xref: /openbmc/qemu/disas/hppa.c (revision b887b6b7)
1 /* Disassembler for the PA-RISC. Somewhat derived from sparc-pinsn.c.
2    Copyright 1989, 1990, 1992, 1993, 1994, 1995, 1998, 1999, 2000, 2001, 2003,
3    2005 Free Software Foundation, Inc.
4 
5    Contributed by the Center for Software Science at the
6    University of Utah (pa-gdb-bugs@cs.utah.edu).
7 
8    This program is free software; you can redistribute it and/or modify
9    it under the terms of the GNU General Public License as published by
10    the Free Software Foundation; either version 2 of the License, or
11    (at your option) any later version.
12 
13    This program is distributed in the hope that it will be useful,
14    but WITHOUT ANY WARRANTY; without even the implied warranty of
15    MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
16    GNU General Public License for more details.
17 
18    You should have received a copy of the GNU General Public License
19    along with this program; if not, see <http://www.gnu.org/licenses/>. */
20 
21 #include "qemu/osdep.h"
22 #include "disas/dis-asm.h"
23 
24 /* HP PA-RISC SOM object file format:  definitions internal to BFD.
25    Copyright 1990, 1991, 1992, 1993, 1994, 1995, 1996, 1998, 1999, 2000,
26    2003 Free Software Foundation, Inc.
27 
28    Contributed by the Center for Software Science at the
29    University of Utah (pa-gdb-bugs@cs.utah.edu).
30 
31    This file is part of BFD, the Binary File Descriptor library.
32 
33    This program is free software; you can redistribute it and/or modify
34    it under the terms of the GNU General Public License as published by
35    the Free Software Foundation; either version 2 of the License, or
36    (at your option) any later version.
37 
38    This program is distributed in the hope that it will be useful,
39    but WITHOUT ANY WARRANTY; without even the implied warranty of
40    MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
41    GNU General Public License for more details.
42 
43    You should have received a copy of the GNU General Public License
44    along with this program; if not, see <http://www.gnu.org/licenses/>.  */
45 
46 #ifndef _LIBHPPA_H
47 #define _LIBHPPA_H
48 
49 #define BYTES_IN_WORD 4
50 #define PA_PAGESIZE 0x1000
51 
52 /* The PA instruction set variants.  */
53 enum pa_arch {pa10 = 10, pa11 = 11, pa20 = 20, pa20w = 25};
54 
55 /* HP PA-RISC relocation types */
56 
57 enum hppa_reloc_field_selector_type
58   {
59     R_HPPA_FSEL = 0x0,
60     R_HPPA_LSSEL = 0x1,
61     R_HPPA_RSSEL = 0x2,
62     R_HPPA_LSEL = 0x3,
63     R_HPPA_RSEL = 0x4,
64     R_HPPA_LDSEL = 0x5,
65     R_HPPA_RDSEL = 0x6,
66     R_HPPA_LRSEL = 0x7,
67     R_HPPA_RRSEL = 0x8,
68     R_HPPA_NSEL  = 0x9,
69     R_HPPA_NLSEL  = 0xa,
70     R_HPPA_NLRSEL  = 0xb,
71     R_HPPA_PSEL = 0xc,
72     R_HPPA_LPSEL = 0xd,
73     R_HPPA_RPSEL = 0xe,
74     R_HPPA_TSEL = 0xf,
75     R_HPPA_LTSEL = 0x10,
76     R_HPPA_RTSEL = 0x11,
77     R_HPPA_LTPSEL = 0x12,
78     R_HPPA_RTPSEL = 0x13
79   };
80 
81 /* /usr/include/reloc.h defines these to constants.  We want to use
82    them in enums, so #undef them before we start using them.  We might
83    be able to fix this another way by simply managing not to include
84    /usr/include/reloc.h, but currently GDB picks up these defines
85    somewhere.  */
86 #undef e_fsel
87 #undef e_lssel
88 #undef e_rssel
89 #undef e_lsel
90 #undef e_rsel
91 #undef e_ldsel
92 #undef e_rdsel
93 #undef e_lrsel
94 #undef e_rrsel
95 #undef e_nsel
96 #undef e_nlsel
97 #undef e_nlrsel
98 #undef e_psel
99 #undef e_lpsel
100 #undef e_rpsel
101 #undef e_tsel
102 #undef e_ltsel
103 #undef e_rtsel
104 #undef e_one
105 #undef e_two
106 #undef e_pcrel
107 #undef e_con
108 #undef e_plabel
109 #undef e_abs
110 
111 /* for compatibility */
112 enum hppa_reloc_field_selector_type_alt
113   {
114     e_fsel = R_HPPA_FSEL,
115     e_lssel = R_HPPA_LSSEL,
116     e_rssel = R_HPPA_RSSEL,
117     e_lsel = R_HPPA_LSEL,
118     e_rsel = R_HPPA_RSEL,
119     e_ldsel = R_HPPA_LDSEL,
120     e_rdsel = R_HPPA_RDSEL,
121     e_lrsel = R_HPPA_LRSEL,
122     e_rrsel = R_HPPA_RRSEL,
123     e_nsel = R_HPPA_NSEL,
124     e_nlsel = R_HPPA_NLSEL,
125     e_nlrsel = R_HPPA_NLRSEL,
126     e_psel = R_HPPA_PSEL,
127     e_lpsel = R_HPPA_LPSEL,
128     e_rpsel = R_HPPA_RPSEL,
129     e_tsel = R_HPPA_TSEL,
130     e_ltsel = R_HPPA_LTSEL,
131     e_rtsel = R_HPPA_RTSEL,
132     e_ltpsel = R_HPPA_LTPSEL,
133     e_rtpsel = R_HPPA_RTPSEL
134   };
135 
136 enum hppa_reloc_expr_type
137   {
138     R_HPPA_E_ONE = 0,
139     R_HPPA_E_TWO = 1,
140     R_HPPA_E_PCREL = 2,
141     R_HPPA_E_CON = 3,
142     R_HPPA_E_PLABEL = 7,
143     R_HPPA_E_ABS = 18
144   };
145 
146 /* for compatibility */
147 enum hppa_reloc_expr_type_alt
148   {
149     e_one = R_HPPA_E_ONE,
150     e_two = R_HPPA_E_TWO,
151     e_pcrel = R_HPPA_E_PCREL,
152     e_con = R_HPPA_E_CON,
153     e_plabel = R_HPPA_E_PLABEL,
154     e_abs = R_HPPA_E_ABS
155   };
156 
157 
158 /* Relocations for function calls must be accompanied by parameter
159    relocation bits.  These bits describe exactly where the caller has
160    placed the function's arguments and where it expects to find a return
161    value.
162 
163    Both ELF and SOM encode this information within the addend field
164    of the call relocation.  (Note this could break very badly if one
165    was to make a call like bl foo + 0x12345678).
166 
167    The high order 10 bits contain parameter relocation information,
168    the low order 22 bits contain the constant offset.  */
169 
170 #define HPPA_R_ARG_RELOC(a)	\
171   (((a) >> 22) & 0x3ff)
172 #define HPPA_R_CONSTANT(a)	\
173   ((((bfd_signed_vma)(a)) << (BFD_ARCH_SIZE-22)) >> (BFD_ARCH_SIZE-22))
174 #define HPPA_R_ADDEND(r, c)	\
175   (((r) << 22) + ((c) & 0x3fffff))
176 
177 
178 /* Some functions to manipulate PA instructions.  */
179 
180 /* Declare the functions with the unused attribute to avoid warnings.  */
181 static inline int sign_extend (int, int) ATTRIBUTE_UNUSED;
182 static inline int low_sign_extend (int, int) ATTRIBUTE_UNUSED;
183 static inline int sign_unext (int, int) ATTRIBUTE_UNUSED;
184 static inline int low_sign_unext (int, int) ATTRIBUTE_UNUSED;
185 static inline int re_assemble_3 (int) ATTRIBUTE_UNUSED;
186 static inline int re_assemble_12 (int) ATTRIBUTE_UNUSED;
187 static inline int re_assemble_14 (int) ATTRIBUTE_UNUSED;
188 static inline int re_assemble_16 (int) ATTRIBUTE_UNUSED;
189 static inline int re_assemble_17 (int) ATTRIBUTE_UNUSED;
190 static inline int re_assemble_21 (int) ATTRIBUTE_UNUSED;
191 static inline int re_assemble_22 (int) ATTRIBUTE_UNUSED;
192 static inline bfd_signed_vma hppa_field_adjust
193   (bfd_vma, bfd_signed_vma, enum hppa_reloc_field_selector_type_alt)
194   ATTRIBUTE_UNUSED;
195 static inline int hppa_rebuild_insn (int, int, int) ATTRIBUTE_UNUSED;
196 
197 
198 /* The *sign_extend functions are used to assemble various bitfields
199    taken from an instruction and return the resulting immediate
200    value.  */
201 
202 static inline int
203 sign_extend (int x, int len)
204 {
205   int signbit = (1 << (len - 1));
206   int mask = (signbit << 1) - 1;
207   return ((x & mask) ^ signbit) - signbit;
208 }
209 
210 static inline int
211 low_sign_extend (int x, int len)
212 {
213   return (x >> 1) - ((x & 1) << (len - 1));
214 }
215 
216 
217 /* The re_assemble_* functions prepare an immediate value for
218    insertion into an opcode. pa-risc uses all sorts of weird bitfields
219    in the instruction to hold the value.  */
220 
221 static inline int
222 sign_unext (int x, int len)
223 {
224   int len_ones;
225 
226   len_ones = (1 << len) - 1;
227 
228   return x & len_ones;
229 }
230 
231 static inline int
232 low_sign_unext (int x, int len)
233 {
234   int temp;
235   int sign;
236 
237   sign = (x >> (len-1)) & 1;
238 
239   temp = sign_unext (x, len-1);
240 
241   return (temp << 1) | sign;
242 }
243 
244 static inline int
245 re_assemble_3 (int as3)
246 {
247   return ((  (as3 & 4) << (13-2))
248 	  | ((as3 & 3) << (13+1)));
249 }
250 
251 static inline int
252 re_assemble_12 (int as12)
253 {
254   return ((  (as12 & 0x800) >> 11)
255 	  | ((as12 & 0x400) >> (10 - 2))
256 	  | ((as12 & 0x3ff) << (1 + 2)));
257 }
258 
259 static inline int
260 re_assemble_14 (int as14)
261 {
262   return ((  (as14 & 0x1fff) << 1)
263 	  | ((as14 & 0x2000) >> 13));
264 }
265 
266 static inline int
267 re_assemble_16 (int as16)
268 {
269   int s, t;
270 
271   /* Unusual 16-bit encoding, for wide mode only.  */
272   t = (as16 << 1) & 0xffff;
273   s = (as16 & 0x8000);
274   return (t ^ s ^ (s >> 1)) | (s >> 15);
275 }
276 
277 static inline int
278 re_assemble_17 (int as17)
279 {
280   return ((  (as17 & 0x10000) >> 16)
281 	  | ((as17 & 0x0f800) << (16 - 11))
282 	  | ((as17 & 0x00400) >> (10 - 2))
283 	  | ((as17 & 0x003ff) << (1 + 2)));
284 }
285 
286 static inline int
287 re_assemble_21 (int as21)
288 {
289   return ((  (as21 & 0x100000) >> 20)
290 	  | ((as21 & 0x0ffe00) >> 8)
291 	  | ((as21 & 0x000180) << 7)
292 	  | ((as21 & 0x00007c) << 14)
293 	  | ((as21 & 0x000003) << 12));
294 }
295 
296 static inline int
297 re_assemble_22 (int as22)
298 {
299   return ((  (as22 & 0x200000) >> 21)
300 	  | ((as22 & 0x1f0000) << (21 - 16))
301 	  | ((as22 & 0x00f800) << (16 - 11))
302 	  | ((as22 & 0x000400) >> (10 - 2))
303 	  | ((as22 & 0x0003ff) << (1 + 2)));
304 }
305 
306 
307 /* Handle field selectors for PA instructions.
308    The L and R (and LS, RS etc.) selectors are used in pairs to form a
309    full 32 bit address.  eg.
310 
311    LDIL	L'start,%r1		; put left part into r1
312    LDW	R'start(%r1),%r2	; add r1 and right part to form address
313 
314    This function returns sign extended values in all cases.
315 */
316 
317 static inline bfd_signed_vma
318 hppa_field_adjust (bfd_vma sym_val,
319 		   bfd_signed_vma addend,
320 		   enum hppa_reloc_field_selector_type_alt r_field)
321 {
322   bfd_signed_vma value;
323 
324   value = sym_val + addend;
325   switch (r_field)
326     {
327     case e_fsel:
328       /* F: No change.  */
329       break;
330 
331     case e_nsel:
332       /* N: null selector.  I don't really understand what this is all
333 	 about, but HP's documentation says "this indicates that zero
334 	 bits are to be used for the displacement on the instruction.
335 	 This fixup is used to identify three-instruction sequences to
336 	 access data (for importing shared library data)."  */
337       value = 0;
338       break;
339 
340     case e_lsel:
341     case e_nlsel:
342       /* L:  Select top 21 bits.  */
343       value = value >> 11;
344       break;
345 
346     case e_rsel:
347       /* R:  Select bottom 11 bits.  */
348       value = value & 0x7ff;
349       break;
350 
351     case e_lssel:
352       /* LS:  Round to nearest multiple of 2048 then select top 21 bits.  */
353       value = value + 0x400;
354       value = value >> 11;
355       break;
356 
357     case e_rssel:
358       /* RS:  Select bottom 11 bits for LS.
359 	 We need to return a value such that 2048 * LS'x + RS'x == x.
360 	 ie. RS'x = x - ((x + 0x400) & -0x800)
361 	 this is just a sign extension from bit 21.  */
362       value = ((value & 0x7ff) ^ 0x400) - 0x400;
363       break;
364 
365     case e_ldsel:
366       /* LD:  Round to next multiple of 2048 then select top 21 bits.
