[PATCH 22/57][Arm][GAS] Add support for MVE instructions: vmlaldav, vmlalv, vmlsldav...
[binutils-gdb.git] / gas / config / tc-mips.c
blob1c5dc7a8830b8c71eee78a6feb5b8c65058a52a5
1 /* tc-mips.c -- assemble code for a MIPS chip.
2 Copyright (C) 1993-2019 Free Software Foundation, Inc.
3 Contributed by the OSF and Ralph Campbell.
4 Written by Keith Knowles and Ralph Campbell, working independently.
5 Modified for ECOFF and R4000 support by Ian Lance Taylor of Cygnus
6 Support.
8 This file is part of GAS.
10 GAS is free software; you can redistribute it and/or modify
11 it under the terms of the GNU General Public License as published by
12 the Free Software Foundation; either version 3, or (at your option)
13 any later version.
15 GAS is distributed in the hope that it will be useful,
16 but WITHOUT ANY WARRANTY; without even the implied warranty of
17 MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
18 GNU General Public License for more details.
20 You should have received a copy of the GNU General Public License
21 along with GAS; see the file COPYING. If not, write to the Free
22 Software Foundation, 51 Franklin Street - Fifth Floor, Boston, MA
23 02110-1301, USA. */
25 #include "as.h"
26 #include "config.h"
27 #include "subsegs.h"
28 #include "safe-ctype.h"
30 #include "opcode/mips.h"
31 #include "itbl-ops.h"
32 #include "dwarf2dbg.h"
33 #include "dw2gencfi.h"
35 /* Check assumptions made in this file. */
36 typedef char static_assert1[sizeof (offsetT) < 8 ? -1 : 1];
37 typedef char static_assert2[sizeof (valueT) < 8 ? -1 : 1];
39 #ifdef DEBUG
40 #define DBG(x) printf x
41 #else
42 #define DBG(x)
43 #endif
45 #define streq(a, b) (strcmp (a, b) == 0)
47 #define SKIP_SPACE_TABS(S) \
48 do { while (*(S) == ' ' || *(S) == '\t') ++(S); } while (0)
50 /* Clean up namespace so we can include obj-elf.h too. */
51 static int mips_output_flavor (void);
52 static int mips_output_flavor (void) { return OUTPUT_FLAVOR; }
53 #undef OBJ_PROCESS_STAB
54 #undef OUTPUT_FLAVOR
55 #undef S_GET_ALIGN
56 #undef S_GET_SIZE
57 #undef S_SET_ALIGN
58 #undef S_SET_SIZE
59 #undef obj_frob_file
60 #undef obj_frob_file_after_relocs
61 #undef obj_frob_symbol
62 #undef obj_pop_insert
63 #undef obj_sec_sym_ok_for_reloc
64 #undef OBJ_COPY_SYMBOL_ATTRIBUTES
66 #include "obj-elf.h"
67 /* Fix any of them that we actually care about. */
68 #undef OUTPUT_FLAVOR
69 #define OUTPUT_FLAVOR mips_output_flavor()
71 #include "elf/mips.h"
73 #ifndef ECOFF_DEBUGGING
74 #define NO_ECOFF_DEBUGGING
75 #define ECOFF_DEBUGGING 0
76 #endif
78 int mips_flag_mdebug = -1;
80 /* Control generation of .pdr sections. Off by default on IRIX: the native
81 linker doesn't know about and discards them, but relocations against them
82 remain, leading to rld crashes. */
83 #ifdef TE_IRIX
84 int mips_flag_pdr = FALSE;
85 #else
86 int mips_flag_pdr = TRUE;
87 #endif
89 #include "ecoff.h"
91 static char *mips_regmask_frag;
92 static char *mips_flags_frag;
94 #define ZERO 0
95 #define ATREG 1
96 #define S0 16
97 #define S7 23
98 #define TREG 24
99 #define PIC_CALL_REG 25
100 #define KT0 26
101 #define KT1 27
102 #define GP 28
103 #define SP 29
104 #define FP 30
105 #define RA 31
107 #define ILLEGAL_REG (32)
109 #define AT mips_opts.at
111 extern int target_big_endian;
113 /* The name of the readonly data section. */
114 #define RDATA_SECTION_NAME ".rodata"
116 /* Ways in which an instruction can be "appended" to the output. */
117 enum append_method {
118 /* Just add it normally. */
119 APPEND_ADD,
121 /* Add it normally and then add a nop. */
122 APPEND_ADD_WITH_NOP,
124 /* Turn an instruction with a delay slot into a "compact" version. */
125 APPEND_ADD_COMPACT,
127 /* Insert the instruction before the last one. */
128 APPEND_SWAP
131 /* Information about an instruction, including its format, operands
132 and fixups. */
133 struct mips_cl_insn
135 /* The opcode's entry in mips_opcodes or mips16_opcodes. */
136 const struct mips_opcode *insn_mo;
138 /* The 16-bit or 32-bit bitstring of the instruction itself. This is
139 a copy of INSN_MO->match with the operands filled in. If we have
140 decided to use an extended MIPS16 instruction, this includes the
141 extension. */
142 unsigned long insn_opcode;
144 /* The name if this is an label. */
145 char label[16];
147 /* The target label name if this is an branch. */
148 char target[16];
150 /* The frag that contains the instruction. */
151 struct frag *frag;
153 /* The offset into FRAG of the first instruction byte. */
154 long where;
156 /* The relocs associated with the instruction, if any. */
157 fixS *fixp[3];
159 /* True if this entry cannot be moved from its current position. */
160 unsigned int fixed_p : 1;
162 /* True if this instruction occurred in a .set noreorder block. */
163 unsigned int noreorder_p : 1;
165 /* True for mips16 instructions that jump to an absolute address. */
166 unsigned int mips16_absolute_jump_p : 1;
168 /* True if this instruction is complete. */
169 unsigned int complete_p : 1;
171 /* True if this instruction is cleared from history by unconditional
172 branch. */
173 unsigned int cleared_p : 1;
176 /* The ABI to use. */
177 enum mips_abi_level
179 NO_ABI = 0,
180 O32_ABI,
181 O64_ABI,
182 N32_ABI,
183 N64_ABI,
184 EABI_ABI
187 /* MIPS ABI we are using for this output file. */
188 static enum mips_abi_level mips_abi = NO_ABI;
190 /* Whether or not we have code that can call pic code. */
191 int mips_abicalls = FALSE;
193 /* Whether or not we have code which can be put into a shared
194 library. */
195 static bfd_boolean mips_in_shared = TRUE;
197 /* This is the set of options which may be modified by the .set
198 pseudo-op. We use a struct so that .set push and .set pop are more
199 reliable. */
201 struct mips_set_options
203 /* MIPS ISA (Instruction Set Architecture) level. This is set to -1
204 if it has not been initialized. Changed by `.set mipsN', and the
205 -mipsN command line option, and the default CPU. */
206 int isa;
207 /* Enabled Application Specific Extensions (ASEs). Changed by `.set
208 <asename>', by command line options, and based on the default
209 architecture. */
210 int ase;
211 /* Whether we are assembling for the mips16 processor. 0 if we are
212 not, 1 if we are, and -1 if the value has not been initialized.
213 Changed by `.set mips16' and `.set nomips16', and the -mips16 and
214 -nomips16 command line options, and the default CPU. */
215 int mips16;
216 /* Whether we are assembling for the mipsMIPS ASE. 0 if we are not,
217 1 if we are, and -1 if the value has not been initialized. Changed
218 by `.set micromips' and `.set nomicromips', and the -mmicromips
219 and -mno-micromips command line options, and the default CPU. */
220 int micromips;
221 /* Non-zero if we should not reorder instructions. Changed by `.set
222 reorder' and `.set noreorder'. */
223 int noreorder;
224 /* Non-zero if we should not permit the register designated "assembler
225 temporary" to be used in instructions. The value is the register
226 number, normally $at ($1). Changed by `.set at=REG', `.set noat'
227 (same as `.set at=$0') and `.set at' (same as `.set at=$1'). */
228 unsigned int at;
229 /* Non-zero if we should warn when a macro instruction expands into
230 more than one machine instruction. Changed by `.set nomacro' and
231 `.set macro'. */
232 int warn_about_macros;
233 /* Non-zero if we should not move instructions. Changed by `.set
234 move', `.set volatile', `.set nomove', and `.set novolatile'. */
235 int nomove;
236 /* Non-zero if we should not optimize branches by moving the target
237 of the branch into the delay slot. Actually, we don't perform
238 this optimization anyhow. Changed by `.set bopt' and `.set
239 nobopt'. */
240 int nobopt;
241 /* Non-zero if we should not autoextend mips16 instructions.
242 Changed by `.set autoextend' and `.set noautoextend'. */
243 int noautoextend;
244 /* True if we should only emit 32-bit microMIPS instructions.
245 Changed by `.set insn32' and `.set noinsn32', and the -minsn32
246 and -mno-insn32 command line options. */
247 bfd_boolean insn32;
248 /* Restrict general purpose registers and floating point registers
249 to 32 bit. This is initially determined when -mgp32 or -mfp32
250 is passed but can changed if the assembler code uses .set mipsN. */
251 int gp;
252 int fp;
253 /* MIPS architecture (CPU) type. Changed by .set arch=FOO, the -march
254 command line option, and the default CPU. */
255 int arch;
256 /* True if ".set sym32" is in effect. */
257 bfd_boolean sym32;
258 /* True if floating-point operations are not allowed. Changed by .set
259 softfloat or .set hardfloat, by command line options -msoft-float or
260 -mhard-float. The default is false. */
261 bfd_boolean soft_float;
263 /* True if only single-precision floating-point operations are allowed.
264 Changed by .set singlefloat or .set doublefloat, command-line options
265 -msingle-float or -mdouble-float. The default is false. */
266 bfd_boolean single_float;
268 /* 1 if single-precision operations on odd-numbered registers are
269 allowed. */
270 int oddspreg;
272 /* The set of ASEs that should be enabled for the user specified
273 architecture. This cannot be inferred from 'arch' for all cores
274 as processors only have a unique 'arch' if they add architecture
275 specific instructions (UDI). */
276 int init_ase;
279 /* Specifies whether module level options have been checked yet. */
280 static bfd_boolean file_mips_opts_checked = FALSE;
282 /* Do we support nan2008? 0 if we don't, 1 if we do, and -1 if the
283 value has not been initialized. Changed by `.nan legacy' and
284 `.nan 2008', and the -mnan=legacy and -mnan=2008 command line
285 options, and the default CPU. */
286 static int mips_nan2008 = -1;
288 /* This is the struct we use to hold the module level set of options.
289 Note that we must set the isa field to ISA_UNKNOWN and the ASE, gp and
290 fp fields to -1 to indicate that they have not been initialized. */
292 static struct mips_set_options file_mips_opts =
294 /* isa */ ISA_UNKNOWN, /* ase */ 0, /* mips16 */ -1, /* micromips */ -1,
295 /* noreorder */ 0, /* at */ ATREG, /* warn_about_macros */ 0,
296 /* nomove */ 0, /* nobopt */ 0, /* noautoextend */ 0, /* insn32 */ FALSE,
297 /* gp */ -1, /* fp */ -1, /* arch */ CPU_UNKNOWN, /* sym32 */ FALSE,
298 /* soft_float */ FALSE, /* single_float */ FALSE, /* oddspreg */ -1,
299 /* init_ase */ 0
302 /* This is similar to file_mips_opts, but for the current set of options. */
304 static struct mips_set_options mips_opts =
306 /* isa */ ISA_UNKNOWN, /* ase */ 0, /* mips16 */ -1, /* micromips */ -1,
307 /* noreorder */ 0, /* at */ ATREG, /* warn_about_macros */ 0,
308 /* nomove */ 0, /* nobopt */ 0, /* noautoextend */ 0, /* insn32 */ FALSE,
309 /* gp */ -1, /* fp */ -1, /* arch */ CPU_UNKNOWN, /* sym32 */ FALSE,
310 /* soft_float */ FALSE, /* single_float */ FALSE, /* oddspreg */ -1,
311 /* init_ase */ 0
314 /* Which bits of file_ase were explicitly set or cleared by ASE options. */
315 static unsigned int file_ase_explicit;
317 /* These variables are filled in with the masks of registers used.
318 The object format code reads them and puts them in the appropriate
319 place. */
320 unsigned long mips_gprmask;
321 unsigned long mips_cprmask[4];
323 /* True if any MIPS16 code was produced. */
324 static int file_ase_mips16;
326 #define ISA_SUPPORTS_MIPS16E (mips_opts.isa == ISA_MIPS32 \
327 || mips_opts.isa == ISA_MIPS32R2 \
328 || mips_opts.isa == ISA_MIPS32R3 \
329 || mips_opts.isa == ISA_MIPS32R5 \
330 || mips_opts.isa == ISA_MIPS64 \
331 || mips_opts.isa == ISA_MIPS64R2 \
332 || mips_opts.isa == ISA_MIPS64R3 \
333 || mips_opts.isa == ISA_MIPS64R5)
335 /* True if any microMIPS code was produced. */
336 static int file_ase_micromips;
338 /* True if we want to create R_MIPS_JALR for jalr $25. */
339 #ifdef TE_IRIX
340 #define MIPS_JALR_HINT_P(EXPR) HAVE_NEWABI
341 #else
342 /* As a GNU extension, we use R_MIPS_JALR for o32 too. However,
343 because there's no place for any addend, the only acceptable
344 expression is a bare symbol. */
345 #define MIPS_JALR_HINT_P(EXPR) \
346 (!HAVE_IN_PLACE_ADDENDS \
347 || ((EXPR)->X_op == O_symbol && (EXPR)->X_add_number == 0))
348 #endif
350 /* The argument of the -march= flag. The architecture we are assembling. */
351 static const char *mips_arch_string;
353 /* The argument of the -mtune= flag. The architecture for which we
354 are optimizing. */
355 static int mips_tune = CPU_UNKNOWN;
356 static const char *mips_tune_string;
358 /* True when generating 32-bit code for a 64-bit processor. */
359 static int mips_32bitmode = 0;
361 /* True if the given ABI requires 32-bit registers. */
362 #define ABI_NEEDS_32BIT_REGS(ABI) ((ABI) == O32_ABI)
364 /* Likewise 64-bit registers. */
365 #define ABI_NEEDS_64BIT_REGS(ABI) \
366 ((ABI) == N32_ABI \
367 || (ABI) == N64_ABI \
368 || (ABI) == O64_ABI)
370 #define ISA_IS_R6(ISA) \
371 ((ISA) == ISA_MIPS32R6 \
372 || (ISA) == ISA_MIPS64R6)
374 /* Return true if ISA supports 64 bit wide gp registers. */
375 #define ISA_HAS_64BIT_REGS(ISA) \
376 ((ISA) == ISA_MIPS3 \
377 || (ISA) == ISA_MIPS4 \
378 || (ISA) == ISA_MIPS5 \
379 || (ISA) == ISA_MIPS64 \
380 || (ISA) == ISA_MIPS64R2 \
381 || (ISA) == ISA_MIPS64R3 \
382 || (ISA) == ISA_MIPS64R5 \
383 || (ISA) == ISA_MIPS64R6)
385 /* Return true if ISA supports 64 bit wide float registers. */
386 #define ISA_HAS_64BIT_FPRS(ISA) \
387 ((ISA) == ISA_MIPS3 \
388 || (ISA) == ISA_MIPS4 \
389 || (ISA) == ISA_MIPS5 \
390 || (ISA) == ISA_MIPS32R2 \
391 || (ISA) == ISA_MIPS32R3 \
392 || (ISA) == ISA_MIPS32R5 \
393 || (ISA) == ISA_MIPS32R6 \
394 || (ISA) == ISA_MIPS64 \
395 || (ISA) == ISA_MIPS64R2 \
396 || (ISA) == ISA_MIPS64R3 \
397 || (ISA) == ISA_MIPS64R5 \
398 || (ISA) == ISA_MIPS64R6)
400 /* Return true if ISA supports 64-bit right rotate (dror et al.)
401 instructions. */
402 #define ISA_HAS_DROR(ISA) \
403 ((ISA) == ISA_MIPS64R2 \
404 || (ISA) == ISA_MIPS64R3 \
405 || (ISA) == ISA_MIPS64R5 \
406 || (ISA) == ISA_MIPS64R6 \
407 || (mips_opts.micromips \
408 && ISA_HAS_64BIT_REGS (ISA)) \
411 /* Return true if ISA supports 32-bit right rotate (ror et al.)
412 instructions. */
413 #define ISA_HAS_ROR(ISA) \
414 ((ISA) == ISA_MIPS32R2 \
415 || (ISA) == ISA_MIPS32R3 \
416 || (ISA) == ISA_MIPS32R5 \
417 || (ISA) == ISA_MIPS32R6 \
418 || (ISA) == ISA_MIPS64R2 \
419 || (ISA) == ISA_MIPS64R3 \
420 || (ISA) == ISA_MIPS64R5 \
421 || (ISA) == ISA_MIPS64R6 \
422 || (mips_opts.ase & ASE_SMARTMIPS) \
423 || mips_opts.micromips \
426 /* Return true if ISA supports single-precision floats in odd registers. */
427 #define ISA_HAS_ODD_SINGLE_FPR(ISA, CPU)\
428 (((ISA) == ISA_MIPS32 \
429 || (ISA) == ISA_MIPS32R2 \
430 || (ISA) == ISA_MIPS32R3 \
431 || (ISA) == ISA_MIPS32R5 \
432 || (ISA) == ISA_MIPS32R6 \
433 || (ISA) == ISA_MIPS64 \
434 || (ISA) == ISA_MIPS64R2 \
435 || (ISA) == ISA_MIPS64R3 \
436 || (ISA) == ISA_MIPS64R5 \
437 || (ISA) == ISA_MIPS64R6 \
438 || (CPU) == CPU_R5900) \
439 && ((CPU) != CPU_GS464 \
440 || (CPU) != CPU_GS464E \
441 || (CPU) != CPU_GS264E))
443 /* Return true if ISA supports move to/from high part of a 64-bit
444 floating-point register. */
445 #define ISA_HAS_MXHC1(ISA) \
446 ((ISA) == ISA_MIPS32R2 \
447 || (ISA) == ISA_MIPS32R3 \
448 || (ISA) == ISA_MIPS32R5 \
449 || (ISA) == ISA_MIPS32R6 \
450 || (ISA) == ISA_MIPS64R2 \
451 || (ISA) == ISA_MIPS64R3 \
452 || (ISA) == ISA_MIPS64R5 \
453 || (ISA) == ISA_MIPS64R6)
455 /* Return true if ISA supports legacy NAN. */
456 #define ISA_HAS_LEGACY_NAN(ISA) \
457 ((ISA) == ISA_MIPS1 \
458 || (ISA) == ISA_MIPS2 \
459 || (ISA) == ISA_MIPS3 \
460 || (ISA) == ISA_MIPS4 \
461 || (ISA) == ISA_MIPS5 \
462 || (ISA) == ISA_MIPS32 \
463 || (ISA) == ISA_MIPS32R2 \
464 || (ISA) == ISA_MIPS32R3 \
465 || (ISA) == ISA_MIPS32R5 \
466 || (ISA) == ISA_MIPS64 \
467 || (ISA) == ISA_MIPS64R2 \
468 || (ISA) == ISA_MIPS64R3 \
469 || (ISA) == ISA_MIPS64R5)
471 #define GPR_SIZE \
472 (mips_opts.gp == 64 && !ISA_HAS_64BIT_REGS (mips_opts.isa) \
473 ? 32 \
474 : mips_opts.gp)
476 #define FPR_SIZE \
477 (mips_opts.fp == 64 && !ISA_HAS_64BIT_FPRS (mips_opts.isa) \
478 ? 32 \
479 : mips_opts.fp)
481 #define HAVE_NEWABI (mips_abi == N32_ABI || mips_abi == N64_ABI)
483 #define HAVE_64BIT_OBJECTS (mips_abi == N64_ABI)
485 /* True if relocations are stored in-place. */
486 #define HAVE_IN_PLACE_ADDENDS (!HAVE_NEWABI)
488 /* The ABI-derived address size. */
489 #define HAVE_64BIT_ADDRESSES \
490 (GPR_SIZE == 64 && (mips_abi == EABI_ABI || mips_abi == N64_ABI))
491 #define HAVE_32BIT_ADDRESSES (!HAVE_64BIT_ADDRESSES)
493 /* The size of symbolic constants (i.e., expressions of the form
494 "SYMBOL" or "SYMBOL + OFFSET"). */
495 #define HAVE_32BIT_SYMBOLS \
496 (HAVE_32BIT_ADDRESSES || !HAVE_64BIT_OBJECTS || mips_opts.sym32)
497 #define HAVE_64BIT_SYMBOLS (!HAVE_32BIT_SYMBOLS)
499 /* Addresses are loaded in different ways, depending on the address size
500 in use. The n32 ABI Documentation also mandates the use of additions
501 with overflow checking, but existing implementations don't follow it. */
502 #define ADDRESS_ADD_INSN \
503 (HAVE_32BIT_ADDRESSES ? "addu" : "daddu")
505 #define ADDRESS_ADDI_INSN \
506 (HAVE_32BIT_ADDRESSES ? "addiu" : "daddiu")
508 #define ADDRESS_LOAD_INSN \
509 (HAVE_32BIT_ADDRESSES ? "lw" : "ld")
511 #define ADDRESS_STORE_INSN \
512 (HAVE_32BIT_ADDRESSES ? "sw" : "sd")
514 /* Return true if the given CPU supports the MIPS16 ASE. */
515 #define CPU_HAS_MIPS16(cpu) \
516 (strncmp (TARGET_CPU, "mips16", sizeof ("mips16") - 1) == 0 \
517 || strncmp (TARGET_CANONICAL, "mips-lsi-elf", sizeof ("mips-lsi-elf") - 1) == 0)
519 /* Return true if the given CPU supports the microMIPS ASE. */
520 #define CPU_HAS_MICROMIPS(cpu) 0
522 /* True if CPU has a dror instruction. */
523 #define CPU_HAS_DROR(CPU) ((CPU) == CPU_VR5400 || (CPU) == CPU_VR5500)
525 /* True if CPU has a ror instruction. */
526 #define CPU_HAS_ROR(CPU) CPU_HAS_DROR (CPU)
528 /* True if CPU is in the Octeon family. */
529 #define CPU_IS_OCTEON(CPU) ((CPU) == CPU_OCTEON || (CPU) == CPU_OCTEONP \
530 || (CPU) == CPU_OCTEON2 || (CPU) == CPU_OCTEON3)
532 /* True if CPU has seq/sne and seqi/snei instructions. */
533 #define CPU_HAS_SEQ(CPU) (CPU_IS_OCTEON (CPU))
535 /* True, if CPU has support for ldc1 and sdc1. */
536 #define CPU_HAS_LDC1_SDC1(CPU) \
537 ((mips_opts.isa != ISA_MIPS1) && ((CPU) != CPU_R5900))
539 /* True if mflo and mfhi can be immediately followed by instructions
540 which write to the HI and LO registers.
542 According to MIPS specifications, MIPS ISAs I, II, and III need
543 (at least) two instructions between the reads of HI/LO and
544 instructions which write them, and later ISAs do not. Contradicting
545 the MIPS specifications, some MIPS IV processor user manuals (e.g.
546 the UM for the NEC Vr5000) document needing the instructions between
547 HI/LO reads and writes, as well. Therefore, we declare only MIPS32,
548 MIPS64 and later ISAs to have the interlocks, plus any specific
549 earlier-ISA CPUs for which CPU documentation declares that the
550 instructions are really interlocked. */
551 #define hilo_interlocks \
552 (mips_opts.isa == ISA_MIPS32 \
553 || mips_opts.isa == ISA_MIPS32R2 \
554 || mips_opts.isa == ISA_MIPS32R3 \
555 || mips_opts.isa == ISA_MIPS32R5 \
556 || mips_opts.isa == ISA_MIPS32R6 \
557 || mips_opts.isa == ISA_MIPS64 \
558 || mips_opts.isa == ISA_MIPS64R2 \
559 || mips_opts.isa == ISA_MIPS64R3 \
560 || mips_opts.isa == ISA_MIPS64R5 \
561 || mips_opts.isa == ISA_MIPS64R6 \
562 || mips_opts.arch == CPU_R4010 \
563 || mips_opts.arch == CPU_R5900 \
564 || mips_opts.arch == CPU_R10000 \
565 || mips_opts.arch == CPU_R12000 \
566 || mips_opts.arch == CPU_R14000 \
567 || mips_opts.arch == CPU_R16000 \
568 || mips_opts.arch == CPU_RM7000 \
569 || mips_opts.arch == CPU_VR5500 \
570 || mips_opts.micromips \
573 /* Whether the processor uses hardware interlocks to protect reads
574 from the GPRs after they are loaded from memory, and thus does not
575 require nops to be inserted. This applies to instructions marked
576 INSN_LOAD_MEMORY. These nops are only required at MIPS ISA
577 level I and microMIPS mode instructions are always interlocked. */
578 #define gpr_interlocks \
579 (mips_opts.isa != ISA_MIPS1 \
580 || mips_opts.arch == CPU_R3900 \
581 || mips_opts.arch == CPU_R5900 \
582 || mips_opts.micromips \
585 /* Whether the processor uses hardware interlocks to avoid delays
586 required by coprocessor instructions, and thus does not require
587 nops to be inserted. This applies to instructions marked
588 INSN_LOAD_COPROC, INSN_COPROC_MOVE, and to delays between
589 instructions marked INSN_WRITE_COND_CODE and ones marked
590 INSN_READ_COND_CODE. These nops are only required at MIPS ISA
591 levels I, II, and III and microMIPS mode instructions are always
592 interlocked. */
593 /* Itbl support may require additional care here. */
594 #define cop_interlocks \
595 ((mips_opts.isa != ISA_MIPS1 \
596 && mips_opts.isa != ISA_MIPS2 \
597 && mips_opts.isa != ISA_MIPS3) \
598 || mips_opts.arch == CPU_R4300 \
599 || mips_opts.micromips \
602 /* Whether the processor uses hardware interlocks to protect reads
603 from coprocessor registers after they are loaded from memory, and
604 thus does not require nops to be inserted. This applies to
605 instructions marked INSN_COPROC_MEMORY_DELAY. These nops are only
606 requires at MIPS ISA level I and microMIPS mode instructions are
607 always interlocked. */
608 #define cop_mem_interlocks \
609 (mips_opts.isa != ISA_MIPS1 \
610 || mips_opts.micromips \
613 /* Is this a mfhi or mflo instruction? */
614 #define MF_HILO_INSN(PINFO) \
615 ((PINFO & INSN_READ_HI) || (PINFO & INSN_READ_LO))
617 /* Whether code compression (either of the MIPS16 or the microMIPS ASEs)
618 has been selected. This implies, in particular, that addresses of text
619 labels have their LSB set. */
620 #define HAVE_CODE_COMPRESSION \
621 ((mips_opts.mips16 | mips_opts.micromips) != 0)
623 /* The minimum and maximum signed values that can be stored in a GPR. */
624 #define GPR_SMAX ((offsetT) (((valueT) 1 << (GPR_SIZE - 1)) - 1))
625 #define GPR_SMIN (-GPR_SMAX - 1)
627 /* MIPS PIC level. */
629 enum mips_pic_level mips_pic;
631 /* 1 if we should generate 32 bit offsets from the $gp register in
632 SVR4_PIC mode. Currently has no meaning in other modes. */
633 static int mips_big_got = 0;
635 /* 1 if trap instructions should used for overflow rather than break
636 instructions. */
637 static int mips_trap = 0;
639 /* 1 if double width floating point constants should not be constructed
640 by assembling two single width halves into two single width floating
641 point registers which just happen to alias the double width destination
642 register. On some architectures this aliasing can be disabled by a bit
643 in the status register, and the setting of this bit cannot be determined
644 automatically at assemble time. */
645 static int mips_disable_float_construction;
647 /* Non-zero if any .set noreorder directives were used. */
649 static int mips_any_noreorder;
651 /* Non-zero if nops should be inserted when the register referenced in
652 an mfhi/mflo instruction is read in the next two instructions. */
653 static int mips_7000_hilo_fix;
655 /* The size of objects in the small data section. */
656 static unsigned int g_switch_value = 8;
657 /* Whether the -G option was used. */
658 static int g_switch_seen = 0;
660 #define N_RMASK 0xc4
661 #define N_VFP 0xd4
663 /* If we can determine in advance that GP optimization won't be
664 possible, we can skip the relaxation stuff that tries to produce
665 GP-relative references. This makes delay slot optimization work
666 better.
668 This function can only provide a guess, but it seems to work for
669 gcc output. It needs to guess right for gcc, otherwise gcc
670 will put what it thinks is a GP-relative instruction in a branch
671 delay slot.
673 I don't know if a fix is needed for the SVR4_PIC mode. I've only
674 fixed it for the non-PIC mode. KR 95/04/07 */
675 static int nopic_need_relax (symbolS *, int);
677 /* Handle of the OPCODE hash table. */
678 static struct hash_control *op_hash = NULL;
680 /* The opcode hash table we use for the mips16. */
681 static struct hash_control *mips16_op_hash = NULL;
683 /* The opcode hash table we use for the microMIPS ASE. */
684 static struct hash_control *micromips_op_hash = NULL;
686 /* This array holds the chars that always start a comment. If the
687 pre-processor is disabled, these aren't very useful. */
688 const char comment_chars[] = "#";
690 /* This array holds the chars that only start a comment at the beginning of
691 a line. If the line seems to have the form '# 123 filename'
692 .line and .file directives will appear in the pre-processed output. */
693 /* Note that input_file.c hand checks for '#' at the beginning of the
694 first line of the input file. This is because the compiler outputs
695 #NO_APP at the beginning of its output. */
696 /* Also note that C style comments are always supported. */
697 const char line_comment_chars[] = "#";
699 /* This array holds machine specific line separator characters. */
700 const char line_separator_chars[] = ";";
702 /* Chars that can be used to separate mant from exp in floating point nums. */
703 const char EXP_CHARS[] = "eE";
705 /* Chars that mean this number is a floating point constant.
706 As in 0f12.456
707 or 0d1.2345e12. */
708 const char FLT_CHARS[] = "rRsSfFdDxXpP";
710 /* Also be aware that MAXIMUM_NUMBER_OF_CHARS_FOR_FLOAT may have to be
711 changed in read.c . Ideally it shouldn't have to know about it at all,
712 but nothing is ideal around here. */
714 /* Types of printf format used for instruction-related error messages.
715 "I" means int ("%d") and "S" means string ("%s"). */
716 enum mips_insn_error_format
718 ERR_FMT_PLAIN,
719 ERR_FMT_I,
720 ERR_FMT_SS,
723 /* Information about an error that was found while assembling the current
724 instruction. */
725 struct mips_insn_error
727 /* We sometimes need to match an instruction against more than one
728 opcode table entry. Errors found during this matching are reported
729 against a particular syntactic argument rather than against the
730 instruction as a whole. We grade these messages so that errors
731 against argument N have a greater priority than an error against
732 any argument < N, since the former implies that arguments up to N
733 were acceptable and that the opcode entry was therefore a closer match.
734 If several matches report an error against the same argument,
735 we only use that error if it is the same in all cases.
737 min_argnum is the minimum argument number for which an error message
738 should be accepted. It is 0 if MSG is against the instruction as
739 a whole. */
740 int min_argnum;
742 /* The printf()-style message, including its format and arguments. */
743 enum mips_insn_error_format format;
744 const char *msg;
745 union
747 int i;
748 const char *ss[2];
749 } u;
752 /* The error that should be reported for the current instruction. */
753 static struct mips_insn_error insn_error;
755 static int auto_align = 1;
757 /* When outputting SVR4 PIC code, the assembler needs to know the
758 offset in the stack frame from which to restore the $gp register.
759 This is set by the .cprestore pseudo-op, and saved in this
760 variable. */
761 static offsetT mips_cprestore_offset = -1;
763 /* Similar for NewABI PIC code, where $gp is callee-saved. NewABI has some
764 more optimizations, it can use a register value instead of a memory-saved
765 offset and even an other register than $gp as global pointer. */
766 static offsetT mips_cpreturn_offset = -1;
767 static int mips_cpreturn_register = -1;
768 static int mips_gp_register = GP;
769 static int mips_gprel_offset = 0;
771 /* Whether mips_cprestore_offset has been set in the current function
772 (or whether it has already been warned about, if not). */
773 static int mips_cprestore_valid = 0;
775 /* This is the register which holds the stack frame, as set by the
776 .frame pseudo-op. This is needed to implement .cprestore. */
777 static int mips_frame_reg = SP;
779 /* Whether mips_frame_reg has been set in the current function
780 (or whether it has already been warned about, if not). */
781 static int mips_frame_reg_valid = 0;
783 /* To output NOP instructions correctly, we need to keep information
784 about the previous two instructions. */
786 /* Whether we are optimizing. The default value of 2 means to remove
787 unneeded NOPs and swap branch instructions when possible. A value
788 of 1 means to not swap branches. A value of 0 means to always
789 insert NOPs. */
790 static int mips_optimize = 2;
792 /* Debugging level. -g sets this to 2. -gN sets this to N. -g0 is
793 equivalent to seeing no -g option at all. */
794 static int mips_debug = 0;
796 /* The maximum number of NOPs needed to avoid the VR4130 mflo/mfhi errata. */
797 #define MAX_VR4130_NOPS 4
799 /* The maximum number of NOPs needed to fill delay slots. */
800 #define MAX_DELAY_NOPS 2
802 /* The maximum number of NOPs needed for any purpose. */
803 #define MAX_NOPS 4
805 /* The maximum range of context length of ll/sc. */
806 #define MAX_LLSC_RANGE 20
808 /* A list of previous instructions, with index 0 being the most recent.
809 We need to look back MAX_NOPS instructions when filling delay slots
810 or working around processor errata. We need to look back one
811 instruction further if we're thinking about using history[0] to
812 fill a branch delay slot. */
813 static struct mips_cl_insn history[1 + MAX_NOPS + MAX_LLSC_RANGE];
815 /* Arrays of operands for each instruction. */
816 #define MAX_OPERANDS 6
817 struct mips_operand_array
819 const struct mips_operand *operand[MAX_OPERANDS];
821 static struct mips_operand_array *mips_operands;
822 static struct mips_operand_array *mips16_operands;
823 static struct mips_operand_array *micromips_operands;
825 /* Nop instructions used by emit_nop. */
826 static struct mips_cl_insn nop_insn;
827 static struct mips_cl_insn mips16_nop_insn;
828 static struct mips_cl_insn micromips_nop16_insn;
829 static struct mips_cl_insn micromips_nop32_insn;
831 /* Sync instructions used by insert sync. */
832 static struct mips_cl_insn sync_insn;
834 /* The appropriate nop for the current mode. */
835 #define NOP_INSN (mips_opts.mips16 \
836 ? &mips16_nop_insn \
837 : (mips_opts.micromips \
838 ? (mips_opts.insn32 \
839 ? &micromips_nop32_insn \
840 : &micromips_nop16_insn) \
841 : &nop_insn))
843 /* The size of NOP_INSN in bytes. */
844 #define NOP_INSN_SIZE ((mips_opts.mips16 \
845 || (mips_opts.micromips && !mips_opts.insn32)) \
846 ? 2 : 4)
848 /* If this is set, it points to a frag holding nop instructions which
849 were inserted before the start of a noreorder section. If those
850 nops turn out to be unnecessary, the size of the frag can be
851 decreased. */
852 static fragS *prev_nop_frag;
854 /* The number of nop instructions we created in prev_nop_frag. */
855 static int prev_nop_frag_holds;
857 /* The number of nop instructions that we know we need in
858 prev_nop_frag. */
859 static int prev_nop_frag_required;
861 /* The number of instructions we've seen since prev_nop_frag. */
862 static int prev_nop_frag_since;
864 /* Relocations against symbols are sometimes done in two parts, with a HI
865 relocation and a LO relocation. Each relocation has only 16 bits of
866 space to store an addend. This means that in order for the linker to
867 handle carries correctly, it must be able to locate both the HI and
868 the LO relocation. This means that the relocations must appear in
869 order in the relocation table.
871 In order to implement this, we keep track of each unmatched HI
872 relocation. We then sort them so that they immediately precede the
873 corresponding LO relocation. */
875 struct mips_hi_fixup
877 /* Next HI fixup. */
878 struct mips_hi_fixup *next;
879 /* This fixup. */
880 fixS *fixp;
881 /* The section this fixup is in. */
882 segT seg;
885 /* The list of unmatched HI relocs. */
887 static struct mips_hi_fixup *mips_hi_fixup_list;
889 /* The frag containing the last explicit relocation operator.
890 Null if explicit relocations have not been used. */
892 static fragS *prev_reloc_op_frag;
894 /* Map mips16 register numbers to normal MIPS register numbers. */
896 static const unsigned int mips16_to_32_reg_map[] =
898 16, 17, 2, 3, 4, 5, 6, 7
901 /* Map microMIPS register numbers to normal MIPS register numbers. */
903 #define micromips_to_32_reg_d_map mips16_to_32_reg_map
905 /* The microMIPS registers with type h. */
906 static const unsigned int micromips_to_32_reg_h_map1[] =
908 5, 5, 6, 4, 4, 4, 4, 4
910 static const unsigned int micromips_to_32_reg_h_map2[] =
912 6, 7, 7, 21, 22, 5, 6, 7
915 /* The microMIPS registers with type m. */
916 static const unsigned int micromips_to_32_reg_m_map[] =
918 0, 17, 2, 3, 16, 18, 19, 20
921 #define micromips_to_32_reg_n_map micromips_to_32_reg_m_map
923 /* Classifies the kind of instructions we're interested in when
924 implementing -mfix-vr4120. */
925 enum fix_vr4120_class
927 FIX_VR4120_MACC,
928 FIX_VR4120_DMACC,
929 FIX_VR4120_MULT,
930 FIX_VR4120_DMULT,
931 FIX_VR4120_DIV,
932 FIX_VR4120_MTHILO,
933 NUM_FIX_VR4120_CLASSES
936 /* ...likewise -mfix-loongson2f-jump. */
937 static bfd_boolean mips_fix_loongson2f_jump;
939 /* ...likewise -mfix-loongson2f-nop. */
940 static bfd_boolean mips_fix_loongson2f_nop;
942 /* True if -mfix-loongson2f-nop or -mfix-loongson2f-jump passed. */
943 static bfd_boolean mips_fix_loongson2f;
945 /* Given two FIX_VR4120_* values X and Y, bit Y of element X is set if
946 there must be at least one other instruction between an instruction
947 of type X and an instruction of type Y. */
948 static unsigned int vr4120_conflicts[NUM_FIX_VR4120_CLASSES];
950 /* True if -mfix-vr4120 is in force. */
951 static int mips_fix_vr4120;
953 /* ...likewise -mfix-vr4130. */
954 static int mips_fix_vr4130;
956 /* ...likewise -mfix-24k. */
957 static int mips_fix_24k;
959 /* ...likewise -mfix-rm7000 */
960 static int mips_fix_rm7000;
962 /* ...likewise -mfix-cn63xxp1 */
963 static bfd_boolean mips_fix_cn63xxp1;
965 /* ...likewise -mfix-r5900 */
966 static bfd_boolean mips_fix_r5900;
967 static bfd_boolean mips_fix_r5900_explicit;
969 /* ...likewise -mfix-loongson3-llsc. */
970 static bfd_boolean mips_fix_loongson3_llsc = DEFAULT_MIPS_FIX_LOONGSON3_LLSC;
972 /* We don't relax branches by default, since this causes us to expand
973 `la .l2 - .l1' if there's a branch between .l1 and .l2, because we
974 fail to compute the offset before expanding the macro to the most
975 efficient expansion. */
977 static int mips_relax_branch;
979 /* TRUE if checks are suppressed for invalid branches between ISA modes.
980 Needed for broken assembly produced by some GCC versions and some
981 sloppy code out there, where branches to data labels are present. */
982 static bfd_boolean mips_ignore_branch_isa;
984 /* The expansion of many macros depends on the type of symbol that
985 they refer to. For example, when generating position-dependent code,
986 a macro that refers to a symbol may have two different expansions,
987 one which uses GP-relative addresses and one which uses absolute
988 addresses. When generating SVR4-style PIC, a macro may have
989 different expansions for local and global symbols.
991 We handle these situations by generating both sequences and putting
992 them in variant frags. In position-dependent code, the first sequence
993 will be the GP-relative one and the second sequence will be the
994 absolute one. In SVR4 PIC, the first sequence will be for global
995 symbols and the second will be for local symbols.
997 The frag's "subtype" is RELAX_ENCODE (FIRST, SECOND), where FIRST and
998 SECOND are the lengths of the two sequences in bytes. These fields
999 can be extracted using RELAX_FIRST() and RELAX_SECOND(). In addition,
1000 the subtype has the following flags:
1002 RELAX_PIC
1003 Set if generating PIC code.
1005 RELAX_USE_SECOND
1006 Set if it has been decided that we should use the second
1007 sequence instead of the first.
1009 RELAX_SECOND_LONGER
1010 Set in the first variant frag if the macro's second implementation
1011 is longer than its first. This refers to the macro as a whole,
1012 not an individual relaxation.
1014 RELAX_NOMACRO
1015 Set in the first variant frag if the macro appeared in a .set nomacro
1016 block and if one alternative requires a warning but the other does not.
1018 RELAX_DELAY_SLOT
1019 Like RELAX_NOMACRO, but indicates that the macro appears in a branch
1020 delay slot.
1022 RELAX_DELAY_SLOT_16BIT
1023 Like RELAX_DELAY_SLOT, but indicates that the delay slot requires a
1024 16-bit instruction.
1026 RELAX_DELAY_SLOT_SIZE_FIRST
1027 Like RELAX_DELAY_SLOT, but indicates that the first implementation of
1028 the macro is of the wrong size for the branch delay slot.
1030 RELAX_DELAY_SLOT_SIZE_SECOND
1031 Like RELAX_DELAY_SLOT, but indicates that the second implementation of
1032 the macro is of the wrong size for the branch delay slot.
1034 The frag's "opcode" points to the first fixup for relaxable code.
1036 Relaxable macros are generated using a sequence such as:
1038 relax_start (SYMBOL);
1039 ... generate first expansion ...
1040 relax_switch ();
1041 ... generate second expansion ...
1042 relax_end ();
1044 The code and fixups for the unwanted alternative are discarded
1045 by md_convert_frag. */
1046 #define RELAX_ENCODE(FIRST, SECOND, PIC) \
1047 (((FIRST) << 8) | (SECOND) | ((PIC) ? 0x10000 : 0))
1049 #define RELAX_FIRST(X) (((X) >> 8) & 0xff)
1050 #define RELAX_SECOND(X) ((X) & 0xff)
1051 #define RELAX_PIC(X) (((X) & 0x10000) != 0)
1052 #define RELAX_USE_SECOND 0x20000
1053 #define RELAX_SECOND_LONGER 0x40000
1054 #define RELAX_NOMACRO 0x80000
1055 #define RELAX_DELAY_SLOT 0x100000
1056 #define RELAX_DELAY_SLOT_16BIT 0x200000
1057 #define RELAX_DELAY_SLOT_SIZE_FIRST 0x400000
1058 #define RELAX_DELAY_SLOT_SIZE_SECOND 0x800000
1060 /* Branch without likely bit. If label is out of range, we turn:
1062 beq reg1, reg2, label
1063 delay slot
1065 into
1067 bne reg1, reg2, 0f
1069 j label
1070 0: delay slot
1072 with the following opcode replacements:
1074 beq <-> bne
1075 blez <-> bgtz
1076 bltz <-> bgez
1077 bc1f <-> bc1t
1079 bltzal <-> bgezal (with jal label instead of j label)
1081 Even though keeping the delay slot instruction in the delay slot of
1082 the branch would be more efficient, it would be very tricky to do
1083 correctly, because we'd have to introduce a variable frag *after*
1084 the delay slot instruction, and expand that instead. Let's do it
1085 the easy way for now, even if the branch-not-taken case now costs
1086 one additional instruction. Out-of-range branches are not supposed
1087 to be common, anyway.
1089 Branch likely. If label is out of range, we turn:
1091 beql reg1, reg2, label
1092 delay slot (annulled if branch not taken)
1094 into
1096 beql reg1, reg2, 1f
1098 beql $0, $0, 2f
1100 1: j[al] label
1101 delay slot (executed only if branch taken)
1104 It would be possible to generate a shorter sequence by losing the
1105 likely bit, generating something like:
1107 bne reg1, reg2, 0f
1109 j[al] label
1110 delay slot (executed only if branch taken)
1113 beql -> bne
1114 bnel -> beq
1115 blezl -> bgtz
1116 bgtzl -> blez
1117 bltzl -> bgez
1118 bgezl -> bltz
1119 bc1fl -> bc1t
1120 bc1tl -> bc1f
1122 bltzall -> bgezal (with jal label instead of j label)
1123 bgezall -> bltzal (ditto)
1126 but it's not clear that it would actually improve performance. */
1127 #define RELAX_BRANCH_ENCODE(at, pic, \
1128 uncond, likely, link, toofar) \
1129 ((relax_substateT) \
1130 (0xc0000000 \
1131 | ((at) & 0x1f) \
1132 | ((pic) ? 0x20 : 0) \
1133 | ((toofar) ? 0x40 : 0) \
1134 | ((link) ? 0x80 : 0) \
1135 | ((likely) ? 0x100 : 0) \
1136 | ((uncond) ? 0x200 : 0)))
1137 #define RELAX_BRANCH_P(i) (((i) & 0xf0000000) == 0xc0000000)
1138 #define RELAX_BRANCH_UNCOND(i) (((i) & 0x200) != 0)
1139 #define RELAX_BRANCH_LIKELY(i) (((i) & 0x100) != 0)
1140 #define RELAX_BRANCH_LINK(i) (((i) & 0x80) != 0)
1141 #define RELAX_BRANCH_TOOFAR(i) (((i) & 0x40) != 0)
1142 #define RELAX_BRANCH_PIC(i) (((i) & 0x20) != 0)
1143 #define RELAX_BRANCH_AT(i) ((i) & 0x1f)
1145 /* For mips16 code, we use an entirely different form of relaxation.
1146 mips16 supports two versions of most instructions which take
1147 immediate values: a small one which takes some small value, and a
1148 larger one which takes a 16 bit value. Since branches also follow
1149 this pattern, relaxing these values is required.
1151 We can assemble both mips16 and normal MIPS code in a single
1152 object. Therefore, we need to support this type of relaxation at
1153 the same time that we support the relaxation described above. We
1154 use the high bit of the subtype field to distinguish these cases.
1156 The information we store for this type of relaxation is the
1157 argument code found in the opcode file for this relocation, whether
1158 the user explicitly requested a small or extended form, and whether
1159 the relocation is in a jump or jal delay slot. That tells us the
1160 size of the value, and how it should be stored. We also store
1161 whether the fragment is considered to be extended or not. We also
1162 store whether this is known to be a branch to a different section,
1163 whether we have tried to relax this frag yet, and whether we have
1164 ever extended a PC relative fragment because of a shift count. */
1165 #define RELAX_MIPS16_ENCODE(type, e2, pic, sym32, nomacro, \
1166 small, ext, \
1167 dslot, jal_dslot) \
1168 (0x80000000 \
1169 | ((type) & 0xff) \
1170 | ((e2) ? 0x100 : 0) \
1171 | ((pic) ? 0x200 : 0) \
1172 | ((sym32) ? 0x400 : 0) \
1173 | ((nomacro) ? 0x800 : 0) \
1174 | ((small) ? 0x1000 : 0) \
1175 | ((ext) ? 0x2000 : 0) \
1176 | ((dslot) ? 0x4000 : 0) \
1177 | ((jal_dslot) ? 0x8000 : 0))
1179 #define RELAX_MIPS16_P(i) (((i) & 0xc0000000) == 0x80000000)
1180 #define RELAX_MIPS16_TYPE(i) ((i) & 0xff)
1181 #define RELAX_MIPS16_E2(i) (((i) & 0x100) != 0)
1182 #define RELAX_MIPS16_PIC(i) (((i) & 0x200) != 0)
1183 #define RELAX_MIPS16_SYM32(i) (((i) & 0x400) != 0)
1184 #define RELAX_MIPS16_NOMACRO(i) (((i) & 0x800) != 0)
1185 #define RELAX_MIPS16_USER_SMALL(i) (((i) & 0x1000) != 0)
1186 #define RELAX_MIPS16_USER_EXT(i) (((i) & 0x2000) != 0)
1187 #define RELAX_MIPS16_DSLOT(i) (((i) & 0x4000) != 0)
1188 #define RELAX_MIPS16_JAL_DSLOT(i) (((i) & 0x8000) != 0)
1190 #define RELAX_MIPS16_EXTENDED(i) (((i) & 0x10000) != 0)
1191 #define RELAX_MIPS16_MARK_EXTENDED(i) ((i) | 0x10000)
1192 #define RELAX_MIPS16_CLEAR_EXTENDED(i) ((i) & ~0x10000)
1193 #define RELAX_MIPS16_ALWAYS_EXTENDED(i) (((i) & 0x20000) != 0)
1194 #define RELAX_MIPS16_MARK_ALWAYS_EXTENDED(i) ((i) | 0x20000)
1195 #define RELAX_MIPS16_CLEAR_ALWAYS_EXTENDED(i) ((i) & ~0x20000)
1196 #define RELAX_MIPS16_MACRO(i) (((i) & 0x40000) != 0)
1197 #define RELAX_MIPS16_MARK_MACRO(i) ((i) | 0x40000)
1198 #define RELAX_MIPS16_CLEAR_MACRO(i) ((i) & ~0x40000)
1200 /* For microMIPS code, we use relaxation similar to one we use for
1201 MIPS16 code. Some instructions that take immediate values support
1202 two encodings: a small one which takes some small value, and a
1203 larger one which takes a 16 bit value. As some branches also follow
1204 this pattern, relaxing these values is required.
1206 We can assemble both microMIPS and normal MIPS code in a single
1207 object. Therefore, we need to support this type of relaxation at
1208 the same time that we support the relaxation described above. We
1209 use one of the high bits of the subtype field to distinguish these
1210 cases.
1212 The information we store for this type of relaxation is the argument
1213 code found in the opcode file for this relocation, the register
1214 selected as the assembler temporary, whether in the 32-bit
1215 instruction mode, whether the branch is unconditional, whether it is
1216 compact, whether there is no delay-slot instruction available to fill
1217 in, whether it stores the link address implicitly in $ra, whether
1218 relaxation of out-of-range 32-bit branches to a sequence of
1219 instructions is enabled, and whether the displacement of a branch is
1220 too large to fit as an immediate argument of a 16-bit and a 32-bit
1221 branch, respectively. */
1222 #define RELAX_MICROMIPS_ENCODE(type, at, insn32, pic, \
1223 uncond, compact, link, nods, \
1224 relax32, toofar16, toofar32) \
1225 (0x40000000 \
1226 | ((type) & 0xff) \
1227 | (((at) & 0x1f) << 8) \
1228 | ((insn32) ? 0x2000 : 0) \
1229 | ((pic) ? 0x4000 : 0) \
1230 | ((uncond) ? 0x8000 : 0) \
1231 | ((compact) ? 0x10000 : 0) \
1232 | ((link) ? 0x20000 : 0) \
1233 | ((nods) ? 0x40000 : 0) \
1234 | ((relax32) ? 0x80000 : 0) \
1235 | ((toofar16) ? 0x100000 : 0) \
1236 | ((toofar32) ? 0x200000 : 0))
1237 #define RELAX_MICROMIPS_P(i) (((i) & 0xc0000000) == 0x40000000)
1238 #define RELAX_MICROMIPS_TYPE(i) ((i) & 0xff)
1239 #define RELAX_MICROMIPS_AT(i) (((i) >> 8) & 0x1f)
1240 #define RELAX_MICROMIPS_INSN32(i) (((i) & 0x2000) != 0)
1241 #define RELAX_MICROMIPS_PIC(i) (((i) & 0x4000) != 0)
1242 #define RELAX_MICROMIPS_UNCOND(i) (((i) & 0x8000) != 0)
1243 #define RELAX_MICROMIPS_COMPACT(i) (((i) & 0x10000) != 0)
1244 #define RELAX_MICROMIPS_LINK(i) (((i) & 0x20000) != 0)
1245 #define RELAX_MICROMIPS_NODS(i) (((i) & 0x40000) != 0)
1246 #define RELAX_MICROMIPS_RELAX32(i) (((i) & 0x80000) != 0)
1248 #define RELAX_MICROMIPS_TOOFAR16(i) (((i) & 0x100000) != 0)
1249 #define RELAX_MICROMIPS_MARK_TOOFAR16(i) ((i) | 0x100000)
1250 #define RELAX_MICROMIPS_CLEAR_TOOFAR16(i) ((i) & ~0x100000)
1251 #define RELAX_MICROMIPS_TOOFAR32(i) (((i) & 0x200000) != 0)
1252 #define RELAX_MICROMIPS_MARK_TOOFAR32(i) ((i) | 0x200000)
1253 #define RELAX_MICROMIPS_CLEAR_TOOFAR32(i) ((i) & ~0x200000)
1255 /* Sign-extend 16-bit value X. */
1256 #define SEXT_16BIT(X) ((((X) + 0x8000) & 0xffff) - 0x8000)
1258 /* Is the given value a sign-extended 32-bit value? */
1259 #define IS_SEXT_32BIT_NUM(x) \
1260 (((x) &~ (offsetT) 0x7fffffff) == 0 \
1261 || (((x) &~ (offsetT) 0x7fffffff) == ~ (offsetT) 0x7fffffff))
1263 /* Is the given value a sign-extended 16-bit value? */
1264 #define IS_SEXT_16BIT_NUM(x) \
1265 (((x) &~ (offsetT) 0x7fff) == 0 \
1266 || (((x) &~ (offsetT) 0x7fff) == ~ (offsetT) 0x7fff))
1268 /* Is the given value a sign-extended 12-bit value? */
1269 #define IS_SEXT_12BIT_NUM(x) \
1270 (((((x) & 0xfff) ^ 0x800LL) - 0x800LL) == (x))
1272 /* Is the given value a sign-extended 9-bit value? */
1273 #define IS_SEXT_9BIT_NUM(x) \
1274 (((((x) & 0x1ff) ^ 0x100LL) - 0x100LL) == (x))
1276 /* Is the given value a zero-extended 32-bit value? Or a negated one? */
1277 #define IS_ZEXT_32BIT_NUM(x) \
1278 (((x) &~ (offsetT) 0xffffffff) == 0 \
1279 || (((x) &~ (offsetT) 0xffffffff) == ~ (offsetT) 0xffffffff))
1281 /* Extract bits MASK << SHIFT from STRUCT and shift them right
1282 SHIFT places. */
1283 #define EXTRACT_BITS(STRUCT, MASK, SHIFT) \
1284 (((STRUCT) >> (SHIFT)) & (MASK))
1286 /* Extract the operand given by FIELD from mips_cl_insn INSN. */
1287 #define EXTRACT_OPERAND(MICROMIPS, FIELD, INSN) \
1288 (!(MICROMIPS) \
1289 ? EXTRACT_BITS ((INSN).insn_opcode, OP_MASK_##FIELD, OP_SH_##FIELD) \
1290 : EXTRACT_BITS ((INSN).insn_opcode, \
1291 MICROMIPSOP_MASK_##FIELD, MICROMIPSOP_SH_##FIELD))
1292 #define MIPS16_EXTRACT_OPERAND(FIELD, INSN) \
1293 EXTRACT_BITS ((INSN).insn_opcode, \
1294 MIPS16OP_MASK_##FIELD, \
1295 MIPS16OP_SH_##FIELD)
1297 /* The MIPS16 EXTEND opcode, shifted left 16 places. */
1298 #define MIPS16_EXTEND (0xf000U << 16)
1300 /* Whether or not we are emitting a branch-likely macro. */
1301 static bfd_boolean emit_branch_likely_macro = FALSE;
1303 /* Global variables used when generating relaxable macros. See the
1304 comment above RELAX_ENCODE for more details about how relaxation
1305 is used. */
1306 static struct {
1307 /* 0 if we're not emitting a relaxable macro.
1308 1 if we're emitting the first of the two relaxation alternatives.
1309 2 if we're emitting the second alternative. */
1310 int sequence;
1312 /* The first relaxable fixup in the current frag. (In other words,
1313 the first fixup that refers to relaxable code.) */
1314 fixS *first_fixup;
1316 /* sizes[0] says how many bytes of the first alternative are stored in
1317 the current frag. Likewise sizes[1] for the second alternative. */
1318 unsigned int sizes[2];
1320 /* The symbol on which the choice of sequence depends. */
1321 symbolS *symbol;
1322 } mips_relax;
1324 /* Global variables used to decide whether a macro needs a warning. */
1325 static struct {
1326 /* True if the macro is in a branch delay slot. */
1327 bfd_boolean delay_slot_p;
1329 /* Set to the length in bytes required if the macro is in a delay slot
1330 that requires a specific length of instruction, otherwise zero. */
1331 unsigned int delay_slot_length;
1333 /* For relaxable macros, sizes[0] is the length of the first alternative
1334 in bytes and sizes[1] is the length of the second alternative.
1335 For non-relaxable macros, both elements give the length of the
1336 macro in bytes. */
1337 unsigned int sizes[2];
1339 /* For relaxable macros, first_insn_sizes[0] is the length of the first
1340 instruction of the first alternative in bytes and first_insn_sizes[1]
1341 is the length of the first instruction of the second alternative.
1342 For non-relaxable macros, both elements give the length of the first
1343 instruction in bytes.
1345 Set to zero if we haven't yet seen the first instruction. */
1346 unsigned int first_insn_sizes[2];
1348 /* For relaxable macros, insns[0] is the number of instructions for the
1349 first alternative and insns[1] is the number of instructions for the
1350 second alternative.
1352 For non-relaxable macros, both elements give the number of
1353 instructions for the macro. */
1354 unsigned int insns[2];
1356 /* The first variant frag for this macro. */
1357 fragS *first_frag;
1358 } mips_macro_warning;
1360 /* Prototypes for static functions. */
1362 enum mips_regclass { MIPS_GR_REG, MIPS_FP_REG, MIPS16_REG };
1364 static void append_insn
1365 (struct mips_cl_insn *, expressionS *, bfd_reloc_code_real_type *,
1366 bfd_boolean expansionp);
1367 static void mips_no_prev_insn (void);
1368 static void macro_build (expressionS *, const char *, const char *, ...);
1369 static void mips16_macro_build
1370 (expressionS *, const char *, const char *, va_list *);
1371 static void load_register (int, expressionS *, int);
1372 static void macro_start (void);
1373 static void macro_end (void);
1374 static void macro (struct mips_cl_insn *ip, char *str);
1375 static void mips16_macro (struct mips_cl_insn * ip);
1376 static void mips_ip (char *str, struct mips_cl_insn * ip);
1377 static void mips16_ip (char *str, struct mips_cl_insn * ip);
1378 static unsigned long mips16_immed_extend (offsetT, unsigned int);
1379 static void mips16_immed
1380 (const char *, unsigned int, int, bfd_reloc_code_real_type, offsetT,
1381 unsigned int, unsigned long *);
1382 static size_t my_getSmallExpression
1383 (expressionS *, bfd_reloc_code_real_type *, char *);
1384 static void my_getExpression (expressionS *, char *);
1385 static void s_align (int);
1386 static void s_change_sec (int);
1387 static void s_change_section (int);
1388 static void s_cons (int);
1389 static void s_float_cons (int);
1390 static void s_mips_globl (int);
1391 static void s_option (int);
1392 static void s_mipsset (int);
1393 static void s_abicalls (int);
1394 static void s_cpload (int);
1395 static void s_cpsetup (int);
1396 static void s_cplocal (int);
1397 static void s_cprestore (int);
1398 static void s_cpreturn (int);
1399 static void s_dtprelword (int);
1400 static void s_dtpreldword (int);
1401 static void s_tprelword (int);
1402 static void s_tpreldword (int);
1403 static void s_gpvalue (int);
1404 static void s_gpword (int);
1405 static void s_gpdword (int);
1406 static void s_ehword (int);
1407 static void s_cpadd (int);
1408 static void s_insn (int);
1409 static void s_nan (int);
1410 static void s_module (int);
1411 static void s_mips_ent (int);
1412 static void s_mips_end (int);
1413 static void s_mips_frame (int);
1414 static void s_mips_mask (int reg_type);
1415 static void s_mips_stab (int);
1416 static void s_mips_weakext (int);
1417 static void s_mips_file (int);
1418 static void s_mips_loc (int);
1419 static bfd_boolean pic_need_relax (symbolS *);
1420 static int relaxed_branch_length (fragS *, asection *, int);
1421 static int relaxed_micromips_16bit_branch_length (fragS *, asection *, int);
1422 static int relaxed_micromips_32bit_branch_length (fragS *, asection *, int);
1423 static void file_mips_check_options (void);
1425 /* Table and functions used to map between CPU/ISA names, and
1426 ISA levels, and CPU numbers. */
1428 struct mips_cpu_info
1430 const char *name; /* CPU or ISA name. */
1431 int flags; /* MIPS_CPU_* flags. */
1432 int ase; /* Set of ASEs implemented by the CPU. */
1433 int isa; /* ISA level. */
1434 int cpu; /* CPU number (default CPU if ISA). */
1437 #define MIPS_CPU_IS_ISA 0x0001 /* Is this an ISA? (If 0, a CPU.) */
1439 static const struct mips_cpu_info *mips_parse_cpu (const char *, const char *);
1440 static const struct mips_cpu_info *mips_cpu_info_from_isa (int);
1441 static const struct mips_cpu_info *mips_cpu_info_from_arch (int);
1443 /* Command-line options. */
1444 const char *md_shortopts = "O::g::G:";
1446 enum options
1448 OPTION_MARCH = OPTION_MD_BASE,
1449 OPTION_MTUNE,
1450 OPTION_MIPS1,
1451 OPTION_MIPS2,
1452 OPTION_MIPS3,
1453 OPTION_MIPS4,
1454 OPTION_MIPS5,
1455 OPTION_MIPS32,
1456 OPTION_MIPS64,
1457 OPTION_MIPS32R2,
1458 OPTION_MIPS32R3,
1459 OPTION_MIPS32R5,
1460 OPTION_MIPS32R6,
1461 OPTION_MIPS64R2,
1462 OPTION_MIPS64R3,
1463 OPTION_MIPS64R5,
1464 OPTION_MIPS64R6,
1465 OPTION_MIPS16,
1466 OPTION_NO_MIPS16,
1467 OPTION_MIPS3D,
1468 OPTION_NO_MIPS3D,
1469 OPTION_MDMX,
1470 OPTION_NO_MDMX,
1471 OPTION_DSP,
1472 OPTION_NO_DSP,
1473 OPTION_MT,
1474 OPTION_NO_MT,
1475 OPTION_VIRT,
1476 OPTION_NO_VIRT,
1477 OPTION_MSA,
1478 OPTION_NO_MSA,
1479 OPTION_SMARTMIPS,
1480 OPTION_NO_SMARTMIPS,
1481 OPTION_DSPR2,
1482 OPTION_NO_DSPR2,
1483 OPTION_DSPR3,
1484 OPTION_NO_DSPR3,
1485 OPTION_EVA,
1486 OPTION_NO_EVA,
1487 OPTION_XPA,
1488 OPTION_NO_XPA,
1489 OPTION_MICROMIPS,
1490 OPTION_NO_MICROMIPS,
1491 OPTION_MCU,
1492 OPTION_NO_MCU,
1493 OPTION_MIPS16E2,
1494 OPTION_NO_MIPS16E2,
1495 OPTION_CRC,
1496 OPTION_NO_CRC,
1497 OPTION_M4650,
1498 OPTION_NO_M4650,
1499 OPTION_M4010,
1500 OPTION_NO_M4010,
1501 OPTION_M4100,
1502 OPTION_NO_M4100,
1503 OPTION_M3900,
1504 OPTION_NO_M3900,
1505 OPTION_M7000_HILO_FIX,
1506 OPTION_MNO_7000_HILO_FIX,
1507 OPTION_FIX_24K,
1508 OPTION_NO_FIX_24K,
1509 OPTION_FIX_RM7000,
1510 OPTION_NO_FIX_RM7000,
1511 OPTION_FIX_LOONGSON3_LLSC,
1512 OPTION_NO_FIX_LOONGSON3_LLSC,
1513 OPTION_FIX_LOONGSON2F_JUMP,
1514 OPTION_NO_FIX_LOONGSON2F_JUMP,
1515 OPTION_FIX_LOONGSON2F_NOP,
1516 OPTION_NO_FIX_LOONGSON2F_NOP,
1517 OPTION_FIX_VR4120,
1518 OPTION_NO_FIX_VR4120,
1519 OPTION_FIX_VR4130,
1520 OPTION_NO_FIX_VR4130,
1521 OPTION_FIX_CN63XXP1,
1522 OPTION_NO_FIX_CN63XXP1,
1523 OPTION_FIX_R5900,
1524 OPTION_NO_FIX_R5900,
1525 OPTION_TRAP,
1526 OPTION_BREAK,
1527 OPTION_EB,
1528 OPTION_EL,
1529 OPTION_FP32,
1530 OPTION_GP32,
1531 OPTION_CONSTRUCT_FLOATS,
1532 OPTION_NO_CONSTRUCT_FLOATS,
1533 OPTION_FP64,
1534 OPTION_FPXX,
1535 OPTION_GP64,
1536 OPTION_RELAX_BRANCH,
1537 OPTION_NO_RELAX_BRANCH,
1538 OPTION_IGNORE_BRANCH_ISA,
1539 OPTION_NO_IGNORE_BRANCH_ISA,
1540 OPTION_INSN32,
1541 OPTION_NO_INSN32,
1542 OPTION_MSHARED,
1543 OPTION_MNO_SHARED,
1544 OPTION_MSYM32,
1545 OPTION_MNO_SYM32,
1546 OPTION_SOFT_FLOAT,
1547 OPTION_HARD_FLOAT,
1548 OPTION_SINGLE_FLOAT,
1549 OPTION_DOUBLE_FLOAT,
1550 OPTION_32,
1551 OPTION_CALL_SHARED,
1552 OPTION_CALL_NONPIC,
1553 OPTION_NON_SHARED,
1554 OPTION_XGOT,
1555 OPTION_MABI,
1556 OPTION_N32,
1557 OPTION_64,
1558 OPTION_MDEBUG,
1559 OPTION_NO_MDEBUG,
1560 OPTION_PDR,
1561 OPTION_NO_PDR,
1562 OPTION_MVXWORKS_PIC,
1563 OPTION_NAN,
1564 OPTION_ODD_SPREG,
1565 OPTION_NO_ODD_SPREG,
1566 OPTION_GINV,
1567 OPTION_NO_GINV,
1568 OPTION_LOONGSON_MMI,
1569 OPTION_NO_LOONGSON_MMI,
1570 OPTION_LOONGSON_CAM,
1571 OPTION_NO_LOONGSON_CAM,
1572 OPTION_LOONGSON_EXT,
1573 OPTION_NO_LOONGSON_EXT,
1574 OPTION_LOONGSON_EXT2,
1575 OPTION_NO_LOONGSON_EXT2,
1576 OPTION_END_OF_ENUM
1579 struct option md_longopts[] =
1581 /* Options which specify architecture. */
1582 {"march", required_argument, NULL, OPTION_MARCH},
1583 {"mtune", required_argument, NULL, OPTION_MTUNE},
1584 {"mips0", no_argument, NULL, OPTION_MIPS1},
1585 {"mips1", no_argument, NULL, OPTION_MIPS1},
1586 {"mips2", no_argument, NULL, OPTION_MIPS2},
1587 {"mips3", no_argument, NULL, OPTION_MIPS3},
1588 {"mips4", no_argument, NULL, OPTION_MIPS4},
1589 {"mips5", no_argument, NULL, OPTION_MIPS5},
1590 {"mips32", no_argument, NULL, OPTION_MIPS32},
1591 {"mips64", no_argument, NULL, OPTION_MIPS64},
1592 {"mips32r2", no_argument, NULL, OPTION_MIPS32R2},
1593 {"mips32r3", no_argument, NULL, OPTION_MIPS32R3},
1594 {"mips32r5", no_argument, NULL, OPTION_MIPS32R5},
1595 {"mips32r6", no_argument, NULL, OPTION_MIPS32R6},
1596 {"mips64r2", no_argument, NULL, OPTION_MIPS64R2},
1597 {"mips64r3", no_argument, NULL, OPTION_MIPS64R3},
1598 {"mips64r5", no_argument, NULL, OPTION_MIPS64R5},
1599 {"mips64r6", no_argument, NULL, OPTION_MIPS64R6},
1601 /* Options which specify Application Specific Extensions (ASEs). */
1602 {"mips16", no_argument, NULL, OPTION_MIPS16},
1603 {"no-mips16", no_argument, NULL, OPTION_NO_MIPS16},
1604 {"mips3d", no_argument, NULL, OPTION_MIPS3D},
1605 {"no-mips3d", no_argument, NULL, OPTION_NO_MIPS3D},
1606 {"mdmx", no_argument, NULL, OPTION_MDMX},
1607 {"no-mdmx", no_argument, NULL, OPTION_NO_MDMX},
1608 {"mdsp", no_argument, NULL, OPTION_DSP},
1609 {"mno-dsp", no_argument, NULL, OPTION_NO_DSP},
1610 {"mmt", no_argument, NULL, OPTION_MT},
1611 {"mno-mt", no_argument, NULL, OPTION_NO_MT},
1612 {"msmartmips", no_argument, NULL, OPTION_SMARTMIPS},
1613 {"mno-smartmips", no_argument, NULL, OPTION_NO_SMARTMIPS},
1614 {"mdspr2", no_argument, NULL, OPTION_DSPR2},
1615 {"mno-dspr2", no_argument, NULL, OPTION_NO_DSPR2},
1616 {"mdspr3", no_argument, NULL, OPTION_DSPR3},
1617 {"mno-dspr3", no_argument, NULL, OPTION_NO_DSPR3},
1618 {"meva", no_argument, NULL, OPTION_EVA},
1619 {"mno-eva", no_argument, NULL, OPTION_NO_EVA},
1620 {"mmicromips", no_argument, NULL, OPTION_MICROMIPS},
1621 {"mno-micromips", no_argument, NULL, OPTION_NO_MICROMIPS},
1622 {"mmcu", no_argument, NULL, OPTION_MCU},
1623 {"mno-mcu", no_argument, NULL, OPTION_NO_MCU},
1624 {"mvirt", no_argument, NULL, OPTION_VIRT},
1625 {"mno-virt", no_argument, NULL, OPTION_NO_VIRT},
1626 {"mmsa", no_argument, NULL, OPTION_MSA},
1627 {"mno-msa", no_argument, NULL, OPTION_NO_MSA},
1628 {"mxpa", no_argument, NULL, OPTION_XPA},
1629 {"mno-xpa", no_argument, NULL, OPTION_NO_XPA},
1630 {"mmips16e2", no_argument, NULL, OPTION_MIPS16E2},
1631 {"mno-mips16e2", no_argument, NULL, OPTION_NO_MIPS16E2},
1632 {"mcrc", no_argument, NULL, OPTION_CRC},
1633 {"mno-crc", no_argument, NULL, OPTION_NO_CRC},
1634 {"mginv", no_argument, NULL, OPTION_GINV},
1635 {"mno-ginv", no_argument, NULL, OPTION_NO_GINV},
1636 {"mloongson-mmi", no_argument, NULL, OPTION_LOONGSON_MMI},
1637 {"mno-loongson-mmi", no_argument, NULL, OPTION_NO_LOONGSON_MMI},
1638 {"mloongson-cam", no_argument, NULL, OPTION_LOONGSON_CAM},
1639 {"mno-loongson-cam", no_argument, NULL, OPTION_NO_LOONGSON_CAM},
1640 {"mloongson-ext", no_argument, NULL, OPTION_LOONGSON_EXT},
1641 {"mno-loongson-ext", no_argument, NULL, OPTION_NO_LOONGSON_EXT},
1642 {"mloongson-ext2", no_argument, NULL, OPTION_LOONGSON_EXT2},
1643 {"mno-loongson-ext2", no_argument, NULL, OPTION_NO_LOONGSON_EXT2},
1645 /* Old-style architecture options. Don't add more of these. */
1646 {"m4650", no_argument, NULL, OPTION_M4650},
1647 {"no-m4650", no_argument, NULL, OPTION_NO_M4650},
1648 {"m4010", no_argument, NULL, OPTION_M4010},
1649 {"no-m4010", no_argument, NULL, OPTION_NO_M4010},
1650 {"m4100", no_argument, NULL, OPTION_M4100},
1651 {"no-m4100", no_argument, NULL, OPTION_NO_M4100},
1652 {"m3900", no_argument, NULL, OPTION_M3900},
1653 {"no-m3900", no_argument, NULL, OPTION_NO_M3900},
1655 /* Options which enable bug fixes. */
1656 {"mfix7000", no_argument, NULL, OPTION_M7000_HILO_FIX},
1657 {"no-fix-7000", no_argument, NULL, OPTION_MNO_7000_HILO_FIX},
1658 {"mno-fix7000", no_argument, NULL, OPTION_MNO_7000_HILO_FIX},
1659 {"mfix-loongson3-llsc", no_argument, NULL, OPTION_FIX_LOONGSON3_LLSC},
1660 {"mno-fix-loongson3-llsc", no_argument, NULL, OPTION_NO_FIX_LOONGSON3_LLSC},
1661 {"mfix-loongson2f-jump", no_argument, NULL, OPTION_FIX_LOONGSON2F_JUMP},
1662 {"mno-fix-loongson2f-jump", no_argument, NULL, OPTION_NO_FIX_LOONGSON2F_JUMP},
1663 {"mfix-loongson2f-nop", no_argument, NULL, OPTION_FIX_LOONGSON2F_NOP},
1664 {"mno-fix-loongson2f-nop", no_argument, NULL, OPTION_NO_FIX_LOONGSON2F_NOP},
1665 {"mfix-vr4120", no_argument, NULL, OPTION_FIX_VR4120},
1666 {"mno-fix-vr4120", no_argument, NULL, OPTION_NO_FIX_VR4120},
1667 {"mfix-vr4130", no_argument, NULL, OPTION_FIX_VR4130},
1668 {"mno-fix-vr4130", no_argument, NULL, OPTION_NO_FIX_VR4130},
1669 {"mfix-24k", no_argument, NULL, OPTION_FIX_24K},
1670 {"mno-fix-24k", no_argument, NULL, OPTION_NO_FIX_24K},
1671 {"mfix-rm7000", no_argument, NULL, OPTION_FIX_RM7000},
1672 {"mno-fix-rm7000", no_argument, NULL, OPTION_NO_FIX_RM7000},
1673 {"mfix-cn63xxp1", no_argument, NULL, OPTION_FIX_CN63XXP1},
1674 {"mno-fix-cn63xxp1", no_argument, NULL, OPTION_NO_FIX_CN63XXP1},
1675 {"mfix-r5900", no_argument, NULL, OPTION_FIX_R5900},
1676 {"mno-fix-r5900", no_argument, NULL, OPTION_NO_FIX_R5900},
1678 /* Miscellaneous options. */
1679 {"trap", no_argument, NULL, OPTION_TRAP},
1680 {"no-break", no_argument, NULL, OPTION_TRAP},
1681 {"break", no_argument, NULL, OPTION_BREAK},
1682 {"no-trap", no_argument, NULL, OPTION_BREAK},
1683 {"EB", no_argument, NULL, OPTION_EB},
1684 {"EL", no_argument, NULL, OPTION_EL},
1685 {"mfp32", no_argument, NULL, OPTION_FP32},
1686 {"mgp32", no_argument, NULL, OPTION_GP32},
1687 {"construct-floats", no_argument, NULL, OPTION_CONSTRUCT_FLOATS},
1688 {"no-construct-floats", no_argument, NULL, OPTION_NO_CONSTRUCT_FLOATS},
1689 {"mfp64", no_argument, NULL, OPTION_FP64},
1690 {"mfpxx", no_argument, NULL, OPTION_FPXX},
1691 {"mgp64", no_argument, NULL, OPTION_GP64},
1692 {"relax-branch", no_argument, NULL, OPTION_RELAX_BRANCH},
1693 {"no-relax-branch", no_argument, NULL, OPTION_NO_RELAX_BRANCH},
1694 {"mignore-branch-isa", no_argument, NULL, OPTION_IGNORE_BRANCH_ISA},
1695 {"mno-ignore-branch-isa", no_argument, NULL, OPTION_NO_IGNORE_BRANCH_ISA},
1696 {"minsn32", no_argument, NULL, OPTION_INSN32},
1697 {"mno-insn32", no_argument, NULL, OPTION_NO_INSN32},
1698 {"mshared", no_argument, NULL, OPTION_MSHARED},
1699 {"mno-shared", no_argument, NULL, OPTION_MNO_SHARED},
1700 {"msym32", no_argument, NULL, OPTION_MSYM32},
1701 {"mno-sym32", no_argument, NULL, OPTION_MNO_SYM32},
1702 {"msoft-float", no_argument, NULL, OPTION_SOFT_FLOAT},
1703 {"mhard-float", no_argument, NULL, OPTION_HARD_FLOAT},
1704 {"msingle-float", no_argument, NULL, OPTION_SINGLE_FLOAT},
1705 {"mdouble-float", no_argument, NULL, OPTION_DOUBLE_FLOAT},
1706 {"modd-spreg", no_argument, NULL, OPTION_ODD_SPREG},
1707 {"mno-odd-spreg", no_argument, NULL, OPTION_NO_ODD_SPREG},
1709 /* Strictly speaking this next option is ELF specific,
1710 but we allow it for other ports as well in order to
1711 make testing easier. */
1712 {"32", no_argument, NULL, OPTION_32},
1714 /* ELF-specific options. */
1715 {"KPIC", no_argument, NULL, OPTION_CALL_SHARED},
1716 {"call_shared", no_argument, NULL, OPTION_CALL_SHARED},
1717 {"call_nonpic", no_argument, NULL, OPTION_CALL_NONPIC},
1718 {"non_shared", no_argument, NULL, OPTION_NON_SHARED},
1719 {"xgot", no_argument, NULL, OPTION_XGOT},
1720 {"mabi", required_argument, NULL, OPTION_MABI},
1721 {"n32", no_argument, NULL, OPTION_N32},
1722 {"64", no_argument, NULL, OPTION_64},
1723 {"mdebug", no_argument, NULL, OPTION_MDEBUG},
1724 {"no-mdebug", no_argument, NULL, OPTION_NO_MDEBUG},
1725 {"mpdr", no_argument, NULL, OPTION_PDR},
1726 {"mno-pdr", no_argument, NULL, OPTION_NO_PDR},
1727 {"mvxworks-pic", no_argument, NULL, OPTION_MVXWORKS_PIC},
1728 {"mnan", required_argument, NULL, OPTION_NAN},
1730 {NULL, no_argument, NULL, 0}
1732 size_t md_longopts_size = sizeof (md_longopts);
1734 /* Information about either an Application Specific Extension or an
1735 optional architecture feature that, for simplicity, we treat in the
1736 same way as an ASE. */
1737 struct mips_ase
1739 /* The name of the ASE, used in both the command-line and .set options. */
1740 const char *name;
1742 /* The associated ASE_* flags. If the ASE is available on both 32-bit
1743 and 64-bit architectures, the flags here refer to the subset that
1744 is available on both. */
1745 unsigned int flags;
1747 /* The ASE_* flag used for instructions that are available on 64-bit
1748 architectures but that are not included in FLAGS. */
1749 unsigned int flags64;
1751 /* The command-line options that turn the ASE on and off. */
1752 int option_on;
1753 int option_off;
1755 /* The minimum required architecture revisions for MIPS32, MIPS64,
1756 microMIPS32 and microMIPS64, or -1 if the extension isn't supported. */
1757 int mips32_rev;
1758 int mips64_rev;
1759 int micromips32_rev;
1760 int micromips64_rev;
1762 /* The architecture where the ASE was removed or -1 if the extension has not
1763 been removed. */
1764 int rem_rev;
1767 /* A table of all supported ASEs. */
1768 static const struct mips_ase mips_ases[] = {
1769 { "dsp", ASE_DSP, ASE_DSP64,
1770 OPTION_DSP, OPTION_NO_DSP,
1771 2, 2, 2, 2,
1772 -1 },
1774 { "dspr2", ASE_DSP | ASE_DSPR2, 0,
1775 OPTION_DSPR2, OPTION_NO_DSPR2,
1776 2, 2, 2, 2,
1777 -1 },
1779 { "dspr3", ASE_DSP | ASE_DSPR2 | ASE_DSPR3, 0,
1780 OPTION_DSPR3, OPTION_NO_DSPR3,
1781 6, 6, -1, -1,
1782 -1 },
1784 { "eva", ASE_EVA, 0,
1785 OPTION_EVA, OPTION_NO_EVA,
1786 2, 2, 2, 2,
1787 -1 },
1789 { "mcu", ASE_MCU, 0,
1790 OPTION_MCU, OPTION_NO_MCU,
1791 2, 2, 2, 2,
1792 -1 },
1794 /* Deprecated in MIPS64r5, but we don't implement that yet. */
1795 { "mdmx", ASE_MDMX, 0,
1796 OPTION_MDMX, OPTION_NO_MDMX,
1797 -1, 1, -1, -1,
1798 6 },
1800 /* Requires 64-bit FPRs, so the minimum MIPS32 revision is 2. */
1801 { "mips3d", ASE_MIPS3D, 0,
1802 OPTION_MIPS3D, OPTION_NO_MIPS3D,
1803 2, 1, -1, -1,
1804 6 },
1806 { "mt", ASE_MT, 0,
1807 OPTION_MT, OPTION_NO_MT,
1808 2, 2, -1, -1,
1809 -1 },
1811 { "smartmips", ASE_SMARTMIPS, 0,
1812 OPTION_SMARTMIPS, OPTION_NO_SMARTMIPS,
1813 1, -1, -1, -1,
1814 6 },
1816 { "virt", ASE_VIRT, ASE_VIRT64,
1817 OPTION_VIRT, OPTION_NO_VIRT,
1818 2, 2, 2, 2,
1819 -1 },
1821 { "msa", ASE_MSA, ASE_MSA64,
1822 OPTION_MSA, OPTION_NO_MSA,
1823 2, 2, 2, 2,
1824 -1 },
1826 { "xpa", ASE_XPA, 0,
1827 OPTION_XPA, OPTION_NO_XPA,
1828 2, 2, 2, 2,
1829 -1 },
1831 { "mips16e2", ASE_MIPS16E2, 0,
1832 OPTION_MIPS16E2, OPTION_NO_MIPS16E2,
1833 2, 2, -1, -1,
1834 6 },
1836 { "crc", ASE_CRC, ASE_CRC64,
1837 OPTION_CRC, OPTION_NO_CRC,
1838 6, 6, -1, -1,
1839 -1 },
1841 { "ginv", ASE_GINV, 0,
1842 OPTION_GINV, OPTION_NO_GINV,
1843 6, 6, 6, 6,
1844 -1 },
1846 { "loongson-mmi", ASE_LOONGSON_MMI, 0,
1847 OPTION_LOONGSON_MMI, OPTION_NO_LOONGSON_MMI,
1848 0, 0, -1, -1,
1849 -1 },
1851 { "loongson-cam", ASE_LOONGSON_CAM, 0,
1852 OPTION_LOONGSON_CAM, OPTION_NO_LOONGSON_CAM,
1853 0, 0, -1, -1,
1854 -1 },
1856 { "loongson-ext", ASE_LOONGSON_EXT, 0,
1857 OPTION_LOONGSON_EXT, OPTION_NO_LOONGSON_EXT,
1858 0, 0, -1, -1,
1859 -1 },
1861 { "loongson-ext2", ASE_LOONGSON_EXT | ASE_LOONGSON_EXT2, 0,
1862 OPTION_LOONGSON_EXT2, OPTION_NO_LOONGSON_EXT2,
1863 0, 0, -1, -1,
1864 -1 },
1867 /* The set of ASEs that require -mfp64. */
1868 #define FP64_ASES (ASE_MIPS3D | ASE_MDMX | ASE_MSA)
1870 /* Groups of ASE_* flags that represent different revisions of an ASE. */
1871 static const unsigned int mips_ase_groups[] = {
1872 ASE_DSP | ASE_DSPR2 | ASE_DSPR3,
1873 ASE_LOONGSON_EXT | ASE_LOONGSON_EXT2
1876 /* Pseudo-op table.
1878 The following pseudo-ops from the Kane and Heinrich MIPS book
1879 should be defined here, but are currently unsupported: .alias,
1880 .galive, .gjaldef, .gjrlive, .livereg, .noalias.
1882 The following pseudo-ops from the Kane and Heinrich MIPS book are
1883 specific to the type of debugging information being generated, and
1884 should be defined by the object format: .aent, .begin, .bend,
1885 .bgnb, .end, .endb, .ent, .fmask, .frame, .loc, .mask, .verstamp,
1886 .vreg.
1888 The following pseudo-ops from the Kane and Heinrich MIPS book are
1889 not MIPS CPU specific, but are also not specific to the object file
1890 format. This file is probably the best place to define them, but
1891 they are not currently supported: .asm0, .endr, .lab, .struct. */
1893 static const pseudo_typeS mips_pseudo_table[] =
1895 /* MIPS specific pseudo-ops. */
1896 {"option", s_option, 0},
1897 {"set", s_mipsset, 0},
1898 {"rdata", s_change_sec, 'r'},
1899 {"sdata", s_change_sec, 's'},
1900 {"livereg", s_ignore, 0},
1901 {"abicalls", s_abicalls, 0},
1902 {"cpload", s_cpload, 0},
1903 {"cpsetup", s_cpsetup, 0},
1904 {"cplocal", s_cplocal, 0},
1905 {"cprestore", s_cprestore, 0},
1906 {"cpreturn", s_cpreturn, 0},
1907 {"dtprelword", s_dtprelword, 0},
1908 {"dtpreldword", s_dtpreldword, 0},
1909 {"tprelword", s_tprelword, 0},
1910 {"tpreldword", s_tpreldword, 0},
1911 {"gpvalue", s_gpvalue, 0},
1912 {"gpword", s_gpword, 0},
1913 {"gpdword", s_gpdword, 0},
1914 {"ehword", s_ehword, 0},
1915 {"cpadd", s_cpadd, 0},
1916 {"insn", s_insn, 0},
1917 {"nan", s_nan, 0},
1918 {"module", s_module, 0},
1920 /* Relatively generic pseudo-ops that happen to be used on MIPS
1921 chips. */
1922 {"asciiz", stringer, 8 + 1},
1923 {"bss", s_change_sec, 'b'},
1924 {"err", s_err, 0},
1925 {"half", s_cons, 1},
1926 {"dword", s_cons, 3},
1927 {"weakext", s_mips_weakext, 0},
1928 {"origin", s_org, 0},
1929 {"repeat", s_rept, 0},
1931 /* For MIPS this is non-standard, but we define it for consistency. */
1932 {"sbss", s_change_sec, 'B'},
1934 /* These pseudo-ops are defined in read.c, but must be overridden
1935 here for one reason or another. */
1936 {"align", s_align, 0},
1937 {"byte", s_cons, 0},
1938 {"data", s_change_sec, 'd'},
1939 {"double", s_float_cons, 'd'},
1940 {"float", s_float_cons, 'f'},
1941 {"globl", s_mips_globl, 0},
1942 {"global", s_mips_globl, 0},
1943 {"hword", s_cons, 1},
1944 {"int", s_cons, 2},
1945 {"long", s_cons, 2},
1946 {"octa", s_cons, 4},
1947 {"quad", s_cons, 3},
1948 {"section", s_change_section, 0},
1949 {"short", s_cons, 1},
1950 {"single", s_float_cons, 'f'},
1951 {"stabd", s_mips_stab, 'd'},
1952 {"stabn", s_mips_stab, 'n'},
1953 {"stabs", s_mips_stab, 's'},
1954 {"text", s_change_sec, 't'},
1955 {"word", s_cons, 2},
1957 { "extern", ecoff_directive_extern, 0},
1959 { NULL, NULL, 0 },
1962 static const pseudo_typeS mips_nonecoff_pseudo_table[] =
1964 /* These pseudo-ops should be defined by the object file format.
1965 However, a.out doesn't support them, so we have versions here. */
1966 {"aent", s_mips_ent, 1},
1967 {"bgnb", s_ignore, 0},
1968 {"end", s_mips_end, 0},
1969 {"endb", s_ignore, 0},
1970 {"ent", s_mips_ent, 0},
1971 {"file", s_mips_file, 0},
1972 {"fmask", s_mips_mask, 'F'},
1973 {"frame", s_mips_frame, 0},
1974 {"loc", s_mips_loc, 0},
1975 {"mask", s_mips_mask, 'R'},
1976 {"verstamp", s_ignore, 0},
1977 { NULL, NULL, 0 },
1980 /* Export the ABI address size for use by TC_ADDRESS_BYTES for the
1981 purpose of the `.dc.a' internal pseudo-op. */
1984 mips_address_bytes (void)
1986 file_mips_check_options ();
1987 return HAVE_64BIT_ADDRESSES ? 8 : 4;
1990 extern void pop_insert (const pseudo_typeS *);
1992 void
1993 mips_pop_insert (void)
1995 pop_insert (mips_pseudo_table);
1996 if (! ECOFF_DEBUGGING)
1997 pop_insert (mips_nonecoff_pseudo_table);
2000 /* Symbols labelling the current insn. */
2002 struct insn_label_list
2004 struct insn_label_list *next;
2005 symbolS *label;
2008 static struct insn_label_list *free_insn_labels;
2009 #define label_list tc_segment_info_data.labels
2011 static void mips_clear_insn_labels (void);
2012 static void mips_mark_labels (void);
2013 static void mips_compressed_mark_labels (void);
2015 static inline void
2016 mips_clear_insn_labels (void)
2018 struct insn_label_list **pl;
2019 segment_info_type *si;
2021 if (now_seg)
2023 for (pl = &free_insn_labels; *pl != NULL; pl = &(*pl)->next)
2026 si = seg_info (now_seg);
2027 *pl = si->label_list;
2028 si->label_list = NULL;
2032 /* Mark instruction labels in MIPS16/microMIPS mode. */
2034 static inline void
2035 mips_mark_labels (void)
2037 if (HAVE_CODE_COMPRESSION)
2038 mips_compressed_mark_labels ();
2041 static char *expr_end;
2043 /* An expression in a macro instruction. This is set by mips_ip and
2044 mips16_ip and when populated is always an O_constant. */
2046 static expressionS imm_expr;
2048 /* The relocatable field in an instruction and the relocs associated
2049 with it. These variables are used for instructions like LUI and
2050 JAL as well as true offsets. They are also used for address
2051 operands in macros. */
2053 static expressionS offset_expr;
2054 static bfd_reloc_code_real_type offset_reloc[3]
2055 = {BFD_RELOC_UNUSED, BFD_RELOC_UNUSED, BFD_RELOC_UNUSED};
2057 /* This is set to the resulting size of the instruction to be produced
2058 by mips16_ip if an explicit extension is used or by mips_ip if an
2059 explicit size is supplied. */
2061 static unsigned int forced_insn_length;
2063 /* True if we are assembling an instruction. All dot symbols defined during
2064 this time should be treated as code labels. */
2066 static bfd_boolean mips_assembling_insn;
2068 /* The pdr segment for per procedure frame/regmask info. Not used for
2069 ECOFF debugging. */
2071 static segT pdr_seg;
2073 /* The default target format to use. */
2075 #if defined (TE_FreeBSD)
2076 #define ELF_TARGET(PREFIX, ENDIAN) PREFIX "trad" ENDIAN "mips-freebsd"
2077 #elif defined (TE_TMIPS)
2078 #define ELF_TARGET(PREFIX, ENDIAN) PREFIX "trad" ENDIAN "mips"
2079 #else
2080 #define ELF_TARGET(PREFIX, ENDIAN) PREFIX ENDIAN "mips"
2081 #endif
2083 const char *
2084 mips_target_format (void)
2086 switch (OUTPUT_FLAVOR)
2088 case bfd_target_elf_flavour:
2089 #ifdef TE_VXWORKS
2090 if (!HAVE_64BIT_OBJECTS && !HAVE_NEWABI)
2091 return (target_big_endian
2092 ? "elf32-bigmips-vxworks"
2093 : "elf32-littlemips-vxworks");
2094 #endif
2095 return (target_big_endian
2096 ? (HAVE_64BIT_OBJECTS
2097 ? ELF_TARGET ("elf64-", "big")
2098 : (HAVE_NEWABI
2099 ? ELF_TARGET ("elf32-n", "big")
2100 : ELF_TARGET ("elf32-", "big")))
2101 : (HAVE_64BIT_OBJECTS
2102 ? ELF_TARGET ("elf64-", "little")
2103 : (HAVE_NEWABI
2104 ? ELF_TARGET ("elf32-n", "little")
2105 : ELF_TARGET ("elf32-", "little"))));
2106 default:
2107 abort ();
2108 return NULL;
2112 /* Return the ISA revision that is currently in use, or 0 if we are
2113 generating code for MIPS V or below. */
2115 static int
2116 mips_isa_rev (void)
2118 if (mips_opts.isa == ISA_MIPS32R2 || mips_opts.isa == ISA_MIPS64R2)
2119 return 2;
2121 if (mips_opts.isa == ISA_MIPS32R3 || mips_opts.isa == ISA_MIPS64R3)
2122 return 3;
2124 if (mips_opts.isa == ISA_MIPS32R5 || mips_opts.isa == ISA_MIPS64R5)
2125 return 5;
2127 if (mips_opts.isa == ISA_MIPS32R6 || mips_opts.isa == ISA_MIPS64R6)
2128 return 6;
2130 /* microMIPS implies revision 2 or above. */
2131 if (mips_opts.micromips)
2132 return 2;
2134 if (mips_opts.isa == ISA_MIPS32 || mips_opts.isa == ISA_MIPS64)
2135 return 1;
2137 return 0;
2140 /* Return the mask of all ASEs that are revisions of those in FLAGS. */
2142 static unsigned int
2143 mips_ase_mask (unsigned int flags)
2145 unsigned int i;
2147 for (i = 0; i < ARRAY_SIZE (mips_ase_groups); i++)
2148 if (flags & mips_ase_groups[i])
2149 flags |= mips_ase_groups[i];
2150 return flags;
2153 /* Check whether the current ISA supports ASE. Issue a warning if
2154 appropriate. */
2156 static void
2157 mips_check_isa_supports_ase (const struct mips_ase *ase)
2159 const char *base;
2160 int min_rev, size;
2161 static unsigned int warned_isa;
2162 static unsigned int warned_fp32;
2164 if (ISA_HAS_64BIT_REGS (mips_opts.isa))
2165 min_rev = mips_opts.micromips ? ase->micromips64_rev : ase->mips64_rev;
2166 else
2167 min_rev = mips_opts.micromips ? ase->micromips32_rev : ase->mips32_rev;
2168 if ((min_rev < 0 || mips_isa_rev () < min_rev)
2169 && (warned_isa & ase->flags) != ase->flags)
2171 warned_isa |= ase->flags;
2172 base = mips_opts.micromips ? "microMIPS" : "MIPS";
2173 size = ISA_HAS_64BIT_REGS (mips_opts.isa) ? 64 : 32;
2174 if (min_rev < 0)
2175 as_warn (_("the %d-bit %s architecture does not support the"
2176 " `%s' extension"), size, base, ase->name);
2177 else
2178 as_warn (_("the `%s' extension requires %s%d revision %d or greater"),
2179 ase->name, base, size, min_rev);
2181 else if ((ase->rem_rev > 0 && mips_isa_rev () >= ase->rem_rev)
2182 && (warned_isa & ase->flags) != ase->flags)
2184 warned_isa |= ase->flags;
2185 base = mips_opts.micromips ? "microMIPS" : "MIPS";
2186 size = ISA_HAS_64BIT_REGS (mips_opts.isa) ? 64 : 32;
2187 as_warn (_("the `%s' extension was removed in %s%d revision %d"),
2188 ase->name, base, size, ase->rem_rev);
2191 if ((ase->flags & FP64_ASES)
2192 && mips_opts.fp != 64
2193 && (warned_fp32 & ase->flags) != ase->flags)
2195 warned_fp32 |= ase->flags;
2196 as_warn (_("the `%s' extension requires 64-bit FPRs"), ase->name);
2200 /* Check all enabled ASEs to see whether they are supported by the
2201 chosen architecture. */
2203 static void
2204 mips_check_isa_supports_ases (void)
2206 unsigned int i, mask;
2208 for (i = 0; i < ARRAY_SIZE (mips_ases); i++)
2210 mask = mips_ase_mask (mips_ases[i].flags);
2211 if ((mips_opts.ase & mask) == mips_ases[i].flags)
2212 mips_check_isa_supports_ase (&mips_ases[i]);
2216 /* Set the state of ASE to ENABLED_P. Return the mask of ASE_* flags
2217 that were affected. */
2219 static unsigned int
2220 mips_set_ase (const struct mips_ase *ase, struct mips_set_options *opts,
2221 bfd_boolean enabled_p)
2223 unsigned int mask;
2225 mask = mips_ase_mask (ase->flags);
2226 opts->ase &= ~mask;
2228 /* Clear combination ASE flags, which need to be recalculated based on
2229 updated regular ASE settings. */
2230 opts->ase &= ~(ASE_MIPS16E2_MT | ASE_XPA_VIRT | ASE_EVA_R6);
2232 if (enabled_p)
2233 opts->ase |= ase->flags;
2235 /* The Virtualization ASE has eXtended Physical Addressing (XPA)
2236 instructions which are only valid when both ASEs are enabled.
