_TYPE * words,int prec)11827 ia64_float_to_chars_littleendian (char *lit, LITTLENUM_TYPE *words,
11828 int prec)
11829 {
11830 while (prec--)
11831 {
11832 number_to_chars_littleendian (lit, (long) (words[prec]),
11833 sizeof (LITTLENUM_TYPE));
11834 lit += sizeof (LITTLENUM_TYPE);
11835 }
11836 }
11837
11838 void
ia64_elf_section_change_hook(void)11839 ia64_elf_section_change_hook (void)
11840 {
11841 if (elf_section_type (now_seg) == SHT_IA_64_UNWIND
11842 && elf_linked_to_section (now_seg) == NULL)
11843 elf_linked_to_section (now_seg) = text_section;
11844 dot_byteorder (-1);
11845 }
11846
11847 /* Check if a label should be made global. */
11848 void
ia64_check_label(symbolS * label)11849 ia64_check_label (symbolS *label)
11850 {
11851 if (*input_line_pointer == ':')
11852 {
11853 S_SET_EXTERNAL (label);
11854 input_line_pointer++;
11855 }
11856 }
11857
11858 /* Used to remember where .alias and .secalias directives are seen. We
11859 will rename symbol and section names when we are about to output
11860 the relocatable file. */
11861 struct alias
11862 {
11863 char *file; /* The file where the directive is seen. */
11864 unsigned int line; /* The line number the directive is at. */
11865 const char *name; /* The orignale name of the symbol. */
11866 };
11867
11868 /* Called for .alias and .secalias directives. If SECTION is 1, it is
11869 .secalias. Otherwise, it is .alias. */
11870 static void
dot_alias(int section)11871 dot_alias (int section)
11872 {
11873 char *name, *alias;
11874 char delim;
11875 char *end_name;
11876 int len;
11877 const char *error_string;
11878 struct alias *h;
11879 const char *a;
11880 struct hash_control *ahash, *nhash;
11881 const char *kind;
11882
11883 name = input_line_pointer;
11884 delim = get_symbol_end ();
11885 end_name = input_line_pointer;
11886 *end_name = delim;
11887
11888 if (name == end_name)
11889 {
11890 as_bad (_("expected symbol name"));
11891 ignore_rest_of_line ();
11892 return;
11893 }
11894
11895 SKIP_WHITESPACE ();
11896
11897 if (*input_line_pointer != ',')
11898 {
11899 *end_name = 0;
11900 as_bad (_("expected comma after \"%s\""), name);
11901 *end_name = delim;
11902 ignore_rest_of_line ();
11903 return;
11904 }
11905
11906 input_line_pointer++;
11907 *end_name = 0;
11908 ia64_canonicalize_symbol_name (name);
11909
11910 /* We call demand_copy_C_string to check if alias string is valid.
11911 There should be a closing `"' and no `\0' in the string. */
11912 alias = demand_copy_C_string (&len);
11913 if (alias == NULL)
11914 {
11915 ignore_rest_of_line ();
11916 return;
11917 }
11918
11919 /* Make a copy of name string. */
11920 len = strlen (name) + 1;
11921 obstack_grow (¬es, name, len);
11922 name = obstack_finish (¬es);
11923
11924 if (section)
11925 {
11926 kind = "section";
11927 ahash = secalias_hash;
11928 nhash = secalias_name_hash;
11929 }
11930 else
11931 {
11932 kind = "symbol";
11933 ahash = alias_hash;
11934 nhash = alias_name_hash;
11935 }
11936
11937 /* Check if alias has been used before. */
11938 h = (struct alias *) hash_find (ahash, alias);
11939 if (h)
11940 {
11941 if (strcmp (h->name, name))
11942 as_bad (_("`%s' is already the alias of %s `%s'"),
11943 alias, kind, h->name);
11944 goto out;
11945 }
11946
11947 /* Check if name already has an alias. */
11948 a = (const char *) hash_find (nhash, name);
11949 if (a)
11950 {
11951 if (strcmp (a, alias))
11952 as_bad (_("%s `%s' already has an alias `%s'"), kind, name, a);
11953 goto out;
11954 }
11955
11956 h = (struct alias *) xmalloc (sizeof (struct alias));
11957 as_where (&h->file, &h->line);
11958 h->name = name;
11959
11960 error_string = hash_jam (ahash, alias, (PTR) h);
11961 if (error_string)
11962 {
11963 as_fatal (_("inserting \"%s\" into %s alias hash table failed: %s"),
11964 alias, kind, error_string);
11965 goto out;
11966 }
11967
11968 error_string = hash_jam (nhash, name, (PTR) alias);
11969 if (error_string)
11970 {
11971 as_fatal (_("inserting \"%s\" into %s name hash table failed: %s"),
11972 alias, kind, error_string);
11973 out:
11974 obstack_free (¬es, name);
11975 obstack_free (¬es, alias);
11976 }
11977
11978 demand_empty_rest_of_line ();
11979 }
11980
11981 /* It renames the original symbol name to its alias. */
11982 static void
do_alias(const char * alias,PTR value)11983 do_alias (const char *alias, PTR value)
11984 {
11985 struct alias *h = (struct alias *) value;
11986 symbolS *sym = symbol_find (h->name);
11987
11988 if (sym == NULL)
11989 as_warn_where (h->file, h->line,
11990 _("symbol `%s' aliased to `%s' is not used"),
11991 h->name, alias);
11992 else
11993 S_SET_NAME (sym, (char *) alias);
11994 }
11995
11996 /* Called from write_object_file. */
11997 void
ia64_adjust_symtab(void)11998 ia64_adjust_symtab (void)
11999 {
12000 hash_traverse (alias_hash, do_alias);
12001 }
12002
12003 /* It renames the original section name to its alias. */
12004 static void
do_secalias(const char * alias,PTR value)12005 do_secalias (const char *alias, PTR value)
12006 {
12007 struct alias *h = (struct alias *) value;
12008 segT sec = bfd_get_section_by_name (stdoutput, h->name);
12009
12010 if (sec == NULL)
12011 as_warn_where (h->file, h->line,
12012 _("section `%s' aliased to `%s' is not used"),
12013 h->name, alias);
12014 else
12015 sec->name = alias;
12016 }
12017
12018 /* Called from write_object_file. */
12019 void
ia64_frob_file(void)12020 ia64_frob_file (void)
12021 {
12022 hash_traverse (secalias_hash, do_secalias);
12023 }
12024