367 	 Yes, if we are already on a multiple of 2048, we go up to the
368 	 next one.  RD in this case will be -2048.  */
369       value = value + 0x800;
370       value = value >> 11;
371       break;
372 
373     case e_rdsel:
374       /* RD:  Set bits 0-20 to one.  */
375       value = value | -0x800;
376       break;
377 
378     case e_lrsel:
379     case e_nlrsel:
380       /* LR:  L with rounding of the addend to nearest 8k.  */
381       value = sym_val + ((addend + 0x1000) & -0x2000);
382       value = value >> 11;
383       break;
384 
385     case e_rrsel:
386       /* RR:  R with rounding of the addend to nearest 8k.
387 	 We need to return a value such that 2048 * LR'x + RR'x == x
388 	 ie. RR'x = s+a - (s + (((a + 0x1000) & -0x2000) & -0x800))
389 	 .	  = s+a - ((s & -0x800) + ((a + 0x1000) & -0x2000))
390 	 .	  = (s & 0x7ff) + a - ((a + 0x1000) & -0x2000)  */
391       value = (sym_val & 0x7ff) + (((addend & 0x1fff) ^ 0x1000) - 0x1000);
392       break;
393 
394     default:
395       abort ();
396     }
397   return value;
398 }
399 
400 /* PA-RISC OPCODES */
401 #define get_opcode(insn)	(((insn) >> 26) & 0x3f)
402 
403 enum hppa_opcode_type
404 {
405   /* None of the opcodes in the first group generate relocs, so we
406      aren't too concerned about them.  */
407   OP_SYSOP   = 0x00,
408   OP_MEMMNG  = 0x01,
409   OP_ALU     = 0x02,
410   OP_NDXMEM  = 0x03,
411   OP_SPOP    = 0x04,
412   OP_DIAG    = 0x05,
413   OP_FMPYADD = 0x06,
414   OP_UNDEF07 = 0x07,
415   OP_COPRW   = 0x09,
416   OP_COPRDW  = 0x0b,
417   OP_COPR    = 0x0c,
418   OP_FLOAT   = 0x0e,
419   OP_PRDSPEC = 0x0f,
420   OP_UNDEF15 = 0x15,
421   OP_UNDEF1d = 0x1d,
422   OP_FMPYSUB = 0x26,
423   OP_FPFUSED = 0x2e,
424   OP_SHEXDP0 = 0x34,
425   OP_SHEXDP1 = 0x35,
426   OP_SHEXDP2 = 0x36,
427   OP_UNDEF37 = 0x37,
428   OP_SHEXDP3 = 0x3c,
429   OP_SHEXDP4 = 0x3d,
430   OP_MULTMED = 0x3e,
431   OP_UNDEF3f = 0x3f,
432 
433   OP_LDIL    = 0x08,
434   OP_ADDIL   = 0x0a,
435 
436   OP_LDO     = 0x0d,
437   OP_LDB     = 0x10,
438   OP_LDH     = 0x11,
439   OP_LDW     = 0x12,
440   OP_LDWM    = 0x13,
441   OP_STB     = 0x18,
442   OP_STH     = 0x19,
443   OP_STW     = 0x1a,
444   OP_STWM    = 0x1b,
445 
446   OP_LDD     = 0x14,
447   OP_STD     = 0x1c,
448 
449   OP_FLDW    = 0x16,
450   OP_LDWL    = 0x17,
451   OP_FSTW    = 0x1e,
452   OP_STWL    = 0x1f,
453 
454   OP_COMBT   = 0x20,
455   OP_COMIBT  = 0x21,
456   OP_COMBF   = 0x22,
457   OP_COMIBF  = 0x23,
458   OP_CMPBDT  = 0x27,
459   OP_ADDBT   = 0x28,
460   OP_ADDIBT  = 0x29,
461   OP_ADDBF   = 0x2a,
462   OP_ADDIBF  = 0x2b,
463   OP_CMPBDF  = 0x2f,
464   OP_BVB     = 0x30,
465   OP_BB      = 0x31,
466   OP_MOVB    = 0x32,
467   OP_MOVIB   = 0x33,
468   OP_CMPIBD  = 0x3b,
469 
470   OP_COMICLR = 0x24,
471   OP_SUBI    = 0x25,
472   OP_ADDIT   = 0x2c,
473   OP_ADDI    = 0x2d,
474 
475   OP_BE      = 0x38,
476   OP_BLE     = 0x39,
477   OP_BL      = 0x3a
478 };
479 
480 
481 /* Insert VALUE into INSN using R_FORMAT to determine exactly what
482    bits to change.  */
483 
484 static inline int
485 hppa_rebuild_insn (int insn, int value, int r_format)
486 {
487   switch (r_format)
488     {
489     case 11:
490       return (insn & ~ 0x7ff) | low_sign_unext (value, 11);
491 
492     case 12:
493       return (insn & ~ 0x1ffd) | re_assemble_12 (value);
494 
495 
496     case 10:
497       return (insn & ~ 0x3ff1) | re_assemble_14 (value & -8);
498 
499     case -11:
500       return (insn & ~ 0x3ff9) | re_assemble_14 (value & -4);
501 
502     case 14:
503       return (insn & ~ 0x3fff) | re_assemble_14 (value);
504 
505 
506     case -10:
507       return (insn & ~ 0xfff1) | re_assemble_16 (value & -8);
508 
509     case -16:
510       return (insn & ~ 0xfff9) | re_assemble_16 (value & -4);
511 
512     case 16:
513       return (insn & ~ 0xffff) | re_assemble_16 (value);
514 
515 
516     case 17:
517       return (insn & ~ 0x1f1ffd) | re_assemble_17 (value);
518 
519     case 21:
520       return (insn & ~ 0x1fffff) | re_assemble_21 (value);
521 
522     case 22:
523       return (insn & ~ 0x3ff1ffd) | re_assemble_22 (value);
524 
525     case 32:
526       return value;
527 
528     default:
529       abort ();
530     }
531   return insn;
532 }
533 
534 #endif /* _LIBHPPA_H */
535 /* Table of opcodes for the PA-RISC.
536    Copyright 1990, 1991, 1992, 1993, 1994, 1995, 1996, 1998, 1999, 2000,
537    2001, 2002, 2003, 2004, 2005
538    Free Software Foundation, Inc.
539 
540    Contributed by the Center for Software Science at the
541    University of Utah (pa-gdb-bugs@cs.utah.edu).
542 
543 This file is part of GAS, the GNU Assembler, and GDB, the GNU disassembler.
544 
545 GAS/GDB is free software; you can redistribute it and/or modify
546 it under the terms of the GNU General Public License as published by
547 the Free Software Foundation; either version 1, or (at your option)
548 any later version.
549 
550 GAS/GDB is distributed in the hope that it will be useful,
551 but WITHOUT ANY WARRANTY; without even the implied warranty of
552 MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
553 GNU General Public License for more details.
554 
555 You should have received a copy of the GNU General Public License
556 along with GAS or GDB; see the file COPYING.
557 If not, see <http://www.gnu.org/licenses/>. */
558 
559 #if !defined(__STDC__) && !defined(const)
560 #define const
561 #endif
562 
563 /*
564  * Structure of an opcode table entry.
565  */
566 
567 /* There are two kinds of delay slot nullification: normal which is
568  * controlled by the nullification bit, and conditional, which depends
569  * on the direction of the branch and its success or failure.
570  *
571  * NONE is unfortunately #defined in the hiux system include files.
572  * #undef it away.
573  */
574 #undef NONE
575 struct pa_opcode
576 {
577     const char *name;
578     unsigned long int match;	/* Bits that must be set...  */
579     unsigned long int mask;	/* ... in these bits. */
580     const char *args;
581     enum pa_arch arch;
582     char flags;
583 };
584 
585 /* Enables strict matching.  Opcodes with match errors are skipped
586    when this bit is set.  */
587 #define FLAG_STRICT 0x1
588 
589 /*
590    All hppa opcodes are 32 bits.
591 
592    The match component is a mask saying which bits must match a
593    particular opcode in order for an instruction to be an instance
594    of that opcode.
595 
596    The args component is a string containing one character for each operand of
597    the instruction.  Characters used as a prefix allow any second character to
598    be used without conflicting with the main operand characters.
599 
600    Bit positions in this description follow HP usage of lsb = 31,
601    "at" is lsb of field.
602 
603    In the args field, the following characters must match exactly:
604 
605 	'+,() '
606 
607    In the args field, the following characters are unused:
608 
609 	'  "         -  /   34 6789:;    '
610 	'@  C         M             [\]  '
611 	'`    e g                     }  '
612 
613    Here are all the characters:
614 
615 	' !"#$%&'()*+-,./0123456789:;<=>?'
616 	'@ABCDEFGHIJKLMNOPQRSTUVWXYZ[\]^_'
617 	'`abcdefghijklmnopqrstuvwxyz{|}~ '
618 
619 Kinds of operands:
620    x    integer register field at 15.
621    b    integer register field at 10.
622    t    integer register field at 31.
623    a	integer register field at 10 and 15 (for PERMH)
624    5    5 bit immediate at 15.
625    s    2 bit space specifier at 17.
626    S    3 bit space specifier at 18.
627    V    5 bit immediate value at 31
628    i    11 bit immediate value at 31
629    j    14 bit immediate value at 31
630    k    21 bit immediate value at 31
631    l    16 bit immediate value at 31 (wide mode only, unusual encoding).
632    n	nullification for branch instructions
633    N	nullification for spop and copr instructions
634    w    12 bit branch displacement
635    W    17 bit branch displacement (PC relative)
636    X    22 bit branch displacement (PC relative)
637    z    17 bit branch displacement (just a number, not an address)
638 
639 Also these:
640 
641    .    2 bit shift amount at 25
642    *    4 bit shift amount at 25
643    p    5 bit shift count at 26 (to support the SHD instruction) encoded as
644         31-p
645    ~    6 bit shift count at 20,22:26 encoded as 63-~.
646    P    5 bit bit position at 26
647    q    6 bit bit position at 20,22:26
648    T    5 bit field length at 31 (encoded as 32-T)
649    %	6 bit field length at 23,27:31 (variable extract/deposit)
650    |	6 bit field length at 19,27:31 (fixed extract/deposit)
651    A    13 bit immediate at 18 (to support the BREAK instruction)
652    ^	like b, but describes a control register
653    !    sar (cr11) register
654    D    26 bit immediate at 31 (to support the DIAG instruction)
655    $    9 bit immediate at 28 (to support POPBTS)
656 
657    v    3 bit Special Function Unit identifier at 25
658    O    20 bit Special Function Unit operation split between 15 bits at 20
659         and 5 bits at 31
660    o    15 bit Special Function Unit operation at 20
661    2    22 bit Special Function Unit operation split between 17 bits at 20
662         and 5 bits at 31
663    1    15 bit Special Function Unit operation split between 10 bits at 20
664         and 5 bits at 31
665    0    10 bit Special Function Unit operation split between 5 bits at 20
666         and 5 bits at 31
667    u    3 bit coprocessor unit identifier at 25
668    F    Source Floating Point Operand Format Completer encoded 2 bits at 20
669    I    Source Floating Point Operand Format Completer encoded 1 bits at 20
670 	(for 0xe format FP instructions)
671    G    Destination Floating Point Operand Format Completer encoded 2 bits at 18
672    H    Floating Point Operand Format at 26 for 'fmpyadd' and 'fmpysub'
673         (very similar to 'F')
674 
675    r	5 bit immediate value at 31 (for the break instruction)
676 	(very similar to V above, except the value is unsigned instead of
677 	low_sign_ext)
678    R	5 bit immediate value at 15 (for the ssm, rsm, probei instructions)
679 	(same as r above, except the value is in a different location)
680    U	10 bit immediate value at 15 (for SSM, RSM on pa2.0)
681    Q	5 bit immediate value at 10 (a bit position specified in
682 	the bb instruction. It's the same as r above, except the
683         value is in a different location)
684    B	5 bit immediate value at 10 (a bit position specified in
685 	the bb instruction. Similar to Q, but 64 bit handling is
686 	different.
687    Z    %r1 -- implicit target of addil instruction.
688    L    ,%r2 completer for new syntax branch
689    {    Source format completer for fcnv
690    _    Destination format completer for fcnv
691    h    cbit for fcmp
692    =    gfx tests for ftest
693    d    14 bit offset for single precision FP long load/store.
694    #    14 bit offset for double precision FP load long/store.
695    J    Yet another 14 bit offset for load/store with ma,mb completers.
696    K    Yet another 14 bit offset for load/store with ma,mb completers.
697    y    16 bit offset for word aligned load/store (PA2.0 wide).
698    &    16 bit offset for dword aligned load/store (PA2.0 wide).
699    <    16 bit offset for load/store with ma,mb completers (PA2.0 wide).
700    >    16 bit offset for load/store with ma,mb completers (PA2.0 wide).
701    Y    %sr0,%r31 -- implicit target of be,l instruction.
702    @	implicit immediate value of 0
703 
704 Completer operands all have 'c' as the prefix:
705 
706    cx   indexed load and store completer.
707    cX   indexed load and store completer.  Like cx, but emits a space
708 	after in disassembler.
709    cm   short load and store completer.
710    cM   short load and store completer.  Like cm, but emits a space
711         after in disassembler.
712    cq   long load and store completer (like cm, but inserted into a
713 	different location in the target instruction).
714    cs   store bytes short completer.
715    cA   store bytes short completer.  Like cs, but emits a space
716         after in disassembler.
717    ce   long load/store completer for LDW/STW with a different encoding
718 	than the others
719    cc   load cache control hint
720    cd   load and clear cache control hint
721    cC   store cache control hint
722    co	ordered access
723 
724    cp	branch link and push completer
725    cP	branch pop completer
726    cl	branch link completer
727    cg	branch gate completer
728 
729    cw	read/write completer for PROBE
730    cW	wide completer for MFCTL
731    cL	local processor completer for cache control
732    cZ   System Control Completer (to support LPA, LHA, etc.)
