1 /* Disassemble i80960 instructions.
2 Copyright (C) 1990, 91, 93, 94, 95, 96, 1998 Free Software Foundation, Inc.
4 This program is free software; you can redistribute it and/or modify
5 it under the terms of the GNU General Public License as published by
6 the Free Software Foundation; either version 2, or (at your option)
9 This program is distributed in the hope that it will be useful,
10 but WITHOUT ANY WARRANTY; without even the implied warranty of
11 MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
12 GNU General Public License for more details.
14 You should have received a copy of the GNU General Public License
15 along with this program; see the file COPYING. If not, write to the
16 Free Software Foundation, 59 Temple Place - Suite 330, Boston, MA
22 static const char *const reg_names
[] = {
23 /* 0 */ "pfp", "sp", "rip", "r3", "r4", "r5", "r6", "r7",
24 /* 8 */ "r8", "r9", "r10", "r11", "r12", "r13", "r14", "r15",
25 /* 16 */ "g0", "g1", "g2", "g3", "g4", "g5", "g6", "g7",
26 /* 24 */ "g8", "g9", "g10", "g11", "g12", "g13", "g14", "fp",
27 /* 32 */ "pc", "ac", "ip", "tc", "fp0", "fp1", "fp2", "fp3"
31 static FILE *stream
; /* Output goes here */
32 static struct disassemble_info
*info
;
33 static void print_addr();
41 static void invalid();
43 static void put_abs();
46 /* Print the i960 instruction at address 'memaddr' in debugged memory,
47 on INFO->STREAM. Returns length of the instruction, in bytes. */
50 print_insn_i960 (memaddr
, info_arg
)
52 struct disassemble_info
*info_arg
;
54 unsigned int word1
, word2
= 0xdeadbeef;
59 stream
= info
->stream
;
61 /* Read word1. Only read word2 if the instruction
62 needs it, to prevent reading past the end of a section. */
64 status
= (*info
->read_memory_func
) (memaddr
, (bfd_byte
*) buffer
, 4, info
);
67 (*info
->memory_error_func
) (status
, memaddr
, info
);
71 word1
= bfd_getl32 (buffer
);
73 /* Divide instruction set into classes based on high 4 bits of opcode. */
74 switch ( (word1
>> 28) & 0xf )
84 status
= (*info
->read_memory_func
)
85 (memaddr
+ 4, (bfd_byte
*) (buffer
+ 4), 4, info
);
88 (*info
->memory_error_func
) (status
, memaddr
, info
);
91 word2
= bfd_getl32 (buffer
+ 4);
95 return pinsn( memaddr
, word1
, word2
);
100 /*****************************************************************************
101 * All code below this point should be identical with that of
102 * the disassembler in gdmp960.
104 A noble sentiment, but at least in cosmetic ways (info->fprintf_func), it
105 just ain't so. -kingdon, 31 Mar 93
106 *****************************************************************************/
113 struct sparse_tabent
{
120 pinsn( memaddr
, word1
, word2
)
122 unsigned long word1
, word2
;
127 put_abs( word1
, word2
);
129 /* Divide instruction set into classes based on high 4 bits of opcode*/
130 switch ( (word1
>> 28) & 0xf ){
133 ctrl( memaddr
, word1
, word2
);
137 cobr( memaddr
, word1
, word2
);
149 instr_len
= mem( memaddr
, word1
, word2
, 0 );
152 /* invalid instruction, print as data word */
159 /****************************************/
161 /****************************************/
163 ctrl( memaddr
, word1
, word2
)
165 unsigned long word1
, word2
;
168 static const struct tabent ctrl_tab
[] = {
169 { NULL
, 0, }, /* 0x00 */
170 { NULL
, 0, }, /* 0x01 */
171 { NULL
, 0, }, /* 0x02 */
172 { NULL
, 0, }, /* 0x03 */
173 { NULL
, 0, }, /* 0x04 */