2237 This sets the ASE_XPA_VIRT flag when both ASEs are present. */
2238 if ((opts->ase & (ASE_XPA | ASE_VIRT)) == (ASE_XPA | ASE_VIRT))
2240 opts->ase |= ASE_XPA_VIRT;
2241 mask |= ASE_XPA_VIRT;
2243 if ((opts->ase & (ASE_MIPS16E2 | ASE_MT)) == (ASE_MIPS16E2 | ASE_MT))
2245 opts->ase |= ASE_MIPS16E2_MT;
2246 mask |= ASE_MIPS16E2_MT;
2249 /* The EVA Extension has instructions which are only valid when the R6 ISA
2250 is enabled. This sets the ASE_EVA_R6 flag when both EVA and R6 ISA are
2251 present. */
2252 if (((opts->ase & ASE_EVA) != 0) && ISA_IS_R6 (opts->isa))
2254 opts->ase |= ASE_EVA_R6;
2255 mask |= ASE_EVA_R6;
2258 return mask;
2261 /* Return the ASE called NAME, or null if none. */
2263 static const struct mips_ase *
2264 mips_lookup_ase (const char *name)
2266 unsigned int i;
2268 for (i = 0; i < ARRAY_SIZE (mips_ases); i++)
2269 if (strcmp (name, mips_ases[i].name) == 0)
2270 return &mips_ases[i];
2271 return NULL;
2274 /* Return the length of a microMIPS instruction in bytes. If bits of
2275 the mask beyond the low 16 are 0, then it is a 16-bit instruction,
2276 otherwise it is a 32-bit instruction. */
2278 static inline unsigned int
2279 micromips_insn_length (const struct mips_opcode *mo)
2281 return mips_opcode_32bit_p (mo) ? 4 : 2;
2284 /* Return the length of MIPS16 instruction OPCODE. */
2286 static inline unsigned int
2287 mips16_opcode_length (unsigned long opcode)
2289 return (opcode >> 16) == 0 ? 2 : 4;
2292 /* Return the length of instruction INSN. */
2294 static inline unsigned int
2295 insn_length (const struct mips_cl_insn *insn)
2297 if (mips_opts.micromips)
2298 return micromips_insn_length (insn->insn_mo);
2299 else if (mips_opts.mips16)
2300 return mips16_opcode_length (insn->insn_opcode);
2301 else
2302 return 4;
2305 /* Initialise INSN from opcode entry MO. Leave its position unspecified. */
2307 static void
2308 create_insn (struct mips_cl_insn *insn, const struct mips_opcode *mo)
2310 size_t i;
2312 insn->insn_mo = mo;
2313 insn->insn_opcode = mo->match;
2314 insn->frag = NULL;
2315 insn->where = 0;
2316 for (i = 0; i < ARRAY_SIZE (insn->fixp); i++)
2317 insn->fixp[i] = NULL;
2318 insn->fixed_p = (mips_opts.noreorder > 0);
2319 insn->noreorder_p = (mips_opts.noreorder > 0);
2320 insn->mips16_absolute_jump_p = 0;
2321 insn->complete_p = 0;
2322 insn->cleared_p = 0;
2325 /* Get a list of all the operands in INSN. */
2327 static const struct mips_operand_array *
2328 insn_operands (const struct mips_cl_insn *insn)
2330 if (insn->insn_mo >= &mips_opcodes[0]
2331 && insn->insn_mo < &mips_opcodes[NUMOPCODES])
2332 return &mips_operands[insn->insn_mo - &mips_opcodes[0]];
2334 if (insn->insn_mo >= &mips16_opcodes[0]
2335 && insn->insn_mo < &mips16_opcodes[bfd_mips16_num_opcodes])
2336 return &mips16_operands[insn->insn_mo - &mips16_opcodes[0]];
2338 if (insn->insn_mo >= &micromips_opcodes[0]
2339 && insn->insn_mo < &micromips_opcodes[bfd_micromips_num_opcodes])
2340 return &micromips_operands[insn->insn_mo - &micromips_opcodes[0]];
2342 abort ();
2345 /* Get a description of operand OPNO of INSN. */
2347 static const struct mips_operand *
2348 insn_opno (const struct mips_cl_insn *insn, unsigned opno)
2350 const struct mips_operand_array *operands;
2352 operands = insn_operands (insn);
2353 if (opno >= MAX_OPERANDS || !operands->operand[opno])
2354 abort ();
2355 return operands->operand[opno];
2358 /* Install UVAL as the value of OPERAND in INSN. */
2360 static inline void
2361 insn_insert_operand (struct mips_cl_insn *insn,
2362 const struct mips_operand *operand, unsigned int uval)
2364 if (mips_opts.mips16
2365 && operand->type == OP_INT && operand->lsb == 0
2366 && mips_opcode_32bit_p (insn->insn_mo))
2367 insn->insn_opcode |= mips16_immed_extend (uval, operand->size);
2368 else
2369 insn->insn_opcode = mips_insert_operand (operand, insn->insn_opcode, uval);
2372 /* Extract the value of OPERAND from INSN. */
2374 static inline unsigned
2375 insn_extract_operand (const struct mips_cl_insn *insn,
2376 const struct mips_operand *operand)
2378 return mips_extract_operand (operand, insn->insn_opcode);
2381 /* Record the current MIPS16/microMIPS mode in now_seg. */
2383 static void
2384 mips_record_compressed_mode (void)
2386 segment_info_type *si;
2388 si = seg_info (now_seg);
2389 if (si->tc_segment_info_data.mips16 != mips_opts.mips16)
2390 si->tc_segment_info_data.mips16 = mips_opts.mips16;
2391 if (si->tc_segment_info_data.micromips != mips_opts.micromips)
2392 si->tc_segment_info_data.micromips = mips_opts.micromips;
2395 /* Read a standard MIPS instruction from BUF. */
2397 static unsigned long
2398 read_insn (char *buf)
2400 if (target_big_endian)
2401 return bfd_getb32 ((bfd_byte *) buf);
2402 else
2403 return bfd_getl32 ((bfd_byte *) buf);
2406 /* Write standard MIPS instruction INSN to BUF. Return a pointer to
2407 the next byte. */
2409 static char *
2410 write_insn (char *buf, unsigned int insn)
2412 md_number_to_chars (buf, insn, 4);
2413 return buf + 4;
2416 /* Read a microMIPS or MIPS16 opcode from BUF, given that it
2417 has length LENGTH. */
2419 static unsigned long
2420 read_compressed_insn (char *buf, unsigned int length)
2422 unsigned long insn;
2423 unsigned int i;
2425 insn = 0;
2426 for (i = 0; i < length; i += 2)
2428 insn <<= 16;
2429 if (target_big_endian)
2430 insn |= bfd_getb16 ((char *) buf);
2431 else
2432 insn |= bfd_getl16 ((char *) buf);
2433 buf += 2;
2435 return insn;
2438 /* Write microMIPS or MIPS16 instruction INSN to BUF, given that the
2439 instruction is LENGTH bytes long. Return a pointer to the next byte. */
2441 static char *
2442 write_compressed_insn (char *buf, unsigned int insn, unsigned int length)
2444 unsigned int i;
2446 for (i = 0; i < length; i += 2)
2447 md_number_to_chars (buf + i, insn >> ((length - i - 2) * 8), 2);
2448 return buf + length;
2451 /* Install INSN at the location specified by its "frag" and "where" fields. */
2453 static void
2454 install_insn (const struct mips_cl_insn *insn)
2456 char *f = insn->frag->fr_literal + insn->where;
2457 if (HAVE_CODE_COMPRESSION)
2458 write_compressed_insn (f, insn->insn_opcode, insn_length (insn));
2459 else
2460 write_insn (f, insn->insn_opcode);
2461 mips_record_compressed_mode ();
2464 /* Move INSN to offset WHERE in FRAG. Adjust the fixups accordingly
2465 and install the opcode in the new location. */
2467 static void
2468 move_insn (struct mips_cl_insn *insn, fragS *frag, long where)
2470 size_t i;
2472 insn->frag = frag;
2473 insn->where = where;
2474 for (i = 0; i < ARRAY_SIZE (insn->fixp); i++)
2475 if (insn->fixp[i] != NULL)
2477 insn->fixp[i]->fx_frag = frag;
2478 insn->fixp[i]->fx_where = where;
2480 install_insn (insn);
2483 /* Add INSN to the end of the output. */
2485 static void
2486 add_fixed_insn (struct mips_cl_insn *insn)
2488 char *f = frag_more (insn_length (insn));
2489 move_insn (insn, frag_now, f - frag_now->fr_literal);
2492 /* Start a variant frag and move INSN to the start of the variant part,
2493 marking it as fixed. The other arguments are as for frag_var. */
2495 static void
2496 add_relaxed_insn (struct mips_cl_insn *insn, int max_chars, int var,
2497 relax_substateT subtype, symbolS *symbol, offsetT offset)
2499 frag_grow (max_chars);
2500 move_insn (insn, frag_now, frag_more (0) - frag_now->fr_literal);
2501 insn->fixed_p = 1;
2502 frag_var (rs_machine_dependent, max_chars, var,
2503 subtype, symbol, offset, NULL);
2506 /* Insert N copies of INSN into the history buffer, starting at
2507 position FIRST. Neither FIRST nor N need to be clipped. */
2509 static void
2510 insert_into_history (unsigned int first, unsigned int n,
2511 const struct mips_cl_insn *insn)
2513 if (mips_relax.sequence != 2)
2515 unsigned int i;
2517 for (i = ARRAY_SIZE (history); i-- > first;)
2518 if (i >= first + n)
2519 history[i] = history[i - n];
2520 else
2521 history[i] = *insn;
2525 /* Clear the error in insn_error. */
2527 static void
2528 clear_insn_error (void)
2530 memset (&insn_error, 0, sizeof (insn_error));
2533 /* Possibly record error message MSG for the current instruction.
2534 If the error is about a particular argument, ARGNUM is the 1-based
2535 number of that argument, otherwise it is 0. FORMAT is the format
2536 of MSG. Return true if MSG was used, false if the current message
2537 was kept. */
2539 static bfd_boolean
2540 set_insn_error_format (int argnum, enum mips_insn_error_format format,
2541 const char *msg)
2543 if (argnum == 0)
2545 /* Give priority to errors against specific arguments, and to
2546 the first whole-instruction message. */
2547 if (insn_error.msg)
2548 return FALSE;
2550 else
2552 /* Keep insn_error if it is against a later argument. */
2553 if (argnum < insn_error.min_argnum)
2554 return FALSE;
2556 /* If both errors are against the same argument but are different,
2557 give up on reporting a specific error for this argument.
2558 See the comment about mips_insn_error for details. */
2559 if (argnum == insn_error.min_argnum
2560 && insn_error.msg
2561 && strcmp (insn_error.msg, msg) != 0)
2563 insn_error.msg = 0;
2564 insn_error.min_argnum += 1;
2565 return FALSE;
2568 insn_error.min_argnum = argnum;
2569 insn_error.format = format;
2570 insn_error.msg = msg;
2571 return TRUE;
2574 /* Record an instruction error with no % format fields. ARGNUM and MSG are
2575 as for set_insn_error_format. */
2577 static void
2578 set_insn_error (int argnum, const char *msg)
2580 set_insn_error_format (argnum, ERR_FMT_PLAIN, msg);
2583 /* Record an instruction error with one %d field I. ARGNUM and MSG are
2584 as for set_insn_error_format. */
2586 static void
2587 set_insn_error_i (int argnum, const char *msg, int i)
2589 if (set_insn_error_format (argnum, ERR_FMT_I, msg))
2590 insn_error.u.i = i;
2593 /* Record an instruction error with two %s fields S1 and S2. ARGNUM and MSG
2594 are as for set_insn_error_format. */
2596 static void
2597 set_insn_error_ss (int argnum, const char *msg, const char *s1, const char *s2)
2599 if (set_insn_error_format (argnum, ERR_FMT_SS, msg))
2601 insn_error.u.ss[0] = s1;
2602 insn_error.u.ss[1] = s2;
2606 /* Report the error in insn_error, which is against assembly code STR. */
2608 static void
2609 report_insn_error (const char *str)
2611 const char *msg = concat (insn_error.msg, " `%s'", NULL);
2613 switch (insn_error.format)
2615 case ERR_FMT_PLAIN:
2616 as_bad (msg, str);
2617 break;
2619 case ERR_FMT_I:
2620 as_bad (msg, insn_error.u.i, str);
2621 break;
2623 case ERR_FMT_SS:
2624 as_bad (msg, insn_error.u.ss[0], insn_error.u.ss[1], str);
2625 break;
2628 free ((char *) msg);
2631 /* Initialize vr4120_conflicts. There is a bit of duplication here:
2632 the idea is to make it obvious at a glance that each errata is
2633 included. */
2635 static void
2636 init_vr4120_conflicts (void)
2638 #define CONFLICT(FIRST, SECOND) \
2639 vr4120_conflicts[FIX_VR4120_##FIRST] |= 1 << FIX_VR4120_##SECOND
2641 /* Errata 21 - [D]DIV[U] after [D]MACC */
2642 CONFLICT (MACC, DIV);
2643 CONFLICT (DMACC, DIV);
2645 /* Errata 23 - Continuous DMULT[U]/DMACC instructions. */
2646 CONFLICT (DMULT, DMULT);
2647 CONFLICT (DMULT, DMACC);
2648 CONFLICT (DMACC, DMULT);
2649 CONFLICT (DMACC, DMACC);
2651 /* Errata 24 - MT{LO,HI} after [D]MACC */
2652 CONFLICT (MACC, MTHILO);
2653 CONFLICT (DMACC, MTHILO);
2655 /* VR4181A errata MD(1): "If a MULT, MULTU, DMULT or DMULTU
2656 instruction is executed immediately after a MACC or DMACC
2657 instruction, the result of [either instruction] is incorrect." */
2658 CONFLICT (MACC, MULT);
2659 CONFLICT (MACC, DMULT);
2660 CONFLICT (DMACC, MULT);
2661 CONFLICT (DMACC, DMULT);
2663 /* VR4181A errata MD(4): "If a MACC or DMACC instruction is
2664 executed immediately after a DMULT, DMULTU, DIV, DIVU,
2665 DDIV or DDIVU instruction, the result of the MACC or
2666 DMACC instruction is incorrect.". */
2667 CONFLICT (DMULT, MACC);
2668 CONFLICT (DMULT, DMACC);
2669 CONFLICT (DIV, MACC);
2670 CONFLICT (DIV, DMACC);
2672 #undef CONFLICT
2675 struct regname {
2676 const char *name;
2677 unsigned int num;
2680 #define RNUM_MASK 0x00000ff
2681 #define RTYPE_MASK 0x0ffff00
2682 #define RTYPE_NUM 0x0000100
2683 #define RTYPE_FPU 0x0000200
2684 #define RTYPE_FCC 0x0000400
2685 #define RTYPE_VEC 0x0000800
2686 #define RTYPE_GP 0x0001000
2687 #define RTYPE_CP0 0x0002000
2688 #define RTYPE_PC 0x0004000
2689 #define RTYPE_ACC 0x0008000
2690 #define RTYPE_CCC 0x0010000
2691 #define RTYPE_VI 0x0020000
2692 #define RTYPE_VF 0x0040000
2693 #define RTYPE_R5900_I 0x0080000
2694 #define RTYPE_R5900_Q 0x0100000
2695 #define RTYPE_R5900_R 0x0200000
2696 #define RTYPE_R5900_ACC 0x0400000
2697 #define RTYPE_MSA 0x0800000
2698 #define RWARN 0x8000000
2700 #define GENERIC_REGISTER_NUMBERS \
2701 {"$0", RTYPE_NUM | 0}, \
2702 {"$1", RTYPE_NUM | 1}, \
2703 {"$2", RTYPE_NUM | 2}, \
2704 {"$3", RTYPE_NUM | 3}, \
2705 {"$4", RTYPE_NUM | 4}, \
2706 {"$5", RTYPE_NUM | 5}, \
2707 {"$6", RTYPE_NUM | 6}, \
2708 {"$7", RTYPE_NUM | 7}, \
2709 {"$8", RTYPE_NUM | 8}, \
2710 {"$9", RTYPE_NUM | 9}, \
2711 {"$10", RTYPE_NUM | 10}, \
2712 {"$11", RTYPE_NUM | 11}, \
2713 {"$12", RTYPE_NUM | 12}, \
2714 {"$13", RTYPE_NUM | 13}, \
2715 {"$14", RTYPE_NUM | 14}, \
2716 {"$15", RTYPE_NUM | 15}, \
2717 {"$16", RTYPE_NUM | 16}, \
2718 {"$17", RTYPE_NUM | 17}, \
2719 {"$18", RTYPE_NUM | 18}, \
2720 {"$19", RTYPE_NUM | 19}, \
2721 {"$20", RTYPE_NUM | 20}, \
2722 {"$21", RTYPE_NUM | 21}, \
2723 {"$22", RTYPE_NUM | 22}, \
2724 {"$23", RTYPE_NUM | 23}, \
2725 {"$24", RTYPE_NUM | 24}, \
2726 {"$25", RTYPE_NUM | 25}, \
2727 {"$26", RTYPE_NUM | 26}, \
2728 {"$27", RTYPE_NUM | 27}, \
2729 {"$28", RTYPE_NUM | 28}, \
2730 {"$29", RTYPE_NUM | 29}, \
2731 {"$30", RTYPE_NUM | 30}, \
2732 {"$31", RTYPE_NUM | 31}
2734 #define FPU_REGISTER_NAMES \
2735 {"$f0", RTYPE_FPU | 0}, \
2736 {"$f1", RTYPE_FPU | 1}, \
2737 {"$f2", RTYPE_FPU | 2}, \
2738 {"$f3", RTYPE_FPU | 3}, \
2739 {"$f4", RTYPE_FPU | 4}, \
2740 {"$f5", RTYPE_FPU | 5}, \
2741 {"$f6", RTYPE_FPU | 6}, \
2742 {"$f7", RTYPE_FPU | 7}, \
2743 {"$f8", RTYPE_FPU | 8}, \
2744 {"$f9", RTYPE_FPU | 9}, \
2745 {"$f10", RTYPE_FPU | 10}, \
2746 {"$f11", RTYPE_FPU | 11}, \
2747 {"$f12", RTYPE_FPU | 12}, \
2748 {"$f13", RTYPE_FPU | 13}, \
2749 {"$f14", RTYPE_FPU | 14}, \
2750 {"$f15", RTYPE_FPU | 15}, \
2751 {"$f16", RTYPE_FPU | 16}, \
2752 {"$f17", RTYPE_FPU | 17}, \
2753 {"$f18", RTYPE_FPU | 18}, \
2754 {"$f19", RTYPE_FPU | 19}, \
2755 {"$f20", RTYPE_FPU | 20}, \
2756 {"$f21", RTYPE_FPU | 21}, \
2757 {"$f22", RTYPE_FPU | 22}, \
2758 {"$f23", RTYPE_FPU | 23}, \
2759 {"$f24", RTYPE_FPU | 24}, \
2760 {"$f25", RTYPE_FPU | 25}, \
2761 {"$f26", RTYPE_FPU | 26}, \
2762 {"$f27", RTYPE_FPU | 27}, \
2763 {"$f28", RTYPE_FPU | 28}, \
2764 {"$f29", RTYPE_FPU | 29}, \
2765 {"$f30", RTYPE_FPU | 30}, \
2766 {"$f31", RTYPE_FPU | 31}
2768 #define FPU_CONDITION_CODE_NAMES \
2769 {"$fcc0", RTYPE_FCC | 0}, \
2770 {"$fcc1", RTYPE_FCC | 1}, \
2771 {"$fcc2", RTYPE_FCC | 2}, \
2772 {"$fcc3", RTYPE_FCC | 3}, \
2773 {"$fcc4", RTYPE_FCC | 4}, \
2774 {"$fcc5", RTYPE_FCC | 5}, \
2775 {"$fcc6", RTYPE_FCC | 6}, \
2776 {"$fcc7", RTYPE_FCC | 7}
2778 #define COPROC_CONDITION_CODE_NAMES \
2779 {"$cc0", RTYPE_FCC | RTYPE_CCC | 0}, \
2780 {"$cc1", RTYPE_FCC | RTYPE_CCC | 1}, \
2781 {"$cc2", RTYPE_FCC | RTYPE_CCC | 2}, \
2782 {"$cc3", RTYPE_FCC | RTYPE_CCC | 3}, \
2783 {"$cc4", RTYPE_FCC | RTYPE_CCC | 4}, \
2784 {"$cc5", RTYPE_FCC | RTYPE_CCC | 5}, \
2785 {"$cc6", RTYPE_FCC | RTYPE_CCC | 6}, \
2786 {"$cc7", RTYPE_FCC | RTYPE_CCC | 7}
2788 #define N32N64_SYMBOLIC_REGISTER_NAMES \
2789 {"$a4", RTYPE_GP | 8}, \
2790 {"$a5", RTYPE_GP | 9}, \
2791 {"$a6", RTYPE_GP | 10}, \
2792 {"$a7", RTYPE_GP | 11}, \
2793 {"$ta0", RTYPE_GP | 8}, /* alias for $a4 */ \
2794 {"$ta1", RTYPE_GP | 9}, /* alias for $a5 */ \
2795 {"$ta2", RTYPE_GP | 10}, /* alias for $a6 */ \
2796 {"$ta3", RTYPE_GP | 11}, /* alias for $a7 */ \
2797 {"$t0", RTYPE_GP | 12}, \
2798 {"$t1", RTYPE_GP | 13}, \
2799 {"$t2", RTYPE_GP | 14}, \
2800 {"$t3", RTYPE_GP | 15}
2802 #define O32_SYMBOLIC_REGISTER_NAMES \
2803 {"$t0", RTYPE_GP | 8}, \
2804 {"$t1", RTYPE_GP | 9}, \
2805 {"$t2", RTYPE_GP | 10}, \
2806 {"$t3", RTYPE_GP | 11}, \
2807 {"$t4", RTYPE_GP | 12}, \
2808 {"$t5", RTYPE_GP | 13}, \
2809 {"$t6", RTYPE_GP | 14}, \
2810 {"$t7", RTYPE_GP | 15}, \
2811 {"$ta0", RTYPE_GP | 12}, /* alias for $t4 */ \
2812 {"$ta1", RTYPE_GP | 13}, /* alias for $t5 */ \
2813 {"$ta2", RTYPE_GP | 14}, /* alias for $t6 */ \
2814 {"$ta3", RTYPE_GP | 15} /* alias for $t7 */
2816 /* Remaining symbolic register names. */
2817 #define SYMBOLIC_REGISTER_NAMES \
2818 {"$zero", RTYPE_GP | 0}, \
2819 {"$at", RTYPE_GP | 1}, \
2820 {"$AT", RTYPE_GP | 1}, \
2821 {"$v0", RTYPE_GP | 2}, \
2822 {"$v1", RTYPE_GP | 3}, \
2823 {"$a0", RTYPE_GP | 4}, \
2824 {"$a1", RTYPE_GP | 5}, \
2825 {"$a2", RTYPE_GP | 6}, \
2826 {"$a3", RTYPE_GP | 7}, \
2827 {"$s0", RTYPE_GP | 16}, \
2828 {"$s1", RTYPE_GP | 17}, \
2829 {"$s2", RTYPE_GP | 18}, \
2830 {"$s3", RTYPE_GP | 19}, \
2831 {"$s4", RTYPE_GP | 20}, \
2832 {"$s5", RTYPE_GP | 21}, \
2833 {"$s6", RTYPE_GP | 22}, \
2834 {"$s7", RTYPE_GP | 23}, \
2835 {"$t8", RTYPE_GP | 24}, \
2836 {"$t9", RTYPE_GP | 25}, \
2837 {"$k0", RTYPE_GP | 26}, \
2838 {"$kt0", RTYPE_GP | 26}, \
2839 {"$k1", RTYPE_GP | 27}, \
2840 {"$kt1", RTYPE_GP | 27}, \
2841 {"$gp", RTYPE_GP | 28}, \
2842 {"$sp", RTYPE_GP | 29}, \
2843 {"$s8", RTYPE_GP | 30}, \
2844 {"$fp", RTYPE_GP | 30}, \
2845 {"$ra", RTYPE_GP | 31}
2847 #define MIPS16_SPECIAL_REGISTER_NAMES \
2848 {"$pc", RTYPE_PC | 0}
2850 #define MDMX_VECTOR_REGISTER_NAMES \
2851 /* {"$v0", RTYPE_VEC | 0}, Clash with REG 2 above. */ \
2852 /* {"$v1", RTYPE_VEC | 1}, Clash with REG 3 above. */ \
2853 {"$v2", RTYPE_VEC | 2}, \
2854 {"$v3", RTYPE_VEC | 3}, \
2855 {"$v4", RTYPE_VEC | 4}, \
2856 {"$v5", RTYPE_VEC | 5}, \
2857 {"$v6", RTYPE_VEC | 6}, \
2858 {"$v7", RTYPE_VEC | 7}, \
2859 {"$v8", RTYPE_VEC | 8}, \
2860 {"$v9", RTYPE_VEC | 9}, \
2861 {"$v10", RTYPE_VEC | 10}, \
2862 {"$v11", RTYPE_VEC | 11}, \
2863 {"$v12", RTYPE_VEC | 12}, \
2864 {"$v13", RTYPE_VEC | 13}, \
2865 {"$v14", RTYPE_VEC | 14}, \
2866 {"$v15", RTYPE_VEC | 15}, \
2867 {"$v16", RTYPE_VEC | 16}, \
2868 {"$v17", RTYPE_VEC | 17}, \
2869 {"$v18", RTYPE_VEC | 18}, \
2870 {"$v19", RTYPE_VEC | 19}, \
2871 {"$v20", RTYPE_VEC | 20}, \
2872 {"$v21", RTYPE_VEC | 21}, \
2873 {"$v22", RTYPE_VEC | 22}, \
2874 {"$v23", RTYPE_VEC | 23}, \
2875 {"$v24", RTYPE_VEC | 24}, \
2876 {"$v25", RTYPE_VEC | 25}, \
2877 {"$v26", RTYPE_VEC | 26}, \
2878 {"$v27", RTYPE_VEC | 27}, \
2879 {"$v28", RTYPE_VEC | 28}, \
2880 {"$v29", RTYPE_VEC | 29}, \
2881 {"$v30", RTYPE_VEC | 30}, \
2882 {"$v31", RTYPE_VEC | 31}
2884 #define R5900_I_NAMES \
2885 {"$I", RTYPE_R5900_I | 0}
2887 #define R5900_Q_NAMES \
2888 {"$Q", RTYPE_R5900_Q | 0}
2890 #define R5900_R_NAMES \
2891 {"$R", RTYPE_R5900_R | 0}
2893 #define R5900_ACC_NAMES \
2894 {"$ACC", RTYPE_R5900_ACC | 0 }
2896 #define MIPS_DSP_ACCUMULATOR_NAMES \
2897 {"$ac0", RTYPE_ACC | 0}, \
2898 {"$ac1", RTYPE_ACC | 1}, \
2899 {"$ac2", RTYPE_ACC | 2}, \
2900 {"$ac3", RTYPE_ACC | 3}
2902 static const struct regname reg_names[] = {
2903 GENERIC_REGISTER_NUMBERS,
2904 FPU_REGISTER_NAMES,
2905 FPU_CONDITION_CODE_NAMES,
2906 COPROC_CONDITION_CODE_NAMES,
2908 /* The $txx registers depends on the abi,
2909 these will be added later into the symbol table from
2910 one of the tables below once mips_abi is set after
2911 parsing of arguments from the command line. */
2912 SYMBOLIC_REGISTER_NAMES,
2914 MIPS16_SPECIAL_REGISTER_NAMES,
2915 MDMX_VECTOR_REGISTER_NAMES,
2916 R5900_I_NAMES,
2917 R5900_Q_NAMES,
2918 R5900_R_NAMES,
2919 R5900_ACC_NAMES,
2920 MIPS_DSP_ACCUMULATOR_NAMES,
2921 {0, 0}
2924 static const struct regname reg_names_o32[] = {
2925 O32_SYMBOLIC_REGISTER_NAMES,
2926 {0, 0}
2929 static const struct regname reg_names_n32n64[] = {
2930 N32N64_SYMBOLIC_REGISTER_NAMES,
2931 {0, 0}
2934 /* Register symbols $v0 and $v1 map to GPRs 2 and 3, but they can also be
2935 interpreted as vector registers 0 and 1. If SYMVAL is the value of one
2936 of these register symbols, return the associated vector register,
2937 otherwise return SYMVAL itself. */
2939 static unsigned int
2940 mips_prefer_vec_regno (unsigned int symval)
2942 if ((symval & -2) == (RTYPE_GP | 2))
2943 return RTYPE_VEC | (symval & 1);
2944 return symval;
2947 /* Return true if string [S, E) is a valid register name, storing its
2948 symbol value in *SYMVAL_PTR if so. */
2950 static bfd_boolean
2951 mips_parse_register_1 (char *s, char *e, unsigned int *symval_ptr)
2953 char save_c;
2954 symbolS *symbol;
2956 /* Terminate name. */
2957 save_c = *e;
2958 *e = '\0';
2960 /* Look up the name. */
2961 symbol = symbol_find (s);
2962 *e = save_c;
2964 if (!symbol || S_GET_SEGMENT (symbol) != reg_section)
2965 return FALSE;
2967 *symval_ptr = S_GET_VALUE (symbol);
2968 return TRUE;
2971 /* Return true if the string at *SPTR is a valid register name. Allow it
2972 to have a VU0-style channel suffix of the form x?y?z?w? if CHANNELS_PTR
2973 is nonnull.
2975 When returning true, move *SPTR past the register, store the
2976 register's symbol value in *SYMVAL_PTR and the channel mask in
2977 *CHANNELS_PTR (if nonnull). The symbol value includes the register
2978 number (RNUM_MASK) and register type (RTYPE_MASK). The channel mask
2979 is a 4-bit value of the form XYZW and is 0 if no suffix was given. */
2981 static bfd_boolean
2982 mips_parse_register (char **sptr, unsigned int *symval_ptr,
2983 unsigned int *channels_ptr)
2985 char *s, *e, *m;
2986 const char *q;
2987 unsigned int channels, symval, bit;
2989 /* Find end of name. */
2990 s = e = *sptr;
2991 if (is_name_beginner (*e))
2992 ++e;
2993 while (is_part_of_name (*e))
2994 ++e;
2996 channels = 0;
2997 if (!mips_parse_register_1 (s, e, &symval))
2999 if (!channels_ptr)
3000 return FALSE;
3002 /* Eat characters from the end of the string that are valid
3003 channel suffixes. The preceding register must be $ACC or
3004 end with a digit, so there is no ambiguity. */
3005 bit = 1;
3006 m = e;
3007 for (q = "wzyx"; *q; q++, bit <<= 1)
3008 if (m > s && m[-1] == *q)
3010 --m;
3011 channels |= bit;
3014 if (channels == 0
3015 || !mips_parse_register_1 (s, m, &symval)
3016 || (symval & (RTYPE_VI | RTYPE_VF | RTYPE_R5900_ACC)) == 0)
3017 return FALSE;
3020 *sptr = e;
3021 *symval_ptr = symval;
3022 if (channels_ptr)
3023 *channels_ptr = channels;
3024 return TRUE;
3027 /* Check if SPTR points at a valid register specifier according to TYPES.
3028 If so, then return 1, advance S to consume the specifier and store
3029 the register's number in REGNOP, otherwise return 0. */
3031 static int
3032 reg_lookup (char **s, unsigned int types, unsigned int *regnop)
3034 unsigned int regno;
3036 if (mips_parse_register (s, &regno, NULL))
3038 if (types & RTYPE_VEC)
3039 regno = mips_prefer_vec_regno (regno);
3040 if (regno & types)
3041 regno &= RNUM_MASK;
3042 else
3043 regno = ~0;
3045 else
3047 if (types & RWARN)
3048 as_warn (_("unrecognized register name `%s'"), *s);
3049 regno = ~0;
3051 if (regnop)
3052 *regnop = regno;
3053 return regno <= RNUM_MASK;
3056 /* Parse a VU0 "x?y?z?w?" channel mask at S and store the associated
3057 mask in *CHANNELS. Return a pointer to the first unconsumed character. */
3059 static char *
3060 mips_parse_vu0_channels (char *s, unsigned int *channels)
3062 unsigned int i;
3064 *channels = 0;
3065 for (i = 0; i < 4; i++)
3066 if (*s == "xyzw"[i])
3068 *channels |= 1 << (3 - i);
3069 ++s;
3071 return s;
3074 /* Token types for parsed operand lists. */
3075 enum mips_operand_token_type {
3076 /* A plain register, e.g. $f2. */
3077 OT_REG,
3079 /* A 4-bit XYZW channel mask. */
3080 OT_CHANNELS,
3082 /* A constant vector index, e.g. [1]. */
3083 OT_INTEGER_INDEX,
3085 /* A register vector index, e.g. [$2]. */
3086 OT_REG_INDEX,
3088 /* A continuous range of registers, e.g. $s0-$s4. */
3089 OT_REG_RANGE,
3091 /* A (possibly relocated) expression. */
3092 OT_INTEGER,
3094 /* A floating-point value. */
3095 OT_FLOAT,
3097 /* A single character. This can be '(', ')' or ',', but '(' only appears
3098 before OT_REGs. */
3099 OT_CHAR,
3101 /* A doubled character, either "--" or "++". */
3102 OT_DOUBLE_CHAR,
3104 /* The end of the operand list. */
3105 OT_END
3108 /* A parsed operand token. */
3109 struct mips_operand_token
3111 /* The type of token. */
3112 enum mips_operand_token_type type;
3113 union
3115 /* The register symbol value for an OT_REG or OT_REG_INDEX. */
3116 unsigned int regno;
3118 /* The 4-bit channel mask for an OT_CHANNEL_SUFFIX. */
3119 unsigned int channels;
3121 /* The integer value of an OT_INTEGER_INDEX. */
3122 addressT index;
3124 /* The two register symbol values involved in an OT_REG_RANGE. */
3125 struct {
3126 unsigned int regno1;
3127 unsigned int regno2;
3128 } reg_range;
3130 /* The value of an OT_INTEGER. The value is represented as an
3131 expression and the relocation operators that were applied to
3132 that expression. The reloc entries are BFD_RELOC_UNUSED if no
3133 relocation operators were used. */
3134 struct {
3135 expressionS value;
3136 bfd_reloc_code_real_type relocs[3];
3137 } integer;
3139 /* The binary data for an OT_FLOAT constant, and the number of bytes
3140 in the constant. */
3141 struct {
3142 unsigned char data[8];
3143 int length;
3144 } flt;
3146 /* The character represented by an OT_CHAR or OT_DOUBLE_CHAR. */
3147 char ch;
3148 } u;
3151 /* An obstack used to construct lists of mips_operand_tokens. */
3152 static struct obstack mips_operand_tokens;
3154 /* Give TOKEN type TYPE and add it to mips_operand_tokens. */
3156 static void
3157 mips_add_token (struct mips_operand_token *token,
3158 enum mips_operand_token_type type)
3160 token->type = type;
3161 obstack_grow (&mips_operand_tokens, token, sizeof (*token));
3164 /* Check whether S is '(' followed by a register name. Add OT_CHAR
3165 and OT_REG tokens for them if so, and return a pointer to the first
3166 unconsumed character. Return null otherwise. */
3168 static char *
3169 mips_parse_base_start (char *s)
3171 struct mips_operand_token token;
3172 unsigned int regno, channels;
3173 bfd_boolean decrement_p;
3175 if (*s != '(')
3176 return 0;
3178 ++s;
3179 SKIP_SPACE_TABS (s);
3181 /* Only match "--" as part of a base expression. In other contexts "--X"
3182 is a double negative. */
3183 decrement_p = (s[0] == '-' && s[1] == '-');
3184 if (decrement_p)
3186 s += 2;
3187 SKIP_SPACE_TABS (s);
3190 /* Allow a channel specifier because that leads to better error messages
3191 than treating something like "$vf0x++" as an expression. */
3192 if (!mips_parse_register (&s, &regno, &channels))
3193 return 0;
3195 token.u.ch = '(';
3196 mips_add_token (&token, OT_CHAR);
3198 if (decrement_p)
3200 token.u.ch = '-';
3201 mips_add_token (&token, OT_DOUBLE_CHAR);
3204 token.u.regno = regno;
3205 mips_add_token (&token, OT_REG);
3207 if (channels)
3209 token.u.channels = channels;
3210 mips_add_token (&token, OT_CHANNELS);
3213 /* For consistency, only match "++" as part of base expressions too. */
3214 SKIP_SPACE_TABS (s);
3215 if (s[0] == '+' && s[1] == '+')
3217 s += 2;
3218 token.u.ch = '+';
3219 mips_add_token (&token, OT_DOUBLE_CHAR);
3222 return s;
3225 /* Parse one or more tokens from S. Return a pointer to the first
3226 unconsumed character on success. Return null if an error was found
3227 and store the error text in insn_error. FLOAT_FORMAT is as for
3228 mips_parse_arguments. */
3230 static char *
3231 mips_parse_argument_token (char *s, char float_format)
3233 char *end, *save_in;
3234 const char *err;
3235 unsigned int regno1, regno2, channels;
3236 struct mips_operand_token token;
3238 /* First look for "($reg", since we want to treat that as an
3239 OT_CHAR and OT_REG rather than an expression. */
3240 end = mips_parse_base_start (s);
3241 if (end)
3242 return end;
3244 /* Handle other characters that end up as OT_CHARs. */
3245 if (*s == ')' || *s == ',')
3247 token.u.ch = *s;
3248 mips_add_token (&token, OT_CHAR);
3249 ++s;
3250 return s;
3253 /* Handle tokens that start with a register. */
3254 if (mips_parse_register (&s, &regno1, &channels))
3256 if (channels)
3258 /* A register and a VU0 channel suffix. */
3259 token.u.regno = regno1;
3260 mips_add_token (&token, OT_REG);
3262 token.u.channels = channels;
3263 mips_add_token (&token, OT_CHANNELS);
3264 return s;
3267 SKIP_SPACE_TABS (s);
3268 if (*s == '-')
3270 /* A register range. */
3271 ++s;
3272 SKIP_SPACE_TABS (s);
3273 if (!mips_parse_register (&s, &regno2, NULL))
3275 set_insn_error (0, _("invalid register range"));
3276 return 0;
3279 token.u.reg_range.regno1 = regno1;
3280 token.u.reg_range.regno2 = regno2;
3281 mips_add_token (&token, OT_REG_RANGE);
3282 return s;
3285 /* Add the register itself. */
3286 token.u.regno = regno1;
3287 mips_add_token (&token, OT_REG);
3289 /* Check for a vector index. */
3290 if (*s == '[')
3292 ++s;
3293 SKIP_SPACE_TABS (s);
3294 if (mips_parse_register (&s, &token.u.regno, NULL))
3295 mips_add_token (&token, OT_REG_INDEX);
3296 else
3298 expressionS element;
3300 my_getExpression (&element, s);
3301 if (element.X_op != O_constant)
3303 set_insn_error (0, _("vector element must be constant"));
3304 return 0;
3306 s = expr_end;
3307 token.u.index = element.X_add_number;
3308 mips_add_token (&token, OT_INTEGER_INDEX);
3310 SKIP_SPACE_TABS (s);
3311 if (*s != ']')
3313 set_insn_error (0, _("missing `]'"));
3314 return 0;
3316 ++s;
3318 return s;
3321 if (float_format)
3323 /* First try to treat expressions as floats. */
3324 save_in = input_line_pointer;
3325 input_line_pointer = s;
3326 err = md_atof (float_format, (char *) token.u.flt.data,
3327 &token.u.flt.length);
3328 end = input_line_pointer;
3329 input_line_pointer = save_in;
3330 if (err && *err)
3332 set_insn_error (0, err);
3333 return 0;
3335 if (s != end)
3337 mips_add_token (&token, OT_FLOAT);
3338 return end;
3342 /* Treat everything else as an integer expression. */
3343 token.u.integer.relocs[0] = BFD_RELOC_UNUSED;
3344 token.u.integer.relocs[1] = BFD_RELOC_UNUSED;
3345 token.u.integer.relocs[2] = BFD_RELOC_UNUSED;
3346 my_getSmallExpression (&token.u.integer.value, token.u.integer.relocs, s);
3347 s = expr_end;
3348 mips_add_token (&token, OT_INTEGER);
3349 return s;
3352 /* S points to the operand list for an instruction. FLOAT_FORMAT is 'f'
3353 if expressions should be treated as 32-bit floating-point constants,
3354 'd' if they should be treated as 64-bit floating-point constants,
3355 or 0 if they should be treated as integer expressions (the usual case).
3357 Return a list of tokens on success, otherwise return 0. The caller
3358 must obstack_free the list after use. */
3360 static struct mips_operand_token *
3361 mips_parse_arguments (char *s, char float_format)
3363 struct mips_operand_token token;
3365 SKIP_SPACE_TABS (s);
3366 while (*s)
3368 s = mips_parse_argument_token (s, float_format);
3369 if (!s)
3371 obstack_free (&mips_operand_tokens,
3372 obstack_finish (&mips_operand_tokens));
3373 return 0;
3375 SKIP_SPACE_TABS (s);
3377 mips_add_token (&token, OT_END);
3378 return (struct mips_operand_token *) obstack_finish (&mips_operand_tokens);
3381 /* Return TRUE if opcode MO is valid on the currently selected ISA, ASE
3382 and architecture. Use is_opcode_valid_16 for MIPS16 opcodes. */
3384 static bfd_boolean
3385 is_opcode_valid (const struct mips_opcode *mo)
3387 int isa = mips_opts.isa;
3388 int ase = mips_opts.ase;
3389 int fp_s, fp_d;
3390 unsigned int i;
3392 if (ISA_HAS_64BIT_REGS (isa))
3393 for (i = 0; i < ARRAY_SIZE (mips_ases); i++)
3394 if ((ase & mips_ases[i].flags) == mips_ases[i].flags)
3395 ase |= mips_ases[i].flags64;
3397 if (!opcode_is_member (mo, isa, ase, mips_opts.arch))
3398 return FALSE;
3400 /* Check whether the instruction or macro requires single-precision or
3401 double-precision floating-point support. Note that this information is
3402 stored differently in the opcode table for insns and macros. */
3403 if (mo->pinfo == INSN_MACRO)
3405 fp_s = mo->pinfo2 & INSN2_M_FP_S;
3406 fp_d = mo->pinfo2 & INSN2_M_FP_D;
3408 else
3410 fp_s = mo->pinfo & FP_S;
3411 fp_d = mo->pinfo & FP_D;
3414 if (fp_d && (mips_opts.soft_float || mips_opts.single_float))
3415 return FALSE;
3417 if (fp_s && mips_opts.soft_float)
3418 return FALSE;
3420 return TRUE;
3423 /* Return TRUE if the MIPS16 opcode MO is valid on the currently
3424 selected ISA and architecture. */
3426 static bfd_boolean
3427 is_opcode_valid_16 (const struct mips_opcode *mo)
3429 int isa = mips_opts.isa;
3430 int ase = mips_opts.ase;
3431 unsigned int i;
3433 if (ISA_HAS_64BIT_REGS (isa))
3434 for (i = 0; i < ARRAY_SIZE (mips_ases); i++)
3435 if ((ase & mips_ases[i].flags) == mips_ases[i].flags)
3436 ase |= mips_ases[i].flags64;
3438 return opcode_is_member (mo, isa, ase, mips_opts.arch);
3441 /* Return TRUE if the size of the microMIPS opcode MO matches one
3442 explicitly requested. Always TRUE in the standard MIPS mode.
3443 Use is_size_valid_16 for MIPS16 opcodes. */
3445 static bfd_boolean
3446 is_size_valid (const struct mips_opcode *mo)
3448 if (!mips_opts.micromips)
3449 return TRUE;
3451 if (mips_opts.insn32)
3453 if (mo->pinfo != INSN_MACRO && micromips_insn_length (mo) != 4)
3454 return FALSE;
3455 if ((mo->pinfo2 & INSN2_BRANCH_DELAY_16BIT) != 0)
3456 return FALSE;
3458 if (!forced_insn_length)
3459 return TRUE;
3460 if (mo->pinfo == INSN_MACRO)
3461 return FALSE;
3462 return forced_insn_length == micromips_insn_length (mo);
3465 /* Return TRUE if the size of the MIPS16 opcode MO matches one
3466 explicitly requested. */
3468 static bfd_boolean
3469 is_size_valid_16 (const struct mips_opcode *mo)
3471 if (!forced_insn_length)
3472 return TRUE;
3473 if (mo->pinfo == INSN_MACRO)
3474 return FALSE;
3475 if (forced_insn_length == 2 && mips_opcode_32bit_p (mo))
3476 return FALSE;
3477 if (forced_insn_length == 4 && (mo->pinfo2 & INSN2_SHORT_ONLY))
3478 return FALSE;
3479 return TRUE;
3482 /* Return TRUE if the microMIPS opcode MO is valid for the delay slot
3483 of the preceding instruction. Always TRUE in the standard MIPS mode.
3485 We don't accept macros in 16-bit delay slots to avoid a case where
3486 a macro expansion fails because it relies on a preceding 32-bit real
3487 instruction to have matched and does not handle the operands correctly.
3488 The only macros that may expand to 16-bit instructions are JAL that
3489 cannot be placed in a delay slot anyway, and corner cases of BALIGN
3490 and BGT (that likewise cannot be placed in a delay slot) that decay to
3491 a NOP. In all these cases the macros precede any corresponding real
3492 instruction definitions in the opcode table, so they will match in the
3493 second pass where the size of the delay slot is ignored and therefore
3494 produce correct code. */
3496 static bfd_boolean
3497 is_delay_slot_valid (const struct mips_opcode *mo)
3499 if (!mips_opts.micromips)
3500 return TRUE;
3502 if (mo->pinfo == INSN_MACRO)
3503 return (history[0].insn_mo->pinfo2 & INSN2_BRANCH_DELAY_16BIT) == 0;
3504 if ((history[0].insn_mo->pinfo2 & INSN2_BRANCH_DELAY_32BIT) != 0
3505 && micromips_insn_length (mo) != 4)
3506 return FALSE;
3507 if ((history[0].insn_mo->pinfo2 & INSN2_BRANCH_DELAY_16BIT) != 0
3508 && micromips_insn_length (mo) != 2)
3509 return FALSE;
3511 return TRUE;
3514 /* For consistency checking, verify that all bits of OPCODE are specified
3515 either by the match/mask part of the instruction definition, or by the
3516 operand list. Also build up a list of operands in OPERANDS.
3518 INSN_BITS says which bits of the instruction are significant.
3519 If OPCODE is a standard or microMIPS instruction, DECODE_OPERAND
3520 provides the mips_operand description of each operand. DECODE_OPERAND
3521 is null for MIPS16 instructions. */
3523 static int
3524 validate_mips_insn (const struct mips_opcode *opcode,
3525 unsigned long insn_bits,
3526 const struct mips_operand *(*decode_operand) (const char *),
3527 struct mips_operand_array *operands)
3529 const char *s;
3530 unsigned long used_bits, doubled, undefined, opno, mask;
3531 const struct mips_operand *operand;
3533 mask = (opcode->pinfo == INSN_MACRO ? 0 : opcode->mask);
3534 if ((mask & opcode->match) != opcode->match)
3536 as_bad (_("internal: bad mips opcode (mask error): %s %s"),
3537 opcode->name, opcode->args);
3538 return 0;
3540 used_bits = 0;
3541 opno = 0;
3542 if (opcode->pinfo2 & INSN2_VU0_CHANNEL_SUFFIX)
3543 used_bits = mips_insert_operand (&mips_vu0_channel_mask, used_bits, -1);
3544 for (s = opcode->args; *s; ++s)
3545 switch (*s)
3547 case ',':
3548 case '(':
3549 case ')':
3550 break;
3552 case '#':
3553 s++;
3554 break;
3556 default:
3557 if (!decode_operand)
3558 operand = decode_mips16_operand (*s, mips_opcode_32bit_p (opcode));
3559 else
3560 operand = decode_operand (s);
3561 if (!operand && opcode->pinfo != INSN_MACRO)
3563 as_bad (_("internal: unknown operand type: %s %s"),
3564 opcode->name, opcode->args);
3565 return 0;
3567 gas_assert (opno < MAX_OPERANDS);
3568 operands->operand[opno] = operand;
3569 if (!decode_operand && operand
3570 && operand->type == OP_INT && operand->lsb == 0
3571 && mips_opcode_32bit_p (opcode))
3572 used_bits |= mips16_immed_extend (-1, operand->size);
3573 else if (operand && operand->type != OP_VU0_MATCH_SUFFIX)
3575 used_bits = mips_insert_operand (operand, used_bits, -1);
3576 if (operand->type == OP_MDMX_IMM_REG)
3577 /* Bit 5 is the format selector (OB vs QH). The opcode table
3578 has separate entries for each format. */
3579 used_bits &= ~(1 << (operand->lsb + 5));
3580 if (operand->type == OP_ENTRY_EXIT_LIST)
3581 used_bits &= ~(mask & 0x700);
3582 /* interAptiv MR2 SAVE/RESTORE instructions have a discontiguous
3583 operand field that cannot be fully described with LSB/SIZE. */
3584 if (operand->type == OP_SAVE_RESTORE_LIST && operand->lsb == 6)
3585 used_bits &= ~0x6000;
3587 /* Skip prefix characters. */
3588 if (decode_operand && (*s == '+' || *s == 'm' || *s == '-'))
3589 ++s;
3590 opno += 1;
3591 break;
3593 doubled = used_bits & mask & insn_bits;
3594 if (doubled)
3596 as_bad (_("internal: bad mips opcode (bits 0x%08lx doubly defined):"
3597 " %s %s"), doubled, opcode->name, opcode->args);
3598 return 0;
3600 used_bits |= mask;
3601 undefined = ~used_bits & insn_bits;
3602 if (opcode->pinfo != INSN_MACRO && undefined)
3604 as_bad (_("internal: bad mips opcode (bits 0x%08lx undefined): %s %s"),
3605 undefined, opcode->name, opcode->args);
3606 return 0;
3608 used_bits &= ~insn_bits;
3609 if (used_bits)
3611 as_bad (_("internal: bad mips opcode (bits 0x%08lx defined): %s %s"),
3612 used_bits, opcode->name, opcode->args);
3613 return 0;
3615 return 1;
3618 /* The MIPS16 version of validate_mips_insn. */
3620 static int
3621 validate_mips16_insn (const struct mips_opcode *opcode,
3622 struct mips_operand_array *operands)
3624 unsigned long insn_bits = mips_opcode_32bit_p (opcode) ? 0xffffffff : 0xffff;
3626 return validate_mips_insn (opcode, insn_bits, 0, operands);
3629 /* The microMIPS version of validate_mips_insn. */
3631 static int
3632 validate_micromips_insn (const struct mips_opcode *opc,
3633 struct mips_operand_array *operands)
3635 unsigned long insn_bits;
3636 unsigned long major;
3637 unsigned int length;
3639 if (opc->pinfo == INSN_MACRO)
3640 return validate_mips_insn (opc, 0xffffffff, decode_micromips_operand,
3641 operands);
3643 length = micromips_insn_length (opc);
3644 if (length != 2 && length != 4)
3646 as_bad (_("internal error: bad microMIPS opcode (incorrect length: %u): "
3647 "%s %s"), length, opc->name, opc->args);
3648 return 0;
3650 major = opc->match >> (10 + 8 * (length - 2));
3651 if ((length == 2 && (major & 7) != 1 && (major & 6) != 2)
3652 || (length == 4 && (major & 7) != 0 && (major & 4) != 4))
3654 as_bad (_("internal error: bad microMIPS opcode "
3655 "(opcode/length mismatch): %s %s"), opc->name, opc->args);
3656 return 0;
3659 /* Shift piecewise to avoid an overflow where unsigned long is 32-bit. */
3660 insn_bits = 1 << 4 * length;
3661 insn_bits <<= 4 * length;
3662 insn_bits -= 1;
3663 return validate_mips_insn (opc, insn_bits, decode_micromips_operand,
3664 operands);
3667 /* This function is called once, at assembler startup time. It should set up
3668 all the tables, etc. that the MD part of the assembler will need. */
3670 void
3671 md_begin (void)
3673 const char *retval = NULL;
3674 int i = 0;
3675 int broken = 0;
3677 if (mips_pic != NO_PIC)
3679 if (g_switch_seen && g_switch_value != 0)
3680 as_bad (_("-G may not be used in position-independent code"));
3681 g_switch_value = 0;
3683 else if (mips_abicalls)
3685 if (g_switch_seen && g_switch_value != 0)
3686 as_bad (_("-G may not be used with abicalls"));
3687 g_switch_value = 0;
3690 if (! bfd_set_arch_mach (stdoutput, bfd_arch_mips, file_mips_opts.arch))
3691 as_warn (_("could not set architecture and machine"));
3693 op_hash = hash_new ();
3695 mips_operands = XCNEWVEC (struct mips_operand_array, NUMOPCODES);
3696 for (i = 0; i < NUMOPCODES;)
3698 const char *name = mips_opcodes[i].name;
3700 retval = hash_insert (op_hash, name, (void *) &mips_opcodes[i]);
3701 if (retval != NULL)
3703 fprintf (stderr, _("internal error: can't hash `%s': %s\n"),
3704 mips_opcodes[i].name, retval);
3705 /* Probably a memory allocation problem? Give up now. */
3706 as_fatal (_("broken assembler, no assembly attempted"));
3710 if (!validate_mips_insn (&mips_opcodes[i], 0xffffffff,
3711 decode_mips_operand, &mips_operands[i]))
3712 broken = 1;
3714 if (nop_insn.insn_mo == NULL && strcmp (name, "nop") == 0)
3716 create_insn (&nop_insn, mips_opcodes + i);
3717 if (mips_fix_loongson2f_nop)
3718 nop_insn.insn_opcode = LOONGSON2F_NOP_INSN;
3719 nop_insn.fixed_p = 1;
3722 if (sync_insn.insn_mo == NULL && strcmp (name, "sync") == 0)
3723 create_insn (&sync_insn, mips_opcodes + i);
3725 ++i;
3727 while ((i < NUMOPCODES) && !strcmp (mips_opcodes[i].name, name));
3730 mips16_op_hash = hash_new ();
3731 mips16_operands = XCNEWVEC (struct mips_operand_array,
3732 bfd_mips16_num_opcodes);
3734 i = 0;
3735 while (i < bfd_mips16_num_opcodes)
3737 const char *name = mips16_opcodes[i].name;
3739 retval = hash_insert (mips16_op_hash, name, (void *) &mips16_opcodes[i]);
3740 if (retval != NULL)
3741 as_fatal (_("internal: can't hash `%s': %s"),
3742 mips16_opcodes[i].name, retval);
3745 if (!validate_mips16_insn (&mips16_opcodes[i], &mips16_operands[i]))
3746 broken = 1;
3747 if (mips16_nop_insn.insn_mo == NULL && strcmp (name, "nop") == 0)
3749 create_insn (&mips16_nop_insn, mips16_opcodes + i);
3750 mips16_nop_insn.fixed_p = 1;
3752 ++i;
3754 while (i < bfd_mips16_num_opcodes
3755 && strcmp (mips16_opcodes[i].name, name) == 0);
3758 micromips_op_hash = hash_new ();
3759 micromips_operands = XCNEWVEC (struct mips_operand_array,
3760 bfd_micromips_num_opcodes);
3762 i = 0;
3763 while (i < bfd_micromips_num_opcodes)
3765 const char *name = micromips_opcodes[i].name;
3767 retval = hash_insert (micromips_op_hash, name,
3768 (void *) &micromips_opcodes[i]);
3769 if (retval != NULL)
3770 as_fatal (_("internal: can't hash `%s': %s"),
3771 micromips_opcodes[i].name, retval);
3774 struct mips_cl_insn *micromips_nop_insn;
3776 if (!validate_micromips_insn (&micromips_opcodes[i],
3777 &micromips_operands[i]))
3778 broken = 1;
3780 if (micromips_opcodes[i].pinfo != INSN_MACRO)
3782 if (micromips_insn_length (micromips_opcodes + i) == 2)
3783 micromips_nop_insn = &micromips_nop16_insn;
3784 else if (micromips_insn_length (micromips_opcodes + i) == 4)
3785 micromips_nop_insn = &micromips_nop32_insn;
3786 else
3787 continue;
3789 if (micromips_nop_insn->insn_mo == NULL
3790 && strcmp (name, "nop") == 0)
3792 create_insn (micromips_nop_insn, micromips_opcodes + i);
3793 micromips_nop_insn->fixed_p = 1;
3797 while (++i < bfd_micromips_num_opcodes
3798 && strcmp (micromips_opcodes[i].name, name) == 0);
3801 if (broken)
3802 as_fatal (_("broken assembler, no assembly attempted"));
3804 /* We add all the general register names to the symbol table. This
3805 helps us detect invalid uses of them. */
3806 for (i = 0; reg_names[i].name; i++)
3807 symbol_table_insert (symbol_new (reg_names[i].name, reg_section,
3808 reg_names[i].num, /* & RNUM_MASK, */
3809 &zero_address_frag));
3810 if (HAVE_NEWABI)
3811 for (i = 0; reg_names_n32n64[i].name; i++)
3812 symbol_table_insert (symbol_new (reg_names_n32n64[i].name, reg_section,
3813 reg_names_n32n64[i].num, /* & RNUM_MASK, */
3814 &zero_address_frag));
3815 else
3816 for (i = 0; reg_names_o32[i].name; i++)
3817 symbol_table_insert (symbol_new (reg_names_o32[i].name, reg_section,
3818 reg_names_o32[i].num, /* & RNUM_MASK, */
3819 &zero_address_frag));
3821 for (i = 0; i < 32; i++)
3823 char regname[6];
3825 /* R5900 VU0 floating-point register. */
3826 sprintf (regname, "$vf%d", i);
3827 symbol_table_insert (symbol_new (regname, reg_section,
3828 RTYPE_VF | i, &zero_address_frag));
3830 /* R5900 VU0 integer register. */
3831 sprintf (regname, "$vi%d", i);
3832 symbol_table_insert (symbol_new (regname, reg_section,
3833 RTYPE_VI | i, &zero_address_frag));
3835 /* MSA register. */
3836 sprintf (regname, "$w%d", i);
3837 symbol_table_insert (symbol_new (regname, reg_section,
3838 RTYPE_MSA | i, &zero_address_frag));
3841 obstack_init (&mips_operand_tokens);
3843 mips_no_prev_insn ();
3845 mips_gprmask = 0;
3846 mips_cprmask[0] = 0;
3847 mips_cprmask[1] = 0;
3848 mips_cprmask[2] = 0;
3849 mips_cprmask[3] = 0;
3851 /* set the default alignment for the text section (2**2) */
3852 record_alignment (text_section, 2);
3854 bfd_set_gp_size (stdoutput, g_switch_value);
3856 /* On a native system other than VxWorks, sections must be aligned
3857 to 16 byte boundaries. When configured for an embedded ELF
3858 target, we don't bother. */
3859 if (strncmp (TARGET_OS, "elf", 3) != 0
3860 && strncmp (TARGET_OS, "vxworks", 7) != 0)
3862 (void) bfd_set_section_alignment (stdoutput, text_section, 4);
3863 (void) bfd_set_section_alignment (stdoutput, data_section, 4);
3864 (void) bfd_set_section_alignment (stdoutput, bss_section, 4);
3867 /* Create a .reginfo section for register masks and a .mdebug
3868 section for debugging information. */
3870 segT seg;
3871 subsegT subseg;
3872 flagword flags;
3873 segT sec;
3875 seg = now_seg;
3876 subseg = now_subseg;
3878 /* The ABI says this section should be loaded so that the
3879 running program can access it. However, we don't load it
3880 if we are configured for an embedded target. */
3881 flags = SEC_READONLY | SEC_DATA;
3882 if (strncmp (TARGET_OS, "elf", 3) != 0)
3883 flags |= SEC_ALLOC | SEC_LOAD;
3885 if (mips_abi != N64_ABI)
3887 sec = subseg_new (".reginfo", (subsegT) 0);
3889 bfd_set_section_flags (stdoutput, sec, flags);
3890 bfd_set_section_alignment (stdoutput, sec, HAVE_NEWABI ? 3 : 2);
3892 mips_regmask_frag = frag_more (sizeof (Elf32_External_RegInfo));
3894 else
3896 /* The 64-bit ABI uses a .MIPS.options section rather than
3897 .reginfo section. */
3898 sec = subseg_new (".MIPS.options", (subsegT) 0);
3899 bfd_set_section_flags (stdoutput, sec, flags);
3900 bfd_set_section_alignment (stdoutput, sec, 3);
3902 /* Set up the option header. */
3904 Elf_Internal_Options opthdr;
3905 char *f;
3907 opthdr.kind = ODK_REGINFO;
3908 opthdr.size = (sizeof (Elf_External_Options)
3909 + sizeof (Elf64_External_RegInfo));
3910 opthdr.section = 0;
3911 opthdr.info = 0;
3912 f = frag_more (sizeof (Elf_External_Options));
3913 bfd_mips_elf_swap_options_out (stdoutput, &opthdr,
3914 (Elf_External_Options *) f);
3916 mips_regmask_frag = frag_more (sizeof (Elf64_External_RegInfo));
3920 sec = subseg_new (".MIPS.abiflags", (subsegT) 0);
3921 bfd_set_section_flags (stdoutput, sec,
3922 SEC_READONLY | SEC_DATA | SEC_ALLOC | SEC_LOAD);
3923 bfd_set_section_alignment (stdoutput, sec, 3);
3924 mips_flags_frag = frag_more (sizeof (Elf_External_ABIFlags_v0));
3926 if (ECOFF_DEBUGGING)
3928 sec = subseg_new (".mdebug", (subsegT) 0);
3929 (void) bfd_set_section_flags (stdoutput, sec,
3930 SEC_HAS_CONTENTS | SEC_READONLY);
3931 (void) bfd_set_section_alignment (stdoutput, sec, 2);
3933 else if (mips_flag_pdr)
3935 pdr_seg = subseg_new (".pdr", (subsegT) 0);
3936 (void) bfd_set_section_flags (stdoutput, pdr_seg,
3937 SEC_READONLY | SEC_RELOC
3938 | SEC_DEBUGGING);
3939 (void) bfd_set_section_alignment (stdoutput, pdr_seg, 2);
3942 subseg_set (seg, subseg);
3945 if (mips_fix_vr4120)
3946 init_vr4120_conflicts ();
3949 static inline void
3950 fpabi_incompatible_with (int fpabi, const char *what)
3952 as_warn (_(".gnu_attribute %d,%d is incompatible with `%s'"),
3953 Tag_GNU_MIPS_ABI_FP, fpabi, what);
3956 static inline void
3957 fpabi_requires (int fpabi, const char *what)
3959 as_warn (_(".gnu_attribute %d,%d requires `%s'"),
3960 Tag_GNU_MIPS_ABI_FP, fpabi, what);
3963 /* Check -mabi and register sizes against the specified FP ABI. */
3964 static void
3965 check_fpabi (int fpabi)
3967 switch (fpabi)
3969 case Val_GNU_MIPS_ABI_FP_DOUBLE:
3970 if (file_mips_opts.soft_float)
3971 fpabi_incompatible_with (fpabi, "softfloat");
3972 else if (file_mips_opts.single_float)
3973 fpabi_incompatible_with (fpabi, "singlefloat");
3974 if (file_mips_opts.gp == 64 && file_mips_opts.fp == 32)
3975 fpabi_incompatible_with (fpabi, "gp=64 fp=32");
3976 else if (file_mips_opts.gp == 32 && file_mips_opts.fp == 64)
3977 fpabi_incompatible_with (fpabi, "gp=32 fp=64");
3978 break;
3980 case Val_GNU_MIPS_ABI_FP_XX:
3981 if (mips_abi != O32_ABI)
3982 fpabi_requires (fpabi, "-mabi=32");
3983 else if (file_mips_opts.soft_float)
3984 fpabi_incompatible_with (fpabi, "softfloat");
3985 else if (file_mips_opts.single_float)
3986 fpabi_incompatible_with (fpabi, "singlefloat");
3987 else if (file_mips_opts.fp != 0)
3988 fpabi_requires (fpabi, "fp=xx");
3989 break;
3991 case Val_GNU_MIPS_ABI_FP_64A:
3992 case Val_GNU_MIPS_ABI_FP_64:
3993 if (mips_abi != O32_ABI)
3994 fpabi_requires (fpabi, "-mabi=32");
3995 else if (file_mips_opts.soft_float)
3996 fpabi_incompatible_with (fpabi, "softfloat");
3997 else if (file_mips_opts.single_float)
3998 fpabi_incompatible_with (fpabi, "singlefloat");
3999 else if (file_mips_opts.fp != 64)
4000 fpabi_requires (fpabi, "fp=64");
4001 else if (fpabi == Val_GNU_MIPS_ABI_FP_64 && !file_mips_opts.oddspreg)
4002 fpabi_incompatible_with (fpabi, "nooddspreg");
4003 else if (fpabi == Val_GNU_MIPS_ABI_FP_64A && file_mips_opts.oddspreg)
4004 fpabi_requires (fpabi, "nooddspreg");
4005 break;
4007 case Val_GNU_MIPS_ABI_FP_SINGLE:
4008 if (file_mips_opts.soft_float)
4009 fpabi_incompatible_with (fpabi, "softfloat");
4010 else if (!file_mips_opts.single_float)
4011 fpabi_requires (fpabi, "singlefloat");
4012 break;
4014 case Val_GNU_MIPS_ABI_FP_SOFT:
4015 if (!file_mips_opts.soft_float)
4016 fpabi_requires (fpabi, "softfloat");
4017 break;
4019 case Val_GNU_MIPS_ABI_FP_OLD_64:
4020 as_warn (_(".gnu_attribute %d,%d is no longer supported"),
4021 Tag_GNU_MIPS_ABI_FP, fpabi);
4022 break;
4024 case Val_GNU_MIPS_ABI_FP_NAN2008:
4025 /* Silently ignore compatibility value. */
4026 break;
4028 default:
4029 as_warn (_(".gnu_attribute %d,%d is not a recognized"
4030 " floating-point ABI"), Tag_GNU_MIPS_ABI_FP, fpabi);
4031 break;
4035 /* Perform consistency checks on the current options. */
4037 static void
4038 mips_check_options (struct mips_set_options *opts, bfd_boolean abi_checks)
4040 /* Check the size of integer registers agrees with the ABI and ISA. */
4041 if (opts->gp == 64 && !ISA_HAS_64BIT_REGS (opts->isa))
4042 as_bad (_("`gp=64' used with a 32-bit processor"));
4043 else if (abi_checks
4044 && opts->gp == 32 && ABI_NEEDS_64BIT_REGS (mips_abi))
4045 as_bad (_("`gp=32' used with a 64-bit ABI"));
4046 else if (abi_checks
4047 && opts->gp == 64 && ABI_NEEDS_32BIT_REGS (mips_abi))
4048 as_bad (_("`gp=64' used with a 32-bit ABI"));
4050 /* Check the size of the float registers agrees with the ABI and ISA. */
4051 switch (opts->fp)
4053 case 0:
4054 if (!CPU_HAS_LDC1_SDC1 (opts->arch))
4055 as_bad (_("`fp=xx' used with a cpu lacking ldc1/sdc1 instructions"));
4056 else if (opts->single_float == 1)
4057 as_bad (_("`fp=xx' cannot be used with `singlefloat'"));
4058 break;
4059 case 64:
4060 if (!ISA_HAS_64BIT_FPRS (opts->isa))
4061 as_bad (_("`fp=64' used with a 32-bit fpu"));
4062 else if (abi_checks
4063 && ABI_NEEDS_32BIT_REGS (mips_abi)
4064 && !ISA_HAS_MXHC1 (opts->isa))
4065 as_warn (_("`fp=64' used with a 32-bit ABI"));
4066 break;
4067 case 32:
4068 if (abi_checks
4069 && ABI_NEEDS_64BIT_REGS (mips_abi))
4070 as_warn (_("`fp=32' used with a 64-bit ABI"));
4071 if (ISA_IS_R6 (opts->isa) && opts->single_float == 0)
4072 as_bad (_("`fp=32' used with a MIPS R6 cpu"));
4073 break;
4074 default:
4075 as_bad (_("Unknown size of floating point registers"));
4076 break;
4079 if (ABI_NEEDS_64BIT_REGS (mips_abi) && !opts->oddspreg)
4080 as_bad (_("`nooddspreg` cannot be used with a 64-bit ABI"));
4082 if (opts->micromips == 1 && opts->mips16 == 1)
4083 as_bad (_("`%s' cannot be used with `%s'"), "mips16", "micromips");
4084 else if (ISA_IS_R6 (opts->isa)
4085 && (opts->micromips == 1
4086 || opts->mips16 == 1))
4087 as_fatal (_("`%s' cannot be used with `%s'"),
4088 opts->micromips ? "micromips" : "mips16",
4089 mips_cpu_info_from_isa (opts->isa)->name);
4091 if (ISA_IS_R6 (opts->isa) && mips_relax_branch)
4092 as_fatal (_("branch relaxation is not supported in `%s'"),
4093 mips_cpu_info_from_isa (opts->isa)->name);
4096 /* Perform consistency checks on the module level options exactly once.
4097 This is a deferred check that happens:
4098 at the first .set directive
4099 or, at the first pseudo op that generates code (inc .dc.a)
4100 or, at the first instruction
4101 or, at the end. */
4103 static void
4104 file_mips_check_options (void)
4106 if (file_mips_opts_checked)
4107 return;
4109 /* The following code determines the register size.
4110 Similar code was added to GCC 3.3 (see override_options() in
4111 config/mips/mips.c). The GAS and GCC code should be kept in sync
4112 as much as possible. */
4114 if (file_mips_opts.gp < 0)
4116 /* Infer the integer register size from the ABI and processor.
4117 Restrict ourselves to 32-bit registers if that's all the
4118 processor has, or if the ABI cannot handle 64-bit registers. */
4119 file_mips_opts.gp = (ABI_NEEDS_32BIT_REGS (mips_abi)
4120 || !ISA_HAS_64BIT_REGS (file_mips_opts.isa))
4121 ? 32 : 64;
4124 if (file_mips_opts.fp < 0)
4126 /* No user specified float register size.
4127 ??? GAS treats single-float processors as though they had 64-bit
4128 float registers (although it complains when double-precision
4129 instructions are used). As things stand, saying they have 32-bit
4130 registers would lead to spurious "register must be even" messages.
4131 So here we assume float registers are never smaller than the
4132 integer ones. */
4133 if (file_mips_opts.gp == 64)
4134 /* 64-bit integer registers implies 64-bit float registers. */
4135 file_mips_opts.fp = 64;
4136 else if ((file_mips_opts.ase & FP64_ASES)
4137 && ISA_HAS_64BIT_FPRS (file_mips_opts.isa))
4138 /* Handle ASEs that require 64-bit float registers, if possible. */
4139 file_mips_opts.fp = 64;
4140 else if (ISA_IS_R6 (mips_opts.isa))
4141 /* R6 implies 64-bit float registers. */
4142 file_mips_opts.fp = 64;
4143 else
4144 /* 32-bit float registers. */
4145 file_mips_opts.fp = 32;
4148 /* Disable operations on odd-numbered floating-point registers by default
4149 when using the FPXX ABI. */
4150 if (file_mips_opts.oddspreg < 0)
4152 if (file_mips_opts.fp == 0)
4153 file_mips_opts.oddspreg = 0;
4154 else
4155 file_mips_opts.oddspreg = 1;
4158 /* End of GCC-shared inference code. */
4160 /* This flag is set when we have a 64-bit capable CPU but use only
4161 32-bit wide registers. Note that EABI does not use it. */
4162 if (ISA_HAS_64BIT_REGS (file_mips_opts.isa)
4163 && ((mips_abi == NO_ABI && file_mips_opts.gp == 32)
4164 || mips_abi == O32_ABI))
4165 mips_32bitmode = 1;
4167 if (file_mips_opts.isa == ISA_MIPS1 && mips_trap)
4168 as_bad (_("trap exception not supported at ISA 1"));
4170 /* If the selected architecture includes support for ASEs, enable
4171 generation of code for them. */
4172 if (file_mips_opts.mips16 == -1)
4173 file_mips_opts.mips16 = (CPU_HAS_MIPS16 (file_mips_opts.arch)) ? 1 : 0;
4174 if (file_mips_opts.micromips == -1)
4175 file_mips_opts.micromips = (CPU_HAS_MICROMIPS (file_mips_opts.arch))
4176 ? 1 : 0;
4178 if (mips_nan2008 == -1)
4179 mips_nan2008 = (ISA_HAS_LEGACY_NAN (file_mips_opts.isa)) ? 0 : 1;
4180 else if (!ISA_HAS_LEGACY_NAN (file_mips_opts.isa) && mips_nan2008 == 0)
4181 as_fatal (_("`%s' does not support legacy NaN"),
4182 mips_cpu_info_from_arch (file_mips_opts.arch)->name);
4184 /* Some ASEs require 64-bit FPRs, so -mfp32 should stop those ASEs from
4185 being selected implicitly. */
4186 if (file_mips_opts.fp != 64)
4187 file_ase_explicit |= ASE_MIPS3D | ASE_MDMX | ASE_MSA;
4189 /* If the user didn't explicitly select or deselect a particular ASE,
4190 use the default setting for the CPU. */
4191 file_mips_opts.ase |= (file_mips_opts.init_ase & ~file_ase_explicit);
4193 /* Set up the current options. These may change throughout assembly. */
4194 mips_opts = file_mips_opts;
4196 mips_check_isa_supports_ases ();
4197 mips_check_options (&file_mips_opts, TRUE);
4198 file_mips_opts_checked = TRUE;
4200 if (!bfd_set_arch_mach (stdoutput, bfd_arch_mips, file_mips_opts.arch))
4201 as_warn (_("could not set architecture and machine"));
4204 void
4205 md_assemble (char *str)
4207 struct mips_cl_insn insn;
4208 bfd_reloc_code_real_type unused_reloc[3]
4209 = {BFD_RELOC_UNUSED, BFD_RELOC_UNUSED, BFD_RELOC_UNUSED};
4211 file_mips_check_options ();
4213 imm_expr.X_op = O_absent;
4214 offset_expr.X_op = O_absent;
4215 offset_reloc[0] = BFD_RELOC_UNUSED;
4216 offset_reloc[1] = BFD_RELOC_UNUSED;
4217 offset_reloc[2] = BFD_RELOC_UNUSED;
4219 mips_mark_labels ();
4220 mips_assembling_insn = TRUE;
4221 clear_insn_error ();
4223 if (mips_opts.mips16)
4224 mips16_ip (str, &insn);
4225 else
4227 mips_ip (str, &insn);
4228 DBG ((_("returned from mips_ip(%s) insn_opcode = 0x%x\n"),
4229 str, insn.insn_opcode));
4232 if (insn_error.msg)
4233 report_insn_error (str);
4234 else if (insn.insn_mo->pinfo == INSN_MACRO)
4236 macro_start ();
4237 if (mips_opts.mips16)
4238 mips16_macro (&insn);
4239 else
4240 macro (&insn, str);
4241 macro_end ();
4243 else
4245 if (offset_expr.X_op != O_absent)
4246 append_insn (&insn, &offset_expr, offset_reloc, FALSE);
4247 else
4248 append_insn (&insn, NULL, unused_reloc, FALSE);
4251 mips_assembling_insn = FALSE;
4254 /* Convenience functions for abstracting away the differences between
4255 MIPS16 and non-MIPS16 relocations. */
4257 static inline bfd_boolean
4258 mips16_reloc_p (bfd_reloc_code_real_type reloc)
4260 switch (reloc)
4262 case BFD_RELOC_MIPS16_JMP:
4263 case BFD_RELOC_MIPS16_GPREL:
4264 case BFD_RELOC_MIPS16_GOT16:
4265 case BFD_RELOC_MIPS16_CALL16:
4266 case BFD_RELOC_MIPS16_HI16_S:
4267 case BFD_RELOC_MIPS16_HI16:
4268 case BFD_RELOC_MIPS16_LO16:
4269 case BFD_RELOC_MIPS16_16_PCREL_S1:
4270 return TRUE;
4272 default:
4273 return FALSE;
4277 static inline bfd_boolean
4278 micromips_reloc_p (bfd_reloc_code_real_type reloc)
4280 switch (reloc)
4282 case BFD_RELOC_MICROMIPS_7_PCREL_S1:
4283 case BFD_RELOC_MICROMIPS_10_PCREL_S1:
4284 case BFD_RELOC_MICROMIPS_16_PCREL_S1:
4285 case BFD_RELOC_MICROMIPS_GPREL16:
4286 case BFD_RELOC_MICROMIPS_JMP:
4287 case BFD_RELOC_MICROMIPS_HI16:
4288 case BFD_RELOC_MICROMIPS_HI16_S:
4289 case BFD_RELOC_MICROMIPS_LO16:
4290 case BFD_RELOC_MICROMIPS_LITERAL:
4291 case BFD_RELOC_MICROMIPS_GOT16:
4292 case BFD_RELOC_MICROMIPS_CALL16:
4293 case BFD_RELOC_MICROMIPS_GOT_HI16:
4294 case BFD_RELOC_MICROMIPS_GOT_LO16:
4295 case BFD_RELOC_MICROMIPS_CALL_HI16:
4296 case BFD_RELOC_MICROMIPS_CALL_LO16:
4297 case BFD_RELOC_MICROMIPS_SUB:
4298 case BFD_RELOC_MICROMIPS_GOT_PAGE:
4299 case BFD_RELOC_MICROMIPS_GOT_OFST:
4300 case BFD_RELOC_MICROMIPS_GOT_DISP:
4301 case BFD_RELOC_MICROMIPS_HIGHEST:
4302 case BFD_RELOC_MICROMIPS_HIGHER:
4303 case BFD_RELOC_MICROMIPS_SCN_DISP:
4304 case BFD_RELOC_MICROMIPS_JALR:
4305 return TRUE;
4307 default:
4308 return FALSE;
4312 static inline bfd_boolean
4313 jmp_reloc_p (bfd_reloc_code_real_type reloc)
4315 return reloc == BFD_RELOC_MIPS_JMP || reloc == BFD_RELOC_MICROMIPS_JMP;
4318 static inline bfd_boolean
4319 b_reloc_p (bfd_reloc_code_real_type reloc)
4321 return (reloc == BFD_RELOC_MIPS_26_PCREL_S2
4322 || reloc == BFD_RELOC_MIPS_21_PCREL_S2
4323 || reloc == BFD_RELOC_16_PCREL_S2
4324 || reloc == BFD_RELOC_MIPS16_16_PCREL_S1
4325 || reloc == BFD_RELOC_MICROMIPS_16_PCREL_S1
4326 || reloc == BFD_RELOC_MICROMIPS_10_PCREL_S1
4327 || reloc == BFD_RELOC_MICROMIPS_7_PCREL_S1);
4330 static inline bfd_boolean
4331 got16_reloc_p (bfd_reloc_code_real_type reloc)
4333 return (reloc == BFD_RELOC_MIPS_GOT16 || reloc == BFD_RELOC_MIPS16_GOT16
4334 || reloc == BFD_RELOC_MICROMIPS_GOT16);
4337 static inline bfd_boolean
4338 hi16_reloc_p (bfd_reloc_code_real_type reloc)
4340 return (reloc == BFD_RELOC_HI16_S || reloc == BFD_RELOC_MIPS16_HI16_S
4341 || reloc == BFD_RELOC_MICROMIPS_HI16_S);
4344 static inline bfd_boolean
4345 lo16_reloc_p (bfd_reloc_code_real_type reloc)
4347 return (reloc == BFD_RELOC_LO16 || reloc == BFD_RELOC_MIPS16_LO16
4348 || reloc == BFD_RELOC_MICROMIPS_LO16);
4351 static inline bfd_boolean
4352 jalr_reloc_p (bfd_reloc_code_real_type reloc)
4354 return reloc == BFD_RELOC_MIPS_JALR || reloc == BFD_RELOC_MICROMIPS_JALR;
4357 static inline bfd_boolean
4358 gprel16_reloc_p (bfd_reloc_code_real_type reloc)
4360 return (reloc == BFD_RELOC_GPREL16 || reloc == BFD_RELOC_MIPS16_GPREL
4361 || reloc == BFD_RELOC_MICROMIPS_GPREL16);
4364 /* Return true if RELOC is a PC-relative relocation that does not have
4365 full address range. */
4367 static inline bfd_boolean
4368 limited_pcrel_reloc_p (bfd_reloc_code_real_type reloc)
4370 switch (reloc)
4372 case BFD_RELOC_16_PCREL_S2:
4373 case BFD_RELOC_MIPS16_16_PCREL_S1:
4374 case BFD_RELOC_MICROMIPS_7_PCREL_S1:
4375 case BFD_RELOC_MICROMIPS_10_PCREL_S1:
4376 case BFD_RELOC_MICROMIPS_16_PCREL_S1:
4377 case BFD_RELOC_MIPS_21_PCREL_S2:
4378 case BFD_RELOC_MIPS_26_PCREL_S2:
4379 case BFD_RELOC_MIPS_18_PCREL_S3:
4380 case BFD_RELOC_MIPS_19_PCREL_S2:
4381 return TRUE;
4383 case BFD_RELOC_32_PCREL:
4384 case BFD_RELOC_HI16_S_PCREL:
4385 case BFD_RELOC_LO16_PCREL:
4386 return HAVE_64BIT_ADDRESSES;
4388 default:
4389 return FALSE;
4393 /* Return true if the given relocation might need a matching %lo().
4394 This is only "might" because SVR4 R_MIPS_GOT16 relocations only
4395 need a matching %lo() when applied to local symbols. */
4397 static inline bfd_boolean
4398 reloc_needs_lo_p (bfd_reloc_code_real_type reloc)
4400 return (HAVE_IN_PLACE_ADDENDS
4401 && (hi16_reloc_p (reloc)
4402 /* VxWorks R_MIPS_GOT16 relocs never need a matching %lo();
4403 all GOT16 relocations evaluate to "G". */
4404 || (got16_reloc_p (reloc) && mips_pic != VXWORKS_PIC)));
4407 /* Return the type of %lo() reloc needed by RELOC, given that
4408 reloc_needs_lo_p. */
4410 static inline bfd_reloc_code_real_type
4411 matching_lo_reloc (bfd_reloc_code_real_type reloc)
4413 return (mips16_reloc_p (reloc) ? BFD_RELOC_MIPS16_LO16
4414 : (micromips_reloc_p (reloc) ? BFD_RELOC_MICROMIPS_LO16
4415 : BFD_RELOC_LO16));
4418 /* Return true if the given fixup is followed by a matching R_MIPS_LO16
4419 relocation. */
4421 static inline bfd_boolean
4422 fixup_has_matching_lo_p (fixS *fixp)
4424 return (fixp->fx_next != NULL
4425 && fixp->fx_next->fx_r_type == matching_lo_reloc (fixp->fx_r_type)
4426 && fixp->fx_addsy == fixp->fx_next->fx_addsy
4427 && fixp->fx_offset == fixp->fx_next->fx_offset);
4430 /* Move all labels in LABELS to the current insertion point. TEXT_P
4431 says whether the labels refer to text or data. */
4433 static void
4434 mips_move_labels (struct insn_label_list *labels, bfd_boolean text_p)
4436 struct insn_label_list *l;
4437 valueT val;
4439 for (l = labels; l != NULL; l = l->next)
4441 gas_assert (S_GET_SEGMENT (l->label) == now_seg);
4442 symbol_set_frag (l->label, frag_now);
4443 val = (valueT) frag_now_fix ();
4444 /* MIPS16/microMIPS text labels are stored as odd. */
4445 if (text_p && HAVE_CODE_COMPRESSION)
4446 ++val;
4447 S_SET_VALUE (l->label, val);
4451 /* Move all labels in insn_labels to the current insertion point
4452 and treat them as text labels. */
4454 static void
4455 mips_move_text_labels (void)
4457 mips_move_labels (seg_info (now_seg)->label_list, TRUE);
4460 /* Duplicate the test for LINK_ONCE sections as in `adjust_reloc_syms'. */
4462 static bfd_boolean
4463 s_is_linkonce (symbolS *sym, segT from_seg)
4465 bfd_boolean linkonce = FALSE;
4466 segT symseg = S_GET_SEGMENT (sym);
4468 if (symseg != from_seg && !S_IS_LOCAL (sym))
4470 if ((bfd_get_section_flags (stdoutput, symseg) & SEC_LINK_ONCE))
4471 linkonce = TRUE;
4472 /* The GNU toolchain uses an extension for ELF: a section
4473 beginning with the magic string .gnu.linkonce is a
4474 linkonce section. */
4475 if (strncmp (segment_name (symseg), ".gnu.linkonce",
4476 sizeof ".gnu.linkonce" - 1) == 0)
4477 linkonce = TRUE;
4479 return linkonce;
4482 /* Mark MIPS16 or microMIPS instruction label LABEL. This permits the
4483 linker to handle them specially, such as generating jalx instructions
4484 when needed. We also make them odd for the duration of the assembly,
4485 in order to generate the right sort of code. We will make them even
4486 in the adjust_symtab routine, while leaving them marked. This is
4487 convenient for the debugger and the disassembler. The linker knows
4488 to make them odd again. */
4490 static void
4491 mips_compressed_mark_label (symbolS *label)
4493 gas_assert (HAVE_CODE_COMPRESSION);
4495 if (mips_opts.mips16)
4496 S_SET_OTHER (label, ELF_ST_SET_MIPS16 (S_GET_OTHER (label)));
4497 else
4498 S_SET_OTHER (label, ELF_ST_SET_MICROMIPS (S_GET_OTHER (label)));
4499 if ((S_GET_VALUE (label) & 1) == 0
4500 /* Don't adjust the address if the label is global or weak, or
4501 in a link-once section, since we'll be emitting symbol reloc
4502 references to it which will be patched up by the linker, and
4503 the final value of the symbol may or may not be MIPS16/microMIPS. */
4504 && !S_IS_WEAK (label)
4505 && !S_IS_EXTERNAL (label)
4506 && !s_is_linkonce (label, now_seg))
4507 S_SET_VALUE (label, S_GET_VALUE (label) | 1);
4510 /* Mark preceding MIPS16 or microMIPS instruction labels. */
4512 static void
4513 mips_compressed_mark_labels (void)
4515 struct insn_label_list *l;
4517 for (l = seg_info (now_seg)->label_list; l != NULL; l = l->next)
4518 mips_compressed_mark_label (l->label);
4521 /* End the current frag. Make it a variant frag and record the
4522 relaxation info. */
4524 static void
4525 relax_close_frag (void)
4527 mips_macro_warning.first_frag = frag_now;
4528 frag_var (rs_machine_dependent, 0, 0,
4529 RELAX_ENCODE (mips_relax.sizes[0], mips_relax.sizes[1],
4530 mips_pic != NO_PIC),
4531 mips_relax.symbol, 0, (char *) mips_relax.first_fixup);
4533 memset (&mips_relax.sizes, 0, sizeof (mips_relax.sizes));
4534 mips_relax.first_fixup = 0;
4537 /* Start a new relaxation sequence whose expansion depends on SYMBOL.
4538 See the comment above RELAX_ENCODE for more details. */
4540 static void
4541 relax_start (symbolS *symbol)
4543 gas_assert (mips_relax.sequence == 0);
4544 mips_relax.sequence = 1;
4545 mips_relax.symbol = symbol;
4548 /* Start generating the second version of a relaxable sequence.
4549 See the comment above RELAX_ENCODE for more details. */
4551 static void
4552 relax_switch (void)
4554 gas_assert (mips_relax.sequence == 1);
4555 mips_relax.sequence = 2;
4558 /* End the current relaxable sequence. */
4560 static void
4561 relax_end (void)
4563 gas_assert (mips_relax.sequence == 2);
4564 relax_close_frag ();
4565 mips_relax.sequence = 0;
4568 /* Return true if IP is a delayed branch or jump. */
4570 static inline bfd_boolean
4571 delayed_branch_p (const struct mips_cl_insn *ip)
4573 return (ip->insn_mo->pinfo & (INSN_UNCOND_BRANCH_DELAY
4574 | INSN_COND_BRANCH_DELAY
4575 | INSN_COND_BRANCH_LIKELY)) != 0;
4578 /* Return true if IP is a compact branch or jump. */
4580 static inline bfd_boolean
4581 compact_branch_p (const struct mips_cl_insn *ip)
4583 return (ip->insn_mo->pinfo2 & (INSN2_UNCOND_BRANCH
4584 | INSN2_COND_BRANCH)) != 0;
4587 /* Return true if IP is an unconditional branch or jump. */
4589 static inline bfd_boolean
4590 uncond_branch_p (const struct mips_cl_insn *ip)
4592 return ((ip->insn_mo->pinfo & INSN_UNCOND_BRANCH_DELAY) != 0
4593 || (ip->insn_mo->pinfo2 & INSN2_UNCOND_BRANCH) != 0);
4596 /* Return true if IP is a branch-likely instruction. */
4598 static inline bfd_boolean
4599 branch_likely_p (const struct mips_cl_insn *ip)
4601 return (ip->insn_mo->pinfo & INSN_COND_BRANCH_LIKELY) != 0;
4604 /* Return the type of nop that should be used to fill the delay slot
4605 of delayed branch IP. */
4607 static struct mips_cl_insn *
4608 get_delay_slot_nop (const struct mips_cl_insn *ip)
4610 if (mips_opts.micromips
4611 && (ip->insn_mo->pinfo2 & INSN2_BRANCH_DELAY_32BIT))
4612 return &micromips_nop32_insn;
4613 return NOP_INSN;
4616 /* Return a mask that has bit N set if OPCODE reads the register(s)
4617 in operand N. */
4619 static unsigned int
4620 insn_read_mask (const struct mips_opcode *opcode)
4622 return (opcode->pinfo & INSN_READ_ALL) >> INSN_READ_SHIFT;
4625 /* Return a mask that has bit N set if OPCODE writes to the register(s)
4626 in operand N. */
4628 static unsigned int
4629 insn_write_mask (const struct mips_opcode *opcode)
4631 return (opcode->pinfo & INSN_WRITE_ALL) >> INSN_WRITE_SHIFT;
4634 /* Return a mask of the registers specified by operand OPERAND of INSN.
4635 Ignore registers of type OP_REG_<t> unless bit OP_REG_<t> of TYPE_MASK
4636 is set. */
4638 static unsigned int
4639 operand_reg_mask (const struct mips_cl_insn *insn,
4640 const struct mips_operand *operand,
4641 unsigned int type_mask)
4643 unsigned int uval, vsel;
4645 switch (operand->type)
4647 case OP_INT:
4648 case OP_MAPPED_INT:
4649 case OP_MSB:
4650 case OP_PCREL:
4651 case OP_PERF_REG:
4652 case OP_ADDIUSP_INT:
4653 case OP_ENTRY_EXIT_LIST:
4654 case OP_REPEAT_DEST_REG:
4655 case OP_REPEAT_PREV_REG:
4656 case OP_PC:
4657 case OP_VU0_SUFFIX:
4658 case OP_VU0_MATCH_SUFFIX:
4659 case OP_IMM_INDEX:
4660 abort ();
4662 case OP_REG28:
4663 return 1 << 28;
4665 case OP_REG:
4666 case OP_OPTIONAL_REG:
4668 const struct mips_reg_operand *reg_op;
4670 reg_op = (const struct mips_reg_operand *) operand;
4671 if (!(type_mask & (1 << reg_op->reg_type)))
4672 return 0;
4673 uval = insn_extract_operand (insn, operand);
4674 return 1 << mips_decode_reg_operand (reg_op, uval);
4677 case OP_REG_PAIR:
4679 const struct mips_reg_pair_operand *pair_op;
4681 pair_op = (const struct mips_reg_pair_operand *) operand;
4682 if (!(type_mask & (1 << pair_op->reg_type)))
4683 return 0;
4684 uval = insn_extract_operand (insn, operand);
4685 return (1 << pair_op->reg1_map[uval]) | (1 << pair_op->reg2_map[uval]);
4688 case OP_CLO_CLZ_DEST:
4689 if (!(type_mask & (1 << OP_REG_GP)))
4690 return 0;
4691 uval = insn_extract_operand (insn, operand);
4692 return (1 << (uval & 31)) | (1 << (uval >> 5));
4694 case OP_SAME_RS_RT:
4695 if (!(type_mask & (1 << OP_REG_GP)))
4696 return 0;
4697 uval = insn_extract_operand (insn, operand);
4698 gas_assert ((uval & 31) == (uval >> 5));
4699 return 1 << (uval & 31);
4701 case OP_CHECK_PREV:
4702 case OP_NON_ZERO_REG:
4703 if (!(type_mask & (1 << OP_REG_GP)))
4704 return 0;
4705 uval = insn_extract_operand (insn, operand);
4706 return 1 << (uval & 31);
4708 case OP_LWM_SWM_LIST:
4709 abort ();
4711 case OP_SAVE_RESTORE_LIST:
4712 abort ();
4714 case OP_MDMX_IMM_REG:
4715 if (!(type_mask & (1 << OP_REG_VEC)))
4716 return 0;
4717 uval = insn_extract_operand (insn, operand);
4718 vsel = uval >> 5;
4719 if ((vsel & 0x18) == 0x18)
4720 return 0;
4721 return 1 << (uval & 31);
4723 case OP_REG_INDEX:
4724 if (!(type_mask & (1 << OP_REG_GP)))
4725 return 0;
4726 return 1 << insn_extract_operand (insn, operand);
4728 abort ();
4731 /* Return a mask of the registers specified by operands OPNO_MASK of INSN,
4732 where bit N of OPNO_MASK is set if operand N should be included.
4733 Ignore registers of type OP_REG_<t> unless bit OP_REG_<t> of TYPE_MASK
4734 is set. */
4736 static unsigned int
4737 insn_reg_mask (const struct mips_cl_insn *insn,
4738 unsigned int type_mask, unsigned int opno_mask)
4740 unsigned int opno, reg_mask;
4742 opno = 0;
4743 reg_mask = 0;
4744 while (opno_mask != 0)
4746 if (opno_mask & 1)
4747 reg_mask |= operand_reg_mask (insn, insn_opno (insn, opno), type_mask);
4748 opno_mask >>= 1;
4749 opno += 1;
4751 return reg_mask;
4754 /* Return the mask of core registers that IP reads. */
4756 static unsigned int
4757 gpr_read_mask (const struct mips_cl_insn *ip)
4759 unsigned long pinfo, pinfo2;
4760 unsigned int mask;
4762 mask = insn_reg_mask (ip, 1 << OP_REG_GP, insn_read_mask (ip->insn_mo));
4763 pinfo = ip->insn_mo->pinfo;
4764 pinfo2 = ip->insn_mo->pinfo2;
4765 if (pinfo & INSN_UDI)
4767 /* UDI instructions have traditionally been assumed to read RS
4768 and RT. */
4769 mask |= 1 << EXTRACT_OPERAND (mips_opts.micromips, RT, *ip);
4770 mask |= 1 << EXTRACT_OPERAND (mips_opts.micromips, RS, *ip);
4772 if (pinfo & INSN_READ_GPR_24)
4773 mask |= 1 << 24;
4774 if (pinfo2 & INSN2_READ_GPR_16)
4775 mask |= 1 << 16;
4776 if (pinfo2 & INSN2_READ_SP)
4777 mask |= 1 << SP;
4778 if (pinfo2 & INSN2_READ_GPR_31)
4779 mask |= 1 << 31;
4780 /* Don't include register 0. */
4781 return mask & ~1;
4784 /* Return the mask of core registers that IP writes. */
4786 static unsigned int
4787 gpr_write_mask (const struct mips_cl_insn *ip)
4789 unsigned long pinfo, pinfo2;
4790 unsigned int mask;
4792 mask = insn_reg_mask (ip, 1 << OP_REG_GP, insn_write_mask (ip->insn_mo));
4793 pinfo = ip->insn_mo->pinfo;
4794 pinfo2 = ip->insn_mo->pinfo2;
4795 if (pinfo & INSN_WRITE_GPR_24)
4796 mask |= 1 << 24;
4797 if (pinfo & INSN_WRITE_GPR_31)
4798 mask |= 1 << 31;
4799 if (pinfo & INSN_UDI)
4800 /* UDI instructions have traditionally been assumed to write to RD. */
4801 mask |= 1 << EXTRACT_OPERAND (mips_opts.micromips, RD, *ip);
4802 if (pinfo2 & INSN2_WRITE_SP)
4803 mask |= 1 << SP;
4804 /* Don't include register 0. */
4805 return mask & ~1;
4808 /* Return the mask of floating-point registers that IP reads. */
4810 static unsigned int
4811 fpr_read_mask (const struct mips_cl_insn *ip)
4813 unsigned long pinfo;
4814 unsigned int mask;
4816 mask = insn_reg_mask (ip, ((1 << OP_REG_FP) | (1 << OP_REG_VEC)
4817 | (1 << OP_REG_MSA)),
4818 insn_read_mask (ip->insn_mo));
4819 pinfo = ip->insn_mo->pinfo;
4820 /* Conservatively treat all operands to an FP_D instruction are doubles.