733 
734    ci	correction completer for DCOR
735    ca	add completer
736    cy	32 bit add carry completer
737    cY	64 bit add carry completer
738    cv	signed overflow trap completer
739    ct	trap on condition completer for ADDI, SUB
740    cT	trap on condition completer for UADDCM
741    cb	32 bit borrow completer for SUB
742    cB	64 bit borrow completer for SUB
743 
744    ch	left/right half completer
745    cH	signed/unsigned saturation completer
746    cS	signed/unsigned completer at 21
747    cz	zero/sign extension completer.
748    c*	permutation completer
749 
750 Condition operands all have '?' as the prefix:
751 
752    ?f   Floating point compare conditions (encoded as 5 bits at 31)
753 
754    ?a	add conditions
755    ?A	64 bit add conditions
756    ?@   add branch conditions followed by nullify
757    ?d	non-negated add branch conditions
758    ?D	negated add branch conditions
759    ?w	wide mode non-negated add branch conditions
760    ?W	wide mode negated add branch conditions
761 
762    ?s   compare/subtract conditions
763    ?S	64 bit compare/subtract conditions
764    ?t   non-negated compare and branch conditions
765    ?n   32 bit compare and branch conditions followed by nullify
766    ?N   64 bit compare and branch conditions followed by nullify
767    ?Q	64 bit compare and branch conditions for CMPIB instruction
768 
769    ?l   logical conditions
770    ?L	64 bit logical conditions
771 
772    ?b   branch on bit conditions
773    ?B	64 bit branch on bit conditions
774 
775    ?x   shift/extract/deposit conditions
776    ?X	64 bit shift/extract/deposit conditions
777    ?y   shift/extract/deposit conditions followed by nullify for conditional
778         branches
779 
780    ?u   unit conditions
781    ?U   64 bit unit conditions
782 
783 Floating point registers all have 'f' as a prefix:
784 
785    ft	target register at 31
786    fT	target register with L/R halves at 31
787    fa	operand 1 register at 10
788    fA   operand 1 register with L/R halves at 10
789    fX   Same as fA, except prints a space before register during disasm
790    fb	operand 2 register at 15
791    fB   operand 2 register with L/R halves at 15
792    fC   operand 3 register with L/R halves at 16:18,21:23
793    fe   Like fT, but encoding is different.
794    fE   Same as fe, except prints a space before register during disasm.
795    fx	target register at 15 (only for PA 2.0 long format FLDD/FSTD).
796 
797 Float registers for fmpyadd and fmpysub:
798 
799    fi	mult operand 1 register at 10
800    fj	mult operand 2 register at 15
801    fk	mult target register at 20
802    fl	add/sub operand register at 25
803    fm	add/sub target register at 31
804 
805 */
806 
807 
808 #if 0
809 /* List of characters not to put a space after.  Note that
810    "," is included, as the "spopN" operations use literal
811    commas in their completer sections.  */
812 static const char *const completer_chars = ",CcY<>?!@+&U~FfGHINnOoZMadu|/=0123%e$m}";
813 #endif
814 
815 /* The order of the opcodes in this table is significant:
816 
817    * The assembler requires that all instances of the same mnemonic be
818      consecutive.  If they aren't, the assembler will bomb at runtime.
819 
820    * Immediate fields use pa_get_absolute_expression to parse the
821      string.  It will generate a "bad expression" error if passed
822      a register name.  Thus, register index variants of an opcode
823      need to precede immediate variants.
824 
825    * The disassembler does not care about the order of the opcodes
826      except in cases where implicit addressing is used.
827 
828    Here are the rules for ordering the opcodes of a mnemonic:
829 
830    1) Opcodes with FLAG_STRICT should precede opcodes without
831       FLAG_STRICT.
832 
833    2) Opcodes with FLAG_STRICT should be ordered as follows:
834       register index opcodes, short immediate opcodes, and finally
835       long immediate opcodes.  When both pa10 and pa11 variants
836       of the same opcode are available, the pa10 opcode should
837       come first for correct architectural promotion.
838 
839    3) When implicit addressing is available for an opcode, the
840       implicit opcode should precede the explicit opcode.
841 
842    4) Opcodes without FLAG_STRICT should be ordered as follows:
843       register index opcodes, long immediate opcodes, and finally
844       short immediate opcodes.  */
845 
846 static const struct pa_opcode pa_opcodes[] =
847 {
848 
849 /* Pseudo-instructions.  */
850 
851 { "ldi",	0x34000000, 0xffe00000, "l,x", pa20w, 0},/* ldo val(r0),r */
852 { "ldi",	0x34000000, 0xffe0c000, "j,x", pa10, 0},/* ldo val(r0),r */
853 
854 { "cmpib",	0xec000000, 0xfc000000, "?Qn5,b,w", pa20, FLAG_STRICT},
855 { "cmpib", 	0x84000000, 0xf4000000, "?nn5,b,w", pa10, FLAG_STRICT},
856 { "comib", 	0x84000000, 0xfc000000, "?nn5,b,w", pa10, 0}, /* comib{tf}*/
857 /* This entry is for the disassembler only.  It will never be used by
858    assembler.  */
859 { "comib", 	0x8c000000, 0xfc000000, "?nn5,b,w", pa10, 0}, /* comib{tf}*/
860 { "cmpb",	0x9c000000, 0xdc000000, "?Nnx,b,w", pa20, FLAG_STRICT},
861 { "cmpb",	0x80000000, 0xf4000000, "?nnx,b,w", pa10, FLAG_STRICT},
862 { "comb",	0x80000000, 0xfc000000, "?nnx,b,w", pa10, 0}, /* comb{tf} */
863 /* This entry is for the disassembler only.  It will never be used by
864    assembler.  */
865 { "comb",	0x88000000, 0xfc000000, "?nnx,b,w", pa10, 0}, /* comb{tf} */
866 { "addb",	0xa0000000, 0xf4000000, "?Wnx,b,w", pa20w, FLAG_STRICT},
867 { "addb",	0xa0000000, 0xfc000000, "?@nx,b,w", pa10, 0}, /* addb{tf} */
868 /* This entry is for the disassembler only.  It will never be used by
869    assembler.  */
870 { "addb",	0xa8000000, 0xfc000000, "?@nx,b,w", pa10, 0},
871 { "addib",	0xa4000000, 0xf4000000, "?Wn5,b,w", pa20w, FLAG_STRICT},
872 { "addib",	0xa4000000, 0xfc000000, "?@n5,b,w", pa10, 0}, /* addib{tf}*/
873 /* This entry is for the disassembler only.  It will never be used by
874    assembler.  */
875 { "addib",	0xac000000, 0xfc000000, "?@n5,b,w", pa10, 0}, /* addib{tf}*/
876 { "nop",	0x08000240, 0xffffffff, "", pa10, 0},      /* or 0,0,0 */
877 { "copy",	0x08000240, 0xffe0ffe0, "x,t", pa10, 0},   /* or r,0,t */
878 { "mtsar",	0x01601840, 0xffe0ffff, "x", pa10, 0}, /* mtctl r,cr11 */
879 
880 /* Loads and Stores for integer registers.  */
881 
882 { "ldd",	0x0c0000c0, 0xfc00d3c0, "cxccx(b),t", pa20, FLAG_STRICT},
883 { "ldd",	0x0c0000c0, 0xfc0013c0, "cxccx(s,b),t", pa20, FLAG_STRICT},
884 { "ldd",	0x0c0010e0, 0xfc1ff3e0, "cocc@(b),t", pa20, FLAG_STRICT},
885 { "ldd",	0x0c0010e0, 0xfc1f33e0, "cocc@(s,b),t", pa20, FLAG_STRICT},
886 { "ldd",	0x0c0010c0, 0xfc00d3c0, "cmcc5(b),t", pa20, FLAG_STRICT},
887 { "ldd",	0x0c0010c0, 0xfc0013c0, "cmcc5(s,b),t", pa20, FLAG_STRICT},
888 { "ldd",	0x50000000, 0xfc000002, "cq&(b),x", pa20w, FLAG_STRICT},
889 { "ldd",	0x50000000, 0xfc00c002, "cq#(b),x", pa20, FLAG_STRICT},
890 { "ldd",	0x50000000, 0xfc000002, "cq#(s,b),x", pa20, FLAG_STRICT},
891 { "ldw",	0x0c000080, 0xfc00dfc0, "cXx(b),t", pa10, FLAG_STRICT},
892 { "ldw",	0x0c000080, 0xfc001fc0, "cXx(s,b),t", pa10, FLAG_STRICT},
893 { "ldw",	0x0c000080, 0xfc00d3c0, "cxccx(b),t", pa11, FLAG_STRICT},
894 { "ldw",	0x0c000080, 0xfc0013c0, "cxccx(s,b),t", pa11, FLAG_STRICT},
895 { "ldw",	0x0c0010a0, 0xfc1ff3e0, "cocc@(b),t", pa20, FLAG_STRICT},
896 { "ldw",	0x0c0010a0, 0xfc1f33e0, "cocc@(s,b),t", pa20, FLAG_STRICT},
897 { "ldw",	0x0c001080, 0xfc00dfc0, "cM5(b),t", pa10, FLAG_STRICT},
898 { "ldw",	0x0c001080, 0xfc001fc0, "cM5(s,b),t", pa10, FLAG_STRICT},
899 { "ldw",	0x0c001080, 0xfc00d3c0, "cmcc5(b),t", pa11, FLAG_STRICT},
900 { "ldw",	0x0c001080, 0xfc0013c0, "cmcc5(s,b),t", pa11, FLAG_STRICT},
901 { "ldw",	0x4c000000, 0xfc000000, "ce<(b),x", pa20w, FLAG_STRICT},
902 { "ldw",	0x5c000004, 0xfc000006, "ce>(b),x", pa20w, FLAG_STRICT},
903 { "ldw",	0x48000000, 0xfc000000, "l(b),x", pa20w, FLAG_STRICT},
904 { "ldw",	0x5c000004, 0xfc00c006, "ceK(b),x", pa20, FLAG_STRICT},
905 { "ldw",	0x5c000004, 0xfc000006, "ceK(s,b),x", pa20, FLAG_STRICT},
906 { "ldw",	0x4c000000, 0xfc00c000, "ceJ(b),x", pa10, FLAG_STRICT},
907 { "ldw",	0x4c000000, 0xfc000000, "ceJ(s,b),x", pa10, FLAG_STRICT},
908 { "ldw",	0x48000000, 0xfc00c000, "j(b),x", pa10, 0},
909 { "ldw",	0x48000000, 0xfc000000, "j(s,b),x", pa10, 0},