174 { NULL
, 0, }, /* 0x05 */
175 { NULL
, 0, }, /* 0x06 */
176 { NULL
, 0, }, /* 0x07 */
177 { "b", 1, }, /* 0x08 */
178 { "call", 1, }, /* 0x09 */
179 { "ret", 0, }, /* 0x0a */
180 { "bal", 1, }, /* 0x0b */
181 { NULL
, 0, }, /* 0x0c */
182 { NULL
, 0, }, /* 0x0d */
183 { NULL
, 0, }, /* 0x0e */
184 { NULL
, 0, }, /* 0x0f */
185 { "bno", 1, }, /* 0x10 */
186 { "bg", 1, }, /* 0x11 */
187 { "be", 1, }, /* 0x12 */
188 { "bge", 1, }, /* 0x13 */
189 { "bl", 1, }, /* 0x14 */
190 { "bne", 1, }, /* 0x15 */
191 { "ble", 1, }, /* 0x16 */
192 { "bo", 1, }, /* 0x17 */
193 { "faultno", 0, }, /* 0x18 */
194 { "faultg", 0, }, /* 0x19 */
195 { "faulte", 0, }, /* 0x1a */
196 { "faultge", 0, }, /* 0x1b */
197 { "faultl", 0, }, /* 0x1c */
198 { "faultne", 0, }, /* 0x1d */
199 { "faultle", 0, }, /* 0x1e */
200 { "faulto", 0, }, /* 0x1f */
203 i
= (word1
>> 24) & 0xff;
204 if ( (ctrl_tab
[i
].name
== NULL
) || ((word1
& 1) != 0) ){
209 (*info
->fprintf_func
) ( stream
, ctrl_tab
[i
].name
);
210 if ( word1
& 2 ){ /* Predicts branch not taken */
211 (*info
->fprintf_func
) ( stream
, ".f" );
214 if ( ctrl_tab
[i
].numops
== 1 ){
215 /* EXTRACT DISPLACEMENT AND CONVERT TO ADDRESS */
217 if ( word1
& 0x00800000 ){ /* Sign bit is set */
218 word1
|= (-1 & ~0xffffff); /* Sign extend */
220 (*info
->fprintf_func
)( stream
, "\t" );
221 print_addr( word1
+ memaddr
);
225 /****************************************/
227 /****************************************/
229 cobr( memaddr
, word1
, word2
)
231 unsigned long word1
, word2
;
237 static const struct tabent cobr_tab
[] = {
238 { "testno", 1, }, /* 0x20 */
239 { "testg", 1, }, /* 0x21 */
240 { "teste", 1, }, /* 0x22 */
241 { "testge", 1, }, /* 0x23 */
242 { "testl", 1, }, /* 0x24 */
243 { "testne", 1, }, /* 0x25 */
244 { "testle", 1, }, /* 0x26 */
245 { "testo", 1, }, /* 0x27 */
246 { NULL
, 0, }, /* 0x28 */
247 { NULL
, 0, }, /* 0x29 */
248 { NULL
, 0, }, /* 0x2a */
249 { NULL
, 0, }, /* 0x2b */
250 { NULL
, 0, }, /* 0x2c */
251 { NULL
, 0, }, /* 0x2d */
252 { NULL
, 0, }, /* 0x2e */
253 { NULL
, 0, }, /* 0x2f */
254 { "bbc", 3, }, /* 0x30 */
255 { "cmpobg", 3, }, /* 0x31 */
256 { "cmpobe", 3, }, /* 0x32 */
257 { "cmpobge", 3, }, /* 0x33 */
258 { "cmpobl", 3, }, /* 0x34 */
259 { "cmpobne", 3, }, /* 0x35 */
260 { "cmpoble", 3, }, /* 0x36 */
261 { "bbs", 3, }, /* 0x37 */
262 { "cmpibno", 3, }, /* 0x38 */
263 { "cmpibg", 3, }, /* 0x39 */
264 { "cmpibe", 3, }, /* 0x3a */
265 { "cmpibge", 3, }, /* 0x3b */
266 { "cmpibl", 3, }, /* 0x3c */
267 { "cmpibne", 3, }, /* 0x3d */
268 { "cmpible", 3, }, /* 0x3e */
269 { "cmpibo", 3, }, /* 0x3f */
272 i
= ((word1
>> 24) & 0xff) - 0x20;
273 if ( cobr_tab
[i
].name
== NULL
){
278 (*info
->fprintf_func
) ( stream
, cobr_tab
[i
].name
);
279 if ( word1
& 2 ){ /* Predicts branch not taken */
280 (*info
->fprintf_func
) ( stream
, ".f" );
282 (*info
->fprintf_func
)( stream
, "\t" );
284 src1
= (word1
>> 19) & 0x1f;
285 src2
= (word1
>> 14) & 0x1f;
287 if ( word1
& 0x02000 ){ /* M1 is 1 */
288 (*info
->fprintf_func
)( stream
, "%d", src1
);
289 } else { /* M1 is 0 */
290 (*info
->fprintf_func
)( stream
, reg_names
[src1
] );
293 if ( cobr_tab
[i
].numops
> 1 ){
294 if ( word1
& 1 ){ /* S2 is 1 */
295 (*info
->fprintf_func
)( stream
, ",sf%d,", src2
);
296 } else { /* S1 is 0 */
297 (*info
->fprintf_func
)( stream
, ",%s,", reg_names
[src2
] );
300 /* Extract displacement and convert to address