4821 (This is overly pessimistic for things like cvt.d.s.) */
4822 if (FPR_SIZE != 64 && (pinfo & FP_D))
4823 mask |= mask << 1;
4824 return mask;
4827 /* Return the mask of floating-point registers that IP writes. */
4829 static unsigned int
4830 fpr_write_mask (const struct mips_cl_insn *ip)
4832 unsigned long pinfo;
4833 unsigned int mask;
4835 mask = insn_reg_mask (ip, ((1 << OP_REG_FP) | (1 << OP_REG_VEC)
4836 | (1 << OP_REG_MSA)),
4837 insn_write_mask (ip->insn_mo));
4838 pinfo = ip->insn_mo->pinfo;
4839 /* Conservatively treat all operands to an FP_D instruction are doubles.
4840 (This is overly pessimistic for things like cvt.s.d.) */
4841 if (FPR_SIZE != 64 && (pinfo & FP_D))
4842 mask |= mask << 1;
4843 return mask;
4846 /* Operand OPNUM of INSN is an odd-numbered floating-point register.
4847 Check whether that is allowed. */
4849 static bfd_boolean
4850 mips_oddfpreg_ok (const struct mips_opcode *insn, int opnum)
4852 const char *s = insn->name;
4853 bfd_boolean oddspreg = (ISA_HAS_ODD_SINGLE_FPR (mips_opts.isa, mips_opts.arch)
4854 || FPR_SIZE == 64)
4855 && mips_opts.oddspreg;
4857 if (insn->pinfo == INSN_MACRO)
4858 /* Let a macro pass, we'll catch it later when it is expanded. */
4859 return TRUE;
4861 /* Single-precision coprocessor loads and moves are OK for 32-bit registers,
4862 otherwise it depends on oddspreg. */
4863 if ((insn->pinfo & FP_S)
4864 && (insn->pinfo & (INSN_LOAD_MEMORY | INSN_STORE_MEMORY
4865 | INSN_LOAD_COPROC | INSN_COPROC_MOVE)))
4866 return FPR_SIZE == 32 || oddspreg;
4868 /* Allow odd registers for single-precision ops and double-precision if the
4869 floating-point registers are 64-bit wide. */
4870 switch (insn->pinfo & (FP_S | FP_D))
4872 case FP_S:
4873 case 0:
4874 return oddspreg;
4875 case FP_D:
4876 return FPR_SIZE == 64;
4877 default:
4878 break;
4881 /* Cvt.w.x and cvt.x.w allow an odd register for a 'w' or 's' operand. */
4882 s = strchr (insn->name, '.');
4883 if (s != NULL && opnum == 2)
4884 s = strchr (s + 1, '.');
4885 if (s != NULL && (s[1] == 'w' || s[1] == 's'))
4886 return oddspreg;
4888 return FPR_SIZE == 64;
4891 /* Information about an instruction argument that we're trying to match. */
4892 struct mips_arg_info
4894 /* The instruction so far. */
4895 struct mips_cl_insn *insn;
4897 /* The first unconsumed operand token. */
4898 struct mips_operand_token *token;
4900 /* The 1-based operand number, in terms of insn->insn_mo->args. */
4901 int opnum;
4903 /* The 1-based argument number, for error reporting. This does not
4904 count elided optional registers, etc.. */
4905 int argnum;
4907 /* The last OP_REG operand seen, or ILLEGAL_REG if none. */
4908 unsigned int last_regno;
4910 /* If the first operand was an OP_REG, this is the register that it
4911 specified, otherwise it is ILLEGAL_REG. */
4912 unsigned int dest_regno;
4914 /* The value of the last OP_INT operand. Only used for OP_MSB,
4915 where it gives the lsb position. */
4916 unsigned int last_op_int;
4918 /* If true, match routines should assume that no later instruction
4919 alternative matches and should therefore be as accommodating as
4920 possible. Match routines should not report errors if something
4921 is only invalid for !LAX_MATCH. */
4922 bfd_boolean lax_match;
4924 /* True if a reference to the current AT register was seen. */
4925 bfd_boolean seen_at;
4928 /* Record that the argument is out of range. */
4930 static void
4931 match_out_of_range (struct mips_arg_info *arg)
4933 set_insn_error_i (arg->argnum, _("operand %d out of range"), arg->argnum);
4936 /* Record that the argument isn't constant but needs to be. */
4938 static void
4939 match_not_constant (struct mips_arg_info *arg)
4941 set_insn_error_i (arg->argnum, _("operand %d must be constant"),
4942 arg->argnum);
4945 /* Try to match an OT_CHAR token for character CH. Consume the token
4946 and return true on success, otherwise return false. */
4948 static bfd_boolean
4949 match_char (struct mips_arg_info *arg, char ch)
4951 if (arg->token->type == OT_CHAR && arg->token->u.ch == ch)
4953 ++arg->token;
4954 if (ch == ',')
4955 arg->argnum += 1;
4956 return TRUE;
4958 return FALSE;
4961 /* Try to get an expression from the next tokens in ARG. Consume the
4962 tokens and return true on success, storing the expression value in
4963 VALUE and relocation types in R. */
4965 static bfd_boolean
4966 match_expression (struct mips_arg_info *arg, expressionS *value,
4967 bfd_reloc_code_real_type *r)
4969 /* If the next token is a '(' that was parsed as being part of a base
4970 expression, assume we have an elided offset. The later match will fail
4971 if this turns out to be wrong. */
4972 if (arg->token->type == OT_CHAR && arg->token->u.ch == '(')
4974 value->X_op = O_constant;
4975 value->X_add_number = 0;
4976 r[0] = r[1] = r[2] = BFD_RELOC_UNUSED;
4977 return TRUE;
4980 /* Reject register-based expressions such as "0+$2" and "(($2))".
4981 For plain registers the default error seems more appropriate. */
4982 if (arg->token->type == OT_INTEGER
4983 && arg->token->u.integer.value.X_op == O_register)
4985 set_insn_error (arg->argnum, _("register value used as expression"));
4986 return FALSE;
4989 if (arg->token->type == OT_INTEGER)
4991 *value = arg->token->u.integer.value;
4992 memcpy (r, arg->token->u.integer.relocs, 3 * sizeof (*r));
4993 ++arg->token;
4994 return TRUE;
4997 set_insn_error_i
4998 (arg->argnum, _("operand %d must be an immediate expression"),
4999 arg->argnum);
5000 return FALSE;
5003 /* Try to get a constant expression from the next tokens in ARG. Consume
5004 the tokens and return true on success, storing the constant value
5005 in *VALUE. */
5007 static bfd_boolean
5008 match_const_int (struct mips_arg_info *arg, offsetT *value)
5010 expressionS ex;
5011 bfd_reloc_code_real_type r[3];
5013 if (!match_expression (arg, &ex, r))
5014 return FALSE;
5016 if (r[0] == BFD_RELOC_UNUSED && ex.X_op == O_constant)
5017 *value = ex.X_add_number;
5018 else
5020 if (r[0] == BFD_RELOC_UNUSED && ex.X_op == O_big)
5021 match_out_of_range (arg);
5022 else
5023 match_not_constant (arg);
5024 return FALSE;
5026 return TRUE;
5029 /* Return the RTYPE_* flags for a register operand of type TYPE that
5030 appears in instruction OPCODE. */
5032 static unsigned int
5033 convert_reg_type (const struct mips_opcode *opcode,
5034 enum mips_reg_operand_type type)
5036 switch (type)
5038 case OP_REG_GP:
5039 return RTYPE_NUM | RTYPE_GP;
5041 case OP_REG_FP:
5042 /* Allow vector register names for MDMX if the instruction is a 64-bit
5043 FPR load, store or move (including moves to and from GPRs). */
5044 if ((mips_opts.ase & ASE_MDMX)
5045 && (opcode->pinfo & FP_D)
5046 && (opcode->pinfo & (INSN_COPROC_MOVE
5047 | INSN_COPROC_MEMORY_DELAY
5048 | INSN_LOAD_COPROC
5049 | INSN_LOAD_MEMORY
5050 | INSN_STORE_MEMORY)))
5051 return RTYPE_FPU | RTYPE_VEC;
5052 return RTYPE_FPU;
5054 case OP_REG_CCC:
5055 if (opcode->pinfo & (FP_D | FP_S))
5056 return RTYPE_CCC | RTYPE_FCC;
5057 return RTYPE_CCC;
5059 case OP_REG_VEC:
5060 if (opcode->membership & INSN_5400)
5061 return RTYPE_FPU;
5062 return RTYPE_FPU | RTYPE_VEC;
5064 case OP_REG_ACC:
5065 return RTYPE_ACC;
5067 case OP_REG_COPRO:
5068 if (opcode->name[strlen (opcode->name) - 1] == '0')
5069 return RTYPE_NUM | RTYPE_CP0;
5070 return RTYPE_NUM;
5072 case OP_REG_HW:
5073 return RTYPE_NUM;
5075 case OP_REG_VI:
5076 return RTYPE_NUM | RTYPE_VI;
5078 case OP_REG_VF:
5079 return RTYPE_NUM | RTYPE_VF;
5081 case OP_REG_R5900_I:
5082 return RTYPE_R5900_I;
5084 case OP_REG_R5900_Q:
5085 return RTYPE_R5900_Q;
5087 case OP_REG_R5900_R:
5088 return RTYPE_R5900_R;
5090 case OP_REG_R5900_ACC:
5091 return RTYPE_R5900_ACC;
5093 case OP_REG_MSA:
5094 return RTYPE_MSA;
5096 case OP_REG_MSA_CTRL:
5097 return RTYPE_NUM;
5099 abort ();
5102 /* ARG is register REGNO, of type TYPE. Warn about any dubious registers. */
5104 static void
5105 check_regno (struct mips_arg_info *arg,
5106 enum mips_reg_operand_type type, unsigned int regno)
5108 if (AT && type == OP_REG_GP && regno == AT)
5109 arg->seen_at = TRUE;
5111 if (type == OP_REG_FP
5112 && (regno & 1) != 0
5113 && !mips_oddfpreg_ok (arg->insn->insn_mo, arg->opnum))
5115 /* This was a warning prior to introducing O32 FPXX and FP64 support
5116 so maintain a warning for FP32 but raise an error for the new
5117 cases. */
5118 if (FPR_SIZE == 32)
5119 as_warn (_("float register should be even, was %d"), regno);
5120 else
5121 as_bad (_("float register should be even, was %d"), regno);
5124 if (type == OP_REG_CCC)
5126 const char *name;
5127 size_t length;
5129 name = arg->insn->insn_mo->name;
5130 length = strlen (name);
5131 if ((regno & 1) != 0
5132 && ((length >= 3 && strcmp (name + length - 3, ".ps") == 0)
5133 || (length >= 5 && strncmp (name + length - 5, "any2", 4) == 0)))
5134 as_warn (_("condition code register should be even for %s, was %d"),
5135 name, regno);
5137 if ((regno & 3) != 0
5138 && (length >= 5 && strncmp (name + length - 5, "any4", 4) == 0))
5139 as_warn (_("condition code register should be 0 or 4 for %s, was %d"),
5140 name, regno);
5144 /* ARG is a register with symbol value SYMVAL. Try to interpret it as
5145 a register of type TYPE. Return true on success, storing the register
5146 number in *REGNO and warning about any dubious uses. */
5148 static bfd_boolean
5149 match_regno (struct mips_arg_info *arg, enum mips_reg_operand_type type,
5150 unsigned int symval, unsigned int *regno)
5152 if (type == OP_REG_VEC)
5153 symval = mips_prefer_vec_regno (symval);
5154 if (!(symval & convert_reg_type (arg->insn->insn_mo, type)))
5155 return FALSE;
5157 *regno = symval & RNUM_MASK;
5158 check_regno (arg, type, *regno);
5159 return TRUE;
5162 /* Try to interpret the next token in ARG as a register of type TYPE.
5163 Consume the token and return true on success, storing the register
5164 number in *REGNO. Return false on failure. */
5166 static bfd_boolean
5167 match_reg (struct mips_arg_info *arg, enum mips_reg_operand_type type,
5168 unsigned int *regno)
5170 if (arg->token->type == OT_REG
5171 && match_regno (arg, type, arg->token->u.regno, regno))
5173 ++arg->token;
5174 return TRUE;
5176 return FALSE;
5179 /* Try to interpret the next token in ARG as a range of registers of type TYPE.
5180 Consume the token and return true on success, storing the register numbers
5181 in *REGNO1 and *REGNO2. Return false on failure. */
5183 static bfd_boolean
5184 match_reg_range (struct mips_arg_info *arg, enum mips_reg_operand_type type,
5185 unsigned int *regno1, unsigned int *regno2)
5187 if (match_reg (arg, type, regno1))
5189 *regno2 = *regno1;
5190 return TRUE;
5192 if (arg->token->type == OT_REG_RANGE
5193 && match_regno (arg, type, arg->token->u.reg_range.regno1, regno1)
5194 && match_regno (arg, type, arg->token->u.reg_range.regno2, regno2)
5195 && *regno1 <= *regno2)
5197 ++arg->token;
5198 return TRUE;
5200 return FALSE;
5203 /* OP_INT matcher. */
5205 static bfd_boolean
5206 match_int_operand (struct mips_arg_info *arg,
5207 const struct mips_operand *operand_base)
5209 const struct mips_int_operand *operand;
5210 unsigned int uval;
5211 int min_val, max_val, factor;
5212 offsetT sval;
5214 operand = (const struct mips_int_operand *) operand_base;
5215 factor = 1 << operand->shift;
5216 min_val = mips_int_operand_min (operand);
5217 max_val = mips_int_operand_max (operand);
5219 if (operand_base->lsb == 0
5220 && operand_base->size == 16
5221 && operand->shift == 0
5222 && operand->bias == 0
5223 && (operand->max_val == 32767 || operand->max_val == 65535))
5225 /* The operand can be relocated. */
5226 if (!match_expression (arg, &offset_expr, offset_reloc))
5227 return FALSE;
5229 if (offset_expr.X_op == O_big)
5231 match_out_of_range (arg);
5232 return FALSE;
5235 if (offset_reloc[0] != BFD_RELOC_UNUSED)
5236 /* Relocation operators were used. Accept the argument and
5237 leave the relocation value in offset_expr and offset_relocs
5238 for the caller to process. */
5239 return TRUE;
5241 if (offset_expr.X_op != O_constant)
5243 /* Accept non-constant operands if no later alternative matches,
5244 leaving it for the caller to process. */
5245 if (!arg->lax_match)
5247 match_not_constant (arg);
5248 return FALSE;
5250 offset_reloc[0] = BFD_RELOC_LO16;
5251 return TRUE;
5254 /* Clear the global state; we're going to install the operand
5255 ourselves. */
5256 sval = offset_expr.X_add_number;
5257 offset_expr.X_op = O_absent;
5259 /* For compatibility with older assemblers, we accept
5260 0x8000-0xffff as signed 16-bit numbers when only
5261 signed numbers are allowed. */
5262 if (sval > max_val)
5264 max_val = ((1 << operand_base->size) - 1) << operand->shift;
5265 if (!arg->lax_match && sval <= max_val)
5267 match_out_of_range (arg);
5268 return FALSE;
5272 else
5274 if (!match_const_int (arg, &sval))
5275 return FALSE;
5278 arg->last_op_int = sval;
5280 if (sval < min_val || sval > max_val || sval % factor)
5282 match_out_of_range (arg);
5283 return FALSE;
5286 uval = (unsigned int) sval >> operand->shift;
5287 uval -= operand->bias;
5289 /* Handle -mfix-cn63xxp1. */
5290 if (arg->opnum == 1
5291 && mips_fix_cn63xxp1
5292 && !mips_opts.micromips
5293 && strcmp ("pref", arg->insn->insn_mo->name) == 0)
5294 switch (uval)
5296 case 5:
5297 case 25:
5298 case 26:
5299 case 27:
5300 case 28:
5301 case 29:
5302 case 30:
5303 case 31:
5304 /* These are ok. */
5305 break;
5307 default:
5308 /* The rest must be changed to 28. */
5309 uval = 28;
5310 break;
5313 insn_insert_operand (arg->insn, operand_base, uval);
5314 return TRUE;
5317 /* OP_MAPPED_INT matcher. */
5319 static bfd_boolean
5320 match_mapped_int_operand (struct mips_arg_info *arg,
5321 const struct mips_operand *operand_base)
5323 const struct mips_mapped_int_operand *operand;
5324 unsigned int uval, num_vals;
5325 offsetT sval;
5327 operand = (const struct mips_mapped_int_operand *) operand_base;
5328 if (!match_const_int (arg, &sval))
5329 return FALSE;
5331 num_vals = 1 << operand_base->size;
5332 for (uval = 0; uval < num_vals; uval++)
5333 if (operand->int_map[uval] == sval)
5334 break;
5335 if (uval == num_vals)
5337 match_out_of_range (arg);
5338 return FALSE;
5341 insn_insert_operand (arg->insn, operand_base, uval);
5342 return TRUE;
5345 /* OP_MSB matcher. */
5347 static bfd_boolean
5348 match_msb_operand (struct mips_arg_info *arg,
5349 const struct mips_operand *operand_base)
5351 const struct mips_msb_operand *operand;
5352 int min_val, max_val, max_high;
5353 offsetT size, sval, high;
5355 operand = (const struct mips_msb_operand *) operand_base;
5356 min_val = operand->bias;
5357 max_val = min_val + (1 << operand_base->size) - 1;
5358 max_high = operand->opsize;
5360 if (!match_const_int (arg, &size))
5361 return FALSE;
5363 high = size + arg->last_op_int;
5364 sval = operand->add_lsb ? high : size;
5366 if (size < 0 || high > max_high || sval < min_val || sval > max_val)
5368 match_out_of_range (arg);
5369 return FALSE;
5371 insn_insert_operand (arg->insn, operand_base, sval - min_val);
5372 return TRUE;
5375 /* OP_REG matcher. */
5377 static bfd_boolean
5378 match_reg_operand (struct mips_arg_info *arg,
5379 const struct mips_operand *operand_base)
5381 const struct mips_reg_operand *operand;
5382 unsigned int regno, uval, num_vals;
5384 operand = (const struct mips_reg_operand *) operand_base;
5385 if (!match_reg (arg, operand->reg_type, &regno))
5386 return FALSE;
5388 if (operand->reg_map)
5390 num_vals = 1 << operand->root.size;
5391 for (uval = 0; uval < num_vals; uval++)
5392 if (operand->reg_map[uval] == regno)
5393 break;
5394 if (num_vals == uval)
5395 return FALSE;
5397 else
5398 uval = regno;
5400 arg->last_regno = regno;
5401 if (arg->opnum == 1)
5402 arg->dest_regno = regno;
5403 insn_insert_operand (arg->insn, operand_base, uval);
5404 return TRUE;
5407 /* OP_REG_PAIR matcher. */
5409 static bfd_boolean
5410 match_reg_pair_operand (struct mips_arg_info *arg,
5411 const struct mips_operand *operand_base)
5413 const struct mips_reg_pair_operand *operand;
5414 unsigned int regno1, regno2, uval, num_vals;
5416 operand = (const struct mips_reg_pair_operand *) operand_base;
5417 if (!match_reg (arg, operand->reg_type, &regno1)
5418 || !match_char (arg, ',')
5419 || !match_reg (arg, operand->reg_type, &regno2))
5420 return FALSE;
5422 num_vals = 1 << operand_base->size;
5423 for (uval = 0; uval < num_vals; uval++)
5424 if (operand->reg1_map[uval] == regno1 && operand->reg2_map[uval] == regno2)
5425 break;
5426 if (uval == num_vals)
5427 return FALSE;
5429 insn_insert_operand (arg->insn, operand_base, uval);
5430 return TRUE;
5433 /* OP_PCREL matcher. The caller chooses the relocation type. */
5435 static bfd_boolean
5436 match_pcrel_operand (struct mips_arg_info *arg)
5438 bfd_reloc_code_real_type r[3];
5440 return match_expression (arg, &offset_expr, r) && r[0] == BFD_RELOC_UNUSED;
5443 /* OP_PERF_REG matcher. */
5445 static bfd_boolean
5446 match_perf_reg_operand (struct mips_arg_info *arg,
5447 const struct mips_operand *operand)
5449 offsetT sval;
5451 if (!match_const_int (arg, &sval))
5452 return FALSE;
5454 if (sval != 0
5455 && (sval != 1
5456 || (mips_opts.arch == CPU_R5900
5457 && (strcmp (arg->insn->insn_mo->name, "mfps") == 0
5458 || strcmp (arg->insn->insn_mo->name, "mtps") == 0))))
5460 set_insn_error (arg->argnum, _("invalid performance register"));
5461 return FALSE;
5464 insn_insert_operand (arg->insn, operand, sval);
5465 return TRUE;
5468 /* OP_ADDIUSP matcher. */
5470 static bfd_boolean
5471 match_addiusp_operand (struct mips_arg_info *arg,
5472 const struct mips_operand *operand)
5474 offsetT sval;
5475 unsigned int uval;
5477 if (!match_const_int (arg, &sval))
5478 return FALSE;
5480 if (sval % 4)
5482 match_out_of_range (arg);
5483 return FALSE;
5486 sval /= 4;
5487 if (!(sval >= -258 && sval <= 257) || (sval >= -2 && sval <= 1))
5489 match_out_of_range (arg);
5490 return FALSE;
5493 uval = (unsigned int) sval;
5494 uval = ((uval >> 1) & ~0xff) | (uval & 0xff);
5495 insn_insert_operand (arg->insn, operand, uval);
5496 return TRUE;
5499 /* OP_CLO_CLZ_DEST matcher. */
5501 static bfd_boolean
5502 match_clo_clz_dest_operand (struct mips_arg_info *arg,
5503 const struct mips_operand *operand)
5505 unsigned int regno;
5507 if (!match_reg (arg, OP_REG_GP, &regno))
5508 return FALSE;
5510 insn_insert_operand (arg->insn, operand, regno | (regno << 5));
5511 return TRUE;
5514 /* OP_CHECK_PREV matcher. */
5516 static bfd_boolean
5517 match_check_prev_operand (struct mips_arg_info *arg,
5518 const struct mips_operand *operand_base)
5520 const struct mips_check_prev_operand *operand;
5521 unsigned int regno;
5523 operand = (const struct mips_check_prev_operand *) operand_base;
5525 if (!match_reg (arg, OP_REG_GP, &regno))
5526 return FALSE;
5528 if (!operand->zero_ok && regno == 0)
5529 return FALSE;
5531 if ((operand->less_than_ok && regno < arg->last_regno)
5532 || (operand->greater_than_ok && regno > arg->last_regno)
5533 || (operand->equal_ok && regno == arg->last_regno))
5535 arg->last_regno = regno;
5536 insn_insert_operand (arg->insn, operand_base, regno);
5537 return TRUE;
5540 return FALSE;
5543 /* OP_SAME_RS_RT matcher. */
5545 static bfd_boolean
5546 match_same_rs_rt_operand (struct mips_arg_info *arg,
5547 const struct mips_operand *operand)
5549 unsigned int regno;
5551 if (!match_reg (arg, OP_REG_GP, &regno))
5552 return FALSE;
5554 if (regno == 0)
5556 set_insn_error (arg->argnum, _("the source register must not be $0"));
5557 return FALSE;
5560 arg->last_regno = regno;
5562 insn_insert_operand (arg->insn, operand, regno | (regno << 5));
5563 return TRUE;
5566 /* OP_LWM_SWM_LIST matcher. */
5568 static bfd_boolean
5569 match_lwm_swm_list_operand (struct mips_arg_info *arg,
5570 const struct mips_operand *operand)
5572 unsigned int reglist, sregs, ra, regno1, regno2;
5573 struct mips_arg_info reset;
5575 reglist = 0;
5576 if (!match_reg_range (arg, OP_REG_GP, &regno1, &regno2))
5577 return FALSE;
5580 if (regno2 == FP && regno1 >= S0 && regno1 <= S7)
5582 reglist |= 1 << FP;
5583 regno2 = S7;
5585 reglist |= ((1U << regno2 << 1) - 1) & -(1U << regno1);
5586 reset = *arg;
5588 while (match_char (arg, ',')
5589 && match_reg_range (arg, OP_REG_GP, &regno1, &regno2));
5590 *arg = reset;
5592 if (operand->size == 2)
5594 /* The list must include both ra and s0-sN, for 0 <= N <= 3. E.g.:
5596 s0, ra
5597 s0, s1, ra, s2, s3
5598 s0-s2, ra
5600 and any permutations of these. */
5601 if ((reglist & 0xfff1ffff) != 0x80010000)
5602 return FALSE;
5604 sregs = (reglist >> 17) & 7;
5605 ra = 0;
5607 else
5609 /* The list must include at least one of ra and s0-sN,
5610 for 0 <= N <= 8. (Note that there is a gap between s7 and s8,
5611 which are $23 and $30 respectively.) E.g.:
5615 ra, s0, s1, s2
5616 s0-s8
5617 s0-s5, ra
5619 and any permutations of these. */
5620 if ((reglist & 0x3f00ffff) != 0)
5621 return FALSE;
5623 ra = (reglist >> 27) & 0x10;
5624 sregs = ((reglist >> 22) & 0x100) | ((reglist >> 16) & 0xff);
5626 sregs += 1;
5627 if ((sregs & -sregs) != sregs)
5628 return FALSE;
5630 insn_insert_operand (arg->insn, operand, (ffs (sregs) - 1) | ra);
5631 return TRUE;
5634 /* OP_ENTRY_EXIT_LIST matcher. */
5636 static unsigned int
5637 match_entry_exit_operand (struct mips_arg_info *arg,
5638 const struct mips_operand *operand)
5640 unsigned int mask;
5641 bfd_boolean is_exit;
5643 /* The format is the same for both ENTRY and EXIT, but the constraints
5644 are different. */
5645 is_exit = strcmp (arg->insn->insn_mo->name, "exit") == 0;
5646 mask = (is_exit ? 7 << 3 : 0);
5649 unsigned int regno1, regno2;
5650 bfd_boolean is_freg;
5652 if (match_reg_range (arg, OP_REG_GP, &regno1, &regno2))
5653 is_freg = FALSE;
5654 else if (match_reg_range (arg, OP_REG_FP, &regno1, &regno2))
5655 is_freg = TRUE;
5656 else
5657 return FALSE;
5659 if (is_exit && is_freg && regno1 == 0 && regno2 < 2)
5661 mask &= ~(7 << 3);
5662 mask |= (5 + regno2) << 3;
5664 else if (!is_exit && regno1 == 4 && regno2 >= 4 && regno2 <= 7)
5665 mask |= (regno2 - 3) << 3;
5666 else if (regno1 == 16 && regno2 >= 16 && regno2 <= 17)
5667 mask |= (regno2 - 15) << 1;
5668 else if (regno1 == RA && regno2 == RA)
5669 mask |= 1;
5670 else
5671 return FALSE;
5673 while (match_char (arg, ','));
5675 insn_insert_operand (arg->insn, operand, mask);
5676 return TRUE;
5679 /* Encode regular MIPS SAVE/RESTORE instruction operands according to
5680 the argument register mask AMASK, the number of static registers
5681 saved NSREG, the $ra, $s0 and $s1 register specifiers RA, S0 and S1
5682 respectively, and the frame size FRAME_SIZE. */
5684 static unsigned int
5685 mips_encode_save_restore (unsigned int amask, unsigned int nsreg,
5686 unsigned int ra, unsigned int s0, unsigned int s1,
5687 unsigned int frame_size)
5689 return ((nsreg << 23) | ((frame_size & 0xf0) << 15) | (amask << 15)
5690 | (ra << 12) | (s0 << 11) | (s1 << 10) | ((frame_size & 0xf) << 6));
5693 /* Encode MIPS16 SAVE/RESTORE instruction operands according to the
5694 argument register mask AMASK, the number of static registers saved
5695 NSREG, the $ra, $s0 and $s1 register specifiers RA, S0 and S1
5696 respectively, and the frame size FRAME_SIZE. */
5698 static unsigned int
5699 mips16_encode_save_restore (unsigned int amask, unsigned int nsreg,
5700 unsigned int ra, unsigned int s0, unsigned int s1,
5701 unsigned int frame_size)
5703 unsigned int args;
5705 args = (ra << 6) | (s0 << 5) | (s1 << 4) | (frame_size & 0xf);
5706 if (nsreg || amask || frame_size == 0 || frame_size > 16)
5707 args |= (MIPS16_EXTEND | (nsreg << 24) | (amask << 16)
5708 | ((frame_size & 0xf0) << 16));
5709 return args;
5712 /* OP_SAVE_RESTORE_LIST matcher. */
5714 static bfd_boolean
5715 match_save_restore_list_operand (struct mips_arg_info *arg)
5717 unsigned int opcode, args, statics, sregs;
5718 unsigned int num_frame_sizes, num_args, num_statics, num_sregs;
5719 unsigned int arg_mask, ra, s0, s1;
5720 offsetT frame_size;
5722 opcode = arg->insn->insn_opcode;
5723 frame_size = 0;
5724 num_frame_sizes = 0;
5725 args = 0;
5726 statics = 0;
5727 sregs = 0;
5728 ra = 0;
5729 s0 = 0;
5730 s1 = 0;
5733 unsigned int regno1, regno2;
5735 if (arg->token->type == OT_INTEGER)
5737 /* Handle the frame size. */
5738 if (!match_const_int (arg, &frame_size))
5739 return FALSE;
5740 num_frame_sizes += 1;
5742 else
5744 if (!match_reg_range (arg, OP_REG_GP, &regno1, &regno2))
5745 return FALSE;
5747 while (regno1 <= regno2)
5749 if (regno1 >= 4 && regno1 <= 7)
5751 if (num_frame_sizes == 0)
5752 /* args $a0-$a3 */
5753 args |= 1 << (regno1 - 4);
5754 else
5755 /* statics $a0-$a3 */
5756 statics |= 1 << (regno1 - 4);
5758 else if (regno1 >= 16 && regno1 <= 23)
5759 /* $s0-$s7 */
5760 sregs |= 1 << (regno1 - 16);
5761 else if (regno1 == 30)
5762 /* $s8 */
5763 sregs |= 1 << 8;
5764 else if (regno1 == 31)
5765 /* Add $ra to insn. */
5766 ra = 1;
5767 else
5768 return FALSE;
5769 regno1 += 1;
5770 if (regno1 == 24)
5771 regno1 = 30;
5775 while (match_char (arg, ','));
5777 /* Encode args/statics combination. */
5778 if (args & statics)
5779 return FALSE;
5780 else if (args == 0xf)
5781 /* All $a0-$a3 are args. */
5782 arg_mask = MIPS_SVRS_ALL_ARGS;
5783 else if (statics == 0xf)
5784 /* All $a0-$a3 are statics. */
5785 arg_mask = MIPS_SVRS_ALL_STATICS;
5786 else
5788 /* Count arg registers. */
5789 num_args = 0;
5790 while (args & 0x1)
5792 args >>= 1;
5793 num_args += 1;
5795 if (args != 0)
5796 return FALSE;
5798 /* Count static registers. */
5799 num_statics = 0;
5800 while (statics & 0x8)
5802 statics = (statics << 1) & 0xf;
5803 num_statics += 1;
5805 if (statics != 0)
5806 return FALSE;
5808 /* Encode args/statics. */
5809 arg_mask = (num_args << 2) | num_statics;
5812 /* Encode $s0/$s1. */
5813 if (sregs & (1 << 0)) /* $s0 */
5814 s0 = 1;
5815 if (sregs & (1 << 1)) /* $s1 */
5816 s1 = 1;
5817 sregs >>= 2;
5819 /* Encode $s2-$s8. */
5820 num_sregs = 0;
5821 while (sregs & 1)
5823 sregs >>= 1;
5824 num_sregs += 1;
5826 if (sregs != 0)
5827 return FALSE;
5829 /* Encode frame size. */
5830 if (num_frame_sizes == 0)
5832 set_insn_error (arg->argnum, _("missing frame size"));
5833 return FALSE;
5835 if (num_frame_sizes > 1)
5837 set_insn_error (arg->argnum, _("frame size specified twice"));
5838 return FALSE;
5840 if ((frame_size & 7) != 0 || frame_size < 0 || frame_size > 0xff * 8)
5842 set_insn_error (arg->argnum, _("invalid frame size"));
5843 return FALSE;
5845 frame_size /= 8;
5847 /* Finally build the instruction. */
5848 if (mips_opts.mips16)
5849 opcode |= mips16_encode_save_restore (arg_mask, num_sregs, ra, s0, s1,
5850 frame_size);
5851 else if (!mips_opts.micromips)
5852 opcode |= mips_encode_save_restore (arg_mask, num_sregs, ra, s0, s1,
5853 frame_size);
5854 else
5855 abort ();
5857 arg->insn->insn_opcode = opcode;
5858 return TRUE;
5861 /* OP_MDMX_IMM_REG matcher. */
5863 static bfd_boolean
5864 match_mdmx_imm_reg_operand (struct mips_arg_info *arg,
5865 const struct mips_operand *operand)
5867 unsigned int regno, uval;
5868 bfd_boolean is_qh;
5869 const struct mips_opcode *opcode;
5871 /* The mips_opcode records whether this is an octobyte or quadhalf
5872 instruction. Start out with that bit in place. */
5873 opcode = arg->insn->insn_mo;
5874 uval = mips_extract_operand (operand, opcode->match);
5875 is_qh = (uval != 0);
5877 if (arg->token->type == OT_REG)
5879 if ((opcode->membership & INSN_5400)
5880 && strcmp (opcode->name, "rzu.ob") == 0)
5882 set_insn_error_i (arg->argnum, _("operand %d must be an immediate"),
5883 arg->argnum);
5884 return FALSE;
5887 if (!match_regno (arg, OP_REG_VEC, arg->token->u.regno, &regno))
5888 return FALSE;
5889 ++arg->token;
5891 /* Check whether this is a vector register or a broadcast of
5892 a single element. */
5893 if (arg->token->type == OT_INTEGER_INDEX)
5895 if (arg->token->u.index > (is_qh ? 3 : 7))
5897 set_insn_error (arg->argnum, _("invalid element selector"));
5898 return FALSE;
5900 uval |= arg->token->u.index << (is_qh ? 2 : 1) << 5;
5901 ++arg->token;
5903 else
5905 /* A full vector. */
5906 if ((opcode->membership & INSN_5400)
5907 && (strcmp (opcode->name, "sll.ob") == 0
5908 || strcmp (opcode->name, "srl.ob") == 0))
5910 set_insn_error_i (arg->argnum, _("operand %d must be scalar"),
5911 arg->argnum);
5912 return FALSE;
5915 if (is_qh)
5916 uval |= MDMX_FMTSEL_VEC_QH << 5;
5917 else
5918 uval |= MDMX_FMTSEL_VEC_OB << 5;
5920 uval |= regno;
5922 else
5924 offsetT sval;
5926 if (!match_const_int (arg, &sval))
5927 return FALSE;
5928 if (sval < 0 || sval > 31)
5930 match_out_of_range (arg);
5931 return FALSE;
5933 uval |= (sval & 31);
5934 if (is_qh)
5935 uval |= MDMX_FMTSEL_IMM_QH << 5;
5936 else
5937 uval |= MDMX_FMTSEL_IMM_OB << 5;
5939 insn_insert_operand (arg->insn, operand, uval);
5940 return TRUE;
5943 /* OP_IMM_INDEX matcher. */
5945 static bfd_boolean
5946 match_imm_index_operand (struct mips_arg_info *arg,
5947 const struct mips_operand *operand)
5949 unsigned int max_val;
5951 if (arg->token->type != OT_INTEGER_INDEX)
5952 return FALSE;
5954 max_val = (1 << operand->size) - 1;
5955 if (arg->token->u.index > max_val)
5957 match_out_of_range (arg);
5958 return FALSE;
5960 insn_insert_operand (arg->insn, operand, arg->token->u.index);
5961 ++arg->token;
5962 return TRUE;
5965 /* OP_REG_INDEX matcher. */
5967 static bfd_boolean
5968 match_reg_index_operand (struct mips_arg_info *arg,
5969 const struct mips_operand *operand)
5971 unsigned int regno;
5973 if (arg->token->type != OT_REG_INDEX)
5974 return FALSE;
5976 if (!match_regno (arg, OP_REG_GP, arg->token->u.regno, &regno))
5977 return FALSE;
5979 insn_insert_operand (arg->insn, operand, regno);
5980 ++arg->token;
5981 return TRUE;
5984 /* OP_PC matcher. */
5986 static bfd_boolean
5987 match_pc_operand (struct mips_arg_info *arg)
5989 if (arg->token->type == OT_REG && (arg->token->u.regno & RTYPE_PC))
5991 ++arg->token;
5992 return TRUE;
5994 return FALSE;
5997 /* OP_REG28 matcher. */
5999 static bfd_boolean
6000 match_reg28_operand (struct mips_arg_info *arg)
6002 unsigned int regno;
6004 if (arg->token->type == OT_REG
6005 && match_regno (arg, OP_REG_GP, arg->token->u.regno, &regno)
6006 && regno == GP)
6008 ++arg->token;
6009 return TRUE;
6011 return FALSE;
6014 /* OP_NON_ZERO_REG matcher. */
6016 static bfd_boolean
6017 match_non_zero_reg_operand (struct mips_arg_info *arg,
6018 const struct mips_operand *operand)
6020 unsigned int regno;
6022 if (!match_reg (arg, OP_REG_GP, &regno))
6023 return FALSE;
6025 if (regno == 0)
6027 set_insn_error (arg->argnum, _("the source register must not be $0"));
6028 return FALSE;
6031 arg->last_regno = regno;
6032 insn_insert_operand (arg->insn, operand, regno);
6033 return TRUE;
6036 /* OP_REPEAT_DEST_REG and OP_REPEAT_PREV_REG matcher. OTHER_REGNO is the
6037 register that we need to match. */
6039 static bfd_boolean
6040 match_tied_reg_operand (struct mips_arg_info *arg, unsigned int other_regno)
6042 unsigned int regno;
6044 return match_reg (arg, OP_REG_GP, &regno) && regno == other_regno;
6047 /* Try to match a floating-point constant from ARG for LI.S or LI.D.
6048 LENGTH is the length of the value in bytes (4 for float, 8 for double)
6049 and USING_GPRS says whether the destination is a GPR rather than an FPR.
6051 Return the constant in IMM and OFFSET as follows:
6053 - If the constant should be loaded via memory, set IMM to O_absent and
6054 OFFSET to the memory address.
6056 - Otherwise, if the constant should be loaded into two 32-bit registers,
6057 set IMM to the O_constant to load into the high register and OFFSET
6058 to the corresponding value for the low register.
6060 - Otherwise, set IMM to the full O_constant and set OFFSET to O_absent.
6062 These constants only appear as the last operand in an instruction,
6063 and every instruction that accepts them in any variant accepts them
6064 in all variants. This means we don't have to worry about backing out
6065 any changes if the instruction does not match. We just match
6066 unconditionally and report an error if the constant is invalid. */
6068 static bfd_boolean
6069 match_float_constant (struct mips_arg_info *arg, expressionS *imm,
6070 expressionS *offset, int length, bfd_boolean using_gprs)
6072 char *p;
6073 segT seg, new_seg;
6074 subsegT subseg;
6075 const char *newname;
6076 unsigned char *data;
6078 /* Where the constant is placed is based on how the MIPS assembler
6079 does things:
6081 length == 4 && using_gprs -- immediate value only
6082 length == 8 && using_gprs -- .rdata or immediate value
6083 length == 4 && !using_gprs -- .lit4 or immediate value
6084 length == 8 && !using_gprs -- .lit8 or immediate value
6086 The .lit4 and .lit8 sections are only used if permitted by the
6087 -G argument. */
6088 if (arg->token->type != OT_FLOAT)
6090 set_insn_error (arg->argnum, _("floating-point expression required"));
6091 return FALSE;
6094 gas_assert (arg->token->u.flt.length == length);
6095 data = arg->token->u.flt.data;
6096 ++arg->token;
6098 /* Handle 32-bit constants for which an immediate value is best. */
6099 if (length == 4
6100 && (using_gprs
6101 || g_switch_value < 4
6102 || (data[0] == 0 && data[1] == 0)
6103 || (data[2] == 0 && data[3] == 0)))
6105 imm->X_op = O_constant;
6106 if (!target_big_endian)
6107 imm->X_add_number = bfd_getl32 (data);
6108 else
6109 imm->X_add_number = bfd_getb32 (data);
6110 offset->X_op = O_absent;
6111 return TRUE;
6114 /* Handle 64-bit constants for which an immediate value is best. */
6115 if (length == 8
6116 && !mips_disable_float_construction
6117 /* Constants can only be constructed in GPRs and copied to FPRs if the
6118 GPRs are at least as wide as the FPRs or MTHC1 is available.
6119 Unlike most tests for 32-bit floating-point registers this check
6120 specifically looks for GPR_SIZE == 32 as the FPXX ABI does not
6121 permit 64-bit moves without MXHC1.
6122 Force the constant into memory otherwise. */
6123 && (using_gprs
6124 || GPR_SIZE == 64
6125 || ISA_HAS_MXHC1 (mips_opts.isa)
6126 || FPR_SIZE == 32)
6127 && ((data[0] == 0 && data[1] == 0)
6128 || (data[2] == 0 && data[3] == 0))
6129 && ((data[4] == 0 && data[5] == 0)
6130 || (data[6] == 0 && data[7] == 0)))
6132 /* The value is simple enough to load with a couple of instructions.
6133 If using 32-bit registers, set IMM to the high order 32 bits and
6134 OFFSET to the low order 32 bits. Otherwise, set IMM to the entire
6135 64 bit constant. */
6136 if (GPR_SIZE == 32 || (!using_gprs && FPR_SIZE != 64))
6138 imm->X_op = O_constant;
6139 offset->X_op = O_constant;
6140 if (!target_big_endian)
6142 imm->X_add_number = bfd_getl32 (data + 4);
6143 offset->X_add_number = bfd_getl32 (data);
6145 else
6147 imm->X_add_number = bfd_getb32 (data);
6148 offset->X_add_number = bfd_getb32 (data + 4);
6150 if (offset->X_add_number == 0)
6151 offset->X_op = O_absent;
6153 else
6155 imm->X_op = O_constant;
6156 if (!target_big_endian)
6157 imm->X_add_number = bfd_getl64 (data);
6158 else
6159 imm->X_add_number = bfd_getb64 (data);
6160 offset->X_op = O_absent;
6162 return TRUE;
6165 /* Switch to the right section. */
6166 seg = now_seg;
6167 subseg = now_subseg;
6168 if (length == 4)
6170 gas_assert (!using_gprs && g_switch_value >= 4);
6171 newname = ".lit4";
6173 else
6175 if (using_gprs || g_switch_value < 8)
6176 newname = RDATA_SECTION_NAME;
6177 else
6178 newname = ".lit8";
6181 new_seg = subseg_new (newname, (subsegT) 0);
6182 bfd_set_section_flags (stdoutput, new_seg,
6183 SEC_ALLOC | SEC_LOAD | SEC_READONLY | SEC_DATA);
6184 frag_align (length == 4 ? 2 : 3, 0, 0);
6185 if (strncmp (TARGET_OS, "elf", 3) != 0)
6186 record_alignment (new_seg, 4);
6187 else
6188 record_alignment (new_seg, length == 4 ? 2 : 3);
6189 if (seg == now_seg)
6190 as_bad (_("cannot use `%s' in this section"), arg->insn->insn_mo->name);
6192 /* Set the argument to the current address in the section. */
6193 imm->X_op = O_absent;
6194 offset->X_op = O_symbol;
6195 offset->X_add_symbol = symbol_temp_new_now ();
6196 offset->X_add_number = 0;
6198 /* Put the floating point number into the section. */
6199 p = frag_more (length);
6200 memcpy (p, data, length);
6202 /* Switch back to the original section. */
6203 subseg_set (seg, subseg);
6204 return TRUE;
6207 /* OP_VU0_SUFFIX and OP_VU0_MATCH_SUFFIX matcher; MATCH_P selects between
6208 them. */
6210 static bfd_boolean
6211 match_vu0_suffix_operand (struct mips_arg_info *arg,
6212 const struct mips_operand *operand,
6213 bfd_boolean match_p)
6215 unsigned int uval;
6217 /* The operand can be an XYZW mask or a single 2-bit channel index
6218 (with X being 0). */
6219 gas_assert (operand->size == 2 || operand->size == 4);
6221 /* The suffix can be omitted when it is already part of the opcode. */
6222 if (arg->token->type != OT_CHANNELS)
6223 return match_p;
6225 uval = arg->token->u.channels;
6226 if (operand->size == 2)
6228 /* Check that a single bit is set and convert it into a 2-bit index. */
6229 if ((uval & -uval) != uval)
6230 return FALSE;
6231 uval = 4 - ffs (uval);
6234 if (match_p && insn_extract_operand (arg->insn, operand) != uval)
6235 return FALSE;
6237 ++arg->token;
6238 if (!match_p)
6239 insn_insert_operand (arg->insn, operand, uval);
6240 return TRUE;
6243 /* Try to match a token from ARG against OPERAND. Consume the token
6244 and return true on success, otherwise return false. */
6246 static bfd_boolean
6247 match_operand (struct mips_arg_info *arg,
6248 const struct mips_operand *operand)
6250 switch (operand->type)
6252 case OP_INT:
6253 return match_int_operand (arg, operand);
6255 case OP_MAPPED_INT:
6256 return match_mapped_int_operand (arg, operand);
6258 case OP_MSB:
6259 return match_msb_operand (arg, operand);
6261 case OP_REG:
6262 case OP_OPTIONAL_REG:
6263 return match_reg_operand (arg, operand);
6265 case OP_REG_PAIR:
6266 return match_reg_pair_operand (arg, operand);
6268 case OP_PCREL:
6269 return match_pcrel_operand (arg);
6271 case OP_PERF_REG:
6272 return match_perf_reg_operand (arg, operand);
6274 case OP_ADDIUSP_INT:
6275 return match_addiusp_operand (arg, operand);
6277 case OP_CLO_CLZ_DEST:
6278 return match_clo_clz_dest_operand (arg, operand);
6280 case OP_LWM_SWM_LIST:
6281 return match_lwm_swm_list_operand (arg, operand);
6283 case OP_ENTRY_EXIT_LIST:
6284 return match_entry_exit_operand (arg, operand);
6286 case OP_SAVE_RESTORE_LIST:
6287 return match_save_restore_list_operand (arg);
6289 case OP_MDMX_IMM_REG:
6290 return match_mdmx_imm_reg_operand (arg, operand);
6292 case OP_REPEAT_DEST_REG:
6293 return match_tied_reg_operand (arg, arg->dest_regno);
6295 case OP_REPEAT_PREV_REG:
6296 return match_tied_reg_operand (arg, arg->last_regno);
6298 case OP_PC:
6299 return match_pc_operand (arg);
6301 case OP_REG28:
6302 return match_reg28_operand (arg);
6304 case OP_VU0_SUFFIX:
6305 return match_vu0_suffix_operand (arg, operand, FALSE);
6307 case OP_VU0_MATCH_SUFFIX:
6308 return match_vu0_suffix_operand (arg, operand, TRUE);
6310 case OP_IMM_INDEX:
6311 return match_imm_index_operand (arg, operand);
6313 case OP_REG_INDEX:
6314 return match_reg_index_operand (arg, operand);
6316 case OP_SAME_RS_RT:
6317 return match_same_rs_rt_operand (arg, operand);
6319 case OP_CHECK_PREV:
6320 return match_check_prev_operand (arg, operand);
6322 case OP_NON_ZERO_REG:
6323 return match_non_zero_reg_operand (arg, operand);
6325 abort ();
6328 /* ARG is the state after successfully matching an instruction.
6329 Issue any queued-up warnings. */
6331 static void
6332 check_completed_insn (struct mips_arg_info *arg)
6334 if (arg->seen_at)
6336 if (AT == ATREG)
6337 as_warn (_("used $at without \".set noat\""));
6338 else
6339 as_warn (_("used $%u with \".set at=$%u\""), AT, AT);
6343 /* Return true if modifying general-purpose register REG needs a delay. */
6345 static bfd_boolean
6346 reg_needs_delay (unsigned int reg)
6348 unsigned long prev_pinfo;
6350 prev_pinfo = history[0].insn_mo->pinfo;
6351 if (!mips_opts.noreorder
6352 && (((prev_pinfo & INSN_LOAD_MEMORY) && !gpr_interlocks)
6353 || ((prev_pinfo & INSN_LOAD_COPROC) && !cop_interlocks))
6354 && (gpr_write_mask (&history[0]) & (1 << reg)))
6355 return TRUE;
6357 return FALSE;
6360 /* Classify an instruction according to the FIX_VR4120_* enumeration.
6361 Return NUM_FIX_VR4120_CLASSES if the instruction isn't affected
6362 by VR4120 errata. */
6364 static unsigned int
6365 classify_vr4120_insn (const char *name)
6367 if (strncmp (name, "macc", 4) == 0)
6368 return FIX_VR4120_MACC;
6369 if (strncmp (name, "dmacc", 5) == 0)
6370 return FIX_VR4120_DMACC;
6371 if (strncmp (name, "mult", 4) == 0)
6372 return FIX_VR4120_MULT;
6373 if (strncmp (name, "dmult", 5) == 0)
6374 return FIX_VR4120_DMULT;
6375 if (strstr (name, "div"))
6376 return FIX_VR4120_DIV;
6377 if (strcmp (name, "mtlo") == 0 || strcmp (name, "mthi") == 0)
6378 return FIX_VR4120_MTHILO;
6379 return NUM_FIX_VR4120_CLASSES;
6382 #define INSN_ERET 0x42000018
6383 #define INSN_DERET 0x4200001f
6384 #define INSN_DMULT 0x1c
6385 #define INSN_DMULTU 0x1d
6387 /* Return the number of instructions that must separate INSN1 and INSN2,
6388 where INSN1 is the earlier instruction. Return the worst-case value
6389 for any INSN2 if INSN2 is null. */
6391 static unsigned int
6392 insns_between (const struct mips_cl_insn *insn1,
6393 const struct mips_cl_insn *insn2)
6395 unsigned long pinfo1, pinfo2;
6396 unsigned int mask;
6398 /* If INFO2 is null, pessimistically assume that all flags are set for
6399 the second instruction. */
6400 pinfo1 = insn1->insn_mo->pinfo;
6401 pinfo2 = insn2 ? insn2->insn_mo->pinfo : ~0U;
6403 /* For most targets, write-after-read dependencies on the HI and LO
6404 registers must be separated by at least two instructions. */
6405 if (!hilo_interlocks)
6407 if ((pinfo1 & INSN_READ_LO) && (pinfo2 & INSN_WRITE_LO))
6408 return 2;
6409 if ((pinfo1 & INSN_READ_HI) && (pinfo2 & INSN_WRITE_HI))
6410 return 2;
6413 /* If we're working around r7000 errata, there must be two instructions
6414 between an mfhi or mflo and any instruction that uses the result. */
6415 if (mips_7000_hilo_fix
6416 && !mips_opts.micromips
6417 && MF_HILO_INSN (pinfo1)
6418 && (insn2 == NULL || (gpr_read_mask (insn2) & gpr_write_mask (insn1))))
6419 return 2;
6421 /* If we're working around 24K errata, one instruction is required
6422 if an ERET or DERET is followed by a branch instruction. */
6423 if (mips_fix_24k && !mips_opts.micromips)
6425 if (insn1->insn_opcode == INSN_ERET
6426 || insn1->insn_opcode == INSN_DERET)
6428 if (insn2 == NULL
6429 || insn2->insn_opcode == INSN_ERET
6430 || insn2->insn_opcode == INSN_DERET
6431 || delayed_branch_p (insn2))
6432 return 1;
6436 /* If we're working around PMC RM7000 errata, there must be three
6437 nops between a dmult and a load instruction. */
6438 if (mips_fix_rm7000 && !mips_opts.micromips)
6440 if ((insn1->insn_opcode & insn1->insn_mo->mask) == INSN_DMULT
6441 || (insn1->insn_opcode & insn1->insn_mo->mask) == INSN_DMULTU)
6443 if (pinfo2 & INSN_LOAD_MEMORY)
6444 return 3;
6448 /* If working around VR4120 errata, check for combinations that need
6449 a single intervening instruction. */
6450 if (mips_fix_vr4120 && !mips_opts.micromips)
6452 unsigned int class1, class2;
6454 class1 = classify_vr4120_insn (insn1->insn_mo->name);
6455 if (class1 != NUM_FIX_VR4120_CLASSES && vr4120_conflicts[class1] != 0)
6457 if (insn2 == NULL)
6458 return 1;
6459 class2 = classify_vr4120_insn (insn2->insn_mo->name);
6460 if (vr4120_conflicts[class1] & (1 << class2))
6461 return 1;
6465 if (!HAVE_CODE_COMPRESSION)
6467 /* Check for GPR or coprocessor load delays. All such delays
6468 are on the RT register. */
6469 /* Itbl support may require additional care here. */
6470 if ((!gpr_interlocks && (pinfo1 & INSN_LOAD_MEMORY))
6471 || (!cop_interlocks && (pinfo1 & INSN_LOAD_COPROC)))
6473 if (insn2 == NULL || (gpr_read_mask (insn2) & gpr_write_mask (insn1)))
6474 return 1;
6477 /* Check for generic coprocessor hazards.
6479 This case is not handled very well. There is no special
6480 knowledge of CP0 handling, and the coprocessors other than
6481 the floating point unit are not distinguished at all. */
6482 /* Itbl support may require additional care here. FIXME!
6483 Need to modify this to include knowledge about
6484 user specified delays! */
6485 else if ((!cop_interlocks && (pinfo1 & INSN_COPROC_MOVE))
6486 || (!cop_mem_interlocks && (pinfo1 & INSN_COPROC_MEMORY_DELAY)))
6488 /* Handle cases where INSN1 writes to a known general coprocessor
6489 register. There must be a one instruction delay before INSN2
6490 if INSN2 reads that register, otherwise no delay is needed. */
6491 mask = fpr_write_mask (insn1);
6492 if (mask != 0)
6494 if (!insn2 || (mask & fpr_read_mask (insn2)) != 0)
6495 return 1;
6497 else
6499 /* Read-after-write dependencies on the control registers
6500 require a two-instruction gap. */
6501 if ((pinfo1 & INSN_WRITE_COND_CODE)
6502 && (pinfo2 & INSN_READ_COND_CODE))
6503 return 2;
6505 /* We don't know exactly what INSN1 does. If INSN2 is
6506 also a coprocessor instruction, assume there must be
6507 a one instruction gap. */
6508 if (pinfo2 & INSN_COP)
6509 return 1;
6513 /* Check for read-after-write dependencies on the coprocessor
6514 control registers in cases where INSN1 does not need a general
6515 coprocessor delay. This means that INSN1 is a floating point
6516 comparison instruction. */
6517 /* Itbl support may require additional care here. */
6518 else if (!cop_interlocks
6519 && (pinfo1 & INSN_WRITE_COND_CODE)
6520 && (pinfo2 & INSN_READ_COND_CODE))
6521 return 1;
6524 /* Forbidden slots can not contain Control Transfer Instructions (CTIs)
6525 CTIs include all branches and jumps, nal, eret, eretnc, deret, wait
6526 and pause. */
6527 if ((insn1->insn_mo->pinfo2 & INSN2_FORBIDDEN_SLOT)
6528 && ((pinfo2 & INSN_NO_DELAY_SLOT)
6529 || (insn2 && delayed_branch_p (insn2))))
6530 return 1;
6532 return 0;
6535 /* Return the number of nops that would be needed to work around the
6536 VR4130 mflo/mfhi errata if instruction INSN immediately followed
6537 the MAX_VR4130_NOPS instructions described by HIST. Ignore hazards
6538 that are contained within the first IGNORE instructions of HIST. */
6540 static int
6541 nops_for_vr4130 (int ignore, const struct mips_cl_insn *hist,
6542 const struct mips_cl_insn *insn)
6544 int i, j;
6545 unsigned int mask;
6547 /* Check if the instruction writes to HI or LO. MTHI and MTLO
6548 are not affected by the errata. */
6549 if (insn != 0
6550 && ((insn->insn_mo->pinfo & (INSN_WRITE_HI | INSN_WRITE_LO)) == 0
6551 || strcmp (insn->insn_mo->name, "mtlo") == 0
6552 || strcmp (insn->insn_mo->name, "mthi") == 0))
6553 return 0;
6555 /* Search for the first MFLO or MFHI. */
6556 for (i = 0; i < MAX_VR4130_NOPS; i++)
6557 if (MF_HILO_INSN (hist[i].insn_mo->pinfo))
6559 /* Extract the destination register. */
6560 mask = gpr_write_mask (&hist[i]);
6562 /* No nops are needed if INSN reads that register. */
6563 if (insn != NULL && (gpr_read_mask (insn) & mask) != 0)
6564 return 0;
6566 /* ...or if any of the intervening instructions do. */
6567 for (j = 0; j < i; j++)
6568 if (gpr_read_mask (&hist[j]) & mask)
6569 return 0;
6571 if (i >= ignore)
6572 return MAX_VR4130_NOPS - i;
6574 return 0;
6577 #define BASE_REG_EQ(INSN1, INSN2) \
6578 ((((INSN1) >> OP_SH_RS) & OP_MASK_RS) \
6579 == (((INSN2) >> OP_SH_RS) & OP_MASK_RS))
6581 /* Return the minimum alignment for this store instruction. */
6583 static int
6584 fix_24k_align_to (const struct mips_opcode *mo)
6586 if (strcmp (mo->name, "sh") == 0)
6587 return 2;
6589 if (strcmp (mo->name, "swc1") == 0
6590 || strcmp (mo->name, "swc2") == 0
6591 || strcmp (mo->name, "sw") == 0
6592 || strcmp (mo->name, "sc") == 0
6593 || strcmp (mo->name, "s.s") == 0)
6594 return 4;
6596 if (strcmp (mo->name, "sdc1") == 0
6597 || strcmp (mo->name, "sdc2") == 0
6598 || strcmp (mo->name, "s.d") == 0)
6599 return 8;
6601 /* sb, swl, swr */
6602 return 1;
6605 struct fix_24k_store_info
6607 /* Immediate offset, if any, for this store instruction. */
6608 short off;
6609 /* Alignment required by this store instruction. */
6610 int align_to;
6611 /* True for register offsets. */
6612 int register_offset;
6615 /* Comparison function used by qsort. */
6617 static int
6618 fix_24k_sort (const void *a, const void *b)
6620 const struct fix_24k_store_info *pos1 = a;
6621 const struct fix_24k_store_info *pos2 = b;
6623 return (pos1->off - pos2->off);
6626 /* INSN is a store instruction. Try to record the store information
6627 in STINFO. Return false if the information isn't known. */
6629 static bfd_boolean
6630 fix_24k_record_store_info (struct fix_24k_store_info *stinfo,
6631 const struct mips_cl_insn *insn)
6633 /* The instruction must have a known offset. */
6634 if (!insn->complete_p || !strstr (insn->insn_mo->args, "o("))
6635 return FALSE;
6637 stinfo->off = (insn->insn_opcode >> OP_SH_IMMEDIATE) & OP_MASK_IMMEDIATE;
6638 stinfo->align_to = fix_24k_align_to (insn->insn_mo);
6639 return TRUE;
6642 /* Return the number of nops that would be needed to work around the 24k
6643 "lost data on stores during refill" errata if instruction INSN
6644 immediately followed the 2 instructions described by HIST.
6645 Ignore hazards that are contained within the first IGNORE
6646 instructions of HIST.
6648 Problem: The FSB (fetch store buffer) acts as an intermediate buffer
6649 for the data cache refills and store data. The following describes
6650 the scenario where the store data could be lost.
6652 * A data cache miss, due to either a load or a store, causing fill
6653 data to be supplied by the memory subsystem
6654 * The first three doublewords of fill data are returned and written
6655 into the cache
6656 * A sequence of four stores occurs in consecutive cycles around the
6657 final doubleword of the fill:
6658 * Store A
6659 * Store B
6660 * Store C
6661 * Zero, One or more instructions
6662 * Store D
6664 The four stores A-D must be to different doublewords of the line that
6665 is being filled. The fourth instruction in the sequence above permits
6666 the fill of the final doubleword to be transferred from the FSB into
6667 the cache. In the sequence above, the stores may be either integer
6668 (sb, sh, sw, swr, swl, sc) or coprocessor (swc1/swc2, sdc1/sdc2,
6669 swxc1, sdxc1, suxc1) stores, as long as the four stores are to
6670 different doublewords on the line. If the floating point unit is
6671 running in 1:2 mode, it is not possible to create the sequence above
6672 using only floating point store instructions.
6674 In this case, the cache line being filled is incorrectly marked
6675 invalid, thereby losing the data from any store to the line that
6676 occurs between the original miss and the completion of the five
6677 cycle sequence shown above.
6679 The workarounds are:
6681 * Run the data cache in write-through mode.
6682 * Insert a non-store instruction between
6683 Store A and Store B or Store B and Store C. */
6685 static int
6686 nops_for_24k (int ignore, const struct mips_cl_insn *hist,
6687 const struct mips_cl_insn *insn)
6689 struct fix_24k_store_info pos[3];
6690 int align, i, base_offset;
6692 if (ignore >= 2)
6693 return 0;
6695 /* If the previous instruction wasn't a store, there's nothing to
6696 worry about. */
6697 if ((hist[0].insn_mo->pinfo & INSN_STORE_MEMORY) == 0)
6698 return 0;
6700 /* If the instructions after the previous one are unknown, we have
6701 to assume the worst. */
6702 if (!insn)
6703 return 1;
6705 /* Check whether we are dealing with three consecutive stores. */
6706 if ((insn->insn_mo->pinfo & INSN_STORE_MEMORY) == 0
6707 || (hist[1].insn_mo->pinfo & INSN_STORE_MEMORY) == 0)
6708 return 0;
6710 /* If we don't know the relationship between the store addresses,
6711 assume the worst. */
6712 if (!BASE_REG_EQ (insn->insn_opcode, hist[0].insn_opcode)
6713 || !BASE_REG_EQ (insn->insn_opcode, hist[1].insn_opcode))
6714 return 1;
6716 if (!fix_24k_record_store_info (&pos[0], insn)
6717 || !fix_24k_record_store_info (&pos[1], &hist[0])
6718 || !fix_24k_record_store_info (&pos[2], &hist[1]))
6719 return 1;
6721 qsort (&pos, 3, sizeof (struct fix_24k_store_info), fix_24k_sort);
6723 /* Pick a value of ALIGN and X such that all offsets are adjusted by
6724 X bytes and such that the base register + X is known to be aligned
6725 to align bytes. */
6727 if (((insn->insn_opcode >> OP_SH_RS) & OP_MASK_RS) == SP)
6728 align = 8;
6729 else
6731 align = pos[0].align_to;
6732 base_offset = pos[0].off;
6733 for (i = 1; i < 3; i++)
6734 if (align < pos[i].align_to)
6736 align = pos[i].align_to;
6737 base_offset = pos[i].off;
6739 for (i = 0; i < 3; i++)
6740 pos[i].off -= base_offset;
6743 pos[0].off &= ~align + 1;
6744 pos[1].off &= ~align + 1;
6745 pos[2].off &= ~align + 1;
6747 /* If any two stores write to the same chunk, they also write to the
6748 same doubleword. The offsets are still sorted at this point. */
6749 if (pos[0].off == pos[1].off || pos[1].off == pos[2].off)
6750 return 0;
6752 /* A range of at least 9 bytes is needed for the stores to be in
6753 non-overlapping doublewords. */
6754 if (pos[2].off - pos[0].off <= 8)
6755 return 0;
6757 if (pos[2].off - pos[1].off >= 24
6758 || pos[1].off - pos[0].off >= 24
6759 || pos[2].off - pos[0].off >= 32)
6760 return 0;
6762 return 1;
6765 /* Return the number of nops that would be needed if instruction INSN
6766 immediately followed the MAX_NOPS instructions given by HIST,
6767 where HIST[0] is the most recent instruction. Ignore hazards
6768 between INSN and the first IGNORE instructions in HIST.
6770 If INSN is null, return the worse-case number of nops for any
6771 instruction. */
6773 static int
6774 nops_for_insn (int ignore, const struct mips_cl_insn *hist,
6775 const struct mips_cl_insn *insn)
6777 int i, nops, tmp_nops;
6779 nops = 0;
6780 for (i = ignore; i < MAX_DELAY_NOPS; i++)
6782 tmp_nops = insns_between (hist + i, insn) - i;
6783 if (tmp_nops > nops)
6784 nops = tmp_nops;
6787 if (mips_fix_vr4130 && !mips_opts.micromips)
6789 tmp_nops = nops_for_vr4130 (ignore, hist, insn);
6790 if (tmp_nops > nops)
6791 nops = tmp_nops;
6794 if (mips_fix_24k && !mips_opts.micromips)
6796 tmp_nops = nops_for_24k (ignore, hist, insn);
6797 if (tmp_nops > nops)
6798 nops = tmp_nops;
6801 return nops;
6804 /* The variable arguments provide NUM_INSNS extra instructions that
6805 might be added to HIST. Return the largest number of nops that
6806 would be needed after the extended sequence, ignoring hazards
6807 in the first IGNORE instructions. */
6809 static int
6810 nops_for_sequence (int num_insns, int ignore,
6811 const struct mips_cl_insn *hist, ...)
6813 va_list args;
6814 struct mips_cl_insn buffer[MAX_NOPS];
6815 struct mips_cl_insn *cursor;
6816 int nops;
6818 va_start (args, hist);
6819 cursor = buffer + num_insns;
6820 memcpy (cursor, hist, (MAX_NOPS - num_insns) * sizeof (*cursor));
6821 while (cursor > buffer)
6822 *--cursor = *va_arg (args, const struct mips_cl_insn *);
6824 nops = nops_for_insn (ignore, buffer, NULL);
6825 va_end (args);
6826 return nops;
6829 /* Like nops_for_insn, but if INSN is a branch, take into account the
6830 worst-case delay for the branch target. */
6832 static int
6833 nops_for_insn_or_target (int ignore, const struct mips_cl_insn *hist,
6834 const struct mips_cl_insn *insn)
6836 int nops, tmp_nops;
6838 nops = nops_for_insn (ignore, hist, insn);
6839 if (delayed_branch_p (insn))
6841 tmp_nops = nops_for_sequence (2, ignore ? ignore + 2 : 0,
6842 hist, insn, get_delay_slot_nop (insn));
6843 if (tmp_nops > nops)
6844 nops = tmp_nops;
6846 else if (compact_branch_p (insn))
6848 tmp_nops = nops_for_sequence (1, ignore ? ignore + 1 : 0, hist, insn);
6849 if (tmp_nops > nops)
6850 nops = tmp_nops;
6852 return nops;
6855 /* Fix NOP issue: Replace nops by "or at,at,zero". */
6857 static void
6858 fix_loongson2f_nop (struct mips_cl_insn * ip)
6860 gas_assert (!HAVE_CODE_COMPRESSION);
6861 if (strcmp (ip->insn_mo->name, "nop") == 0)
6862 ip->insn_opcode = LOONGSON2F_NOP_INSN;
6865 /* Fix Jump Issue: Eliminate instruction fetch from outside 256M region
6866 jr target pc &= 'hffff_ffff_cfff_ffff. */
6868 static void
6869 fix_loongson2f_jump (struct mips_cl_insn * ip)
6871 gas_assert (!HAVE_CODE_COMPRESSION);
6872 if (strcmp (ip->insn_mo->name, "j") == 0
6873 || strcmp (ip->insn_mo->name, "jr") == 0
6874 || strcmp (ip->insn_mo->name, "jalr") == 0)
6876 int sreg;
6877 expressionS ep;
6879 if (! mips_opts.at)
6880 return;
6882 sreg = EXTRACT_OPERAND (0, RS, *ip);
6883 if (sreg == ZERO || sreg == KT0 || sreg == KT1 || sreg == ATREG)
6884 return;
6886 ep.X_op = O_constant;
6887 ep.X_add_number = 0xcfff0000;
6888 macro_build (&ep, "lui", "t,u", ATREG, BFD_RELOC_HI16);
6889 ep.X_add_number = 0xffff;
6890 macro_build (&ep, "ori", "t,r,i", ATREG, ATREG, BFD_RELOC_LO16);
6891 macro_build (NULL, "and", "d,v,t", sreg, sreg, ATREG);
6895 static void
6896 fix_loongson2f (struct mips_cl_insn * ip)
6898 if (mips_fix_loongson2f_nop)
6899 fix_loongson2f_nop (ip);
6901 if (mips_fix_loongson2f_jump)
6902 fix_loongson2f_jump (ip);
6905 /* Fix loongson3 llsc errata: Insert sync before ll/lld. */
6907 static void
6908 fix_loongson3_llsc (struct mips_cl_insn * ip)
6910 gas_assert (!HAVE_CODE_COMPRESSION);
6912 /* If is an local label and the insn is not sync,
6913 look forward that whether an branch between ll/sc jump to here
6914 if so, insert a sync. */
6915 if (seg_info (now_seg)->label_list
6916 && S_IS_LOCAL (seg_info (now_seg)->label_list->label)
6917 && (strcmp (ip->insn_mo->name, "sync") != 0))
6919 const char *label_name = S_GET_NAME (seg_info (now_seg)->label_list->label);
6920 unsigned long lookback = ARRAY_SIZE (history);
6921 unsigned long i;
6923 for (i = 0; i < lookback; i++)
6925 if (streq (history[i].insn_mo->name, "ll")
6926 || streq (history[i].insn_mo->name, "lld"))
6927 break;
6929 if (streq (history[i].insn_mo->name, "sc")
6930 || streq (history[i].insn_mo->name, "scd"))
6932 unsigned long j;
6934 for (j = i + 1; j < lookback; j++)
6936 if (streq (history[i].insn_mo->name, "ll")
6937 || streq (history[i].insn_mo->name, "lld"))
6938 break;
6940 if (delayed_branch_p (&history[j]))
6942 if (streq (history[j].target, label_name))
6944 add_fixed_insn (&sync_insn);
6945 insert_into_history (0, 1, &sync_insn);
6946 i = lookback;
6947 break;
6954 /* If we find a sc, we look forward to look for an branch insn,
6955 and see whether it jump back and out of ll/sc. */
6956 else if (streq(ip->insn_mo->name, "sc") || streq(ip->insn_mo->name, "scd"))
6958 unsigned long lookback = ARRAY_SIZE (history) - 1;
6959 unsigned long i;
6961 for (i = 0; i < lookback; i++)
6963 if (streq (history[i].insn_mo->name, "ll")
6964 || streq (history[i].insn_mo->name, "lld"))
6965 break;
6967 if (delayed_branch_p (&history[i]))
6969 unsigned long j;
6971 for (j = i + 1; j < lookback; j++)
6973 if (streq (history[j].insn_mo->name, "ll")
6974 || streq (history[i].insn_mo->name, "lld"))
6975 break;
6978 for (; j < lookback; j++)
6980 if (history[j].label[0] != '\0'
6981 && streq (history[j].label, history[i].target)
6982 && strcmp (history[j+1].insn_mo->name, "sync") != 0)
6984 add_fixed_insn (&sync_insn);
6985 insert_into_history (++j, 1, &sync_insn);
6992 /* Skip if there is a sync before ll/lld. */
6993 if ((strcmp (ip->insn_mo->name, "ll") == 0
6994 || strcmp (ip->insn_mo->name, "lld") == 0)
6995 && (strcmp (history[0].insn_mo->name, "sync") != 0))
6997 add_fixed_insn (&sync_insn);
6998 insert_into_history (0, 1, &sync_insn);
7002 /* IP is a branch that has a delay slot, and we need to fill it
7003 automatically. Return true if we can do that by swapping IP
7004 with the previous instruction.
7005 ADDRESS_EXPR is an operand of the instruction to be used with
7006 RELOC_TYPE. */
7008 static bfd_boolean
7009 can_swap_branch_p (struct mips_cl_insn *ip, expressionS *address_expr,
7010 bfd_reloc_code_real_type *reloc_type)
7012 unsigned long pinfo, pinfo2, prev_pinfo, prev_pinfo2;
7013 unsigned int gpr_read, gpr_write, prev_gpr_read, prev_gpr_write;
7014 unsigned int fpr_read, prev_fpr_write;
7016 /* -O2 and above is required for this optimization. */
7017 if (mips_optimize < 2)
7018 return FALSE;
7020 /* If we have seen .set volatile or .set nomove, don't optimize. */
7021 if (mips_opts.nomove)
7022 return FALSE;
7024 /* We can't swap if the previous instruction's position is fixed. */
7025 if (history[0].fixed_p)
7026 return FALSE;
7028 /* If the previous previous insn was in a .set noreorder, we can't
7029 swap. Actually, the MIPS assembler will swap in this situation.
7030 However, gcc configured -with-gnu-as will generate code like
7032 .set noreorder
7033 lw $4,XXX
7034 .set reorder
7035 INSN
7036 bne $4,$0,foo
7038 in which we can not swap the bne and INSN. If gcc is not configured
7039 -with-gnu-as, it does not output the .set pseudo-ops. */
7040 if (history[1].noreorder_p)
7041 return FALSE;
7043 /* If the previous instruction had a fixup in mips16 mode, we can not swap.
7044 This means that the previous instruction was a 4-byte one anyhow. */
7045 if (mips_opts.mips16 && history[0].fixp[0])
7046 return FALSE;
7048 /* If the branch is itself the target of a branch, we can not swap.
7049 We cheat on this; all we check for is whether there is a label on
7050 this instruction. If there are any branches to anything other than
7051 a label, users must use .set noreorder. */
7052 if (seg_info (now_seg)->label_list)
7053 return FALSE;
7055 /* If the previous instruction is in a variant frag other than this
7056 branch's one, we cannot do the swap. This does not apply to
7057 MIPS16 code, which uses variant frags for different purposes. */
7058 if (!mips_opts.mips16
7059 && history[0].frag
7060 && history[0].frag->fr_type == rs_machine_dependent)
7061 return FALSE;
7063 /* We do not swap with instructions that cannot architecturally
7064 be placed in a branch delay slot, such as SYNC or ERET. We
7065 also refrain from swapping with a trap instruction, since it
7066 complicates trap handlers to have the trap instruction be in
7067 a delay slot. */
7068 prev_pinfo = history[0].insn_mo->pinfo;
7069 if (prev_pinfo & INSN_NO_DELAY_SLOT)
7070 return FALSE;
7072 /* Check for conflicts between the branch and the instructions
7073 before the candidate delay slot. */
7074 if (nops_for_insn (0, history + 1, ip) > 0)
7075 return FALSE;
7077 /* Check for conflicts between the swapped sequence and the
7078 target of the branch. */
7079 if (nops_for_sequence (2, 0, history + 1, ip, history) > 0)
7080 return FALSE;
7082 /* If the branch reads a register that the previous
7083 instruction sets, we can not swap. */
7084 gpr_read = gpr_read_mask (ip);
7085 prev_gpr_write = gpr_write_mask (&history[0]);
7086 if (gpr_read & prev_gpr_write)
7087 return FALSE;
7089 fpr_read = fpr_read_mask (ip);
7090 prev_fpr_write = fpr_write_mask (&history[0]);
7091 if (fpr_read & prev_fpr_write)
7092 return FALSE;
7094 /* If the branch writes a register that the previous
7095 instruction sets, we can not swap. */
7096 gpr_write = gpr_write_mask (ip);
7097 if (gpr_write & prev_gpr_write)
7098 return FALSE;
7100 /* If the branch writes a register that the previous
7101 instruction reads, we can not swap. */
7102 prev_gpr_read = gpr_read_mask (&history[0]);
7103 if (gpr_write & prev_gpr_read)
7104 return FALSE;
7106 /* If one instruction sets a condition code and the
7107 other one uses a condition code, we can not swap. */
7108 pinfo = ip->insn_mo->pinfo;
7109 if ((pinfo & INSN_READ_COND_CODE)
7110 && (prev_pinfo & INSN_WRITE_COND_CODE))
7111 return FALSE;
7112 if ((pinfo & INSN_WRITE_COND_CODE)
7113 && (prev_pinfo & INSN_READ_COND_CODE))
7114 return FALSE;
7116 /* If the previous instruction uses the PC, we can not swap. */
7117 prev_pinfo2 = history[0].insn_mo->pinfo2;
7118 if (prev_pinfo2 & INSN2_READ_PC)
7119 return FALSE;
7121 /* If the previous instruction has an incorrect size for a fixed
7122 branch delay slot in microMIPS mode, we cannot swap. */
7123 pinfo2 = ip->insn_mo->pinfo2;
7124 if (mips_opts.micromips
7125 && (pinfo2 & INSN2_BRANCH_DELAY_16BIT)
7126 && insn_length (history) != 2)
7127 return FALSE;
7128 if (mips_opts.micromips
7129 && (pinfo2 & INSN2_BRANCH_DELAY_32BIT)
7130 && insn_length (history) != 4)
7131 return FALSE;
7133 /* On the R5900 short loops need to be fixed by inserting a NOP in the
7134 branch delay slot.
7136 The short loop bug under certain conditions causes loops to execute
7137 only once or twice. We must ensure that the assembler never
7138 generates loops that satisfy all of the following conditions:
7140 - a loop consists of less than or equal to six instructions
7141 (including the branch delay slot);
7142 - a loop contains only one conditional branch instruction at the end
7143 of the loop;
7144 - a loop does not contain any other branch or jump instructions;
7145 - a branch delay slot of the loop is not NOP (EE 2.9 or later).
7147 We need to do this because of a hardware bug in the R5900 chip. */
7148 if (mips_fix_r5900
7149 /* Check if instruction has a parameter, ignore "j $31". */
7150 && (address_expr != NULL)
7151 /* Parameter must be 16 bit. */
7152 && (*reloc_type == BFD_RELOC_16_PCREL_S2)
7153 /* Branch to same segment. */
7154 && (S_GET_SEGMENT (address_expr->X_add_symbol) == now_seg)
7155 /* Branch to same code fragment. */
7156 && (symbol_get_frag (address_expr->X_add_symbol) == frag_now)
7157 /* Can only calculate branch offset if value is known. */
7158 && symbol_constant_p (address_expr->X_add_symbol)
7159 /* Check if branch is really conditional. */
7160 && !((ip->insn_opcode & 0xffff0000) == 0x10000000 /* beq $0,$0 */
7161 || (ip->insn_opcode & 0xffff0000) == 0x04010000 /* bgez $0 */
7162 || (ip->insn_opcode & 0xffff0000) == 0x04110000)) /* bgezal $0 */
7164 int distance;
7165 /* Check if loop is shorter than or equal to 6 instructions
7166 including branch and delay slot. */
7167 distance = frag_now_fix () - S_GET_VALUE (address_expr->X_add_symbol);
7168 if (distance <= 20)
7170 int i;
7171 int rv;
7173 rv = FALSE;
7174 /* When the loop includes branches or jumps,
7175 it is not a short loop. */
7176 for (i = 0; i < (distance / 4); i++)
7178 if ((history[i].cleared_p)
7179 || delayed_branch_p (&history[i]))
7181 rv = TRUE;
7182 break;
7185 if (!rv)
7187 /* Insert nop after branch to fix short loop. */
7188 return FALSE;
7193 return TRUE;
7196 /* Decide how we should add IP to the instruction stream.
7197 ADDRESS_EXPR is an operand of the instruction to be used with
7198 RELOC_TYPE. */
7200 static enum append_method
7201 get_append_method (struct mips_cl_insn *ip, expressionS *address_expr,
7202 bfd_reloc_code_real_type *reloc_type)
7204 /* The relaxed version of a macro sequence must be inherently
7205 hazard-free. */
7206 if (mips_relax.sequence == 2)
7207 return APPEND_ADD;
7209 /* We must not dabble with instructions in a ".set noreorder" block. */
7210 if (mips_opts.noreorder)
7211 return APPEND_ADD;
7213 /* Otherwise, it's our responsibility to fill branch delay slots. */
7214 if (delayed_branch_p (ip))
7216 if (!branch_likely_p (ip)
7217 && can_swap_branch_p (ip, address_expr, reloc_type))
7218 return APPEND_SWAP;
7220 if (mips_opts.mips16
7221 && ISA_SUPPORTS_MIPS16E
7222 && gpr_read_mask (ip) != 0)
7223 return APPEND_ADD_COMPACT;
7225 if (mips_opts.micromips
7226 && ((ip->insn_opcode & 0xffe0) == 0x4580
7227 || (!forced_insn_length
7228 && ((ip->insn_opcode & 0xfc00) == 0xcc00
7229 || (ip->insn_opcode & 0xdc00) == 0x8c00))
7230 || (ip->insn_opcode & 0xdfe00000) == 0x94000000
7231 || (ip->insn_opcode & 0xdc1f0000) == 0x94000000))
7232 return APPEND_ADD_COMPACT;
7234 return APPEND_ADD_WITH_NOP;
7237 return APPEND_ADD;
7240 /* IP is an instruction whose opcode we have just changed, END points
7241 to the end of the opcode table processed. Point IP->insn_mo to the
7242 new opcode's definition. */
7244 static void
7245 find_altered_opcode (struct mips_cl_insn *ip, const struct mips_opcode *end)
7247 const struct mips_opcode *mo;
7249 for (mo = ip->insn_mo; mo < end; mo++)
7250 if (mo->pinfo != INSN_MACRO
7251 && (ip->insn_opcode & mo->mask) == mo->match)
7253 ip->insn_mo = mo;
7254 return;
7256 abort ();
7259 /* IP is a MIPS16 instruction whose opcode we have just changed.
7260 Point IP->insn_mo to the new opcode's definition. */
7262 static void
7263 find_altered_mips16_opcode (struct mips_cl_insn *ip)
7265 find_altered_opcode (ip, &mips16_opcodes[bfd_mips16_num_opcodes]);
7268 /* IP is a microMIPS instruction whose opcode we have just changed.
7269 Point IP->insn_mo to the new opcode's definition. */
7271 static void
7272 find_altered_micromips_opcode (struct mips_cl_insn *ip)
7274 find_altered_opcode (ip, &micromips_opcodes[bfd_micromips_num_opcodes]);
7277 /* For microMIPS macros, we need to generate a local number label
7278 as the target of branches. */
7279 #define MICROMIPS_LABEL_CHAR '\037'
7280 static unsigned long micromips_target_label;
7281 static char micromips_target_name[32];
7283 static char *
7284 micromips_label_name (void)
7286 char *p = micromips_target_name;
7287 char symbol_name_temporary[24];
7288 unsigned long l;
7289 int i;
7291 if (*p)
7292 return p;
7294 i = 0;
7295 l = micromips_target_label;
7296 #ifdef LOCAL_LABEL_PREFIX
7297 *p++ = LOCAL_LABEL_PREFIX;
7298 #endif
7299 *p++ = 'L';
7300 *p++ = MICROMIPS_LABEL_CHAR;
7303 symbol_name_temporary[i++] = l % 10 + '0';
7304 l /= 10;
7306 while (l != 0);
7307 while (i > 0)
7308 *p++ = symbol_name_temporary[--i];
7309 *p = '\0';
7311 return micromips_target_name;
7314 static void
7315 micromips_label_expr (expressionS *label_expr)
7317 label_expr->X_op = O_symbol;
7318 label_expr->X_add_symbol = symbol_find_or_make (micromips_label_name ());
7319 label_expr->X_add_number = 0;
7322 static void
7323 micromips_label_inc (void)
7325 micromips_target_label++;
7326 *micromips_target_name = '\0';
7329 static void
7330 micromips_add_label (void)
7332 symbolS *s;
7334 s = colon (micromips_label_name ());
7335 micromips_label_inc ();
7336 S_SET_OTHER (s, ELF_ST_SET_MICROMIPS (S_GET_OTHER (s)));
7339 /* If assembling microMIPS code, then return the microMIPS reloc
7340 corresponding to the requested one if any. Otherwise return
7341 the reloc unchanged. */
7343 static bfd_reloc_code_real_type
7344 micromips_map_reloc (bfd_reloc_code_real_type reloc)
7346 static const bfd_reloc_code_real_type relocs[][2] =
7348 /* Keep sorted incrementally by the left-hand key. */
7349 { BFD_RELOC_16_PCREL_S2, BFD_RELOC_MICROMIPS_16_PCREL_S1 },
7350 { BFD_RELOC_GPREL16, BFD_RELOC_MICROMIPS_GPREL16 },
7351 { BFD_RELOC_MIPS_JMP, BFD_RELOC_MICROMIPS_JMP },
7352 { BFD_RELOC_HI16, BFD_RELOC_MICROMIPS_HI16 },
7353 { BFD_RELOC_HI16_S, BFD_RELOC_MICROMIPS_HI16_S },
7354 { BFD_RELOC_LO16, BFD_RELOC_MICROMIPS_LO16 },
7355 { BFD_RELOC_MIPS_LITERAL, BFD_RELOC_MICROMIPS_LITERAL },
7356 { BFD_RELOC_MIPS_GOT16, BFD_RELOC_MICROMIPS_GOT16 },
7357 { BFD_RELOC_MIPS_CALL16, BFD_RELOC_MICROMIPS_CALL16 },
7358 { BFD_RELOC_MIPS_GOT_HI16, BFD_RELOC_MICROMIPS_GOT_HI16 },
7359 { BFD_RELOC_MIPS_GOT_LO16, BFD_RELOC_MICROMIPS_GOT_LO16 },
7360 { BFD_RELOC_MIPS_CALL_HI16, BFD_RELOC_MICROMIPS_CALL_HI16 },
7361 { BFD_RELOC_MIPS_CALL_LO16, BFD_RELOC_MICROMIPS_CALL_LO16 },
7362 { BFD_RELOC_MIPS_SUB, BFD_RELOC_MICROMIPS_SUB },
7363 { BFD_RELOC_MIPS_GOT_PAGE, BFD_RELOC_MICROMIPS_GOT_PAGE },
7364 { BFD_RELOC_MIPS_GOT_OFST, BFD_RELOC_MICROMIPS_GOT_OFST },
7365 { BFD_RELOC_MIPS_GOT_DISP, BFD_RELOC_MICROMIPS_GOT_DISP },
7366 { BFD_RELOC_MIPS_HIGHEST, BFD_RELOC_MICROMIPS_HIGHEST },
7367 { BFD_RELOC_MIPS_HIGHER, BFD_RELOC_MICROMIPS_HIGHER },
7368 { BFD_RELOC_MIPS_SCN_DISP, BFD_RELOC_MICROMIPS_SCN_DISP },
7369 { BFD_RELOC_MIPS_TLS_GD, BFD_RELOC_MICROMIPS_TLS_GD },
7370 { BFD_RELOC_MIPS_TLS_LDM, BFD_RELOC_MICROMIPS_TLS_LDM },
7371 { BFD_RELOC_MIPS_TLS_DTPREL_HI16, BFD_RELOC_MICROMIPS_TLS_DTPREL_HI16 },
7372 { BFD_RELOC_MIPS_TLS_DTPREL_LO16, BFD_RELOC_MICROMIPS_TLS_DTPREL_LO16 },
7373 { BFD_RELOC_MIPS_TLS_GOTTPREL, BFD_RELOC_MICROMIPS_TLS_GOTTPREL },
7374 { BFD_RELOC_MIPS_TLS_TPREL_HI16, BFD_RELOC_MICROMIPS_TLS_TPREL_HI16 },
7375 { BFD_RELOC_MIPS_TLS_TPREL_LO16, BFD_RELOC_MICROMIPS_TLS_TPREL_LO16 }
7377 bfd_reloc_code_real_type r;
7378 size_t i;
7380 if (!mips_opts.micromips)
7381 return reloc;
7382 for (i = 0; i < ARRAY_SIZE (relocs); i++)
7384 r = relocs[i][0];
7385 if (r > reloc)
7386 return reloc;
7387 if (r == reloc)
7388 return relocs[i][1];
7390 return reloc;
7393 /* Try to resolve relocation RELOC against constant OPERAND at assembly time.
7394 Return true on success, storing the resolved value in RESULT. */
7396 static bfd_boolean
7397 calculate_reloc (bfd_reloc_code_real_type reloc, offsetT operand,
7398 offsetT *result)
7400 switch (reloc)
7402 case BFD_RELOC_MIPS_HIGHEST:
7403 case BFD_RELOC_MICROMIPS_HIGHEST:
7404 *result = ((operand + 0x800080008000ull) >> 48) & 0xffff;
7405 return TRUE;
7407 case BFD_RELOC_MIPS_HIGHER:
7408 case BFD_RELOC_MICROMIPS_HIGHER:
7409 *result = ((operand + 0x80008000ull) >> 32) & 0xffff;
7410 return TRUE;
7412 case BFD_RELOC_HI16_S:
7413 case BFD_RELOC_HI16_S_PCREL:
7414 case BFD_RELOC_MICROMIPS_HI16_S:
7415 case BFD_RELOC_MIPS16_HI16_S:
7416 *result = ((operand + 0x8000) >> 16) & 0xffff;
7417 return TRUE;
7419 case BFD_RELOC_HI16:
7420 case BFD_RELOC_MICROMIPS_HI16:
7421 case BFD_RELOC_MIPS16_HI16:
7422 *result = (operand >> 16) & 0xffff;
7423 return TRUE;
7425 case BFD_RELOC_LO16:
7426 case BFD_RELOC_LO16_PCREL:
7427 case BFD_RELOC_MICROMIPS_LO16:
7428 case BFD_RELOC_MIPS16_LO16:
7429 *result = operand & 0xffff;
7430 return TRUE;
7432 case BFD_RELOC_UNUSED:
7433 *result = operand;
7434 return TRUE;
7436 default:
7437 return FALSE;
7441 /* Output an instruction. IP is the instruction information.
7442 ADDRESS_EXPR is an operand of the instruction to be used with
7443 RELOC_TYPE. EXPANSIONP is true if the instruction is part of
7444 a macro expansion. */
7446 static void
7447 append_insn (struct mips_cl_insn *ip, expressionS *address_expr,
7448 bfd_reloc_code_real_type *reloc_type, bfd_boolean expansionp)
7450 unsigned long prev_pinfo2, pinfo;
7451 bfd_boolean relaxed_branch = FALSE;
7452 enum append_method method;
7453 bfd_boolean relax32;
7454 int branch_disp;
7456 if (mips_fix_loongson2f && !HAVE_CODE_COMPRESSION)
7457 fix_loongson2f (ip);
7459 ip->target[0] = '\0';
7460 if (offset_expr.X_op == O_symbol)
7461 strncpy (ip->target, S_GET_NAME (offset_expr.X_add_symbol), 15);
7462 ip->label[0] = '\0';
7463 if (seg_info (now_seg)->label_list)
7464 strncpy (ip->label, S_GET_NAME (seg_info (now_seg)->label_list->label), 15);
7465 if (mips_fix_loongson3_llsc && !HAVE_CODE_COMPRESSION)
7466 fix_loongson3_llsc (ip);
7468 file_ase_mips16 |= mips_opts.mips16;
7469 file_ase_micromips |= mips_opts.micromips;
7471 prev_pinfo2 = history[0].insn_mo->pinfo2;
7472 pinfo = ip->insn_mo->pinfo;
7474 /* Don't raise alarm about `nods' frags as they'll fill in the right
7475 kind of nop in relaxation if required. */
7476 if (mips_opts.micromips
7477 && !expansionp
7478 && !(history[0].frag
7479 && history[0].frag->fr_type == rs_machine_dependent
7480 && RELAX_MICROMIPS_P (history[0].frag->fr_subtype)
7481 && RELAX_MICROMIPS_NODS (history[0].frag->fr_subtype))
7482 && (((prev_pinfo2 & INSN2_BRANCH_DELAY_16BIT) != 0
7483 && micromips_insn_length (ip->insn_mo) != 2)
7484 || ((prev_pinfo2 & INSN2_BRANCH_DELAY_32BIT) != 0
7485 && micromips_insn_length (ip->insn_mo) != 4)))
7486 as_warn (_("wrong size instruction in a %u-bit branch delay slot"),
7487 (prev_pinfo2 & INSN2_BRANCH_DELAY_16BIT) != 0 ? 16 : 32);
7489 if (address_expr == NULL)
7490 ip->complete_p = 1;
7491 else if (reloc_type[0] <= BFD_RELOC_UNUSED
7492 && reloc_type[1] == BFD_RELOC_UNUSED
7493 && reloc_type[2] == BFD_RELOC_UNUSED
7494 && address_expr->X_op == O_constant)
7496 switch (*reloc_type)
7498 case BFD_RELOC_MIPS_JMP:
7500 int shift;
7502 /* Shift is 2, unusually, for microMIPS JALX. */
7503 shift = (mips_opts.micromips
7504 && strcmp (ip->insn_mo->name, "jalx") != 0) ? 1 : 2;
7505 if ((address_expr->X_add_number & ((1 << shift) - 1)) != 0)
7506 as_bad (_("jump to misaligned address (0x%lx)"),
7507 (unsigned long) address_expr->X_add_number);
7508 ip->insn_opcode |= ((address_expr->X_add_number >> shift)
7509 & 0x3ffffff);
7510 ip->complete_p = 1;
7512 break;
7514 case BFD_RELOC_MIPS16_JMP:
7515 if ((address_expr->X_add_number & 3) != 0)
7516 as_bad (_("jump to misaligned address (0x%lx)"),
7517 (unsigned long) address_expr->X_add_number);
7518 ip->insn_opcode |=
7519 (((address_expr->X_add_number & 0x7c0000) << 3)
7520 | ((address_expr->X_add_number & 0xf800000) >> 7)
7521 | ((address_expr->X_add_number & 0x3fffc) >> 2));
7522 ip->complete_p = 1;
7523 break;
7525 case BFD_RELOC_16_PCREL_S2:
7527 int shift;
7529 shift = mips_opts.micromips ? 1 : 2;
7530 if ((address_expr->X_add_number & ((1 << shift) - 1)) != 0)
7531 as_bad (_("branch to misaligned address (0x%lx)"),
7532 (unsigned long) address_expr->X_add_number);
7533 if (!mips_relax_branch)
7535 if ((address_expr->X_add_number + (1 << (shift + 15)))
7536 & ~((1 << (shift + 16)) - 1))
7537 as_bad (_("branch address range overflow (0x%lx)"),
7538 (unsigned long) address_expr->X_add_number);
7539 ip->insn_opcode |= ((address_expr->X_add_number >> shift)
7540 & 0xffff);
7543 break;
7545 case BFD_RELOC_MIPS_21_PCREL_S2:
7547 int shift;
7549 shift = 2;
7550 if ((address_expr->X_add_number & ((1 << shift) - 1)) != 0)
7551 as_bad (_("branch to misaligned address (0x%lx)"),
7552 (unsigned long) address_expr->X_add_number);
7553 if ((address_expr->X_add_number + (1 << (shift + 20)))
7554 & ~((1 << (shift + 21)) - 1))
7555 as_bad (_("branch address range overflow (0x%lx)"),
7556 (unsigned long) address_expr->X_add_number);
7557 ip->insn_opcode |= ((address_expr->X_add_number >> shift)
7558 & 0x1fffff);
7560 break;
7562 case BFD_RELOC_MIPS_26_PCREL_S2:
7564 int shift;
7566 shift = 2;
7567 if ((address_expr->X_add_number & ((1 << shift) - 1)) != 0)
7568 as_bad (_("branch to misaligned address (0x%lx)"),
7569 (unsigned long) address_expr->X_add_number);
7570 if ((address_expr->X_add_number + (1 << (shift + 25)))
7571 & ~((1 << (shift + 26)) - 1))
7572 as_bad (_("branch address range overflow (0x%lx)"),
7573 (unsigned long) address_expr->X_add_number);
7574 ip->insn_opcode |= ((address_expr->X_add_number >> shift)
7575 & 0x3ffffff);
7577 break;
7579 default:
7581 offsetT value;
7583 if (calculate_reloc (*reloc_type, address_expr->X_add_number,
7584 &value))
7586 ip->insn_opcode |= value & 0xffff;
7587 ip->complete_p = 1;
7590 break;
7594 if (mips_relax.sequence != 2 && !mips_opts.noreorder)
7596 /* There are a lot of optimizations we could do that we don't.