910 { "ldh",	0x0c000040, 0xfc00dfc0, "cXx(b),t", pa10, FLAG_STRICT},
911 { "ldh",	0x0c000040, 0xfc001fc0, "cXx(s,b),t", pa10, FLAG_STRICT},
912 { "ldh",	0x0c000040, 0xfc00d3c0, "cxccx(b),t", pa11, FLAG_STRICT},
913 { "ldh",	0x0c000040, 0xfc0013c0, "cxccx(s,b),t", pa11, FLAG_STRICT},
914 { "ldh",	0x0c001060, 0xfc1ff3e0, "cocc@(b),t", pa20, FLAG_STRICT},
915 { "ldh",	0x0c001060, 0xfc1f33e0, "cocc@(s,b),t", pa20, FLAG_STRICT},
916 { "ldh",	0x0c001040, 0xfc00dfc0, "cM5(b),t", pa10, FLAG_STRICT},
917 { "ldh",	0x0c001040, 0xfc001fc0, "cM5(s,b),t", pa10, FLAG_STRICT},
918 { "ldh",	0x0c001040, 0xfc00d3c0, "cmcc5(b),t", pa11, FLAG_STRICT},
919 { "ldh",	0x0c001040, 0xfc0013c0, "cmcc5(s,b),t", pa11, FLAG_STRICT},
920 { "ldh",	0x44000000, 0xfc000000, "l(b),x", pa20w, FLAG_STRICT},
921 { "ldh",	0x44000000, 0xfc00c000, "j(b),x", pa10, 0},
922 { "ldh",	0x44000000, 0xfc000000, "j(s,b),x", pa10, 0},
923 { "ldb",	0x0c000000, 0xfc00dfc0, "cXx(b),t", pa10, FLAG_STRICT},
924 { "ldb",	0x0c000000, 0xfc001fc0, "cXx(s,b),t", pa10, FLAG_STRICT},
925 { "ldb",	0x0c000000, 0xfc00d3c0, "cxccx(b),t", pa11, FLAG_STRICT},
926 { "ldb",	0x0c000000, 0xfc0013c0, "cxccx(s,b),t", pa11, FLAG_STRICT},
927 { "ldb",	0x0c001020, 0xfc1ff3e0, "cocc@(b),t", pa20, FLAG_STRICT},
928 { "ldb",	0x0c001020, 0xfc1f33e0, "cocc@(s,b),t", pa20, FLAG_STRICT},
929 { "ldb",	0x0c001000, 0xfc00dfc0, "cM5(b),t", pa10, FLAG_STRICT},
930 { "ldb",	0x0c001000, 0xfc001fc0, "cM5(s,b),t", pa10, FLAG_STRICT},
931 { "ldb",	0x0c001000, 0xfc00d3c0, "cmcc5(b),t", pa11, FLAG_STRICT},
932 { "ldb",	0x0c001000, 0xfc0013c0, "cmcc5(s,b),t", pa11, FLAG_STRICT},
933 { "ldb",	0x40000000, 0xfc000000, "l(b),x", pa20w, FLAG_STRICT},
934 { "ldb",	0x40000000, 0xfc00c000, "j(b),x", pa10, 0},
935 { "ldb",	0x40000000, 0xfc000000, "j(s,b),x", pa10, 0},
936 { "std",	0x0c0012e0, 0xfc00f3ff, "cocCx,@(b)", pa20, FLAG_STRICT},
937 { "std",	0x0c0012e0, 0xfc0033ff, "cocCx,@(s,b)", pa20, FLAG_STRICT},
938 { "std",	0x0c0012c0, 0xfc00d3c0, "cmcCx,V(b)", pa20, FLAG_STRICT},
939 { "std",	0x0c0012c0, 0xfc0013c0, "cmcCx,V(s,b)", pa20, FLAG_STRICT},
940 { "std",	0x70000000, 0xfc000002, "cqx,&(b)", pa20w, FLAG_STRICT},
941 { "std",	0x70000000, 0xfc00c002, "cqx,#(b)", pa20, FLAG_STRICT},
942 { "std",	0x70000000, 0xfc000002, "cqx,#(s,b)", pa20, FLAG_STRICT},
943 { "stw",	0x0c0012a0, 0xfc00f3ff, "cocCx,@(b)", pa20, FLAG_STRICT},
944 { "stw",	0x0c0012a0, 0xfc0033ff, "cocCx,@(s,b)", pa20, FLAG_STRICT},
945 { "stw",	0x0c001280, 0xfc00dfc0, "cMx,V(b)", pa10, FLAG_STRICT},
946 { "stw",	0x0c001280, 0xfc001fc0, "cMx,V(s,b)", pa10, FLAG_STRICT},
947 { "stw",	0x0c001280, 0xfc00d3c0, "cmcCx,V(b)", pa11, FLAG_STRICT},
948 { "stw",	0x0c001280, 0xfc0013c0, "cmcCx,V(s,b)", pa11, FLAG_STRICT},
949 { "stw",	0x6c000000, 0xfc000000, "cex,<(b)", pa20w, FLAG_STRICT},
950 { "stw",	0x7c000004, 0xfc000006, "cex,>(b)", pa20w, FLAG_STRICT},
951 { "stw",	0x68000000, 0xfc000000, "x,l(b)", pa20w, FLAG_STRICT},
952 { "stw",	0x7c000004, 0xfc00c006, "cex,K(b)", pa20, FLAG_STRICT},
953 { "stw",	0x7c000004, 0xfc000006, "cex,K(s,b)", pa20, FLAG_STRICT},
954 { "stw",	0x6c000000, 0xfc00c000, "cex,J(b)", pa10, FLAG_STRICT},
955 { "stw",	0x6c000000, 0xfc000000, "cex,J(s,b)", pa10, FLAG_STRICT},
956 { "stw",	0x68000000, 0xfc00c000, "x,j(b)", pa10, 0},
957 { "stw",	0x68000000, 0xfc000000, "x,j(s,b)", pa10, 0},
958 { "sth",	0x0c001260, 0xfc00f3ff, "cocCx,@(b)", pa20, FLAG_STRICT},
959 { "sth",	0x0c001260, 0xfc0033ff, "cocCx,@(s,b)", pa20, FLAG_STRICT},
960 { "sth",	0x0c001240, 0xfc00dfc0, "cMx,V(b)", pa10, FLAG_STRICT},
961 { "sth",	0x0c001240, 0xfc001fc0, "cMx,V(s,b)", pa10, FLAG_STRICT},
962 { "sth",	0x0c001240, 0xfc00d3c0, "cmcCx,V(b)", pa11, FLAG_STRICT},
963 { "sth",	0x0c001240, 0xfc0013c0, "cmcCx,V(s,b)", pa11, FLAG_STRICT},
964 { "sth",	0x64000000, 0xfc000000, "x,l(b)", pa20w, FLAG_STRICT},
965 { "sth",	0x64000000, 0xfc00c000, "x,j(b)", pa10, 0},
966 { "sth",	0x64000000, 0xfc000000, "x,j(s,b)", pa10, 0},
967 { "stb",	0x0c001220, 0xfc00f3ff, "cocCx,@(b)", pa20, FLAG_STRICT},
968 { "stb",	0x0c001220, 0xfc0033ff, "cocCx,@(s,b)", pa20, FLAG_STRICT},
969 { "stb",	0x0c001200, 0xfc00dfc0, "cMx,V(b)", pa10, FLAG_STRICT},
970 { "stb",	0x0c001200, 0xfc001fc0, "cMx,V(s,b)", pa10, FLAG_STRICT},
971 { "stb",	0x0c001200, 0xfc00d3c0, "cmcCx,V(b)", pa11, FLAG_STRICT},
972 { "stb",	0x0c001200, 0xfc0013c0, "cmcCx,V(s,b)", pa11, FLAG_STRICT},
973 { "stb",	0x60000000, 0xfc000000, "x,l(b)", pa20w, FLAG_STRICT},
974 { "stb",	0x60000000, 0xfc00c000, "x,j(b)", pa10, 0},
975 { "stb",	0x60000000, 0xfc000000, "x,j(s,b)", pa10, 0},
976 { "ldwm",	0x4c000000, 0xfc00c000, "j(b),x", pa10, 0},
977 { "ldwm",	0x4c000000, 0xfc000000, "j(s,b),x", pa10, 0},
978 { "stwm",	0x6c000000, 0xfc00c000, "x,j(b)", pa10, 0},
979 { "stwm",	0x6c000000, 0xfc000000, "x,j(s,b)", pa10, 0},
980 { "ldwx",	0x0c000080, 0xfc00dfc0, "cXx(b),t", pa10, FLAG_STRICT},
981 { "ldwx",	0x0c000080, 0xfc001fc0, "cXx(s,b),t", pa10, FLAG_STRICT},
982 { "ldwx",	0x0c000080, 0xfc00d3c0, "cxccx(b),t", pa11, FLAG_STRICT},
983 { "ldwx",	0x0c000080, 0xfc0013c0, "cxccx(s,b),t", pa11, FLAG_STRICT},
984 { "ldwx",	0x0c000080, 0xfc00dfc0, "cXx(b),t", pa10, 0},
985 { "ldwx",	0x0c000080, 0xfc001fc0, "cXx(s,b),t", pa10, 0},
986 { "ldhx",	0x0c000040, 0xfc00dfc0, "cXx(b),t", pa10, FLAG_STRICT},
987 { "ldhx",	0x0c000040, 0xfc001fc0, "cXx(s,b),t", pa10, FLAG_STRICT},
988 { "ldhx",	0x0c000040, 0xfc00d3c0, "cxccx(b),t", pa11, FLAG_STRICT},
989 { "ldhx",	0x0c000040, 0xfc0013c0, "cxccx(s,b),t", pa11, FLAG_STRICT},
990 { "ldhx",	0x0c000040, 0xfc00dfc0, "cXx(b),t", pa10, 0},
991 { "ldhx",	0x0c000040, 0xfc001fc0, "cXx(s,b),t", pa10, 0},
992 { "ldbx",	0x0c000000, 0xfc00dfc0, "cXx(b),t", pa10, FLAG_STRICT},
993 { "ldbx",	0x0c000000, 0xfc001fc0, "cXx(s,b),t", pa10, FLAG_STRICT},
994 { "ldbx",	0x0c000000, 0xfc00d3c0, "cxccx(b),t", pa11, FLAG_STRICT},
995 { "ldbx",	0x0c000000, 0xfc0013c0, "cxccx(s,b),t", pa11, FLAG_STRICT},
996 { "ldbx",	0x0c000000, 0xfc00dfc0, "cXx(b),t", pa10, 0},
997 { "ldbx",	0x0c000000, 0xfc001fc0, "cXx(s,b),t", pa10, 0},
998 { "ldwa",	0x0c000180, 0xfc00dfc0, "cXx(b),t", pa10, FLAG_STRICT},
999 { "ldwa",	0x0c000180, 0xfc00d3c0, "cxccx(b),t", pa11, FLAG_STRICT},
1000 { "ldwa",	0x0c0011a0, 0xfc1ff3e0, "cocc@(b),t", pa20, FLAG_STRICT},
1001 { "ldwa",	0x0c001180, 0xfc00dfc0, "cM5(b),t", pa10, FLAG_STRICT},
1002 { "ldwa",	0x0c001180, 0xfc00d3c0, "cmcc5(b),t", pa11, FLAG_STRICT},
1003 { "ldcw",	0x0c0001c0, 0xfc00dfc0, "cXx(b),t", pa10, FLAG_STRICT},
1004 { "ldcw",	0x0c0001c0, 0xfc001fc0, "cXx(s,b),t", pa10, FLAG_STRICT},
1005 { "ldcw",	0x0c0001c0, 0xfc00d3c0, "cxcdx(b),t", pa11, FLAG_STRICT},
1006 { "ldcw",	0x0c0001c0, 0xfc0013c0, "cxcdx(s,b),t", pa11, FLAG_STRICT},
1007 { "ldcw",	0x0c0011c0, 0xfc00dfc0, "cM5(b),t", pa10, FLAG_STRICT},
1008 { "ldcw",	0x0c0011c0, 0xfc001fc0, "cM5(s,b),t", pa10, FLAG_STRICT},
1009 { "ldcw",	0x0c0011c0, 0xfc00d3c0, "cmcd5(b),t", pa11, FLAG_STRICT},
1010 { "ldcw",	0x0c0011c0, 0xfc0013c0, "cmcd5(s,b),t", pa11, FLAG_STRICT},
1011 { "stwa",	0x0c0013a0, 0xfc00d3ff, "cocCx,@(b)", pa20, FLAG_STRICT},
1012 { "stwa",	0x0c001380, 0xfc00dfc0, "cMx,V(b)", pa10, FLAG_STRICT},
1013 { "stwa",	0x0c001380, 0xfc00d3c0, "cmcCx,V(b)", pa11, FLAG_STRICT},
1014 { "stby",	0x0c001300, 0xfc00dfc0, "cAx,V(b)", pa10, FLAG_STRICT},
1015 { "stby",	0x0c001300, 0xfc001fc0, "cAx,V(s,b)", pa10, FLAG_STRICT},
1016 { "stby",	0x0c001300, 0xfc00d3c0, "cscCx,V(b)", pa11, FLAG_STRICT},
1017 { "stby",	0x0c001300, 0xfc0013c0, "cscCx,V(s,b)", pa11, FLAG_STRICT},
1018 { "ldda",	0x0c000100, 0xfc00d3c0, "cxccx(b),t", pa20, FLAG_STRICT},
1019 { "ldda",	0x0c001120, 0xfc1ff3e0, "cocc@(b),t", pa20, FLAG_STRICT},
1020 { "ldda",	0x0c001100, 0xfc00d3c0, "cmcc5(b),t", pa20, FLAG_STRICT},
1021 { "ldcd",	0x0c000140, 0xfc00d3c0, "cxcdx(b),t", pa20, FLAG_STRICT},
1022 { "ldcd",	0x0c000140, 0xfc0013c0, "cxcdx(s,b),t", pa20, FLAG_STRICT},
1023 { "ldcd",	0x0c001140, 0xfc00d3c0, "cmcd5(b),t", pa20, FLAG_STRICT},
1024 { "ldcd",	0x0c001140, 0xfc0013c0, "cmcd5(s,b),t", pa20, FLAG_STRICT},
1025 { "stda",	0x0c0013e0, 0xfc00f3ff, "cocCx,@(b)", pa20, FLAG_STRICT},
1026 { "stda",	0x0c0013c0, 0xfc00d3c0, "cmcCx,V(b)", pa20, FLAG_STRICT},
1027 { "ldwax",	0x0c000180, 0xfc00dfc0, "cXx(b),t", pa10, FLAG_STRICT},
1028 { "ldwax",	0x0c000180, 0xfc00d3c0, "cxccx(b),t", pa11, FLAG_STRICT},
1029 { "ldwax",	0x0c000180, 0xfc00dfc0, "cXx(b),t", pa10, 0},