303 if ( word1
& 0x00001000 ){ /* Negative displacement */
304 word1
|= (-1 & ~0x1fff); /* Sign extend */
306 print_addr( memaddr
+ word1
);
310 /****************************************/
312 /****************************************/
313 static int /* returns instruction length: 4 or 8 */
314 mem( memaddr
, word1
, word2
, noprint
)
316 unsigned long word1
, word2
;
317 int noprint
; /* If TRUE, return instruction length, but
318 * don't output any text.
325 const char *reg1
, *reg2
, *reg3
;
327 /* This lookup table is too sparse to make it worth typing in, but not
328 so large as to make a sparse array necessary. We create the table
332 * NOTE: In this table, the meaning of 'numops' is:
334 * 2: 2 operands, load instruction
335 * -2: 2 operands, store instruction
337 static struct tabent
*mem_tab
;
338 /* Opcodes of 0x8X, 9X, aX, bX, and cX must be in the table. */
341 #define MEM_SIZ ( * sizeof(struct tabent))
343 static const struct sparse_tabent mem_init
[] = {
345 { 0x82, "stob", -2 },
348 { 0x86, "callx", 1 },
350 { 0x8a, "stos", -2 },
358 { 0xac, "dcinva", 1 },
362 { 0xc2, "stib", -2 },
364 { 0xca, "stis", -2 },
367 static struct tabent mem_tab_buf
[MEM_MAX
- MEM_MIN
+ 1];
369 if ( mem_tab
== NULL
){
370 mem_tab
= mem_tab_buf
;
371 for ( i
= 0; mem_init
[i
].opcode
!= 0; i
++ ){
372 j
= mem_init
[i
].opcode
- MEM_MIN
;
373 mem_tab
[j
].name
= mem_init
[i
].name
;
374 mem_tab
[j
].numops
= mem_init
[i
].numops
;
378 i
= ((word1
>> 24) & 0xff) - MEM_MIN
;
379 mode
= (word1
>> 10) & 0xf;
381 if ( (mem_tab
[i
].name
!= NULL
) /* Valid instruction */
382 && ((mode
== 5) || (mode
>=12)) ){ /* With 32-bit displacement */
392 if ( (mem_tab
[i
].name
== NULL
) || (mode
== 6) ){
397 (*info
->fprintf_func
)( stream
, "%s\t", mem_tab
[i
].name
);
399 reg1
= reg_names
[ (word1
>> 19) & 0x1f ]; /* MEMB only */
400 reg2
= reg_names
[ (word1
>> 14) & 0x1f ];
401 reg3
= reg_names
[ word1
& 0x1f ]; /* MEMB only */
402 offset
= word1
& 0xfff; /* MEMA only */
404 switch ( mem_tab
[i
].numops
){
406 case 2: /* LOAD INSTRUCTION */
407 if ( mode
& 4 ){ /* MEMB FORMAT */
408 ea( memaddr
, mode
, reg2
, reg3
, word1
, word2
);
409 (*info
->fprintf_func
)( stream
, ",%s", reg1
);
410 } else { /* MEMA FORMAT */
411 (*info
->fprintf_func
)( stream
, "0x%x", (unsigned) offset
);
413 (*info
->fprintf_func
)( stream
, "(%s)", reg2
);
415 (*info
->fprintf_func
)( stream
, ",%s", reg1
);
419 case -2: /* STORE INSTRUCTION */
420 if ( mode
& 4 ){ /* MEMB FORMAT */
421 (*info
->fprintf_func
)( stream
, "%s,", reg1
);
422 ea( memaddr
, mode
, reg2
, reg3
, word1
, word2
);
423 } else { /* MEMA FORMAT */
424 (*info
->fprintf_func
)( stream
, "%s,0x%x", reg1
, (unsigned) offset
);
426 (*info
->fprintf_func
)( stream
, "(%s)", reg2
);
431 case 1: /* BX/CALLX INSTRUCTION */
432 if ( mode
& 4 ){ /* MEMB FORMAT */
433 ea( memaddr
, mode
, reg2
, reg3
, word1
, word2
);
434 } else { /* MEMA FORMAT */
435 (*info
->fprintf_func
)( stream
, "0x%x", (unsigned) offset
);
437 (*info
->fprintf_func
)( stream
, "(%s)", reg2
);
446 /****************************************/
448 /****************************************/
461 /* This lookup table is too sparse to make it worth typing in, but not
462 so large as to make a sparse array necessary. We create the table
466 * NOTE: In this table, the meaning of 'numops' is:
467 * 1: single operand, which is NOT a destination.