7597 In particular, we do not, in general, reorder instructions.
7598 If you use gcc with optimization, it will reorder
7599 instructions and generally do much more optimization then we
7600 do here; repeating all that work in the assembler would only
7601 benefit hand written assembly code, and does not seem worth
7602 it. */
7603 int nops = (mips_optimize == 0
7604 ? nops_for_insn (0, history, NULL)
7605 : nops_for_insn_or_target (0, history, ip));
7606 if (nops > 0)
7608 fragS *old_frag;
7609 unsigned long old_frag_offset;
7610 int i;
7612 old_frag = frag_now;
7613 old_frag_offset = frag_now_fix ();
7615 for (i = 0; i < nops; i++)
7616 add_fixed_insn (NOP_INSN);
7617 insert_into_history (0, nops, NOP_INSN);
7619 if (listing)
7621 listing_prev_line ();
7622 /* We may be at the start of a variant frag. In case we
7623 are, make sure there is enough space for the frag
7624 after the frags created by listing_prev_line. The
7625 argument to frag_grow here must be at least as large
7626 as the argument to all other calls to frag_grow in
7627 this file. We don't have to worry about being in the
7628 middle of a variant frag, because the variants insert
7629 all needed nop instructions themselves. */
7630 frag_grow (40);
7633 mips_move_text_labels ();
7635 #ifndef NO_ECOFF_DEBUGGING
7636 if (ECOFF_DEBUGGING)
7637 ecoff_fix_loc (old_frag, old_frag_offset);
7638 #endif
7641 else if (mips_relax.sequence != 2 && prev_nop_frag != NULL)
7643 int nops;
7645 /* Work out how many nops in prev_nop_frag are needed by IP,
7646 ignoring hazards generated by the first prev_nop_frag_since
7647 instructions. */
7648 nops = nops_for_insn_or_target (prev_nop_frag_since, history, ip);
7649 gas_assert (nops <= prev_nop_frag_holds);
7651 /* Enforce NOPS as a minimum. */
7652 if (nops > prev_nop_frag_required)
7653 prev_nop_frag_required = nops;
7655 if (prev_nop_frag_holds == prev_nop_frag_required)
7657 /* Settle for the current number of nops. Update the history
7658 accordingly (for the benefit of any future .set reorder code). */
7659 prev_nop_frag = NULL;
7660 insert_into_history (prev_nop_frag_since,
7661 prev_nop_frag_holds, NOP_INSN);
7663 else
7665 /* Allow this instruction to replace one of the nops that was
7666 tentatively added to prev_nop_frag. */
7667 prev_nop_frag->fr_fix -= NOP_INSN_SIZE;
7668 prev_nop_frag_holds--;
7669 prev_nop_frag_since++;
7673 method = get_append_method (ip, address_expr, reloc_type);
7674 branch_disp = method == APPEND_SWAP ? insn_length (history) : 0;
7676 dwarf2_emit_insn (0);
7677 /* We want MIPS16 and microMIPS debug info to use ISA-encoded addresses,
7678 so "move" the instruction address accordingly.
7680 Also, it doesn't seem appropriate for the assembler to reorder .loc
7681 entries. If this instruction is a branch that we are going to swap
7682 with the previous instruction, the two instructions should be
7683 treated as a unit, and the debug information for both instructions
7684 should refer to the start of the branch sequence. Using the
7685 current position is certainly wrong when swapping a 32-bit branch
7686 and a 16-bit delay slot, since the current position would then be
7687 in the middle of a branch. */
7688 dwarf2_move_insn ((HAVE_CODE_COMPRESSION ? 1 : 0) - branch_disp);
7690 relax32 = (mips_relax_branch
7691 /* Don't try branch relaxation within .set nomacro, or within
7692 .set noat if we use $at for PIC computations. If it turns
7693 out that the branch was out-of-range, we'll get an error. */
7694 && !mips_opts.warn_about_macros
7695 && (mips_opts.at || mips_pic == NO_PIC)
7696 /* Don't relax BPOSGE32/64 or BC1ANY2T/F and BC1ANY4T/F
7697 as they have no complementing branches. */
7698 && !(ip->insn_mo->ase & (ASE_MIPS3D | ASE_DSP64 | ASE_DSP)));
7700 if (!HAVE_CODE_COMPRESSION
7701 && address_expr
7702 && relax32
7703 && *reloc_type == BFD_RELOC_16_PCREL_S2
7704 && delayed_branch_p (ip))
7706 relaxed_branch = TRUE;
7707 add_relaxed_insn (ip, (relaxed_branch_length
7708 (NULL, NULL,
7709 uncond_branch_p (ip) ? -1
7710 : branch_likely_p (ip) ? 1
7711 : 0)), 4,
7712 RELAX_BRANCH_ENCODE
7713 (AT, mips_pic != NO_PIC,
7714 uncond_branch_p (ip),
7715 branch_likely_p (ip),
7716 pinfo & INSN_WRITE_GPR_31,
7718 address_expr->X_add_symbol,
7719 address_expr->X_add_number);
7720 *reloc_type = BFD_RELOC_UNUSED;
7722 else if (mips_opts.micromips
7723 && address_expr
7724 && ((relax32 && *reloc_type == BFD_RELOC_16_PCREL_S2)
7725 || *reloc_type > BFD_RELOC_UNUSED)
7726 && (delayed_branch_p (ip) || compact_branch_p (ip))
7727 /* Don't try branch relaxation when users specify
7728 16-bit/32-bit instructions. */
7729 && !forced_insn_length)
7731 bfd_boolean relax16 = (method != APPEND_ADD_COMPACT
7732 && *reloc_type > BFD_RELOC_UNUSED);
7733 int type = relax16 ? *reloc_type - BFD_RELOC_UNUSED : 0;
7734 int uncond = uncond_branch_p (ip) ? -1 : 0;
7735 int compact = compact_branch_p (ip) || method == APPEND_ADD_COMPACT;
7736 int nods = method == APPEND_ADD_WITH_NOP;
7737 int al = pinfo & INSN_WRITE_GPR_31;
7738 int length32 = nods ? 8 : 4;
7740 gas_assert (address_expr != NULL);
7741 gas_assert (!mips_relax.sequence);
7743 relaxed_branch = TRUE;
7744 if (nods)
7745 method = APPEND_ADD;
7746 if (relax32)
7747 length32 = relaxed_micromips_32bit_branch_length (NULL, NULL, uncond);
7748 add_relaxed_insn (ip, length32, relax16 ? 2 : 4,
7749 RELAX_MICROMIPS_ENCODE (type, AT, mips_opts.insn32,
7750 mips_pic != NO_PIC,
7751 uncond, compact, al, nods,
7752 relax32, 0, 0),
7753 address_expr->X_add_symbol,
7754 address_expr->X_add_number);
7755 *reloc_type = BFD_RELOC_UNUSED;
7757 else if (mips_opts.mips16 && *reloc_type > BFD_RELOC_UNUSED)
7759 bfd_boolean require_unextended;
7760 bfd_boolean require_extended;
7761 symbolS *symbol;
7762 offsetT offset;
7764 if (forced_insn_length != 0)
7766 require_unextended = forced_insn_length == 2;
7767 require_extended = forced_insn_length == 4;
7769 else
7771 require_unextended = (mips_opts.noautoextend
7772 && !mips_opcode_32bit_p (ip->insn_mo));
7773 require_extended = 0;
7776 /* We need to set up a variant frag. */
7777 gas_assert (address_expr != NULL);
7778 /* Pass any `O_symbol' expression unchanged as an `expr_section'
7779 symbol created by `make_expr_symbol' may not get a necessary
7780 external relocation produced. */
7781 if (address_expr->X_op == O_symbol)
7783 symbol = address_expr->X_add_symbol;
7784 offset = address_expr->X_add_number;
7786 else
7788 symbol = make_expr_symbol (address_expr);
7789 symbol_append (symbol, symbol_lastP, &symbol_rootP, &symbol_lastP);
7790 offset = 0;
7792 add_relaxed_insn (ip, 12, 0,
7793 RELAX_MIPS16_ENCODE
7794 (*reloc_type - BFD_RELOC_UNUSED,
7795 mips_opts.ase & ASE_MIPS16E2,
7796 mips_pic != NO_PIC,
7797 HAVE_32BIT_SYMBOLS,
7798 mips_opts.warn_about_macros,
7799 require_unextended, require_extended,
7800 delayed_branch_p (&history[0]),
7801 history[0].mips16_absolute_jump_p),
7802 symbol, offset);
7804 else if (mips_opts.mips16 && insn_length (ip) == 2)
7806 if (!delayed_branch_p (ip))
7807 /* Make sure there is enough room to swap this instruction with
7808 a following jump instruction. */
7809 frag_grow (6);
7810 add_fixed_insn (ip);
7812 else
7814 if (mips_opts.mips16
7815 && mips_opts.noreorder
7816 && delayed_branch_p (&history[0]))
7817 as_warn (_("extended instruction in delay slot"));
7819 if (mips_relax.sequence)
7821 /* If we've reached the end of this frag, turn it into a variant
7822 frag and record the information for the instructions we've
7823 written so far. */
7824 if (frag_room () < 4)
7825 relax_close_frag ();
7826 mips_relax.sizes[mips_relax.sequence - 1] += insn_length (ip);
7829 if (mips_relax.sequence != 2)
7831 if (mips_macro_warning.first_insn_sizes[0] == 0)
7832 mips_macro_warning.first_insn_sizes[0] = insn_length (ip);
7833 mips_macro_warning.sizes[0] += insn_length (ip);
7834 mips_macro_warning.insns[0]++;
7836 if (mips_relax.sequence != 1)
7838 if (mips_macro_warning.first_insn_sizes[1] == 0)
7839 mips_macro_warning.first_insn_sizes[1] = insn_length (ip);
7840 mips_macro_warning.sizes[1] += insn_length (ip);
7841 mips_macro_warning.insns[1]++;
7844 if (mips_opts.mips16)
7846 ip->fixed_p = 1;
7847 ip->mips16_absolute_jump_p = (*reloc_type == BFD_RELOC_MIPS16_JMP);
7849 add_fixed_insn (ip);
7852 if (!ip->complete_p && *reloc_type < BFD_RELOC_UNUSED)
7854 bfd_reloc_code_real_type final_type[3];
7855 reloc_howto_type *howto0;
7856 reloc_howto_type *howto;
7857 int i;
7859 /* Perform any necessary conversion to microMIPS relocations
7860 and find out how many relocations there actually are. */
7861 for (i = 0; i < 3 && reloc_type[i] != BFD_RELOC_UNUSED; i++)
7862 final_type[i] = micromips_map_reloc (reloc_type[i]);
7864 /* In a compound relocation, it is the final (outermost)
7865 operator that determines the relocated field. */
7866 howto = howto0 = bfd_reloc_type_lookup (stdoutput, final_type[i - 1]);
7867 if (!howto)
7868 abort ();
7870 if (i > 1)
7871 howto0 = bfd_reloc_type_lookup (stdoutput, final_type[0]);
7872 ip->fixp[0] = fix_new_exp (ip->frag, ip->where,
7873 bfd_get_reloc_size (howto),
7874 address_expr,
7875 howto0 && howto0->pc_relative,
7876 final_type[0]);
7877 /* Record non-PIC mode in `fx_tcbit2' for `md_apply_fix'. */
7878 ip->fixp[0]->fx_tcbit2 = mips_pic == NO_PIC;
7880 /* Tag symbols that have a R_MIPS16_26 relocation against them. */
7881 if (final_type[0] == BFD_RELOC_MIPS16_JMP && ip->fixp[0]->fx_addsy)
7882 *symbol_get_tc (ip->fixp[0]->fx_addsy) = 1;
7884 /* These relocations can have an addend that won't fit in
7885 4 octets for 64bit assembly. */
7886 if (GPR_SIZE == 64
7887 && ! howto->partial_inplace
7888 && (reloc_type[0] == BFD_RELOC_16
7889 || reloc_type[0] == BFD_RELOC_32
7890 || reloc_type[0] == BFD_RELOC_MIPS_JMP
7891 || reloc_type[0] == BFD_RELOC_GPREL16
7892 || reloc_type[0] == BFD_RELOC_MIPS_LITERAL
7893 || reloc_type[0] == BFD_RELOC_GPREL32
7894 || reloc_type[0] == BFD_RELOC_64
7895 || reloc_type[0] == BFD_RELOC_CTOR
7896 || reloc_type[0] == BFD_RELOC_MIPS_SUB
7897 || reloc_type[0] == BFD_RELOC_MIPS_HIGHEST
7898 || reloc_type[0] == BFD_RELOC_MIPS_HIGHER
7899 || reloc_type[0] == BFD_RELOC_MIPS_SCN_DISP
7900 || reloc_type[0] == BFD_RELOC_MIPS_REL16
7901 || reloc_type[0] == BFD_RELOC_MIPS_RELGOT
7902 || reloc_type[0] == BFD_RELOC_MIPS16_GPREL
7903 || hi16_reloc_p (reloc_type[0])
7904 || lo16_reloc_p (reloc_type[0])))
7905 ip->fixp[0]->fx_no_overflow = 1;
7907 /* These relocations can have an addend that won't fit in 2 octets. */
7908 if (reloc_type[0] == BFD_RELOC_MICROMIPS_7_PCREL_S1
7909 || reloc_type[0] == BFD_RELOC_MICROMIPS_10_PCREL_S1)
7910 ip->fixp[0]->fx_no_overflow = 1;
7912 if (mips_relax.sequence)
7914 if (mips_relax.first_fixup == 0)
7915 mips_relax.first_fixup = ip->fixp[0];
7917 else if (reloc_needs_lo_p (*reloc_type))
7919 struct mips_hi_fixup *hi_fixup;
7921 /* Reuse the last entry if it already has a matching %lo. */
7922 hi_fixup = mips_hi_fixup_list;
7923 if (hi_fixup == 0
7924 || !fixup_has_matching_lo_p (hi_fixup->fixp))
7926 hi_fixup = XNEW (struct mips_hi_fixup);
7927 hi_fixup->next = mips_hi_fixup_list;
7928 mips_hi_fixup_list = hi_fixup;
7930 hi_fixup->fixp = ip->fixp[0];
7931 hi_fixup->seg = now_seg;
7934 /* Add fixups for the second and third relocations, if given.
7935 Note that the ABI allows the second relocation to be
7936 against RSS_UNDEF, RSS_GP, RSS_GP0 or RSS_LOC. At the
7937 moment we only use RSS_UNDEF, but we could add support
7938 for the others if it ever becomes necessary. */
7939 for (i = 1; i < 3; i++)
7940 if (reloc_type[i] != BFD_RELOC_UNUSED)
7942 ip->fixp[i] = fix_new (ip->frag, ip->where,
7943 ip->fixp[0]->fx_size, NULL, 0,
7944 FALSE, final_type[i]);
7946 /* Use fx_tcbit to mark compound relocs. */
7947 ip->fixp[0]->fx_tcbit = 1;
7948 ip->fixp[i]->fx_tcbit = 1;
7952 /* Update the register mask information. */
7953 mips_gprmask |= gpr_read_mask (ip) | gpr_write_mask (ip);
7954 mips_cprmask[1] |= fpr_read_mask (ip) | fpr_write_mask (ip);
7956 switch (method)
7958 case APPEND_ADD:
7959 insert_into_history (0, 1, ip);
7960 break;
7962 case APPEND_ADD_WITH_NOP:
7964 struct mips_cl_insn *nop;
7966 insert_into_history (0, 1, ip);
7967 nop = get_delay_slot_nop (ip);
7968 add_fixed_insn (nop);
7969 insert_into_history (0, 1, nop);
7970 if (mips_relax.sequence)
7971 mips_relax.sizes[mips_relax.sequence - 1] += insn_length (nop);
7973 break;
7975 case APPEND_ADD_COMPACT:
7976 /* Convert MIPS16 jr/jalr into a "compact" jump. */
7977 if (mips_opts.mips16)
7979 ip->insn_opcode |= 0x0080;
7980 find_altered_mips16_opcode (ip);
7982 /* Convert microMIPS instructions. */
7983 else if (mips_opts.micromips)
7985 /* jr16->jrc */
7986 if ((ip->insn_opcode & 0xffe0) == 0x4580)
7987 ip->insn_opcode |= 0x0020;
7988 /* b16->bc */
7989 else if ((ip->insn_opcode & 0xfc00) == 0xcc00)
7990 ip->insn_opcode = 0x40e00000;
7991 /* beqz16->beqzc, bnez16->bnezc */
7992 else if ((ip->insn_opcode & 0xdc00) == 0x8c00)
7994 unsigned long regno;
7996 regno = ip->insn_opcode >> MICROMIPSOP_SH_MD;
7997 regno &= MICROMIPSOP_MASK_MD;
7998 regno = micromips_to_32_reg_d_map[regno];
7999 ip->insn_opcode = (((ip->insn_opcode << 9) & 0x00400000)
8000 | (regno << MICROMIPSOP_SH_RS)
8001 | 0x40a00000) ^ 0x00400000;
8003 /* beqz->beqzc, bnez->bnezc */
8004 else if ((ip->insn_opcode & 0xdfe00000) == 0x94000000)
8005 ip->insn_opcode = ((ip->insn_opcode & 0x001f0000)
8006 | ((ip->insn_opcode >> 7) & 0x00400000)
8007 | 0x40a00000) ^ 0x00400000;
8008 /* beq $0->beqzc, bne $0->bnezc */
8009 else if ((ip->insn_opcode & 0xdc1f0000) == 0x94000000)
8010 ip->insn_opcode = (((ip->insn_opcode >>
8011 (MICROMIPSOP_SH_RT - MICROMIPSOP_SH_RS))
8012 & (MICROMIPSOP_MASK_RS << MICROMIPSOP_SH_RS))
8013 | ((ip->insn_opcode >> 7) & 0x00400000)
8014 | 0x40a00000) ^ 0x00400000;
8015 else
8016 abort ();
8017 find_altered_micromips_opcode (ip);
8019 else
8020 abort ();
8021 install_insn (ip);
8022 insert_into_history (0, 1, ip);
8023 break;
8025 case APPEND_SWAP:
8027 struct mips_cl_insn delay = history[0];
8029 if (relaxed_branch || delay.frag != ip->frag)
8031 /* Add the delay slot instruction to the end of the
8032 current frag and shrink the fixed part of the
8033 original frag. If the branch occupies the tail of
8034 the latter, move it backwards to cover the gap. */
8035 delay.frag->fr_fix -= branch_disp;
8036 if (delay.frag == ip->frag)
8037 move_insn (ip, ip->frag, ip->where - branch_disp);
8038 add_fixed_insn (&delay);
8040 else
8042 /* If this is not a relaxed branch and we are in the
8043 same frag, then just swap the instructions. */
8044 move_insn (ip, delay.frag, delay.where);
8045 move_insn (&delay, ip->frag, ip->where + insn_length (ip));
8047 history[0] = *ip;
8048 delay.fixed_p = 1;
8049 insert_into_history (0, 1, &delay);
8051 break;
8054 /* If we have just completed an unconditional branch, clear the history. */
8055 if ((delayed_branch_p (&history[1]) && uncond_branch_p (&history[1]))
8056 || (compact_branch_p (&history[0]) && uncond_branch_p (&history[0])))
8058 unsigned int i;
8060 mips_no_prev_insn ();
8062 for (i = 0; i < ARRAY_SIZE (history); i++)
8063 history[i].cleared_p = 1;
8066 /* We need to emit a label at the end of branch-likely macros. */
8067 if (emit_branch_likely_macro)
8069 emit_branch_likely_macro = FALSE;
8070 micromips_add_label ();
8073 /* We just output an insn, so the next one doesn't have a label. */
8074 mips_clear_insn_labels ();
8077 /* Forget that there was any previous instruction or label.
8078 When BRANCH is true, the branch history is also flushed. */
8080 static void
8081 mips_no_prev_insn (void)
8083 prev_nop_frag = NULL;
8084 insert_into_history (0, ARRAY_SIZE (history), NOP_INSN);
8085 mips_clear_insn_labels ();
8088 /* This function must be called before we emit something other than
8089 instructions. It is like mips_no_prev_insn except that it inserts
8090 any NOPS that might be needed by previous instructions. */
8092 void
8093 mips_emit_delays (void)
8095 if (! mips_opts.noreorder)
8097 int nops = nops_for_insn (0, history, NULL);
8098 if (nops > 0)
8100 while (nops-- > 0)
8101 add_fixed_insn (NOP_INSN);
8102 mips_move_text_labels ();
8105 mips_no_prev_insn ();
8108 /* Start a (possibly nested) noreorder block. */
8110 static void
8111 start_noreorder (void)
8113 if (mips_opts.noreorder == 0)
8115 unsigned int i;
8116 int nops;
8118 /* None of the instructions before the .set noreorder can be moved. */
8119 for (i = 0; i < ARRAY_SIZE (history); i++)
8120 history[i].fixed_p = 1;
8122 /* Insert any nops that might be needed between the .set noreorder
8123 block and the previous instructions. We will later remove any
8124 nops that turn out not to be needed. */
8125 nops = nops_for_insn (0, history, NULL);
8126 if (nops > 0)
8128 if (mips_optimize != 0)
8130 /* Record the frag which holds the nop instructions, so
8131 that we can remove them if we don't need them. */
8132 frag_grow (nops * NOP_INSN_SIZE);
8133 prev_nop_frag = frag_now;
8134 prev_nop_frag_holds = nops;
8135 prev_nop_frag_required = 0;
8136 prev_nop_frag_since = 0;
8139 for (; nops > 0; --nops)
8140 add_fixed_insn (NOP_INSN);
8142 /* Move on to a new frag, so that it is safe to simply
8143 decrease the size of prev_nop_frag. */
8144 frag_wane (frag_now);
8145 frag_new (0);
8146 mips_move_text_labels ();
8148 mips_mark_labels ();
8149 mips_clear_insn_labels ();
8151 mips_opts.noreorder++;
8152 mips_any_noreorder = 1;
8155 /* End a nested noreorder block. */
8157 static void
8158 end_noreorder (void)
8160 mips_opts.noreorder--;
8161 if (mips_opts.noreorder == 0 && prev_nop_frag != NULL)
8163 /* Commit to inserting prev_nop_frag_required nops and go back to
8164 handling nop insertion the .set reorder way. */
8165 prev_nop_frag->fr_fix -= ((prev_nop_frag_holds - prev_nop_frag_required)
8166 * NOP_INSN_SIZE);
8167 insert_into_history (prev_nop_frag_since,
8168 prev_nop_frag_required, NOP_INSN);
8169 prev_nop_frag = NULL;
8173 /* Sign-extend 32-bit mode constants that have bit 31 set and all
8174 higher bits unset. */
8176 static void
8177 normalize_constant_expr (expressionS *ex)
8179 if (ex->X_op == O_constant
8180 && IS_ZEXT_32BIT_NUM (ex->X_add_number))
8181 ex->X_add_number = (((ex->X_add_number & 0xffffffff) ^ 0x80000000)
8182 - 0x80000000);
8185 /* Sign-extend 32-bit mode address offsets that have bit 31 set and
8186 all higher bits unset. */
8188 static void
8189 normalize_address_expr (expressionS *ex)
8191 if (((ex->X_op == O_constant && HAVE_32BIT_ADDRESSES)
8192 || (ex->X_op == O_symbol && HAVE_32BIT_SYMBOLS))
8193 && IS_ZEXT_32BIT_NUM (ex->X_add_number))
8194 ex->X_add_number = (((ex->X_add_number & 0xffffffff) ^ 0x80000000)
8195 - 0x80000000);
8198 /* Try to match TOKENS against OPCODE, storing the result in INSN.
8199 Return true if the match was successful.
8201 OPCODE_EXTRA is a value that should be ORed into the opcode
8202 (used for VU0 channel suffixes, etc.). MORE_ALTS is true if
8203 there are more alternatives after OPCODE and SOFT_MATCH is
8204 as for mips_arg_info. */
8206 static bfd_boolean
8207 match_insn (struct mips_cl_insn *insn, const struct mips_opcode *opcode,
8208 struct mips_operand_token *tokens, unsigned int opcode_extra,
8209 bfd_boolean lax_match, bfd_boolean complete_p)
8211 const char *args;
8212 struct mips_arg_info arg;
8213 const struct mips_operand *operand;
8214 char c;
8216 imm_expr.X_op = O_absent;
8217 offset_expr.X_op = O_absent;
8218 offset_reloc[0] = BFD_RELOC_UNUSED;
8219 offset_reloc[1] = BFD_RELOC_UNUSED;
8220 offset_reloc[2] = BFD_RELOC_UNUSED;
8222 create_insn (insn, opcode);
8223 /* When no opcode suffix is specified, assume ".xyzw". */
8224 if ((opcode->pinfo2 & INSN2_VU0_CHANNEL_SUFFIX) != 0 && opcode_extra == 0)
8225 insn->insn_opcode |= 0xf << mips_vu0_channel_mask.lsb;
8226 else
8227 insn->insn_opcode |= opcode_extra;
8228 memset (&arg, 0, sizeof (arg));
8229 arg.insn = insn;
8230 arg.token = tokens;
8231 arg.argnum = 1;
8232 arg.last_regno = ILLEGAL_REG;
8233 arg.dest_regno = ILLEGAL_REG;
8234 arg.lax_match = lax_match;
8235 for (args = opcode->args;; ++args)
8237 if (arg.token->type == OT_END)
8239 /* Handle unary instructions in which only one operand is given.
8240 The source is then the same as the destination. */
8241 if (arg.opnum == 1 && *args == ',')
8243 operand = (mips_opts.micromips
8244 ? decode_micromips_operand (args + 1)
8245 : decode_mips_operand (args + 1));
8246 if (operand && mips_optional_operand_p (operand))
8248 arg.token = tokens;
8249 arg.argnum = 1;
8250 continue;
8254 /* Treat elided base registers as $0. */
8255 if (strcmp (args, "(b)") == 0)
8256 args += 3;
8258 if (args[0] == '+')
8259 switch (args[1])
8261 case 'K':
8262 case 'N':
8263 /* The register suffix is optional. */
8264 args += 2;
8265 break;
8268 /* Fail the match if there were too few operands. */
8269 if (*args)
8270 return FALSE;
8272 /* Successful match. */
8273 if (!complete_p)
8274 return TRUE;
8275 clear_insn_error ();
8276 if (arg.dest_regno == arg.last_regno
8277 && strncmp (insn->insn_mo->name, "jalr", 4) == 0)
8279 if (arg.opnum == 2)
8280 set_insn_error
8281 (0, _("source and destination must be different"));
8282 else if (arg.last_regno == 31)
8283 set_insn_error
8284 (0, _("a destination register must be supplied"));
8286 else if (arg.last_regno == 31
8287 && (strncmp (insn->insn_mo->name, "bltzal", 6) == 0
8288 || strncmp (insn->insn_mo->name, "bgezal", 6) == 0))
8289 set_insn_error (0, _("the source register must not be $31"));
8290 check_completed_insn (&arg);
8291 return TRUE;
8294 /* Fail the match if the line has too many operands. */
8295 if (*args == 0)
8296 return FALSE;
8298 /* Handle characters that need to match exactly. */
8299 if (*args == '(' || *args == ')' || *args == ',')
8301 if (match_char (&arg, *args))
8302 continue;
8303 return FALSE;
8305 if (*args == '#')
8307 ++args;
8308 if (arg.token->type == OT_DOUBLE_CHAR
8309 && arg.token->u.ch == *args)
8311 ++arg.token;
8312 continue;
8314 return FALSE;
8317 /* Handle special macro operands. Work out the properties of
8318 other operands. */
8319 arg.opnum += 1;
8320 switch (*args)
8322 case '-':
8323 switch (args[1])
8325 case 'A':
8326 *offset_reloc = BFD_RELOC_MIPS_19_PCREL_S2;
8327 break;
8329 case 'B':
8330 *offset_reloc = BFD_RELOC_MIPS_18_PCREL_S3;
8331 break;
8333 break;
8335 case '+':
8336 switch (args[1])
8338 case 'i':
8339 *offset_reloc = BFD_RELOC_MIPS_JMP;
8340 break;
8342 case '\'':
8343 *offset_reloc = BFD_RELOC_MIPS_26_PCREL_S2;
8344 break;
8346 case '\"':
8347 *offset_reloc = BFD_RELOC_MIPS_21_PCREL_S2;
8348 break;
8350 break;
8352 case 'I':
8353 if (!match_const_int (&arg, &imm_expr.X_add_number))
8354 return FALSE;
8355 imm_expr.X_op = O_constant;
8356 if (GPR_SIZE == 32)
8357 normalize_constant_expr (&imm_expr);
8358 continue;
8360 case 'A':
8361 if (arg.token->type == OT_CHAR && arg.token->u.ch == '(')
8363 /* Assume that the offset has been elided and that what
8364 we saw was a base register. The match will fail later
8365 if that assumption turns out to be wrong. */
8366 offset_expr.X_op = O_constant;
8367 offset_expr.X_add_number = 0;
8369 else
8371 if (!match_expression (&arg, &offset_expr, offset_reloc))
8372 return FALSE;
8373 normalize_address_expr (&offset_expr);
8375 continue;
8377 case 'F':
8378 if (!match_float_constant (&arg, &imm_expr, &offset_expr,
8379 8, TRUE))
8380 return FALSE;
8381 continue;
8383 case 'L':
8384 if (!match_float_constant (&arg, &imm_expr, &offset_expr,
8385 8, FALSE))
8386 return FALSE;
8387 continue;
8389 case 'f':
8390 if (!match_float_constant (&arg, &imm_expr, &offset_expr,
8391 4, TRUE))
8392 return FALSE;
8393 continue;
8395 case 'l':
8396 if (!match_float_constant (&arg, &imm_expr, &offset_expr,
8397 4, FALSE))
8398 return FALSE;
8399 continue;
8401 case 'p':
8402 *offset_reloc = BFD_RELOC_16_PCREL_S2;
8403 break;
8405 case 'a':
8406 *offset_reloc = BFD_RELOC_MIPS_JMP;
8407 break;
8409 case 'm':
8410 gas_assert (mips_opts.micromips);
8411 c = args[1];
8412 switch (c)
8414 case 'D':
8415 case 'E':
8416 if (!forced_insn_length)
8417 *offset_reloc = (int) BFD_RELOC_UNUSED + c;
8418 else if (c == 'D')
8419 *offset_reloc = BFD_RELOC_MICROMIPS_10_PCREL_S1;
8420 else
8421 *offset_reloc = BFD_RELOC_MICROMIPS_7_PCREL_S1;
8422 break;
8424 break;
8427 operand = (mips_opts.micromips
8428 ? decode_micromips_operand (args)
8429 : decode_mips_operand (args));
8430 if (!operand)
8431 abort ();
8433 /* Skip prefixes. */
8434 if (*args == '+' || *args == 'm' || *args == '-')
8435 args++;
8437 if (mips_optional_operand_p (operand)
8438 && args[1] == ','
8439 && (arg.token[0].type != OT_REG
8440 || arg.token[1].type == OT_END))
8442 /* Assume that the register has been elided and is the
8443 same as the first operand. */
8444 arg.token = tokens;
8445 arg.argnum = 1;
8448 if (!match_operand (&arg, operand))
8449 return FALSE;
8453 /* Like match_insn, but for MIPS16. */
8455 static bfd_boolean
8456 match_mips16_insn (struct mips_cl_insn *insn, const struct mips_opcode *opcode,
8457 struct mips_operand_token *tokens)
8459 const char *args;
8460 const struct mips_operand *operand;
8461 const struct mips_operand *ext_operand;
8462 bfd_boolean pcrel = FALSE;
8463 int required_insn_length;
8464 struct mips_arg_info arg;
8465 int relax_char;
8467 if (forced_insn_length)
8468 required_insn_length = forced_insn_length;
8469 else if (mips_opts.noautoextend && !mips_opcode_32bit_p (opcode))
8470 required_insn_length = 2;
8471 else
8472 required_insn_length = 0;
8474 create_insn (insn, opcode);
8475 imm_expr.X_op = O_absent;
8476 offset_expr.X_op = O_absent;
8477 offset_reloc[0] = BFD_RELOC_UNUSED;
8478 offset_reloc[1] = BFD_RELOC_UNUSED;
8479 offset_reloc[2] = BFD_RELOC_UNUSED;
8480 relax_char = 0;
8482 memset (&arg, 0, sizeof (arg));
8483 arg.insn = insn;
8484 arg.token = tokens;
8485 arg.argnum = 1;
8486 arg.last_regno = ILLEGAL_REG;
8487 arg.dest_regno = ILLEGAL_REG;
8488 relax_char = 0;
8489 for (args = opcode->args;; ++args)
8491 int c;
8493 if (arg.token->type == OT_END)
8495 offsetT value;
8497 /* Handle unary instructions in which only one operand is given.
8498 The source is then the same as the destination. */
8499 if (arg.opnum == 1 && *args == ',')
8501 operand = decode_mips16_operand (args[1], FALSE);
8502 if (operand && mips_optional_operand_p (operand))
8504 arg.token = tokens;
8505 arg.argnum = 1;
8506 continue;
8510 /* Fail the match if there were too few operands. */
8511 if (*args)
8512 return FALSE;
8514 /* Successful match. Stuff the immediate value in now, if
8515 we can. */
8516 clear_insn_error ();
8517 if (opcode->pinfo == INSN_MACRO)
8519 gas_assert (relax_char == 0 || relax_char == 'p');
8520 gas_assert (*offset_reloc == BFD_RELOC_UNUSED);
8522 else if (relax_char
8523 && offset_expr.X_op == O_constant
8524 && !pcrel
8525 && calculate_reloc (*offset_reloc,
8526 offset_expr.X_add_number,
8527 &value))
8529 mips16_immed (NULL, 0, relax_char, *offset_reloc, value,
8530 required_insn_length, &insn->insn_opcode);
8531 offset_expr.X_op = O_absent;
8532 *offset_reloc = BFD_RELOC_UNUSED;
8534 else if (relax_char && *offset_reloc != BFD_RELOC_UNUSED)
8536 if (required_insn_length == 2)
8537 set_insn_error (0, _("invalid unextended operand value"));
8538 else if (!mips_opcode_32bit_p (opcode))
8540 forced_insn_length = 4;
8541 insn->insn_opcode |= MIPS16_EXTEND;
8544 else if (relax_char)
8545 *offset_reloc = (int) BFD_RELOC_UNUSED + relax_char;
8547 check_completed_insn (&arg);
8548 return TRUE;
8551 /* Fail the match if the line has too many operands. */
8552 if (*args == 0)
8553 return FALSE;
8555 /* Handle characters that need to match exactly. */
8556 if (*args == '(' || *args == ')' || *args == ',')
8558 if (match_char (&arg, *args))
8559 continue;
8560 return FALSE;
8563 arg.opnum += 1;
8564 c = *args;
8565 switch (c)
8567 case 'p':
8568 case 'q':
8569 case 'A':
8570 case 'B':
8571 case 'E':
8572 case 'V':
8573 case 'u':
8574 relax_char = c;
8575 break;
8577 case 'I':
8578 if (!match_const_int (&arg, &imm_expr.X_add_number))
8579 return FALSE;
8580 imm_expr.X_op = O_constant;
8581 if (GPR_SIZE == 32)
8582 normalize_constant_expr (&imm_expr);
8583 continue;
8585 case 'a':
8586 case 'i':
8587 *offset_reloc = BFD_RELOC_MIPS16_JMP;
8588 break;
8591 operand = decode_mips16_operand (c, mips_opcode_32bit_p (opcode));
8592 if (!operand)
8593 abort ();
8595 if (operand->type == OP_PCREL)
8596 pcrel = TRUE;
8597 else
8599 ext_operand = decode_mips16_operand (c, TRUE);
8600 if (operand != ext_operand)
8602 if (arg.token->type == OT_CHAR && arg.token->u.ch == '(')
8604 offset_expr.X_op = O_constant;
8605 offset_expr.X_add_number = 0;
8606 relax_char = c;
8607 continue;
8610 if (!match_expression (&arg, &offset_expr, offset_reloc))
8611 return FALSE;
8613 /* '8' is used for SLTI(U) and has traditionally not
8614 been allowed to take relocation operators. */
8615 if (offset_reloc[0] != BFD_RELOC_UNUSED
8616 && (ext_operand->size != 16 || c == '8'))
8618 match_not_constant (&arg);
8619 return FALSE;
8622 if (offset_expr.X_op == O_big)
8624 match_out_of_range (&arg);
8625 return FALSE;
8628 relax_char = c;
8629 continue;
8633 if (mips_optional_operand_p (operand)
8634 && args[1] == ','
8635 && (arg.token[0].type != OT_REG
8636 || arg.token[1].type == OT_END))
8638 /* Assume that the register has been elided and is the
8639 same as the first operand. */
8640 arg.token = tokens;
8641 arg.argnum = 1;
8644 if (!match_operand (&arg, operand))
8645 return FALSE;
8649 /* Record that the current instruction is invalid for the current ISA. */
8651 static void
8652 match_invalid_for_isa (void)
8654 set_insn_error_ss
8655 (0, _("opcode not supported on this processor: %s (%s)"),
8656 mips_cpu_info_from_arch (mips_opts.arch)->name,
8657 mips_cpu_info_from_isa (mips_opts.isa)->name);
8660 /* Try to match TOKENS against a series of opcode entries, starting at FIRST.
8661 Return true if a definite match or failure was found, storing any match
8662 in INSN. OPCODE_EXTRA is a value that should be ORed into the opcode
8663 (to handle things like VU0 suffixes). LAX_MATCH is true if we have already
8664 tried and failed to match under normal conditions and now want to try a
8665 more relaxed match. */
8667 static bfd_boolean
8668 match_insns (struct mips_cl_insn *insn, const struct mips_opcode *first,
8669 const struct mips_opcode *past, struct mips_operand_token *tokens,
8670 int opcode_extra, bfd_boolean lax_match)
8672 const struct mips_opcode *opcode;
8673 const struct mips_opcode *invalid_delay_slot;
8674 bfd_boolean seen_valid_for_isa, seen_valid_for_size;
8676 /* Search for a match, ignoring alternatives that don't satisfy the
8677 current ISA or forced_length. */
8678 invalid_delay_slot = 0;
8679 seen_valid_for_isa = FALSE;
8680 seen_valid_for_size = FALSE;
8681 opcode = first;
8684 gas_assert (strcmp (opcode->name, first->name) == 0);
8685 if (is_opcode_valid (opcode))
8687 seen_valid_for_isa = TRUE;
8688 if (is_size_valid (opcode))
8690 bfd_boolean delay_slot_ok;
8692 seen_valid_for_size = TRUE;
8693 delay_slot_ok = is_delay_slot_valid (opcode);
8694 if (match_insn (insn, opcode, tokens, opcode_extra,
8695 lax_match, delay_slot_ok))
8697 if (!delay_slot_ok)
8699 if (!invalid_delay_slot)
8700 invalid_delay_slot = opcode;
8702 else
8703 return TRUE;
8707 ++opcode;
8709 while (opcode < past && strcmp (opcode->name, first->name) == 0);
8711 /* If the only matches we found had the wrong length for the delay slot,
8712 pick the first such match. We'll issue an appropriate warning later. */
8713 if (invalid_delay_slot)
8715 if (match_insn (insn, invalid_delay_slot, tokens, opcode_extra,
8716 lax_match, TRUE))
8717 return TRUE;
8718 abort ();
8721 /* Handle the case where we didn't try to match an instruction because
8722 all the alternatives were incompatible with the current ISA. */
8723 if (!seen_valid_for_isa)
8725 match_invalid_for_isa ();
8726 return TRUE;
8729 /* Handle the case where we didn't try to match an instruction because
8730 all the alternatives were of the wrong size. */
8731 if (!seen_valid_for_size)
8733 if (mips_opts.insn32)
8734 set_insn_error (0, _("opcode not supported in the `insn32' mode"));
8735 else
8736 set_insn_error_i
8737 (0, _("unrecognized %d-bit version of microMIPS opcode"),
8738 8 * forced_insn_length);
8739 return TRUE;
8742 return FALSE;
8745 /* Like match_insns, but for MIPS16. */
8747 static bfd_boolean
8748 match_mips16_insns (struct mips_cl_insn *insn, const struct mips_opcode *first,
8749 struct mips_operand_token *tokens)
8751 const struct mips_opcode *opcode;
8752 bfd_boolean seen_valid_for_isa;
8753 bfd_boolean seen_valid_for_size;
8755 /* Search for a match, ignoring alternatives that don't satisfy the
8756 current ISA. There are no separate entries for extended forms so
8757 we deal with forced_length later. */
8758 seen_valid_for_isa = FALSE;
8759 seen_valid_for_size = FALSE;
8760 opcode = first;
8763 gas_assert (strcmp (opcode->name, first->name) == 0);
8764 if (is_opcode_valid_16 (opcode))
8766 seen_valid_for_isa = TRUE;
8767 if (is_size_valid_16 (opcode))
8769 seen_valid_for_size = TRUE;
8770 if (match_mips16_insn (insn, opcode, tokens))
8771 return TRUE;
8774 ++opcode;
8776 while (opcode < &mips16_opcodes[bfd_mips16_num_opcodes]
8777 && strcmp (opcode->name, first->name) == 0);
8779 /* Handle the case where we didn't try to match an instruction because
8780 all the alternatives were incompatible with the current ISA. */
8781 if (!seen_valid_for_isa)
8783 match_invalid_for_isa ();
8784 return TRUE;
8787 /* Handle the case where we didn't try to match an instruction because
8788 all the alternatives were of the wrong size. */
8789 if (!seen_valid_for_size)
8791 if (forced_insn_length == 2)
8792 set_insn_error
8793 (0, _("unrecognized unextended version of MIPS16 opcode"));
8794 else
8795 set_insn_error
8796 (0, _("unrecognized extended version of MIPS16 opcode"));
8797 return TRUE;
8800 return FALSE;
8803 /* Set up global variables for the start of a new macro. */
8805 static void
8806 macro_start (void)
8808 memset (&mips_macro_warning.sizes, 0, sizeof (mips_macro_warning.sizes));
8809 memset (&mips_macro_warning.first_insn_sizes, 0,
8810 sizeof (mips_macro_warning.first_insn_sizes));
8811 memset (&mips_macro_warning.insns, 0, sizeof (mips_macro_warning.insns));
8812 mips_macro_warning.delay_slot_p = (mips_opts.noreorder
8813 && delayed_branch_p (&history[0]));
8814 if (history[0].frag
8815 && history[0].frag->fr_type == rs_machine_dependent
8816 && RELAX_MICROMIPS_P (history[0].frag->fr_subtype)
8817 && RELAX_MICROMIPS_NODS (history[0].frag->fr_subtype))
8818 mips_macro_warning.delay_slot_length = 0;
8819 else
8820 switch (history[0].insn_mo->pinfo2
8821 & (INSN2_BRANCH_DELAY_32BIT | INSN2_BRANCH_DELAY_16BIT))
8823 case INSN2_BRANCH_DELAY_32BIT:
8824 mips_macro_warning.delay_slot_length = 4;
8825 break;
8826 case INSN2_BRANCH_DELAY_16BIT:
8827 mips_macro_warning.delay_slot_length = 2;
8828 break;
8829 default:
8830 mips_macro_warning.delay_slot_length = 0;
8831 break;
8833 mips_macro_warning.first_frag = NULL;
8836 /* Given that a macro is longer than one instruction or of the wrong size,
8837 return the appropriate warning for it. Return null if no warning is
8838 needed. SUBTYPE is a bitmask of RELAX_DELAY_SLOT, RELAX_DELAY_SLOT_16BIT,
8839 RELAX_DELAY_SLOT_SIZE_FIRST, RELAX_DELAY_SLOT_SIZE_SECOND,
8840 and RELAX_NOMACRO. */
8842 static const char *
8843 macro_warning (relax_substateT subtype)
8845 if (subtype & RELAX_DELAY_SLOT)
8846 return _("macro instruction expanded into multiple instructions"
8847 " in a branch delay slot");
8848 else if (subtype & RELAX_NOMACRO)
8849 return _("macro instruction expanded into multiple instructions");
8850 else if (subtype & (RELAX_DELAY_SLOT_SIZE_FIRST
8851 | RELAX_DELAY_SLOT_SIZE_SECOND))
8852 return ((subtype & RELAX_DELAY_SLOT_16BIT)
8853 ? _("macro instruction expanded into a wrong size instruction"
8854 " in a 16-bit branch delay slot")
8855 : _("macro instruction expanded into a wrong size instruction"
8856 " in a 32-bit branch delay slot"));
8857 else
8858 return 0;
8861 /* Finish up a macro. Emit warnings as appropriate. */
8863 static void
8864 macro_end (void)
8866 /* Relaxation warning flags. */
8867 relax_substateT subtype = 0;
8869 /* Check delay slot size requirements. */
8870 if (mips_macro_warning.delay_slot_length == 2)
8871 subtype |= RELAX_DELAY_SLOT_16BIT;
8872 if (mips_macro_warning.delay_slot_length != 0)
8874 if (mips_macro_warning.delay_slot_length
8875 != mips_macro_warning.first_insn_sizes[0])
8876 subtype |= RELAX_DELAY_SLOT_SIZE_FIRST;
8877 if (mips_macro_warning.delay_slot_length
8878 != mips_macro_warning.first_insn_sizes[1])
8879 subtype |= RELAX_DELAY_SLOT_SIZE_SECOND;
8882 /* Check instruction count requirements. */
8883 if (mips_macro_warning.insns[0] > 1 || mips_macro_warning.insns[1] > 1)
8885 if (mips_macro_warning.insns[1] > mips_macro_warning.insns[0])
8886 subtype |= RELAX_SECOND_LONGER;
8887 if (mips_opts.warn_about_macros)
8888 subtype |= RELAX_NOMACRO;
8889 if (mips_macro_warning.delay_slot_p)
8890 subtype |= RELAX_DELAY_SLOT;
8893 /* If both alternatives fail to fill a delay slot correctly,
8894 emit the warning now. */
8895 if ((subtype & RELAX_DELAY_SLOT_SIZE_FIRST) != 0
8896 && (subtype & RELAX_DELAY_SLOT_SIZE_SECOND) != 0)
8898 relax_substateT s;
8899 const char *msg;
8901 s = subtype & (RELAX_DELAY_SLOT_16BIT
8902 | RELAX_DELAY_SLOT_SIZE_FIRST
8903 | RELAX_DELAY_SLOT_SIZE_SECOND);
8904 msg = macro_warning (s);
8905 if (msg != NULL)
8906 as_warn ("%s", msg);
8907 subtype &= ~s;
8910 /* If both implementations are longer than 1 instruction, then emit the
8911 warning now. */
8912 if (mips_macro_warning.insns[0] > 1 && mips_macro_warning.insns[1] > 1)
8914 relax_substateT s;
8915 const char *msg;
8917 s = subtype & (RELAX_SECOND_LONGER | RELAX_NOMACRO | RELAX_DELAY_SLOT);
8918 msg = macro_warning (s);
8919 if (msg != NULL)
8920 as_warn ("%s", msg);
8921 subtype &= ~s;
8924 /* If any flags still set, then one implementation might need a warning
8925 and the other either will need one of a different kind or none at all.
8926 Pass any remaining flags over to relaxation. */
8927 if (mips_macro_warning.first_frag != NULL)
8928 mips_macro_warning.first_frag->fr_subtype |= subtype;
8931 /* Instruction operand formats used in macros that vary between
8932 standard MIPS and microMIPS code. */
8934 static const char * const brk_fmt[2][2] = { { "c", "c" }, { "mF", "c" } };
8935 static const char * const cop12_fmt[2] = { "E,o(b)", "E,~(b)" };
8936 static const char * const jalr_fmt[2] = { "d,s", "t,s" };
8937 static const char * const lui_fmt[2] = { "t,u", "s,u" };
8938 static const char * const mem12_fmt[2] = { "t,o(b)", "t,~(b)" };
8939 static const char * const mfhl_fmt[2][2] = { { "d", "d" }, { "mj", "s" } };
8940 static const char * const shft_fmt[2] = { "d,w,<", "t,r,<" };
8941 static const char * const trap_fmt[2] = { "s,t,q", "s,t,|" };
8943 #define BRK_FMT (brk_fmt[mips_opts.micromips][mips_opts.insn32])
8944 #define COP12_FMT (ISA_IS_R6 (mips_opts.isa) ? "E,+:(d)" \
8945 : cop12_fmt[mips_opts.micromips])
8946 #define JALR_FMT (jalr_fmt[mips_opts.micromips])
8947 #define LUI_FMT (lui_fmt[mips_opts.micromips])
8948 #define MEM12_FMT (mem12_fmt[mips_opts.micromips])
8949 #define LL_SC_FMT (ISA_IS_R6 (mips_opts.isa) ? "t,+j(b)" \
8950 : mem12_fmt[mips_opts.micromips])
8951 #define MFHL_FMT (mfhl_fmt[mips_opts.micromips][mips_opts.insn32])
8952 #define SHFT_FMT (shft_fmt[mips_opts.micromips])
8953 #define TRAP_FMT (trap_fmt[mips_opts.micromips])
8955 /* Read a macro's relocation codes from *ARGS and store them in *R.
8956 The first argument in *ARGS will be either the code for a single
8957 relocation or -1 followed by the three codes that make up a
8958 composite relocation. */
8960 static void
8961 macro_read_relocs (va_list *args, bfd_reloc_code_real_type *r)
8963 int i, next;
8965 next = va_arg (*args, int);
8966 if (next >= 0)
8967 r[0] = (bfd_reloc_code_real_type) next;
8968 else
8970 for (i = 0; i < 3; i++)
8971 r[i] = (bfd_reloc_code_real_type) va_arg (*args, int);
8972 /* This function is only used for 16-bit relocation fields.
8973 To make the macro code simpler, treat an unrelocated value
8974 in the same way as BFD_RELOC_LO16. */
8975 if (r[0] == BFD_RELOC_UNUSED)
8976 r[0] = BFD_RELOC_LO16;
8980 /* Build an instruction created by a macro expansion. This is passed
8981 a pointer to the count of instructions created so far, an
8982 expression, the name of the instruction to build, an operand format
8983 string, and corresponding arguments. */
8985 static void
8986 macro_build (expressionS *ep, const char *name, const char *fmt, ...)
8988 const struct mips_opcode *mo = NULL;
8989 bfd_reloc_code_real_type r[3];
8990 const struct mips_opcode *amo;
8991 const struct mips_operand *operand;
8992 struct hash_control *hash;
8993 struct mips_cl_insn insn;
8994 va_list args;
8995 unsigned int uval;
8997 va_start (args, fmt);
8999 if (mips_opts.mips16)
9001 mips16_macro_build (ep, name, fmt, &args);
9002 va_end (args);
9003 return;
9006 r[0] = BFD_RELOC_UNUSED;
9007 r[1] = BFD_RELOC_UNUSED;
9008 r[2] = BFD_RELOC_UNUSED;
9009 hash = mips_opts.micromips ? micromips_op_hash : op_hash;
9010 amo = (struct mips_opcode *) hash_find (hash, name);
9011 gas_assert (amo);
9012 gas_assert (strcmp (name, amo->name) == 0);
9016 /* Search until we get a match for NAME. It is assumed here that
9017 macros will never generate MDMX, MIPS-3D, or MT instructions.
9018 We try to match an instruction that fulfills the branch delay
9019 slot instruction length requirement (if any) of the previous
9020 instruction. While doing this we record the first instruction
9021 seen that matches all the other conditions and use it anyway
9022 if the requirement cannot be met; we will issue an appropriate
9023 warning later on. */
9024 if (strcmp (fmt, amo->args) == 0
9025 && amo->pinfo != INSN_MACRO
9026 && is_opcode_valid (amo)
9027 && is_size_valid (amo))
9029 if (is_delay_slot_valid (amo))
9031 mo = amo;
9032 break;
9034 else if (!mo)
9035 mo = amo;
9038 ++amo;
9039 gas_assert (amo->name);
9041 while (strcmp (name, amo->name) == 0);
9043 gas_assert (mo);
9044 create_insn (&insn, mo);
9045 for (; *fmt; ++fmt)
9047 switch (*fmt)
9049 case ',':
9050 case '(':
9051 case ')':
9052 case 'z':
9053 break;
9055 case 'i':
9056 case 'j':
9057 macro_read_relocs (&args, r);
9058 gas_assert (*r == BFD_RELOC_GPREL16
9059 || *r == BFD_RELOC_MIPS_HIGHER
9060 || *r == BFD_RELOC_HI16_S
9061 || *r == BFD_RELOC_LO16
9062 || *r == BFD_RELOC_MIPS_GOT_OFST
9063 || (mips_opts.micromips
9064 && (*r == BFD_RELOC_16
9065 || *r == BFD_RELOC_MIPS_GOT16
9066 || *r == BFD_RELOC_MIPS_CALL16
9067 || *r == BFD_RELOC_MIPS_GOT_HI16
9068 || *r == BFD_RELOC_MIPS_GOT_LO16
9069 || *r == BFD_RELOC_MIPS_CALL_HI16
9070 || *r == BFD_RELOC_MIPS_CALL_LO16
9071 || *r == BFD_RELOC_MIPS_SUB
9072 || *r == BFD_RELOC_MIPS_GOT_PAGE
9073 || *r == BFD_RELOC_MIPS_HIGHEST
9074 || *r == BFD_RELOC_MIPS_GOT_DISP
9075 || *r == BFD_RELOC_MIPS_TLS_GD
9076 || *r == BFD_RELOC_MIPS_TLS_LDM
9077 || *r == BFD_RELOC_MIPS_TLS_DTPREL_HI16
9078 || *r == BFD_RELOC_MIPS_TLS_DTPREL_LO16
9079 || *r == BFD_RELOC_MIPS_TLS_GOTTPREL
9080 || *r == BFD_RELOC_MIPS_TLS_TPREL_HI16
9081 || *r == BFD_RELOC_MIPS_TLS_TPREL_LO16)));
9082 break;
9084 case 'o':
9085 macro_read_relocs (&args, r);
9086 break;
9088 case 'u':
9089 macro_read_relocs (&args, r);
9090 gas_assert (ep != NULL
9091 && (ep->X_op == O_constant
9092 || (ep->X_op == O_symbol
9093 && (*r == BFD_RELOC_MIPS_HIGHEST
9094 || *r == BFD_RELOC_HI16_S
9095 || *r == BFD_RELOC_HI16
9096 || *r == BFD_RELOC_GPREL16
9097 || *r == BFD_RELOC_MIPS_GOT_HI16
9098 || *r == BFD_RELOC_MIPS_CALL_HI16))));
9099 break;
9101 case 'p':
9102 gas_assert (ep != NULL);
9105 * This allows macro() to pass an immediate expression for
9106 * creating short branches without creating a symbol.
9108 * We don't allow branch relaxation for these branches, as
9109 * they should only appear in ".set nomacro" anyway.
9111 if (ep->X_op == O_constant)
9113 /* For microMIPS we always use relocations for branches.
9114 So we should not resolve immediate values. */
9115 gas_assert (!mips_opts.micromips);
9117 if ((ep->X_add_number & 3) != 0)
9118 as_bad (_("branch to misaligned address (0x%lx)"),
9119 (unsigned long) ep->X_add_number);
9120 if ((ep->X_add_number + 0x20000) & ~0x3ffff)
9121 as_bad (_("branch address range overflow (0x%lx)"),
9122 (unsigned long) ep->X_add_number);
9123 insn.insn_opcode |= (ep->X_add_number >> 2) & 0xffff;
9124 ep = NULL;
9126 else
9127 *r = BFD_RELOC_16_PCREL_S2;
9128 break;
9130 case 'a':
9131 gas_assert (ep != NULL);
9132 *r = BFD_RELOC_MIPS_JMP;
9133 break;
9135 default:
9136 operand = (mips_opts.micromips
9137 ? decode_micromips_operand (fmt)
9138 : decode_mips_operand (fmt));
9139 if (!operand)
9140 abort ();
9142 uval = va_arg (args, int);
9143 if (operand->type == OP_CLO_CLZ_DEST)
9144 uval |= (uval << 5);
9145 insn_insert_operand (&insn, operand, uval);
9147 if (*fmt == '+' || *fmt == 'm' || *fmt == '-')
9148 ++fmt;
9149 break;
9152 va_end (args);
9153 gas_assert (*r == BFD_RELOC_UNUSED ? ep == NULL : ep != NULL);
9155 append_insn (&insn, ep, r, TRUE);
9158 static void
9159 mips16_macro_build (expressionS *ep, const char *name, const char *fmt,
9160 va_list *args)
9162 struct mips_opcode *mo;
9163 struct mips_cl_insn insn;
9164 const struct mips_operand *operand;
9165 bfd_reloc_code_real_type r[3]
9166 = {BFD_RELOC_UNUSED, BFD_RELOC_UNUSED, BFD_RELOC_UNUSED};
9168 mo = (struct mips_opcode *) hash_find (mips16_op_hash, name);
9169 gas_assert (mo);
9170 gas_assert (strcmp (name, mo->name) == 0);
9172 while (strcmp (fmt, mo->args) != 0 || mo->pinfo == INSN_MACRO)
9174 ++mo;
9175 gas_assert (mo->name);
9176 gas_assert (strcmp (name, mo->name) == 0);
9179 create_insn (&insn, mo);
9180 for (; *fmt; ++fmt)
9182 int c;
9184 c = *fmt;
9185 switch (c)
9187 case ',':
9188 case '(':
9189 case ')':
9190 break;
9192 case '.':
9193 case 'S':
9194 case 'P':
9195 case 'R':
9196 break;
9198 case '<':
9199 case '5':
9200 case 'F':
9201 case 'H':
9202 case 'W':
9203 case 'D':
9204 case 'j':
9205 case '8':
9206 case 'V':
9207 case 'C':
9208 case 'U':
9209 case 'k':
9210 case 'K':
9211 case 'p':
9212 case 'q':
9214 offsetT value;
9216 gas_assert (ep != NULL);
9218 if (ep->X_op != O_constant)
9219 *r = (int) BFD_RELOC_UNUSED + c;
9220 else if (calculate_reloc (*r, ep->X_add_number, &value))
9222 mips16_immed (NULL, 0, c, *r, value, 0, &insn.insn_opcode);
9223 ep = NULL;
9224 *r = BFD_RELOC_UNUSED;
9227 break;
9229 default:
9230 operand = decode_mips16_operand (c, FALSE);
9231 if (!operand)
9232 abort ();
9234 insn_insert_operand (&insn, operand, va_arg (*args, int));
9235 break;
9239 gas_assert (*r == BFD_RELOC_UNUSED ? ep == NULL : ep != NULL);
9241 append_insn (&insn, ep, r, TRUE);
9245 * Generate a "jalr" instruction with a relocation hint to the called
9246 * function. This occurs in NewABI PIC code.
9248 static void
9249 macro_build_jalr (expressionS *ep, int cprestore)
9251 static const bfd_reloc_code_real_type jalr_relocs[2]
9252 = { BFD_RELOC_MIPS_JALR, BFD_RELOC_MICROMIPS_JALR };
9253 bfd_reloc_code_real_type jalr_reloc = jalr_relocs[mips_opts.micromips];
9254 const char *jalr;
9255 char *f = NULL;
9257 if (MIPS_JALR_HINT_P (ep))
9259 frag_grow (8);
9260 f = frag_more (0);
9262 if (mips_opts.micromips)
9264 jalr = ((mips_opts.noreorder && !cprestore) || mips_opts.insn32
9265 ? "jalr" : "jalrs");
9266 if (MIPS_JALR_HINT_P (ep)
9267 || mips_opts.insn32
9268 || (history[0].insn_mo->pinfo2 & INSN2_BRANCH_DELAY_32BIT))
9269 macro_build (NULL, jalr, "t,s", RA, PIC_CALL_REG);
9270 else
9271 macro_build (NULL, jalr, "mj", PIC_CALL_REG);
9273 else
9274 macro_build (NULL, "jalr", "d,s", RA, PIC_CALL_REG);
9275 if (MIPS_JALR_HINT_P (ep))
9276 fix_new_exp (frag_now, f - frag_now->fr_literal, 4, ep, FALSE, jalr_reloc);
9280 * Generate a "lui" instruction.
9282 static void
9283 macro_build_lui (expressionS *ep, int regnum)
9285 gas_assert (! mips_opts.mips16);
9287 if (ep->X_op != O_constant)
9289 gas_assert (ep->X_op == O_symbol);
9290 /* _gp_disp is a special case, used from s_cpload.
9291 __gnu_local_gp is used if mips_no_shared. */
9292 gas_assert (mips_pic == NO_PIC
9293 || (! HAVE_NEWABI
9294 && strcmp (S_GET_NAME (ep->X_add_symbol), "_gp_disp") == 0)
9295 || (! mips_in_shared
9296 && strcmp (S_GET_NAME (ep->X_add_symbol),
9297 "__gnu_local_gp") == 0));
9300 macro_build (ep, "lui", LUI_FMT, regnum, BFD_RELOC_HI16_S);
9303 /* Generate a sequence of instructions to do a load or store from a constant
9304 offset off of a base register (breg) into/from a target register (treg),
9305 using AT if necessary. */
9306 static void
9307 macro_build_ldst_constoffset (expressionS *ep, const char *op,
9308 int treg, int breg, int dbl)
9310 gas_assert (ep->X_op == O_constant);
9312 /* Sign-extending 32-bit constants makes their handling easier. */
9313 if (!dbl)
9314 normalize_constant_expr (ep);
9316 /* Right now, this routine can only handle signed 32-bit constants. */
9317 if (! IS_SEXT_32BIT_NUM(ep->X_add_number + 0x8000))
9318 as_warn (_("operand overflow"));
9320 if (IS_SEXT_16BIT_NUM(ep->X_add_number))
9322 /* Signed 16-bit offset will fit in the op. Easy! */
9323 macro_build (ep, op, "t,o(b)", treg, BFD_RELOC_LO16, breg);
9325 else
9327 /* 32-bit offset, need multiple instructions and AT, like:
9328 lui $tempreg,const_hi (BFD_RELOC_HI16_S)
9329 addu $tempreg,$tempreg,$breg
9330 <op> $treg,const_lo($tempreg) (BFD_RELOC_LO16)
9331 to handle the complete offset. */
9332 macro_build_lui (ep, AT);
9333 macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t", AT, AT, breg);
9334 macro_build (ep, op, "t,o(b)", treg, BFD_RELOC_LO16, AT);
9336 if (!mips_opts.at)
9337 as_bad (_("macro used $at after \".set noat\""));
9341 /* set_at()
9342 * Generates code to set the $at register to true (one)
9343 * if reg is less than the immediate expression.
9345 static void
9346 set_at (int reg, int unsignedp)
9348 if (imm_expr.X_add_number >= -0x8000
9349 && imm_expr.X_add_number < 0x8000)
9350 macro_build (&imm_expr, unsignedp ? "sltiu" : "slti", "t,r,j",
9351 AT, reg, BFD_RELOC_LO16);
9352 else
9354 load_register (AT, &imm_expr, GPR_SIZE == 64);
9355 macro_build (NULL, unsignedp ? "sltu" : "slt", "d,v,t", AT, reg, AT);
9359 /* Count the leading zeroes by performing a binary chop. This is a
9360 bulky bit of source, but performance is a LOT better for the
9361 majority of values than a simple loop to count the bits:
9362 for (lcnt = 0; (lcnt < 32); lcnt++)
9363 if ((v) & (1 << (31 - lcnt)))
9364 break;
9365 However it is not code size friendly, and the gain will drop a bit
9366 on certain cached systems.
9368 #define COUNT_TOP_ZEROES(v) \
9369 (((v) & ~0xffff) == 0 \
9370 ? ((v) & ~0xff) == 0 \
9371 ? ((v) & ~0xf) == 0 \
9372 ? ((v) & ~0x3) == 0 \
9373 ? ((v) & ~0x1) == 0 \
9374 ? !(v) \
9375 ? 32 \
9376 : 31 \
9377 : 30 \
9378 : ((v) & ~0x7) == 0 \
9379 ? 29 \
9380 : 28 \
9381 : ((v) & ~0x3f) == 0 \
9382 ? ((v) & ~0x1f) == 0 \
9383 ? 27 \
9384 : 26 \
9385 : ((v) & ~0x7f) == 0 \
9386 ? 25 \
9387 : 24 \
9388 : ((v) & ~0xfff) == 0 \
9389 ? ((v) & ~0x3ff) == 0 \
9390 ? ((v) & ~0x1ff) == 0 \
9391 ? 23 \
9392 : 22 \
9393 : ((v) & ~0x7ff) == 0 \
9394 ? 21 \
9395 : 20 \
9396 : ((v) & ~0x3fff) == 0 \
9397 ? ((v) & ~0x1fff) == 0 \
9398 ? 19 \
9399 : 18 \
9400 : ((v) & ~0x7fff) == 0 \
9401 ? 17 \
9402 : 16 \
9403 : ((v) & ~0xffffff) == 0 \
9404 ? ((v) & ~0xfffff) == 0 \
9405 ? ((v) & ~0x3ffff) == 0 \
9406 ? ((v) & ~0x1ffff) == 0 \
9407 ? 15 \
9408 : 14 \
9409 : ((v) & ~0x7ffff) == 0 \
9410 ? 13 \
9411 : 12 \
9412 : ((v) & ~0x3fffff) == 0 \
9413 ? ((v) & ~0x1fffff) == 0 \
9414 ? 11 \
9415 : 10 \
9416 : ((v) & ~0x7fffff) == 0 \
9417 ? 9 \
9418 : 8 \
9419 : ((v) & ~0xfffffff) == 0 \
9420 ? ((v) & ~0x3ffffff) == 0 \
9421 ? ((v) & ~0x1ffffff) == 0 \
9422 ? 7 \
9423 : 6 \
9424 : ((v) & ~0x7ffffff) == 0 \
9425 ? 5 \
9426 : 4 \
9427 : ((v) & ~0x3fffffff) == 0 \
9428 ? ((v) & ~0x1fffffff) == 0 \
9429 ? 3 \
9430 : 2 \
9431 : ((v) & ~0x7fffffff) == 0 \
9432 ? 1 \
9433 : 0)
9435 /* load_register()
9436 * This routine generates the least number of instructions necessary to load
9437 * an absolute expression value into a register.
9439 static void
9440 load_register (int reg, expressionS *ep, int dbl)
9442 int freg;
9443 expressionS hi32, lo32;
9445 if (ep->X_op != O_big)
9447 gas_assert (ep->X_op == O_constant);
9449 /* Sign-extending 32-bit constants makes their handling easier. */
9450 if (!dbl)
9451 normalize_constant_expr (ep);
9453 if (IS_SEXT_16BIT_NUM (ep->X_add_number))
9455 /* We can handle 16 bit signed values with an addiu to
9456 $zero. No need to ever use daddiu here, since $zero and
9457 the result are always correct in 32 bit mode. */
9458 macro_build (ep, "addiu", "t,r,j", reg, 0, BFD_RELOC_LO16);
9459 return;
9461 else if (ep->X_add_number >= 0 && ep->X_add_number < 0x10000)
9463 /* We can handle 16 bit unsigned values with an ori to
9464 $zero. */
9465 macro_build (ep, "ori", "t,r,i", reg, 0, BFD_RELOC_LO16);
9466 return;
9468 else if ((IS_SEXT_32BIT_NUM (ep->X_add_number)))
9470 /* 32 bit values require an lui. */
9471 macro_build (ep, "lui", LUI_FMT, reg, BFD_RELOC_HI16);
9472 if ((ep->X_add_number & 0xffff) != 0)
9473 macro_build (ep, "ori", "t,r,i", reg, reg, BFD_RELOC_LO16);
9474 return;
9478 /* The value is larger than 32 bits. */
9480 if (!dbl || GPR_SIZE == 32)
9482 char value[32];
9484 sprintf_vma (value, ep->X_add_number);
9485 as_bad (_("number (0x%s) larger than 32 bits"), value);
9486 macro_build (ep, "addiu", "t,r,j", reg, 0, BFD_RELOC_LO16);
9487 return;
9490 if (ep->X_op != O_big)
9492 hi32 = *ep;
9493 hi32.X_add_number = (valueT) hi32.X_add_number >> 16;
9494 hi32.X_add_number = (valueT) hi32.X_add_number >> 16;
9495 hi32.X_add_number &= 0xffffffff;
9496 lo32 = *ep;
9497 lo32.X_add_number &= 0xffffffff;
9499 else
9501 gas_assert (ep->X_add_number > 2);
9502 if (ep->X_add_number == 3)
9503 generic_bignum[3] = 0;
9504 else if (ep->X_add_number > 4)
9505 as_bad (_("number larger than 64 bits"));
9506 lo32.X_op = O_constant;
9507 lo32.X_add_number = generic_bignum[0] + (generic_bignum[1] << 16);
9508 hi32.X_op = O_constant;
9509 hi32.X_add_number = generic_bignum[2] + (generic_bignum[3] << 16);
9512 if (hi32.X_add_number == 0)
9513 freg = 0;
9514 else
9516 int shift, bit;
9517 unsigned long hi, lo;
9519 if (hi32.X_add_number == (offsetT) 0xffffffff)
9521 if ((lo32.X_add_number & 0xffff8000) == 0xffff8000)
9523 macro_build (&lo32, "addiu", "t,r,j", reg, 0, BFD_RELOC_LO16);
9524 return;
9526 if (lo32.X_add_number & 0x80000000)
9528 macro_build (&lo32, "lui", LUI_FMT, reg, BFD_RELOC_HI16);
9529 if (lo32.X_add_number & 0xffff)
9530 macro_build (&lo32, "ori", "t,r,i", reg, reg, BFD_RELOC_LO16);
9531 return;
9535 /* Check for 16bit shifted constant. We know that hi32 is
9536 non-zero, so start the mask on the first bit of the hi32
9537 value. */
9538 shift = 17;
9541 unsigned long himask, lomask;
9543 if (shift < 32)
9545 himask = 0xffff >> (32 - shift);
9546 lomask = (0xffff << shift) & 0xffffffff;
9548 else
9550 himask = 0xffff << (shift - 32);
9551 lomask = 0;
9553 if ((hi32.X_add_number & ~(offsetT) himask) == 0
9554 && (lo32.X_add_number & ~(offsetT) lomask) == 0)
9556 expressionS tmp;
9558 tmp.X_op = O_constant;
9559 if (shift < 32)
9560 tmp.X_add_number = ((hi32.X_add_number << (32 - shift))
9561 | (lo32.X_add_number >> shift));
9562 else
9563 tmp.X_add_number = hi32.X_add_number >> (shift - 32);
9564 macro_build (&tmp, "ori", "t,r,i", reg, 0, BFD_RELOC_LO16);
9565 macro_build (NULL, (shift >= 32) ? "dsll32" : "dsll", SHFT_FMT,
9566 reg, reg, (shift >= 32) ? shift - 32 : shift);
9567 return;
9569 ++shift;
9571 while (shift <= (64 - 16));
9573 /* Find the bit number of the lowest one bit, and store the
9574 shifted value in hi/lo. */
9575 hi = (unsigned long) (hi32.X_add_number & 0xffffffff);
9576 lo = (unsigned long) (lo32.X_add_number & 0xffffffff);
9577 if (lo != 0)
9579 bit = 0;
9580 while ((lo & 1) == 0)
9582 lo >>= 1;
9583 ++bit;
9585 lo |= (hi & (((unsigned long) 1 << bit) - 1)) << (32 - bit);
9586 hi >>= bit;
9588 else
9590 bit = 32;
9591 while ((hi & 1) == 0)
9593 hi >>= 1;
9594 ++bit;
9596 lo = hi;
9597 hi = 0;
9600 /* Optimize if the shifted value is a (power of 2) - 1. */
9601 if ((hi == 0 && ((lo + 1) & lo) == 0)
9602 || (lo == 0xffffffff && ((hi + 1) & hi) == 0))
9604 shift = COUNT_TOP_ZEROES ((unsigned int) hi32.X_add_number);
9605 if (shift != 0)
9607 expressionS tmp;
9609 /* This instruction will set the register to be all
9610 ones. */
9611 tmp.X_op = O_constant;
9612 tmp.X_add_number = (offsetT) -1;
9613 macro_build (&tmp, "addiu", "t,r,j", reg, 0, BFD_RELOC_LO16);
9614 if (bit != 0)
9616 bit += shift;
9617 macro_build (NULL, (bit >= 32) ? "dsll32" : "dsll", SHFT_FMT,
9618 reg, reg, (bit >= 32) ? bit - 32 : bit);
9620 macro_build (NULL, (shift >= 32) ? "dsrl32" : "dsrl", SHFT_FMT,
9621 reg, reg, (shift >= 32) ? shift - 32 : shift);
9622 return;
9626 /* Sign extend hi32 before calling load_register, because we can
9627 generally get better code when we load a sign extended value. */
9628 if ((hi32.X_add_number & 0x80000000) != 0)
9629 hi32.X_add_number |= ~(offsetT) 0xffffffff;
9630 load_register (reg, &hi32, 0);
9631 freg = reg;
9633 if ((lo32.X_add_number & 0xffff0000) == 0)
9635 if (freg != 0)
9637 macro_build (NULL, "dsll32", SHFT_FMT, reg, freg, 0);
9638 freg = reg;
9641 else
9643 expressionS mid16;
9645 if ((freg == 0) && (lo32.X_add_number == (offsetT) 0xffffffff))
9647 macro_build (&lo32, "lui", LUI_FMT, reg, BFD_RELOC_HI16);
9648 macro_build (NULL, "dsrl32", SHFT_FMT, reg, reg, 0);
9649 return;
9652 if (freg != 0)
9654 macro_build (NULL, "dsll", SHFT_FMT, reg, freg, 16);
9655 freg = reg;
9657 mid16 = lo32;
9658 mid16.X_add_number >>= 16;
9659 macro_build (&mid16, "ori", "t,r,i", reg, freg, BFD_RELOC_LO16);
9660 macro_build (NULL, "dsll", SHFT_FMT, reg, reg, 16);
9661 freg = reg;
9663 if ((lo32.X_add_number & 0xffff) != 0)
9664 macro_build (&lo32, "ori", "t,r,i", reg, freg, BFD_RELOC_LO16);
9667 static inline void
9668 load_delay_nop (void)
9670 if (!gpr_interlocks)
9671 macro_build (NULL, "nop", "");
9674 /* Load an address into a register. */
9676 static void
9677 load_address (int reg, expressionS *ep, int *used_at)
9679 if (ep->X_op != O_constant
9680 && ep->X_op != O_symbol)
9682 as_bad (_("expression too complex"));
9683 ep->X_op = O_constant;
9686 if (ep->X_op == O_constant)
9688 load_register (reg, ep, HAVE_64BIT_ADDRESSES);
9689 return;
9692 if (mips_pic == NO_PIC)
9694 /* If this is a reference to a GP relative symbol, we want
9695 addiu $reg,$gp,<sym> (BFD_RELOC_GPREL16)
9696 Otherwise we want
9697 lui $reg,<sym> (BFD_RELOC_HI16_S)
9698 addiu $reg,$reg,<sym> (BFD_RELOC_LO16)
9699 If we have an addend, we always use the latter form.
9701 With 64bit address space and a usable $at we want
9702 lui $reg,<sym> (BFD_RELOC_MIPS_HIGHEST)
9703 lui $at,<sym> (BFD_RELOC_HI16_S)
9704 daddiu $reg,<sym> (BFD_RELOC_MIPS_HIGHER)
9705 daddiu $at,<sym> (BFD_RELOC_LO16)
9706 dsll32 $reg,0
9707 daddu $reg,$reg,$at
9709 If $at is already in use, we use a path which is suboptimal
9710 on superscalar processors.
9711 lui $reg,<sym> (BFD_RELOC_MIPS_HIGHEST)
9712 daddiu $reg,<sym> (BFD_RELOC_MIPS_HIGHER)
9713 dsll $reg,16
9714 daddiu $reg,<sym> (BFD_RELOC_HI16_S)
9715 dsll $reg,16
9716 daddiu $reg,<sym> (BFD_RELOC_LO16)
9718 For GP relative symbols in 64bit address space we can use
9719 the same sequence as in 32bit address space. */
9720 if (HAVE_64BIT_SYMBOLS)
9722 if ((valueT) ep->X_add_number <= MAX_GPREL_OFFSET
9723 && !nopic_need_relax (ep->X_add_symbol, 1))
9725 relax_start (ep->X_add_symbol);
9726 macro_build (ep, ADDRESS_ADDI_INSN, "t,r,j", reg,
9727 mips_gp_register, BFD_RELOC_GPREL16);
9728 relax_switch ();
9731 if (*used_at == 0 && mips_opts.at)
9733 macro_build (ep, "lui", LUI_FMT, reg, BFD_RELOC_MIPS_HIGHEST);
9734 macro_build (ep, "lui", LUI_FMT, AT, BFD_RELOC_HI16_S);
9735 macro_build (ep, "daddiu", "t,r,j", reg, reg,
9736 BFD_RELOC_MIPS_HIGHER);
9737 macro_build (ep, "daddiu", "t,r,j", AT, AT, BFD_RELOC_LO16);
9738 macro_build (NULL, "dsll32", SHFT_FMT, reg, reg, 0);
9739 macro_build (NULL, "daddu", "d,v,t", reg, reg, AT);
9740 *used_at = 1;
9742 else
9744 macro_build (ep, "lui", LUI_FMT, reg, BFD_RELOC_MIPS_HIGHEST);
9745 macro_build (ep, "daddiu", "t,r,j", reg, reg,
9746 BFD_RELOC_MIPS_HIGHER);
9747 macro_build (NULL, "dsll", SHFT_FMT, reg, reg, 16);
9748 macro_build (ep, "daddiu", "t,r,j", reg, reg, BFD_RELOC_HI16_S);
9749 macro_build (NULL, "dsll", SHFT_FMT, reg, reg, 16);
9750 macro_build (ep, "daddiu", "t,r,j", reg, reg, BFD_RELOC_LO16);
9753 if (mips_relax.sequence)
9754 relax_end ();
9756 else
9758 if ((valueT) ep->X_add_number <= MAX_GPREL_OFFSET
9759 && !nopic_need_relax (ep->X_add_symbol, 1))
9761 relax_start (ep->X_add_symbol);
9762 macro_build (ep, ADDRESS_ADDI_INSN, "t,r,j", reg,
9763 mips_gp_register, BFD_RELOC_GPREL16);
9764 relax_switch ();
9766 macro_build_lui (ep, reg);
9767 macro_build (ep, ADDRESS_ADDI_INSN, "t,r,j",
9768 reg, reg, BFD_RELOC_LO16);
9769 if (mips_relax.sequence)
9770 relax_end ();
9773 else if (!mips_big_got)
9775 expressionS ex;
9777 /* If this is a reference to an external symbol, we want
9778 lw $reg,<sym>($gp) (BFD_RELOC_MIPS_GOT16)
9779 Otherwise we want
9780 lw $reg,<sym>($gp) (BFD_RELOC_MIPS_GOT16)
9782 addiu $reg,$reg,<sym> (BFD_RELOC_LO16)
9783 If there is a constant, it must be added in after.
9785 If we have NewABI, we want
9786 lw $reg,<sym+cst>($gp) (BFD_RELOC_MIPS_GOT_DISP)
9787 unless we're referencing a global symbol with a non-zero
9788 offset, in which case cst must be added separately. */
9789 if (HAVE_NEWABI)
9791 if (ep->X_add_number)
9793 ex.X_add_number = ep->X_add_number;
9794 ep->X_add_number = 0;
9795 relax_start (ep->X_add_symbol);
9796 macro_build (ep, ADDRESS_LOAD_INSN, "t,o(b)", reg,
9797 BFD_RELOC_MIPS_GOT_DISP, mips_gp_register);
9798 if (ex.X_add_number < -0x8000 || ex.X_add_number >= 0x8000)
9799 as_bad (_("PIC code offset overflow (max 16 signed bits)"));
9800 ex.X_op = O_constant;
9801 macro_build (&ex, ADDRESS_ADDI_INSN, "t,r,j",
9802 reg, reg, BFD_RELOC_LO16);
9803 ep->X_add_number = ex.X_add_number;
9804 relax_switch ();
9806 macro_build (ep, ADDRESS_LOAD_INSN, "t,o(b)", reg,
9807 BFD_RELOC_MIPS_GOT_DISP, mips_gp_register);
9808 if (mips_relax.sequence)
9809 relax_end ();
9811 else
9813 ex.X_add_number = ep->X_add_number;
9814 ep->X_add_number = 0;
9815 macro_build (ep, ADDRESS_LOAD_INSN, "t,o(b)", reg,
9816 BFD_RELOC_MIPS_GOT16, mips_gp_register);
9817 load_delay_nop ();
9818 relax_start (ep->X_add_symbol);
9819 relax_switch ();
9820 macro_build (ep, ADDRESS_ADDI_INSN, "t,r,j", reg, reg,
9821 BFD_RELOC_LO16);
9822 relax_end ();
9824 if (ex.X_add_number != 0)
9826 if (ex.X_add_number < -0x8000 || ex.X_add_number >= 0x8000)
9827 as_bad (_("PIC code offset overflow (max 16 signed bits)"));
9828 ex.X_op = O_constant;
9829 macro_build (&ex, ADDRESS_ADDI_INSN, "t,r,j",
9830 reg, reg, BFD_RELOC_LO16);
9834 else if (mips_big_got)
9836 expressionS ex;
9838 /* This is the large GOT case. If this is a reference to an
9839 external symbol, we want
9840 lui $reg,<sym> (BFD_RELOC_MIPS_GOT_HI16)
9841 addu $reg,$reg,$gp
9842 lw $reg,<sym>($reg) (BFD_RELOC_MIPS_GOT_LO16)
9844 Otherwise, for a reference to a local symbol in old ABI, we want
9845 lw $reg,<sym>($gp) (BFD_RELOC_MIPS_GOT16)
9847 addiu $reg,$reg,<sym> (BFD_RELOC_LO16)
9848 If there is a constant, it must be added in after.
9850 In the NewABI, for local symbols, with or without offsets, we want:
9851 lw $reg,<sym>($gp) (BFD_RELOC_MIPS_GOT_PAGE)
9852 addiu $reg,$reg,<sym> (BFD_RELOC_MIPS_GOT_OFST)
9854 if (HAVE_NEWABI)
9856 ex.X_add_number = ep->X_add_number;
9857 ep->X_add_number = 0;
9858 relax_start (ep->X_add_symbol);
9859 macro_build (ep, "lui", LUI_FMT, reg, BFD_RELOC_MIPS_GOT_HI16);
9860 macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t",
9861 reg, reg, mips_gp_register);
9862 macro_build (ep, ADDRESS_LOAD_INSN, "t,o(b)",
9863 reg, BFD_RELOC_MIPS_GOT_LO16, reg);
9864 if (ex.X_add_number < -0x8000 || ex.X_add_number >= 0x8000)
9865 as_bad (_("PIC code offset overflow (max 16 signed bits)"));
9866 else if (ex.X_add_number)
9868 ex.X_op = O_constant;
9869 macro_build (&ex, ADDRESS_ADDI_INSN, "t,r,j", reg, reg,
9870 BFD_RELOC_LO16);
9873 ep->X_add_number = ex.X_add_number;
9874 relax_switch ();
9875 macro_build (ep, ADDRESS_LOAD_INSN, "t,o(b)", reg,
9876 BFD_RELOC_MIPS_GOT_PAGE, mips_gp_register);
9877 macro_build (ep, ADDRESS_ADDI_INSN, "t,r,j", reg, reg,
9878 BFD_RELOC_MIPS_GOT_OFST);
9879 relax_end ();
9881 else
9883 ex.X_add_number = ep->X_add_number;
9884 ep->X_add_number = 0;
9885 relax_start (ep->X_add_symbol);
9886 macro_build (ep, "lui", LUI_FMT, reg, BFD_RELOC_MIPS_GOT_HI16);
9887 macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t",
9888 reg, reg, mips_gp_register);
9889 macro_build (ep, ADDRESS_LOAD_INSN, "t,o(b)",
9890 reg, BFD_RELOC_MIPS_GOT_LO16, reg);
9891 relax_switch ();
9892 if (reg_needs_delay (mips_gp_register))
9894 /* We need a nop before loading from $gp. This special
9895 check is required because the lui which starts the main
9896 instruction stream does not refer to $gp, and so will not
9897 insert the nop which may be required. */
9898 macro_build (NULL, "nop", "");
9900 macro_build (ep, ADDRESS_LOAD_INSN, "t,o(b)", reg,
9901 BFD_RELOC_MIPS_GOT16, mips_gp_register);
9902 load_delay_nop ();
9903 macro_build (ep, ADDRESS_ADDI_INSN, "t,r,j", reg, reg,
9904 BFD_RELOC_LO16);
9905 relax_end ();
9907 if (ex.X_add_number != 0)
9909 if (ex.X_add_number < -0x8000 || ex.X_add_number >= 0x8000)
9910 as_bad (_("PIC code offset overflow (max 16 signed bits)"));
9911 ex.X_op = O_constant;
9912 macro_build (&ex, ADDRESS_ADDI_INSN, "t,r,j", reg, reg,
9913 BFD_RELOC_LO16);
9917 else
9918 abort ();
9920 if (!mips_opts.at && *used_at == 1)
9921 as_bad (_("macro used $at after \".set noat\""));
9924 /* Move the contents of register SOURCE into register DEST. */
9926 static void
9927 move_register (int dest, int source)
9929 /* Prefer to use a 16-bit microMIPS instruction unless the previous
9930 instruction specifically requires a 32-bit one. */
9931 if (mips_opts.micromips
9932 && !mips_opts.insn32
9933 && !(history[0].insn_mo->pinfo2 & INSN2_BRANCH_DELAY_32BIT))
9934 macro_build (NULL, "move", "mp,mj", dest, source);
9935 else
9936 macro_build (NULL, "or", "d,v,t", dest, source, 0);
9939 /* Emit an SVR4 PIC sequence to load address LOCAL into DEST, where
9940 LOCAL is the sum of a symbol and a 16-bit or 32-bit displacement.
9941 The two alternatives are:
9943 Global symbol Local symbol
9944 ------------- ------------
9945 lw DEST,%got(SYMBOL) lw DEST,%got(SYMBOL + OFFSET)
9946 ... ...
9947 addiu DEST,DEST,OFFSET addiu DEST,DEST,%lo(SYMBOL + OFFSET)
9949 load_got_offset emits the first instruction and add_got_offset
9950 emits the second for a 16-bit offset or add_got_offset_hilo emits
9951 a sequence to add a 32-bit offset using a scratch register. */
9953 static void
9954 load_got_offset (int dest, expressionS *local)
9956 expressionS global;
9958 global = *local;
9959 global.X_add_number = 0;
9961 relax_start (local->X_add_symbol);
9962 macro_build (&global, ADDRESS_LOAD_INSN, "t,o(b)", dest,
9963 BFD_RELOC_MIPS_GOT16, mips_gp_register);
9964 relax_switch ();
9965 macro_build (local, ADDRESS_LOAD_INSN, "t,o(b)", dest,
9966 BFD_RELOC_MIPS_GOT16, mips_gp_register);
9967 relax_end ();
9970 static void
9971 add_got_offset (int dest, expressionS *local)
9973 expressionS global;
9975 global.X_op = O_constant;
9976 global.X_op_symbol = NULL;
9977 global.X_add_symbol = NULL;
9978 global.X_add_number = local->X_add_number;
9980 relax_start (local->X_add_symbol);
9981 macro_build (&global, ADDRESS_ADDI_INSN, "t,r,j",
9982 dest, dest, BFD_RELOC_LO16);
9983 relax_switch ();
9984 macro_build (local, ADDRESS_ADDI_INSN, "t,r,j", dest, dest, BFD_RELOC_LO16);
9985 relax_end ();
9988 static void
9989 add_got_offset_hilo (int dest, expressionS *local, int tmp)
9991 expressionS global;
9992 int hold_mips_optimize;
9994 global.X_op = O_constant;
9995 global.X_op_symbol = NULL;
9996 global.X_add_symbol = NULL;
9997 global.X_add_number = local->X_add_number;
9999 relax_start (local->X_add_symbol);
10000 load_register (tmp, &global, HAVE_64BIT_ADDRESSES);
10001 relax_switch ();
10002 /* Set mips_optimize around the lui instruction to avoid
10003 inserting an unnecessary nop after the lw. */
10004 hold_mips_optimize = mips_optimize;
10005 mips_optimize = 2;
10006 macro_build_lui (&global, tmp);
10007 mips_optimize = hold_mips_optimize;
10008 macro_build (local, ADDRESS_ADDI_INSN, "t,r,j", tmp, tmp, BFD_RELOC_LO16);
10009 relax_end ();
10011 macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t", dest, dest, tmp);
10014 /* Emit a sequence of instructions to emulate a branch likely operation.
10015 BR is an ordinary branch corresponding to one to be emulated. BRNEG
10016 is its complementing branch with the original condition negated.
10017 CALL is set if the original branch specified the link operation.
10018 EP, FMT, SREG and TREG specify the usual macro_build() parameters.
10020 Code like this is produced in the noreorder mode:
10022 BRNEG <args>, 1f
10024 b <sym>
10025 delay slot (executed only if branch taken)
10028 or, if CALL is set:
10030 BRNEG <args>, 1f
10032 bal <sym>
10033 delay slot (executed only if branch taken)
10036 In the reorder mode the delay slot would be filled with a nop anyway,
10037 so code produced is simply:
10039 BR <args>, <sym>
10042 This function is used when producing code for the microMIPS ASE that
10043 does not implement branch likely instructions in hardware. */
10045 static void
10046 macro_build_branch_likely (const char *br, const char *brneg,
10047 int call, expressionS *ep, const char *fmt,
10048 unsigned int sreg, unsigned int treg)
10050 int noreorder = mips_opts.noreorder;
10051 expressionS expr1;
10053 gas_assert (mips_opts.micromips);
10054 start_noreorder ();
10055 if (noreorder)
10057 micromips_label_expr (&expr1);
10058 macro_build (&expr1, brneg, fmt, sreg, treg);
10059 macro_build (NULL, "nop", "");
10060 macro_build (ep, call ? "bal" : "b", "p");
10062 /* Set to true so that append_insn adds a label. */
10063 emit_branch_likely_macro = TRUE;
10065 else
10067 macro_build (ep, br, fmt, sreg, treg);
10068 macro_build (NULL, "nop", "");
10070 end_noreorder ();
10073 /* Emit a coprocessor branch-likely macro specified by TYPE, using CC as
10074 the condition code tested. EP specifies the branch target. */
10076 static void
10077 macro_build_branch_ccl (int type, expressionS *ep, unsigned int cc)
10079 const int call = 0;
10080 const char *brneg;
10081 const char *br;
10083 switch (type)
10085 case M_BC1FL:
10086 br = "bc1f";
10087 brneg = "bc1t";
10088 break;
10089 case M_BC1TL:
10090 br = "bc1t";
10091 brneg = "bc1f";
10092 break;
10093 case M_BC2FL:
10094 br = "bc2f";
10095 brneg = "bc2t";
10096 break;
10097 case M_BC2TL:
10098 br = "bc2t";
10099 brneg = "bc2f";
10100 break;
10101 default:
10102 abort ();
10104 macro_build_branch_likely (br, brneg, call, ep, "N,p", cc, ZERO);
10107 /* Emit a two-argument branch macro specified by TYPE, using SREG as
10108 the register tested. EP specifies the branch target. */
10110 static void
10111 macro_build_branch_rs (int type, expressionS *ep, unsigned int sreg)
10113 const char *brneg = NULL;
10114 const char *br;
10115 int call = 0;
10117 switch (type)
10119 case M_BGEZ:
10120 br = "bgez";
10121 break;
10122 case M_BGEZL:
10123 br = mips_opts.micromips ? "bgez" : "bgezl";
10124 brneg = "bltz";
10125 break;
10126 case M_BGEZALL:
10127 gas_assert (mips_opts.micromips);
10128 br = mips_opts.insn32 ? "bgezal" : "bgezals";
10129 brneg = "bltz";
10130 call = 1;
10131 break;
10132 case M_BGTZ:
10133 br = "bgtz";
10134 break;
10135 case M_BGTZL:
10136 br = mips_opts.micromips ? "bgtz" : "bgtzl";
10137 brneg = "blez";
10138 break;
10139 case M_BLEZ:
10140 br = "blez";
10141 break;
10142 case M_BLEZL:
10143 br = mips_opts.micromips ? "blez" : "blezl";
10144 brneg = "bgtz";
10145 break;
10146 case M_BLTZ:
10147 br = "bltz";
10148 break;
10149 case M_BLTZL:
10150 br = mips_opts.micromips ? "bltz" : "bltzl";
10151 brneg = "bgez";
10152 break;
10153 case M_BLTZALL:
10154 gas_assert (mips_opts.micromips);
10155 br = mips_opts.insn32 ? "bltzal" : "bltzals";
10156 brneg = "bgez";
10157 call = 1;
10158 break;
10159 default:
10160 abort ();
10162 if (mips_opts.micromips && brneg)
10163 macro_build_branch_likely (br, brneg, call, ep, "s,p", sreg, ZERO);
10164 else
10165 macro_build (ep, br, "s,p", sreg);
10168 /* Emit a three-argument branch macro specified by TYPE, using SREG and
10169 TREG as the registers tested. EP specifies the branch target. */
10171 static void
10172 macro_build_branch_rsrt (int type, expressionS *ep,
10173 unsigned int sreg, unsigned int treg)
10175 const char *brneg = NULL;
10176 const int call = 0;
10177 const char *br;
10179 switch (type)
10181 case M_BEQ:
10182 case M_BEQ_I:
10183 br = "beq";
10184 break;
10185 case M_BEQL:
10186 case M_BEQL_I:
10187 br = mips_opts.micromips ? "beq" : "beql";
10188 brneg = "bne";
10189 break;
10190 case M_BNE:
10191 case M_BNE_I:
10192 br = "bne";
10193 break;
10194 case M_BNEL:
10195 case M_BNEL_I:
10196 br = mips_opts.micromips ? "bne" : "bnel";
10197 brneg = "beq";
10198 break;
10199 default:
10200 abort ();
10202 if (mips_opts.micromips && brneg)
10203 macro_build_branch_likely (br, brneg, call, ep, "s,t,p", sreg, treg);
10204 else
10205 macro_build (ep, br, "s,t,p", sreg, treg);
10208 /* Return the high part that should be loaded in order to make the low
10209 part of VALUE accessible using an offset of OFFBITS bits. */
10211 static offsetT
10212 offset_high_part (offsetT value, unsigned int offbits)
10214 offsetT bias;
10215 addressT low_mask;
10217 if (offbits == 0)
10218 return value;
10219 bias = 1 << (offbits - 1);
10220 low_mask = bias * 2 - 1;
10221 return (value + bias) & ~low_mask;
10224 /* Return true if the value stored in offset_expr and offset_reloc
10225 fits into a signed offset of OFFBITS bits. RANGE is the maximum
10226 amount that the caller wants to add without inducing overflow
10227 and ALIGN is the known alignment of the value in bytes. */
10229 static bfd_boolean
10230 small_offset_p (unsigned int range, unsigned int align, unsigned int offbits)
10232 if (offbits == 16)
10234 /* Accept any relocation operator if overflow isn't a concern. */
10235 if (range < align && *offset_reloc != BFD_RELOC_UNUSED)
10236 return TRUE;
10238 /* These relocations are guaranteed not to overflow in correct links. */
10239 if (*offset_reloc == BFD_RELOC_MIPS_LITERAL
10240 || gprel16_reloc_p (*offset_reloc))
10241 return TRUE;
10243 if (offset_expr.X_op == O_constant
10244 && offset_high_part (offset_expr.X_add_number, offbits) == 0
10245 && offset_high_part (offset_expr.X_add_number + range, offbits) == 0)
10246 return TRUE;
10247 return FALSE;
10251 * Build macros
10252 * This routine implements the seemingly endless macro or synthesized
10253 * instructions and addressing modes in the mips assembly language. Many
10254 * of these macros are simple and are similar to each other. These could
10255 * probably be handled by some kind of table or grammar approach instead of
10256 * this verbose method. Others are not simple macros but are more like
10257 * optimizing code generation.
10258 * One interesting optimization is when several store macros appear
10259 * consecutively that would load AT with the upper half of the same address.
10260 * The ensuing load upper instructions are omitted. This implies some kind
10261 * of global optimization. We currently only optimize within a single macro.
10262 * For many of the load and store macros if the address is specified as a
10263 * constant expression in the first 64k of memory (ie ld $2,0x4000c) we
10264 * first load register 'at' with zero and use it as the base register. The
10265 * mips assembler simply uses register $zero. Just one tiny optimization
10266 * we're missing.