1030 { "ldcwx",	0x0c0001c0, 0xfc00dfc0, "cXx(b),t", pa10, FLAG_STRICT},
1031 { "ldcwx",	0x0c0001c0, 0xfc001fc0, "cXx(s,b),t", pa10, FLAG_STRICT},
1032 { "ldcwx",	0x0c0001c0, 0xfc00d3c0, "cxcdx(b),t", pa11, FLAG_STRICT},
1033 { "ldcwx",	0x0c0001c0, 0xfc0013c0, "cxcdx(s,b),t", pa11, FLAG_STRICT},
1034 { "ldcwx",	0x0c0001c0, 0xfc00dfc0, "cXx(b),t", pa10, 0},
1035 { "ldcwx",	0x0c0001c0, 0xfc001fc0, "cXx(s,b),t", pa10, 0},
1036 { "ldws",	0x0c001080, 0xfc00dfc0, "cM5(b),t", pa10, FLAG_STRICT},
1037 { "ldws",	0x0c001080, 0xfc001fc0, "cM5(s,b),t", pa10, FLAG_STRICT},
1038 { "ldws",	0x0c001080, 0xfc00d3c0, "cmcc5(b),t", pa11, FLAG_STRICT},
1039 { "ldws",	0x0c001080, 0xfc0013c0, "cmcc5(s,b),t", pa11, FLAG_STRICT},
1040 { "ldws",	0x0c001080, 0xfc00dfc0, "cM5(b),t", pa10, 0},
1041 { "ldws",	0x0c001080, 0xfc001fc0, "cM5(s,b),t", pa10, 0},
1042 { "ldhs",	0x0c001040, 0xfc00dfc0, "cM5(b),t", pa10, FLAG_STRICT},
1043 { "ldhs",	0x0c001040, 0xfc001fc0, "cM5(s,b),t", pa10, FLAG_STRICT},
1044 { "ldhs",	0x0c001040, 0xfc00d3c0, "cmcc5(b),t", pa11, FLAG_STRICT},
1045 { "ldhs",	0x0c001040, 0xfc0013c0, "cmcc5(s,b),t", pa11, FLAG_STRICT},
1046 { "ldhs",	0x0c001040, 0xfc00dfc0, "cM5(b),t", pa10, 0},
1047 { "ldhs",	0x0c001040, 0xfc001fc0, "cM5(s,b),t", pa10, 0},
1048 { "ldbs",	0x0c001000, 0xfc00dfc0, "cM5(b),t", pa10, FLAG_STRICT},
1049 { "ldbs",	0x0c001000, 0xfc001fc0, "cM5(s,b),t", pa10, FLAG_STRICT},
1050 { "ldbs",	0x0c001000, 0xfc00d3c0, "cmcc5(b),t", pa11, FLAG_STRICT},
1051 { "ldbs",	0x0c001000, 0xfc0013c0, "cmcc5(s,b),t", pa11, FLAG_STRICT},
1052 { "ldbs",	0x0c001000, 0xfc00dfc0, "cM5(b),t", pa10, 0},
1053 { "ldbs",	0x0c001000, 0xfc001fc0, "cM5(s,b),t", pa10, 0},
1054 { "ldwas",	0x0c001180, 0xfc00dfc0, "cM5(b),t", pa10, FLAG_STRICT},
1055 { "ldwas",	0x0c001180, 0xfc00d3c0, "cmcc5(b),t", pa11, FLAG_STRICT},
1056 { "ldwas",	0x0c001180, 0xfc00dfc0, "cM5(b),t", pa10, 0},
1057 { "ldcws",	0x0c0011c0, 0xfc00dfc0, "cM5(b),t", pa10, FLAG_STRICT},
1058 { "ldcws",	0x0c0011c0, 0xfc001fc0, "cM5(s,b),t", pa10, FLAG_STRICT},
1059 { "ldcws",	0x0c0011c0, 0xfc00d3c0, "cmcd5(b),t", pa11, FLAG_STRICT},
1060 { "ldcws",	0x0c0011c0, 0xfc0013c0, "cmcd5(s,b),t", pa11, FLAG_STRICT},
1061 { "ldcws",	0x0c0011c0, 0xfc00dfc0, "cM5(b),t", pa10, 0},
1062 { "ldcws",	0x0c0011c0, 0xfc001fc0, "cM5(s,b),t", pa10, 0},
1063 { "stws",	0x0c001280, 0xfc00dfc0, "cMx,V(b)", pa10, FLAG_STRICT},
1064 { "stws",	0x0c001280, 0xfc001fc0, "cMx,V(s,b)", pa10, FLAG_STRICT},
1065 { "stws",	0x0c001280, 0xfc00d3c0, "cmcCx,V(b)", pa11, FLAG_STRICT},
1066 { "stws",	0x0c001280, 0xfc0013c0, "cmcCx,V(s,b)", pa11, FLAG_STRICT},
1067 { "stws",	0x0c001280, 0xfc00dfc0, "cMx,V(b)", pa10, 0},
1068 { "stws",	0x0c001280, 0xfc001fc0, "cMx,V(s,b)", pa10, 0},
1069 { "sths",	0x0c001240, 0xfc00dfc0, "cMx,V(b)", pa10, FLAG_STRICT},
1070 { "sths",	0x0c001240, 0xfc001fc0, "cMx,V(s,b)", pa10, FLAG_STRICT},
1071 { "sths",	0x0c001240, 0xfc00d3c0, "cmcCx,V(b)", pa11, FLAG_STRICT},
1072 { "sths",	0x0c001240, 0xfc0013c0, "cmcCx,V(s,b)", pa11, FLAG_STRICT},
1073 { "sths",	0x0c001240, 0xfc00dfc0, "cMx,V(b)", pa10, 0},
1074 { "sths",	0x0c001240, 0xfc001fc0, "cMx,V(s,b)", pa10, 0},
1075 { "stbs",	0x0c001200, 0xfc00dfc0, "cMx,V(b)", pa10, FLAG_STRICT},
1076 { "stbs",	0x0c001200, 0xfc001fc0, "cMx,V(s,b)", pa10, FLAG_STRICT},
1077 { "stbs",	0x0c001200, 0xfc00d3c0, "cmcCx,V(b)", pa11, FLAG_STRICT},
1078 { "stbs",	0x0c001200, 0xfc0013c0, "cmcCx,V(s,b)", pa11, FLAG_STRICT},
1079 { "stbs",	0x0c001200, 0xfc00dfc0, "cMx,V(b)", pa10, 0},
1080 { "stbs",	0x0c001200, 0xfc001fc0, "cMx,V(s,b)", pa10, 0},
1081 { "stwas",	0x0c001380, 0xfc00dfc0, "cMx,V(b)", pa10, FLAG_STRICT},
1082 { "stwas",	0x0c001380, 0xfc00d3c0, "cmcCx,V(b)", pa11, FLAG_STRICT},
1083 { "stwas",	0x0c001380, 0xfc00dfc0, "cMx,V(b)", pa10, 0},
1084 { "stdby",	0x0c001340, 0xfc00d3c0, "cscCx,V(b)", pa20, FLAG_STRICT},
1085 { "stdby",	0x0c001340, 0xfc0013c0, "cscCx,V(s,b)", pa20, FLAG_STRICT},
1086 { "stbys",	0x0c001300, 0xfc00dfc0, "cAx,V(b)", pa10, FLAG_STRICT},
1087 { "stbys",	0x0c001300, 0xfc001fc0, "cAx,V(s,b)", pa10, FLAG_STRICT},
1088 { "stbys",	0x0c001300, 0xfc00d3c0, "cscCx,V(b)", pa11, FLAG_STRICT},
1089 { "stbys",	0x0c001300, 0xfc0013c0, "cscCx,V(s,b)", pa11, FLAG_STRICT},
1090 { "stbys",	0x0c001300, 0xfc00dfc0, "cAx,V(b)", pa10, 0},
1091 { "stbys",	0x0c001300, 0xfc001fc0, "cAx,V(s,b)", pa10, 0},
1092 
1093 /* Immediate instructions.  */
1094 { "ldo",	0x34000000, 0xfc000000, "l(b),x", pa20w, 0},
1095 { "ldo",	0x34000000, 0xfc00c000, "j(b),x", pa10, 0},
1096 { "ldil",	0x20000000, 0xfc000000, "k,b", pa10, 0},
1097 { "addil",	0x28000000, 0xfc000000, "k,b,Z", pa10, 0},
1098 { "addil",	0x28000000, 0xfc000000, "k,b", pa10, 0},
1099 
1100 /* Branching instructions.  */
1101 { "b",		0xe8008000, 0xfc00e000, "cpnXL", pa20, FLAG_STRICT},
1102 { "b",		0xe800a000, 0xfc00e000, "clnXL", pa20, FLAG_STRICT},
1103 { "b",		0xe8000000, 0xfc00e000, "clnW,b", pa10, FLAG_STRICT},
1104 { "b",		0xe8002000, 0xfc00e000, "cgnW,b", pa10, FLAG_STRICT},
1105 { "b",		0xe8000000, 0xffe0e000, "nW", pa10, 0},  /* b,l foo,r0 */
1106 { "bl",		0xe8000000, 0xfc00e000, "nW,b", pa10, 0},
1107 { "gate",	0xe8002000, 0xfc00e000, "nW,b", pa10, 0},
1108 { "blr",	0xe8004000, 0xfc00e001, "nx,b", pa10, 0},
1109 { "bv",		0xe800c000, 0xfc00fffd, "nx(b)", pa10, 0},
1110 { "bv",		0xe800c000, 0xfc00fffd, "n(b)", pa10, 0},
1111 { "bve",	0xe800f001, 0xfc1ffffd, "cpn(b)L", pa20, FLAG_STRICT},
1112 { "bve",	0xe800f000, 0xfc1ffffd, "cln(b)L", pa20, FLAG_STRICT},
1113 { "bve",	0xe800d001, 0xfc1ffffd, "cPn(b)", pa20, FLAG_STRICT},
1114 { "bve",	0xe800d000, 0xfc1ffffd, "n(b)", pa20, FLAG_STRICT},
1115 { "be",		0xe4000000, 0xfc000000, "clnz(S,b),Y", pa10, FLAG_STRICT},
1116 { "be",		0xe4000000, 0xfc000000, "clnz(b),Y", pa10, FLAG_STRICT},
1117 { "be",		0xe0000000, 0xfc000000, "nz(S,b)", pa10, 0},
1118 { "be",		0xe0000000, 0xfc000000, "nz(b)", pa10, 0},
1119 { "ble",	0xe4000000, 0xfc000000, "nz(S,b)", pa10, 0},
1120 { "movb",	0xc8000000, 0xfc000000, "?ynx,b,w", pa10, 0},
1121 { "movib",	0xcc000000, 0xfc000000, "?yn5,b,w", pa10, 0},
1122 { "combt",	0x80000000, 0xfc000000, "?tnx,b,w", pa10, 0},
1123 { "combf",	0x88000000, 0xfc000000, "?tnx,b,w", pa10, 0},
1124 { "comibt",	0x84000000, 0xfc000000, "?tn5,b,w", pa10, 0},
1125 { "comibf",	0x8c000000, 0xfc000000, "?tn5,b,w", pa10, 0},
1126 { "addbt",	0xa0000000, 0xfc000000, "?dnx,b,w", pa10, 0},
1127 { "addbf",	0xa8000000, 0xfc000000, "?dnx,b,w", pa10, 0},
1128 { "addibt",	0xa4000000, 0xfc000000, "?dn5,b,w", pa10, 0},
1129 { "addibf",	0xac000000, 0xfc000000, "?dn5,b,w", pa10, 0},
1130 { "bb",		0xc0004000, 0xffe06000, "?bnx,!,w", pa10, FLAG_STRICT},
1131 { "bb",		0xc0006000, 0xffe06000, "?Bnx,!,w", pa20, FLAG_STRICT},
1132 { "bb",		0xc4004000, 0xfc006000, "?bnx,Q,w", pa10, FLAG_STRICT},
1133 { "bb",		0xc4004000, 0xfc004000, "?Bnx,B,w", pa20, FLAG_STRICT},
1134 { "bvb",	0xc0004000, 0xffe04000, "?bnx,w", pa10, 0},
1135 { "clrbts",	0xe8004005, 0xffffffff, "", pa20, FLAG_STRICT},
1136 { "popbts",	0xe8004005, 0xfffff007, "$", pa20, FLAG_STRICT},
1137 { "pushnom",	0xe8004001, 0xffffffff, "", pa20, FLAG_STRICT},
1138 { "pushbts",	0xe8004001, 0xffe0ffff, "x", pa20, FLAG_STRICT},
1139 
1140 /* Computation Instructions.  */
1141 
1142 { "cmpclr",	0x080008a0, 0xfc000fe0, "?Sx,b,t", pa20, FLAG_STRICT},
1143 { "cmpclr",	0x08000880, 0xfc000fe0, "?sx,b,t", pa10, FLAG_STRICT},
1144 { "comclr",	0x08000880, 0xfc000fe0, "?sx,b,t", pa10, 0},
1145 { "or",		0x08000260, 0xfc000fe0, "?Lx,b,t", pa20, FLAG_STRICT},
1146 { "or",		0x08000240, 0xfc000fe0, "?lx,b,t", pa10, 0},
1147 { "xor",	0x080002a0, 0xfc000fe0, "?Lx,b,t", pa20, FLAG_STRICT},
1148 { "xor",	0x08000280, 0xfc000fe0, "?lx,b,t", pa10, 0},
1149 { "and",	0x08000220, 0xfc000fe0, "?Lx,b,t", pa20, FLAG_STRICT},
1150 { "and",	0x08000200, 0xfc000fe0, "?lx,b,t", pa10, 0},
1151 { "andcm",	0x08000020, 0xfc000fe0, "?Lx,b,t", pa20, FLAG_STRICT},
1152 { "andcm",	0x08000000, 0xfc000fe0, "?lx,b,t", pa10, 0},
1153 { "uxor",	0x080003a0, 0xfc000fe0, "?Ux,b,t", pa20, FLAG_STRICT},
1154 { "uxor",	0x08000380, 0xfc000fe0, "?ux,b,t", pa10, 0},
1155 { "uaddcm",	0x080009a0, 0xfc000fa0, "cT?Ux,b,t", pa20, FLAG_STRICT},
1156 { "uaddcm",	0x08000980, 0xfc000fa0, "cT?ux,b,t", pa10, FLAG_STRICT},
1157 { "uaddcm",	0x08000980, 0xfc000fe0, "?ux,b,t", pa10, 0},
1158 { "uaddcmt",	0x080009c0, 0xfc000fe0, "?ux,b,t", pa10, 0},
1159 { "dcor",	0x08000ba0, 0xfc1f0fa0, "ci?Ub,t", pa20, FLAG_STRICT},