468 * -1: single operand, which IS a destination.
469 * 2: 2 operands, the 2nd of which is NOT a destination.
470 * -2: 2 operands, the 2nd of which IS a destination.
473 * If an opcode mnemonic begins with "F", it is a floating-point
474 * opcode (the "F" is not printed).
477 static struct tabent
*reg_tab
;
478 static const struct sparse_tabent reg_init
[] = {
479 #define REG_MIN 0x580
480 { 0x580, "notbit", 3 },
482 { 0x582, "andnot", 3 },
483 { 0x583, "setbit", 3 },
484 { 0x584, "notand", 3 },
488 { 0x589, "xnor", 3 },
489 { 0x58a, "not", -2 },
490 { 0x58b, "ornot", 3 },
491 { 0x58c, "clrbit", 3 },
492 { 0x58d, "notor", 3 },
493 { 0x58e, "nand", 3 },
494 { 0x58f, "alterbit", 3 },
495 { 0x590, "addo", 3 },
496 { 0x591, "addi", 3 },
497 { 0x592, "subo", 3 },
498 { 0x593, "subi", 3 },
499 { 0x594, "cmpob", 2 },
500 { 0x595, "cmpib", 2 },
501 { 0x596, "cmpos", 2 },
502 { 0x597, "cmpis", 2 },
503 { 0x598, "shro", 3 },
504 { 0x59a, "shrdi", 3 },
505 { 0x59b, "shri", 3 },
506 { 0x59c, "shlo", 3 },
507 { 0x59d, "rotate", 3 },
508 { 0x59e, "shli", 3 },
509 { 0x5a0, "cmpo", 2 },
510 { 0x5a1, "cmpi", 2 },
511 { 0x5a2, "concmpo", 2 },
512 { 0x5a3, "concmpi", 2 },
513 { 0x5a4, "cmpinco", 3 },
514 { 0x5a5, "cmpinci", 3 },
515 { 0x5a6, "cmpdeco", 3 },
516 { 0x5a7, "cmpdeci", 3 },
517 { 0x5ac, "scanbyte", 2 },
518 { 0x5ad, "bswap", -2 },
519 { 0x5ae, "chkbit", 2 },
520 { 0x5b0, "addc", 3 },
521 { 0x5b2, "subc", 3 },
522 { 0x5b4, "intdis", 0 },
523 { 0x5b5, "inten", 0 },
524 { 0x5cc, "mov", -2 },
525 { 0x5d8, "eshro", 3 },
526 { 0x5dc, "movl", -2 },
527 { 0x5ec, "movt", -2 },
528 { 0x5fc, "movq", -2 },
529 { 0x600, "synmov", 2 },
530 { 0x601, "synmovl", 2 },
531 { 0x602, "synmovq", 2 },
532 { 0x603, "cmpstr", 3 },
533 { 0x604, "movqstr", 3 },
534 { 0x605, "movstr", 3 },
535 { 0x610, "atmod", 3 },
536 { 0x612, "atadd", 3 },
537 { 0x613, "inspacc", -2 },
538 { 0x614, "ldphy", -2 },
539 { 0x615, "synld", -2 },
540 { 0x617, "fill", 3 },
541 { 0x630, "sdma", 3 },
542 { 0x631, "udma", 0 },
543 { 0x640, "spanbit", -2 },
544 { 0x641, "scanbit", -2 },
545 { 0x642, "daddc", 3 },
546 { 0x643, "dsubc", 3 },
547 { 0x644, "dmovt", -2 },
548 { 0x645, "modac", 3 },
549 { 0x646, "condrec", -2 },
550 { 0x650, "modify", 3 },
551 { 0x651, "extract", 3 },
552 { 0x654, "modtc", 3 },
553 { 0x655, "modpc", 3 },
554 { 0x656, "receive", -2 },