10268 static void
10269 macro (struct mips_cl_insn *ip, char *str)
10271 const struct mips_operand_array *operands;
10272 unsigned int breg, i;
10273 unsigned int tempreg;
10274 int mask;
10275 int used_at = 0;
10276 expressionS label_expr;
10277 expressionS expr1;
10278 expressionS *ep;
10279 const char *s;
10280 const char *s2;
10281 const char *fmt;
10282 int likely = 0;
10283 int coproc = 0;
10284 int offbits = 16;
10285 int call = 0;
10286 int jals = 0;
10287 int dbl = 0;
10288 int imm = 0;
10289 int ust = 0;
10290 int lp = 0;
10291 int ll_sc_paired = 0;
10292 bfd_boolean large_offset;
10293 int off;
10294 int hold_mips_optimize;
10295 unsigned int align;
10296 unsigned int op[MAX_OPERANDS];
10298 gas_assert (! mips_opts.mips16);
10300 operands = insn_operands (ip);
10301 for (i = 0; i < MAX_OPERANDS; i++)
10302 if (operands->operand[i])
10303 op[i] = insn_extract_operand (ip, operands->operand[i]);
10304 else
10305 op[i] = -1;
10307 mask = ip->insn_mo->mask;
10309 label_expr.X_op = O_constant;
10310 label_expr.X_op_symbol = NULL;
10311 label_expr.X_add_symbol = NULL;
10312 label_expr.X_add_number = 0;
10314 expr1.X_op = O_constant;
10315 expr1.X_op_symbol = NULL;
10316 expr1.X_add_symbol = NULL;
10317 expr1.X_add_number = 1;
10318 align = 1;
10320 switch (mask)
10322 case M_DABS:
10323 dbl = 1;
10324 /* Fall through. */
10325 case M_ABS:
10326 /* bgez $a0,1f
10327 move v0,$a0
10328 sub v0,$zero,$a0
10332 start_noreorder ();
10334 if (mips_opts.micromips)
10335 micromips_label_expr (&label_expr);
10336 else
10337 label_expr.X_add_number = 8;
10338 macro_build (&label_expr, "bgez", "s,p", op[1]);
10339 if (op[0] == op[1])
10340 macro_build (NULL, "nop", "");
10341 else
10342 move_register (op[0], op[1]);
10343 macro_build (NULL, dbl ? "dsub" : "sub", "d,v,t", op[0], 0, op[1]);
10344 if (mips_opts.micromips)
10345 micromips_add_label ();
10347 end_noreorder ();
10348 break;
10350 case M_ADD_I:
10351 s = "addi";
10352 s2 = "add";
10353 if (ISA_IS_R6 (mips_opts.isa))
10354 goto do_addi_i;
10355 else
10356 goto do_addi;
10357 case M_ADDU_I:
10358 s = "addiu";
10359 s2 = "addu";
10360 goto do_addi;
10361 case M_DADD_I:
10362 dbl = 1;
10363 s = "daddi";
10364 s2 = "dadd";
10365 if (!mips_opts.micromips && !ISA_IS_R6 (mips_opts.isa))
10366 goto do_addi;
10367 if (imm_expr.X_add_number >= -0x200
10368 && imm_expr.X_add_number < 0x200
10369 && !ISA_IS_R6 (mips_opts.isa))
10371 macro_build (NULL, s, "t,r,.", op[0], op[1],
10372 (int) imm_expr.X_add_number);
10373 break;
10375 goto do_addi_i;
10376 case M_DADDU_I:
10377 dbl = 1;
10378 s = "daddiu";
10379 s2 = "daddu";
10380 do_addi:
10381 if (imm_expr.X_add_number >= -0x8000
10382 && imm_expr.X_add_number < 0x8000)
10384 macro_build (&imm_expr, s, "t,r,j", op[0], op[1], BFD_RELOC_LO16);
10385 break;
10387 do_addi_i:
10388 used_at = 1;
10389 load_register (AT, &imm_expr, dbl);
10390 macro_build (NULL, s2, "d,v,t", op[0], op[1], AT);
10391 break;
10393 case M_AND_I:
10394 s = "andi";
10395 s2 = "and";
10396 goto do_bit;
10397 case M_OR_I:
10398 s = "ori";
10399 s2 = "or";
10400 goto do_bit;
10401 case M_NOR_I:
10402 s = "";
10403 s2 = "nor";
10404 goto do_bit;
10405 case M_XOR_I:
10406 s = "xori";
10407 s2 = "xor";
10408 do_bit:
10409 if (imm_expr.X_add_number >= 0
10410 && imm_expr.X_add_number < 0x10000)
10412 if (mask != M_NOR_I)
10413 macro_build (&imm_expr, s, "t,r,i", op[0], op[1], BFD_RELOC_LO16);
10414 else
10416 macro_build (&imm_expr, "ori", "t,r,i",
10417 op[0], op[1], BFD_RELOC_LO16);
10418 macro_build (NULL, "nor", "d,v,t", op[0], op[0], 0);
10420 break;
10423 used_at = 1;
10424 load_register (AT, &imm_expr, GPR_SIZE == 64);
10425 macro_build (NULL, s2, "d,v,t", op[0], op[1], AT);
10426 break;
10428 case M_BALIGN:
10429 switch (imm_expr.X_add_number)
10431 case 0:
10432 macro_build (NULL, "nop", "");
10433 break;
10434 case 2:
10435 macro_build (NULL, "packrl.ph", "d,s,t", op[0], op[0], op[1]);
10436 break;
10437 case 1:
10438 case 3:
10439 macro_build (NULL, "balign", "t,s,2", op[0], op[1],
10440 (int) imm_expr.X_add_number);
10441 break;
10442 default:
10443 as_bad (_("BALIGN immediate not 0, 1, 2 or 3 (%lu)"),
10444 (unsigned long) imm_expr.X_add_number);
10445 break;
10447 break;
10449 case M_BC1FL:
10450 case M_BC1TL:
10451 case M_BC2FL:
10452 case M_BC2TL:
10453 gas_assert (mips_opts.micromips);
10454 macro_build_branch_ccl (mask, &offset_expr,
10455 EXTRACT_OPERAND (1, BCC, *ip));
10456 break;
10458 case M_BEQ_I:
10459 case M_BEQL_I:
10460 case M_BNE_I:
10461 case M_BNEL_I:
10462 if (imm_expr.X_add_number == 0)
10463 op[1] = 0;
10464 else
10466 op[1] = AT;
10467 used_at = 1;
10468 load_register (op[1], &imm_expr, GPR_SIZE == 64);
10470 /* Fall through. */
10471 case M_BEQL:
10472 case M_BNEL:
10473 macro_build_branch_rsrt (mask, &offset_expr, op[0], op[1]);
10474 break;
10476 case M_BGEL:
10477 likely = 1;
10478 /* Fall through. */
10479 case M_BGE:
10480 if (op[1] == 0)
10481 macro_build_branch_rs (likely ? M_BGEZL : M_BGEZ, &offset_expr, op[0]);
10482 else if (op[0] == 0)
10483 macro_build_branch_rs (likely ? M_BLEZL : M_BLEZ, &offset_expr, op[1]);
10484 else
10486 used_at = 1;
10487 macro_build (NULL, "slt", "d,v,t", AT, op[0], op[1]);
10488 macro_build_branch_rsrt (likely ? M_BEQL : M_BEQ,
10489 &offset_expr, AT, ZERO);
10491 break;
10493 case M_BGEZL:
10494 case M_BGEZALL:
10495 case M_BGTZL:
10496 case M_BLEZL:
10497 case M_BLTZL:
10498 case M_BLTZALL:
10499 macro_build_branch_rs (mask, &offset_expr, op[0]);
10500 break;
10502 case M_BGTL_I:
10503 likely = 1;
10504 /* Fall through. */
10505 case M_BGT_I:
10506 /* Check for > max integer. */
10507 if (imm_expr.X_add_number >= GPR_SMAX)
10509 do_false:
10510 /* Result is always false. */
10511 if (! likely)
10512 macro_build (NULL, "nop", "");
10513 else
10514 macro_build_branch_rsrt (M_BNEL, &offset_expr, ZERO, ZERO);
10515 break;
10517 ++imm_expr.X_add_number;
10518 /* Fall through. */
10519 case M_BGE_I:
10520 case M_BGEL_I:
10521 if (mask == M_BGEL_I)
10522 likely = 1;
10523 if (imm_expr.X_add_number == 0)
10525 macro_build_branch_rs (likely ? M_BGEZL : M_BGEZ,
10526 &offset_expr, op[0]);
10527 break;
10529 if (imm_expr.X_add_number == 1)
10531 macro_build_branch_rs (likely ? M_BGTZL : M_BGTZ,
10532 &offset_expr, op[0]);
10533 break;
10535 if (imm_expr.X_add_number <= GPR_SMIN)
10537 do_true:
10538 /* Result is always true. */
10539 as_warn (_("branch %s is always true"), ip->insn_mo->name);
10540 macro_build (&offset_expr, "b", "p");
10541 break;
10543 used_at = 1;
10544 set_at (op[0], 0);
10545 macro_build_branch_rsrt (likely ? M_BEQL : M_BEQ,
10546 &offset_expr, AT, ZERO);
10547 break;
10549 case M_BGEUL:
10550 likely = 1;
10551 /* Fall through. */
10552 case M_BGEU:
10553 if (op[1] == 0)
10554 goto do_true;
10555 else if (op[0] == 0)
10556 macro_build_branch_rsrt (likely ? M_BEQL : M_BEQ,
10557 &offset_expr, ZERO, op[1]);
10558 else
10560 used_at = 1;
10561 macro_build (NULL, "sltu", "d,v,t", AT, op[0], op[1]);
10562 macro_build_branch_rsrt (likely ? M_BEQL : M_BEQ,
10563 &offset_expr, AT, ZERO);
10565 break;
10567 case M_BGTUL_I:
10568 likely = 1;
10569 /* Fall through. */
10570 case M_BGTU_I:
10571 if (op[0] == 0
10572 || (GPR_SIZE == 32
10573 && imm_expr.X_add_number == -1))
10574 goto do_false;
10575 ++imm_expr.X_add_number;
10576 /* Fall through. */
10577 case M_BGEU_I:
10578 case M_BGEUL_I:
10579 if (mask == M_BGEUL_I)
10580 likely = 1;
10581 if (imm_expr.X_add_number == 0)
10582 goto do_true;
10583 else if (imm_expr.X_add_number == 1)
10584 macro_build_branch_rsrt (likely ? M_BNEL : M_BNE,
10585 &offset_expr, op[0], ZERO);
10586 else
10588 used_at = 1;
10589 set_at (op[0], 1);
10590 macro_build_branch_rsrt (likely ? M_BEQL : M_BEQ,
10591 &offset_expr, AT, ZERO);
10593 break;
10595 case M_BGTL:
10596 likely = 1;
10597 /* Fall through. */
10598 case M_BGT:
10599 if (op[1] == 0)
10600 macro_build_branch_rs (likely ? M_BGTZL : M_BGTZ, &offset_expr, op[0]);
10601 else if (op[0] == 0)
10602 macro_build_branch_rs (likely ? M_BLTZL : M_BLTZ, &offset_expr, op[1]);
10603 else
10605 used_at = 1;
10606 macro_build (NULL, "slt", "d,v,t", AT, op[1], op[0]);
10607 macro_build_branch_rsrt (likely ? M_BNEL : M_BNE,
10608 &offset_expr, AT, ZERO);
10610 break;
10612 case M_BGTUL:
10613 likely = 1;
10614 /* Fall through. */
10615 case M_BGTU:
10616 if (op[1] == 0)
10617 macro_build_branch_rsrt (likely ? M_BNEL : M_BNE,
10618 &offset_expr, op[0], ZERO);
10619 else if (op[0] == 0)
10620 goto do_false;
10621 else
10623 used_at = 1;
10624 macro_build (NULL, "sltu", "d,v,t", AT, op[1], op[0]);
10625 macro_build_branch_rsrt (likely ? M_BNEL : M_BNE,
10626 &offset_expr, AT, ZERO);
10628 break;
10630 case M_BLEL:
10631 likely = 1;
10632 /* Fall through. */
10633 case M_BLE:
10634 if (op[1] == 0)
10635 macro_build_branch_rs (likely ? M_BLEZL : M_BLEZ, &offset_expr, op[0]);
10636 else if (op[0] == 0)
10637 macro_build_branch_rs (likely ? M_BGEZL : M_BGEZ, &offset_expr, op[1]);
10638 else
10640 used_at = 1;
10641 macro_build (NULL, "slt", "d,v,t", AT, op[1], op[0]);
10642 macro_build_branch_rsrt (likely ? M_BEQL : M_BEQ,
10643 &offset_expr, AT, ZERO);
10645 break;
10647 case M_BLEL_I:
10648 likely = 1;
10649 /* Fall through. */
10650 case M_BLE_I:
10651 if (imm_expr.X_add_number >= GPR_SMAX)
10652 goto do_true;
10653 ++imm_expr.X_add_number;
10654 /* Fall through. */
10655 case M_BLT_I:
10656 case M_BLTL_I:
10657 if (mask == M_BLTL_I)
10658 likely = 1;
10659 if (imm_expr.X_add_number == 0)
10660 macro_build_branch_rs (likely ? M_BLTZL : M_BLTZ, &offset_expr, op[0]);
10661 else if (imm_expr.X_add_number == 1)
10662 macro_build_branch_rs (likely ? M_BLEZL : M_BLEZ, &offset_expr, op[0]);
10663 else
10665 used_at = 1;
10666 set_at (op[0], 0);
10667 macro_build_branch_rsrt (likely ? M_BNEL : M_BNE,
10668 &offset_expr, AT, ZERO);
10670 break;
10672 case M_BLEUL:
10673 likely = 1;
10674 /* Fall through. */
10675 case M_BLEU:
10676 if (op[1] == 0)
10677 macro_build_branch_rsrt (likely ? M_BEQL : M_BEQ,
10678 &offset_expr, op[0], ZERO);
10679 else if (op[0] == 0)
10680 goto do_true;
10681 else
10683 used_at = 1;
10684 macro_build (NULL, "sltu", "d,v,t", AT, op[1], op[0]);
10685 macro_build_branch_rsrt (likely ? M_BEQL : M_BEQ,
10686 &offset_expr, AT, ZERO);
10688 break;
10690 case M_BLEUL_I:
10691 likely = 1;
10692 /* Fall through. */
10693 case M_BLEU_I:
10694 if (op[0] == 0
10695 || (GPR_SIZE == 32
10696 && imm_expr.X_add_number == -1))
10697 goto do_true;
10698 ++imm_expr.X_add_number;
10699 /* Fall through. */
10700 case M_BLTU_I:
10701 case M_BLTUL_I:
10702 if (mask == M_BLTUL_I)
10703 likely = 1;
10704 if (imm_expr.X_add_number == 0)
10705 goto do_false;
10706 else if (imm_expr.X_add_number == 1)
10707 macro_build_branch_rsrt (likely ? M_BEQL : M_BEQ,
10708 &offset_expr, op[0], ZERO);
10709 else
10711 used_at = 1;
10712 set_at (op[0], 1);
10713 macro_build_branch_rsrt (likely ? M_BNEL : M_BNE,
10714 &offset_expr, AT, ZERO);
10716 break;
10718 case M_BLTL:
10719 likely = 1;
10720 /* Fall through. */
10721 case M_BLT:
10722 if (op[1] == 0)
10723 macro_build_branch_rs (likely ? M_BLTZL : M_BLTZ, &offset_expr, op[0]);
10724 else if (op[0] == 0)
10725 macro_build_branch_rs (likely ? M_BGTZL : M_BGTZ, &offset_expr, op[1]);
10726 else
10728 used_at = 1;
10729 macro_build (NULL, "slt", "d,v,t", AT, op[0], op[1]);
10730 macro_build_branch_rsrt (likely ? M_BNEL : M_BNE,
10731 &offset_expr, AT, ZERO);
10733 break;
10735 case M_BLTUL:
10736 likely = 1;
10737 /* Fall through. */
10738 case M_BLTU:
10739 if (op[1] == 0)
10740 goto do_false;
10741 else if (op[0] == 0)
10742 macro_build_branch_rsrt (likely ? M_BNEL : M_BNE,
10743 &offset_expr, ZERO, op[1]);
10744 else
10746 used_at = 1;
10747 macro_build (NULL, "sltu", "d,v,t", AT, op[0], op[1]);
10748 macro_build_branch_rsrt (likely ? M_BNEL : M_BNE,
10749 &offset_expr, AT, ZERO);
10751 break;
10753 case M_DDIV_3:
10754 dbl = 1;
10755 /* Fall through. */
10756 case M_DIV_3:
10757 s = "mflo";
10758 goto do_div3;
10759 case M_DREM_3:
10760 dbl = 1;
10761 /* Fall through. */
10762 case M_REM_3:
10763 s = "mfhi";
10764 do_div3:
10765 if (op[2] == 0)
10767 as_warn (_("divide by zero"));
10768 if (mips_trap)
10769 macro_build (NULL, "teq", TRAP_FMT, ZERO, ZERO, 7);
10770 else
10771 macro_build (NULL, "break", BRK_FMT, 7);
10772 break;
10775 start_noreorder ();
10776 if (mips_trap)
10778 macro_build (NULL, "teq", TRAP_FMT, op[2], ZERO, 7);
10779 macro_build (NULL, dbl ? "ddiv" : "div", "z,s,t", op[1], op[2]);
10781 else
10783 if (mips_opts.micromips)
10784 micromips_label_expr (&label_expr);
10785 else
10786 label_expr.X_add_number = 8;
10787 macro_build (&label_expr, "bne", "s,t,p", op[2], ZERO);
10788 macro_build (NULL, dbl ? "ddiv" : "div", "z,s,t", op[1], op[2]);
10789 macro_build (NULL, "break", BRK_FMT, 7);
10790 if (mips_opts.micromips)
10791 micromips_add_label ();
10793 expr1.X_add_number = -1;
10794 used_at = 1;
10795 load_register (AT, &expr1, dbl);
10796 if (mips_opts.micromips)
10797 micromips_label_expr (&label_expr);
10798 else
10799 label_expr.X_add_number = mips_trap ? (dbl ? 12 : 8) : (dbl ? 20 : 16);
10800 macro_build (&label_expr, "bne", "s,t,p", op[2], AT);
10801 if (dbl)
10803 expr1.X_add_number = 1;
10804 load_register (AT, &expr1, dbl);
10805 macro_build (NULL, "dsll32", SHFT_FMT, AT, AT, 31);
10807 else
10809 expr1.X_add_number = 0x80000000;
10810 macro_build (&expr1, "lui", LUI_FMT, AT, BFD_RELOC_HI16);
10812 if (mips_trap)
10814 macro_build (NULL, "teq", TRAP_FMT, op[1], AT, 6);
10815 /* We want to close the noreorder block as soon as possible, so
10816 that later insns are available for delay slot filling. */
10817 end_noreorder ();
10819 else
10821 if (mips_opts.micromips)
10822 micromips_label_expr (&label_expr);
10823 else
10824 label_expr.X_add_number = 8;
10825 macro_build (&label_expr, "bne", "s,t,p", op[1], AT);
10826 macro_build (NULL, "nop", "");
10828 /* We want to close the noreorder block as soon as possible, so
10829 that later insns are available for delay slot filling. */
10830 end_noreorder ();
10832 macro_build (NULL, "break", BRK_FMT, 6);
10834 if (mips_opts.micromips)
10835 micromips_add_label ();
10836 macro_build (NULL, s, MFHL_FMT, op[0]);
10837 break;
10839 case M_DIV_3I:
10840 s = "div";
10841 s2 = "mflo";
10842 goto do_divi;
10843 case M_DIVU_3I:
10844 s = "divu";
10845 s2 = "mflo";
10846 goto do_divi;
10847 case M_REM_3I:
10848 s = "div";
10849 s2 = "mfhi";
10850 goto do_divi;
10851 case M_REMU_3I:
10852 s = "divu";
10853 s2 = "mfhi";
10854 goto do_divi;
10855 case M_DDIV_3I:
10856 dbl = 1;
10857 s = "ddiv";
10858 s2 = "mflo";
10859 goto do_divi;
10860 case M_DDIVU_3I:
10861 dbl = 1;
10862 s = "ddivu";
10863 s2 = "mflo";
10864 goto do_divi;
10865 case M_DREM_3I:
10866 dbl = 1;
10867 s = "ddiv";
10868 s2 = "mfhi";
10869 goto do_divi;
10870 case M_DREMU_3I:
10871 dbl = 1;
10872 s = "ddivu";
10873 s2 = "mfhi";
10874 do_divi:
10875 if (imm_expr.X_add_number == 0)
10877 as_warn (_("divide by zero"));
10878 if (mips_trap)
10879 macro_build (NULL, "teq", TRAP_FMT, ZERO, ZERO, 7);
10880 else
10881 macro_build (NULL, "break", BRK_FMT, 7);
10882 break;
10884 if (imm_expr.X_add_number == 1)
10886 if (strcmp (s2, "mflo") == 0)
10887 move_register (op[0], op[1]);
10888 else
10889 move_register (op[0], ZERO);
10890 break;
10892 if (imm_expr.X_add_number == -1 && s[strlen (s) - 1] != 'u')
10894 if (strcmp (s2, "mflo") == 0)
10895 macro_build (NULL, dbl ? "dneg" : "neg", "d,w", op[0], op[1]);
10896 else
10897 move_register (op[0], ZERO);
10898 break;
10901 used_at = 1;
10902 load_register (AT, &imm_expr, dbl);
10903 macro_build (NULL, s, "z,s,t", op[1], AT);
10904 macro_build (NULL, s2, MFHL_FMT, op[0]);
10905 break;
10907 case M_DIVU_3:
10908 s = "divu";
10909 s2 = "mflo";
10910 goto do_divu3;
10911 case M_REMU_3:
10912 s = "divu";
10913 s2 = "mfhi";
10914 goto do_divu3;
10915 case M_DDIVU_3:
10916 s = "ddivu";
10917 s2 = "mflo";
10918 goto do_divu3;
10919 case M_DREMU_3:
10920 s = "ddivu";
10921 s2 = "mfhi";
10922 do_divu3:
10923 start_noreorder ();
10924 if (mips_trap)
10926 macro_build (NULL, "teq", TRAP_FMT, op[2], ZERO, 7);
10927 macro_build (NULL, s, "z,s,t", op[1], op[2]);
10928 /* We want to close the noreorder block as soon as possible, so
10929 that later insns are available for delay slot filling. */
10930 end_noreorder ();
10932 else
10934 if (mips_opts.micromips)
10935 micromips_label_expr (&label_expr);
10936 else
10937 label_expr.X_add_number = 8;
10938 macro_build (&label_expr, "bne", "s,t,p", op[2], ZERO);
10939 macro_build (NULL, s, "z,s,t", op[1], op[2]);
10941 /* We want to close the noreorder block as soon as possible, so
10942 that later insns are available for delay slot filling. */
10943 end_noreorder ();
10944 macro_build (NULL, "break", BRK_FMT, 7);
10945 if (mips_opts.micromips)
10946 micromips_add_label ();
10948 macro_build (NULL, s2, MFHL_FMT, op[0]);
10949 break;
10951 case M_DLCA_AB:
10952 dbl = 1;
10953 /* Fall through. */
10954 case M_LCA_AB:
10955 call = 1;
10956 goto do_la;
10957 case M_DLA_AB:
10958 dbl = 1;
10959 /* Fall through. */
10960 case M_LA_AB:
10961 do_la:
10962 /* Load the address of a symbol into a register. If breg is not
10963 zero, we then add a base register to it. */
10965 breg = op[2];
10966 if (dbl && GPR_SIZE == 32)
10967 as_warn (_("dla used to load 32-bit register; recommend using la "
10968 "instead"));
10970 if (!dbl && HAVE_64BIT_OBJECTS)
10971 as_warn (_("la used to load 64-bit address; recommend using dla "
10972 "instead"));
10974 if (small_offset_p (0, align, 16))
10976 macro_build (&offset_expr, ADDRESS_ADDI_INSN, "t,r,j", op[0], breg,
10977 -1, offset_reloc[0], offset_reloc[1], offset_reloc[2]);
10978 break;
10981 if (mips_opts.at && (op[0] == breg))
10983 tempreg = AT;
10984 used_at = 1;
10986 else
10987 tempreg = op[0];
10989 if (offset_expr.X_op != O_symbol
10990 && offset_expr.X_op != O_constant)
10992 as_bad (_("expression too complex"));
10993 offset_expr.X_op = O_constant;
10996 if (offset_expr.X_op == O_constant)
10997 load_register (tempreg, &offset_expr, HAVE_64BIT_ADDRESSES);
10998 else if (mips_pic == NO_PIC)
11000 /* If this is a reference to a GP relative symbol, we want
11001 addiu $tempreg,$gp,<sym> (BFD_RELOC_GPREL16)
11002 Otherwise we want
11003 lui $tempreg,<sym> (BFD_RELOC_HI16_S)
11004 addiu $tempreg,$tempreg,<sym> (BFD_RELOC_LO16)
11005 If we have a constant, we need two instructions anyhow,
11006 so we may as well always use the latter form.
11008 With 64bit address space and a usable $at we want
11009 lui $tempreg,<sym> (BFD_RELOC_MIPS_HIGHEST)
11010 lui $at,<sym> (BFD_RELOC_HI16_S)
11011 daddiu $tempreg,<sym> (BFD_RELOC_MIPS_HIGHER)
11012 daddiu $at,<sym> (BFD_RELOC_LO16)
11013 dsll32 $tempreg,0
11014 daddu $tempreg,$tempreg,$at
11016 If $at is already in use, we use a path which is suboptimal
11017 on superscalar processors.
11018 lui $tempreg,<sym> (BFD_RELOC_MIPS_HIGHEST)
11019 daddiu $tempreg,<sym> (BFD_RELOC_MIPS_HIGHER)
11020 dsll $tempreg,16
11021 daddiu $tempreg,<sym> (BFD_RELOC_HI16_S)
11022 dsll $tempreg,16
11023 daddiu $tempreg,<sym> (BFD_RELOC_LO16)
11025 For GP relative symbols in 64bit address space we can use
11026 the same sequence as in 32bit address space. */
11027 if (HAVE_64BIT_SYMBOLS)
11029 if ((valueT) offset_expr.X_add_number <= MAX_GPREL_OFFSET
11030 && !nopic_need_relax (offset_expr.X_add_symbol, 1))
11032 relax_start (offset_expr.X_add_symbol);
11033 macro_build (&offset_expr, ADDRESS_ADDI_INSN, "t,r,j",
11034 tempreg, mips_gp_register, BFD_RELOC_GPREL16);
11035 relax_switch ();
11038 if (used_at == 0 && mips_opts.at)
11040 macro_build (&offset_expr, "lui", LUI_FMT,
11041 tempreg, BFD_RELOC_MIPS_HIGHEST);
11042 macro_build (&offset_expr, "lui", LUI_FMT,
11043 AT, BFD_RELOC_HI16_S);
11044 macro_build (&offset_expr, "daddiu", "t,r,j",
11045 tempreg, tempreg, BFD_RELOC_MIPS_HIGHER);
11046 macro_build (&offset_expr, "daddiu", "t,r,j",
11047 AT, AT, BFD_RELOC_LO16);
11048 macro_build (NULL, "dsll32", SHFT_FMT, tempreg, tempreg, 0);
11049 macro_build (NULL, "daddu", "d,v,t", tempreg, tempreg, AT);
11050 used_at = 1;
11052 else
11054 macro_build (&offset_expr, "lui", LUI_FMT,
11055 tempreg, BFD_RELOC_MIPS_HIGHEST);
11056 macro_build (&offset_expr, "daddiu", "t,r,j",
11057 tempreg, tempreg, BFD_RELOC_MIPS_HIGHER);
11058 macro_build (NULL, "dsll", SHFT_FMT, tempreg, tempreg, 16);
11059 macro_build (&offset_expr, "daddiu", "t,r,j",
11060 tempreg, tempreg, BFD_RELOC_HI16_S);
11061 macro_build (NULL, "dsll", SHFT_FMT, tempreg, tempreg, 16);
11062 macro_build (&offset_expr, "daddiu", "t,r,j",
11063 tempreg, tempreg, BFD_RELOC_LO16);
11066 if (mips_relax.sequence)
11067 relax_end ();
11069 else
11071 if ((valueT) offset_expr.X_add_number <= MAX_GPREL_OFFSET
11072 && !nopic_need_relax (offset_expr.X_add_symbol, 1))
11074 relax_start (offset_expr.X_add_symbol);
11075 macro_build (&offset_expr, ADDRESS_ADDI_INSN, "t,r,j",
11076 tempreg, mips_gp_register, BFD_RELOC_GPREL16);
11077 relax_switch ();
11079 if (!IS_SEXT_32BIT_NUM (offset_expr.X_add_number))
11080 as_bad (_("offset too large"));
11081 macro_build_lui (&offset_expr, tempreg);
11082 macro_build (&offset_expr, ADDRESS_ADDI_INSN, "t,r,j",
11083 tempreg, tempreg, BFD_RELOC_LO16);
11084 if (mips_relax.sequence)
11085 relax_end ();
11088 else if (!mips_big_got && !HAVE_NEWABI)
11090 int lw_reloc_type = (int) BFD_RELOC_MIPS_GOT16;
11092 /* If this is a reference to an external symbol, and there
11093 is no constant, we want
11094 lw $tempreg,<sym>($gp) (BFD_RELOC_MIPS_GOT16)
11095 or for lca or if tempreg is PIC_CALL_REG
11096 lw $tempreg,<sym>($gp) (BFD_RELOC_MIPS_CALL16)
11097 For a local symbol, we want
11098 lw $tempreg,<sym>($gp) (BFD_RELOC_MIPS_GOT16)
11100 addiu $tempreg,$tempreg,<sym> (BFD_RELOC_LO16)
11102 If we have a small constant, and this is a reference to
11103 an external symbol, we want
11104 lw $tempreg,<sym>($gp) (BFD_RELOC_MIPS_GOT16)
11106 addiu $tempreg,$tempreg,<constant>
11107 For a local symbol, we want the same instruction
11108 sequence, but we output a BFD_RELOC_LO16 reloc on the
11109 addiu instruction.
11111 If we have a large constant, and this is a reference to
11112 an external symbol, we want
11113 lw $tempreg,<sym>($gp) (BFD_RELOC_MIPS_GOT16)
11114 lui $at,<hiconstant>
11115 addiu $at,$at,<loconstant>
11116 addu $tempreg,$tempreg,$at
11117 For a local symbol, we want the same instruction
11118 sequence, but we output a BFD_RELOC_LO16 reloc on the
11119 addiu instruction.
11122 if (offset_expr.X_add_number == 0)
11124 if (mips_pic == SVR4_PIC
11125 && breg == 0
11126 && (call || tempreg == PIC_CALL_REG))
11127 lw_reloc_type = (int) BFD_RELOC_MIPS_CALL16;
11129 relax_start (offset_expr.X_add_symbol);
11130 macro_build (&offset_expr, ADDRESS_LOAD_INSN, "t,o(b)", tempreg,
11131 lw_reloc_type, mips_gp_register);
11132 if (breg != 0)
11134 /* We're going to put in an addu instruction using
11135 tempreg, so we may as well insert the nop right
11136 now. */
11137 load_delay_nop ();
11139 relax_switch ();
11140 macro_build (&offset_expr, ADDRESS_LOAD_INSN, "t,o(b)",
11141 tempreg, BFD_RELOC_MIPS_GOT16, mips_gp_register);
11142 load_delay_nop ();
11143 macro_build (&offset_expr, ADDRESS_ADDI_INSN, "t,r,j",
11144 tempreg, tempreg, BFD_RELOC_LO16);
11145 relax_end ();
11146 /* FIXME: If breg == 0, and the next instruction uses
11147 $tempreg, then if this variant case is used an extra
11148 nop will be generated. */
11150 else if (offset_expr.X_add_number >= -0x8000
11151 && offset_expr.X_add_number < 0x8000)
11153 load_got_offset (tempreg, &offset_expr);
11154 load_delay_nop ();
11155 add_got_offset (tempreg, &offset_expr);
11157 else
11159 expr1.X_add_number = offset_expr.X_add_number;
11160 offset_expr.X_add_number =
11161 SEXT_16BIT (offset_expr.X_add_number);
11162 load_got_offset (tempreg, &offset_expr);
11163 offset_expr.X_add_number = expr1.X_add_number;
11164 /* If we are going to add in a base register, and the
11165 target register and the base register are the same,
11166 then we are using AT as a temporary register. Since
11167 we want to load the constant into AT, we add our
11168 current AT (from the global offset table) and the
11169 register into the register now, and pretend we were
11170 not using a base register. */
11171 if (breg == op[0])
11173 load_delay_nop ();
11174 macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t",
11175 op[0], AT, breg);
11176 breg = 0;
11177 tempreg = op[0];
11179 add_got_offset_hilo (tempreg, &offset_expr, AT);
11180 used_at = 1;
11183 else if (!mips_big_got && HAVE_NEWABI)
11185 int add_breg_early = 0;
11187 /* If this is a reference to an external, and there is no
11188 constant, or local symbol (*), with or without a
11189 constant, we want
11190 lw $tempreg,<sym>($gp) (BFD_RELOC_MIPS_GOT_DISP)
11191 or for lca or if tempreg is PIC_CALL_REG
11192 lw $tempreg,<sym>($gp) (BFD_RELOC_MIPS_CALL16)
11194 If we have a small constant, and this is a reference to
11195 an external symbol, we want
11196 lw $tempreg,<sym>($gp) (BFD_RELOC_MIPS_GOT_DISP)
11197 addiu $tempreg,$tempreg,<constant>
11199 If we have a large constant, and this is a reference to
11200 an external symbol, we want
11201 lw $tempreg,<sym>($gp) (BFD_RELOC_MIPS_GOT_DISP)
11202 lui $at,<hiconstant>
11203 addiu $at,$at,<loconstant>
11204 addu $tempreg,$tempreg,$at
11206 (*) Other assemblers seem to prefer GOT_PAGE/GOT_OFST for
11207 local symbols, even though it introduces an additional
11208 instruction. */
11210 if (offset_expr.X_add_number)
11212 expr1.X_add_number = offset_expr.X_add_number;
11213 offset_expr.X_add_number = 0;
11215 relax_start (offset_expr.X_add_symbol);
11216 macro_build (&offset_expr, ADDRESS_LOAD_INSN, "t,o(b)", tempreg,
11217 BFD_RELOC_MIPS_GOT_DISP, mips_gp_register);
11219 if (expr1.X_add_number >= -0x8000
11220 && expr1.X_add_number < 0x8000)
11222 macro_build (&expr1, ADDRESS_ADDI_INSN, "t,r,j",
11223 tempreg, tempreg, BFD_RELOC_LO16);
11225 else if (IS_SEXT_32BIT_NUM (expr1.X_add_number + 0x8000))
11227 unsigned int dreg;
11229 /* If we are going to add in a base register, and the
11230 target register and the base register are the same,
11231 then we are using AT as a temporary register. Since
11232 we want to load the constant into AT, we add our
11233 current AT (from the global offset table) and the
11234 register into the register now, and pretend we were
11235 not using a base register. */
11236 if (breg != op[0])
11237 dreg = tempreg;
11238 else
11240 gas_assert (tempreg == AT);
11241 macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t",
11242 op[0], AT, breg);
11243 dreg = op[0];
11244 add_breg_early = 1;
11247 load_register (AT, &expr1, HAVE_64BIT_ADDRESSES);
11248 macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t",
11249 dreg, dreg, AT);
11251 used_at = 1;
11253 else
11254 as_bad (_("PIC code offset overflow (max 32 signed bits)"));
11256 relax_switch ();
11257 offset_expr.X_add_number = expr1.X_add_number;
11259 macro_build (&offset_expr, ADDRESS_LOAD_INSN, "t,o(b)", tempreg,
11260 BFD_RELOC_MIPS_GOT_DISP, mips_gp_register);
11261 if (add_breg_early)
11263 macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t",
11264 op[0], tempreg, breg);
11265 breg = 0;
11266 tempreg = op[0];
11268 relax_end ();
11270 else if (breg == 0 && (call || tempreg == PIC_CALL_REG))
11272 relax_start (offset_expr.X_add_symbol);
11273 macro_build (&offset_expr, ADDRESS_LOAD_INSN, "t,o(b)", tempreg,
11274 BFD_RELOC_MIPS_CALL16, mips_gp_register);
11275 relax_switch ();
11276 macro_build (&offset_expr, ADDRESS_LOAD_INSN, "t,o(b)", tempreg,
11277 BFD_RELOC_MIPS_GOT_DISP, mips_gp_register);
11278 relax_end ();
11280 else
11282 macro_build (&offset_expr, ADDRESS_LOAD_INSN, "t,o(b)", tempreg,
11283 BFD_RELOC_MIPS_GOT_DISP, mips_gp_register);
11286 else if (mips_big_got && !HAVE_NEWABI)
11288 int gpdelay;
11289 int lui_reloc_type = (int) BFD_RELOC_MIPS_GOT_HI16;
11290 int lw_reloc_type = (int) BFD_RELOC_MIPS_GOT_LO16;
11291 int local_reloc_type = (int) BFD_RELOC_MIPS_GOT16;
11293 /* This is the large GOT case. If this is a reference to an
11294 external symbol, and there is no constant, we want
11295 lui $tempreg,<sym> (BFD_RELOC_MIPS_GOT_HI16)
11296 addu $tempreg,$tempreg,$gp
11297 lw $tempreg,<sym>($tempreg) (BFD_RELOC_MIPS_GOT_LO16)
11298 or for lca or if tempreg is PIC_CALL_REG
11299 lui $tempreg,<sym> (BFD_RELOC_MIPS_CALL_HI16)
11300 addu $tempreg,$tempreg,$gp
11301 lw $tempreg,<sym>($tempreg) (BFD_RELOC_MIPS_CALL_LO16)
11302 For a local symbol, we want
11303 lw $tempreg,<sym>($gp) (BFD_RELOC_MIPS_GOT16)
11305 addiu $tempreg,$tempreg,<sym> (BFD_RELOC_LO16)
11307 If we have a small constant, and this is a reference to
11308 an external symbol, we want
11309 lui $tempreg,<sym> (BFD_RELOC_MIPS_GOT_HI16)
11310 addu $tempreg,$tempreg,$gp
11311 lw $tempreg,<sym>($tempreg) (BFD_RELOC_MIPS_GOT_LO16)
11313 addiu $tempreg,$tempreg,<constant>
11314 For a local symbol, we want
11315 lw $tempreg,<sym>($gp) (BFD_RELOC_MIPS_GOT16)
11317 addiu $tempreg,$tempreg,<constant> (BFD_RELOC_LO16)
11319 If we have a large constant, and this is a reference to
11320 an external symbol, we want
11321 lui $tempreg,<sym> (BFD_RELOC_MIPS_GOT_HI16)
11322 addu $tempreg,$tempreg,$gp
11323 lw $tempreg,<sym>($tempreg) (BFD_RELOC_MIPS_GOT_LO16)
11324 lui $at,<hiconstant>
11325 addiu $at,$at,<loconstant>
11326 addu $tempreg,$tempreg,$at
11327 For a local symbol, we want
11328 lw $tempreg,<sym>($gp) (BFD_RELOC_MIPS_GOT16)
11329 lui $at,<hiconstant>
11330 addiu $at,$at,<loconstant> (BFD_RELOC_LO16)
11331 addu $tempreg,$tempreg,$at
11334 expr1.X_add_number = offset_expr.X_add_number;
11335 offset_expr.X_add_number = 0;
11336 relax_start (offset_expr.X_add_symbol);
11337 gpdelay = reg_needs_delay (mips_gp_register);
11338 if (expr1.X_add_number == 0 && breg == 0
11339 && (call || tempreg == PIC_CALL_REG))
11341 lui_reloc_type = (int) BFD_RELOC_MIPS_CALL_HI16;
11342 lw_reloc_type = (int) BFD_RELOC_MIPS_CALL_LO16;
11344 macro_build (&offset_expr, "lui", LUI_FMT, tempreg, lui_reloc_type);
11345 macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t",
11346 tempreg, tempreg, mips_gp_register);
11347 macro_build (&offset_expr, ADDRESS_LOAD_INSN, "t,o(b)",
11348 tempreg, lw_reloc_type, tempreg);
11349 if (expr1.X_add_number == 0)
11351 if (breg != 0)
11353 /* We're going to put in an addu instruction using
11354 tempreg, so we may as well insert the nop right
11355 now. */
11356 load_delay_nop ();
11359 else if (expr1.X_add_number >= -0x8000
11360 && expr1.X_add_number < 0x8000)
11362 load_delay_nop ();
11363 macro_build (&expr1, ADDRESS_ADDI_INSN, "t,r,j",
11364 tempreg, tempreg, BFD_RELOC_LO16);
11366 else
11368 unsigned int dreg;
11370 /* If we are going to add in a base register, and the
11371 target register and the base register are the same,
11372 then we are using AT as a temporary register. Since
11373 we want to load the constant into AT, we add our
11374 current AT (from the global offset table) and the
11375 register into the register now, and pretend we were
11376 not using a base register. */
11377 if (breg != op[0])
11378 dreg = tempreg;
11379 else
11381 gas_assert (tempreg == AT);
11382 load_delay_nop ();
11383 macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t",
11384 op[0], AT, breg);
11385 dreg = op[0];
11388 load_register (AT, &expr1, HAVE_64BIT_ADDRESSES);
11389 macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t", dreg, dreg, AT);
11391 used_at = 1;
11393 offset_expr.X_add_number = SEXT_16BIT (expr1.X_add_number);
11394 relax_switch ();
11396 if (gpdelay)
11398 /* This is needed because this instruction uses $gp, but
11399 the first instruction on the main stream does not. */
11400 macro_build (NULL, "nop", "");
11403 macro_build (&offset_expr, ADDRESS_LOAD_INSN, "t,o(b)", tempreg,
11404 local_reloc_type, mips_gp_register);
11405 if (expr1.X_add_number >= -0x8000
11406 && expr1.X_add_number < 0x8000)
11408 load_delay_nop ();
11409 macro_build (&offset_expr, ADDRESS_ADDI_INSN, "t,r,j",
11410 tempreg, tempreg, BFD_RELOC_LO16);
11411 /* FIXME: If add_number is 0, and there was no base
11412 register, the external symbol case ended with a load,
11413 so if the symbol turns out to not be external, and
11414 the next instruction uses tempreg, an unnecessary nop
11415 will be inserted. */
11417 else
11419 if (breg == op[0])
11421 /* We must add in the base register now, as in the
11422 external symbol case. */
11423 gas_assert (tempreg == AT);
11424 load_delay_nop ();
11425 macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t",
11426 op[0], AT, breg);
11427 tempreg = op[0];
11428 /* We set breg to 0 because we have arranged to add
11429 it in in both cases. */
11430 breg = 0;
11433 macro_build_lui (&expr1, AT);
11434 macro_build (&offset_expr, ADDRESS_ADDI_INSN, "t,r,j",
11435 AT, AT, BFD_RELOC_LO16);
11436 macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t",
11437 tempreg, tempreg, AT);
11438 used_at = 1;
11440 relax_end ();
11442 else if (mips_big_got && HAVE_NEWABI)
11444 int lui_reloc_type = (int) BFD_RELOC_MIPS_GOT_HI16;
11445 int lw_reloc_type = (int) BFD_RELOC_MIPS_GOT_LO16;
11446 int add_breg_early = 0;
11448 /* This is the large GOT case. If this is a reference to an
11449 external symbol, and there is no constant, we want
11450 lui $tempreg,<sym> (BFD_RELOC_MIPS_GOT_HI16)
11451 add $tempreg,$tempreg,$gp
11452 lw $tempreg,<sym>($tempreg) (BFD_RELOC_MIPS_GOT_LO16)
11453 or for lca or if tempreg is PIC_CALL_REG
11454 lui $tempreg,<sym> (BFD_RELOC_MIPS_CALL_HI16)
11455 add $tempreg,$tempreg,$gp
11456 lw $tempreg,<sym>($tempreg) (BFD_RELOC_MIPS_CALL_LO16)
11458 If we have a small constant, and this is a reference to
11459 an external symbol, we want
11460 lui $tempreg,<sym> (BFD_RELOC_MIPS_GOT_HI16)
11461 add $tempreg,$tempreg,$gp
11462 lw $tempreg,<sym>($tempreg) (BFD_RELOC_MIPS_GOT_LO16)
11463 addi $tempreg,$tempreg,<constant>
11465 If we have a large constant, and this is a reference to
11466 an external symbol, we want
11467 lui $tempreg,<sym> (BFD_RELOC_MIPS_GOT_HI16)
11468 addu $tempreg,$tempreg,$gp
11469 lw $tempreg,<sym>($tempreg) (BFD_RELOC_MIPS_GOT_LO16)
11470 lui $at,<hiconstant>
11471 addi $at,$at,<loconstant>
11472 add $tempreg,$tempreg,$at
11474 If we have NewABI, and we know it's a local symbol, we want
11475 lw $reg,<sym>($gp) (BFD_RELOC_MIPS_GOT_PAGE)
11476 addiu $reg,$reg,<sym> (BFD_RELOC_MIPS_GOT_OFST)
11477 otherwise we have to resort to GOT_HI16/GOT_LO16. */
11479 relax_start (offset_expr.X_add_symbol);
11481 expr1.X_add_number = offset_expr.X_add_number;
11482 offset_expr.X_add_number = 0;
11484 if (expr1.X_add_number == 0 && breg == 0
11485 && (call || tempreg == PIC_CALL_REG))
11487 lui_reloc_type = (int) BFD_RELOC_MIPS_CALL_HI16;
11488 lw_reloc_type = (int) BFD_RELOC_MIPS_CALL_LO16;
11490 macro_build (&offset_expr, "lui", LUI_FMT, tempreg, lui_reloc_type);
11491 macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t",
11492 tempreg, tempreg, mips_gp_register);
11493 macro_build (&offset_expr, ADDRESS_LOAD_INSN, "t,o(b)",
11494 tempreg, lw_reloc_type, tempreg);
11496 if (expr1.X_add_number == 0)
11498 else if (expr1.X_add_number >= -0x8000
11499 && expr1.X_add_number < 0x8000)
11501 macro_build (&expr1, ADDRESS_ADDI_INSN, "t,r,j",
11502 tempreg, tempreg, BFD_RELOC_LO16);
11504 else if (IS_SEXT_32BIT_NUM (expr1.X_add_number + 0x8000))
11506 unsigned int dreg;
11508 /* If we are going to add in a base register, and the
11509 target register and the base register are the same,
11510 then we are using AT as a temporary register. Since
11511 we want to load the constant into AT, we add our
11512 current AT (from the global offset table) and the
11513 register into the register now, and pretend we were
11514 not using a base register. */
11515 if (breg != op[0])
11516 dreg = tempreg;
11517 else
11519 gas_assert (tempreg == AT);
11520 macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t",
11521 op[0], AT, breg);
11522 dreg = op[0];
11523 add_breg_early = 1;
11526 load_register (AT, &expr1, HAVE_64BIT_ADDRESSES);
11527 macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t", dreg, dreg, AT);
11529 used_at = 1;
11531 else
11532 as_bad (_("PIC code offset overflow (max 32 signed bits)"));
11534 relax_switch ();
11535 offset_expr.X_add_number = expr1.X_add_number;
11536 macro_build (&offset_expr, ADDRESS_LOAD_INSN, "t,o(b)", tempreg,
11537 BFD_RELOC_MIPS_GOT_PAGE, mips_gp_register);
11538 macro_build (&offset_expr, ADDRESS_ADDI_INSN, "t,r,j", tempreg,
11539 tempreg, BFD_RELOC_MIPS_GOT_OFST);
11540 if (add_breg_early)
11542 macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t",
11543 op[0], tempreg, breg);
11544 breg = 0;
11545 tempreg = op[0];
11547 relax_end ();
11549 else
11550 abort ();
11552 if (breg != 0)
11553 macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t", op[0], tempreg, breg);
11554 break;
11556 case M_MSGSND:
11557 gas_assert (!mips_opts.micromips);
11558 macro_build (NULL, "c2", "C", (op[0] << 16) | 0x01);
11559 break;
11561 case M_MSGLD:
11562 gas_assert (!mips_opts.micromips);
11563 macro_build (NULL, "c2", "C", 0x02);
11564 break;
11566 case M_MSGLD_T:
11567 gas_assert (!mips_opts.micromips);
11568 macro_build (NULL, "c2", "C", (op[0] << 16) | 0x02);
11569 break;
11571 case M_MSGWAIT:
11572 gas_assert (!mips_opts.micromips);
11573 macro_build (NULL, "c2", "C", 3);
11574 break;
11576 case M_MSGWAIT_T:
11577 gas_assert (!mips_opts.micromips);
11578 macro_build (NULL, "c2", "C", (op[0] << 16) | 0x03);
11579 break;
11581 case M_J_A:
11582 /* The j instruction may not be used in PIC code, since it
11583 requires an absolute address. We convert it to a b
11584 instruction. */
11585 if (mips_pic == NO_PIC)
11586 macro_build (&offset_expr, "j", "a");
11587 else
11588 macro_build (&offset_expr, "b", "p");
11589 break;
11591 /* The jal instructions must be handled as macros because when
11592 generating PIC code they expand to multi-instruction
11593 sequences. Normally they are simple instructions. */
11594 case M_JALS_1:
11595 op[1] = op[0];
11596 op[0] = RA;
11597 /* Fall through. */
11598 case M_JALS_2:
11599 gas_assert (mips_opts.micromips);
11600 if (mips_opts.insn32)
11602 as_bad (_("opcode not supported in the `insn32' mode `%s'"), str);
11603 break;
11605 jals = 1;
11606 goto jal;
11607 case M_JAL_1:
11608 op[1] = op[0];
11609 op[0] = RA;
11610 /* Fall through. */
11611 case M_JAL_2:
11612 jal:
11613 if (mips_pic == NO_PIC)
11615 s = jals ? "jalrs" : "jalr";
11616 if (mips_opts.micromips
11617 && !mips_opts.insn32
11618 && op[0] == RA
11619 && !(history[0].insn_mo->pinfo2 & INSN2_BRANCH_DELAY_32BIT))
11620 macro_build (NULL, s, "mj", op[1]);
11621 else
11622 macro_build (NULL, s, JALR_FMT, op[0], op[1]);
11624 else
11626 int cprestore = (mips_pic == SVR4_PIC && !HAVE_NEWABI
11627 && mips_cprestore_offset >= 0);
11629 if (op[1] != PIC_CALL_REG)
11630 as_warn (_("MIPS PIC call to register other than $25"));
11632 s = ((mips_opts.micromips
11633 && !mips_opts.insn32
11634 && (!mips_opts.noreorder || cprestore))
11635 ? "jalrs" : "jalr");
11636 if (mips_opts.micromips
11637 && !mips_opts.insn32
11638 && op[0] == RA
11639 && !(history[0].insn_mo->pinfo2 & INSN2_BRANCH_DELAY_32BIT))
11640 macro_build (NULL, s, "mj", op[1]);
11641 else
11642 macro_build (NULL, s, JALR_FMT, op[0], op[1]);
11643 if (mips_pic == SVR4_PIC && !HAVE_NEWABI)
11645 if (mips_cprestore_offset < 0)
11646 as_warn (_("no .cprestore pseudo-op used in PIC code"));
11647 else
11649 if (!mips_frame_reg_valid)
11651 as_warn (_("no .frame pseudo-op used in PIC code"));
11652 /* Quiet this warning. */
11653 mips_frame_reg_valid = 1;
11655 if (!mips_cprestore_valid)
11657 as_warn (_("no .cprestore pseudo-op used in PIC code"));
11658 /* Quiet this warning. */
11659 mips_cprestore_valid = 1;
11661 if (mips_opts.noreorder)
11662 macro_build (NULL, "nop", "");
11663 expr1.X_add_number = mips_cprestore_offset;
11664 macro_build_ldst_constoffset (&expr1, ADDRESS_LOAD_INSN,
11665 mips_gp_register,
11666 mips_frame_reg,
11667 HAVE_64BIT_ADDRESSES);
11672 break;
11674 case M_JALS_A:
11675 gas_assert (mips_opts.micromips);
11676 if (mips_opts.insn32)
11678 as_bad (_("opcode not supported in the `insn32' mode `%s'"), str);
11679 break;
11681 jals = 1;
11682 /* Fall through. */
11683 case M_JAL_A:
11684 if (mips_pic == NO_PIC)
11685 macro_build (&offset_expr, jals ? "jals" : "jal", "a");
11686 else if (mips_pic == SVR4_PIC)
11688 /* If this is a reference to an external symbol, and we are
11689 using a small GOT, we want
11690 lw $25,<sym>($gp) (BFD_RELOC_MIPS_CALL16)
11692 jalr $ra,$25
11694 lw $gp,cprestore($sp)
11695 The cprestore value is set using the .cprestore
11696 pseudo-op. If we are using a big GOT, we want
11697 lui $25,<sym> (BFD_RELOC_MIPS_CALL_HI16)
11698 addu $25,$25,$gp
11699 lw $25,<sym>($25) (BFD_RELOC_MIPS_CALL_LO16)
11701 jalr $ra,$25
11703 lw $gp,cprestore($sp)
11704 If the symbol is not external, we want
11705 lw $25,<sym>($gp) (BFD_RELOC_MIPS_GOT16)
11707 addiu $25,$25,<sym> (BFD_RELOC_LO16)
11708 jalr $ra,$25
11710 lw $gp,cprestore($sp)
11712 For NewABI, we use the same CALL16 or CALL_HI16/CALL_LO16
11713 sequences above, minus nops, unless the symbol is local,
11714 which enables us to use GOT_PAGE/GOT_OFST (big got) or
11715 GOT_DISP. */
11716 if (HAVE_NEWABI)
11718 if (!mips_big_got)
11720 relax_start (offset_expr.X_add_symbol);
11721 macro_build (&offset_expr, ADDRESS_LOAD_INSN, "t,o(b)",
11722 PIC_CALL_REG, BFD_RELOC_MIPS_CALL16,
11723 mips_gp_register);
11724 relax_switch ();
11725 macro_build (&offset_expr, ADDRESS_LOAD_INSN, "t,o(b)",
11726 PIC_CALL_REG, BFD_RELOC_MIPS_GOT_DISP,
11727 mips_gp_register);
11728 relax_end ();
11730 else
11732 relax_start (offset_expr.X_add_symbol);
11733 macro_build (&offset_expr, "lui", LUI_FMT, PIC_CALL_REG,
11734 BFD_RELOC_MIPS_CALL_HI16);
11735 macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t", PIC_CALL_REG,
11736 PIC_CALL_REG, mips_gp_register);
11737 macro_build (&offset_expr, ADDRESS_LOAD_INSN, "t,o(b)",
11738 PIC_CALL_REG, BFD_RELOC_MIPS_CALL_LO16,
11739 PIC_CALL_REG);
11740 relax_switch ();
11741 macro_build (&offset_expr, ADDRESS_LOAD_INSN, "t,o(b)",
11742 PIC_CALL_REG, BFD_RELOC_MIPS_GOT_PAGE,
11743 mips_gp_register);
11744 macro_build (&offset_expr, ADDRESS_ADDI_INSN, "t,r,j",
11745 PIC_CALL_REG, PIC_CALL_REG,
11746 BFD_RELOC_MIPS_GOT_OFST);
11747 relax_end ();
11750 macro_build_jalr (&offset_expr, 0);
11752 else
11754 relax_start (offset_expr.X_add_symbol);
11755 if (!mips_big_got)
11757 macro_build (&offset_expr, ADDRESS_LOAD_INSN, "t,o(b)",
11758 PIC_CALL_REG, BFD_RELOC_MIPS_CALL16,
11759 mips_gp_register);
11760 load_delay_nop ();
11761 relax_switch ();
11763 else
11765 int gpdelay;
11767 gpdelay = reg_needs_delay (mips_gp_register);
11768 macro_build (&offset_expr, "lui", LUI_FMT, PIC_CALL_REG,
11769 BFD_RELOC_MIPS_CALL_HI16);
11770 macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t", PIC_CALL_REG,
11771 PIC_CALL_REG, mips_gp_register);
11772 macro_build (&offset_expr, ADDRESS_LOAD_INSN, "t,o(b)",
11773 PIC_CALL_REG, BFD_RELOC_MIPS_CALL_LO16,
11774 PIC_CALL_REG);
11775 load_delay_nop ();
11776 relax_switch ();
11777 if (gpdelay)
11778 macro_build (NULL, "nop", "");
11780 macro_build (&offset_expr, ADDRESS_LOAD_INSN, "t,o(b)",
11781 PIC_CALL_REG, BFD_RELOC_MIPS_GOT16,
11782 mips_gp_register);
11783 load_delay_nop ();
11784 macro_build (&offset_expr, ADDRESS_ADDI_INSN, "t,r,j",
11785 PIC_CALL_REG, PIC_CALL_REG, BFD_RELOC_LO16);
11786 relax_end ();
11787 macro_build_jalr (&offset_expr, mips_cprestore_offset >= 0);
11789 if (mips_cprestore_offset < 0)
11790 as_warn (_("no .cprestore pseudo-op used in PIC code"));
11791 else
11793 if (!mips_frame_reg_valid)
11795 as_warn (_("no .frame pseudo-op used in PIC code"));
11796 /* Quiet this warning. */
11797 mips_frame_reg_valid = 1;
11799 if (!mips_cprestore_valid)
11801 as_warn (_("no .cprestore pseudo-op used in PIC code"));
11802 /* Quiet this warning. */
11803 mips_cprestore_valid = 1;
11805 if (mips_opts.noreorder)
11806 macro_build (NULL, "nop", "");
11807 expr1.X_add_number = mips_cprestore_offset;
11808 macro_build_ldst_constoffset (&expr1, ADDRESS_LOAD_INSN,
11809 mips_gp_register,
11810 mips_frame_reg,
11811 HAVE_64BIT_ADDRESSES);
11815 else if (mips_pic == VXWORKS_PIC)
11816 as_bad (_("non-PIC jump used in PIC library"));
11817 else
11818 abort ();
11820 break;
11822 case M_LBUE_AB:
11823 s = "lbue";
11824 fmt = "t,+j(b)";
11825 offbits = 9;
11826 goto ld_st;
11827 case M_LHUE_AB:
11828 s = "lhue";
11829 fmt = "t,+j(b)";
11830 offbits = 9;
11831 goto ld_st;
11832 case M_LBE_AB:
11833 s = "lbe";
11834 fmt = "t,+j(b)";
11835 offbits = 9;
11836 goto ld_st;
11837 case M_LHE_AB:
11838 s = "lhe";
11839 fmt = "t,+j(b)";
11840 offbits = 9;
11841 goto ld_st;
11842 case M_LLE_AB:
11843 s = "lle";
11844 fmt = "t,+j(b)";
11845 offbits = 9;
11846 goto ld_st;
11847 case M_LWE_AB:
11848 s = "lwe";
11849 fmt = "t,+j(b)";
11850 offbits = 9;
11851 goto ld_st;
11852 case M_LWLE_AB:
11853 s = "lwle";
11854 fmt = "t,+j(b)";
11855 offbits = 9;
11856 goto ld_st;
11857 case M_LWRE_AB:
11858 s = "lwre";
11859 fmt = "t,+j(b)";
11860 offbits = 9;
11861 goto ld_st;
11862 case M_SBE_AB:
11863 s = "sbe";
11864 fmt = "t,+j(b)";
11865 offbits = 9;
11866 goto ld_st;
11867 case M_SCE_AB:
11868 s = "sce";
11869 fmt = "t,+j(b)";
11870 offbits = 9;
11871 goto ld_st;
11872 case M_SHE_AB:
11873 s = "she";
11874 fmt = "t,+j(b)";
11875 offbits = 9;
11876 goto ld_st;
11877 case M_SWE_AB:
11878 s = "swe";
11879 fmt = "t,+j(b)";
11880 offbits = 9;
11881 goto ld_st;
11882 case M_SWLE_AB:
11883 s = "swle";
11884 fmt = "t,+j(b)";
11885 offbits = 9;
11886 goto ld_st;
11887 case M_SWRE_AB:
11888 s = "swre";
11889 fmt = "t,+j(b)";
11890 offbits = 9;
11891 goto ld_st;
11892 case M_ACLR_AB:
11893 s = "aclr";
11894 fmt = "\\,~(b)";
11895 offbits = 12;
11896 goto ld_st;
11897 case M_ASET_AB:
11898 s = "aset";
11899 fmt = "\\,~(b)";
11900 offbits = 12;
11901 goto ld_st;
11902 case M_LB_AB:
11903 s = "lb";
11904 fmt = "t,o(b)";
11905 goto ld;
11906 case M_LBU_AB:
11907 s = "lbu";
11908 fmt = "t,o(b)";
11909 goto ld;
11910 case M_LH_AB:
11911 s = "lh";
11912 fmt = "t,o(b)";
11913 goto ld;
11914 case M_LHU_AB:
11915 s = "lhu";
11916 fmt = "t,o(b)";
11917 goto ld;
11918 case M_LW_AB:
11919 s = "lw";
11920 fmt = "t,o(b)";
11921 goto ld;
11922 case M_LWC0_AB:
11923 gas_assert (!mips_opts.micromips);
11924 s = "lwc0";
11925 fmt = "E,o(b)";
11926 /* Itbl support may require additional care here. */
11927 coproc = 1;
11928 goto ld_st;
11929 case M_LWC1_AB:
11930 s = "lwc1";
11931 fmt = "T,o(b)";
11932 /* Itbl support may require additional care here. */
11933 coproc = 1;
11934 goto ld_st;
11935 case M_LWC2_AB:
11936 s = "lwc2";
11937 fmt = COP12_FMT;
11938 offbits = (mips_opts.micromips ? 12
11939 : ISA_IS_R6 (mips_opts.isa) ? 11
11940 : 16);
11941 /* Itbl support may require additional care here. */
11942 coproc = 1;
11943 goto ld_st;
11944 case M_LWC3_AB:
11945 gas_assert (!mips_opts.micromips);
11946 s = "lwc3";
11947 fmt = "E,o(b)";
11948 /* Itbl support may require additional care here. */
11949 coproc = 1;
11950 goto ld_st;
11951 case M_LWL_AB:
11952 s = "lwl";
11953 fmt = MEM12_FMT;
11954 offbits = (mips_opts.micromips ? 12 : 16);
11955 goto ld_st;
11956 case M_LWR_AB:
11957 s = "lwr";
11958 fmt = MEM12_FMT;
11959 offbits = (mips_opts.micromips ? 12 : 16);
11960 goto ld_st;
11961 case M_LDC1_AB:
11962 s = "ldc1";
11963 fmt = "T,o(b)";
11964 /* Itbl support may require additional care here. */
11965 coproc = 1;
11966 goto ld_st;
11967 case M_LDC2_AB:
11968 s = "ldc2";
11969 fmt = COP12_FMT;
11970 offbits = (mips_opts.micromips ? 12
11971 : ISA_IS_R6 (mips_opts.isa) ? 11
11972 : 16);
11973 /* Itbl support may require additional care here. */
11974 coproc = 1;
11975 goto ld_st;
11976 case M_LQC2_AB:
11977 s = "lqc2";
11978 fmt = "+7,o(b)";
11979 /* Itbl support may require additional care here. */
11980 coproc = 1;
11981 goto ld_st;
11982 case M_LDC3_AB:
11983 s = "ldc3";
11984 fmt = "E,o(b)";
11985 /* Itbl support may require additional care here. */
11986 coproc = 1;
11987 goto ld_st;
11988 case M_LDL_AB:
11989 s = "ldl";
11990 fmt = MEM12_FMT;
11991 offbits = (mips_opts.micromips ? 12 : 16);
11992 goto ld_st;
11993 case M_LDR_AB:
11994 s = "ldr";
11995 fmt = MEM12_FMT;
11996 offbits = (mips_opts.micromips ? 12 : 16);
11997 goto ld_st;
11998 case M_LL_AB:
11999 s = "ll";
12000 fmt = LL_SC_FMT;
12001 offbits = (mips_opts.micromips ? 12
12002 : ISA_IS_R6 (mips_opts.isa) ? 9
12003 : 16);
12004 goto ld;
12005 case M_LLD_AB:
12006 s = "lld";
12007 fmt = LL_SC_FMT;
12008 offbits = (mips_opts.micromips ? 12
12009 : ISA_IS_R6 (mips_opts.isa) ? 9
12010 : 16);
12011 goto ld;
12012 case M_LWU_AB:
12013 s = "lwu";
12014 fmt = MEM12_FMT;
12015 offbits = (mips_opts.micromips ? 12 : 16);
12016 goto ld;
12017 case M_LWP_AB:
12018 gas_assert (mips_opts.micromips);
12019 s = "lwp";
12020 fmt = "t,~(b)";
12021 offbits = 12;
12022 lp = 1;
12023 goto ld;
12024 case M_LDP_AB:
12025 gas_assert (mips_opts.micromips);
12026 s = "ldp";
12027 fmt = "t,~(b)";
12028 offbits = 12;
12029 lp = 1;
12030 goto ld;
12031 case M_LLDP_AB:
12032 case M_LLWP_AB:
12033 case M_LLWPE_AB:
12034 s = ip->insn_mo->name;
12035 fmt = "t,d,s";
12036 ll_sc_paired = 1;
12037 offbits = 0;
12038 goto ld;
12039 case M_LWM_AB:
12040 gas_assert (mips_opts.micromips);
12041 s = "lwm";
12042 fmt = "n,~(b)";
12043 offbits = 12;
12044 goto ld_st;
12045 case M_LDM_AB:
12046 gas_assert (mips_opts.micromips);
12047 s = "ldm";
12048 fmt = "n,~(b)";
12049 offbits = 12;
12050 goto ld_st;
12053 /* Try to use one the the load registers to compute the base address.
12054 We don't want to use $0 as tempreg. */
12055 if (ll_sc_paired)
12057 if ((op[0] == ZERO && op[3] == op[1])
12058 || (op[1] == ZERO && op[3] == op[0])
12059 || (op[0] == ZERO && op[1] == ZERO))
12060 goto ld_st;
12061 else if (op[0] != op[3] && op[0] != ZERO)
12062 tempreg = op[0];
12063 else
12064 tempreg = op[1];
12066 else
12068 if (op[2] == op[0] + lp || op[0] + lp == ZERO)
12069 goto ld_st;
12070 else
12071 tempreg = op[0] + lp;
12073 goto ld_noat;
12075 case M_SB_AB:
12076 s = "sb";
12077 fmt = "t,o(b)";
12078 goto ld_st;
12079 case M_SH_AB:
12080 s = "sh";
12081 fmt = "t,o(b)";
12082 goto ld_st;
12083 case M_SW_AB:
12084 s = "sw";
12085 fmt = "t,o(b)";
12086 goto ld_st;
12087 case M_SWC0_AB:
12088 gas_assert (!mips_opts.micromips);
12089 s = "swc0";
12090 fmt = "E,o(b)";
12091 /* Itbl support may require additional care here. */
12092 coproc = 1;
12093 goto ld_st;
12094 case M_SWC1_AB:
12095 s = "swc1";
12096 fmt = "T,o(b)";
12097 /* Itbl support may require additional care here. */
12098 coproc = 1;
12099 goto ld_st;
12100 case M_SWC2_AB:
12101 s = "swc2";
12102 fmt = COP12_FMT;
12103 offbits = (mips_opts.micromips ? 12
12104 : ISA_IS_R6 (mips_opts.isa) ? 11
12105 : 16);
12106 /* Itbl support may require additional care here. */
12107 coproc = 1;
12108 goto ld_st;
12109 case M_SWC3_AB:
12110 gas_assert (!mips_opts.micromips);
12111 s = "swc3";
12112 fmt = "E,o(b)";
12113 /* Itbl support may require additional care here. */
12114 coproc = 1;
12115 goto ld_st;
12116 case M_SWL_AB:
12117 s = "swl";
12118 fmt = MEM12_FMT;
12119 offbits = (mips_opts.micromips ? 12 : 16);
12120 goto ld_st;
12121 case M_SWR_AB:
12122 s = "swr";
12123 fmt = MEM12_FMT;
12124 offbits = (mips_opts.micromips ? 12 : 16);
12125 goto ld_st;
12126 case M_SC_AB:
12127 s = "sc";
12128 fmt = LL_SC_FMT;
12129 offbits = (mips_opts.micromips ? 12
12130 : ISA_IS_R6 (mips_opts.isa) ? 9
12131 : 16);
12132 goto ld_st;
12133 case M_SCD_AB:
12134 s = "scd";
12135 fmt = LL_SC_FMT;
12136 offbits = (mips_opts.micromips ? 12
12137 : ISA_IS_R6 (mips_opts.isa) ? 9
12138 : 16);
12139 goto ld_st;
12140 case M_SCDP_AB:
12141 case M_SCWP_AB:
12142 case M_SCWPE_AB:
12143 s = ip->insn_mo->name;
12144 fmt = "t,d,s";
12145 ll_sc_paired = 1;
12146 offbits = 0;
12147 goto ld_st;
12148 case M_CACHE_AB:
12149 s = "cache";
12150 fmt = (mips_opts.micromips ? "k,~(b)"
12151 : ISA_IS_R6 (mips_opts.isa) ? "k,+j(b)"
12152 : "k,o(b)");
12153 offbits = (mips_opts.micromips ? 12
12154 : ISA_IS_R6 (mips_opts.isa) ? 9
12155 : 16);
12156 goto ld_st;
12157 case M_CACHEE_AB:
12158 s = "cachee";
12159 fmt = "k,+j(b)";
12160 offbits = 9;
12161 goto ld_st;
12162 case M_PREF_AB:
12163 s = "pref";
12164 fmt = (mips_opts.micromips ? "k,~(b)"
12165 : ISA_IS_R6 (mips_opts.isa) ? "k,+j(b)"
12166 : "k,o(b)");
12167 offbits = (mips_opts.micromips ? 12
12168 : ISA_IS_R6 (mips_opts.isa) ? 9
12169 : 16);
12170 goto ld_st;
12171 case M_PREFE_AB:
12172 s = "prefe";
12173 fmt = "k,+j(b)";
12174 offbits = 9;
12175 goto ld_st;
12176 case M_SDC1_AB:
12177 s = "sdc1";
12178 fmt = "T,o(b)";
12179 coproc = 1;
12180 /* Itbl support may require additional care here. */
12181 goto ld_st;
12182 case M_SDC2_AB:
12183 s = "sdc2";
12184 fmt = COP12_FMT;
12185 offbits = (mips_opts.micromips ? 12
12186 : ISA_IS_R6 (mips_opts.isa) ? 11
12187 : 16);
12188 /* Itbl support may require additional care here. */
12189 coproc = 1;
12190 goto ld_st;
12191 case M_SQC2_AB:
12192 s = "sqc2";
12193 fmt = "+7,o(b)";
12194 /* Itbl support may require additional care here. */
12195 coproc = 1;
12196 goto ld_st;
12197 case M_SDC3_AB:
12198 gas_assert (!mips_opts.micromips);
12199 s = "sdc3";
12200 fmt = "E,o(b)";
12201 /* Itbl support may require additional care here. */
12202 coproc = 1;
12203 goto ld_st;
12204 case M_SDL_AB:
12205 s = "sdl";
12206 fmt = MEM12_FMT;
12207 offbits = (mips_opts.micromips ? 12 : 16);
12208 goto ld_st;
12209 case M_SDR_AB:
12210 s = "sdr";
12211 fmt = MEM12_FMT;
12212 offbits = (mips_opts.micromips ? 12 : 16);
12213 goto ld_st;
12214 case M_SWP_AB:
12215 gas_assert (mips_opts.micromips);
12216 s = "swp";
12217 fmt = "t,~(b)";
12218 offbits = 12;
12219 goto ld_st;
12220 case M_SDP_AB:
12221 gas_assert (mips_opts.micromips);
12222 s = "sdp";
12223 fmt = "t,~(b)";
12224 offbits = 12;
12225 goto ld_st;
12226 case M_SWM_AB:
12227 gas_assert (mips_opts.micromips);
12228 s = "swm";
12229 fmt = "n,~(b)";
12230 offbits = 12;
12231 goto ld_st;
12232 case M_SDM_AB:
12233 gas_assert (mips_opts.micromips);
12234 s = "sdm";
12235 fmt = "n,~(b)";
12236 offbits = 12;
12238 ld_st:
12239 tempreg = AT;
12240 ld_noat:
12241 breg = ll_sc_paired ? op[3] : op[2];
12242 if (small_offset_p (0, align, 16))
12244 /* The first case exists for M_LD_AB and M_SD_AB, which are
12245 macros for o32 but which should act like normal instructions
12246 otherwise. */
12247 if (offbits == 16)
12248 macro_build (&offset_expr, s, fmt, op[0], -1, offset_reloc[0],
12249 offset_reloc[1], offset_reloc[2], breg);
12250 else if (small_offset_p (0, align, offbits))
12252 if (offbits == 0)
12254 if (ll_sc_paired)
12255 macro_build (NULL, s, fmt, op[0], op[1], breg);
12256 else
12257 macro_build (NULL, s, fmt, op[0], breg);
12259 else
12260 macro_build (NULL, s, fmt, op[0],
12261 (int) offset_expr.X_add_number, breg);
12263 else
12265 if (tempreg == AT)
12266 used_at = 1;
12267 macro_build (&offset_expr, ADDRESS_ADDI_INSN, "t,r,j",
12268 tempreg, breg, -1, offset_reloc[0],
12269 offset_reloc[1], offset_reloc[2]);
12270 if (offbits == 0)
12272 if (ll_sc_paired)
12273 macro_build (NULL, s, fmt, op[0], op[1], tempreg);
12274 else
12275 macro_build (NULL, s, fmt, op[0], tempreg);
12277 else
12278 macro_build (NULL, s, fmt, op[0], 0, tempreg);
12280 break;
12283 if (tempreg == AT)
12284 used_at = 1;
12286 if (offset_expr.X_op != O_constant
12287 && offset_expr.X_op != O_symbol)
12289 as_bad (_("expression too complex"));
12290 offset_expr.X_op = O_constant;
12293 if (HAVE_32BIT_ADDRESSES
12294 && !IS_SEXT_32BIT_NUM (offset_expr.X_add_number))
12296 char value [32];
12298 sprintf_vma (value, offset_expr.X_add_number);
12299 as_bad (_("number (0x%s) larger than 32 bits"), value);
12302 /* A constant expression in PIC code can be handled just as it
12303 is in non PIC code. */
12304 if (offset_expr.X_op == O_constant)
12306 expr1.X_add_number = offset_high_part (offset_expr.X_add_number,
12307 offbits == 0 ? 16 : offbits);
12308 offset_expr.X_add_number -= expr1.X_add_number;
12310 load_register (tempreg, &expr1, HAVE_64BIT_ADDRESSES);
12311 if (breg != 0)
12312 macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t",
12313 tempreg, tempreg, breg);
12314 if (offbits == 0)
12316 if (offset_expr.X_add_number != 0)
12317 macro_build (&offset_expr, ADDRESS_ADDI_INSN,
12318 "t,r,j", tempreg, tempreg, BFD_RELOC_LO16);
12319 if (ll_sc_paired)
12320 macro_build (NULL, s, fmt, op[0], op[1], tempreg);
12321 else
12322 macro_build (NULL, s, fmt, op[0], tempreg);
12324 else if (offbits == 16)
12325 macro_build (&offset_expr, s, fmt, op[0], BFD_RELOC_LO16, tempreg);
12326 else
12327 macro_build (NULL, s, fmt, op[0],
12328 (int) offset_expr.X_add_number, tempreg);
12330 else if (offbits != 16)
12332 /* The offset field is too narrow to be used for a low-part
12333 relocation, so load the whole address into the auxiliary
12334 register. */
12335 load_address (tempreg, &offset_expr, &used_at);
12336 if (breg != 0)
12337 macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t",
12338 tempreg, tempreg, breg);
12339 if (offbits == 0)
12341 if (ll_sc_paired)
12342 macro_build (NULL, s, fmt, op[0], op[1], tempreg);
12343 else
12344 macro_build (NULL, s, fmt, op[0], tempreg);
12346 else
12347 macro_build (NULL, s, fmt, op[0], 0, tempreg);
12349 else if (mips_pic == NO_PIC)
12351 /* If this is a reference to a GP relative symbol, and there
12352 is no base register, we want
12353 <op> op[0],<sym>($gp) (BFD_RELOC_GPREL16)
12354 Otherwise, if there is no base register, we want
12355 lui $tempreg,<sym> (BFD_RELOC_HI16_S)
12356 <op> op[0],<sym>($tempreg) (BFD_RELOC_LO16)
12357 If we have a constant, we need two instructions anyhow,
12358 so we always use the latter form.
12360 If we have a base register, and this is a reference to a
12361 GP relative symbol, we want
12362 addu $tempreg,$breg,$gp
12363 <op> op[0],<sym>($tempreg) (BFD_RELOC_GPREL16)
12364 Otherwise we want
12365 lui $tempreg,<sym> (BFD_RELOC_HI16_S)
12366 addu $tempreg,$tempreg,$breg
12367 <op> op[0],<sym>($tempreg) (BFD_RELOC_LO16)
12368 With a constant we always use the latter case.
12370 With 64bit address space and no base register and $at usable,
12371 we want
12372 lui $tempreg,<sym> (BFD_RELOC_MIPS_HIGHEST)
12373 lui $at,<sym> (BFD_RELOC_HI16_S)
12374 daddiu $tempreg,<sym> (BFD_RELOC_MIPS_HIGHER)
12375 dsll32 $tempreg,0
12376 daddu $tempreg,$at
12377 <op> op[0],<sym>($tempreg) (BFD_RELOC_LO16)
12378 If we have a base register, we want
12379 lui $tempreg,<sym> (BFD_RELOC_MIPS_HIGHEST)
12380 lui $at,<sym> (BFD_RELOC_HI16_S)
12381 daddiu $tempreg,<sym> (BFD_RELOC_MIPS_HIGHER)
12382 daddu $at,$breg
12383 dsll32 $tempreg,0
12384 daddu $tempreg,$at
12385 <op> op[0],<sym>($tempreg) (BFD_RELOC_LO16)
12387 Without $at we can't generate the optimal path for superscalar
12388 processors here since this would require two temporary registers.
12389 lui $tempreg,<sym> (BFD_RELOC_MIPS_HIGHEST)
12390 daddiu $tempreg,<sym> (BFD_RELOC_MIPS_HIGHER)
12391 dsll $tempreg,16
12392 daddiu $tempreg,<sym> (BFD_RELOC_HI16_S)
12393 dsll $tempreg,16
12394 <op> op[0],<sym>($tempreg) (BFD_RELOC_LO16)
12395 If we have a base register, we want
12396 lui $tempreg,<sym> (BFD_RELOC_MIPS_HIGHEST)
12397 daddiu $tempreg,<sym> (BFD_RELOC_MIPS_HIGHER)
12398 dsll $tempreg,16
12399 daddiu $tempreg,<sym> (BFD_RELOC_HI16_S)
12400 dsll $tempreg,16
12401 daddu $tempreg,$tempreg,$breg
12402 <op> op[0],<sym>($tempreg) (BFD_RELOC_LO16)
12404 For GP relative symbols in 64bit address space we can use
12405 the same sequence as in 32bit address space. */
12406 if (HAVE_64BIT_SYMBOLS)
12408 if ((valueT) offset_expr.X_add_number <= MAX_GPREL_OFFSET
12409 && !nopic_need_relax (offset_expr.X_add_symbol, 1))
12411 relax_start (offset_expr.X_add_symbol);
12412 if (breg == 0)
12414 macro_build (&offset_expr, s, fmt, op[0],
12415 BFD_RELOC_GPREL16, mips_gp_register);
12417 else
12419 macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t",
12420 tempreg, breg, mips_gp_register);
12421 macro_build (&offset_expr, s, fmt, op[0],
12422 BFD_RELOC_GPREL16, tempreg);
12424 relax_switch ();
12427 if (used_at == 0 && mips_opts.at)
12429 macro_build (&offset_expr, "lui", LUI_FMT, tempreg,
12430 BFD_RELOC_MIPS_HIGHEST);
12431 macro_build (&offset_expr, "lui", LUI_FMT, AT,
12432 BFD_RELOC_HI16_S);
12433 macro_build (&offset_expr, "daddiu", "t,r,j", tempreg,
12434 tempreg, BFD_RELOC_MIPS_HIGHER);
12435 if (breg != 0)
12436 macro_build (NULL, "daddu", "d,v,t", AT, AT, breg);
12437 macro_build (NULL, "dsll32", SHFT_FMT, tempreg, tempreg, 0);
12438 macro_build (NULL, "daddu", "d,v,t", tempreg, tempreg, AT);
12439 macro_build (&offset_expr, s, fmt, op[0], BFD_RELOC_LO16,
12440 tempreg);
12441 used_at = 1;
12443 else
12445 macro_build (&offset_expr, "lui", LUI_FMT, tempreg,
12446 BFD_RELOC_MIPS_HIGHEST);
12447 macro_build (&offset_expr, "daddiu", "t,r,j", tempreg,
12448 tempreg, BFD_RELOC_MIPS_HIGHER);
12449 macro_build (NULL, "dsll", SHFT_FMT, tempreg, tempreg, 16);
12450 macro_build (&offset_expr, "daddiu", "t,r,j", tempreg,
12451 tempreg, BFD_RELOC_HI16_S);
12452 macro_build (NULL, "dsll", SHFT_FMT, tempreg, tempreg, 16);
12453 if (breg != 0)
12454 macro_build (NULL, "daddu", "d,v,t",
12455 tempreg, tempreg, breg);
12456 macro_build (&offset_expr, s, fmt, op[0],
12457 BFD_RELOC_LO16, tempreg);
12460 if (mips_relax.sequence)
12461 relax_end ();
12462 break;
12465 if (breg == 0)
12467 if ((valueT) offset_expr.X_add_number <= MAX_GPREL_OFFSET
12468 && !nopic_need_relax (offset_expr.X_add_symbol, 1))
12470 relax_start (offset_expr.X_add_symbol);
12471 macro_build (&offset_expr, s, fmt, op[0], BFD_RELOC_GPREL16,
12472 mips_gp_register);
12473 relax_switch ();
12475 macro_build_lui (&offset_expr, tempreg);
12476 macro_build (&offset_expr, s, fmt, op[0],
12477 BFD_RELOC_LO16, tempreg);
12478 if (mips_relax.sequence)
12479 relax_end ();
12481 else
12483 if ((valueT) offset_expr.X_add_number <= MAX_GPREL_OFFSET
12484 && !nopic_need_relax (offset_expr.X_add_symbol, 1))
12486 relax_start (offset_expr.X_add_symbol);
12487 macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t",
12488 tempreg, breg, mips_gp_register);
12489 macro_build (&offset_expr, s, fmt, op[0],
12490 BFD_RELOC_GPREL16, tempreg);
12491 relax_switch ();
12493 macro_build_lui (&offset_expr, tempreg);
12494 macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t",
12495 tempreg, tempreg, breg);
12496 macro_build (&offset_expr, s, fmt, op[0],
12497 BFD_RELOC_LO16, tempreg);
12498 if (mips_relax.sequence)
12499 relax_end ();
12502 else if (!mips_big_got)
12504 int lw_reloc_type = (int) BFD_RELOC_MIPS_GOT16;
12506 /* If this is a reference to an external symbol, we want
12507 lw $tempreg,<sym>($gp) (BFD_RELOC_MIPS_GOT16)
12509 <op> op[0],0($tempreg)
12510 Otherwise we want
12511 lw $tempreg,<sym>($gp) (BFD_RELOC_MIPS_GOT16)
12513 addiu $tempreg,$tempreg,<sym> (BFD_RELOC_LO16)
12514 <op> op[0],0($tempreg)
12516 For NewABI, we want
12517 lw $tempreg,<sym>($gp) (BFD_RELOC_MIPS_GOT_PAGE)
12518 <op> op[0],<sym>($tempreg) (BFD_RELOC_MIPS_GOT_OFST)
12520 If there is a base register, we add it to $tempreg before
12521 the <op>. If there is a constant, we stick it in the
12522 <op> instruction. We don't handle constants larger than
12523 16 bits, because we have no way to load the upper 16 bits
12524 (actually, we could handle them for the subset of cases
12525 in which we are not using $at). */
12526 gas_assert (offset_expr.X_op == O_symbol);
12527 if (HAVE_NEWABI)
12529 macro_build (&offset_expr, ADDRESS_LOAD_INSN, "t,o(b)", tempreg,
12530 BFD_RELOC_MIPS_GOT_PAGE, mips_gp_register);
12531 if (breg != 0)
12532 macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t",
12533 tempreg, tempreg, breg);
12534 macro_build (&offset_expr, s, fmt, op[0],
12535 BFD_RELOC_MIPS_GOT_OFST, tempreg);
12536 break;
12538 expr1.X_add_number = offset_expr.X_add_number;
12539 offset_expr.X_add_number = 0;
12540 if (expr1.X_add_number < -0x8000
12541 || expr1.X_add_number >= 0x8000)
12542 as_bad (_("PIC code offset overflow (max 16 signed bits)"));
12543 macro_build (&offset_expr, ADDRESS_LOAD_INSN, "t,o(b)", tempreg,
12544 lw_reloc_type, mips_gp_register);
12545 load_delay_nop ();
12546 relax_start (offset_expr.X_add_symbol);
12547 relax_switch ();
12548 macro_build (&offset_expr, ADDRESS_ADDI_INSN, "t,r,j", tempreg,
12549 tempreg, BFD_RELOC_LO16);
12550 relax_end ();
12551 if (breg != 0)
12552 macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t",
12553 tempreg, tempreg, breg);
12554 macro_build (&expr1, s, fmt, op[0], BFD_RELOC_LO16, tempreg);
12556 else if (mips_big_got && !HAVE_NEWABI)
12558 int gpdelay;
12560 /* If this is a reference to an external symbol, we want
12561 lui $tempreg,<sym> (BFD_RELOC_MIPS_GOT_HI16)
12562 addu $tempreg,$tempreg,$gp
12563 lw $tempreg,<sym>($tempreg) (BFD_RELOC_MIPS_GOT_LO16)
12564 <op> op[0],0($tempreg)
12565 Otherwise we want
12566 lw $tempreg,<sym>($gp) (BFD_RELOC_MIPS_GOT16)
12568 addiu $tempreg,$tempreg,<sym> (BFD_RELOC_LO16)
12569 <op> op[0],0($tempreg)
12570 If there is a base register, we add it to $tempreg before
12571 the <op>. If there is a constant, we stick it in the
12572 <op> instruction. We don't handle constants larger than
12573 16 bits, because we have no way to load the upper 16 bits
12574 (actually, we could handle them for the subset of cases
12575 in which we are not using $at). */
12576 gas_assert (offset_expr.X_op == O_symbol);
12577 expr1.X_add_number = offset_expr.X_add_number;
12578 offset_expr.X_add_number = 0;
12579 if (expr1.X_add_number < -0x8000
12580 || expr1.X_add_number >= 0x8000)
12581 as_bad (_("PIC code offset overflow (max 16 signed bits)"));
12582 gpdelay = reg_needs_delay (mips_gp_register);
12583 relax_start (offset_expr.X_add_symbol);
12584 macro_build (&offset_expr, "lui", LUI_FMT, tempreg,
12585 BFD_RELOC_MIPS_GOT_HI16);
12586 macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t", tempreg, tempreg,
12587 mips_gp_register);
12588 macro_build (&offset_expr, ADDRESS_LOAD_INSN, "t,o(b)", tempreg,
12589 BFD_RELOC_MIPS_GOT_LO16, tempreg);
12590 relax_switch ();
12591 if (gpdelay)
12592 macro_build (NULL, "nop", "");
12593 macro_build (&offset_expr, ADDRESS_LOAD_INSN, "t,o(b)", tempreg,
12594 BFD_RELOC_MIPS_GOT16, mips_gp_register);
12595 load_delay_nop ();
12596 macro_build (&offset_expr, ADDRESS_ADDI_INSN, "t,r,j", tempreg,
12597 tempreg, BFD_RELOC_LO16);
12598 relax_end ();
12600 if (breg != 0)
12601 macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t",
12602 tempreg, tempreg, breg);
12603 macro_build (&expr1, s, fmt, op[0], BFD_RELOC_LO16, tempreg);
12605 else if (mips_big_got && HAVE_NEWABI)
12607 /* If this is a reference to an external symbol, we want
12608 lui $tempreg,<sym> (BFD_RELOC_MIPS_GOT_HI16)
12609 add $tempreg,$tempreg,$gp
12610 lw $tempreg,<sym>($tempreg) (BFD_RELOC_MIPS_GOT_LO16)
12611 <op> op[0],<ofst>($tempreg)
12612 Otherwise, for local symbols, we want:
12613 lw $tempreg,<sym>($gp) (BFD_RELOC_MIPS_GOT_PAGE)
12614 <op> op[0],<sym>($tempreg) (BFD_RELOC_MIPS_GOT_OFST) */
12615 gas_assert (offset_expr.X_op == O_symbol);
12616 expr1.X_add_number = offset_expr.X_add_number;
12617 offset_expr.X_add_number = 0;
12618 if (expr1.X_add_number < -0x8000
12619 || expr1.X_add_number >= 0x8000)
12620 as_bad (_("PIC code offset overflow (max 16 signed bits)"));
12621 relax_start (offset_expr.X_add_symbol);
12622 macro_build (&offset_expr, "lui", LUI_FMT, tempreg,
12623 BFD_RELOC_MIPS_GOT_HI16);
12624 macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t", tempreg, tempreg,
12625 mips_gp_register);
12626 macro_build (&offset_expr, ADDRESS_LOAD_INSN, "t,o(b)", tempreg,
12627 BFD_RELOC_MIPS_GOT_LO16, tempreg);
12628 if (breg != 0)
12629 macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t",
12630 tempreg, tempreg, breg);
12631 macro_build (&expr1, s, fmt, op[0], BFD_RELOC_LO16, tempreg);
12633 relax_switch ();
12634 offset_expr.X_add_number = expr1.X_add_number;
12635 macro_build (&offset_expr, ADDRESS_LOAD_INSN, "t,o(b)", tempreg,
12636 BFD_RELOC_MIPS_GOT_PAGE, mips_gp_register);
12637 if (breg != 0)
12638 macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t",
12639 tempreg, tempreg, breg);
12640 macro_build (&offset_expr, s, fmt, op[0],
12641 BFD_RELOC_MIPS_GOT_OFST, tempreg);
12642 relax_end ();
12644 else
12645 abort ();
12647 break;
12649 case M_JRADDIUSP:
12650 gas_assert (mips_opts.micromips);
12651 gas_assert (mips_opts.insn32);
12652 start_noreorder ();
12653 macro_build (NULL, "jr", "s", RA);
12654 expr1.X_add_number = op[0] << 2;
12655 macro_build (&expr1, "addiu", "t,r,j", SP, SP, BFD_RELOC_LO16);
12656 end_noreorder ();
12657 break;
12659 case M_JRC:
12660 gas_assert (mips_opts.micromips);
12661 gas_assert (mips_opts.insn32);
12662 macro_build (NULL, "jr", "s", op[0]);
12663 if (mips_opts.noreorder)
12664 macro_build (NULL, "nop", "");
12665 break;
12667 case M_LI:
12668 case M_LI_S:
12669 load_register (op[0], &imm_expr, 0);
12670 break;
12672 case M_DLI:
12673 load_register (op[0], &imm_expr, 1);
12674 break;
12676 case M_LI_SS:
12677 if (imm_expr.X_op == O_constant)
12679 used_at = 1;
12680 load_register (AT, &imm_expr, 0);
12681 macro_build (NULL, "mtc1", "t,G", AT, op[0]);
12682 break;
12684 else
12686 gas_assert (imm_expr.X_op == O_absent
12687 && offset_expr.X_op == O_symbol
12688 && strcmp (segment_name (S_GET_SEGMENT
12689 (offset_expr.X_add_symbol)),
12690 ".lit4") == 0
12691 && offset_expr.X_add_number == 0);
12692 macro_build (&offset_expr, "lwc1", "T,o(b)", op[0],
12693 BFD_RELOC_MIPS_LITERAL, mips_gp_register);
12694 break;
12697 case M_LI_D:
12698 /* Check if we have a constant in IMM_EXPR. If the GPRs are 64 bits
12699 wide, IMM_EXPR is the entire value. Otherwise IMM_EXPR is the high
12700 order 32 bits of the value and the low order 32 bits are either
12701 zero or in OFFSET_EXPR. */
12702 if (imm_expr.X_op == O_constant)
12704 if (GPR_SIZE == 64)
12705 load_register (op[0], &imm_expr, 1);
12706 else
12708 int hreg, lreg;
12710 if (target_big_endian)
12712 hreg = op[0];
12713 lreg = op[0] + 1;
12715 else
12717 hreg = op[0] + 1;
12718 lreg = op[0];
12721 if (hreg <= 31)
12722 load_register (hreg, &imm_expr, 0);
12723 if (lreg <= 31)
12725 if (offset_expr.X_op == O_absent)
12726 move_register (lreg, 0);
12727 else
12729 gas_assert (offset_expr.X_op == O_constant);
12730 load_register (lreg, &offset_expr, 0);
12734 break;
12736 gas_assert (imm_expr.X_op == O_absent);
12738 /* We know that sym is in the .rdata section. First we get the
12739 upper 16 bits of the address. */
12740 if (mips_pic == NO_PIC)
12742 macro_build_lui (&offset_expr, AT);
12743 used_at = 1;
12745 else
12747 macro_build (&offset_expr, ADDRESS_LOAD_INSN, "t,o(b)", AT,
12748 BFD_RELOC_MIPS_GOT16, mips_gp_register);
12749 used_at = 1;
12752 /* Now we load the register(s). */
12753 if (GPR_SIZE == 64)
12755 used_at = 1;
12756 macro_build (&offset_expr, "ld", "t,o(b)", op[0],
12757 BFD_RELOC_LO16, AT);
12759 else
12761 used_at = 1;
12762 macro_build (&offset_expr, "lw", "t,o(b)", op[0],
12763 BFD_RELOC_LO16, AT);
12764 if (op[0] != RA)
12766 /* FIXME: How in the world do we deal with the possible
12767 overflow here? */
12768 offset_expr.X_add_number += 4;
12769 macro_build (&offset_expr, "lw", "t,o(b)",
12770 op[0] + 1, BFD_RELOC_LO16, AT);
12773 break;
12775 case M_LI_DD:
12776 /* Check if we have a constant in IMM_EXPR. If the FPRs are 64 bits
12777 wide, IMM_EXPR is the entire value and the GPRs are known to be 64
12778 bits wide as well. Otherwise IMM_EXPR is the high order 32 bits of
12779 the value and the low order 32 bits are either zero or in
12780 OFFSET_EXPR. */
12781 if (imm_expr.X_op == O_constant)
12783 used_at = 1;
12784 load_register (AT, &imm_expr, FPR_SIZE == 64);
12785 if (FPR_SIZE == 64 && GPR_SIZE == 64)
12786 macro_build (NULL, "dmtc1", "t,S", AT, op[0]);
12787 else
12789 if (ISA_HAS_MXHC1 (mips_opts.isa))
12790 macro_build (NULL, "mthc1", "t,G", AT, op[0]);
12791 else if (FPR_SIZE != 32)
12792 as_bad (_("Unable to generate `%s' compliant code "
12793 "without mthc1"),
12794 (FPR_SIZE == 64) ? "fp64" : "fpxx");
12795 else
12796 macro_build (NULL, "mtc1", "t,G", AT, op[0] + 1);
12797 if (offset_expr.X_op == O_absent)
12798 macro_build (NULL, "mtc1", "t,G", 0, op[0]);
12799 else
12801 gas_assert (offset_expr.X_op == O_constant);
12802 load_register (AT, &offset_expr, 0);
12803 macro_build (NULL, "mtc1", "t,G", AT, op[0]);
12806 break;
12809 gas_assert (imm_expr.X_op == O_absent
12810 && offset_expr.X_op == O_symbol
12811 && offset_expr.X_add_number == 0);
12812 s = segment_name (S_GET_SEGMENT (offset_expr.X_add_symbol));
12813 if (strcmp (s, ".lit8") == 0)
12815 op[2] = mips_gp_register;
12816 offset_reloc[0] = BFD_RELOC_MIPS_LITERAL;
12817 offset_reloc[1] = BFD_RELOC_UNUSED;
12818 offset_reloc[2] = BFD_RELOC_UNUSED;
12820 else
12822 gas_assert (strcmp (s, RDATA_SECTION_NAME) == 0);
12823 used_at = 1;
12824 if (mips_pic != NO_PIC)
12825 macro_build (&offset_expr, ADDRESS_LOAD_INSN, "t,o(b)", AT,
12826 BFD_RELOC_MIPS_GOT16, mips_gp_register);
12827 else
12829 /* FIXME: This won't work for a 64 bit address. */
12830 macro_build_lui (&offset_expr, AT);
12833 op[2] = AT;
12834 offset_reloc[0] = BFD_RELOC_LO16;
12835 offset_reloc[1] = BFD_RELOC_UNUSED;
12836 offset_reloc[2] = BFD_RELOC_UNUSED;
12838 align = 8;
12839 /* Fall through. */
12841 case M_L_DAB:
12842 /* The MIPS assembler seems to check for X_add_number not
12843 being double aligned and generating:
12844 lui at,%hi(foo+1)
12845 addu at,at,v1
12846 addiu at,at,%lo(foo+1)
12847 lwc1 f2,0(at)
12848 lwc1 f3,4(at)
12849 But, the resulting address is the same after relocation so why
12850 generate the extra instruction? */
12851 /* Itbl support may require additional care here. */
12852 coproc = 1;
12853 fmt = "T,o(b)";
12854 if (CPU_HAS_LDC1_SDC1 (mips_opts.arch))
12856 s = "ldc1";
12857 goto ld_st;
12859 s = "lwc1";
12860 goto ldd_std;
12862 case M_S_DAB:
12863 gas_assert (!mips_opts.micromips);
12864 /* Itbl support may require additional care here. */
12865 coproc = 1;
12866 fmt = "T,o(b)";
12867 if (CPU_HAS_LDC1_SDC1 (mips_opts.arch))
12869 s = "sdc1";
12870 goto ld_st;
12872 s = "swc1";
12873 goto ldd_std;
12875 case M_LQ_AB:
12876 fmt = "t,o(b)";
12877 s = "lq";
12878 goto ld;
12880 case M_SQ_AB:
12881 fmt = "t,o(b)";
12882 s = "sq";
12883 goto ld_st;
12885 case M_LD_AB:
12886 fmt = "t,o(b)";
12887 if (GPR_SIZE == 64)
12889 s = "ld";
12890 goto ld;
12892 s = "lw";
12893 goto ldd_std;
12895 case M_SD_AB:
12896 fmt = "t,o(b)";
12897 if (GPR_SIZE == 64)
12899 s = "sd";
12900 goto ld_st;
12902 s = "sw";
12904 ldd_std:
12905 /* Even on a big endian machine $fn comes before $fn+1. We have
12906 to adjust when loading from memory. We set coproc if we must
12907 load $fn+1 first. */
12908 /* Itbl support may require additional care here. */
12909 if (!target_big_endian)
12910 coproc = 0;
12912 breg = op[2];
12913 if (small_offset_p (0, align, 16))
12915 ep = &offset_expr;
12916 if (!small_offset_p (4, align, 16))
12918 macro_build (&offset_expr, ADDRESS_ADDI_INSN, "t,r,j", AT, breg,
12919 -1, offset_reloc[0], offset_reloc[1],
12920 offset_reloc[2]);
12921 expr1.X_add_number = 0;
12922 ep = &expr1;
12923 breg = AT;
12924 used_at = 1;
12925 offset_reloc[0] = BFD_RELOC_LO16;
12926 offset_reloc[1] = BFD_RELOC_UNUSED;
12927 offset_reloc[2] = BFD_RELOC_UNUSED;
12929 if (strcmp (s, "lw") == 0 && op[0] == breg)
12931 ep->X_add_number += 4;
12932 macro_build (ep, s, fmt, op[0] + 1, -1, offset_reloc[0],
12933 offset_reloc[1], offset_reloc[2], breg);
12934 ep->X_add_number -= 4;
12935 macro_build (ep, s, fmt, op[0], -1, offset_reloc[0],
12936 offset_reloc[1], offset_reloc[2], breg);
12938 else
12940 macro_build (ep, s, fmt, coproc ? op[0] + 1 : op[0], -1,
12941 offset_reloc[0], offset_reloc[1], offset_reloc[2],
12942 breg);
12943 ep->X_add_number += 4;
12944 macro_build (ep, s, fmt, coproc ? op[0] : op[0] + 1, -1,
12945 offset_reloc[0], offset_reloc[1], offset_reloc[2],
12946 breg);
12948 break;
12951 if (offset_expr.X_op != O_symbol
12952 && offset_expr.X_op != O_constant)
12954 as_bad (_("expression too complex"));
12955 offset_expr.X_op = O_constant;
12958 if (HAVE_32BIT_ADDRESSES
12959 && !IS_SEXT_32BIT_NUM (offset_expr.X_add_number))
12961 char value [32];
12963 sprintf_vma (value, offset_expr.X_add_number);
12964 as_bad (_("number (0x%s) larger than 32 bits"), value);
12967 if (mips_pic == NO_PIC || offset_expr.X_op == O_constant)
12969 /* If this is a reference to a GP relative symbol, we want
12970 <op> op[0],<sym>($gp) (BFD_RELOC_GPREL16)
12971 <op> op[0]+1,<sym>+4($gp) (BFD_RELOC_GPREL16)
12972 If we have a base register, we use this
12973 addu $at,$breg,$gp
12974 <op> op[0],<sym>($at) (BFD_RELOC_GPREL16)
12975 <op> op[0]+1,<sym>+4($at) (BFD_RELOC_GPREL16)
12976 If this is not a GP relative symbol, we want
12977 lui $at,<sym> (BFD_RELOC_HI16_S)
12978 <op> op[0],<sym>($at) (BFD_RELOC_LO16)
12979 <op> op[0]+1,<sym>+4($at) (BFD_RELOC_LO16)
12980 If there is a base register, we add it to $at after the
12981 lui instruction. If there is a constant, we always use
12982 the last case. */
12983 if (offset_expr.X_op == O_symbol
12984 && (valueT) offset_expr.X_add_number <= MAX_GPREL_OFFSET
12985 && !nopic_need_relax (offset_expr.X_add_symbol, 1))
12987 relax_start (offset_expr.X_add_symbol);
12988 if (breg == 0)
12990 tempreg = mips_gp_register;
12992 else
12994 macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t",
12995 AT, breg, mips_gp_register);
12996 tempreg = AT;
12997 used_at = 1;
13000 /* Itbl support may require additional care here. */
13001 macro_build (&offset_expr, s, fmt, coproc ? op[0] + 1 : op[0],
13002 BFD_RELOC_GPREL16, tempreg);
13003 offset_expr.X_add_number += 4;
13005 /* Set mips_optimize to 2 to avoid inserting an
13006 undesired nop. */
13007 hold_mips_optimize = mips_optimize;
13008 mips_optimize = 2;
13009 /* Itbl support may require additional care here. */
13010 macro_build (&offset_expr, s, fmt, coproc ? op[0] : op[0] + 1,
13011 BFD_RELOC_GPREL16, tempreg);
13012 mips_optimize = hold_mips_optimize;
13014 relax_switch ();
13016 offset_expr.X_add_number -= 4;
13018 used_at = 1;
13019 if (offset_high_part (offset_expr.X_add_number, 16)
13020 != offset_high_part (offset_expr.X_add_number + 4, 16))
13022 load_address (AT, &offset_expr, &used_at);
13023 offset_expr.X_op = O_constant;
13024 offset_expr.X_add_number = 0;
13026 else
13027 macro_build_lui (&offset_expr, AT);
13028 if (breg != 0)
13029 macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t", AT, breg, AT);
13030 /* Itbl support may require additional care here. */
13031 macro_build (&offset_expr, s, fmt, coproc ? op[0] + 1 : op[0],
13032 BFD_RELOC_LO16, AT);
13033 /* FIXME: How do we handle overflow here? */
13034 offset_expr.X_add_number += 4;
13035 /* Itbl support may require additional care here. */
13036 macro_build (&offset_expr, s, fmt, coproc ? op[0] : op[0] + 1,
13037 BFD_RELOC_LO16, AT);
13038 if (mips_relax.sequence)
13039 relax_end ();
13041 else if (!mips_big_got)
13043 /* If this is a reference to an external symbol, we want
13044 lw $at,<sym>($gp) (BFD_RELOC_MIPS_GOT16)
13046 <op> op[0],0($at)
13047 <op> op[0]+1,4($at)
13048 Otherwise we want
13049 lw $at,<sym>($gp) (BFD_RELOC_MIPS_GOT16)
13051 <op> op[0],<sym>($at) (BFD_RELOC_LO16)
13052 <op> op[0]+1,<sym>+4($at) (BFD_RELOC_LO16)
13053 If there is a base register we add it to $at before the
13054 lwc1 instructions. If there is a constant we include it
13055 in the lwc1 instructions. */
13056 used_at = 1;
13057 expr1.X_add_number = offset_expr.X_add_number;
13058 if (expr1.X_add_number < -0x8000
13059 || expr1.X_add_number >= 0x8000 - 4)
13060 as_bad (_("PIC code offset overflow (max 16 signed bits)"));
13061 load_got_offset (AT, &offset_expr);
13062 load_delay_nop ();
13063 if (breg != 0)
13064 macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t", AT, breg, AT);
13066 /* Set mips_optimize to 2 to avoid inserting an undesired
13067 nop. */
13068 hold_mips_optimize = mips_optimize;
13069 mips_optimize = 2;
13071 /* Itbl support may require additional care here. */
13072 relax_start (offset_expr.X_add_symbol);
13073 macro_build (&expr1, s, fmt, coproc ? op[0] + 1 : op[0],
13074 BFD_RELOC_LO16, AT);
13075 expr1.X_add_number += 4;
13076 macro_build (&expr1, s, fmt, coproc ? op[0] : op[0] + 1,
13077 BFD_RELOC_LO16, AT);
13078 relax_switch ();
13079 macro_build (&offset_expr, s, fmt, coproc ? op[0] + 1 : op[0],
13080 BFD_RELOC_LO16, AT);
13081 offset_expr.X_add_number += 4;
13082 macro_build (&offset_expr, s, fmt, coproc ? op[0] : op[0] + 1,
13083 BFD_RELOC_LO16, AT);
13084 relax_end ();
13086 mips_optimize = hold_mips_optimize;
13088 else if (mips_big_got)
13090 int gpdelay;
13092 /* If this is a reference to an external symbol, we want
13093 lui $at,<sym> (BFD_RELOC_MIPS_GOT_HI16)
13094 addu $at,$at,$gp
13095 lw $at,<sym>($at) (BFD_RELOC_MIPS_GOT_LO16)
13097 <op> op[0],0($at)
13098 <op> op[0]+1,4($at)
13099 Otherwise we want
13100 lw $at,<sym>($gp) (BFD_RELOC_MIPS_GOT16)
13102 <op> op[0],<sym>($at) (BFD_RELOC_LO16)
13103 <op> op[0]+1,<sym>+4($at) (BFD_RELOC_LO16)
13104 If there is a base register we add it to $at before the
13105 lwc1 instructions. If there is a constant we include it
13106 in the lwc1 instructions. */
13107 used_at = 1;
13108 expr1.X_add_number = offset_expr.X_add_number;
13109 offset_expr.X_add_number = 0;
13110 if (expr1.X_add_number < -0x8000
13111 || expr1.X_add_number >= 0x8000 - 4)
13112 as_bad (_("PIC code offset overflow (max 16 signed bits)"));
13113 gpdelay = reg_needs_delay (mips_gp_register);
13114 relax_start (offset_expr.X_add_symbol);
13115 macro_build (&offset_expr, "lui", LUI_FMT,
13116 AT, BFD_RELOC_MIPS_GOT_HI16);
13117 macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t",
13118 AT, AT, mips_gp_register);
13119 macro_build (&offset_expr, ADDRESS_LOAD_INSN, "t,o(b)",
13120 AT, BFD_RELOC_MIPS_GOT_LO16, AT);
13121 load_delay_nop ();
13122 if (breg != 0)
13123 macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t", AT, breg, AT);
13124 /* Itbl support may require additional care here. */
13125 macro_build (&expr1, s, fmt, coproc ? op[0] + 1 : op[0],
13126 BFD_RELOC_LO16, AT);
13127 expr1.X_add_number += 4;
13129 /* Set mips_optimize to 2 to avoid inserting an undesired
13130 nop. */
13131 hold_mips_optimize = mips_optimize;
13132 mips_optimize = 2;
13133 /* Itbl support may require additional care here. */
13134 macro_build (&expr1, s, fmt, coproc ? op[0] : op[0] + 1,
13135 BFD_RELOC_LO16, AT);
13136 mips_optimize = hold_mips_optimize;
13137 expr1.X_add_number -= 4;
13139 relax_switch ();
13140 offset_expr.X_add_number = expr1.X_add_number;
13141 if (gpdelay)
13142 macro_build (NULL, "nop", "");
13143 macro_build (&offset_expr, ADDRESS_LOAD_INSN, "t,o(b)", AT,
13144 BFD_RELOC_MIPS_GOT16, mips_gp_register);
13145 load_delay_nop ();
13146 if (breg != 0)
13147 macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t", AT, breg, AT);
13148 /* Itbl support may require additional care here. */
13149 macro_build (&offset_expr, s, fmt, coproc ? op[0] + 1 : op[0],
13150 BFD_RELOC_LO16, AT);
13151 offset_expr.X_add_number += 4;
13153 /* Set mips_optimize to 2 to avoid inserting an undesired
13154 nop. */
13155 hold_mips_optimize = mips_optimize;
13156 mips_optimize = 2;
13157 /* Itbl support may require additional care here. */
13158 macro_build (&offset_expr, s, fmt, coproc ? op[0] : op[0] + 1,
13159 BFD_RELOC_LO16, AT);
13160 mips_optimize = hold_mips_optimize;
13161 relax_end ();
13163 else
13164 abort ();
13166 break;
13168 case M_SAA_AB:
13169 s = "saa";
13170 goto saa_saad;
13171 case M_SAAD_AB:
13172 s = "saad";
13173 saa_saad:
13174 gas_assert (!mips_opts.micromips);
13175 offbits = 0;
13176 fmt = "t,(b)";
13177 goto ld_st;
13179 /* New code added to support COPZ instructions.