1160 { "dcor",	0x08000b80, 0xfc1f0fa0, "ci?ub,t", pa10, FLAG_STRICT},
1161 { "dcor",	0x08000b80, 0xfc1f0fe0, "?ub,t",   pa10, 0},
1162 { "idcor",	0x08000bc0, 0xfc1f0fe0, "?ub,t",   pa10, 0},
1163 { "addi",	0xb0000000, 0xfc000000, "ct?ai,b,x", pa10, FLAG_STRICT},
1164 { "addi",	0xb4000000, 0xfc000000, "cv?ai,b,x", pa10, FLAG_STRICT},
1165 { "addi",	0xb4000000, 0xfc000800, "?ai,b,x", pa10, 0},
1166 { "addio",	0xb4000800, 0xfc000800, "?ai,b,x", pa10, 0},
1167 { "addit",	0xb0000000, 0xfc000800, "?ai,b,x", pa10, 0},
1168 { "addito",	0xb0000800, 0xfc000800, "?ai,b,x", pa10, 0},
1169 { "add",	0x08000720, 0xfc0007e0, "cY?Ax,b,t", pa20, FLAG_STRICT},
1170 { "add",	0x08000700, 0xfc0007e0, "cy?ax,b,t", pa10, FLAG_STRICT},
1171 { "add",	0x08000220, 0xfc0003e0, "ca?Ax,b,t", pa20, FLAG_STRICT},
1172 { "add",	0x08000200, 0xfc0003e0, "ca?ax,b,t", pa10, FLAG_STRICT},
1173 { "add",	0x08000600, 0xfc000fe0, "?ax,b,t", pa10, 0},
1174 { "addl",	0x08000a00, 0xfc000fe0, "?ax,b,t", pa10, 0},
1175 { "addo",	0x08000e00, 0xfc000fe0, "?ax,b,t", pa10, 0},
1176 { "addc",	0x08000700, 0xfc000fe0, "?ax,b,t", pa10, 0},
1177 { "addco",	0x08000f00, 0xfc000fe0, "?ax,b,t", pa10, 0},
1178 { "sub",	0x080004e0, 0xfc0007e0, "ct?Sx,b,t", pa20, FLAG_STRICT},
1179 { "sub",	0x080004c0, 0xfc0007e0, "ct?sx,b,t", pa10, FLAG_STRICT},
1180 { "sub",	0x08000520, 0xfc0007e0, "cB?Sx,b,t", pa20, FLAG_STRICT},
1181 { "sub",	0x08000500, 0xfc0007e0, "cb?sx,b,t", pa10, FLAG_STRICT},
1182 { "sub",	0x08000420, 0xfc0007e0, "cv?Sx,b,t", pa20, FLAG_STRICT},
1183 { "sub",	0x08000400, 0xfc0007e0, "cv?sx,b,t", pa10, FLAG_STRICT},
1184 { "sub",	0x08000400, 0xfc000fe0, "?sx,b,t", pa10, 0},
1185 { "subo",	0x08000c00, 0xfc000fe0, "?sx,b,t", pa10, 0},
1186 { "subb",	0x08000500, 0xfc000fe0, "?sx,b,t", pa10, 0},
1187 { "subbo",	0x08000d00, 0xfc000fe0, "?sx,b,t", pa10, 0},
1188 { "subt",	0x080004c0, 0xfc000fe0, "?sx,b,t", pa10, 0},
1189 { "subto",	0x08000cc0, 0xfc000fe0, "?sx,b,t", pa10, 0},
1190 { "ds",		0x08000440, 0xfc000fe0, "?sx,b,t", pa10, 0},
1191 { "subi",	0x94000000, 0xfc000000, "cv?si,b,x", pa10, FLAG_STRICT},
1192 { "subi",	0x94000000, 0xfc000800, "?si,b,x", pa10, 0},
1193 { "subio",	0x94000800, 0xfc000800, "?si,b,x", pa10, 0},
1194 { "cmpiclr",	0x90000800, 0xfc000800, "?Si,b,x", pa20, FLAG_STRICT},
1195 { "cmpiclr",	0x90000000, 0xfc000800, "?si,b,x", pa10, FLAG_STRICT},
1196 { "comiclr",	0x90000000, 0xfc000800, "?si,b,x", pa10, 0},
1197 { "shladd",	0x08000220, 0xfc000320, "ca?Ax,.,b,t", pa20, FLAG_STRICT},
1198 { "shladd",	0x08000200, 0xfc000320, "ca?ax,.,b,t", pa10, FLAG_STRICT},
1199 { "sh1add",	0x08000640, 0xfc000fe0, "?ax,b,t", pa10, 0},
1200 { "sh1addl",	0x08000a40, 0xfc000fe0, "?ax,b,t", pa10, 0},
1201 { "sh1addo",	0x08000e40, 0xfc000fe0, "?ax,b,t", pa10, 0},
1202 { "sh2add",	0x08000680, 0xfc000fe0, "?ax,b,t", pa10, 0},
1203 { "sh2addl",	0x08000a80, 0xfc000fe0, "?ax,b,t", pa10, 0},
1204 { "sh2addo",	0x08000e80, 0xfc000fe0, "?ax,b,t", pa10, 0},
1205 { "sh3add",	0x080006c0, 0xfc000fe0, "?ax,b,t", pa10, 0},
1206 { "sh3addl",	0x08000ac0, 0xfc000fe0, "?ax,b,t", pa10, 0},
1207 { "sh3addo",	0x08000ec0, 0xfc000fe0, "?ax,b,t", pa10, 0},
1208 
1209 /* Subword Operation Instructions.  */
1210 
1211 { "hadd",	0x08000300, 0xfc00ff20, "cHx,b,t", pa20, FLAG_STRICT},
1212 { "havg",	0x080002c0, 0xfc00ffe0, "x,b,t", pa20, FLAG_STRICT},
1213 { "hshl",	0xf8008800, 0xffe0fc20, "x,*,t", pa20, FLAG_STRICT},
1214 { "hshladd",	0x08000700, 0xfc00ff20, "x,.,b,t", pa20, FLAG_STRICT},
1215 { "hshr",	0xf800c800, 0xfc1ff820, "cSb,*,t", pa20, FLAG_STRICT},
1216 { "hshradd",	0x08000500, 0xfc00ff20, "x,.,b,t", pa20, FLAG_STRICT},
1217 { "hsub",	0x08000100, 0xfc00ff20, "cHx,b,t", pa20, FLAG_STRICT},
1218 { "mixh",	0xf8008400, 0xfc009fe0, "chx,b,t", pa20, FLAG_STRICT},
1219 { "mixw",	0xf8008000, 0xfc009fe0, "chx,b,t", pa20, FLAG_STRICT},
1220 { "permh",	0xf8000000, 0xfc009020, "c*a,t", pa20, FLAG_STRICT},
1221 
1222 
1223 /* Extract and Deposit Instructions.  */
1224 
1225 { "shrpd",	0xd0000200, 0xfc001fe0, "?Xx,b,!,t", pa20, FLAG_STRICT},
1226 { "shrpd",	0xd0000400, 0xfc001400, "?Xx,b,~,t", pa20, FLAG_STRICT},
1227 { "shrpw",	0xd0000000, 0xfc001fe0, "?xx,b,!,t", pa10, FLAG_STRICT},
1228 { "shrpw",	0xd0000800, 0xfc001c00, "?xx,b,p,t", pa10, FLAG_STRICT},
1229 { "vshd",	0xd0000000, 0xfc001fe0, "?xx,b,t", pa10, 0},
1230 { "shd",	0xd0000800, 0xfc001c00, "?xx,b,p,t", pa10, 0},
1231 { "extrd",	0xd0001200, 0xfc001ae0, "cS?Xb,!,%,x", pa20, FLAG_STRICT},
1232 { "extrd",	0xd8000000, 0xfc000000, "cS?Xb,q,|,x", pa20, FLAG_STRICT},
1233 { "extrw",	0xd0001000, 0xfc001be0, "cS?xb,!,T,x", pa10, FLAG_STRICT},
1234 { "extrw",	0xd0001800, 0xfc001800, "cS?xb,P,T,x", pa10, FLAG_STRICT},
1235 { "vextru",	0xd0001000, 0xfc001fe0, "?xb,T,x", pa10, 0},
1236 { "vextrs",	0xd0001400, 0xfc001fe0, "?xb,T,x", pa10, 0},
1237 { "extru",	0xd0001800, 0xfc001c00, "?xb,P,T,x", pa10, 0},
1238 { "extrs",	0xd0001c00, 0xfc001c00, "?xb,P,T,x", pa10, 0},
1239 { "depd",	0xd4000200, 0xfc001ae0, "cz?Xx,!,%,b", pa20, FLAG_STRICT},
1240 { "depd",	0xf0000000, 0xfc000000, "cz?Xx,~,|,b", pa20, FLAG_STRICT},
1241 { "depdi",	0xd4001200, 0xfc001ae0, "cz?X5,!,%,b", pa20, FLAG_STRICT},
1242 { "depdi",	0xf4000000, 0xfc000000, "cz?X5,~,|,b", pa20, FLAG_STRICT},
1243 { "depw",	0xd4000000, 0xfc001be0, "cz?xx,!,T,b", pa10, FLAG_STRICT},
1244 { "depw",	0xd4000800, 0xfc001800, "cz?xx,p,T,b", pa10, FLAG_STRICT},
1245 { "depwi",	0xd4001000, 0xfc001be0, "cz?x5,!,T,b", pa10, FLAG_STRICT},
1246 { "depwi",	0xd4001800, 0xfc001800, "cz?x5,p,T,b", pa10, FLAG_STRICT},
1247 { "zvdep",	0xd4000000, 0xfc001fe0, "?xx,T,b", pa10, 0},
1248 { "vdep",	0xd4000400, 0xfc001fe0, "?xx,T,b", pa10, 0},
1249 { "zdep",	0xd4000800, 0xfc001c00, "?xx,p,T,b", pa10, 0},
1250 { "dep",	0xd4000c00, 0xfc001c00, "?xx,p,T,b", pa10, 0},
1251 { "zvdepi",	0xd4001000, 0xfc001fe0, "?x5,T,b", pa10, 0},
1252 { "vdepi",	0xd4001400, 0xfc001fe0, "?x5,T,b", pa10, 0},
1253 { "zdepi",	0xd4001800, 0xfc001c00, "?x5,p,T,b", pa10, 0},
1254 { "depi",	0xd4001c00, 0xfc001c00, "?x5,p,T,b", pa10, 0},
1255 
1256 /* System Control Instructions.  */
1257 
1258 { "break",	0x00000000, 0xfc001fe0, "r,A", pa10, 0},
1259 { "rfi",	0x00000c00, 0xffffff1f, "cr", pa10, FLAG_STRICT},
1260 { "rfi",	0x00000c00, 0xffffffff, "", pa10, 0},
1261 { "rfir",	0x00000ca0, 0xffffffff, "", pa11, 0},
1262 { "ssm",	0x00000d60, 0xfc00ffe0, "U,t", pa20, FLAG_STRICT},
1263 { "ssm",	0x00000d60, 0xffe0ffe0, "R,t", pa10, 0},
1264 { "rsm",	0x00000e60, 0xfc00ffe0, "U,t", pa20, FLAG_STRICT},
1265 { "rsm",	0x00000e60, 0xffe0ffe0, "R,t", pa10, 0},
1266 { "mtsm",	0x00001860, 0xffe0ffff, "x", pa10, 0},
1267 { "ldsid",	0x000010a0, 0xfc1fffe0, "(b),t", pa10, 0},
1268 { "ldsid",	0x000010a0, 0xfc1f3fe0, "(s,b),t", pa10, 0},
1269 { "mtsp",	0x00001820, 0xffe01fff, "x,S", pa10, 0},
1270 { "mtctl",	0x00001840, 0xfc00ffff, "x,^", pa10, 0},
1271 { "mtsarcm",	0x016018C0, 0xffe0ffff, "x", pa20, FLAG_STRICT},
1272 { "mfia",	0x000014A0, 0xffffffe0, "t", pa20, FLAG_STRICT},
1273 { "mfsp",	0x000004a0, 0xffff1fe0, "S,t", pa10, 0},
1274 { "mfctl",	0x016048a0, 0xffffffe0, "cW!,t", pa20, FLAG_STRICT},
1275 { "mfctl",	0x000008a0, 0xfc1fffe0, "^,t", pa10, 0},
1276 { "sync",	0x00000400, 0xffffffff, "", pa10, 0},
1277 { "syncdma",	0x00100400, 0xffffffff, "", pa10, 0},
1278 { "probe",	0x04001180, 0xfc00ffa0, "cw(b),x,t", pa10, FLAG_STRICT},
1279 { "probe",	0x04001180, 0xfc003fa0, "cw(s,b),x,t", pa10, FLAG_STRICT},
1280 { "probei",	0x04003180, 0xfc00ffa0, "cw(b),R,t", pa10, FLAG_STRICT},
1281 { "probei",	0x04003180, 0xfc003fa0, "cw(s,b),R,t", pa10, FLAG_STRICT},
1282 { "prober",	0x04001180, 0xfc00ffe0, "(b),x,t", pa10, 0},
1283 { "prober",	0x04001180, 0xfc003fe0, "(s,b),x,t", pa10, 0},
1284 { "proberi",	0x04003180, 0xfc00ffe0, "(b),R,t", pa10, 0},
1285 { "proberi",	0x04003180, 0xfc003fe0, "(s,b),R,t", pa10, 0},
1286 { "probew",	0x040011c0, 0xfc00ffe0, "(b),x,t", pa10, 0},
1287 { "probew",	0x040011c0, 0xfc003fe0, "(s,b),x,t", pa10, 0},
1288 { "probewi",	0x040031c0, 0xfc00ffe0, "(b),R,t", pa10, 0},
1289 { "probewi",	0x040031c0, 0xfc003fe0, "(s,b),R,t", pa10, 0},
1290 { "lpa",	0x04001340, 0xfc00ffc0, "cZx(b),t", pa10, 0},
1291 { "lpa",	0x04001340, 0xfc003fc0, "cZx(s,b),t", pa10, 0},
1292 { "lci",	0x04001300, 0xfc00ffe0, "x(b),t", pa11, 0},
1293 { "lci",	0x04001300, 0xfc003fe0, "x(s,b),t", pa11, 0},