555 { 0x658, "intctl", -2 },
556 { 0x659, "sysctl", 3 },
557 { 0x65b, "icctl", 3 },
558 { 0x65c, "dcctl", 3 },
559 { 0x65d, "halt", 0 },
560 { 0x660, "calls", 1 },
561 { 0x662, "send", 3 },
562 { 0x663, "sendserv", 1 },
563 { 0x664, "resumprcs", 1 },
564 { 0x665, "schedprcs", 1 },
565 { 0x666, "saveprcs", 0 },
566 { 0x668, "condwait", 1 },
567 { 0x669, "wait", 1 },
568 { 0x66a, "signal", 1 },
569 { 0x66b, "mark", 0 },
570 { 0x66c, "fmark", 0 },
571 { 0x66d, "flushreg", 0 },
572 { 0x66f, "syncf", 0 },
573 { 0x670, "emul", 3 },
574 { 0x671, "ediv", 3 },
575 { 0x673, "ldtime", -1 },
576 { 0x674, "Fcvtir", -2 },
577 { 0x675, "Fcvtilr", -2 },
578 { 0x676, "Fscalerl", 3 },
579 { 0x677, "Fscaler", 3 },
580 { 0x680, "Fatanr", 3 },
581 { 0x681, "Flogepr", 3 },
582 { 0x682, "Flogr", 3 },
583 { 0x683, "Fremr", 3 },
584 { 0x684, "Fcmpor", 2 },
585 { 0x685, "Fcmpr", 2 },
586 { 0x688, "Fsqrtr", -2 },
587 { 0x689, "Fexpr", -2 },
588 { 0x68a, "Flogbnr", -2 },
589 { 0x68b, "Froundr", -2 },
590 { 0x68c, "Fsinr", -2 },
591 { 0x68d, "Fcosr", -2 },
592 { 0x68e, "Ftanr", -2 },
593 { 0x68f, "Fclassr", 1 },
594 { 0x690, "Fatanrl", 3 },
595 { 0x691, "Flogeprl", 3 },
596 { 0x692, "Flogrl", 3 },
597 { 0x693, "Fremrl", 3 },
598 { 0x694, "Fcmporl", 2 },
599 { 0x695, "Fcmprl", 2 },
600 { 0x698, "Fsqrtrl", -2 },
601 { 0x699, "Fexprl", -2 },
602 { 0x69a, "Flogbnrl", -2 },
603 { 0x69b, "Froundrl", -2 },
604 { 0x69c, "Fsinrl", -2 },
605 { 0x69d, "Fcosrl", -2 },
606 { 0x69e, "Ftanrl", -2 },
607 { 0x69f, "Fclassrl", 1 },
608 { 0x6c0, "Fcvtri", -2 },
609 { 0x6c1, "Fcvtril", -2 },
610 { 0x6c2, "Fcvtzri", -2 },
611 { 0x6c3, "Fcvtzril", -2 },
612 { 0x6c9, "Fmovr", -2 },
613 { 0x6d9, "Fmovrl", -2 },
614 { 0x6e1, "Fmovre", -2 },
615 { 0x6e2, "Fcpysre", 3 },
616 { 0x6e3, "Fcpyrsre", 3 },
617 { 0x701, "mulo", 3 },
618 { 0x708, "remo", 3 },
619 { 0x70b, "divo", 3 },
620 { 0x741, "muli", 3 },
621 { 0x748, "remi", 3 },
622 { 0x749, "modi", 3 },
623 { 0x74b, "divi", 3 },
624 { 0x780, "addono", 3 },
625 { 0x781, "addino", 3 },
626 { 0x782, "subono", 3 },
627 { 0x783, "subino", 3 },
628 { 0x784, "selno", 3 },
629 { 0x78b, "Fdivr", 3 },
630 { 0x78c, "Fmulr", 3 },
631 { 0x78d, "Fsubr", 3 },
632 { 0x78f, "Faddr", 3 },
633 { 0x790, "addog", 3 },
634 { 0x791, "addig", 3 },
635 { 0x792, "subog", 3 },
636 { 0x793, "subig", 3 },
637 { 0x794, "selg", 3 },
638 { 0x79b, "Fdivrl", 3 },