13180 This code builds table entries out of the macros in mip_opcodes.
13181 R4000 uses interlocks to handle coproc delays.
13182 Other chips (like the R3000) require nops to be inserted for delays.
13184 FIXME: Currently, we require that the user handle delays.
13185 In order to fill delay slots for non-interlocked chips,
13186 we must have a way to specify delays based on the coprocessor.
13187 Eg. 4 cycles if load coproc reg from memory, 1 if in cache, etc.
13188 What are the side-effects of the cop instruction?
13189 What cache support might we have and what are its effects?
13190 Both coprocessor & memory require delays. how long???
13191 What registers are read/set/modified?
13193 If an itbl is provided to interpret cop instructions,
13194 this knowledge can be encoded in the itbl spec. */
13196 case M_COP0:
13197 s = "c0";
13198 goto copz;
13199 case M_COP1:
13200 s = "c1";
13201 goto copz;
13202 case M_COP2:
13203 s = "c2";
13204 goto copz;
13205 case M_COP3:
13206 s = "c3";
13207 copz:
13208 gas_assert (!mips_opts.micromips);
13209 /* For now we just do C (same as Cz). The parameter will be
13210 stored in insn_opcode by mips_ip. */
13211 macro_build (NULL, s, "C", (int) ip->insn_opcode);
13212 break;
13214 case M_MOVE:
13215 move_register (op[0], op[1]);
13216 break;
13218 case M_MOVEP:
13219 gas_assert (mips_opts.micromips);
13220 gas_assert (mips_opts.insn32);
13221 move_register (micromips_to_32_reg_h_map1[op[0]],
13222 micromips_to_32_reg_m_map[op[1]]);
13223 move_register (micromips_to_32_reg_h_map2[op[0]],
13224 micromips_to_32_reg_n_map[op[2]]);
13225 break;
13227 case M_DMUL:
13228 dbl = 1;
13229 /* Fall through. */
13230 case M_MUL:
13231 if (mips_opts.arch == CPU_R5900)
13232 macro_build (NULL, dbl ? "dmultu" : "multu", "d,s,t", op[0], op[1],
13233 op[2]);
13234 else
13236 macro_build (NULL, dbl ? "dmultu" : "multu", "s,t", op[1], op[2]);
13237 macro_build (NULL, "mflo", MFHL_FMT, op[0]);
13239 break;
13241 case M_DMUL_I:
13242 dbl = 1;
13243 /* Fall through. */
13244 case M_MUL_I:
13245 /* The MIPS assembler some times generates shifts and adds. I'm
13246 not trying to be that fancy. GCC should do this for us
13247 anyway. */
13248 used_at = 1;
13249 load_register (AT, &imm_expr, dbl);
13250 macro_build (NULL, dbl ? "dmult" : "mult", "s,t", op[1], AT);
13251 macro_build (NULL, "mflo", MFHL_FMT, op[0]);
13252 break;
13254 case M_DMULO_I:
13255 dbl = 1;
13256 /* Fall through. */
13257 case M_MULO_I:
13258 imm = 1;
13259 goto do_mulo;
13261 case M_DMULO:
13262 dbl = 1;
13263 /* Fall through. */
13264 case M_MULO:
13265 do_mulo:
13266 start_noreorder ();
13267 used_at = 1;
13268 if (imm)
13269 load_register (AT, &imm_expr, dbl);
13270 macro_build (NULL, dbl ? "dmult" : "mult", "s,t",
13271 op[1], imm ? AT : op[2]);
13272 macro_build (NULL, "mflo", MFHL_FMT, op[0]);
13273 macro_build (NULL, dbl ? "dsra32" : "sra", SHFT_FMT, op[0], op[0], 31);
13274 macro_build (NULL, "mfhi", MFHL_FMT, AT);
13275 if (mips_trap)
13276 macro_build (NULL, "tne", TRAP_FMT, op[0], AT, 6);
13277 else
13279 if (mips_opts.micromips)
13280 micromips_label_expr (&label_expr);
13281 else
13282 label_expr.X_add_number = 8;
13283 macro_build (&label_expr, "beq", "s,t,p", op[0], AT);
13284 macro_build (NULL, "nop", "");
13285 macro_build (NULL, "break", BRK_FMT, 6);
13286 if (mips_opts.micromips)
13287 micromips_add_label ();
13289 end_noreorder ();
13290 macro_build (NULL, "mflo", MFHL_FMT, op[0]);
13291 break;
13293 case M_DMULOU_I:
13294 dbl = 1;
13295 /* Fall through. */
13296 case M_MULOU_I:
13297 imm = 1;
13298 goto do_mulou;
13300 case M_DMULOU:
13301 dbl = 1;
13302 /* Fall through. */
13303 case M_MULOU:
13304 do_mulou:
13305 start_noreorder ();
13306 used_at = 1;
13307 if (imm)
13308 load_register (AT, &imm_expr, dbl);
13309 macro_build (NULL, dbl ? "dmultu" : "multu", "s,t",
13310 op[1], imm ? AT : op[2]);
13311 macro_build (NULL, "mfhi", MFHL_FMT, AT);
13312 macro_build (NULL, "mflo", MFHL_FMT, op[0]);
13313 if (mips_trap)
13314 macro_build (NULL, "tne", TRAP_FMT, AT, ZERO, 6);
13315 else
13317 if (mips_opts.micromips)
13318 micromips_label_expr (&label_expr);
13319 else
13320 label_expr.X_add_number = 8;
13321 macro_build (&label_expr, "beq", "s,t,p", AT, ZERO);
13322 macro_build (NULL, "nop", "");
13323 macro_build (NULL, "break", BRK_FMT, 6);
13324 if (mips_opts.micromips)
13325 micromips_add_label ();
13327 end_noreorder ();
13328 break;
13330 case M_DROL:
13331 if (ISA_HAS_DROR (mips_opts.isa) || CPU_HAS_DROR (mips_opts.arch))
13333 if (op[0] == op[1])
13335 tempreg = AT;
13336 used_at = 1;
13338 else
13339 tempreg = op[0];
13340 macro_build (NULL, "dnegu", "d,w", tempreg, op[2]);
13341 macro_build (NULL, "drorv", "d,t,s", op[0], op[1], tempreg);
13342 break;
13344 used_at = 1;
13345 macro_build (NULL, "dsubu", "d,v,t", AT, ZERO, op[2]);
13346 macro_build (NULL, "dsrlv", "d,t,s", AT, op[1], AT);
13347 macro_build (NULL, "dsllv", "d,t,s", op[0], op[1], op[2]);
13348 macro_build (NULL, "or", "d,v,t", op[0], op[0], AT);
13349 break;
13351 case M_ROL:
13352 if (ISA_HAS_ROR (mips_opts.isa) || CPU_HAS_ROR (mips_opts.arch))
13354 if (op[0] == op[1])
13356 tempreg = AT;
13357 used_at = 1;
13359 else
13360 tempreg = op[0];
13361 macro_build (NULL, "negu", "d,w", tempreg, op[2]);
13362 macro_build (NULL, "rorv", "d,t,s", op[0], op[1], tempreg);
13363 break;
13365 used_at = 1;
13366 macro_build (NULL, "subu", "d,v,t", AT, ZERO, op[2]);
13367 macro_build (NULL, "srlv", "d,t,s", AT, op[1], AT);
13368 macro_build (NULL, "sllv", "d,t,s", op[0], op[1], op[2]);
13369 macro_build (NULL, "or", "d,v,t", op[0], op[0], AT);
13370 break;
13372 case M_DROL_I:
13374 unsigned int rot;
13375 const char *l;
13376 const char *rr;
13378 rot = imm_expr.X_add_number & 0x3f;
13379 if (ISA_HAS_DROR (mips_opts.isa) || CPU_HAS_DROR (mips_opts.arch))
13381 rot = (64 - rot) & 0x3f;
13382 if (rot >= 32)
13383 macro_build (NULL, "dror32", SHFT_FMT, op[0], op[1], rot - 32);
13384 else
13385 macro_build (NULL, "dror", SHFT_FMT, op[0], op[1], rot);
13386 break;
13388 if (rot == 0)
13390 macro_build (NULL, "dsrl", SHFT_FMT, op[0], op[1], 0);
13391 break;
13393 l = (rot < 0x20) ? "dsll" : "dsll32";
13394 rr = ((0x40 - rot) < 0x20) ? "dsrl" : "dsrl32";
13395 rot &= 0x1f;
13396 used_at = 1;
13397 macro_build (NULL, l, SHFT_FMT, AT, op[1], rot);
13398 macro_build (NULL, rr, SHFT_FMT, op[0], op[1], (0x20 - rot) & 0x1f);
13399 macro_build (NULL, "or", "d,v,t", op[0], op[0], AT);
13401 break;
13403 case M_ROL_I:
13405 unsigned int rot;
13407 rot = imm_expr.X_add_number & 0x1f;
13408 if (ISA_HAS_ROR (mips_opts.isa) || CPU_HAS_ROR (mips_opts.arch))
13410 macro_build (NULL, "ror", SHFT_FMT, op[0], op[1],
13411 (32 - rot) & 0x1f);
13412 break;
13414 if (rot == 0)
13416 macro_build (NULL, "srl", SHFT_FMT, op[0], op[1], 0);
13417 break;
13419 used_at = 1;
13420 macro_build (NULL, "sll", SHFT_FMT, AT, op[1], rot);
13421 macro_build (NULL, "srl", SHFT_FMT, op[0], op[1], (0x20 - rot) & 0x1f);
13422 macro_build (NULL, "or", "d,v,t", op[0], op[0], AT);
13424 break;
13426 case M_DROR:
13427 if (ISA_HAS_DROR (mips_opts.isa) || CPU_HAS_DROR (mips_opts.arch))
13429 macro_build (NULL, "drorv", "d,t,s", op[0], op[1], op[2]);
13430 break;
13432 used_at = 1;
13433 macro_build (NULL, "dsubu", "d,v,t", AT, ZERO, op[2]);
13434 macro_build (NULL, "dsllv", "d,t,s", AT, op[1], AT);
13435 macro_build (NULL, "dsrlv", "d,t,s", op[0], op[1], op[2]);
13436 macro_build (NULL, "or", "d,v,t", op[0], op[0], AT);
13437 break;
13439 case M_ROR:
13440 if (ISA_HAS_ROR (mips_opts.isa) || CPU_HAS_ROR (mips_opts.arch))
13442 macro_build (NULL, "rorv", "d,t,s", op[0], op[1], op[2]);
13443 break;
13445 used_at = 1;
13446 macro_build (NULL, "subu", "d,v,t", AT, ZERO, op[2]);
13447 macro_build (NULL, "sllv", "d,t,s", AT, op[1], AT);
13448 macro_build (NULL, "srlv", "d,t,s", op[0], op[1], op[2]);
13449 macro_build (NULL, "or", "d,v,t", op[0], op[0], AT);
13450 break;
13452 case M_DROR_I:
13454 unsigned int rot;
13455 const char *l;
13456 const char *rr;
13458 rot = imm_expr.X_add_number & 0x3f;
13459 if (ISA_HAS_DROR (mips_opts.isa) || CPU_HAS_DROR (mips_opts.arch))
13461 if (rot >= 32)
13462 macro_build (NULL, "dror32", SHFT_FMT, op[0], op[1], rot - 32);
13463 else
13464 macro_build (NULL, "dror", SHFT_FMT, op[0], op[1], rot);
13465 break;
13467 if (rot == 0)
13469 macro_build (NULL, "dsrl", SHFT_FMT, op[0], op[1], 0);
13470 break;
13472 rr = (rot < 0x20) ? "dsrl" : "dsrl32";
13473 l = ((0x40 - rot) < 0x20) ? "dsll" : "dsll32";
13474 rot &= 0x1f;
13475 used_at = 1;
13476 macro_build (NULL, rr, SHFT_FMT, AT, op[1], rot);
13477 macro_build (NULL, l, SHFT_FMT, op[0], op[1], (0x20 - rot) & 0x1f);
13478 macro_build (NULL, "or", "d,v,t", op[0], op[0], AT);
13480 break;
13482 case M_ROR_I:
13484 unsigned int rot;
13486 rot = imm_expr.X_add_number & 0x1f;
13487 if (ISA_HAS_ROR (mips_opts.isa) || CPU_HAS_ROR (mips_opts.arch))
13489 macro_build (NULL, "ror", SHFT_FMT, op[0], op[1], rot);
13490 break;
13492 if (rot == 0)
13494 macro_build (NULL, "srl", SHFT_FMT, op[0], op[1], 0);
13495 break;
13497 used_at = 1;
13498 macro_build (NULL, "srl", SHFT_FMT, AT, op[1], rot);
13499 macro_build (NULL, "sll", SHFT_FMT, op[0], op[1], (0x20 - rot) & 0x1f);
13500 macro_build (NULL, "or", "d,v,t", op[0], op[0], AT);
13502 break;
13504 case M_SEQ:
13505 if (op[1] == 0)
13506 macro_build (&expr1, "sltiu", "t,r,j", op[0], op[2], BFD_RELOC_LO16);
13507 else if (op[2] == 0)
13508 macro_build (&expr1, "sltiu", "t,r,j", op[0], op[1], BFD_RELOC_LO16);
13509 else
13511 macro_build (NULL, "xor", "d,v,t", op[0], op[1], op[2]);
13512 macro_build (&expr1, "sltiu", "t,r,j", op[0], op[0], BFD_RELOC_LO16);
13514 break;
13516 case M_SEQ_I:
13517 if (imm_expr.X_add_number == 0)
13519 macro_build (&expr1, "sltiu", "t,r,j", op[0], op[1], BFD_RELOC_LO16);
13520 break;
13522 if (op[1] == 0)
13524 as_warn (_("instruction %s: result is always false"),
13525 ip->insn_mo->name);
13526 move_register (op[0], 0);
13527 break;
13529 if (CPU_HAS_SEQ (mips_opts.arch)
13530 && -512 <= imm_expr.X_add_number
13531 && imm_expr.X_add_number < 512)
13533 macro_build (NULL, "seqi", "t,r,+Q", op[0], op[1],
13534 (int) imm_expr.X_add_number);
13535 break;
13537 if (imm_expr.X_add_number >= 0
13538 && imm_expr.X_add_number < 0x10000)
13539 macro_build (&imm_expr, "xori", "t,r,i", op[0], op[1], BFD_RELOC_LO16);
13540 else if (imm_expr.X_add_number > -0x8000
13541 && imm_expr.X_add_number < 0)
13543 imm_expr.X_add_number = -imm_expr.X_add_number;
13544 macro_build (&imm_expr, GPR_SIZE == 32 ? "addiu" : "daddiu",
13545 "t,r,j", op[0], op[1], BFD_RELOC_LO16);
13547 else if (CPU_HAS_SEQ (mips_opts.arch))
13549 used_at = 1;
13550 load_register (AT, &imm_expr, GPR_SIZE == 64);
13551 macro_build (NULL, "seq", "d,v,t", op[0], op[1], AT);
13552 break;
13554 else
13556 load_register (AT, &imm_expr, GPR_SIZE == 64);
13557 macro_build (NULL, "xor", "d,v,t", op[0], op[1], AT);
13558 used_at = 1;
13560 macro_build (&expr1, "sltiu", "t,r,j", op[0], op[0], BFD_RELOC_LO16);
13561 break;
13563 case M_SGE: /* X >= Y <==> not (X < Y) */
13564 s = "slt";
13565 goto sge;
13566 case M_SGEU:
13567 s = "sltu";
13568 sge:
13569 macro_build (NULL, s, "d,v,t", op[0], op[1], op[2]);
13570 macro_build (&expr1, "xori", "t,r,i", op[0], op[0], BFD_RELOC_LO16);
13571 break;
13573 case M_SGE_I: /* X >= I <==> not (X < I). */
13574 case M_SGEU_I:
13575 if (imm_expr.X_add_number >= -0x8000
13576 && imm_expr.X_add_number < 0x8000)
13577 macro_build (&imm_expr, mask == M_SGE_I ? "slti" : "sltiu", "t,r,j",
13578 op[0], op[1], BFD_RELOC_LO16);
13579 else
13581 load_register (AT, &imm_expr, GPR_SIZE == 64);
13582 macro_build (NULL, mask == M_SGE_I ? "slt" : "sltu", "d,v,t",
13583 op[0], op[1], AT);
13584 used_at = 1;
13586 macro_build (&expr1, "xori", "t,r,i", op[0], op[0], BFD_RELOC_LO16);
13587 break;
13589 case M_SGT: /* X > Y <==> Y < X. */
13590 s = "slt";
13591 goto sgt;
13592 case M_SGTU:
13593 s = "sltu";
13594 sgt:
13595 macro_build (NULL, s, "d,v,t", op[0], op[2], op[1]);
13596 break;
13598 case M_SGT_I: /* X > I <==> I < X. */
13599 s = "slt";
13600 goto sgti;
13601 case M_SGTU_I:
13602 s = "sltu";
13603 sgti:
13604 used_at = 1;
13605 load_register (AT, &imm_expr, GPR_SIZE == 64);
13606 macro_build (NULL, s, "d,v,t", op[0], AT, op[1]);
13607 break;
13609 case M_SLE: /* X <= Y <==> Y >= X <==> not (Y < X). */
13610 s = "slt";
13611 goto sle;
13612 case M_SLEU:
13613 s = "sltu";
13614 sle:
13615 macro_build (NULL, s, "d,v,t", op[0], op[2], op[1]);
13616 macro_build (&expr1, "xori", "t,r,i", op[0], op[0], BFD_RELOC_LO16);
13617 break;
13619 case M_SLE_I: /* X <= I <==> I >= X <==> not (I < X) */
13620 s = "slt";
13621 goto slei;
13622 case M_SLEU_I:
13623 s = "sltu";
13624 slei:
13625 used_at = 1;
13626 load_register (AT, &imm_expr, GPR_SIZE == 64);
13627 macro_build (NULL, s, "d,v,t", op[0], AT, op[1]);
13628 macro_build (&expr1, "xori", "t,r,i", op[0], op[0], BFD_RELOC_LO16);
13629 break;
13631 case M_SLT_I:
13632 if (imm_expr.X_add_number >= -0x8000
13633 && imm_expr.X_add_number < 0x8000)
13635 macro_build (&imm_expr, "slti", "t,r,j", op[0], op[1],
13636 BFD_RELOC_LO16);
13637 break;
13639 used_at = 1;
13640 load_register (AT, &imm_expr, GPR_SIZE == 64);
13641 macro_build (NULL, "slt", "d,v,t", op[0], op[1], AT);
13642 break;
13644 case M_SLTU_I:
13645 if (imm_expr.X_add_number >= -0x8000
13646 && imm_expr.X_add_number < 0x8000)
13648 macro_build (&imm_expr, "sltiu", "t,r,j", op[0], op[1],
13649 BFD_RELOC_LO16);
13650 break;
13652 used_at = 1;
13653 load_register (AT, &imm_expr, GPR_SIZE == 64);
13654 macro_build (NULL, "sltu", "d,v,t", op[0], op[1], AT);
13655 break;
13657 case M_SNE:
13658 if (op[1] == 0)
13659 macro_build (NULL, "sltu", "d,v,t", op[0], 0, op[2]);
13660 else if (op[2] == 0)
13661 macro_build (NULL, "sltu", "d,v,t", op[0], 0, op[1]);
13662 else
13664 macro_build (NULL, "xor", "d,v,t", op[0], op[1], op[2]);
13665 macro_build (NULL, "sltu", "d,v,t", op[0], 0, op[0]);
13667 break;
13669 case M_SNE_I:
13670 if (imm_expr.X_add_number == 0)
13672 macro_build (NULL, "sltu", "d,v,t", op[0], 0, op[1]);
13673 break;
13675 if (op[1] == 0)
13677 as_warn (_("instruction %s: result is always true"),
13678 ip->insn_mo->name);
13679 macro_build (&expr1, GPR_SIZE == 32 ? "addiu" : "daddiu", "t,r,j",
13680 op[0], 0, BFD_RELOC_LO16);
13681 break;
13683 if (CPU_HAS_SEQ (mips_opts.arch)
13684 && -512 <= imm_expr.X_add_number
13685 && imm_expr.X_add_number < 512)
13687 macro_build (NULL, "snei", "t,r,+Q", op[0], op[1],
13688 (int) imm_expr.X_add_number);
13689 break;
13691 if (imm_expr.X_add_number >= 0
13692 && imm_expr.X_add_number < 0x10000)
13694 macro_build (&imm_expr, "xori", "t,r,i", op[0], op[1],
13695 BFD_RELOC_LO16);
13697 else if (imm_expr.X_add_number > -0x8000
13698 && imm_expr.X_add_number < 0)
13700 imm_expr.X_add_number = -imm_expr.X_add_number;
13701 macro_build (&imm_expr, GPR_SIZE == 32 ? "addiu" : "daddiu",
13702 "t,r,j", op[0], op[1], BFD_RELOC_LO16);
13704 else if (CPU_HAS_SEQ (mips_opts.arch))
13706 used_at = 1;
13707 load_register (AT, &imm_expr, GPR_SIZE == 64);
13708 macro_build (NULL, "sne", "d,v,t", op[0], op[1], AT);
13709 break;
13711 else
13713 load_register (AT, &imm_expr, GPR_SIZE == 64);
13714 macro_build (NULL, "xor", "d,v,t", op[0], op[1], AT);
13715 used_at = 1;
13717 macro_build (NULL, "sltu", "d,v,t", op[0], 0, op[0]);
13718 break;
13720 case M_SUB_I:
13721 s = "addi";
13722 s2 = "sub";
13723 if (ISA_IS_R6 (mips_opts.isa))
13724 goto do_subi_i;
13725 else
13726 goto do_subi;
13727 case M_SUBU_I:
13728 s = "addiu";
13729 s2 = "subu";
13730 goto do_subi;
13731 case M_DSUB_I:
13732 dbl = 1;
13733 s = "daddi";
13734 s2 = "dsub";
13735 if (!mips_opts.micromips && !ISA_IS_R6 (mips_opts.isa))
13736 goto do_subi;
13737 if (imm_expr.X_add_number > -0x200
13738 && imm_expr.X_add_number <= 0x200
13739 && !ISA_IS_R6 (mips_opts.isa))
13741 macro_build (NULL, s, "t,r,.", op[0], op[1],
13742 (int) -imm_expr.X_add_number);
13743 break;
13745 goto do_subi_i;
13746 case M_DSUBU_I:
13747 dbl = 1;
13748 s = "daddiu";
13749 s2 = "dsubu";
13750 do_subi:
13751 if (imm_expr.X_add_number > -0x8000
13752 && imm_expr.X_add_number <= 0x8000)
13754 imm_expr.X_add_number = -imm_expr.X_add_number;
13755 macro_build (&imm_expr, s, "t,r,j", op[0], op[1], BFD_RELOC_LO16);
13756 break;
13758 do_subi_i:
13759 used_at = 1;
13760 load_register (AT, &imm_expr, dbl);
13761 macro_build (NULL, s2, "d,v,t", op[0], op[1], AT);
13762 break;
13764 case M_TEQ_I:
13765 s = "teq";
13766 goto trap;
13767 case M_TGE_I:
13768 s = "tge";
13769 goto trap;
13770 case M_TGEU_I:
13771 s = "tgeu";
13772 goto trap;
13773 case M_TLT_I:
13774 s = "tlt";
13775 goto trap;
13776 case M_TLTU_I:
13777 s = "tltu";
13778 goto trap;
13779 case M_TNE_I:
13780 s = "tne";
13781 trap:
13782 used_at = 1;
13783 load_register (AT, &imm_expr, GPR_SIZE == 64);
13784 macro_build (NULL, s, "s,t", op[0], AT);
13785 break;
13787 case M_TRUNCWS:
13788 case M_TRUNCWD:
13789 gas_assert (!mips_opts.micromips);
13790 gas_assert (mips_opts.isa == ISA_MIPS1);
13791 used_at = 1;
13794 * Is the double cfc1 instruction a bug in the mips assembler;
13795 * or is there a reason for it?
13797 start_noreorder ();
13798 macro_build (NULL, "cfc1", "t,G", op[2], RA);
13799 macro_build (NULL, "cfc1", "t,G", op[2], RA);
13800 macro_build (NULL, "nop", "");
13801 expr1.X_add_number = 3;
13802 macro_build (&expr1, "ori", "t,r,i", AT, op[2], BFD_RELOC_LO16);
13803 expr1.X_add_number = 2;
13804 macro_build (&expr1, "xori", "t,r,i", AT, AT, BFD_RELOC_LO16);
13805 macro_build (NULL, "ctc1", "t,G", AT, RA);
13806 macro_build (NULL, "nop", "");
13807 macro_build (NULL, mask == M_TRUNCWD ? "cvt.w.d" : "cvt.w.s", "D,S",
13808 op[0], op[1]);
13809 macro_build (NULL, "ctc1", "t,G", op[2], RA);
13810 macro_build (NULL, "nop", "");
13811 end_noreorder ();
13812 break;
13814 case M_ULH_AB:
13815 s = "lb";
13816 s2 = "lbu";
13817 off = 1;
13818 goto uld_st;
13819 case M_ULHU_AB:
13820 s = "lbu";
13821 s2 = "lbu";
13822 off = 1;
13823 goto uld_st;
13824 case M_ULW_AB:
13825 s = "lwl";
13826 s2 = "lwr";
13827 offbits = (mips_opts.micromips ? 12 : 16);
13828 off = 3;
13829 goto uld_st;
13830 case M_ULD_AB:
13831 s = "ldl";
13832 s2 = "ldr";
13833 offbits = (mips_opts.micromips ? 12 : 16);
13834 off = 7;
13835 goto uld_st;
13836 case M_USH_AB:
13837 s = "sb";
13838 s2 = "sb";
13839 off = 1;
13840 ust = 1;
13841 goto uld_st;
13842 case M_USW_AB:
13843 s = "swl";
13844 s2 = "swr";
13845 offbits = (mips_opts.micromips ? 12 : 16);
13846 off = 3;
13847 ust = 1;
13848 goto uld_st;
13849 case M_USD_AB:
13850 s = "sdl";
13851 s2 = "sdr";
13852 offbits = (mips_opts.micromips ? 12 : 16);
13853 off = 7;
13854 ust = 1;
13856 uld_st:
13857 breg = op[2];
13858 large_offset = !small_offset_p (off, align, offbits);
13859 ep = &offset_expr;
13860 expr1.X_add_number = 0;
13861 if (large_offset)
13863 used_at = 1;
13864 tempreg = AT;
13865 if (small_offset_p (0, align, 16))
13866 macro_build (ep, ADDRESS_ADDI_INSN, "t,r,j", tempreg, breg, -1,
13867 offset_reloc[0], offset_reloc[1], offset_reloc[2]);
13868 else
13870 load_address (tempreg, ep, &used_at);
13871 if (breg != 0)
13872 macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t",
13873 tempreg, tempreg, breg);
13875 offset_reloc[0] = BFD_RELOC_LO16;
13876 offset_reloc[1] = BFD_RELOC_UNUSED;
13877 offset_reloc[2] = BFD_RELOC_UNUSED;
13878 breg = tempreg;
13879 tempreg = op[0];
13880 ep = &expr1;
13882 else if (!ust && op[0] == breg)
13884 used_at = 1;
13885 tempreg = AT;
13887 else
13888 tempreg = op[0];
13890 if (off == 1)
13891 goto ulh_sh;
13893 if (!target_big_endian)
13894 ep->X_add_number += off;
13895 if (offbits == 12)
13896 macro_build (NULL, s, "t,~(b)", tempreg, (int) ep->X_add_number, breg);
13897 else
13898 macro_build (ep, s, "t,o(b)", tempreg, -1,
13899 offset_reloc[0], offset_reloc[1], offset_reloc[2], breg);
13901 if (!target_big_endian)
13902 ep->X_add_number -= off;
13903 else
13904 ep->X_add_number += off;
13905 if (offbits == 12)
13906 macro_build (NULL, s2, "t,~(b)",
13907 tempreg, (int) ep->X_add_number, breg);
13908 else
13909 macro_build (ep, s2, "t,o(b)", tempreg, -1,
13910 offset_reloc[0], offset_reloc[1], offset_reloc[2], breg);
13912 /* If necessary, move the result in tempreg to the final destination. */
13913 if (!ust && op[0] != tempreg)
13915 /* Protect second load's delay slot. */
13916 load_delay_nop ();
13917 move_register (op[0], tempreg);
13919 break;
13921 ulh_sh:
13922 used_at = 1;
13923 if (target_big_endian == ust)
13924 ep->X_add_number += off;
13925 tempreg = ust || large_offset ? op[0] : AT;
13926 macro_build (ep, s, "t,o(b)", tempreg, -1,
13927 offset_reloc[0], offset_reloc[1], offset_reloc[2], breg);
13929 /* For halfword transfers we need a temporary register to shuffle
13930 bytes. Unfortunately for M_USH_A we have none available before
13931 the next store as AT holds the base address. We deal with this
13932 case by clobbering TREG and then restoring it as with ULH. */
13933 tempreg = ust == large_offset ? op[0] : AT;
13934 if (ust)
13935 macro_build (NULL, "srl", SHFT_FMT, tempreg, op[0], 8);
13937 if (target_big_endian == ust)
13938 ep->X_add_number -= off;
13939 else
13940 ep->X_add_number += off;
13941 macro_build (ep, s2, "t,o(b)", tempreg, -1,
13942 offset_reloc[0], offset_reloc[1], offset_reloc[2], breg);
13944 /* For M_USH_A re-retrieve the LSB. */
13945 if (ust && large_offset)
13947 if (target_big_endian)
13948 ep->X_add_number += off;
13949 else
13950 ep->X_add_number -= off;
13951 macro_build (&expr1, "lbu", "t,o(b)", AT, -1,
13952 offset_reloc[0], offset_reloc[1], offset_reloc[2], AT);
13954 /* For ULH and M_USH_A OR the LSB in. */
13955 if (!ust || large_offset)
13957 tempreg = !large_offset ? AT : op[0];
13958 macro_build (NULL, "sll", SHFT_FMT, tempreg, tempreg, 8);
13959 macro_build (NULL, "or", "d,v,t", op[0], op[0], AT);
13961 break;
13963 default:
13964 /* FIXME: Check if this is one of the itbl macros, since they
13965 are added dynamically. */
13966 as_bad (_("macro %s not implemented yet"), ip->insn_mo->name);
13967 break;
13969 if (!mips_opts.at && used_at)
13970 as_bad (_("macro used $at after \".set noat\""));
13973 /* Implement macros in mips16 mode. */
13975 static void
13976 mips16_macro (struct mips_cl_insn *ip)
13978 const struct mips_operand_array *operands;
13979 int mask;
13980 int tmp;
13981 expressionS expr1;
13982 int dbl;
13983 const char *s, *s2, *s3;
13984 unsigned int op[MAX_OPERANDS];
13985 unsigned int i;
13987 mask = ip->insn_mo->mask;
13989 operands = insn_operands (ip);
13990 for (i = 0; i < MAX_OPERANDS; i++)
13991 if (operands->operand[i])
13992 op[i] = insn_extract_operand (ip, operands->operand[i]);
13993 else
13994 op[i] = -1;
13996 expr1.X_op = O_constant;
13997 expr1.X_op_symbol = NULL;
13998 expr1.X_add_symbol = NULL;
13999 expr1.X_add_number = 1;
14001 dbl = 0;
14003 switch (mask)
14005 default:
14006 abort ();
14008 case M_DDIV_3:
14009 dbl = 1;
14010 /* Fall through. */
14011 case M_DIV_3:
14012 s = "mflo";
14013 goto do_div3;
14014 case M_DREM_3:
14015 dbl = 1;
14016 /* Fall through. */
14017 case M_REM_3:
14018 s = "mfhi";
14019 do_div3:
14020 start_noreorder ();
14021 macro_build (NULL, dbl ? "ddiv" : "div", ".,x,y", op[1], op[2]);
14022 expr1.X_add_number = 2;
14023 macro_build (&expr1, "bnez", "x,p", op[2]);
14024 macro_build (NULL, "break", "6", 7);
14026 /* FIXME: The normal code checks for of -1 / -0x80000000 here,
14027 since that causes an overflow. We should do that as well,
14028 but I don't see how to do the comparisons without a temporary
14029 register. */
14030 end_noreorder ();
14031 macro_build (NULL, s, "x", op[0]);
14032 break;
14034 case M_DIVU_3:
14035 s = "divu";
14036 s2 = "mflo";
14037 goto do_divu3;
14038 case M_REMU_3:
14039 s = "divu";
14040 s2 = "mfhi";
14041 goto do_divu3;
14042 case M_DDIVU_3:
14043 s = "ddivu";
14044 s2 = "mflo";
14045 goto do_divu3;
14046 case M_DREMU_3:
14047 s = "ddivu";
14048 s2 = "mfhi";
14049 do_divu3:
14050 start_noreorder ();
14051 macro_build (NULL, s, ".,x,y", op[1], op[2]);
14052 expr1.X_add_number = 2;
14053 macro_build (&expr1, "bnez", "x,p", op[2]);
14054 macro_build (NULL, "break", "6", 7);
14055 end_noreorder ();
14056 macro_build (NULL, s2, "x", op[0]);
14057 break;
14059 case M_DMUL:
14060 dbl = 1;
14061 /* Fall through. */
14062 case M_MUL:
14063 macro_build (NULL, dbl ? "dmultu" : "multu", "x,y", op[1], op[2]);
14064 macro_build (NULL, "mflo", "x", op[0]);
14065 break;
14067 case M_DSUBU_I:
14068 dbl = 1;
14069 goto do_subu;
14070 case M_SUBU_I:
14071 do_subu:
14072 imm_expr.X_add_number = -imm_expr.X_add_number;
14073 macro_build (&imm_expr, dbl ? "daddiu" : "addiu", "y,x,F", op[0], op[1]);
14074 break;
14076 case M_SUBU_I_2:
14077 imm_expr.X_add_number = -imm_expr.X_add_number;
14078 macro_build (&imm_expr, "addiu", "x,k", op[0]);
14079 break;
14081 case M_DSUBU_I_2:
14082 imm_expr.X_add_number = -imm_expr.X_add_number;
14083 macro_build (&imm_expr, "daddiu", "y,j", op[0]);
14084 break;
14086 case M_BEQ:
14087 s = "cmp";
14088 s2 = "bteqz";
14089 goto do_branch;
14090 case M_BNE:
14091 s = "cmp";
14092 s2 = "btnez";
14093 goto do_branch;
14094 case M_BLT:
14095 s = "slt";
14096 s2 = "btnez";
14097 goto do_branch;
14098 case M_BLTU:
14099 s = "sltu";
14100 s2 = "btnez";
14101 goto do_branch;
14102 case M_BLE:
14103 s = "slt";
14104 s2 = "bteqz";
14105 goto do_reverse_branch;
14106 case M_BLEU:
14107 s = "sltu";
14108 s2 = "bteqz";
14109 goto do_reverse_branch;
14110 case M_BGE:
14111 s = "slt";
14112 s2 = "bteqz";
14113 goto do_branch;
14114 case M_BGEU:
14115 s = "sltu";
14116 s2 = "bteqz";
14117 goto do_branch;
14118 case M_BGT:
14119 s = "slt";
14120 s2 = "btnez";
14121 goto do_reverse_branch;
14122 case M_BGTU:
14123 s = "sltu";
14124 s2 = "btnez";
14126 do_reverse_branch:
14127 tmp = op[1];
14128 op[1] = op[0];
14129 op[0] = tmp;
14131 do_branch:
14132 macro_build (NULL, s, "x,y", op[0], op[1]);
14133 macro_build (&offset_expr, s2, "p");
14134 break;
14136 case M_BEQ_I:
14137 s = "cmpi";
14138 s2 = "bteqz";
14139 s3 = "x,U";
14140 goto do_branch_i;
14141 case M_BNE_I:
14142 s = "cmpi";
14143 s2 = "btnez";
14144 s3 = "x,U";
14145 goto do_branch_i;
14146 case M_BLT_I:
14147 s = "slti";
14148 s2 = "btnez";
14149 s3 = "x,8";
14150 goto do_branch_i;
14151 case M_BLTU_I:
14152 s = "sltiu";
14153 s2 = "btnez";
14154 s3 = "x,8";
14155 goto do_branch_i;
14156 case M_BLE_I:
14157 s = "slti";
14158 s2 = "btnez";
14159 s3 = "x,8";
14160 goto do_addone_branch_i;
14161 case M_BLEU_I:
14162 s = "sltiu";
14163 s2 = "btnez";
14164 s3 = "x,8";
14165 goto do_addone_branch_i;
14166 case M_BGE_I:
14167 s = "slti";
14168 s2 = "bteqz";
14169 s3 = "x,8";
14170 goto do_branch_i;
14171 case M_BGEU_I:
14172 s = "sltiu";
14173 s2 = "bteqz";
14174 s3 = "x,8";
14175 goto do_branch_i;
14176 case M_BGT_I:
14177 s = "slti";
14178 s2 = "bteqz";
14179 s3 = "x,8";
14180 goto do_addone_branch_i;
14181 case M_BGTU_I:
14182 s = "sltiu";
14183 s2 = "bteqz";
14184 s3 = "x,8";
14186 do_addone_branch_i:
14187 ++imm_expr.X_add_number;
14189 do_branch_i:
14190 macro_build (&imm_expr, s, s3, op[0]);
14191 macro_build (&offset_expr, s2, "p");
14192 break;
14194 case M_ABS:
14195 expr1.X_add_number = 0;
14196 macro_build (&expr1, "slti", "x,8", op[1]);
14197 if (op[0] != op[1])
14198 macro_build (NULL, "move", "y,X", op[0], mips16_to_32_reg_map[op[1]]);
14199 expr1.X_add_number = 2;
14200 macro_build (&expr1, "bteqz", "p");
14201 macro_build (NULL, "neg", "x,w", op[0], op[0]);
14202 break;
14206 /* Look up instruction [START, START + LENGTH) in HASH. Record any extra
14207 opcode bits in *OPCODE_EXTRA. */
14209 static struct mips_opcode *
14210 mips_lookup_insn (struct hash_control *hash, const char *start,
14211 ssize_t length, unsigned int *opcode_extra)
14213 char *name, *dot, *p;
14214 unsigned int mask, suffix;
14215 ssize_t opend;
14216 struct mips_opcode *insn;
14218 /* Make a copy of the instruction so that we can fiddle with it. */
14219 name = xstrndup (start, length);
14221 /* Look up the instruction as-is. */
14222 insn = (struct mips_opcode *) hash_find (hash, name);
14223 if (insn)
14224 goto end;
14226 dot = strchr (name, '.');
14227 if (dot && dot[1])
14229 /* Try to interpret the text after the dot as a VU0 channel suffix. */
14230 p = mips_parse_vu0_channels (dot + 1, &mask);
14231 if (*p == 0 && mask != 0)
14233 *dot = 0;
14234 insn = (struct mips_opcode *) hash_find (hash, name);
14235 *dot = '.';
14236 if (insn && (insn->pinfo2 & INSN2_VU0_CHANNEL_SUFFIX) != 0)
14238 *opcode_extra |= mask << mips_vu0_channel_mask.lsb;
14239 goto end;
14244 if (mips_opts.micromips)
14246 /* See if there's an instruction size override suffix,
14247 either `16' or `32', at the end of the mnemonic proper,
14248 that defines the operation, i.e. before the first `.'
14249 character if any. Strip it and retry. */
14250 opend = dot != NULL ? dot - name : length;
14251 if (opend >= 3 && name[opend - 2] == '1' && name[opend - 1] == '6')
14252 suffix = 2;
14253 else if (opend >= 2 && name[opend - 2] == '3' && name[opend - 1] == '2')
14254 suffix = 4;
14255 else
14256 suffix = 0;
14257 if (suffix)
14259 memmove (name + opend - 2, name + opend, length - opend + 1);
14260 insn = (struct mips_opcode *) hash_find (hash, name);
14261 if (insn)
14263 forced_insn_length = suffix;
14264 goto end;
14269 insn = NULL;
14270 end:
14271 free (name);
14272 return insn;
14275 /* Assemble an instruction into its binary format. If the instruction
14276 is a macro, set imm_expr and offset_expr to the values associated
14277 with "I" and "A" operands respectively. Otherwise store the value
14278 of the relocatable field (if any) in offset_expr. In both cases
14279 set offset_reloc to the relocation operators applied to offset_expr. */
14281 static void
14282 mips_ip (char *str, struct mips_cl_insn *insn)
14284 const struct mips_opcode *first, *past;
14285 struct hash_control *hash;
14286 char format;
14287 size_t end;
14288 struct mips_operand_token *tokens;
14289 unsigned int opcode_extra;
14291 if (mips_opts.micromips)
14293 hash = micromips_op_hash;
14294 past = &micromips_opcodes[bfd_micromips_num_opcodes];
14296 else
14298 hash = op_hash;
14299 past = &mips_opcodes[NUMOPCODES];
14301 forced_insn_length = 0;
14302 opcode_extra = 0;
14304 /* We first try to match an instruction up to a space or to the end. */
14305 for (end = 0; str[end] != '\0' && !ISSPACE (str[end]); end++)
14306 continue;
14308 first = mips_lookup_insn (hash, str, end, &opcode_extra);
14309 if (first == NULL)
14311 set_insn_error (0, _("unrecognized opcode"));
14312 return;
14315 if (strcmp (first->name, "li.s") == 0)
14316 format = 'f';
14317 else if (strcmp (first->name, "li.d") == 0)
14318 format = 'd';
14319 else
14320 format = 0;
14321 tokens = mips_parse_arguments (str + end, format);
14322 if (!tokens)
14323 return;
14325 if (!match_insns (insn, first, past, tokens, opcode_extra, FALSE)
14326 && !match_insns (insn, first, past, tokens, opcode_extra, TRUE))
14327 set_insn_error (0, _("invalid operands"));
14329 obstack_free (&mips_operand_tokens, tokens);
14332 /* As for mips_ip, but used when assembling MIPS16 code.
14333 Also set forced_insn_length to the resulting instruction size in
14334 bytes if the user explicitly requested a small or extended instruction. */
14336 static void
14337 mips16_ip (char *str, struct mips_cl_insn *insn)
14339 char *end, *s, c;
14340 struct mips_opcode *first;
14341 struct mips_operand_token *tokens;
14342 unsigned int l;
14344 for (s = str; *s != '\0' && *s != '.' && *s != ' '; ++s)
14346 end = s;
14347 c = *end;
14349 l = 0;
14350 switch (c)
14352 case '\0':
14353 break;
14355 case ' ':
14356 s++;
14357 break;
14359 case '.':
14360 s++;
14361 if (*s == 't')
14363 l = 2;
14364 s++;
14366 else if (*s == 'e')
14368 l = 4;
14369 s++;
14371 if (*s == '\0')
14372 break;
14373 else if (*s++ == ' ')
14374 break;
14375 set_insn_error (0, _("unrecognized opcode"));
14376 return;
14378 forced_insn_length = l;
14380 *end = 0;
14381 first = (struct mips_opcode *) hash_find (mips16_op_hash, str);
14382 *end = c;
14384 if (!first)
14386 set_insn_error (0, _("unrecognized opcode"));
14387 return;
14390 tokens = mips_parse_arguments (s, 0);
14391 if (!tokens)
14392 return;
14394 if (!match_mips16_insns (insn, first, tokens))
14395 set_insn_error (0, _("invalid operands"));
14397 obstack_free (&mips_operand_tokens, tokens);
14400 /* Marshal immediate value VAL for an extended MIPS16 instruction.
14401 NBITS is the number of significant bits in VAL. */
14403 static unsigned long
14404 mips16_immed_extend (offsetT val, unsigned int nbits)
14406 int extval;
14408 extval = 0;
14409 val &= (1U << nbits) - 1;
14410 if (nbits == 16 || nbits == 9)
14412 extval = ((val >> 11) & 0x1f) | (val & 0x7e0);
14413 val &= 0x1f;
14415 else if (nbits == 15)
14417 extval = ((val >> 11) & 0xf) | (val & 0x7f0);
14418 val &= 0xf;
14420 else if (nbits == 6)
14422 extval = ((val & 0x1f) << 6) | (val & 0x20);
14423 val = 0;
14425 return (extval << 16) | val;
14428 /* Like decode_mips16_operand, but require the operand to be defined and
14429 require it to be an integer. */
14431 static const struct mips_int_operand *
14432 mips16_immed_operand (int type, bfd_boolean extended_p)
14434 const struct mips_operand *operand;
14436 operand = decode_mips16_operand (type, extended_p);
14437 if (!operand || (operand->type != OP_INT && operand->type != OP_PCREL))
14438 abort ();
14439 return (const struct mips_int_operand *) operand;
14442 /* Return true if SVAL fits OPERAND. RELOC is as for mips16_immed. */
14444 static bfd_boolean
14445 mips16_immed_in_range_p (const struct mips_int_operand *operand,
14446 bfd_reloc_code_real_type reloc, offsetT sval)
14448 int min_val, max_val;
14450 min_val = mips_int_operand_min (operand);
14451 max_val = mips_int_operand_max (operand);
14452 if (reloc != BFD_RELOC_UNUSED)
14454 if (min_val < 0)
14455 sval = SEXT_16BIT (sval);
14456 else
14457 sval &= 0xffff;
14460 return (sval >= min_val
14461 && sval <= max_val
14462 && (sval & ((1 << operand->shift) - 1)) == 0);
14465 /* Install immediate value VAL into MIPS16 instruction *INSN,
14466 extending it if necessary. The instruction in *INSN may
14467 already be extended.
14469 RELOC is the relocation that produced VAL, or BFD_RELOC_UNUSED
14470 if none. In the former case, VAL is a 16-bit number with no
14471 defined signedness.
14473 TYPE is the type of the immediate field. USER_INSN_LENGTH
14474 is the length that the user requested, or 0 if none. */
14476 static void
14477 mips16_immed (const char *file, unsigned int line, int type,
14478 bfd_reloc_code_real_type reloc, offsetT val,
14479 unsigned int user_insn_length, unsigned long *insn)
14481 const struct mips_int_operand *operand;
14482 unsigned int uval, length;
14484 operand = mips16_immed_operand (type, FALSE);
14485 if (!mips16_immed_in_range_p (operand, reloc, val))
14487 /* We need an extended instruction. */
14488 if (user_insn_length == 2)
14489 as_bad_where (file, line, _("invalid unextended operand value"));
14490 else
14491 *insn |= MIPS16_EXTEND;
14493 else if (user_insn_length == 4)
14495 /* The operand doesn't force an unextended instruction to be extended.
14496 Warn if the user wanted an extended instruction anyway. */
14497 *insn |= MIPS16_EXTEND;
14498 as_warn_where (file, line,
14499 _("extended operand requested but not required"));
14502 length = mips16_opcode_length (*insn);
14503 if (length == 4)
14505 operand = mips16_immed_operand (type, TRUE);
14506 if (!mips16_immed_in_range_p (operand, reloc, val))
14507 as_bad_where (file, line,
14508 _("operand value out of range for instruction"));
14510 uval = ((unsigned int) val >> operand->shift) - operand->bias;
14511 if (length == 2 || operand->root.lsb != 0)
14512 *insn = mips_insert_operand (&operand->root, *insn, uval);
14513 else
14514 *insn |= mips16_immed_extend (uval, operand->root.size);
14517 struct percent_op_match
14519 const char *str;
14520 bfd_reloc_code_real_type reloc;
14523 static const struct percent_op_match mips_percent_op[] =
14525 {"%lo", BFD_RELOC_LO16},
14526 {"%call_hi", BFD_RELOC_MIPS_CALL_HI16},
14527 {"%call_lo", BFD_RELOC_MIPS_CALL_LO16},
14528 {"%call16", BFD_RELOC_MIPS_CALL16},
14529 {"%got_disp", BFD_RELOC_MIPS_GOT_DISP},
14530 {"%got_page", BFD_RELOC_MIPS_GOT_PAGE},
14531 {"%got_ofst", BFD_RELOC_MIPS_GOT_OFST},
14532 {"%got_hi", BFD_RELOC_MIPS_GOT_HI16},
14533 {"%got_lo", BFD_RELOC_MIPS_GOT_LO16},
14534 {"%got", BFD_RELOC_MIPS_GOT16},
14535 {"%gp_rel", BFD_RELOC_GPREL16},
14536 {"%gprel", BFD_RELOC_GPREL16},
14537 {"%half", BFD_RELOC_16},
14538 {"%highest", BFD_RELOC_MIPS_HIGHEST},
14539 {"%higher", BFD_RELOC_MIPS_HIGHER},
14540 {"%neg", BFD_RELOC_MIPS_SUB},
14541 {"%tlsgd", BFD_RELOC_MIPS_TLS_GD},
14542 {"%tlsldm", BFD_RELOC_MIPS_TLS_LDM},
14543 {"%dtprel_hi", BFD_RELOC_MIPS_TLS_DTPREL_HI16},
14544 {"%dtprel_lo", BFD_RELOC_MIPS_TLS_DTPREL_LO16},
14545 {"%tprel_hi", BFD_RELOC_MIPS_TLS_TPREL_HI16},
14546 {"%tprel_lo", BFD_RELOC_MIPS_TLS_TPREL_LO16},
14547 {"%gottprel", BFD_RELOC_MIPS_TLS_GOTTPREL},
14548 {"%hi", BFD_RELOC_HI16_S},
14549 {"%pcrel_hi", BFD_RELOC_HI16_S_PCREL},
14550 {"%pcrel_lo", BFD_RELOC_LO16_PCREL}
14553 static const struct percent_op_match mips16_percent_op[] =
14555 {"%lo", BFD_RELOC_MIPS16_LO16},
14556 {"%gp_rel", BFD_RELOC_MIPS16_GPREL},
14557 {"%gprel", BFD_RELOC_MIPS16_GPREL},
14558 {"%got", BFD_RELOC_MIPS16_GOT16},
14559 {"%call16", BFD_RELOC_MIPS16_CALL16},
14560 {"%hi", BFD_RELOC_MIPS16_HI16_S},
14561 {"%tlsgd", BFD_RELOC_MIPS16_TLS_GD},
14562 {"%tlsldm", BFD_RELOC_MIPS16_TLS_LDM},
14563 {"%dtprel_hi", BFD_RELOC_MIPS16_TLS_DTPREL_HI16},
14564 {"%dtprel_lo", BFD_RELOC_MIPS16_TLS_DTPREL_LO16},
14565 {"%tprel_hi", BFD_RELOC_MIPS16_TLS_TPREL_HI16},
14566 {"%tprel_lo", BFD_RELOC_MIPS16_TLS_TPREL_LO16},
14567 {"%gottprel", BFD_RELOC_MIPS16_TLS_GOTTPREL}
14571 /* Return true if *STR points to a relocation operator. When returning true,
14572 move *STR over the operator and store its relocation code in *RELOC.
14573 Leave both *STR and *RELOC alone when returning false. */
14575 static bfd_boolean
14576 parse_relocation (char **str, bfd_reloc_code_real_type *reloc)
14578 const struct percent_op_match *percent_op;
14579 size_t limit, i;
14581 if (mips_opts.mips16)
14583 percent_op = mips16_percent_op;
14584 limit = ARRAY_SIZE (mips16_percent_op);
14586 else
14588 percent_op = mips_percent_op;
14589 limit = ARRAY_SIZE (mips_percent_op);
14592 for (i = 0; i < limit; i++)
14593 if (strncasecmp (*str, percent_op[i].str, strlen (percent_op[i].str)) == 0)
14595 int len = strlen (percent_op[i].str);
14597 if (!ISSPACE ((*str)[len]) && (*str)[len] != '(')
14598 continue;
14600 *str += strlen (percent_op[i].str);
14601 *reloc = percent_op[i].reloc;
14603 /* Check whether the output BFD supports this relocation.
14604 If not, issue an error and fall back on something safe. */
14605 if (!bfd_reloc_type_lookup (stdoutput, percent_op[i].reloc))
14607 as_bad (_("relocation %s isn't supported by the current ABI"),
14608 percent_op[i].str);
14609 *reloc = BFD_RELOC_UNUSED;
14611 return TRUE;
14613 return FALSE;
14617 /* Parse string STR as a 16-bit relocatable operand. Store the
14618 expression in *EP and the relocations in the array starting
14619 at RELOC. Return the number of relocation operators used.
14621 On exit, EXPR_END points to the first character after the expression. */
14623 static size_t
14624 my_getSmallExpression (expressionS *ep, bfd_reloc_code_real_type *reloc,
14625 char *str)
14627 bfd_reloc_code_real_type reversed_reloc[3];
14628 size_t reloc_index, i;
14629 int crux_depth, str_depth;
14630 char *crux;
14632 /* Search for the start of the main expression, recoding relocations
14633 in REVERSED_RELOC. End the loop with CRUX pointing to the start
14634 of the main expression and with CRUX_DEPTH containing the number
14635 of open brackets at that point. */
14636 reloc_index = -1;
14637 str_depth = 0;
14640 reloc_index++;
14641 crux = str;
14642 crux_depth = str_depth;
14644 /* Skip over whitespace and brackets, keeping count of the number
14645 of brackets. */
14646 while (*str == ' ' || *str == '\t' || *str == '(')
14647 if (*str++ == '(')
14648 str_depth++;
14650 while (*str == '%'
14651 && reloc_index < (HAVE_NEWABI ? 3 : 1)
14652 && parse_relocation (&str, &reversed_reloc[reloc_index]));
14654 my_getExpression (ep, crux);
14655 str = expr_end;
14657 /* Match every open bracket. */
14658 while (crux_depth > 0 && (*str == ')' || *str == ' ' || *str == '\t'))
14659 if (*str++ == ')')
14660 crux_depth--;
14662 if (crux_depth > 0)
14663 as_bad (_("unclosed '('"));
14665 expr_end = str;
14667 if (reloc_index != 0)
14669 prev_reloc_op_frag = frag_now;
14670 for (i = 0; i < reloc_index; i++)
14671 reloc[i] = reversed_reloc[reloc_index - 1 - i];
14674 return reloc_index;
14677 static void
14678 my_getExpression (expressionS *ep, char *str)
14680 char *save_in;
14682 save_in = input_line_pointer;
14683 input_line_pointer = str;
14684 expression (ep);
14685 expr_end = input_line_pointer;
14686 input_line_pointer = save_in;
14689 const char *
14690 md_atof (int type, char *litP, int *sizeP)
14692 return ieee_md_atof (type, litP, sizeP, target_big_endian);
14695 void
14696 md_number_to_chars (char *buf, valueT val, int n)
14698 if (target_big_endian)
14699 number_to_chars_bigendian (buf, val, n);
14700 else
14701 number_to_chars_littleendian (buf, val, n);
14704 static int support_64bit_objects(void)
14706 const char **list, **l;
14707 int yes;
14709 list = bfd_target_list ();
14710 for (l = list; *l != NULL; l++)
14711 if (strcmp (*l, ELF_TARGET ("elf64-", "big")) == 0
14712 || strcmp (*l, ELF_TARGET ("elf64-", "little")) == 0)
14713 break;
14714 yes = (*l != NULL);
14715 free (list);
14716 return yes;
14719 /* Set STRING_PTR (either &mips_arch_string or &mips_tune_string) to
14720 NEW_VALUE. Warn if another value was already specified. Note:
14721 we have to defer parsing the -march and -mtune arguments in order
14722 to handle 'from-abi' correctly, since the ABI might be specified
14723 in a later argument. */
14725 static void
14726 mips_set_option_string (const char **string_ptr, const char *new_value)
14728 if (*string_ptr != 0 && strcasecmp (*string_ptr, new_value) != 0)
14729 as_warn (_("a different %s was already specified, is now %s"),
14730 string_ptr == &mips_arch_string ? "-march" : "-mtune",
14731 new_value);
14733 *string_ptr = new_value;
14737 md_parse_option (int c, const char *arg)
14739 unsigned int i;
14741 for (i = 0; i < ARRAY_SIZE (mips_ases); i++)
14742 if (c == mips_ases[i].option_on || c == mips_ases[i].option_off)
14744 file_ase_explicit |= mips_set_ase (&mips_ases[i], &file_mips_opts,
14745 c == mips_ases[i].option_on);
14746 return 1;
14749 switch (c)
14751 case OPTION_CONSTRUCT_FLOATS:
14752 mips_disable_float_construction = 0;
14753 break;
14755 case OPTION_NO_CONSTRUCT_FLOATS:
14756 mips_disable_float_construction = 1;
14757 break;
14759 case OPTION_TRAP:
14760 mips_trap = 1;
14761 break;
14763 case OPTION_BREAK:
14764 mips_trap = 0;
14765 break;
14767 case OPTION_EB:
14768 target_big_endian = 1;
14769 break;
14771 case OPTION_EL:
14772 target_big_endian = 0;
14773 break;
14775 case 'O':
14776 if (arg == NULL)
14777 mips_optimize = 1;
14778 else if (arg[0] == '0')
14779 mips_optimize = 0;
14780 else if (arg[0] == '1')
14781 mips_optimize = 1;
14782 else
14783 mips_optimize = 2;
14784 break;
14786 case 'g':
14787 if (arg == NULL)
14788 mips_debug = 2;
14789 else
14790 mips_debug = atoi (arg);
14791 break;
14793 case OPTION_MIPS1:
14794 file_mips_opts.isa = ISA_MIPS1;
14795 break;
14797 case OPTION_MIPS2:
14798 file_mips_opts.isa = ISA_MIPS2;
14799 break;
14801 case OPTION_MIPS3:
14802 file_mips_opts.isa = ISA_MIPS3;
14803 break;
14805 case OPTION_MIPS4:
14806 file_mips_opts.isa = ISA_MIPS4;
14807 break;
14809 case OPTION_MIPS5:
14810 file_mips_opts.isa = ISA_MIPS5;
14811 break;
14813 case OPTION_MIPS32:
14814 file_mips_opts.isa = ISA_MIPS32;
14815 break;
14817 case OPTION_MIPS32R2:
14818 file_mips_opts.isa = ISA_MIPS32R2;
14819 break;
14821 case OPTION_MIPS32R3:
14822 file_mips_opts.isa = ISA_MIPS32R3;
14823 break;
14825 case OPTION_MIPS32R5:
14826 file_mips_opts.isa = ISA_MIPS32R5;
14827 break;
14829 case OPTION_MIPS32R6:
14830 file_mips_opts.isa = ISA_MIPS32R6;
14831 break;
14833 case OPTION_MIPS64R2:
14834 file_mips_opts.isa = ISA_MIPS64R2;
14835 break;
14837 case OPTION_MIPS64R3:
14838 file_mips_opts.isa = ISA_MIPS64R3;
14839 break;
14841 case OPTION_MIPS64R5:
14842 file_mips_opts.isa = ISA_MIPS64R5;
14843 break;
14845 case OPTION_MIPS64R6:
14846 file_mips_opts.isa = ISA_MIPS64R6;
14847 break;
14849 case OPTION_MIPS64:
14850 file_mips_opts.isa = ISA_MIPS64;
14851 break;
14853 case OPTION_MTUNE:
14854 mips_set_option_string (&mips_tune_string, arg);
14855 break;
14857 case OPTION_MARCH:
14858 mips_set_option_string (&mips_arch_string, arg);
14859 break;
14861 case OPTION_M4650:
14862 mips_set_option_string (&mips_arch_string, "4650");
14863 mips_set_option_string (&mips_tune_string, "4650");
14864 break;
14866 case OPTION_NO_M4650:
14867 break;
14869 case OPTION_M4010:
14870 mips_set_option_string (&mips_arch_string, "4010");
14871 mips_set_option_string (&mips_tune_string, "4010");
14872 break;
14874 case OPTION_NO_M4010:
14875 break;
14877 case OPTION_M4100:
14878 mips_set_option_string (&mips_arch_string, "4100");
14879 mips_set_option_string (&mips_tune_string, "4100");
14880 break;
14882 case OPTION_NO_M4100:
14883 break;
14885 case OPTION_M3900:
14886 mips_set_option_string (&mips_arch_string, "3900");
14887 mips_set_option_string (&mips_tune_string, "3900");
14888 break;
14890 case OPTION_NO_M3900:
14891 break;
14893 case OPTION_MICROMIPS:
14894 if (file_mips_opts.mips16 == 1)
14896 as_bad (_("-mmicromips cannot be used with -mips16"));
14897 return 0;
14899 file_mips_opts.micromips = 1;
14900 mips_no_prev_insn ();
14901 break;
14903 case OPTION_NO_MICROMIPS:
14904 file_mips_opts.micromips = 0;
14905 mips_no_prev_insn ();
14906 break;
14908 case OPTION_MIPS16:
14909 if (file_mips_opts.micromips == 1)
14911 as_bad (_("-mips16 cannot be used with -micromips"));
14912 return 0;
14914 file_mips_opts.mips16 = 1;
14915 mips_no_prev_insn ();
14916 break;
14918 case OPTION_NO_MIPS16:
14919 file_mips_opts.mips16 = 0;
14920 mips_no_prev_insn ();
14921 break;
14923 case OPTION_FIX_24K:
14924 mips_fix_24k = 1;
14925 break;
14927 case OPTION_NO_FIX_24K:
14928 mips_fix_24k = 0;
14929 break;
14931 case OPTION_FIX_RM7000:
14932 mips_fix_rm7000 = 1;
14933 break;
14935 case OPTION_NO_FIX_RM7000:
14936 mips_fix_rm7000 = 0;
14937 break;
14939 case OPTION_FIX_LOONGSON3_LLSC:
14940 mips_fix_loongson3_llsc = TRUE;
14941 break;
14943 case OPTION_NO_FIX_LOONGSON3_LLSC:
14944 mips_fix_loongson3_llsc = FALSE;
14945 break;
14947 case OPTION_FIX_LOONGSON2F_JUMP:
14948 mips_fix_loongson2f_jump = TRUE;
14949 break;
14951 case OPTION_NO_FIX_LOONGSON2F_JUMP:
14952 mips_fix_loongson2f_jump = FALSE;
14953 break;
14955 case OPTION_FIX_LOONGSON2F_NOP:
14956 mips_fix_loongson2f_nop = TRUE;
14957 break;
14959 case OPTION_NO_FIX_LOONGSON2F_NOP:
14960 mips_fix_loongson2f_nop = FALSE;
14961 break;
14963 case OPTION_FIX_VR4120:
14964 mips_fix_vr4120 = 1;
14965 break;
14967 case OPTION_NO_FIX_VR4120:
14968 mips_fix_vr4120 = 0;
14969 break;
14971 case OPTION_FIX_VR4130:
14972 mips_fix_vr4130 = 1;
14973 break;
14975 case OPTION_NO_FIX_VR4130:
14976 mips_fix_vr4130 = 0;
14977 break;
14979 case OPTION_FIX_CN63XXP1:
14980 mips_fix_cn63xxp1 = TRUE;
14981 break;
14983 case OPTION_NO_FIX_CN63XXP1:
14984 mips_fix_cn63xxp1 = FALSE;
14985 break;
14987 case OPTION_FIX_R5900:
14988 mips_fix_r5900 = TRUE;
14989 mips_fix_r5900_explicit = TRUE;
14990 break;
14992 case OPTION_NO_FIX_R5900:
14993 mips_fix_r5900 = FALSE;
14994 mips_fix_r5900_explicit = TRUE;
14995 break;
14997 case OPTION_RELAX_BRANCH:
14998 mips_relax_branch = 1;
14999 break;
15001 case OPTION_NO_RELAX_BRANCH:
15002 mips_relax_branch = 0;
15003 break;
15005 case OPTION_IGNORE_BRANCH_ISA:
15006 mips_ignore_branch_isa = TRUE;
15007 break;
15009 case OPTION_NO_IGNORE_BRANCH_ISA:
15010 mips_ignore_branch_isa = FALSE;
15011 break;
15013 case OPTION_INSN32:
15014 file_mips_opts.insn32 = TRUE;
15015 break;
15017 case OPTION_NO_INSN32:
15018 file_mips_opts.insn32 = FALSE;
15019 break;
15021 case OPTION_MSHARED:
15022 mips_in_shared = TRUE;
15023 break;
15025 case OPTION_MNO_SHARED:
15026 mips_in_shared = FALSE;
15027 break;
15029 case OPTION_MSYM32:
15030 file_mips_opts.sym32 = TRUE;
15031 break;
15033 case OPTION_MNO_SYM32:
15034 file_mips_opts.sym32 = FALSE;
15035 break;
15037 /* When generating ELF code, we permit -KPIC and -call_shared to
15038 select SVR4_PIC, and -non_shared to select no PIC. This is
15039 intended to be compatible with Irix 5. */
15040 case OPTION_CALL_SHARED:
15041 mips_pic = SVR4_PIC;
15042 mips_abicalls = TRUE;
15043 break;
15045 case OPTION_CALL_NONPIC:
15046 mips_pic = NO_PIC;
15047 mips_abicalls = TRUE;
15048 break;
15050 case OPTION_NON_SHARED:
15051 mips_pic = NO_PIC;
15052 mips_abicalls = FALSE;
15053 break;
15055 /* The -xgot option tells the assembler to use 32 bit offsets
15056 when accessing the got in SVR4_PIC mode. It is for Irix
15057 compatibility. */
15058 case OPTION_XGOT:
15059 mips_big_got = 1;
15060 break;
15062 case 'G':
15063 g_switch_value = atoi (arg);
15064 g_switch_seen = 1;
15065 break;
15067 /* The -32, -n32 and -64 options are shortcuts for -mabi=32, -mabi=n32
15068 and -mabi=64. */
15069 case OPTION_32:
15070 mips_abi = O32_ABI;
15071 break;
15073 case OPTION_N32:
15074 mips_abi = N32_ABI;
15075 break;
15077 case OPTION_64:
15078 mips_abi = N64_ABI;
15079 if (!support_64bit_objects())
15080 as_fatal (_("no compiled in support for 64 bit object file format"));
15081 break;
15083 case OPTION_GP32:
15084 file_mips_opts.gp = 32;
15085 break;
15087 case OPTION_GP64:
15088 file_mips_opts.gp = 64;
15089 break;
15091 case OPTION_FP32:
15092 file_mips_opts.fp = 32;
15093 break;
15095 case OPTION_FPXX:
15096 file_mips_opts.fp = 0;
15097 break;
15099 case OPTION_FP64:
15100 file_mips_opts.fp = 64;
15101 break;
15103 case OPTION_ODD_SPREG:
15104 file_mips_opts.oddspreg = 1;
15105 break;
15107 case OPTION_NO_ODD_SPREG:
15108 file_mips_opts.oddspreg = 0;
15109 break;
15111 case OPTION_SINGLE_FLOAT:
15112 file_mips_opts.single_float = 1;
15113 break;
15115 case OPTION_DOUBLE_FLOAT:
15116 file_mips_opts.single_float = 0;
15117 break;
15119 case OPTION_SOFT_FLOAT:
15120 file_mips_opts.soft_float = 1;
15121 break;
15123 case OPTION_HARD_FLOAT:
15124 file_mips_opts.soft_float = 0;
15125 break;
15127 case OPTION_MABI:
15128 if (strcmp (arg, "32") == 0)
15129 mips_abi = O32_ABI;
15130 else if (strcmp (arg, "o64") == 0)
15131 mips_abi = O64_ABI;
15132 else if (strcmp (arg, "n32") == 0)
15133 mips_abi = N32_ABI;
15134 else if (strcmp (arg, "64") == 0)
15136 mips_abi = N64_ABI;
15137 if (! support_64bit_objects())
15138 as_fatal (_("no compiled in support for 64 bit object file "
15139 "format"));
15141 else if (strcmp (arg, "eabi") == 0)
15142 mips_abi = EABI_ABI;
15143 else
15145 as_fatal (_("invalid abi -mabi=%s"), arg);
15146 return 0;
15148 break;
15150 case OPTION_M7000_HILO_FIX:
15151 mips_7000_hilo_fix = TRUE;
15152 break;
15154 case OPTION_MNO_7000_HILO_FIX:
15155 mips_7000_hilo_fix = FALSE;
15156 break;
15158 case OPTION_MDEBUG:
15159 mips_flag_mdebug = TRUE;
15160 break;
15162 case OPTION_NO_MDEBUG:
15163 mips_flag_mdebug = FALSE;
15164 break;
15166 case OPTION_PDR:
15167 mips_flag_pdr = TRUE;
15168 break;
15170 case OPTION_NO_PDR:
15171 mips_flag_pdr = FALSE;
15172 break;
15174 case OPTION_MVXWORKS_PIC:
15175 mips_pic = VXWORKS_PIC;
15176 break;
15178 case OPTION_NAN:
15179 if (strcmp (arg, "2008") == 0)
15180 mips_nan2008 = 1;
15181 else if (strcmp (arg, "legacy") == 0)
15182 mips_nan2008 = 0;
15183 else
15185 as_fatal (_("invalid NaN setting -mnan=%s"), arg);
15186 return 0;
15188 break;
15190 default:
15191 return 0;
15194 mips_fix_loongson2f = mips_fix_loongson2f_nop || mips_fix_loongson2f_jump;
15196 return 1;
15199 /* Set up globals to tune for the ISA or processor described by INFO. */
15201 static void
15202 mips_set_tune (const struct mips_cpu_info *info)
15204 if (info != 0)
15205 mips_tune = info->cpu;
15209 void
15210 mips_after_parse_args (void)
15212 const struct mips_cpu_info *arch_info = 0;
15213 const struct mips_cpu_info *tune_info = 0;
15215 /* GP relative stuff not working for PE. */
15216 if (strncmp (TARGET_OS, "pe", 2) == 0)
15218 if (g_switch_seen && g_switch_value != 0)
15219 as_bad (_("-G not supported in this configuration"));
15220 g_switch_value = 0;
15223 if (mips_abi == NO_ABI)
15224 mips_abi = MIPS_DEFAULT_ABI;
15226 /* The following code determines the architecture.
15227 Similar code was added to GCC 3.3 (see override_options() in
15228 config/mips/mips.c). The GAS and GCC code should be kept in sync
15229 as much as possible. */
15231 if (mips_arch_string != 0)
15232 arch_info = mips_parse_cpu ("-march", mips_arch_string);
15234 if (file_mips_opts.isa != ISA_UNKNOWN)
15236 /* Handle -mipsN. At this point, file_mips_opts.isa contains the
15237 ISA level specified by -mipsN, while arch_info->isa contains
15238 the -march selection (if any). */
15239 if (arch_info != 0)
15241 /* -march takes precedence over -mipsN, since it is more descriptive.
15242 There's no harm in specifying both as long as the ISA levels
15243 are the same. */
15244 if (file_mips_opts.isa != arch_info->isa)
15245 as_bad (_("-%s conflicts with the other architecture options,"
15246 " which imply -%s"),
15247 mips_cpu_info_from_isa (file_mips_opts.isa)->name,
15248 mips_cpu_info_from_isa (arch_info->isa)->name);
15250 else
15251 arch_info = mips_cpu_info_from_isa (file_mips_opts.isa);
15254 if (arch_info == 0)
15256 arch_info = mips_parse_cpu ("default CPU", MIPS_CPU_STRING_DEFAULT);
15257 gas_assert (arch_info);
15260 if (ABI_NEEDS_64BIT_REGS (mips_abi) && !ISA_HAS_64BIT_REGS (arch_info->isa))
15261 as_bad (_("-march=%s is not compatible with the selected ABI"),
15262 arch_info->name);
15264 file_mips_opts.arch = arch_info->cpu;
15265 file_mips_opts.isa = arch_info->isa;
15266 file_mips_opts.init_ase = arch_info->ase;
15268 /* The EVA Extension has instructions which are only valid when the R6 ISA
15269 is enabled. This sets the ASE_EVA_R6 flag when both EVA and R6 ISA are
15270 present. */
15271 if (((file_mips_opts.ase & ASE_EVA) != 0) && ISA_IS_R6 (file_mips_opts.isa))
15272 file_mips_opts.ase |= ASE_EVA_R6;
15274 /* Set up initial mips_opts state. */
15275 mips_opts = file_mips_opts;
15277 /* For the R5900 default to `-mfix-r5900' unless the user told otherwise. */
15278 if (!mips_fix_r5900_explicit)
15279 mips_fix_r5900 = file_mips_opts.arch == CPU_R5900;
15281 /* The register size inference code is now placed in
15282 file_mips_check_options. */
15284 /* Optimize for file_mips_opts.arch, unless -mtune selects a different
15285 processor. */
15286 if (mips_tune_string != 0)
15287 tune_info = mips_parse_cpu ("-mtune", mips_tune_string);
15289 if (tune_info == 0)
15290 mips_set_tune (arch_info);
15291 else
15292 mips_set_tune (tune_info);
15294 if (mips_flag_mdebug < 0)
15295 mips_flag_mdebug = 0;
15298 void
15299 mips_init_after_args (void)
15301 /* Initialize opcodes. */
15302 bfd_mips_num_opcodes = bfd_mips_num_builtin_opcodes;
15303 mips_opcodes = (struct mips_opcode *) mips_builtin_opcodes;
15306 long
15307 md_pcrel_from (fixS *fixP)
15309 valueT addr = fixP->fx_where + fixP->fx_frag->fr_address;
15311 switch (fixP->fx_r_type)
15313 case BFD_RELOC_MICROMIPS_7_PCREL_S1:
15314 case BFD_RELOC_MICROMIPS_10_PCREL_S1:
15315 /* Return the address of the delay slot. */
15316 return addr + 2;
15318 case BFD_RELOC_MICROMIPS_16_PCREL_S1:
15319 case BFD_RELOC_MICROMIPS_JMP:
15320 case BFD_RELOC_MIPS16_16_PCREL_S1:
15321 case BFD_RELOC_16_PCREL_S2:
15322 case BFD_RELOC_MIPS_21_PCREL_S2:
15323 case BFD_RELOC_MIPS_26_PCREL_S2:
15324 case BFD_RELOC_MIPS_JMP:
15325 /* Return the address of the delay slot. */
15326 return addr + 4;
15328 case BFD_RELOC_MIPS_18_PCREL_S3:
15329 /* Return the aligned address of the doubleword containing
15330 the instruction. */
15331 return addr & ~7;
15333 default:
15334 return addr;
15338 /* This is called before the symbol table is processed. In order to
15339 work with gcc when using mips-tfile, we must keep all local labels.
15340 However, in other cases, we want to discard them. If we were
15341 called with -g, but we didn't see any debugging information, it may
15342 mean that gcc is smuggling debugging information through to
15343 mips-tfile, in which case we must generate all local labels. */
15345 void
15346 mips_frob_file_before_adjust (void)
15348 #ifndef NO_ECOFF_DEBUGGING
15349 if (ECOFF_DEBUGGING
15350 && mips_debug != 0
15351 && ! ecoff_debugging_seen)
15352 flag_keep_locals = 1;
15353 #endif
15356 /* Sort any unmatched HI16 and GOT16 relocs so that they immediately precede
15357 the corresponding LO16 reloc. This is called before md_apply_fix and
15358 tc_gen_reloc. Unmatched relocs can only be generated by use of explicit
15359 relocation operators.
15361 For our purposes, a %lo() expression matches a %got() or %hi()
15362 expression if:
15364 (a) it refers to the same symbol; and
15365 (b) the offset applied in the %lo() expression is no lower than
15366 the offset applied in the %got() or %hi().
15368 (b) allows us to cope with code like:
15370 lui $4,%hi(foo)
15371 lh $4,%lo(foo+2)($4)
15373 ...which is legal on RELA targets, and has a well-defined behaviour
15374 if the user knows that adding 2 to "foo" will not induce a carry to
15375 the high 16 bits.
15377 When several %lo()s match a particular %got() or %hi(), we use the
15378 following rules to distinguish them:
15380 (1) %lo()s with smaller offsets are a better match than %lo()s with
15381 higher offsets.
15383 (2) %lo()s with no matching %got() or %hi() are better than those
15384 that already have a matching %got() or %hi().
15386 (3) later %lo()s are better than earlier %lo()s.
15388 These rules are applied in order.
15390 (1) means, among other things, that %lo()s with identical offsets are
15391 chosen if they exist.
15393 (2) means that we won't associate several high-part relocations with
15394 the same low-part relocation unless there's no alternative. Having
15395 several high parts for the same low part is a GNU extension; this rule
15396 allows careful users to avoid it.
15398 (3) is purely cosmetic. mips_hi_fixup_list is is in reverse order,
15399 with the last high-part relocation being at the front of the list.
15400 It therefore makes sense to choose the last matching low-part
15401 relocation, all other things being equal. It's also easier
15402 to code that way. */
15404 void
15405 mips_frob_file (void)
15407 struct mips_hi_fixup *l;
15408 bfd_reloc_code_real_type looking_for_rtype = BFD_RELOC_UNUSED;
15410 for (l = mips_hi_fixup_list; l != NULL; l = l->next)
15412 segment_info_type *seginfo;
15413 bfd_boolean matched_lo_p;
15414 fixS **hi_pos, **lo_pos, **pos;
15416 gas_assert (reloc_needs_lo_p (l->fixp->fx_r_type));
15418 /* If a GOT16 relocation turns out to be against a global symbol,
15419 there isn't supposed to be a matching LO. Ignore %gots against
15420 constants; we'll report an error for those later. */
15421 if (got16_reloc_p (l->fixp->fx_r_type)
15422 && !(l->fixp->fx_addsy
15423 && pic_need_relax (l->fixp->fx_addsy)))
15424 continue;
15426 /* Check quickly whether the next fixup happens to be a matching %lo. */
15427 if (fixup_has_matching_lo_p (l->fixp))
15428 continue;
15430 seginfo = seg_info (l->seg);
15432 /* Set HI_POS to the position of this relocation in the chain.
15433 Set LO_POS to the position of the chosen low-part relocation.
15434 MATCHED_LO_P is true on entry to the loop if *POS is a low-part
15435 relocation that matches an immediately-preceding high-part
15436 relocation. */
15437 hi_pos = NULL;
15438 lo_pos = NULL;
15439 matched_lo_p = FALSE;
15440 looking_for_rtype = matching_lo_reloc (l->fixp->fx_r_type);
15442 for (pos = &seginfo->fix_root; *pos != NULL; pos = &(*pos)->fx_next)
15444 if (*pos == l->fixp)
15445 hi_pos = pos;
15447 if ((*pos)->fx_r_type == looking_for_rtype
15448 && symbol_same_p ((*pos)->fx_addsy, l->fixp->fx_addsy)
15449 && (*pos)->fx_offset >= l->fixp->fx_offset
15450 && (lo_pos == NULL
15451 || (*pos)->fx_offset < (*lo_pos)->fx_offset
15452 || (!matched_lo_p
15453 && (*pos)->fx_offset == (*lo_pos)->fx_offset)))
15454 lo_pos = pos;
15456 matched_lo_p = (reloc_needs_lo_p ((*pos)->fx_r_type)
15457 && fixup_has_matching_lo_p (*pos));
15460 /* If we found a match, remove the high-part relocation from its
15461 current position and insert it before the low-part relocation.
15462 Make the offsets match so that fixup_has_matching_lo_p()
15463 will return true.
15465 We don't warn about unmatched high-part relocations since some
15466 versions of gcc have been known to emit dead "lui ...%hi(...)"
15467 instructions. */
15468 if (lo_pos != NULL)
15470 l->fixp->fx_offset = (*lo_pos)->fx_offset;
15471 if (l->fixp->fx_next != *lo_pos)
15473 *hi_pos = l->fixp->fx_next;
15474 l->fixp->fx_next = *lo_pos;
15475 *lo_pos = l->fixp;
15482 mips_force_relocation (fixS *fixp)
15484 if (generic_force_reloc (fixp))
15485 return 1;
15487 /* We want to keep BFD_RELOC_MICROMIPS_*_PCREL_S1 relocation,
15488 so that the linker relaxation can update targets. */
15489 if (fixp->fx_r_type == BFD_RELOC_MICROMIPS_7_PCREL_S1
15490 || fixp->fx_r_type == BFD_RELOC_MICROMIPS_10_PCREL_S1
15491 || fixp->fx_r_type == BFD_RELOC_MICROMIPS_16_PCREL_S1)
15492 return 1;
15494 /* We want to keep BFD_RELOC_16_PCREL_S2 BFD_RELOC_MIPS_21_PCREL_S2
15495 and BFD_RELOC_MIPS_26_PCREL_S2 relocations against MIPS16 and
15496 microMIPS symbols so that we can do cross-mode branch diagnostics
15497 and BAL to JALX conversion by the linker. */
15498 if ((fixp->fx_r_type == BFD_RELOC_16_PCREL_S2
15499 || fixp->fx_r_type == BFD_RELOC_MIPS_21_PCREL_S2
15500 || fixp->fx_r_type == BFD_RELOC_MIPS_26_PCREL_S2)
15501 && fixp->fx_addsy
15502 && ELF_ST_IS_COMPRESSED (S_GET_OTHER (fixp->fx_addsy)))
15503 return 1;
15505 /* We want all PC-relative relocations to be kept for R6 relaxation. */
15506 if (ISA_IS_R6 (file_mips_opts.isa)
15507 && (fixp->fx_r_type == BFD_RELOC_16_PCREL_S2
15508 || fixp->fx_r_type == BFD_RELOC_MIPS_21_PCREL_S2
15509 || fixp->fx_r_type == BFD_RELOC_MIPS_26_PCREL_S2
15510 || fixp->fx_r_type == BFD_RELOC_MIPS_18_PCREL_S3
15511 || fixp->fx_r_type == BFD_RELOC_MIPS_19_PCREL_S2
15512 || fixp->fx_r_type == BFD_RELOC_HI16_S_PCREL
15513 || fixp->fx_r_type == BFD_RELOC_LO16_PCREL))
15514 return 1;
15516 return 0;
15519 /* Implement TC_FORCE_RELOCATION_ABS. */
15521 bfd_boolean
15522 mips_force_relocation_abs (fixS *fixp)
15524 if (generic_force_reloc (fixp))
15525 return TRUE;
15527 /* These relocations do not have enough bits in the in-place addend
15528 to hold an arbitrary absolute section's offset. */
15529 if (HAVE_IN_PLACE_ADDENDS && limited_pcrel_reloc_p (fixp->fx_r_type))
15530 return TRUE;
15532 return FALSE;
15535 /* Read the instruction associated with RELOC from BUF. */
15537 static unsigned int
15538 read_reloc_insn (char *buf, bfd_reloc_code_real_type reloc)
15540 if (mips16_reloc_p (reloc) || micromips_reloc_p (reloc))
15541 return read_compressed_insn (buf, 4);
15542 else
15543 return read_insn (buf);
15546 /* Write instruction INSN to BUF, given that it has been relocated
15547 by RELOC. */
15549 static void
15550 write_reloc_insn (char *buf, bfd_reloc_code_real_type reloc,
15551 unsigned long insn)
15553 if (mips16_reloc_p (reloc) || micromips_reloc_p (reloc))
15554 write_compressed_insn (buf, insn, 4);
15555 else
15556 write_insn (buf, insn);
15559 /* Return TRUE if the instruction pointed to by FIXP is an invalid jump
15560 to a symbol in another ISA mode, which cannot be converted to JALX. */
15562 static bfd_boolean
15563 fix_bad_cross_mode_jump_p (fixS *fixP)
15565 unsigned long opcode;
15566 int other;
15567 char *buf;
15569 if (!fixP->fx_addsy || S_FORCE_RELOC (fixP->fx_addsy, TRUE))
15570 return FALSE;
15572 other = S_GET_OTHER (fixP->fx_addsy);
15573 buf = fixP->fx_frag->fr_literal + fixP->fx_where;
15574 opcode = read_reloc_insn (buf, fixP->fx_r_type) >> 26;
15575 switch (fixP->fx_r_type)
15577 case BFD_RELOC_MIPS_JMP:
15578 return opcode != 0x1d && opcode != 0x03 && ELF_ST_IS_COMPRESSED (other);
15579 case BFD_RELOC_MICROMIPS_JMP:
15580 return opcode != 0x3c && opcode != 0x3d && !ELF_ST_IS_MICROMIPS (other);
15581 default:
15582 return FALSE;
15586 /* Return TRUE if the instruction pointed to by FIXP is an invalid JALX
15587 jump to a symbol in the same ISA mode. */
15589 static bfd_boolean
15590 fix_bad_same_mode_jalx_p (fixS *fixP)
15592 unsigned long opcode;
15593 int other;
15594 char *buf;
15596 if (!fixP->fx_addsy || S_FORCE_RELOC (fixP->fx_addsy, TRUE))
15597 return FALSE;
15599 other = S_GET_OTHER (fixP->fx_addsy);
15600 buf = fixP->fx_frag->fr_literal + fixP->fx_where;
15601 opcode = read_reloc_insn (buf, fixP->fx_r_type) >> 26;
15602 switch (fixP->fx_r_type)
15604 case BFD_RELOC_MIPS_JMP:
15605 return opcode == 0x1d && !ELF_ST_IS_COMPRESSED (other);
15606 case BFD_RELOC_MIPS16_JMP:
15607 return opcode == 0x07 && ELF_ST_IS_COMPRESSED (other);
15608 case BFD_RELOC_MICROMIPS_JMP:
15609 return opcode == 0x3c && ELF_ST_IS_COMPRESSED (other);
15610 default:
15611 return FALSE;
15615 /* Return TRUE if the instruction pointed to by FIXP is an invalid jump
15616 to a symbol whose value plus addend is not aligned according to the
15617 ultimate (after linker relaxation) jump instruction's immediate field
15618 requirement, either to (1 << SHIFT), or, for jumps from microMIPS to
15619 regular MIPS code, to (1 << 2). */
15621 static bfd_boolean
15622 fix_bad_misaligned_jump_p (fixS *fixP, int shift)
15624 bfd_boolean micro_to_mips_p;
15625 valueT val;
15626 int other;
15628 if (!fixP->fx_addsy || S_FORCE_RELOC (fixP->fx_addsy, TRUE))
15629 return FALSE;
15631 other = S_GET_OTHER (fixP->fx_addsy);
15632 val = S_GET_VALUE (fixP->fx_addsy) | ELF_ST_IS_COMPRESSED (other);
15633 val += fixP->fx_offset;
15634 micro_to_mips_p = (fixP->fx_r_type == BFD_RELOC_MICROMIPS_JMP
15635 && !ELF_ST_IS_MICROMIPS (other));
15636 return ((val & ((1 << (micro_to_mips_p ? 2 : shift)) - 1))
15637 != ELF_ST_IS_COMPRESSED (other));
15640 /* Return TRUE if the instruction pointed to by FIXP is an invalid branch
15641 to a symbol whose annotation indicates another ISA mode. For absolute
15642 symbols check the ISA bit instead.