1294 { "pdtlb",	0x04001600, 0xfc00ffdf, "cLcZx(b)", pa20, FLAG_STRICT},
1295 { "pdtlb",	0x04001600, 0xfc003fdf, "cLcZx(s,b)", pa20, FLAG_STRICT},
1296 { "pdtlb",	0x04001600, 0xfc1fffdf, "cLcZ@(b)", pa20, FLAG_STRICT},
1297 { "pdtlb",	0x04001600, 0xfc1f3fdf, "cLcZ@(s,b)", pa20, FLAG_STRICT},
1298 { "pdtlb",	0x04001200, 0xfc00ffdf, "cZx(b)", pa10, 0},
1299 { "pdtlb",	0x04001200, 0xfc003fdf, "cZx(s,b)", pa10, 0},
1300 { "pitlb",	0x04000600, 0xfc001fdf, "cLcZx(S,b)", pa20, FLAG_STRICT},
1301 { "pitlb",	0x04000600, 0xfc1f1fdf, "cLcZ@(S,b)", pa20, FLAG_STRICT},
1302 { "pitlb",	0x04000200, 0xfc001fdf, "cZx(S,b)", pa10, 0},
1303 { "pdtlbe",	0x04001240, 0xfc00ffdf, "cZx(b)", pa10, 0},
1304 { "pdtlbe",	0x04001240, 0xfc003fdf, "cZx(s,b)", pa10, 0},
1305 { "pitlbe",	0x04000240, 0xfc001fdf, "cZx(S,b)", pa10, 0},
1306 { "idtlba",	0x04001040, 0xfc00ffff, "x,(b)", pa10, 0},
1307 { "idtlba",	0x04001040, 0xfc003fff, "x,(s,b)", pa10, 0},
1308 { "iitlba",	0x04000040, 0xfc001fff, "x,(S,b)", pa10, 0},
1309 { "idtlbp",	0x04001000, 0xfc00ffff, "x,(b)", pa10, 0},
1310 { "idtlbp",	0x04001000, 0xfc003fff, "x,(s,b)", pa10, 0},
1311 { "iitlbp",	0x04000000, 0xfc001fff, "x,(S,b)", pa10, 0},
1312 { "pdc",	0x04001380, 0xfc00ffdf, "cZx(b)", pa10, 0},
1313 { "pdc",	0x04001380, 0xfc003fdf, "cZx(s,b)", pa10, 0},
1314 { "fdc",	0x04001280, 0xfc00ffdf, "cZx(b)", pa10, FLAG_STRICT},
1315 { "fdc",	0x04001280, 0xfc003fdf, "cZx(s,b)", pa10, FLAG_STRICT},
1316 { "fdc",	0x04003280, 0xfc00ffff, "5(b)", pa20, FLAG_STRICT},
1317 { "fdc",	0x04003280, 0xfc003fff, "5(s,b)", pa20, FLAG_STRICT},
1318 { "fdc",	0x04001280, 0xfc00ffdf, "cZx(b)", pa10, 0},
1319 { "fdc",	0x04001280, 0xfc003fdf, "cZx(s,b)", pa10, 0},
1320 { "fic",	0x040013c0, 0xfc00dfdf, "cZx(b)", pa20, FLAG_STRICT},
1321 { "fic",	0x04000280, 0xfc001fdf, "cZx(S,b)", pa10, 0},
1322 { "fdce",	0x040012c0, 0xfc00ffdf, "cZx(b)", pa10, 0},
1323 { "fdce",	0x040012c0, 0xfc003fdf, "cZx(s,b)", pa10, 0},
1324 { "fice",	0x040002c0, 0xfc001fdf, "cZx(S,b)", pa10, 0},
1325 { "diag",	0x14000000, 0xfc000000, "D", pa10, 0},
1326 { "idtlbt",	0x04001800, 0xfc00ffff, "x,b", pa20, FLAG_STRICT},
1327 { "iitlbt",	0x04000800, 0xfc00ffff, "x,b", pa20, FLAG_STRICT},
1328 
1329 /* These may be specific to certain versions of the PA.  Joel claimed
1330    they were 72000 (7200?) specific.  However, I'm almost certain the
1331    mtcpu/mfcpu were undocumented, but available in the older 700 machines.  */
1332 { "mtcpu",	0x14001600, 0xfc00ffff, "x,^", pa10, 0},
1333 { "mfcpu",	0x14001A00, 0xfc00ffff, "^,x", pa10, 0},
1334 { "tocen",	0x14403600, 0xffffffff, "", pa10, 0},
1335 { "tocdis",	0x14401620, 0xffffffff, "", pa10, 0},
1336 { "shdwgr",	0x14402600, 0xffffffff, "", pa10, 0},
1337 { "grshdw",	0x14400620, 0xffffffff, "", pa10, 0},
1338 
1339 /* gfw and gfr are not in the HP PA 1.1 manual, but they are in either
1340    the Timex FPU or the Mustang ERS (not sure which) manual.  */
1341 { "gfw",	0x04001680, 0xfc00ffdf, "cZx(b)", pa11, 0},
1342 { "gfw",	0x04001680, 0xfc003fdf, "cZx(s,b)", pa11, 0},
1343 { "gfr",	0x04001a80, 0xfc00ffdf, "cZx(b)", pa11, 0},
1344 { "gfr",	0x04001a80, 0xfc003fdf, "cZx(s,b)", pa11, 0},
1345 
1346 /* Floating Point Coprocessor Instructions.  */
1347 
1348 { "fldw",	0x24000000, 0xfc00df80, "cXx(b),fT", pa10, FLAG_STRICT},
1349 { "fldw",	0x24000000, 0xfc001f80, "cXx(s,b),fT", pa10, FLAG_STRICT},
1350 { "fldw",	0x24000000, 0xfc00d380, "cxccx(b),fT", pa11, FLAG_STRICT},
1351 { "fldw",	0x24000000, 0xfc001380, "cxccx(s,b),fT", pa11, FLAG_STRICT},
1352 { "fldw",	0x24001020, 0xfc1ff3a0, "cocc@(b),fT", pa20, FLAG_STRICT},
1353 { "fldw",	0x24001020, 0xfc1f33a0, "cocc@(s,b),fT", pa20, FLAG_STRICT},
1354 { "fldw",	0x24001000, 0xfc00df80, "cM5(b),fT", pa10, FLAG_STRICT},
1355 { "fldw",	0x24001000, 0xfc001f80, "cM5(s,b),fT", pa10, FLAG_STRICT},
1356 { "fldw",	0x24001000, 0xfc00d380, "cmcc5(b),fT", pa11, FLAG_STRICT},
1357 { "fldw",	0x24001000, 0xfc001380, "cmcc5(s,b),fT", pa11, FLAG_STRICT},
1358 { "fldw",	0x5c000000, 0xfc000004, "y(b),fe", pa20w, FLAG_STRICT},
1359 { "fldw",	0x58000000, 0xfc000000, "cJy(b),fe", pa20w, FLAG_STRICT},
1360 { "fldw",	0x5c000000, 0xfc00c004, "d(b),fe", pa20, FLAG_STRICT},
1361 { "fldw",	0x5c000000, 0xfc000004, "d(s,b),fe", pa20, FLAG_STRICT},
1362 { "fldw",	0x58000000, 0xfc00c000, "cJd(b),fe", pa20, FLAG_STRICT},
1363 { "fldw",	0x58000000, 0xfc000000, "cJd(s,b),fe", pa20, FLAG_STRICT},
1364 { "fldd",	0x2c000000, 0xfc00dfc0, "cXx(b),ft", pa10, FLAG_STRICT},
1365 { "fldd",	0x2c000000, 0xfc001fc0, "cXx(s,b),ft", pa10, FLAG_STRICT},
1366 { "fldd",	0x2c000000, 0xfc00d3c0, "cxccx(b),ft", pa11, FLAG_STRICT},
1367 { "fldd",	0x2c000000, 0xfc0013c0, "cxccx(s,b),ft", pa11, FLAG_STRICT},
1368 { "fldd",	0x2c001020, 0xfc1ff3e0, "cocc@(b),ft", pa20, FLAG_STRICT},
1369 { "fldd",	0x2c001020, 0xfc1f33e0, "cocc@(s,b),ft", pa20, FLAG_STRICT},
1370 { "fldd",	0x2c001000, 0xfc00dfc0, "cM5(b),ft", pa10, FLAG_STRICT},
1371 { "fldd",	0x2c001000, 0xfc001fc0, "cM5(s,b),ft", pa10, FLAG_STRICT},
1372 { "fldd",	0x2c001000, 0xfc00d3c0, "cmcc5(b),ft", pa11, FLAG_STRICT},
1373 { "fldd",	0x2c001000, 0xfc0013c0, "cmcc5(s,b),ft", pa11, FLAG_STRICT},
1374 { "fldd",	0x50000002, 0xfc000002, "cq&(b),fx", pa20w, FLAG_STRICT},
1375 { "fldd",	0x50000002, 0xfc00c002, "cq#(b),fx", pa20, FLAG_STRICT},
1376 { "fldd",	0x50000002, 0xfc000002, "cq#(s,b),fx", pa20, FLAG_STRICT},
1377 { "fstw",	0x24000200, 0xfc00df80, "cXfT,x(b)", pa10, FLAG_STRICT},
1378 { "fstw",	0x24000200, 0xfc001f80, "cXfT,x(s,b)", pa10, FLAG_STRICT},
1379 { "fstw",	0x24000200, 0xfc00d380, "cxcCfT,x(b)", pa11, FLAG_STRICT},
1380 { "fstw",	0x24000200, 0xfc001380, "cxcCfT,x(s,b)", pa11, FLAG_STRICT},
1381 { "fstw",	0x24001220, 0xfc1ff3a0, "cocCfT,@(b)", pa20, FLAG_STRICT},
1382 { "fstw",	0x24001220, 0xfc1f33a0, "cocCfT,@(s,b)", pa20, FLAG_STRICT},
1383 { "fstw",	0x24001200, 0xfc00df80, "cMfT,5(b)", pa10, FLAG_STRICT},
1384 { "fstw",	0x24001200, 0xfc001f80, "cMfT,5(s,b)", pa10, FLAG_STRICT},
1385 { "fstw",	0x24001200, 0xfc00df80, "cMfT,5(b)", pa10, FLAG_STRICT},
1386 { "fstw",	0x24001200, 0xfc001f80, "cMfT,5(s,b)", pa10, FLAG_STRICT},
1387 { "fstw",	0x7c000000, 0xfc000004, "fE,y(b)", pa20w, FLAG_STRICT},
1388 { "fstw",	0x78000000, 0xfc000000, "cJfE,y(b)", pa20w, FLAG_STRICT},
1389 { "fstw",	0x7c000000, 0xfc00c004, "fE,d(b)", pa20, FLAG_STRICT},
1390 { "fstw",	0x7c000000, 0xfc000004, "fE,d(s,b)", pa20, FLAG_STRICT},
1391 { "fstw",	0x78000000, 0xfc00c000, "cJfE,d(b)", pa20, FLAG_STRICT},
1392 { "fstw",	0x78000000, 0xfc000000, "cJfE,d(s,b)", pa20, FLAG_STRICT},
1393 { "fstd",	0x2c000200, 0xfc00dfc0, "cXft,x(b)", pa10, FLAG_STRICT},
1394 { "fstd",	0x2c000200, 0xfc001fc0, "cXft,x(s,b)", pa10, FLAG_STRICT},
1395 { "fstd",	0x2c000200, 0xfc00d3c0, "cxcCft,x(b)", pa11, FLAG_STRICT},
1396 { "fstd",	0x2c000200, 0xfc0013c0, "cxcCft,x(s,b)", pa11, FLAG_STRICT},
1397 { "fstd",	0x2c001220, 0xfc1ff3e0, "cocCft,@(b)", pa20, FLAG_STRICT},
1398 { "fstd",	0x2c001220, 0xfc1f33e0, "cocCft,@(s,b)", pa20, FLAG_STRICT},
1399 { "fstd",	0x2c001200, 0xfc00dfc0, "cMft,5(b)", pa10, FLAG_STRICT},
1400 { "fstd",	0x2c001200, 0xfc001fc0, "cMft,5(s,b)", pa10, FLAG_STRICT},
1401 { "fstd",	0x2c001200, 0xfc00d3c0, "cmcCft,5(b)", pa11, FLAG_STRICT},
1402 { "fstd",	0x2c001200, 0xfc0013c0, "cmcCft,5(s,b)", pa11, FLAG_STRICT},
1403 { "fstd",	0x70000002, 0xfc000002, "cqfx,&(b)", pa20w, FLAG_STRICT},
1404 { "fstd",	0x70000002, 0xfc00c002, "cqfx,#(b)", pa20, FLAG_STRICT},
1405 { "fstd",	0x70000002, 0xfc000002, "cqfx,#(s,b)", pa20, FLAG_STRICT},
1406 { "fldwx",	0x24000000, 0xfc00df80, "cXx(b),fT", pa10, FLAG_STRICT},
1407 { "fldwx",	0x24000000, 0xfc001f80, "cXx(s,b),fT", pa10, FLAG_STRICT},
1408 { "fldwx",	0x24000000, 0xfc00d380, "cxccx(b),fT", pa11, FLAG_STRICT},
1409 { "fldwx",	0x24000000, 0xfc001380, "cxccx(s,b),fT", pa11, FLAG_STRICT},
1410 { "fldwx",	0x24000000, 0xfc00df80, "cXx(b),fT", pa10, 0},
1411 { "fldwx",	0x24000000, 0xfc001f80, "cXx(s,b),fT", pa10, 0},
1412 { "flddx",	0x2c000000, 0xfc00dfc0, "cXx(b),ft", pa10, FLAG_STRICT},
1413 { "flddx",	0x2c000000, 0xfc001fc0, "cXx(s,b),ft", pa10, FLAG_STRICT},
1414 { "flddx",	0x2c000000, 0xfc00d3c0, "cxccx(b),ft", pa11, FLAG_STRICT},
1415 { "flddx",	0x2c000000, 0xfc0013c0, "cxccx(s,b),ft", pa11, FLAG_STRICT},
1416 { "flddx",	0x2c000000, 0xfc00dfc0, "cXx(b),ft", pa10, 0},
1417 { "flddx",	0x2c000000, 0xfc001fc0, "cXx(s,b),ft", pa10, 0},