639 { 0x79c, "Fmulrl", 3 },
640 { 0x79d, "Fsubrl", 3 },
641 { 0x79f, "Faddrl", 3 },
642 { 0x7a0, "addoe", 3 },
643 { 0x7a1, "addie", 3 },
644 { 0x7a2, "suboe", 3 },
645 { 0x7a3, "subie", 3 },
646 { 0x7a4, "sele", 3 },
647 { 0x7b0, "addoge", 3 },
648 { 0x7b1, "addige", 3 },
649 { 0x7b2, "suboge", 3 },
650 { 0x7b3, "subige", 3 },
651 { 0x7b4, "selge", 3 },
652 { 0x7c0, "addol", 3 },
653 { 0x7c1, "addil", 3 },
654 { 0x7c2, "subol", 3 },
655 { 0x7c3, "subil", 3 },
656 { 0x7c4, "sell", 3 },
657 { 0x7d0, "addone", 3 },
658 { 0x7d1, "addine", 3 },
659 { 0x7d2, "subone", 3 },
660 { 0x7d3, "subine", 3 },
661 { 0x7d4, "selne", 3 },
662 { 0x7e0, "addole", 3 },
663 { 0x7e1, "addile", 3 },
664 { 0x7e2, "subole", 3 },
665 { 0x7e3, "subile", 3 },
666 { 0x7e4, "selle", 3 },
667 { 0x7f0, "addoo", 3 },
668 { 0x7f1, "addio", 3 },
669 { 0x7f2, "suboo", 3 },
670 { 0x7f3, "subio", 3 },
671 { 0x7f4, "selo", 3 },
672 #define REG_MAX 0x7f4
675 static struct tabent reg_tab_buf
[REG_MAX
- REG_MIN
+ 1];
677 if ( reg_tab
== NULL
){
678 reg_tab
= reg_tab_buf
;
679 for ( i
= 0; reg_init
[i
].opcode
!= 0; i
++ ){
680 j
= reg_init
[i
].opcode
- REG_MIN
;
681 reg_tab
[j
].name
= reg_init
[i
].name
;
682 reg_tab
[j
].numops
= reg_init
[i
].numops
;
686 opcode
= ((word1
>> 20) & 0xff0) | ((word1
>> 7) & 0xf);
687 i
= opcode
- REG_MIN
;
689 if ( (opcode
<REG_MIN
) || (opcode
>REG_MAX
) || (reg_tab
[i
].name
==NULL
) ){
694 mnemp
= reg_tab
[i
].name
;
695 if ( *mnemp
== 'F' ){
702 (*info
->fprintf_func
)( stream
, mnemp
);
704 s1
= (word1
>> 5) & 1;
705 s2
= (word1
>> 6) & 1;
706 m1
= (word1
>> 11) & 1;
707 m2
= (word1
>> 12) & 1;
708 m3
= (word1
>> 13) & 1;
710 src2
= (word1
>> 14) & 0x1f;
711 dst
= (word1
>> 19) & 0x1f;
713 if ( reg_tab
[i
].numops
!= 0 ){
714 (*info
->fprintf_func
)( stream
, "\t" );
716 switch ( reg_tab
[i
].numops
){
718 regop( m1
, s1
, src
, fp
);
721 dstop( m3
, dst
, fp
);
724 regop( m1
, s1
, src
, fp
);
725 (*info
->fprintf_func
)( stream
, "," );
726 regop( m2
, s2
, src2
, fp
);
729 regop( m1
, s1
, src
, fp
);
730 (*info
->fprintf_func
)( stream
, "," );
731 dstop( m3
, dst
, fp
);
734 regop( m1
, s1
, src
, fp
);
735 (*info
->fprintf_func
)( stream
, "," );
736 regop( m2
, s2
, src2
, fp
);
737 (*info
->fprintf_func
)( stream
, "," );
738 dstop( m3
, dst
, fp
);
746 * Print out effective address for memb instructions.