15644 We accept BFD_RELOC_16_PCREL_S2 relocations against MIPS16 and microMIPS
15645 symbols or BFD_RELOC_MICROMIPS_16_PCREL_S1 relocations against regular
15646 MIPS symbols and associated with BAL instructions as these instructions
15647 may be converted to JALX by the linker. */
15649 static bfd_boolean
15650 fix_bad_cross_mode_branch_p (fixS *fixP)
15652 bfd_boolean absolute_p;
15653 unsigned long opcode;
15654 asection *symsec;
15655 valueT val;
15656 int other;
15657 char *buf;
15659 if (mips_ignore_branch_isa)
15660 return FALSE;
15662 if (!fixP->fx_addsy || S_FORCE_RELOC (fixP->fx_addsy, TRUE))
15663 return FALSE;
15665 symsec = S_GET_SEGMENT (fixP->fx_addsy);
15666 absolute_p = bfd_is_abs_section (symsec);
15668 val = S_GET_VALUE (fixP->fx_addsy) + fixP->fx_offset;
15669 other = S_GET_OTHER (fixP->fx_addsy);
15671 buf = fixP->fx_frag->fr_literal + fixP->fx_where;
15672 opcode = read_reloc_insn (buf, fixP->fx_r_type) >> 16;
15673 switch (fixP->fx_r_type)
15675 case BFD_RELOC_16_PCREL_S2:
15676 return ((absolute_p ? val & 1 : ELF_ST_IS_COMPRESSED (other))
15677 && opcode != 0x0411);
15678 case BFD_RELOC_MICROMIPS_16_PCREL_S1:
15679 return ((absolute_p ? !(val & 1) : !ELF_ST_IS_MICROMIPS (other))
15680 && opcode != 0x4060);
15681 case BFD_RELOC_MIPS_21_PCREL_S2:
15682 case BFD_RELOC_MIPS_26_PCREL_S2:
15683 return absolute_p ? val & 1 : ELF_ST_IS_COMPRESSED (other);
15684 case BFD_RELOC_MIPS16_16_PCREL_S1:
15685 return absolute_p ? !(val & 1) : !ELF_ST_IS_MIPS16 (other);
15686 case BFD_RELOC_MICROMIPS_7_PCREL_S1:
15687 case BFD_RELOC_MICROMIPS_10_PCREL_S1:
15688 return absolute_p ? !(val & 1) : !ELF_ST_IS_MICROMIPS (other);
15689 default:
15690 abort ();
15694 /* Return TRUE if the symbol plus addend associated with a regular MIPS
15695 branch instruction pointed to by FIXP is not aligned according to the
15696 branch instruction's immediate field requirement. We need the addend
15697 to preserve the ISA bit and also the sum must not have bit 2 set. We
15698 must explicitly OR in the ISA bit from symbol annotation as the bit
15699 won't be set in the symbol's value then. */
15701 static bfd_boolean
15702 fix_bad_misaligned_branch_p (fixS *fixP)
15704 bfd_boolean absolute_p;
15705 asection *symsec;
15706 valueT isa_bit;
15707 valueT val;
15708 valueT off;
15709 int other;
15711 if (!fixP->fx_addsy || S_FORCE_RELOC (fixP->fx_addsy, TRUE))
15712 return FALSE;
15714 symsec = S_GET_SEGMENT (fixP->fx_addsy);
15715 absolute_p = bfd_is_abs_section (symsec);
15717 val = S_GET_VALUE (fixP->fx_addsy);
15718 other = S_GET_OTHER (fixP->fx_addsy);
15719 off = fixP->fx_offset;
15721 isa_bit = absolute_p ? (val + off) & 1 : ELF_ST_IS_COMPRESSED (other);
15722 val |= ELF_ST_IS_COMPRESSED (other);
15723 val += off;
15724 return (val & 0x3) != isa_bit;
15727 /* Make the necessary checks on a regular MIPS branch pointed to by FIXP
15728 and its calculated value VAL. */
15730 static void
15731 fix_validate_branch (fixS *fixP, valueT val)
15733 if (fixP->fx_done && (val & 0x3) != 0)
15734 as_bad_where (fixP->fx_file, fixP->fx_line,
15735 _("branch to misaligned address (0x%lx)"),
15736 (long) (val + md_pcrel_from (fixP)));
15737 else if (fix_bad_cross_mode_branch_p (fixP))
15738 as_bad_where (fixP->fx_file, fixP->fx_line,
15739 _("branch to a symbol in another ISA mode"));
15740 else if (fix_bad_misaligned_branch_p (fixP))
15741 as_bad_where (fixP->fx_file, fixP->fx_line,
15742 _("branch to misaligned address (0x%lx)"),
15743 (long) (S_GET_VALUE (fixP->fx_addsy) + fixP->fx_offset));
15744 else if (HAVE_IN_PLACE_ADDENDS && (fixP->fx_offset & 0x3) != 0)
15745 as_bad_where (fixP->fx_file, fixP->fx_line,
15746 _("cannot encode misaligned addend "
15747 "in the relocatable field (0x%lx)"),
15748 (long) fixP->fx_offset);
15751 /* Apply a fixup to the object file. */
15753 void
15754 md_apply_fix (fixS *fixP, valueT *valP, segT seg ATTRIBUTE_UNUSED)
15756 char *buf;
15757 unsigned long insn;
15758 reloc_howto_type *howto;
15760 if (fixP->fx_pcrel)
15761 switch (fixP->fx_r_type)
15763 case BFD_RELOC_16_PCREL_S2:
15764 case BFD_RELOC_MIPS16_16_PCREL_S1:
15765 case BFD_RELOC_MICROMIPS_7_PCREL_S1:
15766 case BFD_RELOC_MICROMIPS_10_PCREL_S1:
15767 case BFD_RELOC_MICROMIPS_16_PCREL_S1:
15768 case BFD_RELOC_32_PCREL:
15769 case BFD_RELOC_MIPS_21_PCREL_S2:
15770 case BFD_RELOC_MIPS_26_PCREL_S2:
15771 case BFD_RELOC_MIPS_18_PCREL_S3:
15772 case BFD_RELOC_MIPS_19_PCREL_S2:
15773 case BFD_RELOC_HI16_S_PCREL:
15774 case BFD_RELOC_LO16_PCREL:
15775 break;
15777 case BFD_RELOC_32:
15778 fixP->fx_r_type = BFD_RELOC_32_PCREL;
15779 break;
15781 default:
15782 as_bad_where (fixP->fx_file, fixP->fx_line,
15783 _("PC-relative reference to a different section"));
15784 break;
15787 /* Handle BFD_RELOC_8, since it's easy. Punt on other bfd relocations
15788 that have no MIPS ELF equivalent. */
15789 if (fixP->fx_r_type != BFD_RELOC_8)
15791 howto = bfd_reloc_type_lookup (stdoutput, fixP->fx_r_type);
15792 if (!howto)
15793 return;
15796 gas_assert (fixP->fx_size == 2
15797 || fixP->fx_size == 4
15798 || fixP->fx_r_type == BFD_RELOC_8
15799 || fixP->fx_r_type == BFD_RELOC_16
15800 || fixP->fx_r_type == BFD_RELOC_64
15801 || fixP->fx_r_type == BFD_RELOC_CTOR
15802 || fixP->fx_r_type == BFD_RELOC_MIPS_SUB
15803 || fixP->fx_r_type == BFD_RELOC_MICROMIPS_SUB
15804 || fixP->fx_r_type == BFD_RELOC_VTABLE_INHERIT
15805 || fixP->fx_r_type == BFD_RELOC_VTABLE_ENTRY
15806 || fixP->fx_r_type == BFD_RELOC_MIPS_TLS_DTPREL64
15807 || fixP->fx_r_type == BFD_RELOC_NONE);
15809 buf = fixP->fx_frag->fr_literal + fixP->fx_where;
15811 /* Don't treat parts of a composite relocation as done. There are two
15812 reasons for this:
15814 (1) The second and third parts will be against 0 (RSS_UNDEF) but
15815 should nevertheless be emitted if the first part is.
15817 (2) In normal usage, composite relocations are never assembly-time
15818 constants. The easiest way of dealing with the pathological
15819 exceptions is to generate a relocation against STN_UNDEF and
15820 leave everything up to the linker. */
15821 if (fixP->fx_addsy == NULL && !fixP->fx_pcrel && fixP->fx_tcbit == 0)
15822 fixP->fx_done = 1;
15824 switch (fixP->fx_r_type)
15826 case BFD_RELOC_MIPS_TLS_GD:
15827 case BFD_RELOC_MIPS_TLS_LDM:
15828 case BFD_RELOC_MIPS_TLS_DTPREL32:
15829 case BFD_RELOC_MIPS_TLS_DTPREL64:
15830 case BFD_RELOC_MIPS_TLS_DTPREL_HI16:
15831 case BFD_RELOC_MIPS_TLS_DTPREL_LO16:
15832 case BFD_RELOC_MIPS_TLS_GOTTPREL:
15833 case BFD_RELOC_MIPS_TLS_TPREL32:
15834 case BFD_RELOC_MIPS_TLS_TPREL64:
15835 case BFD_RELOC_MIPS_TLS_TPREL_HI16:
15836 case BFD_RELOC_MIPS_TLS_TPREL_LO16:
15837 case BFD_RELOC_MICROMIPS_TLS_GD:
15838 case BFD_RELOC_MICROMIPS_TLS_LDM:
15839 case BFD_RELOC_MICROMIPS_TLS_DTPREL_HI16:
15840 case BFD_RELOC_MICROMIPS_TLS_DTPREL_LO16:
15841 case BFD_RELOC_MICROMIPS_TLS_GOTTPREL:
15842 case BFD_RELOC_MICROMIPS_TLS_TPREL_HI16:
15843 case BFD_RELOC_MICROMIPS_TLS_TPREL_LO16:
15844 case BFD_RELOC_MIPS16_TLS_GD:
15845 case BFD_RELOC_MIPS16_TLS_LDM:
15846 case BFD_RELOC_MIPS16_TLS_DTPREL_HI16:
15847 case BFD_RELOC_MIPS16_TLS_DTPREL_LO16:
15848 case BFD_RELOC_MIPS16_TLS_GOTTPREL:
15849 case BFD_RELOC_MIPS16_TLS_TPREL_HI16:
15850 case BFD_RELOC_MIPS16_TLS_TPREL_LO16:
15851 if (fixP->fx_addsy)
15852 S_SET_THREAD_LOCAL (fixP->fx_addsy);
15853 else
15854 as_bad_where (fixP->fx_file, fixP->fx_line,
15855 _("TLS relocation against a constant"));
15856 break;
15858 case BFD_RELOC_MIPS_JMP:
15859 case BFD_RELOC_MIPS16_JMP:
15860 case BFD_RELOC_MICROMIPS_JMP:
15862 int shift;
15864 gas_assert (!fixP->fx_done);
15866 /* Shift is 2, unusually, for microMIPS JALX. */
15867 if (fixP->fx_r_type == BFD_RELOC_MICROMIPS_JMP
15868 && (read_compressed_insn (buf, 4) >> 26) != 0x3c)
15869 shift = 1;
15870 else
15871 shift = 2;
15873 if (fix_bad_cross_mode_jump_p (fixP))
15874 as_bad_where (fixP->fx_file, fixP->fx_line,
15875 _("jump to a symbol in another ISA mode"));
15876 else if (fix_bad_same_mode_jalx_p (fixP))
15877 as_bad_where (fixP->fx_file, fixP->fx_line,
15878 _("JALX to a symbol in the same ISA mode"));
15879 else if (fix_bad_misaligned_jump_p (fixP, shift))
15880 as_bad_where (fixP->fx_file, fixP->fx_line,
15881 _("jump to misaligned address (0x%lx)"),
15882 (long) (S_GET_VALUE (fixP->fx_addsy)
15883 + fixP->fx_offset));
15884 else if (HAVE_IN_PLACE_ADDENDS
15885 && (fixP->fx_offset & ((1 << shift) - 1)) != 0)
15886 as_bad_where (fixP->fx_file, fixP->fx_line,
15887 _("cannot encode misaligned addend "
15888 "in the relocatable field (0x%lx)"),
15889 (long) fixP->fx_offset);
15891 /* Fall through. */
15893 case BFD_RELOC_MIPS_SHIFT5:
15894 case BFD_RELOC_MIPS_SHIFT6:
15895 case BFD_RELOC_MIPS_GOT_DISP:
15896 case BFD_RELOC_MIPS_GOT_PAGE:
15897 case BFD_RELOC_MIPS_GOT_OFST:
15898 case BFD_RELOC_MIPS_SUB:
15899 case BFD_RELOC_MIPS_INSERT_A:
15900 case BFD_RELOC_MIPS_INSERT_B:
15901 case BFD_RELOC_MIPS_DELETE:
15902 case BFD_RELOC_MIPS_HIGHEST:
15903 case BFD_RELOC_MIPS_HIGHER:
15904 case BFD_RELOC_MIPS_SCN_DISP:
15905 case BFD_RELOC_MIPS_REL16:
15906 case BFD_RELOC_MIPS_RELGOT:
15907 case BFD_RELOC_MIPS_JALR:
15908 case BFD_RELOC_HI16:
15909 case BFD_RELOC_HI16_S:
15910 case BFD_RELOC_LO16:
15911 case BFD_RELOC_GPREL16:
15912 case BFD_RELOC_MIPS_LITERAL:
15913 case BFD_RELOC_MIPS_CALL16:
15914 case BFD_RELOC_MIPS_GOT16:
15915 case BFD_RELOC_GPREL32:
15916 case BFD_RELOC_MIPS_GOT_HI16:
15917 case BFD_RELOC_MIPS_GOT_LO16:
15918 case BFD_RELOC_MIPS_CALL_HI16:
15919 case BFD_RELOC_MIPS_CALL_LO16:
15920 case BFD_RELOC_HI16_S_PCREL:
15921 case BFD_RELOC_LO16_PCREL:
15922 case BFD_RELOC_MIPS16_GPREL:
15923 case BFD_RELOC_MIPS16_GOT16:
15924 case BFD_RELOC_MIPS16_CALL16:
15925 case BFD_RELOC_MIPS16_HI16:
15926 case BFD_RELOC_MIPS16_HI16_S:
15927 case BFD_RELOC_MIPS16_LO16:
15928 case BFD_RELOC_MICROMIPS_GOT_DISP:
15929 case BFD_RELOC_MICROMIPS_GOT_PAGE:
15930 case BFD_RELOC_MICROMIPS_GOT_OFST:
15931 case BFD_RELOC_MICROMIPS_SUB:
15932 case BFD_RELOC_MICROMIPS_HIGHEST:
15933 case BFD_RELOC_MICROMIPS_HIGHER:
15934 case BFD_RELOC_MICROMIPS_SCN_DISP:
15935 case BFD_RELOC_MICROMIPS_JALR:
15936 case BFD_RELOC_MICROMIPS_HI16:
15937 case BFD_RELOC_MICROMIPS_HI16_S:
15938 case BFD_RELOC_MICROMIPS_LO16:
15939 case BFD_RELOC_MICROMIPS_GPREL16:
15940 case BFD_RELOC_MICROMIPS_LITERAL:
15941 case BFD_RELOC_MICROMIPS_CALL16:
15942 case BFD_RELOC_MICROMIPS_GOT16:
15943 case BFD_RELOC_MICROMIPS_GOT_HI16:
15944 case BFD_RELOC_MICROMIPS_GOT_LO16:
15945 case BFD_RELOC_MICROMIPS_CALL_HI16:
15946 case BFD_RELOC_MICROMIPS_CALL_LO16:
15947 case BFD_RELOC_MIPS_EH:
15948 if (fixP->fx_done)
15950 offsetT value;
15952 if (calculate_reloc (fixP->fx_r_type, *valP, &value))
15954 insn = read_reloc_insn (buf, fixP->fx_r_type);
15955 if (mips16_reloc_p (fixP->fx_r_type))
15956 insn |= mips16_immed_extend (value, 16);
15957 else
15958 insn |= (value & 0xffff);
15959 write_reloc_insn (buf, fixP->fx_r_type, insn);
15961 else
15962 as_bad_where (fixP->fx_file, fixP->fx_line,
15963 _("unsupported constant in relocation"));
15965 break;
15967 case BFD_RELOC_64:
15968 /* This is handled like BFD_RELOC_32, but we output a sign
15969 extended value if we are only 32 bits. */
15970 if (fixP->fx_done)
15972 if (8 <= sizeof (valueT))
15973 md_number_to_chars (buf, *valP, 8);
15974 else
15976 valueT hiv;
15978 if ((*valP & 0x80000000) != 0)
15979 hiv = 0xffffffff;
15980 else
15981 hiv = 0;
15982 md_number_to_chars (buf + (target_big_endian ? 4 : 0), *valP, 4);
15983 md_number_to_chars (buf + (target_big_endian ? 0 : 4), hiv, 4);
15986 break;
15988 case BFD_RELOC_RVA:
15989 case BFD_RELOC_32:
15990 case BFD_RELOC_32_PCREL:
15991 case BFD_RELOC_16:
15992 case BFD_RELOC_8:
15993 /* If we are deleting this reloc entry, we must fill in the
15994 value now. This can happen if we have a .word which is not
15995 resolved when it appears but is later defined. */
15996 if (fixP->fx_done)
15997 md_number_to_chars (buf, *valP, fixP->fx_size);
15998 break;
16000 case BFD_RELOC_MIPS_21_PCREL_S2:
16001 fix_validate_branch (fixP, *valP);
16002 if (!fixP->fx_done)
16003 break;
16005 if (*valP + 0x400000 <= 0x7fffff)
16007 insn = read_insn (buf);
16008 insn |= (*valP >> 2) & 0x1fffff;
16009 write_insn (buf, insn);
16011 else
16012 as_bad_where (fixP->fx_file, fixP->fx_line,
16013 _("branch out of range"));
16014 break;
16016 case BFD_RELOC_MIPS_26_PCREL_S2:
16017 fix_validate_branch (fixP, *valP);
16018 if (!fixP->fx_done)
16019 break;
16021 if (*valP + 0x8000000 <= 0xfffffff)
16023 insn = read_insn (buf);
16024 insn |= (*valP >> 2) & 0x3ffffff;
16025 write_insn (buf, insn);
16027 else
16028 as_bad_where (fixP->fx_file, fixP->fx_line,
16029 _("branch out of range"));
16030 break;
16032 case BFD_RELOC_MIPS_18_PCREL_S3:
16033 if (fixP->fx_addsy && (S_GET_VALUE (fixP->fx_addsy) & 0x7) != 0)
16034 as_bad_where (fixP->fx_file, fixP->fx_line,
16035 _("PC-relative access using misaligned symbol (%lx)"),
16036 (long) S_GET_VALUE (fixP->fx_addsy));
16037 if ((fixP->fx_offset & 0x7) != 0)
16038 as_bad_where (fixP->fx_file, fixP->fx_line,
16039 _("PC-relative access using misaligned offset (%lx)"),
16040 (long) fixP->fx_offset);
16041 if (!fixP->fx_done)
16042 break;
16044 if (*valP + 0x100000 <= 0x1fffff)
16046 insn = read_insn (buf);
16047 insn |= (*valP >> 3) & 0x3ffff;
16048 write_insn (buf, insn);
16050 else
16051 as_bad_where (fixP->fx_file, fixP->fx_line,
16052 _("PC-relative access out of range"));
16053 break;
16055 case BFD_RELOC_MIPS_19_PCREL_S2:
16056 if ((*valP & 0x3) != 0)
16057 as_bad_where (fixP->fx_file, fixP->fx_line,
16058 _("PC-relative access to misaligned address (%lx)"),
16059 (long) *valP);
16060 if (!fixP->fx_done)
16061 break;
16063 if (*valP + 0x100000 <= 0x1fffff)
16065 insn = read_insn (buf);
16066 insn |= (*valP >> 2) & 0x7ffff;
16067 write_insn (buf, insn);
16069 else
16070 as_bad_where (fixP->fx_file, fixP->fx_line,
16071 _("PC-relative access out of range"));
16072 break;
16074 case BFD_RELOC_16_PCREL_S2:
16075 fix_validate_branch (fixP, *valP);
16077 /* We need to save the bits in the instruction since fixup_segment()
16078 might be deleting the relocation entry (i.e., a branch within
16079 the current segment). */
16080 if (! fixP->fx_done)
16081 break;
16083 /* Update old instruction data. */
16084 insn = read_insn (buf);
16086 if (*valP + 0x20000 <= 0x3ffff)
16088 insn |= (*valP >> 2) & 0xffff;
16089 write_insn (buf, insn);
16091 else if (fixP->fx_tcbit2
16092 && fixP->fx_done
16093 && fixP->fx_frag->fr_address >= text_section->vma
16094 && (fixP->fx_frag->fr_address
16095 < text_section->vma + bfd_get_section_size (text_section))
16096 && ((insn & 0xffff0000) == 0x10000000 /* beq $0,$0 */
16097 || (insn & 0xffff0000) == 0x04010000 /* bgez $0 */
16098 || (insn & 0xffff0000) == 0x04110000)) /* bgezal $0 */
16100 /* The branch offset is too large. If this is an
16101 unconditional branch, and we are not generating PIC code,
16102 we can convert it to an absolute jump instruction. */
16103 if ((insn & 0xffff0000) == 0x04110000) /* bgezal $0 */
16104 insn = 0x0c000000; /* jal */
16105 else
16106 insn = 0x08000000; /* j */
16107 fixP->fx_r_type = BFD_RELOC_MIPS_JMP;
16108 fixP->fx_done = 0;
16109 fixP->fx_addsy = section_symbol (text_section);
16110 *valP += md_pcrel_from (fixP);
16111 write_insn (buf, insn);
16113 else
16115 /* If we got here, we have branch-relaxation disabled,
16116 and there's nothing we can do to fix this instruction
16117 without turning it into a longer sequence. */
16118 as_bad_where (fixP->fx_file, fixP->fx_line,
16119 _("branch out of range"));
16121 break;
16123 case BFD_RELOC_MIPS16_16_PCREL_S1:
16124 case BFD_RELOC_MICROMIPS_7_PCREL_S1:
16125 case BFD_RELOC_MICROMIPS_10_PCREL_S1:
16126 case BFD_RELOC_MICROMIPS_16_PCREL_S1:
16127 gas_assert (!fixP->fx_done);
16128 if (fix_bad_cross_mode_branch_p (fixP))
16129 as_bad_where (fixP->fx_file, fixP->fx_line,
16130 _("branch to a symbol in another ISA mode"));
16131 else if (fixP->fx_addsy
16132 && !S_FORCE_RELOC (fixP->fx_addsy, TRUE)
16133 && !bfd_is_abs_section (S_GET_SEGMENT (fixP->fx_addsy))
16134 && (fixP->fx_offset & 0x1) != 0)
16135 as_bad_where (fixP->fx_file, fixP->fx_line,
16136 _("branch to misaligned address (0x%lx)"),
16137 (long) (S_GET_VALUE (fixP->fx_addsy) + fixP->fx_offset));
16138 else if (HAVE_IN_PLACE_ADDENDS && (fixP->fx_offset & 0x1) != 0)
16139 as_bad_where (fixP->fx_file, fixP->fx_line,
16140 _("cannot encode misaligned addend "
16141 "in the relocatable field (0x%lx)"),
16142 (long) fixP->fx_offset);
16143 break;
16145 case BFD_RELOC_VTABLE_INHERIT:
16146 fixP->fx_done = 0;
16147 if (fixP->fx_addsy
16148 && !S_IS_DEFINED (fixP->fx_addsy)
16149 && !S_IS_WEAK (fixP->fx_addsy))
16150 S_SET_WEAK (fixP->fx_addsy);
16151 break;
16153 case BFD_RELOC_NONE:
16154 case BFD_RELOC_VTABLE_ENTRY:
16155 fixP->fx_done = 0;
16156 break;
16158 default:
16159 abort ();
16162 /* Remember value for tc_gen_reloc. */
16163 fixP->fx_addnumber = *valP;
16166 static symbolS *
16167 get_symbol (void)
16169 int c;
16170 char *name;
16171 symbolS *p;
16173 c = get_symbol_name (&name);
16174 p = (symbolS *) symbol_find_or_make (name);
16175 (void) restore_line_pointer (c);
16176 return p;
16179 /* Align the current frag to a given power of two. If a particular
16180 fill byte should be used, FILL points to an integer that contains
16181 that byte, otherwise FILL is null.
16183 This function used to have the comment:
16185 The MIPS assembler also automatically adjusts any preceding label.
16187 The implementation therefore applied the adjustment to a maximum of
16188 one label. However, other label adjustments are applied to batches
16189 of labels, and adjusting just one caused problems when new labels
16190 were added for the sake of debugging or unwind information.
16191 We therefore adjust all preceding labels (given as LABELS) instead. */
16193 static void
16194 mips_align (int to, int *fill, struct insn_label_list *labels)
16196 mips_emit_delays ();
16197 mips_record_compressed_mode ();
16198 if (fill == NULL && subseg_text_p (now_seg))
16199 frag_align_code (to, 0);
16200 else
16201 frag_align (to, fill ? *fill : 0, 0);
16202 record_alignment (now_seg, to);
16203 mips_move_labels (labels, FALSE);
16206 /* Align to a given power of two. .align 0 turns off the automatic
16207 alignment used by the data creating pseudo-ops. */
16209 static void
16210 s_align (int x ATTRIBUTE_UNUSED)
16212 int temp, fill_value, *fill_ptr;
16213 long max_alignment = 28;
16215 /* o Note that the assembler pulls down any immediately preceding label
16216 to the aligned address.
16217 o It's not documented but auto alignment is reinstated by
16218 a .align pseudo instruction.
16219 o Note also that after auto alignment is turned off the mips assembler
16220 issues an error on attempt to assemble an improperly aligned data item.
16221 We don't. */
16223 temp = get_absolute_expression ();
16224 if (temp > max_alignment)
16225 as_bad (_("alignment too large, %d assumed"), temp = max_alignment);
16226 else if (temp < 0)
16228 as_warn (_("alignment negative, 0 assumed"));
16229 temp = 0;
16231 if (*input_line_pointer == ',')
16233 ++input_line_pointer;
16234 fill_value = get_absolute_expression ();
16235 fill_ptr = &fill_value;
16237 else
16238 fill_ptr = 0;
16239 if (temp)
16241 segment_info_type *si = seg_info (now_seg);
16242 struct insn_label_list *l = si->label_list;
16243 /* Auto alignment should be switched on by next section change. */
16244 auto_align = 1;
16245 mips_align (temp, fill_ptr, l);
16247 else
16249 auto_align = 0;
16252 demand_empty_rest_of_line ();
16255 static void
16256 s_change_sec (int sec)
16258 segT seg;
16260 /* The ELF backend needs to know that we are changing sections, so
16261 that .previous works correctly. We could do something like check
16262 for an obj_section_change_hook macro, but that might be confusing
16263 as it would not be appropriate to use it in the section changing
16264 functions in read.c, since obj-elf.c intercepts those. FIXME:
16265 This should be cleaner, somehow. */
16266 obj_elf_section_change_hook ();
16268 mips_emit_delays ();
16270 switch (sec)
16272 case 't':
16273 s_text (0);
16274 break;
16275 case 'd':
16276 s_data (0);
16277 break;
16278 case 'b':
16279 subseg_set (bss_section, (subsegT) get_absolute_expression ());
16280 demand_empty_rest_of_line ();
16281 break;
16283 case 'r':
16284 seg = subseg_new (RDATA_SECTION_NAME,
16285 (subsegT) get_absolute_expression ());
16286 bfd_set_section_flags (stdoutput, seg, (SEC_ALLOC | SEC_LOAD
16287 | SEC_READONLY | SEC_RELOC
16288 | SEC_DATA));
16289 if (strncmp (TARGET_OS, "elf", 3) != 0)
16290 record_alignment (seg, 4);
16291 demand_empty_rest_of_line ();
16292 break;
16294 case 's':
16295 seg = subseg_new (".sdata", (subsegT) get_absolute_expression ());
16296 bfd_set_section_flags (stdoutput, seg,
16297 SEC_ALLOC | SEC_LOAD | SEC_RELOC | SEC_DATA);
16298 if (strncmp (TARGET_OS, "elf", 3) != 0)
16299 record_alignment (seg, 4);
16300 demand_empty_rest_of_line ();
16301 break;
16303 case 'B':
16304 seg = subseg_new (".sbss", (subsegT) get_absolute_expression ());
16305 bfd_set_section_flags (stdoutput, seg, SEC_ALLOC);
16306 if (strncmp (TARGET_OS, "elf", 3) != 0)
16307 record_alignment (seg, 4);
16308 demand_empty_rest_of_line ();
16309 break;
16312 auto_align = 1;
16315 void
16316 s_change_section (int ignore ATTRIBUTE_UNUSED)
16318 char *saved_ilp;
16319 char *section_name;
16320 char c, endc;
16321 char next_c = 0;
16322 int section_type;
16323 int section_flag;
16324 int section_entry_size;
16325 int section_alignment;
16327 saved_ilp = input_line_pointer;
16328 endc = get_symbol_name (&section_name);
16329 c = (endc == '"' ? input_line_pointer[1] : endc);
16330 if (c)
16331 next_c = input_line_pointer [(endc == '"' ? 2 : 1)];
16333 /* Do we have .section Name<,"flags">? */
16334 if (c != ',' || (c == ',' && next_c == '"'))
16336 /* Just after name is now '\0'. */
16337 (void) restore_line_pointer (endc);
16338 input_line_pointer = saved_ilp;
16339 obj_elf_section (ignore);
16340 return;
16343 section_name = xstrdup (section_name);
16344 c = restore_line_pointer (endc);
16346 input_line_pointer++;
16348 /* Do we have .section Name<,type><,flag><,entry_size><,alignment> */
16349 if (c == ',')
16350 section_type = get_absolute_expression ();
16351 else
16352 section_type = 0;
16354 if (*input_line_pointer++ == ',')
16355 section_flag = get_absolute_expression ();
16356 else
16357 section_flag = 0;
16359 if (*input_line_pointer++ == ',')
16360 section_entry_size = get_absolute_expression ();
16361 else
16362 section_entry_size = 0;
16364 if (*input_line_pointer++ == ',')
16365 section_alignment = get_absolute_expression ();
16366 else
16367 section_alignment = 0;
16369 /* FIXME: really ignore? */
16370 (void) section_alignment;
16372 /* When using the generic form of .section (as implemented by obj-elf.c),
16373 there's no way to set the section type to SHT_MIPS_DWARF. Users have
16374 traditionally had to fall back on the more common @progbits instead.
16376 There's nothing really harmful in this, since bfd will correct
16377 SHT_PROGBITS to SHT_MIPS_DWARF before writing out the file. But it
16378 means that, for backwards compatibility, the special_section entries
16379 for dwarf sections must use SHT_PROGBITS rather than SHT_MIPS_DWARF.
16381 Even so, we shouldn't force users of the MIPS .section syntax to
16382 incorrectly label the sections as SHT_PROGBITS. The best compromise
16383 seems to be to map SHT_MIPS_DWARF to SHT_PROGBITS before calling the
16384 generic type-checking code. */
16385 if (section_type == SHT_MIPS_DWARF)
16386 section_type = SHT_PROGBITS;
16388 obj_elf_change_section (section_name, section_type, 0, section_flag,
16389 section_entry_size, 0, 0, 0);
16391 if (now_seg->name != section_name)
16392 free (section_name);
16395 void
16396 mips_enable_auto_align (void)
16398 auto_align = 1;
16401 static void
16402 s_cons (int log_size)
16404 segment_info_type *si = seg_info (now_seg);
16405 struct insn_label_list *l = si->label_list;
16407 mips_emit_delays ();
16408 if (log_size > 0 && auto_align)
16409 mips_align (log_size, 0, l);
16410 cons (1 << log_size);
16411 mips_clear_insn_labels ();
16414 static void
16415 s_float_cons (int type)
16417 segment_info_type *si = seg_info (now_seg);
16418 struct insn_label_list *l = si->label_list;
16420 mips_emit_delays ();
16422 if (auto_align)
16424 if (type == 'd')
16425 mips_align (3, 0, l);
16426 else
16427 mips_align (2, 0, l);
16430 float_cons (type);
16431 mips_clear_insn_labels ();
16434 /* Handle .globl. We need to override it because on Irix 5 you are
16435 permitted to say
16436 .globl foo .text
16437 where foo is an undefined symbol, to mean that foo should be
16438 considered to be the address of a function. */
16440 static void
16441 s_mips_globl (int x ATTRIBUTE_UNUSED)
16443 char *name;
16444 int c;
16445 symbolS *symbolP;
16446 flagword flag;
16450 c = get_symbol_name (&name);
16451 symbolP = symbol_find_or_make (name);
16452 S_SET_EXTERNAL (symbolP);
16454 *input_line_pointer = c;
16455 SKIP_WHITESPACE_AFTER_NAME ();
16457 /* On Irix 5, every global symbol that is not explicitly labelled as
16458 being a function is apparently labelled as being an object. */
16459 flag = BSF_OBJECT;
16461 if (!is_end_of_line[(unsigned char) *input_line_pointer]
16462 && (*input_line_pointer != ','))
16464 char *secname;
16465 asection *sec;
16467 c = get_symbol_name (&secname);
16468 sec = bfd_get_section_by_name (stdoutput, secname);
16469 if (sec == NULL)
16470 as_bad (_("%s: no such section"), secname);
16471 (void) restore_line_pointer (c);
16473 if (sec != NULL && (sec->flags & SEC_CODE) != 0)
16474 flag = BSF_FUNCTION;
16477 symbol_get_bfdsym (symbolP)->flags |= flag;
16479 c = *input_line_pointer;
16480 if (c == ',')
16482 input_line_pointer++;
16483 SKIP_WHITESPACE ();
16484 if (is_end_of_line[(unsigned char) *input_line_pointer])
16485 c = '\n';
16488 while (c == ',');
16490 demand_empty_rest_of_line ();
16493 static void
16494 s_option (int x ATTRIBUTE_UNUSED)
16496 char *opt;
16497 char c;
16499 c = get_symbol_name (&opt);
16501 if (*opt == 'O')
16503 /* FIXME: What does this mean? */
16505 else if (strncmp (opt, "pic", 3) == 0 && ISDIGIT (opt[3]) && opt[4] == '\0')
16507 int i;
16509 i = atoi (opt + 3);
16510 if (i != 0 && i != 2)
16511 as_bad (_(".option pic%d not supported"), i);
16512 else if (mips_pic == VXWORKS_PIC)
16513 as_bad (_(".option pic%d not supported in VxWorks PIC mode"), i);
16514 else if (i == 0)
16515 mips_pic = NO_PIC;
16516 else if (i == 2)
16518 mips_pic = SVR4_PIC;
16519 mips_abicalls = TRUE;
16522 if (mips_pic == SVR4_PIC)
16524 if (g_switch_seen && g_switch_value != 0)
16525 as_warn (_("-G may not be used with SVR4 PIC code"));
16526 g_switch_value = 0;
16527 bfd_set_gp_size (stdoutput, 0);
16530 else
16531 as_warn (_("unrecognized option \"%s\""), opt);
16533 (void) restore_line_pointer (c);
16534 demand_empty_rest_of_line ();
16537 /* This structure is used to hold a stack of .set values. */
16539 struct mips_option_stack
16541 struct mips_option_stack *next;
16542 struct mips_set_options options;
16545 static struct mips_option_stack *mips_opts_stack;
16547 /* Return status for .set/.module option handling. */
16549 enum code_option_type
16551 /* Unrecognized option. */
16552 OPTION_TYPE_BAD = -1,
16554 /* Ordinary option. */
16555 OPTION_TYPE_NORMAL,
16557 /* ISA changing option. */
16558 OPTION_TYPE_ISA
16561 /* Handle common .set/.module options. Return status indicating option
16562 type. */
16564 static enum code_option_type
16565 parse_code_option (char * name)
16567 bfd_boolean isa_set = FALSE;
16568 const struct mips_ase *ase;
16570 if (strncmp (name, "at=", 3) == 0)
16572 char *s = name + 3;
16574 if (!reg_lookup (&s, RTYPE_NUM | RTYPE_GP, &mips_opts.at))
16575 as_bad (_("unrecognized register name `%s'"), s);
16577 else if (strcmp (name, "at") == 0)
16578 mips_opts.at = ATREG;
16579 else if (strcmp (name, "noat") == 0)
16580 mips_opts.at = ZERO;
16581 else if (strcmp (name, "move") == 0 || strcmp (name, "novolatile") == 0)
16582 mips_opts.nomove = 0;
16583 else if (strcmp (name, "nomove") == 0 || strcmp (name, "volatile") == 0)
16584 mips_opts.nomove = 1;
16585 else if (strcmp (name, "bopt") == 0)
16586 mips_opts.nobopt = 0;
16587 else if (strcmp (name, "nobopt") == 0)
16588 mips_opts.nobopt = 1;
16589 else if (strcmp (name, "gp=32") == 0)
16590 mips_opts.gp = 32;
16591 else if (strcmp (name, "gp=64") == 0)
16592 mips_opts.gp = 64;
16593 else if (strcmp (name, "fp=32") == 0)
16594 mips_opts.fp = 32;
16595 else if (strcmp (name, "fp=xx") == 0)
16596 mips_opts.fp = 0;
16597 else if (strcmp (name, "fp=64") == 0)
16598 mips_opts.fp = 64;
16599 else if (strcmp (name, "softfloat") == 0)
16600 mips_opts.soft_float = 1;
16601 else if (strcmp (name, "hardfloat") == 0)
16602 mips_opts.soft_float = 0;
16603 else if (strcmp (name, "singlefloat") == 0)
16604 mips_opts.single_float = 1;
16605 else if (strcmp (name, "doublefloat") == 0)
16606 mips_opts.single_float = 0;
16607 else if (strcmp (name, "nooddspreg") == 0)
16608 mips_opts.oddspreg = 0;
16609 else if (strcmp (name, "oddspreg") == 0)
16610 mips_opts.oddspreg = 1;
16611 else if (strcmp (name, "mips16") == 0
16612 || strcmp (name, "MIPS-16") == 0)
16613 mips_opts.mips16 = 1;
16614 else if (strcmp (name, "nomips16") == 0
16615 || strcmp (name, "noMIPS-16") == 0)
16616 mips_opts.mips16 = 0;
16617 else if (strcmp (name, "micromips") == 0)
16618 mips_opts.micromips = 1;
16619 else if (strcmp (name, "nomicromips") == 0)
16620 mips_opts.micromips = 0;
16621 else if (name[0] == 'n'
16622 && name[1] == 'o'
16623 && (ase = mips_lookup_ase (name + 2)))
16624 mips_set_ase (ase, &mips_opts, FALSE);
16625 else if ((ase = mips_lookup_ase (name)))
16626 mips_set_ase (ase, &mips_opts, TRUE);
16627 else if (strncmp (name, "mips", 4) == 0 || strncmp (name, "arch=", 5) == 0)
16629 /* Permit the user to change the ISA and architecture on the fly.
16630 Needless to say, misuse can cause serious problems. */
16631 if (strncmp (name, "arch=", 5) == 0)
16633 const struct mips_cpu_info *p;
16635 p = mips_parse_cpu ("internal use", name + 5);
16636 if (!p)
16637 as_bad (_("unknown architecture %s"), name + 5);
16638 else
16640 mips_opts.arch = p->cpu;
16641 mips_opts.isa = p->isa;
16642 isa_set = TRUE;
16643 mips_opts.init_ase = p->ase;
16646 else if (strncmp (name, "mips", 4) == 0)
16648 const struct mips_cpu_info *p;
16650 p = mips_parse_cpu ("internal use", name);
16651 if (!p)
16652 as_bad (_("unknown ISA level %s"), name + 4);
16653 else
16655 mips_opts.arch = p->cpu;
16656 mips_opts.isa = p->isa;
16657 isa_set = TRUE;
16658 mips_opts.init_ase = p->ase;
16661 else
16662 as_bad (_("unknown ISA or architecture %s"), name);
16664 else if (strcmp (name, "autoextend") == 0)
16665 mips_opts.noautoextend = 0;
16666 else if (strcmp (name, "noautoextend") == 0)
16667 mips_opts.noautoextend = 1;
16668 else if (strcmp (name, "insn32") == 0)
16669 mips_opts.insn32 = TRUE;
16670 else if (strcmp (name, "noinsn32") == 0)
16671 mips_opts.insn32 = FALSE;
16672 else if (strcmp (name, "sym32") == 0)
16673 mips_opts.sym32 = TRUE;
16674 else if (strcmp (name, "nosym32") == 0)
16675 mips_opts.sym32 = FALSE;
16676 else
16677 return OPTION_TYPE_BAD;
16679 return isa_set ? OPTION_TYPE_ISA : OPTION_TYPE_NORMAL;
16682 /* Handle the .set pseudo-op. */
16684 static void
16685 s_mipsset (int x ATTRIBUTE_UNUSED)
16687 enum code_option_type type = OPTION_TYPE_NORMAL;
16688 char *name = input_line_pointer, ch;
16690 file_mips_check_options ();
16692 while (!is_end_of_line[(unsigned char) *input_line_pointer])
16693 ++input_line_pointer;
16694 ch = *input_line_pointer;
16695 *input_line_pointer = '\0';
16697 if (strchr (name, ','))
16699 /* Generic ".set" directive; use the generic handler. */
16700 *input_line_pointer = ch;
16701 input_line_pointer = name;
16702 s_set (0);
16703 return;
16706 if (strcmp (name, "reorder") == 0)
16708 if (mips_opts.noreorder)
16709 end_noreorder ();
16711 else if (strcmp (name, "noreorder") == 0)
16713 if (!mips_opts.noreorder)
16714 start_noreorder ();
16716 else if (strcmp (name, "macro") == 0)
16717 mips_opts.warn_about_macros = 0;
16718 else if (strcmp (name, "nomacro") == 0)
16720 if (mips_opts.noreorder == 0)
16721 as_bad (_("`noreorder' must be set before `nomacro'"));
16722 mips_opts.warn_about_macros = 1;
16724 else if (strcmp (name, "gp=default") == 0)
16725 mips_opts.gp = file_mips_opts.gp;
16726 else if (strcmp (name, "fp=default") == 0)
16727 mips_opts.fp = file_mips_opts.fp;
16728 else if (strcmp (name, "mips0") == 0 || strcmp (name, "arch=default") == 0)
16730 mips_opts.isa = file_mips_opts.isa;
16731 mips_opts.arch = file_mips_opts.arch;
16732 mips_opts.init_ase = file_mips_opts.init_ase;
16733 mips_opts.gp = file_mips_opts.gp;
16734 mips_opts.fp = file_mips_opts.fp;
16736 else if (strcmp (name, "push") == 0)
16738 struct mips_option_stack *s;
16740 s = XNEW (struct mips_option_stack);
16741 s->next = mips_opts_stack;
16742 s->options = mips_opts;
16743 mips_opts_stack = s;
16745 else if (strcmp (name, "pop") == 0)
16747 struct mips_option_stack *s;
16749 s = mips_opts_stack;
16750 if (s == NULL)
16751 as_bad (_(".set pop with no .set push"));
16752 else
16754 /* If we're changing the reorder mode we need to handle
16755 delay slots correctly. */
16756 if (s->options.noreorder && ! mips_opts.noreorder)
16757 start_noreorder ();
16758 else if (! s->options.noreorder && mips_opts.noreorder)
16759 end_noreorder ();
16761 mips_opts = s->options;
16762 mips_opts_stack = s->next;
16763 free (s);
16766 else
16768 type = parse_code_option (name);
16769 if (type == OPTION_TYPE_BAD)
16770 as_warn (_("tried to set unrecognized symbol: %s\n"), name);
16773 /* The use of .set [arch|cpu]= historically 'fixes' the width of gp and fp
16774 registers based on what is supported by the arch/cpu. */
16775 if (type == OPTION_TYPE_ISA)
16777 switch (mips_opts.isa)
16779 case 0:
16780 break;
16781 case ISA_MIPS1:
16782 /* MIPS I cannot support FPXX. */
16783 mips_opts.fp = 32;
16784 /* fall-through. */
16785 case ISA_MIPS2:
16786 case ISA_MIPS32:
16787 case ISA_MIPS32R2:
16788 case ISA_MIPS32R3:
16789 case ISA_MIPS32R5:
16790 mips_opts.gp = 32;
16791 if (mips_opts.fp != 0)
16792 mips_opts.fp = 32;
16793 break;
16794 case ISA_MIPS32R6:
16795 mips_opts.gp = 32;
16796 mips_opts.fp = 64;
16797 break;
16798 case ISA_MIPS3:
16799 case ISA_MIPS4:
16800 case ISA_MIPS5:
16801 case ISA_MIPS64:
16802 case ISA_MIPS64R2:
16803 case ISA_MIPS64R3:
16804 case ISA_MIPS64R5:
16805 case ISA_MIPS64R6:
16806 mips_opts.gp = 64;
16807 if (mips_opts.fp != 0)
16809 if (mips_opts.arch == CPU_R5900)
16810 mips_opts.fp = 32;
16811 else
16812 mips_opts.fp = 64;
16814 break;
16815 default:
16816 as_bad (_("unknown ISA level %s"), name + 4);
16817 break;
16821 mips_check_options (&mips_opts, FALSE);
16823 mips_check_isa_supports_ases ();
16824 *input_line_pointer = ch;
16825 demand_empty_rest_of_line ();
16828 /* Handle the .module pseudo-op. */
16830 static void
16831 s_module (int ignore ATTRIBUTE_UNUSED)
16833 char *name = input_line_pointer, ch;
16835 while (!is_end_of_line[(unsigned char) *input_line_pointer])
16836 ++input_line_pointer;
16837 ch = *input_line_pointer;
16838 *input_line_pointer = '\0';
16840 if (!file_mips_opts_checked)
16842 if (parse_code_option (name) == OPTION_TYPE_BAD)
16843 as_bad (_(".module used with unrecognized symbol: %s\n"), name);
16845 /* Update module level settings from mips_opts. */
16846 file_mips_opts = mips_opts;
16848 else
16849 as_bad (_(".module is not permitted after generating code"));
16851 *input_line_pointer = ch;
16852 demand_empty_rest_of_line ();
16855 /* Handle the .abicalls pseudo-op. I believe this is equivalent to
16856 .option pic2. It means to generate SVR4 PIC calls. */
16858 static void
16859 s_abicalls (int ignore ATTRIBUTE_UNUSED)
16861 mips_pic = SVR4_PIC;
16862 mips_abicalls = TRUE;
16864 if (g_switch_seen && g_switch_value != 0)
16865 as_warn (_("-G may not be used with SVR4 PIC code"));
16866 g_switch_value = 0;
16868 bfd_set_gp_size (stdoutput, 0);
16869 demand_empty_rest_of_line ();
16872 /* Handle the .cpload pseudo-op. This is used when generating SVR4
16873 PIC code. It sets the $gp register for the function based on the
16874 function address, which is in the register named in the argument.
16875 This uses a relocation against _gp_disp, which is handled specially
16876 by the linker. The result is:
16877 lui $gp,%hi(_gp_disp)
16878 addiu $gp,$gp,%lo(_gp_disp)
16879 addu $gp,$gp,.cpload argument
16880 The .cpload argument is normally $25 == $t9.
16882 The -mno-shared option changes this to:
16883 lui $gp,%hi(__gnu_local_gp)
16884 addiu $gp,$gp,%lo(__gnu_local_gp)
16885 and the argument is ignored. This saves an instruction, but the
16886 resulting code is not position independent; it uses an absolute
16887 address for __gnu_local_gp. Thus code assembled with -mno-shared
16888 can go into an ordinary executable, but not into a shared library. */
16890 static void
16891 s_cpload (int ignore ATTRIBUTE_UNUSED)
16893 expressionS ex;
16894 int reg;
16895 int in_shared;
16897 file_mips_check_options ();
16899 /* If we are not generating SVR4 PIC code, or if this is NewABI code,
16900 .cpload is ignored. */
16901 if (mips_pic != SVR4_PIC || HAVE_NEWABI)
16903 s_ignore (0);
16904 return;
16907 if (mips_opts.mips16)
16909 as_bad (_("%s not supported in MIPS16 mode"), ".cpload");
16910 ignore_rest_of_line ();
16911 return;
16914 /* .cpload should be in a .set noreorder section. */
16915 if (mips_opts.noreorder == 0)
16916 as_warn (_(".cpload not in noreorder section"));
16918 reg = tc_get_register (0);
16920 /* If we need to produce a 64-bit address, we are better off using
16921 the default instruction sequence. */
16922 in_shared = mips_in_shared || HAVE_64BIT_SYMBOLS;
16924 ex.X_op = O_symbol;
16925 ex.X_add_symbol = symbol_find_or_make (in_shared ? "_gp_disp" :
16926 "__gnu_local_gp");
16927 ex.X_op_symbol = NULL;
16928 ex.X_add_number = 0;
16930 /* In ELF, this symbol is implicitly an STT_OBJECT symbol. */
16931 symbol_get_bfdsym (ex.X_add_symbol)->flags |= BSF_OBJECT;
16933 mips_mark_labels ();
16934 mips_assembling_insn = TRUE;
16936 macro_start ();
16937 macro_build_lui (&ex, mips_gp_register);
16938 macro_build (&ex, "addiu", "t,r,j", mips_gp_register,
16939 mips_gp_register, BFD_RELOC_LO16);
16940 if (in_shared)
16941 macro_build (NULL, "addu", "d,v,t", mips_gp_register,
16942 mips_gp_register, reg);
16943 macro_end ();
16945 mips_assembling_insn = FALSE;
16946 demand_empty_rest_of_line ();
16949 /* Handle the .cpsetup pseudo-op defined for NewABI PIC code. The syntax is:
16950 .cpsetup $reg1, offset|$reg2, label
16952 If offset is given, this results in:
16953 sd $gp, offset($sp)
16954 lui $gp, %hi(%neg(%gp_rel(label)))
16955 addiu $gp, $gp, %lo(%neg(%gp_rel(label)))
16956 daddu $gp, $gp, $reg1
16958 If $reg2 is given, this results in:
16959 or $reg2, $gp, $0
16960 lui $gp, %hi(%neg(%gp_rel(label)))
16961 addiu $gp, $gp, %lo(%neg(%gp_rel(label)))
16962 daddu $gp, $gp, $reg1
16963 $reg1 is normally $25 == $t9.
16965 The -mno-shared option replaces the last three instructions with
16966 lui $gp,%hi(_gp)
16967 addiu $gp,$gp,%lo(_gp) */
16969 static void
16970 s_cpsetup (int ignore ATTRIBUTE_UNUSED)
16972 expressionS ex_off;
16973 expressionS ex_sym;
16974 int reg1;
16976 file_mips_check_options ();
16978 /* If we are not generating SVR4 PIC code, .cpsetup is ignored.
16979 We also need NewABI support. */
16980 if (mips_pic != SVR4_PIC || ! HAVE_NEWABI)
16982 s_ignore (0);
16983 return;
16986 if (mips_opts.mips16)
16988 as_bad (_("%s not supported in MIPS16 mode"), ".cpsetup");
16989 ignore_rest_of_line ();
16990 return;
16993 reg1 = tc_get_register (0);
16994 SKIP_WHITESPACE ();
16995 if (*input_line_pointer != ',')
16997 as_bad (_("missing argument separator ',' for .cpsetup"));
16998 return;
17000 else
17001 ++input_line_pointer;
17002 SKIP_WHITESPACE ();
17003 if (*input_line_pointer == '$')
17005 mips_cpreturn_register = tc_get_register (0);
17006 mips_cpreturn_offset = -1;
17008 else
17010 mips_cpreturn_offset = get_absolute_expression ();
17011 mips_cpreturn_register = -1;
17013 SKIP_WHITESPACE ();
17014 if (*input_line_pointer != ',')
17016 as_bad (_("missing argument separator ',' for .cpsetup"));
17017 return;
17019 else
17020 ++input_line_pointer;
17021 SKIP_WHITESPACE ();
17022 expression (&ex_sym);
17024 mips_mark_labels ();
17025 mips_assembling_insn = TRUE;
17027 macro_start ();
17028 if (mips_cpreturn_register == -1)
17030 ex_off.X_op = O_constant;
17031 ex_off.X_add_symbol = NULL;
17032 ex_off.X_op_symbol = NULL;
17033 ex_off.X_add_number = mips_cpreturn_offset;
17035 macro_build (&ex_off, "sd", "t,o(b)", mips_gp_register,
17036 BFD_RELOC_LO16, SP);
17038 else
17039 move_register (mips_cpreturn_register, mips_gp_register);
17041 if (mips_in_shared || HAVE_64BIT_SYMBOLS)
17043 macro_build (&ex_sym, "lui", LUI_FMT, mips_gp_register,
17044 -1, BFD_RELOC_GPREL16, BFD_RELOC_MIPS_SUB,
17045 BFD_RELOC_HI16_S);
17047 macro_build (&ex_sym, "addiu", "t,r,j", mips_gp_register,
17048 mips_gp_register, -1, BFD_RELOC_GPREL16,
17049 BFD_RELOC_MIPS_SUB, BFD_RELOC_LO16);
17051 macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t", mips_gp_register,
17052 mips_gp_register, reg1);
17054 else
17056 expressionS ex;
17058 ex.X_op = O_symbol;
17059 ex.X_add_symbol = symbol_find_or_make ("__gnu_local_gp");
17060 ex.X_op_symbol = NULL;
17061 ex.X_add_number = 0;
17063 /* In ELF, this symbol is implicitly an STT_OBJECT symbol. */
17064 symbol_get_bfdsym (ex.X_add_symbol)->flags |= BSF_OBJECT;
17066 macro_build_lui (&ex, mips_gp_register);
17067 macro_build (&ex, "addiu", "t,r,j", mips_gp_register,
17068 mips_gp_register, BFD_RELOC_LO16);
17071 macro_end ();
17073 mips_assembling_insn = FALSE;
17074 demand_empty_rest_of_line ();
17077 static void
17078 s_cplocal (int ignore ATTRIBUTE_UNUSED)
17080 file_mips_check_options ();
17082 /* If we are not generating SVR4 PIC code, or if this is not NewABI code,
17083 .cplocal is ignored. */
17084 if (mips_pic != SVR4_PIC || ! HAVE_NEWABI)
17086 s_ignore (0);
17087 return;
17090 if (mips_opts.mips16)
17092 as_bad (_("%s not supported in MIPS16 mode"), ".cplocal");
17093 ignore_rest_of_line ();
17094 return;
17097 mips_gp_register = tc_get_register (0);
17098 demand_empty_rest_of_line ();
17101 /* Handle the .cprestore pseudo-op. This stores $gp into a given
17102 offset from $sp. The offset is remembered, and after making a PIC
17103 call $gp is restored from that location. */
17105 static void
17106 s_cprestore (int ignore ATTRIBUTE_UNUSED)
17108 expressionS ex;
17110 file_mips_check_options ();
17112 /* If we are not generating SVR4 PIC code, or if this is NewABI code,
17113 .cprestore is ignored. */
17114 if (mips_pic != SVR4_PIC || HAVE_NEWABI)
17116 s_ignore (0);
17117 return;
17120 if (mips_opts.mips16)
17122 as_bad (_("%s not supported in MIPS16 mode"), ".cprestore");
17123 ignore_rest_of_line ();
17124 return;
17127 mips_cprestore_offset = get_absolute_expression ();
17128 mips_cprestore_valid = 1;
17130 ex.X_op = O_constant;
17131 ex.X_add_symbol = NULL;
17132 ex.X_op_symbol = NULL;
17133 ex.X_add_number = mips_cprestore_offset;
17135 mips_mark_labels ();
17136 mips_assembling_insn = TRUE;
17138 macro_start ();
17139 macro_build_ldst_constoffset (&ex, ADDRESS_STORE_INSN, mips_gp_register,
17140 SP, HAVE_64BIT_ADDRESSES);
17141 macro_end ();
17143 mips_assembling_insn = FALSE;
17144 demand_empty_rest_of_line ();
17147 /* Handle the .cpreturn pseudo-op defined for NewABI PIC code. If an offset
17148 was given in the preceding .cpsetup, it results in:
17149 ld $gp, offset($sp)
17151 If a register $reg2 was given there, it results in:
17152 or $gp, $reg2, $0 */
17154 static void
17155 s_cpreturn (int ignore ATTRIBUTE_UNUSED)
17157 expressionS ex;
17159 file_mips_check_options ();
17161 /* If we are not generating SVR4 PIC code, .cpreturn is ignored.
17162 We also need NewABI support. */
17163 if (mips_pic != SVR4_PIC || ! HAVE_NEWABI)
17165 s_ignore (0);
17166 return;
17169 if (mips_opts.mips16)
17171 as_bad (_("%s not supported in MIPS16 mode"), ".cpreturn");
17172 ignore_rest_of_line ();
17173 return;
17176 mips_mark_labels ();
17177 mips_assembling_insn = TRUE;
17179 macro_start ();
17180 if (mips_cpreturn_register == -1)
17182 ex.X_op = O_constant;
17183 ex.X_add_symbol = NULL;
17184 ex.X_op_symbol = NULL;
17185 ex.X_add_number = mips_cpreturn_offset;
17187 macro_build (&ex, "ld", "t,o(b)", mips_gp_register, BFD_RELOC_LO16, SP);
17189 else
17190 move_register (mips_gp_register, mips_cpreturn_register);
17192 macro_end ();
17194 mips_assembling_insn = FALSE;
17195 demand_empty_rest_of_line ();
17198 /* Handle a .dtprelword, .dtpreldword, .tprelword, or .tpreldword
17199 pseudo-op; DIRSTR says which. The pseudo-op generates a BYTES-size
17200 DTP- or TP-relative relocation of type RTYPE, for use in either DWARF
17201 debug information or MIPS16 TLS. */
17203 static void
17204 s_tls_rel_directive (const size_t bytes, const char *dirstr,
17205 bfd_reloc_code_real_type rtype)
17207 expressionS ex;
17208 char *p;
17210 expression (&ex);
17212 if (ex.X_op != O_symbol)
17214 as_bad (_("unsupported use of %s"), dirstr);
17215 ignore_rest_of_line ();
17218 p = frag_more (bytes);
17219 md_number_to_chars (p, 0, bytes);
17220 fix_new_exp (frag_now, p - frag_now->fr_literal, bytes, &ex, FALSE, rtype);
17221 demand_empty_rest_of_line ();
17222 mips_clear_insn_labels ();
17225 /* Handle .dtprelword. */
17227 static void
17228 s_dtprelword (int ignore ATTRIBUTE_UNUSED)
17230 s_tls_rel_directive (4, ".dtprelword", BFD_RELOC_MIPS_TLS_DTPREL32);
17233 /* Handle .dtpreldword. */
17235 static void
17236 s_dtpreldword (int ignore ATTRIBUTE_UNUSED)
17238 s_tls_rel_directive (8, ".dtpreldword", BFD_RELOC_MIPS_TLS_DTPREL64);
17241 /* Handle .tprelword. */
17243 static void
17244 s_tprelword (int ignore ATTRIBUTE_UNUSED)
17246 s_tls_rel_directive (4, ".tprelword", BFD_RELOC_MIPS_TLS_TPREL32);
17249 /* Handle .tpreldword. */
17251 static void
17252 s_tpreldword (int ignore ATTRIBUTE_UNUSED)
17254 s_tls_rel_directive (8, ".tpreldword", BFD_RELOC_MIPS_TLS_TPREL64);
17257 /* Handle the .gpvalue pseudo-op. This is used when generating NewABI PIC
17258 code. It sets the offset to use in gp_rel relocations. */
17260 static void
17261 s_gpvalue (int ignore ATTRIBUTE_UNUSED)
17263 /* If we are not generating SVR4 PIC code, .gpvalue is ignored.
17264 We also need NewABI support. */
17265 if (mips_pic != SVR4_PIC || ! HAVE_NEWABI)
17267 s_ignore (0);
17268 return;
17271 mips_gprel_offset = get_absolute_expression ();
17273 demand_empty_rest_of_line ();
17276 /* Handle the .gpword pseudo-op. This is used when generating PIC
17277 code. It generates a 32 bit GP relative reloc. */
17279 static void
17280 s_gpword (int ignore ATTRIBUTE_UNUSED)
17282 segment_info_type *si;
17283 struct insn_label_list *l;
17284 expressionS ex;
17285 char *p;
17287 /* When not generating PIC code, this is treated as .word. */
17288 if (mips_pic != SVR4_PIC)
17290 s_cons (2);
17291 return;
17294 si = seg_info (now_seg);
17295 l = si->label_list;
17296 mips_emit_delays ();
17297 if (auto_align)
17298 mips_align (2, 0, l);
17300 expression (&ex);
17301 mips_clear_insn_labels ();
17303 if (ex.X_op != O_symbol || ex.X_add_number != 0)
17305 as_bad (_("unsupported use of .gpword"));
17306 ignore_rest_of_line ();
17309 p = frag_more (4);
17310 md_number_to_chars (p, 0, 4);
17311 fix_new_exp (frag_now, p - frag_now->fr_literal, 4, &ex, FALSE,
17312 BFD_RELOC_GPREL32);
17314 demand_empty_rest_of_line ();
17317 static void
17318 s_gpdword (int ignore ATTRIBUTE_UNUSED)
17320 segment_info_type *si;
17321 struct insn_label_list *l;
17322 expressionS ex;
17323 char *p;
17325 /* When not generating PIC code, this is treated as .dword. */
17326 if (mips_pic != SVR4_PIC)
17328 s_cons (3);
17329 return;
17332 si = seg_info (now_seg);
17333 l = si->label_list;
17334 mips_emit_delays ();
17335 if (auto_align)
17336 mips_align (3, 0, l);
17338 expression (&ex);
17339 mips_clear_insn_labels ();
17341 if (ex.X_op != O_symbol || ex.X_add_number != 0)
17343 as_bad (_("unsupported use of .gpdword"));
17344 ignore_rest_of_line ();
17347 p = frag_more (8);
17348 md_number_to_chars (p, 0, 8);
17349 fix_new_exp (frag_now, p - frag_now->fr_literal, 4, &ex, FALSE,
17350 BFD_RELOC_GPREL32)->fx_tcbit = 1;
17352 /* GPREL32 composed with 64 gives a 64-bit GP offset. */
17353 fix_new (frag_now, p - frag_now->fr_literal, 8, NULL, 0,
17354 FALSE, BFD_RELOC_64)->fx_tcbit = 1;
17356 demand_empty_rest_of_line ();
17359 /* Handle the .ehword pseudo-op. This is used when generating unwinding
17360 tables. It generates a R_MIPS_EH reloc. */
17362 static void
17363 s_ehword (int ignore ATTRIBUTE_UNUSED)
17365 expressionS ex;
17366 char *p;
17368 mips_emit_delays ();
17370 expression (&ex);
17371 mips_clear_insn_labels ();
17373 if (ex.X_op != O_symbol || ex.X_add_number != 0)
17375 as_bad (_("unsupported use of .ehword"));
17376 ignore_rest_of_line ();
17379 p = frag_more (4);
17380 md_number_to_chars (p, 0, 4);
17381 fix_new_exp (frag_now, p - frag_now->fr_literal, 4, &ex, FALSE,
17382 BFD_RELOC_32_PCREL);
17384 demand_empty_rest_of_line ();
17387 /* Handle the .cpadd pseudo-op. This is used when dealing with switch
17388 tables in SVR4 PIC code. */
17390 static void
17391 s_cpadd (int ignore ATTRIBUTE_UNUSED)
17393 int reg;
17395 file_mips_check_options ();
17397 /* This is ignored when not generating SVR4 PIC code. */
17398 if (mips_pic != SVR4_PIC)
17400 s_ignore (0);
17401 return;
17404 mips_mark_labels ();
17405 mips_assembling_insn = TRUE;
17407 /* Add $gp to the register named as an argument. */
17408 macro_start ();
17409 reg = tc_get_register (0);
17410 macro_build (NULL, ADDRESS_ADD_INSN, "d,v,t", reg, reg, mips_gp_register);
17411 macro_end ();
17413 mips_assembling_insn = FALSE;
17414 demand_empty_rest_of_line ();
17417 /* Handle the .insn pseudo-op. This marks instruction labels in
17418 mips16/micromips mode. This permits the linker to handle them specially,
17419 such as generating jalx instructions when needed. We also make
17420 them odd for the duration of the assembly, in order to generate the
17421 right sort of code. We will make them even in the adjust_symtab
17422 routine, while leaving them marked. This is convenient for the
17423 debugger and the disassembler. The linker knows to make them odd
17424 again. */
17426 static void
17427 s_insn (int ignore ATTRIBUTE_UNUSED)
17429 file_mips_check_options ();
17430 file_ase_mips16 |= mips_opts.mips16;
17431 file_ase_micromips |= mips_opts.micromips;
17433 mips_mark_labels ();
17435 demand_empty_rest_of_line ();
17438 /* Handle the .nan pseudo-op. */
17440 static void
17441 s_nan (int ignore ATTRIBUTE_UNUSED)
17443 static const char str_legacy[] = "legacy";
17444 static const char str_2008[] = "2008";
17445 size_t i;
17447 for (i = 0; !is_end_of_line[(unsigned char) input_line_pointer[i]]; i++);
17449 if (i == sizeof (str_2008) - 1
17450 && memcmp (input_line_pointer, str_2008, i) == 0)
17451 mips_nan2008 = 1;
17452 else if (i == sizeof (str_legacy) - 1
17453 && memcmp (input_line_pointer, str_legacy, i) == 0)
17455 if (ISA_HAS_LEGACY_NAN (file_mips_opts.isa))
17456 mips_nan2008 = 0;
17457 else
17458 as_bad (_("`%s' does not support legacy NaN"),
17459 mips_cpu_info_from_isa (file_mips_opts.isa)->name);
17461 else
17462 as_bad (_("bad .nan directive"));
17464 input_line_pointer += i;
17465 demand_empty_rest_of_line ();
17468 /* Handle a .stab[snd] directive. Ideally these directives would be
17469 implemented in a transparent way, so that removing them would not
17470 have any effect on the generated instructions. However, s_stab
17471 internally changes the section, so in practice we need to decide
17472 now whether the preceding label marks compressed code. We do not
17473 support changing the compression mode of a label after a .stab*
17474 directive, such as in:
17476 foo:
17477 .stabs ...
17478 .set mips16
17480 so the current mode wins. */
17482 static void
17483 s_mips_stab (int type)
17485 file_mips_check_options ();
17486 mips_mark_labels ();
17487 s_stab (type);
17490 /* Handle the .weakext pseudo-op as defined in Kane and Heinrich. */
17492 static void
17493 s_mips_weakext (int ignore ATTRIBUTE_UNUSED)
17495 char *name;
17496 int c;
17497 symbolS *symbolP;
17498 expressionS exp;
17500 c = get_symbol_name (&name);
17501 symbolP = symbol_find_or_make (name);
17502 S_SET_WEAK (symbolP);
17503 *input_line_pointer = c;
17505 SKIP_WHITESPACE_AFTER_NAME ();
17507 if (! is_end_of_line[(unsigned char) *input_line_pointer])
17509 if (S_IS_DEFINED (symbolP))
17511 as_bad (_("ignoring attempt to redefine symbol %s"),
17512 S_GET_NAME (symbolP));
17513 ignore_rest_of_line ();
17514 return;
17517 if (*input_line_pointer == ',')
17519 ++input_line_pointer;
17520 SKIP_WHITESPACE ();
17523 expression (&exp);
17524 if (exp.X_op != O_symbol)
17526 as_bad (_("bad .weakext directive"));
17527 ignore_rest_of_line ();
17528 return;
17530 symbol_set_value_expression (symbolP, &exp);
17533 demand_empty_rest_of_line ();
17536 /* Parse a register string into a number. Called from the ECOFF code
17537 to parse .frame. The argument is non-zero if this is the frame
17538 register, so that we can record it in mips_frame_reg. */
17541 tc_get_register (int frame)
17543 unsigned int reg;
17545 SKIP_WHITESPACE ();
17546 if (! reg_lookup (&input_line_pointer, RWARN | RTYPE_NUM | RTYPE_GP, &reg))
17547 reg = 0;
17548 if (frame)
17550 mips_frame_reg = reg != 0 ? reg : SP;
17551 mips_frame_reg_valid = 1;
17552 mips_cprestore_valid = 0;
17554 return reg;
17557 valueT
17558 md_section_align (asection *seg, valueT addr)
17560 int align = bfd_get_section_alignment (stdoutput, seg);
17562 /* We don't need to align ELF sections to the full alignment.
17563 However, Irix 5 may prefer that we align them at least to a 16
17564 byte boundary. We don't bother to align the sections if we
17565 are targeted for an embedded system. */
17566 if (strncmp (TARGET_OS, "elf", 3) == 0)
17567 return addr;
17568 if (align > 4)
17569 align = 4;
17571 return ((addr + (1 << align) - 1) & -(1 << align));
17574 /* Utility routine, called from above as well. If called while the
17575 input file is still being read, it's only an approximation. (For
17576 example, a symbol may later become defined which appeared to be
17577 undefined earlier.) */
17579 static int
17580 nopic_need_relax (symbolS *sym, int before_relaxing)
17582 if (sym == 0)
17583 return 0;
17585 if (g_switch_value > 0)
17587 const char *symname;
17588 int change;
17590 /* Find out whether this symbol can be referenced off the $gp
17591 register. It can be if it is smaller than the -G size or if
17592 it is in the .sdata or .sbss section. Certain symbols can
17593 not be referenced off the $gp, although it appears as though
17594 they can. */
17595 symname = S_GET_NAME (sym);
17596 if (symname != (const char *) NULL
17597 && (strcmp (symname, "eprol") == 0
17598 || strcmp (symname, "etext") == 0
17599 || strcmp (symname, "_gp") == 0
17600 || strcmp (symname, "edata") == 0
17601 || strcmp (symname, "_fbss") == 0
17602 || strcmp (symname, "_fdata") == 0
17603 || strcmp (symname, "_ftext") == 0
17604 || strcmp (symname, "end") == 0
17605 || strcmp (symname, "_gp_disp") == 0))
17606 change = 1;
17607 else if ((! S_IS_DEFINED (sym) || S_IS_COMMON (sym))
17608 && (0
17609 #ifndef NO_ECOFF_DEBUGGING
17610 || (symbol_get_obj (sym)->ecoff_extern_size != 0
17611 && (symbol_get_obj (sym)->ecoff_extern_size
17612 <= g_switch_value))
17613 #endif
17614 /* We must defer this decision until after the whole
17615 file has been read, since there might be a .extern
17616 after the first use of this symbol. */
17617 || (before_relaxing
17618 #ifndef NO_ECOFF_DEBUGGING
17619 && symbol_get_obj (sym)->ecoff_extern_size == 0
17620 #endif
17621 && S_GET_VALUE (sym) == 0)
17622 || (S_GET_VALUE (sym) != 0
17623 && S_GET_VALUE (sym) <= g_switch_value)))
17624 change = 0;
17625 else
17627 const char *segname;
17629 segname = segment_name (S_GET_SEGMENT (sym));
17630 gas_assert (strcmp (segname, ".lit8") != 0
17631 && strcmp (segname, ".lit4") != 0);
17632 change = (strcmp (segname, ".sdata") != 0
17633 && strcmp (segname, ".sbss") != 0
17634 && strncmp (segname, ".sdata.", 7) != 0
17635 && strncmp (segname, ".sbss.", 6) != 0
17636 && strncmp (segname, ".gnu.linkonce.sb.", 17) != 0
17637 && strncmp (segname, ".gnu.linkonce.s.", 16) != 0);
17639 return change;
17641 else
17642 /* We are not optimizing for the $gp register. */
17643 return 1;
17647 /* Return true if the given symbol should be considered local for SVR4 PIC. */
17649 static bfd_boolean
17650 pic_need_relax (symbolS *sym)
17652 asection *symsec;
17654 /* Handle the case of a symbol equated to another symbol. */
17655 while (symbol_equated_reloc_p (sym))
17657 symbolS *n;
17659 /* It's possible to get a loop here in a badly written program. */
17660 n = symbol_get_value_expression (sym)->X_add_symbol;
17661 if (n == sym)
17662 break;
17663 sym = n;
17666 if (symbol_section_p (sym))
17667 return TRUE;
17669 symsec = S_GET_SEGMENT (sym);
17671 /* This must duplicate the test in adjust_reloc_syms. */
17672 return (!bfd_is_und_section (symsec)
17673 && !bfd_is_abs_section (symsec)
17674 && !bfd_is_com_section (symsec)
17675 /* A global or weak symbol is treated as external. */
17676 && (!S_IS_WEAK (sym) && !S_IS_EXTERNAL (sym)));
17679 /* Given a MIPS16 variant frag FRAGP and PC-relative operand PCREL_OP
17680 convert a section-relative value VAL to the equivalent PC-relative
17681 value. */
17683 static offsetT
17684 mips16_pcrel_val (fragS *fragp, const struct mips_pcrel_operand *pcrel_op,
17685 offsetT val, long stretch)
17687 fragS *sym_frag;
17688 addressT addr;
17690 gas_assert (pcrel_op->root.root.type == OP_PCREL);
17692 sym_frag = symbol_get_frag (fragp->fr_symbol);
17694 /* If the relax_marker of the symbol fragment differs from the
17695 relax_marker of this fragment, we have not yet adjusted the
17696 symbol fragment fr_address. We want to add in STRETCH in
17697 order to get a better estimate of the address. This
17698 particularly matters because of the shift bits. */
17699 if (stretch != 0 && sym_frag->relax_marker != fragp->relax_marker)
17701 fragS *f;
17703 /* Adjust stretch for any alignment frag. Note that if have
17704 been expanding the earlier code, the symbol may be
17705 defined in what appears to be an earlier frag. FIXME:
17706 This doesn't handle the fr_subtype field, which specifies
17707 a maximum number of bytes to skip when doing an
17708 alignment. */
17709 for (f = fragp; f != NULL && f != sym_frag; f = f->fr_next)
17711 if (f->fr_type == rs_align || f->fr_type == rs_align_code)
17713 if (stretch < 0)
17714 stretch = -(-stretch & ~((1 << (int) f->fr_offset) - 1));
17715 else
17716 stretch &= ~((1 << (int) f->fr_offset) - 1);
17717 if (stretch == 0)
17718 break;
17721 if (f != NULL)
17722 val += stretch;
17725 addr = fragp->fr_address + fragp->fr_fix;
17727 /* The base address rules are complicated. The base address of
17728 a branch is the following instruction. The base address of a
17729 PC relative load or add is the instruction itself, but if it
17730 is in a delay slot (in which case it can not be extended) use
17731 the address of the instruction whose delay slot it is in. */
17732 if (pcrel_op->include_isa_bit)
17734 addr += 2;
17736 /* If we are currently assuming that this frag should be
17737 extended, then the current address is two bytes higher. */
17738 if (RELAX_MIPS16_EXTENDED (fragp->fr_subtype))
17739 addr += 2;
17741 /* Ignore the low bit in the target, since it will be set
17742 for a text label. */
17743 val &= -2;
17745 else if (RELAX_MIPS16_JAL_DSLOT (fragp->fr_subtype))
17746 addr -= 4;
17747 else if (RELAX_MIPS16_DSLOT (fragp->fr_subtype))
17748 addr -= 2;
17750 val -= addr & -(1 << pcrel_op->align_log2);
17752 return val;
17755 /* Given a mips16 variant frag FRAGP, return non-zero if it needs an
17756 extended opcode. SEC is the section the frag is in. */
17758 static int
17759 mips16_extended_frag (fragS *fragp, asection *sec, long stretch)
17761 const struct mips_int_operand *operand;
17762 offsetT val;
17763 segT symsec;
17764 int type;
17766 if (RELAX_MIPS16_USER_SMALL (fragp->fr_subtype))
17767 return 0;
17768 if (RELAX_MIPS16_USER_EXT (fragp->fr_subtype))
17769 return 1;
17771 symsec = S_GET_SEGMENT (fragp->fr_symbol);
17772 type = RELAX_MIPS16_TYPE (fragp->fr_subtype);
17773 operand = mips16_immed_operand (type, FALSE);
17774 if (S_FORCE_RELOC (fragp->fr_symbol, TRUE)
17775 || (operand->root.type == OP_PCREL
17776 ? sec != symsec
17777 : !bfd_is_abs_section (symsec)))
17778 return 1;
17780 val = S_GET_VALUE (fragp->fr_symbol) + fragp->fr_offset;
17782 if (operand->root.type == OP_PCREL)
17784 const struct mips_pcrel_operand *pcrel_op;
17785 offsetT maxtiny;
17787 if (RELAX_MIPS16_ALWAYS_EXTENDED (fragp->fr_subtype))
17788 return 1;
17790 pcrel_op = (const struct mips_pcrel_operand *) operand;
17791 val = mips16_pcrel_val (fragp, pcrel_op, val, stretch);
17793 /* If any of the shifted bits are set, we must use an extended
17794 opcode. If the address depends on the size of this
17795 instruction, this can lead to a loop, so we arrange to always
17796 use an extended opcode. */
17797 if ((val & ((1 << operand->shift) - 1)) != 0)
17799 fragp->fr_subtype =
17800 RELAX_MIPS16_MARK_ALWAYS_EXTENDED (fragp->fr_subtype);
17801 return 1;
17804 /* If we are about to mark a frag as extended because the value
17805 is precisely the next value above maxtiny, then there is a
17806 chance of an infinite loop as in the following code:
17807 la $4,foo
17808 .skip 1020
17809 .align 2
17810 foo:
17811 In this case when the la is extended, foo is 0x3fc bytes
17812 away, so the la can be shrunk, but then foo is 0x400 away, so
17813 the la must be extended. To avoid this loop, we mark the
17814 frag as extended if it was small, and is about to become
17815 extended with the next value above maxtiny. */
17816 maxtiny = mips_int_operand_max (operand);
17817 if (val == maxtiny + (1 << operand->shift)
17818 && ! RELAX_MIPS16_EXTENDED (fragp->fr_subtype))
17820 fragp->fr_subtype =
17821 RELAX_MIPS16_MARK_ALWAYS_EXTENDED (fragp->fr_subtype);
17822 return 1;
17826 return !mips16_immed_in_range_p (operand, BFD_RELOC_UNUSED, val);
17829 /* Given a MIPS16 variant frag FRAGP, return non-zero if it needs
17830 macro expansion. SEC is the section the frag is in. We only
17831 support PC-relative instructions (LA, DLA, LW, LD) here, in
17832 non-PIC code using 32-bit addressing. */
17834 static int
17835 mips16_macro_frag (fragS *fragp, asection *sec, long stretch)
17837 const struct mips_pcrel_operand *pcrel_op;
17838 const struct mips_int_operand *operand;
17839 offsetT val;
17840 segT symsec;
17841 int type;
17843 gas_assert (!RELAX_MIPS16_USER_SMALL (fragp->fr_subtype));
17845 if (RELAX_MIPS16_USER_EXT (fragp->fr_subtype))
17846 return 0;
17847 if (!RELAX_MIPS16_SYM32 (fragp->fr_subtype))
17848 return 0;
17850 type = RELAX_MIPS16_TYPE (fragp->fr_subtype);
17851 switch (type)
17853 case 'A':
17854 case 'B':
17855 case 'E':
17856 symsec = S_GET_SEGMENT (fragp->fr_symbol);
17857 if (bfd_is_abs_section (symsec))
17858 return 1;
17859 if (RELAX_MIPS16_PIC (fragp->fr_subtype))
17860 return 0;
17861 if (S_FORCE_RELOC (fragp->fr_symbol, TRUE) || sec != symsec)
17862 return 1;
17864 operand = mips16_immed_operand (type, TRUE);
17865 val = S_GET_VALUE (fragp->fr_symbol) + fragp->fr_offset;
17866 pcrel_op = (const struct mips_pcrel_operand *) operand;
17867 val = mips16_pcrel_val (fragp, pcrel_op, val, stretch);
17869 return !mips16_immed_in_range_p (operand, BFD_RELOC_UNUSED, val);
17871 default:
17872 return 0;
17876 /* Compute the length of a branch sequence, and adjust the
17877 RELAX_BRANCH_TOOFAR bit accordingly. If FRAGP is NULL, the
17878 worst-case length is computed, with UPDATE being used to indicate
17879 whether an unconditional (-1), branch-likely (+1) or regular (0)
17880 branch is to be computed. */
17881 static int
17882 relaxed_branch_length (fragS *fragp, asection *sec, int update)
17884 bfd_boolean toofar;
17885 int length;
17887 if (fragp
17888 && S_IS_DEFINED (fragp->fr_symbol)
17889 && !S_IS_WEAK (fragp->fr_symbol)
17890 && sec == S_GET_SEGMENT (fragp->fr_symbol))
17892 addressT addr;
17893 offsetT val;
17895 val = S_GET_VALUE (fragp->fr_symbol) + fragp->fr_offset;
17897 addr = fragp->fr_address + fragp->fr_fix + 4;
17899 val -= addr;
17901 toofar = val < - (0x8000 << 2) || val >= (0x8000 << 2);
17903 else
17904 /* If the symbol is not defined or it's in a different segment,
17905 we emit the long sequence. */
17906 toofar = TRUE;
17908 if (fragp && update && toofar != RELAX_BRANCH_TOOFAR (fragp->fr_subtype))
17909 fragp->fr_subtype
17910 = RELAX_BRANCH_ENCODE (RELAX_BRANCH_AT (fragp->fr_subtype),
17911 RELAX_BRANCH_PIC (fragp->fr_subtype),
17912 RELAX_BRANCH_UNCOND (fragp->fr_subtype),
17913 RELAX_BRANCH_LIKELY (fragp->fr_subtype),
17914 RELAX_BRANCH_LINK (fragp->fr_subtype),
17915 toofar);
17917 length = 4;
17918 if (toofar)
17920 if (fragp ? RELAX_BRANCH_LIKELY (fragp->fr_subtype) : (update > 0))
17921 length += 8;
17923 if (!fragp || RELAX_BRANCH_PIC (fragp->fr_subtype))
17925 /* Additional space for PIC loading of target address. */
17926 length += 8;
17927 if (mips_opts.isa == ISA_MIPS1)
17928 /* Additional space for $at-stabilizing nop. */
17929 length += 4;
17932 /* If branch is conditional. */
17933 if (fragp ? !RELAX_BRANCH_UNCOND (fragp->fr_subtype) : (update >= 0))
17934 length += 8;
17937 return length;
17940 /* Get a FRAG's branch instruction delay slot size, either from the
17941 short-delay-slot bit of a branch-and-link instruction if AL is TRUE,
17942 or SHORT_INSN_SIZE otherwise. */
17944 static int
17945 frag_branch_delay_slot_size (fragS *fragp, bfd_boolean al, int short_insn_size)
17947 char *buf = fragp->fr_literal + fragp->fr_fix;
17949 if (al)
17950 return (read_compressed_insn (buf, 4) & 0x02000000) ? 2 : 4;
17951 else
17952 return short_insn_size;
17955 /* Compute the length of a branch sequence, and adjust the
17956 RELAX_MICROMIPS_TOOFAR32 bit accordingly. If FRAGP is NULL, the
17957 worst-case length is computed, with UPDATE being used to indicate
17958 whether an unconditional (-1), or regular (0) branch is to be
17959 computed. */
17961 static int
17962 relaxed_micromips_32bit_branch_length (fragS *fragp, asection *sec, int update)
17964 bfd_boolean insn32 = TRUE;
17965 bfd_boolean nods = TRUE;
17966 bfd_boolean pic = TRUE;
17967 bfd_boolean al = TRUE;
17968 int short_insn_size;
17969 bfd_boolean toofar;
17970 int length;
17972 if (fragp)
17974 insn32 = RELAX_MICROMIPS_INSN32 (fragp->fr_subtype);
17975 nods = RELAX_MICROMIPS_NODS (fragp->fr_subtype);
17976 pic = RELAX_MICROMIPS_PIC (fragp->fr_subtype);
17977 al = RELAX_MICROMIPS_LINK (fragp->fr_subtype);
17979 short_insn_size = insn32 ? 4 : 2;
17981 if (fragp
17982 && S_IS_DEFINED (fragp->fr_symbol)
17983 && !S_IS_WEAK (fragp->fr_symbol)
17984 && sec == S_GET_SEGMENT (fragp->fr_symbol))
17986 addressT addr;
17987 offsetT val;
17989 val = S_GET_VALUE (fragp->fr_symbol) + fragp->fr_offset;
17990 /* Ignore the low bit in the target, since it will be set
17991 for a text label. */
17992 if ((val & 1) != 0)
17993 --val;
17995 addr = fragp->fr_address + fragp->fr_fix + 4;
17997 val -= addr;
17999 toofar = val < - (0x8000 << 1) || val >= (0x8000 << 1);
18001 else
18002 /* If the symbol is not defined or it's in a different segment,
18003 we emit the long sequence. */
18004 toofar = TRUE;
18006 if (fragp && update
18007 && toofar != RELAX_MICROMIPS_TOOFAR32 (fragp->fr_subtype))
18008 fragp->fr_subtype = (toofar
18009 ? RELAX_MICROMIPS_MARK_TOOFAR32 (fragp->fr_subtype)
18010 : RELAX_MICROMIPS_CLEAR_TOOFAR32 (fragp->fr_subtype));
18012 length = 4;
18013 if (toofar)
18015 bfd_boolean compact_known = fragp != NULL;
18016 bfd_boolean compact = FALSE;
18017 bfd_boolean uncond;
18019 if (fragp)
18021 compact = RELAX_MICROMIPS_COMPACT (fragp->fr_subtype);
18022 uncond = RELAX_MICROMIPS_UNCOND (fragp->fr_subtype);
18024 else
18025 uncond = update < 0;
18027 /* If label is out of range, we turn branch <br>:
18029 <br> label # 4 bytes
18032 into:
18034 j label # 4 bytes
18035 nop # 2/4 bytes if
18036 # compact && (!PIC || insn32)
18039 if ((!pic || insn32) && (!compact_known || compact))
18040 length += short_insn_size;
18042 /* If assembling PIC code, we further turn:
18044 j label # 4 bytes
18046 into:
18048 lw/ld at, %got(label)(gp) # 4 bytes
18049 d/addiu at, %lo(label) # 4 bytes
18050 jr/c at # 2/4 bytes
18052 if (pic)
18053 length += 4 + short_insn_size;
18055 /* Add an extra nop if the jump has no compact form and we need
18056 to fill the delay slot. */
18057 if ((!pic || al) && nods)
18058 length += (fragp
18059 ? frag_branch_delay_slot_size (fragp, al, short_insn_size)
18060 : short_insn_size);
18062 /* If branch <br> is conditional, we prepend negated branch <brneg>:
18064 <brneg> 0f # 4 bytes
18065 nop # 2/4 bytes if !compact
18067 if (!uncond)
18068 length += (compact_known && compact) ? 4 : 4 + short_insn_size;
18070 else if (nods)
18072 /* Add an extra nop to fill the delay slot. */
18073 gas_assert (fragp);
18074 length += frag_branch_delay_slot_size (fragp, al, short_insn_size);
18077 return length;
18080 /* Compute the length of a branch, and adjust the RELAX_MICROMIPS_TOOFAR16
18081 bit accordingly. */
18083 static int
18084 relaxed_micromips_16bit_branch_length (fragS *fragp, asection *sec, int update)
18086 bfd_boolean toofar;
18088 if (fragp
18089 && S_IS_DEFINED (fragp->fr_symbol)
18090 && !S_IS_WEAK (fragp->fr_symbol)
18091 && sec == S_GET_SEGMENT (fragp->fr_symbol))
18093 addressT addr;
18094 offsetT val;
18095 int type;
18097 val = S_GET_VALUE (fragp->fr_symbol) + fragp->fr_offset;
18098 /* Ignore the low bit in the target, since it will be set
18099 for a text label. */
18100 if ((val & 1) != 0)
18101 --val;
18103 /* Assume this is a 2-byte branch. */
18104 addr = fragp->fr_address + fragp->fr_fix + 2;
18106 /* We try to avoid the infinite loop by not adding 2 more bytes for
18107 long branches. */
18109 val -= addr;
18111 type = RELAX_MICROMIPS_TYPE (fragp->fr_subtype);
18112 if (type == 'D')
18113 toofar = val < - (0x200 << 1) || val >= (0x200 << 1);
18114 else if (type == 'E')
18115 toofar = val < - (0x40 << 1) || val >= (0x40 << 1);
18116 else
18117 abort ();
18119 else
18120 /* If the symbol is not defined or it's in a different segment,
18121 we emit a normal 32-bit branch. */
18122 toofar = TRUE;
18124 if (fragp && update
18125 && toofar != RELAX_MICROMIPS_TOOFAR16 (fragp->fr_subtype))
18126 fragp->fr_subtype
18127 = toofar ? RELAX_MICROMIPS_MARK_TOOFAR16 (fragp->fr_subtype)
18128 : RELAX_MICROMIPS_CLEAR_TOOFAR16 (fragp->fr_subtype);
18130 if (toofar)
18131 return 4;
18133 return 2;
18136 /* Estimate the size of a frag before relaxing. Unless this is the
18137 mips16, we are not really relaxing here, and the final size is
18138 encoded in the subtype information. For the mips16, we have to
18139 decide whether we are using an extended opcode or not. */
18142 md_estimate_size_before_relax (fragS *fragp, asection *segtype)
18144 int change;
18146 if (RELAX_BRANCH_P (fragp->fr_subtype))
18149 fragp->fr_var = relaxed_branch_length (fragp, segtype, FALSE);
18151 return fragp->fr_var;
18154 if (RELAX_MIPS16_P (fragp->fr_subtype))
18156 /* We don't want to modify the EXTENDED bit here; it might get us
18157 into infinite loops. We change it only in mips_relax_frag(). */
18158 if (RELAX_MIPS16_MACRO (fragp->fr_subtype))
18159 return RELAX_MIPS16_E2 (fragp->fr_subtype) ? 8 : 12;
18160 else
18161 return RELAX_MIPS16_EXTENDED (fragp->fr_subtype) ? 4 : 2;
18164 if (RELAX_MICROMIPS_P (fragp->fr_subtype))
18166 int length = 4;
18168 if (RELAX_MICROMIPS_TYPE (fragp->fr_subtype) != 0)
18169 length = relaxed_micromips_16bit_branch_length (fragp, segtype, FALSE);
18170 if (length == 4 && RELAX_MICROMIPS_RELAX32 (fragp->fr_subtype))
18171 length = relaxed_micromips_32bit_branch_length (fragp, segtype, FALSE);
18172 fragp->fr_var = length;
18174 return length;
18177 if (mips_pic == VXWORKS_PIC)
18178 /* For vxworks, GOT16 relocations never have a corresponding LO16. */
18179 change = 0;
18180 else if (RELAX_PIC (fragp->fr_subtype))
18181 change = pic_need_relax (fragp->fr_symbol);
18182 else
18183 change = nopic_need_relax (fragp->fr_symbol, 0);
18185 if (change)
18187 fragp->fr_subtype |= RELAX_USE_SECOND;
18188 return -RELAX_FIRST (fragp->fr_subtype);
18190 else
18191 return -RELAX_SECOND (fragp->fr_subtype);
18194 /* This is called to see whether a reloc against a defined symbol
18195 should be converted into a reloc against a section. */
18198 mips_fix_adjustable (fixS *fixp)
18200 if (fixp->fx_r_type == BFD_RELOC_VTABLE_INHERIT
18201 || fixp->fx_r_type == BFD_RELOC_VTABLE_ENTRY)
18202 return 0;
18204 if (fixp->fx_addsy == NULL)
18205 return 1;
18207 /* Allow relocs used for EH tables. */
18208 if (fixp->fx_r_type == BFD_RELOC_32_PCREL)
18209 return 1;
18211 /* If symbol SYM is in a mergeable section, relocations of the form
18212 SYM + 0 can usually be made section-relative. The mergeable data
18213 is then identified by the section offset rather than by the symbol.
18215 However, if we're generating REL LO16 relocations, the offset is split
18216 between the LO16 and partnering high part relocation. The linker will
18217 need to recalculate the complete offset in order to correctly identify
18218 the merge data.
18220 The linker has traditionally not looked for the partnering high part
18221 relocation, and has thus allowed orphaned R_MIPS_LO16 relocations to be
18222 placed anywhere. Rather than break backwards compatibility by changing
18223 this, it seems better not to force the issue, and instead keep the
18224 original symbol. This will work with either linker behavior. */
18225 if ((lo16_reloc_p (fixp->fx_r_type)
18226 || reloc_needs_lo_p (fixp->fx_r_type))
18227 && HAVE_IN_PLACE_ADDENDS
18228 && (S_GET_SEGMENT (fixp->fx_addsy)->flags & SEC_MERGE) != 0)
18229 return 0;
18231 /* There is no place to store an in-place offset for JALR relocations. */
18232 if (jalr_reloc_p (fixp->fx_r_type) && HAVE_IN_PLACE_ADDENDS)
18233 return 0;
18235 /* Likewise an in-range offset of limited PC-relative relocations may
18236 overflow the in-place relocatable field if recalculated against the
18237 start address of the symbol's containing section.
18239 Also, PC relative relocations for MIPS R6 need to be symbol rather than
18240 section relative to allow linker relaxations to be performed later on. */
18241 if (limited_pcrel_reloc_p (fixp->fx_r_type)
18242 && (HAVE_IN_PLACE_ADDENDS || ISA_IS_R6 (file_mips_opts.isa)))
18243 return 0;
18245 /* R_MIPS16_26 relocations against non-MIPS16 functions might resolve
18246 to a floating-point stub. The same is true for non-R_MIPS16_26
18247 relocations against MIPS16 functions; in this case, the stub becomes
18248 the function's canonical address.
18250 Floating-point stubs are stored in unique .mips16.call.* or
18251 .mips16.fn.* sections. If a stub T for function F is in section S,
18252 the first relocation in section S must be against F; this is how the
18253 linker determines the target function. All relocations that might
18254 resolve to T must also be against F. We therefore have the following
18255 restrictions, which are given in an intentionally-redundant way:
18257 1. We cannot reduce R_MIPS16_26 relocations against non-MIPS16
18258 symbols.