749 ea( memaddr
, mode
, reg2
, reg3
, word1
, word2
)
757 static const int scale_tab
[] = { 1, 2, 4, 8, 16 };
759 scale
= (word1
>> 7) & 0x07;
760 if ( (scale
> 4) || (((word1
>> 5) & 0x03) != 0) ){
764 scale
= scale_tab
[scale
];
768 (*info
->fprintf_func
)( stream
, "(%s)", reg2
);
770 case 5: /* displ+8(ip) */
771 print_addr( word2
+8+memaddr
);
773 case 7: /* (reg)[index*scale] */
775 (*info
->fprintf_func
)( stream
, "(%s)[%s]", reg2
, reg3
);
777 (*info
->fprintf_func
)( stream
, "(%s)[%s*%d]",reg2
,reg3
,scale
);
780 case 12: /* displacement */
781 print_addr( (bfd_vma
)word2
);
783 case 13: /* displ(reg) */
784 print_addr( (bfd_vma
)word2
);
785 (*info
->fprintf_func
)( stream
, "(%s)", reg2
);
787 case 14: /* displ[index*scale] */
788 print_addr( (bfd_vma
)word2
);
790 (*info
->fprintf_func
)( stream
, "[%s]", reg3
);
792 (*info
->fprintf_func
)( stream
, "[%s*%d]", reg3
, scale
);
795 case 15: /* displ(reg)[index*scale] */
796 print_addr( (bfd_vma
)word2
);
798 (*info
->fprintf_func
)( stream
, "(%s)[%s]", reg2
, reg3
);
800 (*info
->fprintf_func
)( stream
, "(%s)[%s*%d]",reg2
,reg3
,scale
);
810 /************************************************/
811 /* Register Instruction Operand */
812 /************************************************/
814 regop( mode
, spec
, reg
, fp
)
815 int mode
, spec
, reg
, fp
;
817 if ( fp
){ /* FLOATING POINT INSTRUCTION */
818 if ( mode
== 1 ){ /* FP operand */
820 case 0: (*info
->fprintf_func
)( stream
, "fp0" );
822 case 1: (*info
->fprintf_func
)( stream
, "fp1" );
824 case 2: (*info
->fprintf_func
)( stream
, "fp2" );
826 case 3: (*info
->fprintf_func
)( stream
, "fp3" );
828 case 16: (*info
->fprintf_func
)( stream
, "0f0.0" );
830 case 22: (*info
->fprintf_func
)( stream
, "0f1.0" );
832 default: (*info
->fprintf_func
)( stream
, "?" );
835 } else { /* Non-FP register */
836 (*info
->fprintf_func
)( stream
, reg_names
[reg
] );
838 } else { /* NOT FLOATING POINT */
839 if ( mode
== 1 ){ /* Literal */
840 (*info
->fprintf_func
)( stream
, "%d", reg
);
841 } else { /* Register */
843 (*info
->fprintf_func
)( stream
, reg_names
[reg
] );
845 (*info
->fprintf_func
)( stream
, "sf%d", reg
);
851 /************************************************/
852 /* Register Instruction Destination Operand */
853 /************************************************/
855 dstop( mode
, reg
, fp
)
858 /* 'dst' operand can't be a literal. On non-FP instructions, register
859 * mode is assumed and "m3" acts as if were "s3"; on FP-instructions,
860 * sf registers are not allowed so m3 acts normally.
863 regop( mode
, 0, reg
, fp
);
865 regop( 0, mode
, reg
, fp
);
874 (*info
->fprintf_func
)( stream
, ".word\t0x%08x", (unsigned) word1
);
881 (*info
->print_address_func
) (a
, info
);
885 put_abs( word1
, word2
)
886 unsigned long word1
, word2
;
893 switch ( (word1
>> 28) & 0xf ){
899 /* MEM format instruction */
900 len
= mem( 0, word1
, word2
, 1 );
908 (*info
->fprintf_func
)( stream
, "%08x %08x\t", word1
, word2
);
910 (*info
->fprintf_func
)( stream
, "%08x \t", word1
);