18260 2. We cannot reduce a stub's relocations against non-MIPS16 symbols
18261 if that stub might be used.
18263 3. We cannot reduce non-R_MIPS16_26 relocations against MIPS16
18264 symbols.
18266 4. We cannot reduce a stub's relocations against MIPS16 symbols if
18267 that stub might be used.
18269 There is a further restriction:
18271 5. We cannot reduce jump relocations (R_MIPS_26, R_MIPS16_26 or
18272 R_MICROMIPS_26_S1) or branch relocations (R_MIPS_PC26_S2,
18273 R_MIPS_PC21_S2, R_MIPS_PC16, R_MIPS16_PC16_S1,
18274 R_MICROMIPS_PC16_S1, R_MICROMIPS_PC10_S1 or R_MICROMIPS_PC7_S1)
18275 against MIPS16 or microMIPS symbols because we need to keep the
18276 MIPS16 or microMIPS symbol for the purpose of mode mismatch
18277 detection and JAL or BAL to JALX instruction conversion in the
18278 linker.
18280 For simplicity, we deal with (3)-(4) by not reducing _any_ relocation
18281 against a MIPS16 symbol. We deal with (5) by additionally leaving
18282 alone any jump and branch relocations against a microMIPS symbol.
18284 We deal with (1)-(2) by saying that, if there's a R_MIPS16_26
18285 relocation against some symbol R, no relocation against R may be
18286 reduced. (Note that this deals with (2) as well as (1) because
18287 relocations against global symbols will never be reduced on ELF
18288 targets.) This approach is a little simpler than trying to detect
18289 stub sections, and gives the "all or nothing" per-symbol consistency
18290 that we have for MIPS16 symbols. */
18291 if (fixp->fx_subsy == NULL
18292 && (ELF_ST_IS_MIPS16 (S_GET_OTHER (fixp->fx_addsy))
18293 || (ELF_ST_IS_MICROMIPS (S_GET_OTHER (fixp->fx_addsy))
18294 && (jmp_reloc_p (fixp->fx_r_type)
18295 || b_reloc_p (fixp->fx_r_type)))
18296 || *symbol_get_tc (fixp->fx_addsy)))
18297 return 0;
18299 return 1;
18302 /* Translate internal representation of relocation info to BFD target
18303 format. */
18305 arelent **
18306 tc_gen_reloc (asection *section ATTRIBUTE_UNUSED, fixS *fixp)
18308 static arelent *retval[4];
18309 arelent *reloc;
18310 bfd_reloc_code_real_type code;
18312 memset (retval, 0, sizeof(retval));
18313 reloc = retval[0] = XCNEW (arelent);
18314 reloc->sym_ptr_ptr = XNEW (asymbol *);
18315 *reloc->sym_ptr_ptr = symbol_get_bfdsym (fixp->fx_addsy);
18316 reloc->address = fixp->fx_frag->fr_address + fixp->fx_where;
18318 if (fixp->fx_pcrel)
18320 gas_assert (fixp->fx_r_type == BFD_RELOC_16_PCREL_S2
18321 || fixp->fx_r_type == BFD_RELOC_MIPS16_16_PCREL_S1
18322 || fixp->fx_r_type == BFD_RELOC_MICROMIPS_7_PCREL_S1
18323 || fixp->fx_r_type == BFD_RELOC_MICROMIPS_10_PCREL_S1
18324 || fixp->fx_r_type == BFD_RELOC_MICROMIPS_16_PCREL_S1
18325 || fixp->fx_r_type == BFD_RELOC_32_PCREL
18326 || fixp->fx_r_type == BFD_RELOC_MIPS_21_PCREL_S2
18327 || fixp->fx_r_type == BFD_RELOC_MIPS_26_PCREL_S2
18328 || fixp->fx_r_type == BFD_RELOC_MIPS_18_PCREL_S3
18329 || fixp->fx_r_type == BFD_RELOC_MIPS_19_PCREL_S2
18330 || fixp->fx_r_type == BFD_RELOC_HI16_S_PCREL
18331 || fixp->fx_r_type == BFD_RELOC_LO16_PCREL);
18333 /* At this point, fx_addnumber is "symbol offset - pcrel address".
18334 Relocations want only the symbol offset. */
18335 switch (fixp->fx_r_type)
18337 case BFD_RELOC_MIPS_18_PCREL_S3:
18338 reloc->addend = fixp->fx_addnumber + (reloc->address & ~7);
18339 break;
18340 default:
18341 reloc->addend = fixp->fx_addnumber + reloc->address;
18342 break;
18345 else if (HAVE_IN_PLACE_ADDENDS
18346 && fixp->fx_r_type == BFD_RELOC_MICROMIPS_JMP
18347 && (read_compressed_insn (fixp->fx_frag->fr_literal
18348 + fixp->fx_where, 4) >> 26) == 0x3c)
18350 /* Shift is 2, unusually, for microMIPS JALX. Adjust the in-place
18351 addend accordingly. */
18352 reloc->addend = fixp->fx_addnumber >> 1;
18354 else
18355 reloc->addend = fixp->fx_addnumber;
18357 /* Since the old MIPS ELF ABI uses Rel instead of Rela, encode the vtable
18358 entry to be used in the relocation's section offset. */
18359 if (! HAVE_NEWABI && fixp->fx_r_type == BFD_RELOC_VTABLE_ENTRY)
18361 reloc->address = reloc->addend;
18362 reloc->addend = 0;
18365 code = fixp->fx_r_type;
18367 reloc->howto = bfd_reloc_type_lookup (stdoutput, code);
18368 if (reloc->howto == NULL)
18370 as_bad_where (fixp->fx_file, fixp->fx_line,
18371 _("cannot represent %s relocation in this object file"
18372 " format"),
18373 bfd_get_reloc_code_name (code));
18374 retval[0] = NULL;
18377 return retval;
18380 /* Relax a machine dependent frag. This returns the amount by which
18381 the current size of the frag should change. */
18384 mips_relax_frag (asection *sec, fragS *fragp, long stretch)
18386 if (RELAX_BRANCH_P (fragp->fr_subtype))
18388 offsetT old_var = fragp->fr_var;
18390 fragp->fr_var = relaxed_branch_length (fragp, sec, TRUE);
18392 return fragp->fr_var - old_var;
18395 if (RELAX_MICROMIPS_P (fragp->fr_subtype))
18397 offsetT old_var = fragp->fr_var;
18398 offsetT new_var = 4;
18400 if (RELAX_MICROMIPS_TYPE (fragp->fr_subtype) != 0)
18401 new_var = relaxed_micromips_16bit_branch_length (fragp, sec, TRUE);
18402 if (new_var == 4 && RELAX_MICROMIPS_RELAX32 (fragp->fr_subtype))
18403 new_var = relaxed_micromips_32bit_branch_length (fragp, sec, TRUE);
18404 fragp->fr_var = new_var;
18406 return new_var - old_var;
18409 if (! RELAX_MIPS16_P (fragp->fr_subtype))
18410 return 0;
18412 if (!mips16_extended_frag (fragp, sec, stretch))
18414 if (RELAX_MIPS16_MACRO (fragp->fr_subtype))
18416 fragp->fr_subtype = RELAX_MIPS16_CLEAR_MACRO (fragp->fr_subtype);
18417 return RELAX_MIPS16_E2 (fragp->fr_subtype) ? -6 : -10;
18419 else if (RELAX_MIPS16_EXTENDED (fragp->fr_subtype))
18421 fragp->fr_subtype = RELAX_MIPS16_CLEAR_EXTENDED (fragp->fr_subtype);
18422 return -2;
18424 else
18425 return 0;
18427 else if (!mips16_macro_frag (fragp, sec, stretch))
18429 if (RELAX_MIPS16_MACRO (fragp->fr_subtype))
18431 fragp->fr_subtype = RELAX_MIPS16_CLEAR_MACRO (fragp->fr_subtype);
18432 fragp->fr_subtype = RELAX_MIPS16_MARK_EXTENDED (fragp->fr_subtype);
18433 return RELAX_MIPS16_E2 (fragp->fr_subtype) ? -4 : -8;
18435 else if (!RELAX_MIPS16_EXTENDED (fragp->fr_subtype))
18437 fragp->fr_subtype = RELAX_MIPS16_MARK_EXTENDED (fragp->fr_subtype);
18438 return 2;
18440 else
18441 return 0;
18443 else
18445 if (RELAX_MIPS16_MACRO (fragp->fr_subtype))
18446 return 0;
18447 else if (RELAX_MIPS16_EXTENDED (fragp->fr_subtype))
18449 fragp->fr_subtype = RELAX_MIPS16_CLEAR_EXTENDED (fragp->fr_subtype);
18450 fragp->fr_subtype = RELAX_MIPS16_MARK_MACRO (fragp->fr_subtype);
18451 return RELAX_MIPS16_E2 (fragp->fr_subtype) ? 4 : 8;
18453 else
18455 fragp->fr_subtype = RELAX_MIPS16_MARK_MACRO (fragp->fr_subtype);
18456 return RELAX_MIPS16_E2 (fragp->fr_subtype) ? 6 : 10;
18460 return 0;
18463 /* Convert a machine dependent frag. */
18465 void
18466 md_convert_frag (bfd *abfd ATTRIBUTE_UNUSED, segT asec, fragS *fragp)
18468 if (RELAX_BRANCH_P (fragp->fr_subtype))
18470 char *buf;
18471 unsigned long insn;
18472 fixS *fixp;
18474 buf = fragp->fr_literal + fragp->fr_fix;
18475 insn = read_insn (buf);
18477 if (!RELAX_BRANCH_TOOFAR (fragp->fr_subtype))
18479 /* We generate a fixup instead of applying it right now
18480 because, if there are linker relaxations, we're going to
18481 need the relocations. */
18482 fixp = fix_new (fragp, buf - fragp->fr_literal, 4,
18483 fragp->fr_symbol, fragp->fr_offset,
18484 TRUE, BFD_RELOC_16_PCREL_S2);
18485 fixp->fx_file = fragp->fr_file;
18486 fixp->fx_line = fragp->fr_line;
18488 buf = write_insn (buf, insn);
18490 else
18492 int i;
18494 as_warn_where (fragp->fr_file, fragp->fr_line,
18495 _("relaxed out-of-range branch into a jump"));
18497 if (RELAX_BRANCH_UNCOND (fragp->fr_subtype))
18498 goto uncond;
18500 if (!RELAX_BRANCH_LIKELY (fragp->fr_subtype))
18502 /* Reverse the branch. */
18503 switch ((insn >> 28) & 0xf)
18505 case 4:
18506 if ((insn & 0xff000000) == 0x47000000
18507 || (insn & 0xff600000) == 0x45600000)
18509 /* BZ.df/BNZ.df, BZ.V/BNZ.V can have the condition
18510 reversed by tweaking bit 23. */
18511 insn ^= 0x00800000;
18513 else
18515 /* bc[0-3][tf]l? instructions can have the condition
18516 reversed by tweaking a single TF bit, and their
18517 opcodes all have 0x4???????. */
18518 gas_assert ((insn & 0xf3e00000) == 0x41000000);
18519 insn ^= 0x00010000;
18521 break;
18523 case 0:
18524 /* bltz 0x04000000 bgez 0x04010000
18525 bltzal 0x04100000 bgezal 0x04110000 */
18526 gas_assert ((insn & 0xfc0e0000) == 0x04000000);
18527 insn ^= 0x00010000;
18528 break;
18530 case 1:
18531 /* beq 0x10000000 bne 0x14000000
18532 blez 0x18000000 bgtz 0x1c000000 */
18533 insn ^= 0x04000000;
18534 break;
18536 default:
18537 abort ();
18541 if (RELAX_BRANCH_LINK (fragp->fr_subtype))
18543 /* Clear the and-link bit. */
18544 gas_assert ((insn & 0xfc1c0000) == 0x04100000);
18546 /* bltzal 0x04100000 bgezal 0x04110000
18547 bltzall 0x04120000 bgezall 0x04130000 */
18548 insn &= ~0x00100000;
18551 /* Branch over the branch (if the branch was likely) or the
18552 full jump (not likely case). Compute the offset from the
18553 current instruction to branch to. */
18554 if (RELAX_BRANCH_LIKELY (fragp->fr_subtype))
18555 i = 16;
18556 else
18558 /* How many bytes in instructions we've already emitted? */
18559 i = buf - fragp->fr_literal - fragp->fr_fix;
18560 /* How many bytes in instructions from here to the end? */
18561 i = fragp->fr_var - i;
18563 /* Convert to instruction count. */
18564 i >>= 2;
18565 /* Branch counts from the next instruction. */
18566 i--;
18567 insn |= i;
18568 /* Branch over the jump. */
18569 buf = write_insn (buf, insn);
18571 /* nop */
18572 buf = write_insn (buf, 0);
18574 if (RELAX_BRANCH_LIKELY (fragp->fr_subtype))
18576 /* beql $0, $0, 2f */
18577 insn = 0x50000000;
18578 /* Compute the PC offset from the current instruction to
18579 the end of the variable frag. */
18580 /* How many bytes in instructions we've already emitted? */
18581 i = buf - fragp->fr_literal - fragp->fr_fix;
18582 /* How many bytes in instructions from here to the end? */
18583 i = fragp->fr_var - i;
18584 /* Convert to instruction count. */
18585 i >>= 2;
18586 /* Don't decrement i, because we want to branch over the
18587 delay slot. */
18588 insn |= i;
18590 buf = write_insn (buf, insn);
18591 buf = write_insn (buf, 0);
18594 uncond:
18595 if (!RELAX_BRANCH_PIC (fragp->fr_subtype))
18597 /* j or jal. */
18598 insn = (RELAX_BRANCH_LINK (fragp->fr_subtype)
18599 ? 0x0c000000 : 0x08000000);
18601 fixp = fix_new (fragp, buf - fragp->fr_literal, 4,
18602 fragp->fr_symbol, fragp->fr_offset,
18603 FALSE, BFD_RELOC_MIPS_JMP);
18604 fixp->fx_file = fragp->fr_file;
18605 fixp->fx_line = fragp->fr_line;
18607 buf = write_insn (buf, insn);
18609 else
18611 unsigned long at = RELAX_BRANCH_AT (fragp->fr_subtype);
18613 /* lw/ld $at, <sym>($gp) R_MIPS_GOT16 */
18614 insn = HAVE_64BIT_ADDRESSES ? 0xdf800000 : 0x8f800000;
18615 insn |= at << OP_SH_RT;
18617 fixp = fix_new (fragp, buf - fragp->fr_literal, 4,
18618 fragp->fr_symbol, fragp->fr_offset,
18619 FALSE, BFD_RELOC_MIPS_GOT16);
18620 fixp->fx_file = fragp->fr_file;
18621 fixp->fx_line = fragp->fr_line;
18623 buf = write_insn (buf, insn);
18625 if (mips_opts.isa == ISA_MIPS1)
18626 /* nop */
18627 buf = write_insn (buf, 0);
18629 /* d/addiu $at, $at, <sym> R_MIPS_LO16 */
18630 insn = HAVE_64BIT_ADDRESSES ? 0x64000000 : 0x24000000;
18631 insn |= at << OP_SH_RS | at << OP_SH_RT;
18633 fixp = fix_new (fragp, buf - fragp->fr_literal, 4,
18634 fragp->fr_symbol, fragp->fr_offset,
18635 FALSE, BFD_RELOC_LO16);
18636 fixp->fx_file = fragp->fr_file;
18637 fixp->fx_line = fragp->fr_line;
18639 buf = write_insn (buf, insn);
18641 /* j(al)r $at. */
18642 if (RELAX_BRANCH_LINK (fragp->fr_subtype))
18643 insn = 0x0000f809;
18644 else
18645 insn = 0x00000008;
18646 insn |= at << OP_SH_RS;
18648 buf = write_insn (buf, insn);
18652 fragp->fr_fix += fragp->fr_var;
18653 gas_assert (buf == fragp->fr_literal + fragp->fr_fix);
18654 return;
18657 /* Relax microMIPS branches. */
18658 if (RELAX_MICROMIPS_P (fragp->fr_subtype))
18660 char *buf = fragp->fr_literal + fragp->fr_fix;
18661 bfd_boolean compact = RELAX_MICROMIPS_COMPACT (fragp->fr_subtype);
18662 bfd_boolean insn32 = RELAX_MICROMIPS_INSN32 (fragp->fr_subtype);
18663 bfd_boolean nods = RELAX_MICROMIPS_NODS (fragp->fr_subtype);
18664 bfd_boolean pic = RELAX_MICROMIPS_PIC (fragp->fr_subtype);
18665 bfd_boolean al = RELAX_MICROMIPS_LINK (fragp->fr_subtype);
18666 int type = RELAX_MICROMIPS_TYPE (fragp->fr_subtype);
18667 bfd_boolean short_ds;
18668 unsigned long insn;
18669 fixS *fixp;
18671 fragp->fr_fix += fragp->fr_var;
18673 /* Handle 16-bit branches that fit or are forced to fit. */
18674 if (type != 0 && !RELAX_MICROMIPS_TOOFAR16 (fragp->fr_subtype))
18676 /* We generate a fixup instead of applying it right now,
18677 because if there is linker relaxation, we're going to
18678 need the relocations. */
18679 switch (type)
18681 case 'D':
18682 fixp = fix_new (fragp, buf - fragp->fr_literal, 2,
18683 fragp->fr_symbol, fragp->fr_offset,
18684 TRUE, BFD_RELOC_MICROMIPS_10_PCREL_S1);
18685 break;
18686 case 'E':
18687 fixp = fix_new (fragp, buf - fragp->fr_literal, 2,
18688 fragp->fr_symbol, fragp->fr_offset,
18689 TRUE, BFD_RELOC_MICROMIPS_7_PCREL_S1);
18690 break;
18691 default:
18692 abort ();
18695 fixp->fx_file = fragp->fr_file;
18696 fixp->fx_line = fragp->fr_line;
18698 /* These relocations can have an addend that won't fit in
18699 2 octets. */
18700 fixp->fx_no_overflow = 1;
18702 return;
18705 /* Handle 32-bit branches that fit or are forced to fit. */
18706 if (!RELAX_MICROMIPS_RELAX32 (fragp->fr_subtype)
18707 || !RELAX_MICROMIPS_TOOFAR32 (fragp->fr_subtype))
18709 /* We generate a fixup instead of applying it right now,
18710 because if there is linker relaxation, we're going to
18711 need the relocations. */
18712 fixp = fix_new (fragp, buf - fragp->fr_literal, 4,
18713 fragp->fr_symbol, fragp->fr_offset,
18714 TRUE, BFD_RELOC_MICROMIPS_16_PCREL_S1);
18715 fixp->fx_file = fragp->fr_file;
18716 fixp->fx_line = fragp->fr_line;
18718 if (type == 0)
18720 insn = read_compressed_insn (buf, 4);
18721 buf += 4;
18723 if (nods)
18725 /* Check the short-delay-slot bit. */
18726 if (!al || (insn & 0x02000000) != 0)
18727 buf = write_compressed_insn (buf, 0x0c00, 2);
18728 else
18729 buf = write_compressed_insn (buf, 0x00000000, 4);
18732 gas_assert (buf == fragp->fr_literal + fragp->fr_fix);
18733 return;
18737 /* Relax 16-bit branches to 32-bit branches. */
18738 if (type != 0)
18740 insn = read_compressed_insn (buf, 2);
18742 if ((insn & 0xfc00) == 0xcc00) /* b16 */
18743 insn = 0x94000000; /* beq */
18744 else if ((insn & 0xdc00) == 0x8c00) /* beqz16/bnez16 */
18746 unsigned long regno;
18748 regno = (insn >> MICROMIPSOP_SH_MD) & MICROMIPSOP_MASK_MD;
18749 regno = micromips_to_32_reg_d_map [regno];
18750 insn = ((insn & 0x2000) << 16) | 0x94000000; /* beq/bne */
18751 insn |= regno << MICROMIPSOP_SH_RS;
18753 else
18754 abort ();
18756 /* Nothing else to do, just write it out. */
18757 if (!RELAX_MICROMIPS_RELAX32 (fragp->fr_subtype)
18758 || !RELAX_MICROMIPS_TOOFAR32 (fragp->fr_subtype))
18760 buf = write_compressed_insn (buf, insn, 4);
18761 if (nods)
18762 buf = write_compressed_insn (buf, 0x0c00, 2);
18763 gas_assert (buf == fragp->fr_literal + fragp->fr_fix);
18764 return;
18767 else
18768 insn = read_compressed_insn (buf, 4);
18770 /* Relax 32-bit branches to a sequence of instructions. */
18771 as_warn_where (fragp->fr_file, fragp->fr_line,
18772 _("relaxed out-of-range branch into a jump"));
18774 /* Set the short-delay-slot bit. */
18775 short_ds = !al || (insn & 0x02000000) != 0;
18777 if (!RELAX_MICROMIPS_UNCOND (fragp->fr_subtype))
18779 symbolS *l;
18781 /* Reverse the branch. */
18782 if ((insn & 0xfc000000) == 0x94000000 /* beq */
18783 || (insn & 0xfc000000) == 0xb4000000) /* bne */
18784 insn ^= 0x20000000;
18785 else if ((insn & 0xffe00000) == 0x40000000 /* bltz */
18786 || (insn & 0xffe00000) == 0x40400000 /* bgez */
18787 || (insn & 0xffe00000) == 0x40800000 /* blez */
18788 || (insn & 0xffe00000) == 0x40c00000 /* bgtz */
18789 || (insn & 0xffe00000) == 0x40a00000 /* bnezc */
18790 || (insn & 0xffe00000) == 0x40e00000 /* beqzc */
18791 || (insn & 0xffe00000) == 0x40200000 /* bltzal */
18792 || (insn & 0xffe00000) == 0x40600000 /* bgezal */
18793 || (insn & 0xffe00000) == 0x42200000 /* bltzals */
18794 || (insn & 0xffe00000) == 0x42600000) /* bgezals */
18795 insn ^= 0x00400000;
18796 else if ((insn & 0xffe30000) == 0x43800000 /* bc1f */
18797 || (insn & 0xffe30000) == 0x43a00000 /* bc1t */
18798 || (insn & 0xffe30000) == 0x42800000 /* bc2f */
18799 || (insn & 0xffe30000) == 0x42a00000) /* bc2t */
18800 insn ^= 0x00200000;
18801 else if ((insn & 0xff000000) == 0x83000000 /* BZ.df
18802 BNZ.df */
18803 || (insn & 0xff600000) == 0x81600000) /* BZ.V
18804 BNZ.V */
18805 insn ^= 0x00800000;
18806 else
18807 abort ();
18809 if (al)
18811 /* Clear the and-link and short-delay-slot bits. */
18812 gas_assert ((insn & 0xfda00000) == 0x40200000);
18814 /* bltzal 0x40200000 bgezal 0x40600000 */
18815 /* bltzals 0x42200000 bgezals 0x42600000 */
18816 insn &= ~0x02200000;
18819 /* Make a label at the end for use with the branch. */
18820 l = symbol_new (micromips_label_name (), asec, fragp->fr_fix, fragp);
18821 micromips_label_inc ();
18822 S_SET_OTHER (l, ELF_ST_SET_MICROMIPS (S_GET_OTHER (l)));
18824 /* Refer to it. */
18825 fixp = fix_new (fragp, buf - fragp->fr_literal, 4, l, 0, TRUE,
18826 BFD_RELOC_MICROMIPS_16_PCREL_S1);
18827 fixp->fx_file = fragp->fr_file;
18828 fixp->fx_line = fragp->fr_line;
18830 /* Branch over the jump. */
18831 buf = write_compressed_insn (buf, insn, 4);
18833 if (!compact)
18835 /* nop */
18836 if (insn32)
18837 buf = write_compressed_insn (buf, 0x00000000, 4);
18838 else
18839 buf = write_compressed_insn (buf, 0x0c00, 2);
18843 if (!pic)
18845 unsigned long jal = (short_ds || nods
18846 ? 0x74000000 : 0xf4000000); /* jal/s */
18848 /* j/jal/jals <sym> R_MICROMIPS_26_S1 */
18849 insn = al ? jal : 0xd4000000;
18851 fixp = fix_new (fragp, buf - fragp->fr_literal, 4,
18852 fragp->fr_symbol, fragp->fr_offset,
18853 FALSE, BFD_RELOC_MICROMIPS_JMP);
18854 fixp->fx_file = fragp->fr_file;
18855 fixp->fx_line = fragp->fr_line;
18857 buf = write_compressed_insn (buf, insn, 4);
18859 if (compact || nods)
18861 /* nop */
18862 if (insn32)
18863 buf = write_compressed_insn (buf, 0x00000000, 4);
18864 else
18865 buf = write_compressed_insn (buf, 0x0c00, 2);
18868 else
18870 unsigned long at = RELAX_MICROMIPS_AT (fragp->fr_subtype);
18872 /* lw/ld $at, <sym>($gp) R_MICROMIPS_GOT16 */
18873 insn = HAVE_64BIT_ADDRESSES ? 0xdc1c0000 : 0xfc1c0000;
18874 insn |= at << MICROMIPSOP_SH_RT;
18876 fixp = fix_new (fragp, buf - fragp->fr_literal, 4,
18877 fragp->fr_symbol, fragp->fr_offset,
18878 FALSE, BFD_RELOC_MICROMIPS_GOT16);
18879 fixp->fx_file = fragp->fr_file;
18880 fixp->fx_line = fragp->fr_line;
18882 buf = write_compressed_insn (buf, insn, 4);
18884 /* d/addiu $at, $at, <sym> R_MICROMIPS_LO16 */
18885 insn = HAVE_64BIT_ADDRESSES ? 0x5c000000 : 0x30000000;
18886 insn |= at << MICROMIPSOP_SH_RT | at << MICROMIPSOP_SH_RS;
18888 fixp = fix_new (fragp, buf - fragp->fr_literal, 4,
18889 fragp->fr_symbol, fragp->fr_offset,
18890 FALSE, BFD_RELOC_MICROMIPS_LO16);
18891 fixp->fx_file = fragp->fr_file;
18892 fixp->fx_line = fragp->fr_line;
18894 buf = write_compressed_insn (buf, insn, 4);
18896 if (insn32)
18898 /* jr/jalr $at */
18899 insn = 0x00000f3c | (al ? RA : ZERO) << MICROMIPSOP_SH_RT;
18900 insn |= at << MICROMIPSOP_SH_RS;
18902 buf = write_compressed_insn (buf, insn, 4);
18904 if (compact || nods)
18905 /* nop */
18906 buf = write_compressed_insn (buf, 0x00000000, 4);
18908 else
18910 /* jr/jrc/jalr/jalrs $at */
18911 unsigned long jalr = short_ds ? 0x45e0 : 0x45c0; /* jalr/s */
18912 unsigned long jr = compact || nods ? 0x45a0 : 0x4580; /* jr/c */
18914 insn = al ? jalr : jr;
18915 insn |= at << MICROMIPSOP_SH_MJ;
18917 buf = write_compressed_insn (buf, insn, 2);
18918 if (al && nods)
18920 /* nop */
18921 if (short_ds)
18922 buf = write_compressed_insn (buf, 0x0c00, 2);
18923 else
18924 buf = write_compressed_insn (buf, 0x00000000, 4);
18929 gas_assert (buf == fragp->fr_literal + fragp->fr_fix);
18930 return;
18933 if (RELAX_MIPS16_P (fragp->fr_subtype))
18935 int type;
18936 const struct mips_int_operand *operand;
18937 offsetT val;
18938 char *buf;
18939 unsigned int user_length;
18940 bfd_boolean need_reloc;
18941 unsigned long insn;
18942 bfd_boolean mac;
18943 bfd_boolean ext;
18944 segT symsec;
18946 type = RELAX_MIPS16_TYPE (fragp->fr_subtype);
18947 operand = mips16_immed_operand (type, FALSE);
18949 mac = RELAX_MIPS16_MACRO (fragp->fr_subtype);
18950 ext = RELAX_MIPS16_EXTENDED (fragp->fr_subtype);
18951 val = resolve_symbol_value (fragp->fr_symbol) + fragp->fr_offset;
18953 symsec = S_GET_SEGMENT (fragp->fr_symbol);
18954 need_reloc = (S_FORCE_RELOC (fragp->fr_symbol, TRUE)
18955 || (operand->root.type == OP_PCREL && !mac
18956 ? asec != symsec
18957 : !bfd_is_abs_section (symsec)));
18959 if (operand->root.type == OP_PCREL && !mac)
18961 const struct mips_pcrel_operand *pcrel_op;
18963 pcrel_op = (const struct mips_pcrel_operand *) operand;
18965 if (pcrel_op->include_isa_bit && !need_reloc)
18967 if (!mips_ignore_branch_isa
18968 && !ELF_ST_IS_MIPS16 (S_GET_OTHER (fragp->fr_symbol)))
18969 as_bad_where (fragp->fr_file, fragp->fr_line,
18970 _("branch to a symbol in another ISA mode"));
18971 else if ((fragp->fr_offset & 0x1) != 0)
18972 as_bad_where (fragp->fr_file, fragp->fr_line,
18973 _("branch to misaligned address (0x%lx)"),
18974 (long) val);
18977 val = mips16_pcrel_val (fragp, pcrel_op, val, 0);
18979 /* Make sure the section winds up with the alignment we have
18980 assumed. */
18981 if (operand->shift > 0)
18982 record_alignment (asec, operand->shift);
18985 if (RELAX_MIPS16_JAL_DSLOT (fragp->fr_subtype)
18986 || RELAX_MIPS16_DSLOT (fragp->fr_subtype))
18988 if (mac)
18989 as_warn_where (fragp->fr_file, fragp->fr_line,
18990 _("macro instruction expanded into multiple "
18991 "instructions in a branch delay slot"));
18992 else if (ext)
18993 as_warn_where (fragp->fr_file, fragp->fr_line,
18994 _("extended instruction in a branch delay slot"));
18996 else if (RELAX_MIPS16_NOMACRO (fragp->fr_subtype) && mac)
18997 as_warn_where (fragp->fr_file, fragp->fr_line,
18998 _("macro instruction expanded into multiple "
18999 "instructions"));
19001 buf = fragp->fr_literal + fragp->fr_fix;
19003 insn = read_compressed_insn (buf, 2);
19004 if (ext)
19005 insn |= MIPS16_EXTEND;
19007 if (RELAX_MIPS16_USER_EXT (fragp->fr_subtype))
19008 user_length = 4;
19009 else if (RELAX_MIPS16_USER_SMALL (fragp->fr_subtype))
19010 user_length = 2;
19011 else
19012 user_length = 0;
19014 if (mac)
19016 unsigned long reg;
19017 unsigned long new;
19018 unsigned long op;
19019 bfd_boolean e2;
19021 gas_assert (type == 'A' || type == 'B' || type == 'E');
19022 gas_assert (RELAX_MIPS16_SYM32 (fragp->fr_subtype));
19024 e2 = RELAX_MIPS16_E2 (fragp->fr_subtype);
19026 if (need_reloc)
19028 fixS *fixp;
19030 gas_assert (!RELAX_MIPS16_PIC (fragp->fr_subtype));
19032 fixp = fix_new (fragp, buf - fragp->fr_literal, 4,
19033 fragp->fr_symbol, fragp->fr_offset,
19034 FALSE, BFD_RELOC_MIPS16_HI16_S);
19035 fixp->fx_file = fragp->fr_file;
19036 fixp->fx_line = fragp->fr_line;
19038 fixp = fix_new (fragp, buf - fragp->fr_literal + (e2 ? 4 : 8), 4,
19039 fragp->fr_symbol, fragp->fr_offset,
19040 FALSE, BFD_RELOC_MIPS16_LO16);
19041 fixp->fx_file = fragp->fr_file;
19042 fixp->fx_line = fragp->fr_line;
19044 val = 0;
19047 switch (insn & 0xf800)
19049 case 0x0800: /* ADDIU */
19050 reg = (insn >> 8) & 0x7;
19051 op = 0xf0004800 | (reg << 8);
19052 break;
19053 case 0xb000: /* LW */
19054 reg = (insn >> 8) & 0x7;
19055 op = 0xf0009800 | (reg << 8) | (reg << 5);
19056 break;
19057 case 0xf800: /* I64 */
19058 reg = (insn >> 5) & 0x7;
19059 switch (insn & 0x0700)
19061 case 0x0400: /* LD */
19062 op = 0xf0003800 | (reg << 8) | (reg << 5);
19063 break;
19064 case 0x0600: /* DADDIU */
19065 op = 0xf000fd00 | (reg << 5);
19066 break;
19067 default:
19068 abort ();
19070 break;
19071 default:
19072 abort ();
19075 new = (e2 ? 0xf0006820 : 0xf0006800) | (reg << 8); /* LUI/LI */
19076 new |= mips16_immed_extend ((val + 0x8000) >> 16, 16);
19077 buf = write_compressed_insn (buf, new, 4);
19078 if (!e2)
19080 new = 0xf4003000 | (reg << 8) | (reg << 5); /* SLL */
19081 buf = write_compressed_insn (buf, new, 4);
19083 op |= mips16_immed_extend (val, 16);
19084 buf = write_compressed_insn (buf, op, 4);
19086 fragp->fr_fix += e2 ? 8 : 12;
19088 else
19090 unsigned int length = ext ? 4 : 2;
19092 if (need_reloc)
19094 bfd_reloc_code_real_type reloc = BFD_RELOC_NONE;
19095 fixS *fixp;
19097 switch (type)
19099 case 'p':
19100 case 'q':
19101 reloc = BFD_RELOC_MIPS16_16_PCREL_S1;
19102 break;
19103 default:
19104 break;
19106 if (mac || reloc == BFD_RELOC_NONE)
19107 as_bad_where (fragp->fr_file, fragp->fr_line,
19108 _("unsupported relocation"));
19109 else if (ext)
19111 fixp = fix_new (fragp, buf - fragp->fr_literal, 4,
19112 fragp->fr_symbol, fragp->fr_offset,
19113 TRUE, reloc);
19114 fixp->fx_file = fragp->fr_file;
19115 fixp->fx_line = fragp->fr_line;
19117 else
19118 as_bad_where (fragp->fr_file, fragp->fr_line,
19119 _("invalid unextended operand value"));
19121 else
19122 mips16_immed (fragp->fr_file, fragp->fr_line, type,
19123 BFD_RELOC_UNUSED, val, user_length, &insn);
19125 gas_assert (mips16_opcode_length (insn) == length);
19126 write_compressed_insn (buf, insn, length);
19127 fragp->fr_fix += length;
19130 else
19132 relax_substateT subtype = fragp->fr_subtype;
19133 bfd_boolean second_longer = (subtype & RELAX_SECOND_LONGER) != 0;
19134 bfd_boolean use_second = (subtype & RELAX_USE_SECOND) != 0;
19135 unsigned int first, second;
19136 fixS *fixp;
19138 first = RELAX_FIRST (subtype);
19139 second = RELAX_SECOND (subtype);
19140 fixp = (fixS *) fragp->fr_opcode;
19142 /* If the delay slot chosen does not match the size of the instruction,
19143 then emit a warning. */
19144 if ((!use_second && (subtype & RELAX_DELAY_SLOT_SIZE_FIRST) != 0)
19145 || (use_second && (subtype & RELAX_DELAY_SLOT_SIZE_SECOND) != 0))
19147 relax_substateT s;
19148 const char *msg;
19150 s = subtype & (RELAX_DELAY_SLOT_16BIT
19151 | RELAX_DELAY_SLOT_SIZE_FIRST
19152 | RELAX_DELAY_SLOT_SIZE_SECOND);
19153 msg = macro_warning (s);
19154 if (msg != NULL)
19155 as_warn_where (fragp->fr_file, fragp->fr_line, "%s", msg);
19156 subtype &= ~s;
19159 /* Possibly emit a warning if we've chosen the longer option. */
19160 if (use_second == second_longer)
19162 relax_substateT s;
19163 const char *msg;
19165 s = (subtype
19166 & (RELAX_SECOND_LONGER | RELAX_NOMACRO | RELAX_DELAY_SLOT));
19167 msg = macro_warning (s);
19168 if (msg != NULL)
19169 as_warn_where (fragp->fr_file, fragp->fr_line, "%s", msg);
19170 subtype &= ~s;
19173 /* Go through all the fixups for the first sequence. Disable them
19174 (by marking them as done) if we're going to use the second
19175 sequence instead. */
19176 while (fixp
19177 && fixp->fx_frag == fragp
19178 && fixp->fx_where + second < fragp->fr_fix)
19180 if (subtype & RELAX_USE_SECOND)
19181 fixp->fx_done = 1;
19182 fixp = fixp->fx_next;
19185 /* Go through the fixups for the second sequence. Disable them if
19186 we're going to use the first sequence, otherwise adjust their
19187 addresses to account for the relaxation. */
19188 while (fixp && fixp->fx_frag == fragp)
19190 if (subtype & RELAX_USE_SECOND)
19191 fixp->fx_where -= first;
19192 else
19193 fixp->fx_done = 1;
19194 fixp = fixp->fx_next;
19197 /* Now modify the frag contents. */
19198 if (subtype & RELAX_USE_SECOND)
19200 char *start;
19202 start = fragp->fr_literal + fragp->fr_fix - first - second;
19203 memmove (start, start + first, second);
19204 fragp->fr_fix -= first;
19206 else
19207 fragp->fr_fix -= second;
19211 /* This function is called after the relocs have been generated.
19212 We've been storing mips16 text labels as odd. Here we convert them
19213 back to even for the convenience of the debugger. */
19215 void
19216 mips_frob_file_after_relocs (void)
19218 asymbol **syms;
19219 unsigned int count, i;
19221 syms = bfd_get_outsymbols (stdoutput);
19222 count = bfd_get_symcount (stdoutput);
19223 for (i = 0; i < count; i++, syms++)
19224 if (ELF_ST_IS_COMPRESSED (elf_symbol (*syms)->internal_elf_sym.st_other)
19225 && ((*syms)->value & 1) != 0)
19227 (*syms)->value &= ~1;
19228 /* If the symbol has an odd size, it was probably computed
19229 incorrectly, so adjust that as well. */
19230 if ((elf_symbol (*syms)->internal_elf_sym.st_size & 1) != 0)
19231 ++elf_symbol (*syms)->internal_elf_sym.st_size;
19235 /* This function is called whenever a label is defined, including fake
19236 labels instantiated off the dot special symbol. It is used when
19237 handling branch delays; if a branch has a label, we assume we cannot
19238 move it. This also bumps the value of the symbol by 1 in compressed
19239 code. */
19241 static void
19242 mips_record_label (symbolS *sym)
19244 segment_info_type *si = seg_info (now_seg);
19245 struct insn_label_list *l;
19247 if (free_insn_labels == NULL)
19248 l = XNEW (struct insn_label_list);
19249 else
19251 l = free_insn_labels;
19252 free_insn_labels = l->next;
19255 l->label = sym;
19256 l->next = si->label_list;
19257 si->label_list = l;
19260 /* This function is called as tc_frob_label() whenever a label is defined
19261 and adds a DWARF-2 record we only want for true labels. */
19263 void
19264 mips_define_label (symbolS *sym)
19266 mips_record_label (sym);
19267 dwarf2_emit_label (sym);
19270 /* This function is called by tc_new_dot_label whenever a new dot symbol
19271 is defined. */
19273 void
19274 mips_add_dot_label (symbolS *sym)
19276 mips_record_label (sym);
19277 if (mips_assembling_insn && HAVE_CODE_COMPRESSION)
19278 mips_compressed_mark_label (sym);
19281 /* Converting ASE flags from internal to .MIPS.abiflags values. */
19282 static unsigned int
19283 mips_convert_ase_flags (int ase)
19285 unsigned int ext_ases = 0;
19287 if (ase & ASE_DSP)
19288 ext_ases |= AFL_ASE_DSP;
19289 if (ase & ASE_DSPR2)
19290 ext_ases |= AFL_ASE_DSPR2;
19291 if (ase & ASE_DSPR3)
19292 ext_ases |= AFL_ASE_DSPR3;
19293 if (ase & ASE_EVA)
19294 ext_ases |= AFL_ASE_EVA;
19295 if (ase & ASE_MCU)
19296 ext_ases |= AFL_ASE_MCU;
19297 if (ase & ASE_MDMX)
19298 ext_ases |= AFL_ASE_MDMX;
19299 if (ase & ASE_MIPS3D)
19300 ext_ases |= AFL_ASE_MIPS3D;
19301 if (ase & ASE_MT)
19302 ext_ases |= AFL_ASE_MT;
19303 if (ase & ASE_SMARTMIPS)
19304 ext_ases |= AFL_ASE_SMARTMIPS;
19305 if (ase & ASE_VIRT)
19306 ext_ases |= AFL_ASE_VIRT;
19307 if (ase & ASE_MSA)
19308 ext_ases |= AFL_ASE_MSA;
19309 if (ase & ASE_XPA)
19310 ext_ases |= AFL_ASE_XPA;
19311 if (ase & ASE_MIPS16E2)
19312 ext_ases |= file_ase_mips16 ? AFL_ASE_MIPS16E2 : 0;
19313 if (ase & ASE_CRC)
19314 ext_ases |= AFL_ASE_CRC;
19315 if (ase & ASE_GINV)
19316 ext_ases |= AFL_ASE_GINV;
19317 if (ase & ASE_LOONGSON_MMI)
19318 ext_ases |= AFL_ASE_LOONGSON_MMI;
19319 if (ase & ASE_LOONGSON_CAM)
19320 ext_ases |= AFL_ASE_LOONGSON_CAM;
19321 if (ase & ASE_LOONGSON_EXT)
19322 ext_ases |= AFL_ASE_LOONGSON_EXT;
19323 if (ase & ASE_LOONGSON_EXT2)
19324 ext_ases |= AFL_ASE_LOONGSON_EXT2;
19326 return ext_ases;
19328 /* Some special processing for a MIPS ELF file. */
19330 void
19331 mips_elf_final_processing (void)
19333 int fpabi;
19334 Elf_Internal_ABIFlags_v0 flags;
19336 flags.version = 0;
19337 flags.isa_rev = 0;
19338 switch (file_mips_opts.isa)
19340 case INSN_ISA1:
19341 flags.isa_level = 1;
19342 break;
19343 case INSN_ISA2:
19344 flags.isa_level = 2;
19345 break;
19346 case INSN_ISA3:
19347 flags.isa_level = 3;
19348 break;
19349 case INSN_ISA4:
19350 flags.isa_level = 4;
19351 break;
19352 case INSN_ISA5:
19353 flags.isa_level = 5;
19354 break;
19355 case INSN_ISA32:
19356 flags.isa_level = 32;
19357 flags.isa_rev = 1;
19358 break;
19359 case INSN_ISA32R2:
19360 flags.isa_level = 32;
19361 flags.isa_rev = 2;
19362 break;
19363 case INSN_ISA32R3:
19364 flags.isa_level = 32;
19365 flags.isa_rev = 3;
19366 break;
19367 case INSN_ISA32R5:
19368 flags.isa_level = 32;
19369 flags.isa_rev = 5;
19370 break;
19371 case INSN_ISA32R6:
19372 flags.isa_level = 32;
19373 flags.isa_rev = 6;
19374 break;
19375 case INSN_ISA64:
19376 flags.isa_level = 64;
19377 flags.isa_rev = 1;
19378 break;
19379 case INSN_ISA64R2:
19380 flags.isa_level = 64;
19381 flags.isa_rev = 2;
19382 break;
19383 case INSN_ISA64R3:
19384 flags.isa_level = 64;
19385 flags.isa_rev = 3;
19386 break;
19387 case INSN_ISA64R5:
19388 flags.isa_level = 64;
19389 flags.isa_rev = 5;
19390 break;
19391 case INSN_ISA64R6:
19392 flags.isa_level = 64;
19393 flags.isa_rev = 6;
19394 break;
19397 flags.gpr_size = file_mips_opts.gp == 32 ? AFL_REG_32 : AFL_REG_64;
19398 flags.cpr1_size = file_mips_opts.soft_float ? AFL_REG_NONE
19399 : (file_mips_opts.ase & ASE_MSA) ? AFL_REG_128
19400 : (file_mips_opts.fp == 64) ? AFL_REG_64
19401 : AFL_REG_32;
19402 flags.cpr2_size = AFL_REG_NONE;
19403 flags.fp_abi = bfd_elf_get_obj_attr_int (stdoutput, OBJ_ATTR_GNU,
19404 Tag_GNU_MIPS_ABI_FP);
19405 flags.isa_ext = bfd_mips_isa_ext (stdoutput);
19406 flags.ases = mips_convert_ase_flags (file_mips_opts.ase);
19407 if (file_ase_mips16)
19408 flags.ases |= AFL_ASE_MIPS16;
19409 if (file_ase_micromips)
19410 flags.ases |= AFL_ASE_MICROMIPS;
19411 flags.flags1 = 0;
19412 if ((ISA_HAS_ODD_SINGLE_FPR (file_mips_opts.isa, file_mips_opts.arch)
19413 || file_mips_opts.fp == 64)
19414 && file_mips_opts.oddspreg)
19415 flags.flags1 |= AFL_FLAGS1_ODDSPREG;
19416 flags.flags2 = 0;
19418 bfd_mips_elf_swap_abiflags_v0_out (stdoutput, &flags,
19419 ((Elf_External_ABIFlags_v0 *)
19420 mips_flags_frag));
19422 /* Write out the register information. */
19423 if (mips_abi != N64_ABI)
19425 Elf32_RegInfo s;
19427 s.ri_gprmask = mips_gprmask;
19428 s.ri_cprmask[0] = mips_cprmask[0];
19429 s.ri_cprmask[1] = mips_cprmask[1];
19430 s.ri_cprmask[2] = mips_cprmask[2];
19431 s.ri_cprmask[3] = mips_cprmask[3];
19432 /* The gp_value field is set by the MIPS ELF backend. */
19434 bfd_mips_elf32_swap_reginfo_out (stdoutput, &s,
19435 ((Elf32_External_RegInfo *)
19436 mips_regmask_frag));
19438 else
19440 Elf64_Internal_RegInfo s;
19442 s.ri_gprmask = mips_gprmask;
19443 s.ri_pad = 0;
19444 s.ri_cprmask[0] = mips_cprmask[0];
19445 s.ri_cprmask[1] = mips_cprmask[1];
19446 s.ri_cprmask[2] = mips_cprmask[2];
19447 s.ri_cprmask[3] = mips_cprmask[3];
19448 /* The gp_value field is set by the MIPS ELF backend. */
19450 bfd_mips_elf64_swap_reginfo_out (stdoutput, &s,
19451 ((Elf64_External_RegInfo *)
19452 mips_regmask_frag));
19455 /* Set the MIPS ELF flag bits. FIXME: There should probably be some
19456 sort of BFD interface for this. */
19457 if (mips_any_noreorder)
19458 elf_elfheader (stdoutput)->e_flags |= EF_MIPS_NOREORDER;
19459 if (mips_pic != NO_PIC)
19461 elf_elfheader (stdoutput)->e_flags |= EF_MIPS_PIC;
19462 elf_elfheader (stdoutput)->e_flags |= EF_MIPS_CPIC;
19464 if (mips_abicalls)
19465 elf_elfheader (stdoutput)->e_flags |= EF_MIPS_CPIC;
19467 /* Set MIPS ELF flags for ASEs. Note that not all ASEs have flags
19468 defined at present; this might need to change in future. */
19469 if (file_ase_mips16)
19470 elf_elfheader (stdoutput)->e_flags |= EF_MIPS_ARCH_ASE_M16;
19471 if (file_ase_micromips)
19472 elf_elfheader (stdoutput)->e_flags |= EF_MIPS_ARCH_ASE_MICROMIPS;
19473 if (file_mips_opts.ase & ASE_MDMX)
19474 elf_elfheader (stdoutput)->e_flags |= EF_MIPS_ARCH_ASE_MDMX;
19476 /* Set the MIPS ELF ABI flags. */
19477 if (mips_abi == O32_ABI && USE_E_MIPS_ABI_O32)
19478 elf_elfheader (stdoutput)->e_flags |= E_MIPS_ABI_O32;
19479 else if (mips_abi == O64_ABI)
19480 elf_elfheader (stdoutput)->e_flags |= E_MIPS_ABI_O64;
19481 else if (mips_abi == EABI_ABI)
19483 if (file_mips_opts.gp == 64)
19484 elf_elfheader (stdoutput)->e_flags |= E_MIPS_ABI_EABI64;
19485 else
19486 elf_elfheader (stdoutput)->e_flags |= E_MIPS_ABI_EABI32;
19489 /* Nothing to do for N32_ABI or N64_ABI. */
19491 if (mips_32bitmode)
19492 elf_elfheader (stdoutput)->e_flags |= EF_MIPS_32BITMODE;
19494 if (mips_nan2008 == 1)
19495 elf_elfheader (stdoutput)->e_flags |= EF_MIPS_NAN2008;
19497 /* 32 bit code with 64 bit FP registers. */
19498 fpabi = bfd_elf_get_obj_attr_int (stdoutput, OBJ_ATTR_GNU,
19499 Tag_GNU_MIPS_ABI_FP);
19500 if (fpabi == Val_GNU_MIPS_ABI_FP_OLD_64)
19501 elf_elfheader (stdoutput)->e_flags |= EF_MIPS_FP64;
19504 typedef struct proc {
19505 symbolS *func_sym;
19506 symbolS *func_end_sym;
19507 unsigned long reg_mask;
19508 unsigned long reg_offset;
19509 unsigned long fpreg_mask;
19510 unsigned long fpreg_offset;
19511 unsigned long frame_offset;
19512 unsigned long frame_reg;
19513 unsigned long pc_reg;
19514 } procS;
19516 static procS cur_proc;
19517 static procS *cur_proc_ptr;
19518 static int numprocs;
19520 /* Implement NOP_OPCODE. We encode a MIPS16 nop as "1", a microMIPS nop
19521 as "2", and a normal nop as "0". */
19523 #define NOP_OPCODE_MIPS 0
19524 #define NOP_OPCODE_MIPS16 1
19525 #define NOP_OPCODE_MICROMIPS 2
19527 char
19528 mips_nop_opcode (void)
19530 if (seg_info (now_seg)->tc_segment_info_data.micromips)
19531 return NOP_OPCODE_MICROMIPS;
19532 else if (seg_info (now_seg)->tc_segment_info_data.mips16)
19533 return NOP_OPCODE_MIPS16;
19534 else
19535 return NOP_OPCODE_MIPS;
19538 /* Fill in an rs_align_code fragment. Unlike elsewhere we want to use
19539 32-bit microMIPS NOPs here (if applicable). */
19541 void
19542 mips_handle_align (fragS *fragp)
19544 char nop_opcode;
19545 char *p;
19546 int bytes, size, excess;
19547 valueT opcode;
19549 if (fragp->fr_type != rs_align_code)
19550 return;
19552 p = fragp->fr_literal + fragp->fr_fix;
19553 nop_opcode = *p;
19554 switch (nop_opcode)
19556 case NOP_OPCODE_MICROMIPS:
19557 opcode = micromips_nop32_insn.insn_opcode;
19558 size = 4;
19559 break;
19560 case NOP_OPCODE_MIPS16:
19561 opcode = mips16_nop_insn.insn_opcode;
19562 size = 2;
19563 break;
19564 case NOP_OPCODE_MIPS:
19565 default:
19566 opcode = nop_insn.insn_opcode;
19567 size = 4;
19568 break;
19571 bytes = fragp->fr_next->fr_address - fragp->fr_address - fragp->fr_fix;
19572 excess = bytes % size;
19574 /* Handle the leading part if we're not inserting a whole number of
19575 instructions, and make it the end of the fixed part of the frag.
19576 Try to fit in a short microMIPS NOP if applicable and possible,
19577 and use zeroes otherwise. */
19578 gas_assert (excess < 4);
19579 fragp->fr_fix += excess;
19580 switch (excess)
19582 case 3:
19583 *p++ = '\0';
19584 /* Fall through. */
19585 case 2:
19586 if (nop_opcode == NOP_OPCODE_MICROMIPS && !mips_opts.insn32)
19588 p = write_compressed_insn (p, micromips_nop16_insn.insn_opcode, 2);
19589 break;
19591 *p++ = '\0';
19592 /* Fall through. */
19593 case 1:
19594 *p++ = '\0';
19595 /* Fall through. */
19596 case 0:
19597 break;
19600 md_number_to_chars (p, opcode, size);
19601 fragp->fr_var = size;
19604 static long
19605 get_number (void)
19607 int negative = 0;
19608 long val = 0;
19610 if (*input_line_pointer == '-')
19612 ++input_line_pointer;
19613 negative = 1;
19615 if (!ISDIGIT (*input_line_pointer))
19616 as_bad (_("expected simple number"));
19617 if (input_line_pointer[0] == '0')
19619 if (input_line_pointer[1] == 'x')
19621 input_line_pointer += 2;
19622 while (ISXDIGIT (*input_line_pointer))
19624 val <<= 4;
19625 val |= hex_value (*input_line_pointer++);
19627 return negative ? -val : val;
19629 else
19631 ++input_line_pointer;
19632 while (ISDIGIT (*input_line_pointer))
19634 val <<= 3;
19635 val |= *input_line_pointer++ - '0';
19637 return negative ? -val : val;
19640 if (!ISDIGIT (*input_line_pointer))
19642 printf (_(" *input_line_pointer == '%c' 0x%02x\n"),
19643 *input_line_pointer, *input_line_pointer);
19644 as_warn (_("invalid number"));
19645 return -1;
19647 while (ISDIGIT (*input_line_pointer))
19649 val *= 10;
19650 val += *input_line_pointer++ - '0';
19652 return negative ? -val : val;
19655 /* The .file directive; just like the usual .file directive, but there
19656 is an initial number which is the ECOFF file index. In the non-ECOFF
19657 case .file implies DWARF-2. */
19659 static void
19660 s_mips_file (int x ATTRIBUTE_UNUSED)
19662 static int first_file_directive = 0;
19664 if (ECOFF_DEBUGGING)
19666 get_number ();
19667 s_app_file (0);
19669 else
19671 char *filename;
19673 filename = dwarf2_directive_filename ();
19675 /* Versions of GCC up to 3.1 start files with a ".file"
19676 directive even for stabs output. Make sure that this
19677 ".file" is handled. Note that you need a version of GCC
19678 after 3.1 in order to support DWARF-2 on MIPS. */
19679 if (filename != NULL && ! first_file_directive)
19681 (void) new_logical_line (filename, -1);
19682 s_app_file_string (filename, 0);
19684 first_file_directive = 1;
19688 /* The .loc directive, implying DWARF-2. */
19690 static void
19691 s_mips_loc (int x ATTRIBUTE_UNUSED)
19693 if (!ECOFF_DEBUGGING)
19694 dwarf2_directive_loc (0);
19697 /* The .end directive. */
19699 static void
19700 s_mips_end (int x ATTRIBUTE_UNUSED)
19702 symbolS *p;
19704 /* Following functions need their own .frame and .cprestore directives. */
19705 mips_frame_reg_valid = 0;
19706 mips_cprestore_valid = 0;
19708 if (!is_end_of_line[(unsigned char) *input_line_pointer])
19710 p = get_symbol ();
19711 demand_empty_rest_of_line ();
19713 else
19714 p = NULL;
19716 if ((bfd_get_section_flags (stdoutput, now_seg) & SEC_CODE) == 0)
19717 as_warn (_(".end not in text section"));
19719 if (!cur_proc_ptr)
19721 as_warn (_(".end directive without a preceding .ent directive"));
19722 demand_empty_rest_of_line ();
19723 return;
19726 if (p != NULL)
19728 gas_assert (S_GET_NAME (p));
19729 if (strcmp (S_GET_NAME (p), S_GET_NAME (cur_proc_ptr->func_sym)))
19730 as_warn (_(".end symbol does not match .ent symbol"));
19732 if (debug_type == DEBUG_STABS)
19733 stabs_generate_asm_endfunc (S_GET_NAME (p),
19734 S_GET_NAME (p));
19736 else
19737 as_warn (_(".end directive missing or unknown symbol"));
19739 /* Create an expression to calculate the size of the function. */
19740 if (p && cur_proc_ptr)
19742 OBJ_SYMFIELD_TYPE *obj = symbol_get_obj (p);
19743 expressionS *exp = XNEW (expressionS);
19745 obj->size = exp;
19746 exp->X_op = O_subtract;
19747 exp->X_add_symbol = symbol_temp_new_now ();
19748 exp->X_op_symbol = p;
19749 exp->X_add_number = 0;
19751 cur_proc_ptr->func_end_sym = exp->X_add_symbol;
19754 #ifdef md_flush_pending_output
19755 md_flush_pending_output ();
19756 #endif
19758 /* Generate a .pdr section. */
19759 if (!ECOFF_DEBUGGING && mips_flag_pdr)
19761 segT saved_seg = now_seg;
19762 subsegT saved_subseg = now_subseg;
19763 expressionS exp;
19764 char *fragp;
19766 gas_assert (pdr_seg);
19767 subseg_set (pdr_seg, 0);
19769 /* Write the symbol. */
19770 exp.X_op = O_symbol;
19771 exp.X_add_symbol = p;
19772 exp.X_add_number = 0;
19773 emit_expr (&exp, 4);
19775 fragp = frag_more (7 * 4);
19777 md_number_to_chars (fragp, cur_proc_ptr->reg_mask, 4);
19778 md_number_to_chars (fragp + 4, cur_proc_ptr->reg_offset, 4);
19779 md_number_to_chars (fragp + 8, cur_proc_ptr->fpreg_mask, 4);
19780 md_number_to_chars (fragp + 12, cur_proc_ptr->fpreg_offset, 4);
19781 md_number_to_chars (fragp + 16, cur_proc_ptr->frame_offset, 4);
19782 md_number_to_chars (fragp + 20, cur_proc_ptr->frame_reg, 4);
19783 md_number_to_chars (fragp + 24, cur_proc_ptr->pc_reg, 4);
19785 subseg_set (saved_seg, saved_subseg);
19788 cur_proc_ptr = NULL;
19791 /* The .aent and .ent directives. */
19793 static void
19794 s_mips_ent (int aent)
19796 symbolS *symbolP;
19798 symbolP = get_symbol ();
19799 if (*input_line_pointer == ',')
19800 ++input_line_pointer;
19801 SKIP_WHITESPACE ();
19802 if (ISDIGIT (*input_line_pointer)
19803 || *input_line_pointer == '-')
19804 get_number ();
19806 if ((bfd_get_section_flags (stdoutput, now_seg) & SEC_CODE) == 0)
19807 as_warn (_(".ent or .aent not in text section"));
19809 if (!aent && cur_proc_ptr)
19810 as_warn (_("missing .end"));
19812 if (!aent)
19814 /* This function needs its own .frame and .cprestore directives. */
19815 mips_frame_reg_valid = 0;
19816 mips_cprestore_valid = 0;
19818 cur_proc_ptr = &cur_proc;
19819 memset (cur_proc_ptr, '\0', sizeof (procS));
19821 cur_proc_ptr->func_sym = symbolP;
19823 ++numprocs;
19825 if (debug_type == DEBUG_STABS)
19826 stabs_generate_asm_func (S_GET_NAME (symbolP),
19827 S_GET_NAME (symbolP));
19830 symbol_get_bfdsym (symbolP)->flags |= BSF_FUNCTION;
19832 demand_empty_rest_of_line ();
19835 /* The .frame directive. If the mdebug section is present (IRIX 5 native)
19836 then ecoff.c (ecoff_directive_frame) is used. For embedded targets,
19837 s_mips_frame is used so that we can set the PDR information correctly.
19838 We can't use the ecoff routines because they make reference to the ecoff
19839 symbol table (in the mdebug section). */
19841 static void
19842 s_mips_frame (int ignore ATTRIBUTE_UNUSED)
19844 if (ECOFF_DEBUGGING)
19845 s_ignore (ignore);
19846 else
19848 long val;
19850 if (cur_proc_ptr == (procS *) NULL)
19852 as_warn (_(".frame outside of .ent"));
19853 demand_empty_rest_of_line ();
19854 return;
19857 cur_proc_ptr->frame_reg = tc_get_register (1);
19859 SKIP_WHITESPACE ();
19860 if (*input_line_pointer++ != ','
19861 || get_absolute_expression_and_terminator (&val) != ',')
19863 as_warn (_("bad .frame directive"));
19864 --input_line_pointer;
19865 demand_empty_rest_of_line ();
19866 return;
19869 cur_proc_ptr->frame_offset = val;
19870 cur_proc_ptr->pc_reg = tc_get_register (0);
19872 demand_empty_rest_of_line ();
19876 /* The .fmask and .mask directives. If the mdebug section is present
19877 (IRIX 5 native) then ecoff.c (ecoff_directive_mask) is used. For
19878 embedded targets, s_mips_mask is used so that we can set the PDR
19879 information correctly. We can't use the ecoff routines because they
19880 make reference to the ecoff symbol table (in the mdebug section). */
19882 static void
19883 s_mips_mask (int reg_type)
19885 if (ECOFF_DEBUGGING)
19886 s_ignore (reg_type);
19887 else
19889 long mask, off;
19891 if (cur_proc_ptr == (procS *) NULL)
19893 as_warn (_(".mask/.fmask outside of .ent"));
19894 demand_empty_rest_of_line ();
19895 return;
19898 if (get_absolute_expression_and_terminator (&mask) != ',')
19900 as_warn (_("bad .mask/.fmask directive"));
19901 --input_line_pointer;
19902 demand_empty_rest_of_line ();
19903 return;
19906 off = get_absolute_expression ();
19908 if (reg_type == 'F')
19910 cur_proc_ptr->fpreg_mask = mask;
19911 cur_proc_ptr->fpreg_offset = off;
19913 else
19915 cur_proc_ptr->reg_mask = mask;
19916 cur_proc_ptr->reg_offset = off;
19919 demand_empty_rest_of_line ();
19923 /* A table describing all the processors gas knows about. Names are
19924 matched in the order listed.
19926 To ease comparison, please keep this table in the same order as
19927 gcc's mips_cpu_info_table[]. */
19928 static const struct mips_cpu_info mips_cpu_info_table[] =
19930 /* Entries for generic ISAs. */
19931 { "mips1", MIPS_CPU_IS_ISA, 0, ISA_MIPS1, CPU_R3000 },
19932 { "mips2", MIPS_CPU_IS_ISA, 0, ISA_MIPS2, CPU_R6000 },
19933 { "mips3", MIPS_CPU_IS_ISA, 0, ISA_MIPS3, CPU_R4000 },
19934 { "mips4", MIPS_CPU_IS_ISA, 0, ISA_MIPS4, CPU_R8000 },
19935 { "mips5", MIPS_CPU_IS_ISA, 0, ISA_MIPS5, CPU_MIPS5 },
19936 { "mips32", MIPS_CPU_IS_ISA, 0, ISA_MIPS32, CPU_MIPS32 },
19937 { "mips32r2", MIPS_CPU_IS_ISA, 0, ISA_MIPS32R2, CPU_MIPS32R2 },
19938 { "mips32r3", MIPS_CPU_IS_ISA, 0, ISA_MIPS32R3, CPU_MIPS32R3 },
19939 { "mips32r5", MIPS_CPU_IS_ISA, 0, ISA_MIPS32R5, CPU_MIPS32R5 },
19940 { "mips32r6", MIPS_CPU_IS_ISA, 0, ISA_MIPS32R6, CPU_MIPS32R6 },
19941 { "mips64", MIPS_CPU_IS_ISA, 0, ISA_MIPS64, CPU_MIPS64 },
19942 { "mips64r2", MIPS_CPU_IS_ISA, 0, ISA_MIPS64R2, CPU_MIPS64R2 },
19943 { "mips64r3", MIPS_CPU_IS_ISA, 0, ISA_MIPS64R3, CPU_MIPS64R3 },
19944 { "mips64r5", MIPS_CPU_IS_ISA, 0, ISA_MIPS64R5, CPU_MIPS64R5 },
19945 { "mips64r6", MIPS_CPU_IS_ISA, 0, ISA_MIPS64R6, CPU_MIPS64R6 },
19947 /* MIPS I */
19948 { "r3000", 0, 0, ISA_MIPS1, CPU_R3000 },
19949 { "r2000", 0, 0, ISA_MIPS1, CPU_R3000 },
19950 { "r3900", 0, 0, ISA_MIPS1, CPU_R3900 },
19952 /* MIPS II */
19953 { "r6000", 0, 0, ISA_MIPS2, CPU_R6000 },
19955 /* MIPS III */
19956 { "r4000", 0, 0, ISA_MIPS3, CPU_R4000 },
19957 { "r4010", 0, 0, ISA_MIPS2, CPU_R4010 },
19958 { "vr4100", 0, 0, ISA_MIPS3, CPU_VR4100 },
19959 { "vr4111", 0, 0, ISA_MIPS3, CPU_R4111 },
19960 { "vr4120", 0, 0, ISA_MIPS3, CPU_VR4120 },
19961 { "vr4130", 0, 0, ISA_MIPS3, CPU_VR4120 },
19962 { "vr4181", 0, 0, ISA_MIPS3, CPU_R4111 },
19963 { "vr4300", 0, 0, ISA_MIPS3, CPU_R4300 },
19964 { "r4400", 0, 0, ISA_MIPS3, CPU_R4400 },
19965 { "r4600", 0, 0, ISA_MIPS3, CPU_R4600 },
19966 { "orion", 0, 0, ISA_MIPS3, CPU_R4600 },
19967 { "r4650", 0, 0, ISA_MIPS3, CPU_R4650 },
19968 { "r5900", 0, 0, ISA_MIPS3, CPU_R5900 },
19969 /* ST Microelectronics Loongson 2E and 2F cores. */
19970 { "loongson2e", 0, 0, ISA_MIPS3, CPU_LOONGSON_2E },
19971 { "loongson2f", 0, ASE_LOONGSON_MMI, ISA_MIPS3, CPU_LOONGSON_2F },
19973 /* MIPS IV */
19974 { "r8000", 0, 0, ISA_MIPS4, CPU_R8000 },
19975 { "r10000", 0, 0, ISA_MIPS4, CPU_R10000 },
19976 { "r12000", 0, 0, ISA_MIPS4, CPU_R12000 },
19977 { "r14000", 0, 0, ISA_MIPS4, CPU_R14000 },
19978 { "r16000", 0, 0, ISA_MIPS4, CPU_R16000 },
19979 { "vr5000", 0, 0, ISA_MIPS4, CPU_R5000 },
19980 { "vr5400", 0, 0, ISA_MIPS4, CPU_VR5400 },
19981 { "vr5500", 0, 0, ISA_MIPS4, CPU_VR5500 },
19982 { "rm5200", 0, 0, ISA_MIPS4, CPU_R5000 },
19983 { "rm5230", 0, 0, ISA_MIPS4, CPU_R5000 },
19984 { "rm5231", 0, 0, ISA_MIPS4, CPU_R5000 },
19985 { "rm5261", 0, 0, ISA_MIPS4, CPU_R5000 },
19986 { "rm5721", 0, 0, ISA_MIPS4, CPU_R5000 },
19987 { "rm7000", 0, 0, ISA_MIPS4, CPU_RM7000 },
19988 { "rm9000", 0, 0, ISA_MIPS4, CPU_RM9000 },
19990 /* MIPS 32 */
19991 { "4kc", 0, 0, ISA_MIPS32, CPU_MIPS32 },
19992 { "4km", 0, 0, ISA_MIPS32, CPU_MIPS32 },
19993 { "4kp", 0, 0, ISA_MIPS32, CPU_MIPS32 },
19994 { "4ksc", 0, ASE_SMARTMIPS, ISA_MIPS32, CPU_MIPS32 },
19996 /* MIPS 32 Release 2 */
19997 { "4kec", 0, 0, ISA_MIPS32R2, CPU_MIPS32R2 },
19998 { "4kem", 0, 0, ISA_MIPS32R2, CPU_MIPS32R2 },
19999 { "4kep", 0, 0, ISA_MIPS32R2, CPU_MIPS32R2 },
20000 { "4ksd", 0, ASE_SMARTMIPS, ISA_MIPS32R2, CPU_MIPS32R2 },
20001 { "m4k", 0, 0, ISA_MIPS32R2, CPU_MIPS32R2 },
20002 { "m4kp", 0, 0, ISA_MIPS32R2, CPU_MIPS32R2 },
20003 { "m14k", 0, ASE_MCU, ISA_MIPS32R2, CPU_MIPS32R2 },
20004 { "m14kc", 0, ASE_MCU, ISA_MIPS32R2, CPU_MIPS32R2 },
20005 { "m14ke", 0, ASE_DSP | ASE_DSPR2 | ASE_MCU,
20006 ISA_MIPS32R2, CPU_MIPS32R2 },
20007 { "m14kec", 0, ASE_DSP | ASE_DSPR2 | ASE_MCU,
20008 ISA_MIPS32R2, CPU_MIPS32R2 },
20009 { "24kc", 0, 0, ISA_MIPS32R2, CPU_MIPS32R2 },
20010 { "24kf2_1", 0, 0, ISA_MIPS32R2, CPU_MIPS32R2 },
20011 { "24kf", 0, 0, ISA_MIPS32R2, CPU_MIPS32R2 },
20012 { "24kf1_1", 0, 0, ISA_MIPS32R2, CPU_MIPS32R2 },
20013 /* Deprecated forms of the above. */
20014 { "24kfx", 0, 0, ISA_MIPS32R2, CPU_MIPS32R2 },
20015 { "24kx", 0, 0, ISA_MIPS32R2, CPU_MIPS32R2 },
20016 /* 24KE is a 24K with DSP ASE, other ASEs are optional. */
20017 { "24kec", 0, ASE_DSP, ISA_MIPS32R2, CPU_MIPS32R2 },
20018 { "24kef2_1", 0, ASE_DSP, ISA_MIPS32R2, CPU_MIPS32R2 },
20019 { "24kef", 0, ASE_DSP, ISA_MIPS32R2, CPU_MIPS32R2 },
20020 { "24kef1_1", 0, ASE_DSP, ISA_MIPS32R2, CPU_MIPS32R2 },
20021 /* Deprecated forms of the above. */
20022 { "24kefx", 0, ASE_DSP, ISA_MIPS32R2, CPU_MIPS32R2 },
20023 { "24kex", 0, ASE_DSP, ISA_MIPS32R2, CPU_MIPS32R2 },
20024 /* 34K is a 24K with DSP and MT ASE, other ASEs are optional. */
20025 { "34kc", 0, ASE_DSP | ASE_MT, ISA_MIPS32R2, CPU_MIPS32R2 },
20026 { "34kf2_1", 0, ASE_DSP | ASE_MT, ISA_MIPS32R2, CPU_MIPS32R2 },
20027 { "34kf", 0, ASE_DSP | ASE_MT, ISA_MIPS32R2, CPU_MIPS32R2 },
20028 { "34kf1_1", 0, ASE_DSP | ASE_MT, ISA_MIPS32R2, CPU_MIPS32R2 },
20029 /* Deprecated forms of the above. */
20030 { "34kfx", 0, ASE_DSP | ASE_MT, ISA_MIPS32R2, CPU_MIPS32R2 },
20031 { "34kx", 0, ASE_DSP | ASE_MT, ISA_MIPS32R2, CPU_MIPS32R2 },
20032 /* 34Kn is a 34kc without DSP. */
20033 { "34kn", 0, ASE_MT, ISA_MIPS32R2, CPU_MIPS32R2 },
20034 /* 74K with DSP and DSPR2 ASE, other ASEs are optional. */
20035 { "74kc", 0, ASE_DSP | ASE_DSPR2, ISA_MIPS32R2, CPU_MIPS32R2 },
20036 { "74kf2_1", 0, ASE_DSP | ASE_DSPR2, ISA_MIPS32R2, CPU_MIPS32R2 },
20037 { "74kf", 0, ASE_DSP | ASE_DSPR2, ISA_MIPS32R2, CPU_MIPS32R2 },
20038 { "74kf1_1", 0, ASE_DSP | ASE_DSPR2, ISA_MIPS32R2, CPU_MIPS32R2 },
20039 { "74kf3_2", 0, ASE_DSP | ASE_DSPR2, ISA_MIPS32R2, CPU_MIPS32R2 },
20040 /* Deprecated forms of the above. */
20041 { "74kfx", 0, ASE_DSP | ASE_DSPR2, ISA_MIPS32R2, CPU_MIPS32R2 },
20042 { "74kx", 0, ASE_DSP | ASE_DSPR2, ISA_MIPS32R2, CPU_MIPS32R2 },
20043 /* 1004K cores are multiprocessor versions of the 34K. */
20044 { "1004kc", 0, ASE_DSP | ASE_MT, ISA_MIPS32R2, CPU_MIPS32R2 },
20045 { "1004kf2_1", 0, ASE_DSP | ASE_MT, ISA_MIPS32R2, CPU_MIPS32R2 },
20046 { "1004kf", 0, ASE_DSP | ASE_MT, ISA_MIPS32R2, CPU_MIPS32R2 },
20047 { "1004kf1_1", 0, ASE_DSP | ASE_MT, ISA_MIPS32R2, CPU_MIPS32R2 },
20048 /* interaptiv is the new name for 1004kf. */
20049 { "interaptiv", 0, ASE_DSP | ASE_MT, ISA_MIPS32R2, CPU_MIPS32R2 },
20050 { "interaptiv-mr2", 0,
20051 ASE_DSP | ASE_EVA | ASE_MT | ASE_MIPS16E2 | ASE_MIPS16E2_MT,
20052 ISA_MIPS32R3, CPU_INTERAPTIV_MR2 },
20053 /* M5100 family. */
20054 { "m5100", 0, ASE_MCU, ISA_MIPS32R5, CPU_MIPS32R5 },
20055 { "m5101", 0, ASE_MCU, ISA_MIPS32R5, CPU_MIPS32R5 },
20056 /* P5600 with EVA and Virtualization ASEs, other ASEs are optional. */
20057 { "p5600", 0, ASE_VIRT | ASE_EVA | ASE_XPA, ISA_MIPS32R5, CPU_MIPS32R5 },
20059 /* MIPS 64 */
20060 { "5kc", 0, 0, ISA_MIPS64, CPU_MIPS64 },
20061 { "5kf", 0, 0, ISA_MIPS64, CPU_MIPS64 },
20062 { "20kc", 0, ASE_MIPS3D, ISA_MIPS64, CPU_MIPS64 },
20063 { "25kf", 0, ASE_MIPS3D, ISA_MIPS64, CPU_MIPS64 },
20065 /* Broadcom SB-1 CPU core. */
20066 { "sb1", 0, ASE_MIPS3D | ASE_MDMX, ISA_MIPS64, CPU_SB1 },
20067 /* Broadcom SB-1A CPU core. */
20068 { "sb1a", 0, ASE_MIPS3D | ASE_MDMX, ISA_MIPS64, CPU_SB1 },
20070 /* MIPS 64 Release 2. */
20071 /* Loongson CPU core. */
20072 /* -march=loongson3a is an alias of -march=gs464 for compatibility. */
20073 { "loongson3a", 0, ASE_LOONGSON_MMI | ASE_LOONGSON_CAM | ASE_LOONGSON_EXT,
20074 ISA_MIPS64R2, CPU_GS464 },
20075 { "gs464", 0, ASE_LOONGSON_MMI | ASE_LOONGSON_CAM | ASE_LOONGSON_EXT,
20076 ISA_MIPS64R2, CPU_GS464 },
20077 { "gs464e", 0, ASE_LOONGSON_MMI | ASE_LOONGSON_CAM | ASE_LOONGSON_EXT
20078 | ASE_LOONGSON_EXT2, ISA_MIPS64R2, CPU_GS464E },
20079 { "gs264e", 0, ASE_LOONGSON_MMI | ASE_LOONGSON_CAM | ASE_LOONGSON_EXT
20080 | ASE_LOONGSON_EXT2 | ASE_MSA | ASE_MSA64, ISA_MIPS64R2, CPU_GS264E },
20082 /* Cavium Networks Octeon CPU core. */
20083 { "octeon", 0, 0, ISA_MIPS64R2, CPU_OCTEON },
20084 { "octeon+", 0, 0, ISA_MIPS64R2, CPU_OCTEONP },
20085 { "octeon2", 0, 0, ISA_MIPS64R2, CPU_OCTEON2 },
20086 { "octeon3", 0, ASE_VIRT | ASE_VIRT64, ISA_MIPS64R5, CPU_OCTEON3 },
20088 /* RMI Xlr */
20089 { "xlr", 0, 0, ISA_MIPS64, CPU_XLR },
20091 /* Broadcom XLP.
20092 XLP is mostly like XLR, with the prominent exception that it is
20093 MIPS64R2 rather than MIPS64. */
20094 { "xlp", 0, 0, ISA_MIPS64R2, CPU_XLR },
20096 /* MIPS 64 Release 6. */
20097 { "i6400", 0, ASE_VIRT | ASE_MSA, ISA_MIPS64R6, CPU_MIPS64R6},
20098 { "i6500", 0, ASE_VIRT | ASE_MSA | ASE_CRC | ASE_GINV,
20099 ISA_MIPS64R6, CPU_MIPS64R6},
20100 { "p6600", 0, ASE_VIRT | ASE_MSA, ISA_MIPS64R6, CPU_MIPS64R6},
20102 /* End marker. */
20103 { NULL, 0, 0, 0, 0 }
20107 /* Return true if GIVEN is the same as CANONICAL, or if it is CANONICAL
20108 with a final "000" replaced by "k". Ignore case.
20110 Note: this function is shared between GCC and GAS. */
20112 static bfd_boolean
20113 mips_strict_matching_cpu_name_p (const char *canonical, const char *given)
20115 while (*given != 0 && TOLOWER (*given) == TOLOWER (*canonical))
20116 given++, canonical++;
20118 return ((*given == 0 && *canonical == 0)
20119 || (strcmp (canonical, "000") == 0 && strcasecmp (given, "k") == 0));
20123 /* Return true if GIVEN matches CANONICAL, where GIVEN is a user-supplied
20124 CPU name. We've traditionally allowed a lot of variation here.
20126 Note: this function is shared between GCC and GAS. */
20128 static bfd_boolean
20129 mips_matching_cpu_name_p (const char *canonical, const char *given)
20131 /* First see if the name matches exactly, or with a final "000"
20132 turned into "k". */
20133 if (mips_strict_matching_cpu_name_p (canonical, given))
20134 return TRUE;
20136 /* If not, try comparing based on numerical designation alone.
20137 See if GIVEN is an unadorned number, or 'r' followed by a number. */
20138 if (TOLOWER (*given) == 'r')
20139 given++;
20140 if (!ISDIGIT (*given))
20141 return FALSE;
20143 /* Skip over some well-known prefixes in the canonical name,
20144 hoping to find a number there too. */
20145 if (TOLOWER (canonical[0]) == 'v' && TOLOWER (canonical[1]) == 'r')
20146 canonical += 2;
20147 else if (TOLOWER (canonical[0]) == 'r' && TOLOWER (canonical[1]) == 'm')
20148 canonical += 2;
20149 else if (TOLOWER (canonical[0]) == 'r')
20150 canonical += 1;
20152 return mips_strict_matching_cpu_name_p (canonical, given);
20156 /* Parse an option that takes the name of a processor as its argument.
20157 OPTION is the name of the option and CPU_STRING is the argument.
20158 Return the corresponding processor enumeration if the CPU_STRING is
20159 recognized, otherwise report an error and return null.
20161 A similar function exists in GCC. */
20163 static const struct mips_cpu_info *
20164 mips_parse_cpu (const char *option, const char *cpu_string)
20166 const struct mips_cpu_info *p;
20168 /* 'from-abi' selects the most compatible architecture for the given
20169 ABI: MIPS I for 32-bit ABIs and MIPS III for 64-bit ABIs. For the
20170 EABIs, we have to decide whether we're using the 32-bit or 64-bit
20171 version. Look first at the -mgp options, if given, otherwise base
20172 the choice on MIPS_DEFAULT_64BIT.
20174 Treat NO_ABI like the EABIs. One reason to do this is that the
20175 plain 'mips' and 'mips64' configs have 'from-abi' as their default
20176 architecture. This code picks MIPS I for 'mips' and MIPS III for
20177 'mips64', just as we did in the days before 'from-abi'. */
20178 if (strcasecmp (cpu_string, "from-abi") == 0)
20180 if (ABI_NEEDS_32BIT_REGS (mips_abi))
20181 return mips_cpu_info_from_isa (ISA_MIPS1);
20183 if (ABI_NEEDS_64BIT_REGS (mips_abi))
20184 return mips_cpu_info_from_isa (ISA_MIPS3);
20186 if (file_mips_opts.gp >= 0)
20187 return mips_cpu_info_from_isa (file_mips_opts.gp == 32
20188 ? ISA_MIPS1 : ISA_MIPS3);
20190 return mips_cpu_info_from_isa (MIPS_DEFAULT_64BIT
20191 ? ISA_MIPS3
20192 : ISA_MIPS1);
20195 /* 'default' has traditionally been a no-op. Probably not very useful. */
20196 if (strcasecmp (cpu_string, "default") == 0)
20197 return 0;
20199 for (p = mips_cpu_info_table; p->name != 0; p++)
20200 if (mips_matching_cpu_name_p (p->name, cpu_string))
20201 return p;
20203 as_bad (_("bad value (%s) for %s"), cpu_string, option);
20204 return 0;
20207 /* Return the canonical processor information for ISA (a member of the
20208 ISA_MIPS* enumeration). */
20210 static const struct mips_cpu_info *
20211 mips_cpu_info_from_isa (int isa)
20213 int i;
20215 for (i = 0; mips_cpu_info_table[i].name != NULL; i++)
20216 if ((mips_cpu_info_table[i].flags & MIPS_CPU_IS_ISA)
20217 && isa == mips_cpu_info_table[i].isa)
20218 return (&mips_cpu_info_table[i]);
20220 return NULL;
20223 static const struct mips_cpu_info *
20224 mips_cpu_info_from_arch (int arch)
20226 int i;
20228 for (i = 0; mips_cpu_info_table[i].name != NULL; i++)
20229 if (arch == mips_cpu_info_table[i].cpu)
20230 return (&mips_cpu_info_table[i]);
20232 return NULL;
20235 static void
20236 show (FILE *stream, const char *string, int *col_p, int *first_p)
20238 if (*first_p)
20240 fprintf (stream, "%24s", "");
20241 *col_p = 24;
20243 else
20245 fprintf (stream, ", ");
20246 *col_p += 2;
20249 if (*col_p + strlen (string) > 72)
20251 fprintf (stream, "\n%24s", "");
20252 *col_p = 24;
20255 fprintf (stream, "%s", string);
20256 *col_p += strlen (string);
20258 *first_p = 0;
20261 void
20262 md_show_usage (FILE *stream)
20264 int column, first;
20265 size_t i;
20267 fprintf (stream, _("\
20268 MIPS options:\n\
20269 -EB generate big endian output\n\
20270 -EL generate little endian output\n\
20271 -g, -g2 do not remove unneeded NOPs or swap branches\n\
20272 -G NUM allow referencing objects up to NUM bytes\n\
20273 implicitly with the gp register [default 8]\n"));
20274 fprintf (stream, _("\
20275 -mips1 generate MIPS ISA I instructions\n\
20276 -mips2 generate MIPS ISA II instructions\n\
20277 -mips3 generate MIPS ISA III instructions\n\
20278 -mips4 generate MIPS ISA IV instructions\n\
20279 -mips5 generate MIPS ISA V instructions\n\
20280 -mips32 generate MIPS32 ISA instructions\n\
20281 -mips32r2 generate MIPS32 release 2 ISA instructions\n\
20282 -mips32r3 generate MIPS32 release 3 ISA instructions\n\
20283 -mips32r5 generate MIPS32 release 5 ISA instructions\n\
20284 -mips32r6 generate MIPS32 release 6 ISA instructions\n\
20285 -mips64 generate MIPS64 ISA instructions\n\
20286 -mips64r2 generate MIPS64 release 2 ISA instructions\n\
20287 -mips64r3 generate MIPS64 release 3 ISA instructions\n\
20288 -mips64r5 generate MIPS64 release 5 ISA instructions\n\
20289 -mips64r6 generate MIPS64 release 6 ISA instructions\n\
20290 -march=CPU/-mtune=CPU generate code/schedule for CPU, where CPU is one of:\n"));
20292 first = 1;
20294 for (i = 0; mips_cpu_info_table[i].name != NULL; i++)
20295 show (stream, mips_cpu_info_table[i].name, &column, &first);
20296 show (stream, "from-abi", &column, &first);
20297 fputc ('\n', stream);
20299 fprintf (stream, _("\
20300 -mCPU equivalent to -march=CPU -mtune=CPU. Deprecated.\n\
20301 -no-mCPU don't generate code specific to CPU.\n\
20302 For -mCPU and -no-mCPU, CPU must be one of:\n"));
20304 first = 1;
20306 show (stream, "3900", &column, &first);
20307 show (stream, "4010", &column, &first);
20308 show (stream, "4100", &column, &first);
20309 show (stream, "4650", &column, &first);
20310 fputc ('\n', stream);
20312 fprintf (stream, _("\
20313 -mips16 generate mips16 instructions\n\
20314 -no-mips16 do not generate mips16 instructions\n"));
20315 fprintf (stream, _("\
20316 -mmips16e2 generate MIPS16e2 instructions\n\
20317 -mno-mips16e2 do not generate MIPS16e2 instructions\n"));
20318 fprintf (stream, _("\
20319 -mmicromips generate microMIPS instructions\n\
20320 -mno-micromips do not generate microMIPS instructions\n"));
20321 fprintf (stream, _("\
20322 -msmartmips generate smartmips instructions\n\
20323 -mno-smartmips do not generate smartmips instructions\n"));
20324 fprintf (stream, _("\
20325 -mdsp generate DSP instructions\n\
20326 -mno-dsp do not generate DSP instructions\n"));
20327 fprintf (stream, _("\
20328 -mdspr2 generate DSP R2 instructions\n\
20329 -mno-dspr2 do not generate DSP R2 instructions\n"));
20330 fprintf (stream, _("\
20331 -mdspr3 generate DSP R3 instructions\n\
20332 -mno-dspr3 do not generate DSP R3 instructions\n"));
20333 fprintf (stream, _("\
20334 -mmt generate MT instructions\n\
20335 -mno-mt do not generate MT instructions\n"));
20336 fprintf (stream, _("\
20337 -mmcu generate MCU instructions\n\
20338 -mno-mcu do not generate MCU instructions\n"));
20339 fprintf (stream, _("\
20340 -mmsa generate MSA instructions\n\
20341 -mno-msa do not generate MSA instructions\n"));
20342 fprintf (stream, _("\
20343 -mxpa generate eXtended Physical Address (XPA) instructions\n\
20344 -mno-xpa do not generate eXtended Physical Address (XPA) instructions\n"));
20345 fprintf (stream, _("\
20346 -mvirt generate Virtualization instructions\n\
20347 -mno-virt do not generate Virtualization instructions\n"));
20348 fprintf (stream, _("\
20349 -mcrc generate CRC instructions\n\
20350 -mno-crc do not generate CRC instructions\n"));
20351 fprintf (stream, _("\
20352 -mginv generate Global INValidate (GINV) instructions\n\
20353 -mno-ginv do not generate Global INValidate instructions\n"));
20354 fprintf (stream, _("\
20355 -mloongson-mmi generate Loongson MultiMedia extensions Instructions (MMI) instructions\n\
20356 -mno-loongson-mmi do not generate Loongson MultiMedia extensions Instructions\n"));
20357 fprintf (stream, _("\
20358 -mloongson-cam generate Loongson Content Address Memory (CAM) instructions\n\
20359 -mno-loongson-cam do not generate Loongson Content Address Memory Instructions\n"));
20360 fprintf (stream, _("\
20361 -mloongson-ext generate Loongson EXTensions (EXT) instructions\n\
20362 -mno-loongson-ext do not generate Loongson EXTensions Instructions\n"));
20363 fprintf (stream, _("\
20364 -mloongson-ext2 generate Loongson EXTensions R2 (EXT2) instructions\n\
20365 -mno-loongson-ext2 do not generate Loongson EXTensions R2 Instructions\n"));
20366 fprintf (stream, _("\
20367 -minsn32 only generate 32-bit microMIPS instructions\n\
20368 -mno-insn32 generate all microMIPS instructions\n"));
20369 #if DEFAULT_MIPS_FIX_LOONGSON3_LLSC
20370 fprintf (stream, _("\
20371 -mfix-loongson3-llsc work around Loongson3 LL/SC errata, default\n\
20372 -mno-fix-loongson3-llsc disable work around Loongson3 LL/SC errata\n"));
20373 #else
20374 fprintf (stream, _("\
20375 -mfix-loongson3-llsc work around Loongson3 LL/SC errata\n\
20376 -mno-fix-loongson3-llsc disable work around Loongson3 LL/SC errata, default\n"));
20377 #endif
20378 fprintf (stream, _("\
20379 -mfix-loongson2f-jump work around Loongson2F JUMP instructions\n\
20380 -mfix-loongson2f-nop work around Loongson2F NOP errata\n\
20381 -mfix-loongson3-llsc work around Loongson3 LL/SC errata\n\
20382 -mno-fix-loongson3-llsc disable work around Loongson3 LL/SC errata\n\
20383 -mfix-vr4120 work around certain VR4120 errata\n\
20384 -mfix-vr4130 work around VR4130 mflo/mfhi errata\n\
20385 -mfix-24k insert a nop after ERET and DERET instructions\n\
20386 -mfix-cn63xxp1 work around CN63XXP1 PREF errata\n\
20387 -mfix-r5900 work around R5900 short loop errata\n\
20388 -mgp32 use 32-bit GPRs, regardless of the chosen ISA\n\
20389 -mfp32 use 32-bit FPRs, regardless of the chosen ISA\n\
20390 -msym32 assume all symbols have 32-bit values\n\
20391 -O0 do not remove unneeded NOPs, do not swap branches\n\
20392 -O, -O1 remove unneeded NOPs, do not swap branches\n\
20393 -O2 remove unneeded NOPs and swap branches\n\
20394 --trap, --no-break trap exception on div by 0 and mult overflow\n\
20395 --break, --no-trap break exception on div by 0 and mult overflow\n"));
20396 fprintf (stream, _("\
20397 -mhard-float allow floating-point instructions\n\
20398 -msoft-float do not allow floating-point instructions\n\
20399 -msingle-float only allow 32-bit floating-point operations\n\
20400 -mdouble-float allow 32-bit and 64-bit floating-point operations\n\
20401 --[no-]construct-floats [dis]allow floating point values to be constructed\n\
20402 --[no-]relax-branch [dis]allow out-of-range branches to be relaxed\n\
20403 -mignore-branch-isa accept invalid branches requiring an ISA mode switch\n\
20404 -mno-ignore-branch-isa reject invalid branches requiring an ISA mode switch\n\
20405 -mnan=ENCODING select an IEEE 754 NaN encoding convention, either of:\n"));
20407 first = 1;
20409 show (stream, "legacy", &column, &first);
20410 show (stream, "2008", &column, &first);
20412 fputc ('\n', stream);
20414 fprintf (stream, _("\
20415 -KPIC, -call_shared generate SVR4 position independent code\n\
20416 -call_nonpic generate non-PIC code that can operate with DSOs\n\
20417 -mvxworks-pic generate VxWorks position independent code\n\
20418 -non_shared do not generate code that can operate with DSOs\n\
20419 -xgot assume a 32 bit GOT\n\
20420 -mpdr, -mno-pdr enable/disable creation of .pdr sections\n\
20421 -mshared, -mno-shared disable/enable .cpload optimization for\n\
20422 position dependent (non shared) code\n\
20423 -mabi=ABI create ABI conformant object file for:\n"));
20425 first = 1;
20427 show (stream, "32", &column, &first);
20428 show (stream, "o64", &column, &first);
20429 show (stream, "n32", &column, &first);
20430 show (stream, "64", &column, &first);
20431 show (stream, "eabi", &column, &first);
20433 fputc ('\n', stream);
20435 fprintf (stream, _("\
20436 -32 create o32 ABI object file%s\n"),
20437 MIPS_DEFAULT_ABI == O32_ABI ? _(" (default)") : "");
20438 fprintf (stream, _("\
20439 -n32 create n32 ABI object file%s\n"),
20440 MIPS_DEFAULT_ABI == N32_ABI ? _(" (default)") : "");
20441 fprintf (stream, _("\
20442 -64 create 64 ABI object file%s\n"),
20443 MIPS_DEFAULT_ABI == N64_ABI ? _(" (default)") : "");
20446 #ifdef TE_IRIX
20447 enum dwarf2_format
20448 mips_dwarf2_format (asection *sec ATTRIBUTE_UNUSED)
20450 if (HAVE_64BIT_SYMBOLS)
20451 return dwarf2_format_64bit_irix;
20452 else
20453 return dwarf2_format_32bit;
20455 #endif
20458 mips_dwarf2_addr_size (void)
20460 if (HAVE_64BIT_OBJECTS)
20461 return 8;
20462 else
20463 return 4;
20466 /* Standard calling conventions leave the CFA at SP on entry. */
20467 void
20468 mips_cfi_frame_initial_instructions (void)
20470 cfi_add_CFA_def_cfa_register (SP);
20474 tc_mips_regname_to_dw2regnum (char *regname)
20476 unsigned int regnum = -1;
20477 unsigned int reg;
20479 if (reg_lookup (&regname, RTYPE_GP | RTYPE_NUM, &reg))
20480 regnum = reg;
20482 return regnum;
20485 /* Implement CONVERT_SYMBOLIC_ATTRIBUTE.
20486 Given a symbolic attribute NAME, return the proper integer value.
20487 Returns -1 if the attribute is not known. */
20490 mips_convert_symbolic_attribute (const char *name)
20492 static const struct
20494 const char * name;
20495 const int tag;
20497 attribute_table[] =
20499 #define T(tag) {#tag, tag}
20500 T (Tag_GNU_MIPS_ABI_FP),
20501 T (Tag_GNU_MIPS_ABI_MSA),
20502 #undef T
20504 unsigned int i;
20506 if (name == NULL)
20507 return -1;
20509 for (i = 0; i < ARRAY_SIZE (attribute_table); i++)
20510 if (streq (name, attribute_table[i].name))
20511 return attribute_table[i].tag;
20513 return -1;
20516 void
20517 md_mips_end (void)
20519 int fpabi = Val_GNU_MIPS_ABI_FP_ANY;
20521 mips_emit_delays ();
20522 if (cur_proc_ptr)
20523 as_warn (_("missing .end at end of assembly"));
20525 /* Just in case no code was emitted, do the consistency check. */
20526 file_mips_check_options ();
20528 /* Set a floating-point ABI if the user did not. */
20529 if (obj_elf_seen_attribute (OBJ_ATTR_GNU, Tag_GNU_MIPS_ABI_FP))
20531 /* Perform consistency checks on the floating-point ABI. */
20532 fpabi = bfd_elf_get_obj_attr_int (stdoutput, OBJ_ATTR_GNU,
20533 Tag_GNU_MIPS_ABI_FP);
20534 if (fpabi != Val_GNU_MIPS_ABI_FP_ANY)
20535 check_fpabi (fpabi);
20537 else
20539 /* Soft-float gets precedence over single-float, the two options should
20540 not be used together so this should not matter. */
20541 if (file_mips_opts.soft_float == 1)
20542 fpabi = Val_GNU_MIPS_ABI_FP_SOFT;
20543 /* Single-float gets precedence over all double_float cases. */
20544 else if (file_mips_opts.single_float == 1)
20545 fpabi = Val_GNU_MIPS_ABI_FP_SINGLE;
20546 else
20548 switch (file_mips_opts.fp)
20550 case 32:
20551 if (file_mips_opts.gp == 32)
20552 fpabi = Val_GNU_MIPS_ABI_FP_DOUBLE;
20553 break;
20554 case 0:
20555 fpabi = Val_GNU_MIPS_ABI_FP_XX;
20556 break;
20557 case 64:
20558 if (file_mips_opts.gp == 32 && !file_mips_opts.oddspreg)
20559 fpabi = Val_GNU_MIPS_ABI_FP_64A;
20560 else if (file_mips_opts.gp == 32)
20561 fpabi = Val_GNU_MIPS_ABI_FP_64;
20562 else
20563 fpabi = Val_GNU_MIPS_ABI_FP_DOUBLE;
20564 break;
20568 bfd_elf_add_obj_attr_int (stdoutput, OBJ_ATTR_GNU,
20569 Tag_GNU_MIPS_ABI_FP, fpabi);
20573 /* Returns the relocation type required for a particular CFI encoding. */
20575 bfd_reloc_code_real_type
20576 mips_cfi_reloc_for_encoding (int encoding)
20578 if (encoding == (DW_EH_PE_sdata4 | DW_EH_PE_pcrel))
20579 return BFD_RELOC_32_PCREL;
20580 else return BFD_RELOC_NONE;