1418 { "fstwx",	0x24000200, 0xfc00df80, "cxfT,x(b)", pa10, FLAG_STRICT},
1419 { "fstwx",	0x24000200, 0xfc001f80, "cxfT,x(s,b)", pa10, FLAG_STRICT},
1420 { "fstwx",	0x24000200, 0xfc00d380, "cxcCfT,x(b)", pa11, FLAG_STRICT},
1421 { "fstwx",	0x24000200, 0xfc001380, "cxcCfT,x(s,b)", pa11, FLAG_STRICT},
1422 { "fstwx",	0x24000200, 0xfc00df80, "cxfT,x(b)", pa10, 0},
1423 { "fstwx",	0x24000200, 0xfc001f80, "cxfT,x(s,b)", pa10, 0},
1424 { "fstdx",	0x2c000200, 0xfc00dfc0, "cxft,x(b)", pa10, FLAG_STRICT},
1425 { "fstdx",	0x2c000200, 0xfc001fc0, "cxft,x(s,b)", pa10, FLAG_STRICT},
1426 { "fstdx",	0x2c000200, 0xfc00d3c0, "cxcCft,x(b)", pa11, FLAG_STRICT},
1427 { "fstdx",	0x2c000200, 0xfc0013c0, "cxcCft,x(s,b)", pa11, FLAG_STRICT},
1428 { "fstdx",	0x2c000200, 0xfc00dfc0, "cxft,x(b)", pa10, 0},
1429 { "fstdx",	0x2c000200, 0xfc001fc0, "cxft,x(s,b)", pa10, 0},
1430 { "fstqx",	0x3c000200, 0xfc00dfc0, "cxft,x(b)", pa10, 0},
1431 { "fstqx",	0x3c000200, 0xfc001fc0, "cxft,x(s,b)", pa10, 0},
1432 { "fldws",	0x24001000, 0xfc00df80, "cm5(b),fT", pa10, FLAG_STRICT},
1433 { "fldws",	0x24001000, 0xfc001f80, "cm5(s,b),fT", pa10, FLAG_STRICT},
1434 { "fldws",	0x24001000, 0xfc00d380, "cmcc5(b),fT", pa11, FLAG_STRICT},
1435 { "fldws",	0x24001000, 0xfc001380, "cmcc5(s,b),fT", pa11, FLAG_STRICT},
1436 { "fldws",	0x24001000, 0xfc00df80, "cm5(b),fT", pa10, 0},
1437 { "fldws",	0x24001000, 0xfc001f80, "cm5(s,b),fT", pa10, 0},
1438 { "fldds",	0x2c001000, 0xfc00dfc0, "cm5(b),ft", pa10, FLAG_STRICT},
1439 { "fldds",	0x2c001000, 0xfc001fc0, "cm5(s,b),ft", pa10, FLAG_STRICT},
1440 { "fldds",	0x2c001000, 0xfc00d3c0, "cmcc5(b),ft", pa11, FLAG_STRICT},
1441 { "fldds",	0x2c001000, 0xfc0013c0, "cmcc5(s,b),ft", pa11, FLAG_STRICT},
1442 { "fldds",	0x2c001000, 0xfc00dfc0, "cm5(b),ft", pa10, 0},
1443 { "fldds",	0x2c001000, 0xfc001fc0, "cm5(s,b),ft", pa10, 0},
1444 { "fstws",	0x24001200, 0xfc00df80, "cmfT,5(b)", pa10, FLAG_STRICT},
1445 { "fstws",	0x24001200, 0xfc001f80, "cmfT,5(s,b)", pa10, FLAG_STRICT},
1446 { "fstws",	0x24001200, 0xfc00d380, "cmcCfT,5(b)", pa11, FLAG_STRICT},
1447 { "fstws",	0x24001200, 0xfc001380, "cmcCfT,5(s,b)", pa11, FLAG_STRICT},
1448 { "fstws",	0x24001200, 0xfc00df80, "cmfT,5(b)", pa10, 0},
1449 { "fstws",	0x24001200, 0xfc001f80, "cmfT,5(s,b)", pa10, 0},
1450 { "fstds",	0x2c001200, 0xfc00dfc0, "cmft,5(b)", pa10, FLAG_STRICT},
1451 { "fstds",	0x2c001200, 0xfc001fc0, "cmft,5(s,b)", pa10, FLAG_STRICT},
1452 { "fstds",	0x2c001200, 0xfc00d3c0, "cmcCft,5(b)", pa11, FLAG_STRICT},
1453 { "fstds",	0x2c001200, 0xfc0013c0, "cmcCft,5(s,b)", pa11, FLAG_STRICT},
1454 { "fstds",	0x2c001200, 0xfc00dfc0, "cmft,5(b)", pa10, 0},
1455 { "fstds",	0x2c001200, 0xfc001fc0, "cmft,5(s,b)", pa10, 0},
1456 { "fstqs",	0x3c001200, 0xfc00dfc0, "cmft,5(b)", pa10, 0},
1457 { "fstqs",	0x3c001200, 0xfc001fc0, "cmft,5(s,b)", pa10, 0},
1458 { "fadd",	0x30000600, 0xfc00e7e0, "Ffa,fb,fT", pa10, 0},
1459 { "fadd",	0x38000600, 0xfc00e720, "IfA,fB,fT", pa10, 0},
1460 { "fsub",	0x30002600, 0xfc00e7e0, "Ffa,fb,fT", pa10, 0},
1461 { "fsub",	0x38002600, 0xfc00e720, "IfA,fB,fT", pa10, 0},
1462 { "fmpy",	0x30004600, 0xfc00e7e0, "Ffa,fb,fT", pa10, 0},
1463 { "fmpy",	0x38004600, 0xfc00e720, "IfA,fB,fT", pa10, 0},
1464 { "fdiv",	0x30006600, 0xfc00e7e0, "Ffa,fb,fT", pa10, 0},
1465 { "fdiv",	0x38006600, 0xfc00e720, "IfA,fB,fT", pa10, 0},
1466 { "fsqrt",	0x30008000, 0xfc1fe7e0, "Ffa,fT", pa10, 0},
1467 { "fsqrt",	0x38008000, 0xfc1fe720, "FfA,fT", pa10, 0},
1468 { "fabs",	0x30006000, 0xfc1fe7e0, "Ffa,fT", pa10, 0},
1469 { "fabs",	0x38006000, 0xfc1fe720, "FfA,fT", pa10, 0},
1470 { "frem",	0x30008600, 0xfc00e7e0, "Ffa,fb,fT", pa10, 0},
1471 { "frem",	0x38008600, 0xfc00e720, "FfA,fB,fT", pa10, 0},
1472 { "frnd",	0x3000a000, 0xfc1fe7e0, "Ffa,fT", pa10, 0},
1473 { "frnd",	0x3800a000, 0xfc1fe720, "FfA,fT", pa10, 0},
1474 { "fcpy",	0x30004000, 0xfc1fe7e0, "Ffa,fT", pa10, 0},
1475 { "fcpy",	0x38004000, 0xfc1fe720, "FfA,fT", pa10, 0},
1476 { "fcnvff",	0x30000200, 0xfc1f87e0, "FGfa,fT", pa10, 0},
1477 { "fcnvff",	0x38000200, 0xfc1f8720, "FGfA,fT", pa10, 0},
1478 { "fcnvxf",	0x30008200, 0xfc1f87e0, "FGfa,fT", pa10, 0},
1479 { "fcnvxf",	0x38008200, 0xfc1f8720, "FGfA,fT", pa10, 0},
1480 { "fcnvfx",	0x30010200, 0xfc1f87e0, "FGfa,fT", pa10, 0},
1481 { "fcnvfx",	0x38010200, 0xfc1f8720, "FGfA,fT", pa10, 0},
1482 { "fcnvfxt",	0x30018200, 0xfc1f87e0, "FGfa,fT", pa10, 0},
1483 { "fcnvfxt",	0x38018200, 0xfc1f8720, "FGfA,fT", pa10, 0},
1484 { "fmpyfadd",	0xb8000000, 0xfc000020, "IfA,fB,fC,fT", pa20, FLAG_STRICT},
1485 { "fmpynfadd",	0xb8000020, 0xfc000020, "IfA,fB,fC,fT", pa20, FLAG_STRICT},
1486 { "fneg",	0x3000c000, 0xfc1fe7e0, "Ffa,fT", pa20, FLAG_STRICT},
1487 { "fneg",	0x3800c000, 0xfc1fe720, "IfA,fT", pa20, FLAG_STRICT},
1488 { "fnegabs",	0x3000e000, 0xfc1fe7e0, "Ffa,fT", pa20, FLAG_STRICT},
1489 { "fnegabs",	0x3800e000, 0xfc1fe720, "IfA,fT", pa20, FLAG_STRICT},
1490 { "fcnv",	0x30000200, 0xfc1c0720, "{_fa,fT", pa20, FLAG_STRICT},
1491 { "fcnv",	0x38000200, 0xfc1c0720, "FGfA,fT", pa20, FLAG_STRICT},
1492 { "fcmp",	0x30000400, 0xfc00e7e0, "F?ffa,fb", pa10, FLAG_STRICT},
1493 { "fcmp",	0x38000400, 0xfc00e720, "I?ffA,fB", pa10, FLAG_STRICT},
1494 { "fcmp",	0x30000400, 0xfc0007e0, "F?ffa,fb,h", pa20, FLAG_STRICT},
1495 { "fcmp",	0x38000400, 0xfc000720, "I?ffA,fB,h", pa20, FLAG_STRICT},
1496 { "fcmp",	0x30000400, 0xfc00e7e0, "F?ffa,fb", pa10, 0},
1497 { "fcmp",	0x38000400, 0xfc00e720, "I?ffA,fB", pa10, 0},
1498 { "xmpyu",	0x38004700, 0xfc00e720, "fX,fB,fT", pa11, 0},
1499 { "fmpyadd",	0x18000000, 0xfc000000, "Hfi,fj,fk,fl,fm", pa11, 0},
1500 { "fmpysub",	0x98000000, 0xfc000000, "Hfi,fj,fk,fl,fm", pa11, 0},
1501 { "ftest",	0x30002420, 0xffffffff, "", pa10, FLAG_STRICT},
1502 { "ftest",	0x30002420, 0xffffffe0, ",=", pa20, FLAG_STRICT},
1503 { "ftest",	0x30000420, 0xffff1fff, "m", pa20, FLAG_STRICT},
1504 { "fid",	0x30000000, 0xffffffff, "", pa11, 0},
1505 
1506 /* Performance Monitor Instructions.  */
1507 
1508 { "pmdis",	0x30000280, 0xffffffdf, "N", pa20, FLAG_STRICT},
1509 { "pmenb",	0x30000680, 0xffffffff, "", pa20, FLAG_STRICT},
1510 
1511 /* Assist Instructions.  */
1512 
1513 { "spop0",	0x10000000, 0xfc000600, "v,ON", pa10, 0},
1514 { "spop1",	0x10000200, 0xfc000600, "v,oNt", pa10, 0},
1515 { "spop2",	0x10000400, 0xfc000600, "v,1Nb", pa10, 0},
1516 { "spop3",	0x10000600, 0xfc000600, "v,0Nx,b", pa10, 0},
1517 { "copr",	0x30000000, 0xfc000000, "u,2N", pa10, 0},
1518 { "cldw",	0x24000000, 0xfc00de00, "ucXx(b),t", pa10, FLAG_STRICT},
1519 { "cldw",	0x24000000, 0xfc001e00, "ucXx(s,b),t", pa10, FLAG_STRICT},
1520 { "cldw",	0x24000000, 0xfc00d200, "ucxccx(b),t", pa11, FLAG_STRICT},
1521 { "cldw",	0x24000000, 0xfc001200, "ucxccx(s,b),t", pa11, FLAG_STRICT},
1522 { "cldw",	0x24001000, 0xfc00d200, "ucocc@(b),t", pa20, FLAG_STRICT},
1523 { "cldw",	0x24001000, 0xfc001200, "ucocc@(s,b),t", pa20, FLAG_STRICT},
1524 { "cldw",	0x24001000, 0xfc00de00, "ucM5(b),t", pa10, FLAG_STRICT},
1525 { "cldw",	0x24001000, 0xfc001e00, "ucM5(s,b),t", pa10, FLAG_STRICT},
1526 { "cldw",	0x24001000, 0xfc00d200, "ucmcc5(b),t", pa11, FLAG_STRICT},
1527 { "cldw",	0x24001000, 0xfc001200, "ucmcc5(s,b),t", pa11, FLAG_STRICT},
1528 { "cldd",	0x2c000000, 0xfc00de00, "ucXx(b),t", pa10, FLAG_STRICT},
1529 { "cldd",	0x2c000000, 0xfc001e00, "ucXx(s,b),t", pa10, FLAG_STRICT},
1530 { "cldd",	0x2c000000, 0xfc00d200, "ucxccx(b),t", pa11, FLAG_STRICT},
1531 { "cldd",	0x2c000000, 0xfc001200, "ucxccx(s,b),t", pa11, FLAG_STRICT},
1532 { "cldd",	0x2c001000, 0xfc00d200, "ucocc@(b),t", pa20, FLAG_STRICT},
1533 { "cldd",	0x2c001000, 0xfc001200, "ucocc@(s,b),t", pa20, FLAG_STRICT},
1534 { "cldd",	0x2c001000, 0xfc00de00, "ucM5(b),t", pa10, FLAG_STRICT},
1535 { "cldd",	0x2c001000, 0xfc001e00, "ucM5(s,b),t", pa10, FLAG_STRICT},
1536 { "cldd",	0x2c001000, 0xfc00d200, "ucmcc5(b),t", pa11, FLAG_STRICT},
1537 { "cldd",	0x2c001000, 0xfc001200, "ucmcc5(s,b),t", pa11, FLAG_STRICT},
1538 { "cstw",	0x24000200, 0xfc00de00, "ucXt,x(b)", pa10, FLAG_STRICT},
1539 { "cstw",	0x24000200, 0xfc001e00, "ucXt,x(s,b)", pa10, FLAG_STRICT},
1540 { "cstw",	0x24000200, 0xfc00d200, "ucxcCt,x(b)", pa11, FLAG_STRICT},
1541 { "cstw",	0x24000200, 0xfc001200, "ucxcCt,x(s,b)", pa11, FLAG_STRICT},
1542 { "cstw",	0x24001200, 0xfc00d200, "ucocCt,@(b)", pa20, FLAG_STRICT},
1543 { "cstw",	0x24001200, 0xfc001200, "ucocCt,@(s,b)", pa20, FLAG_STRICT},
1544 { "cstw",	0x24001200, 0xfc00de00, "ucMt,5(b)", pa10, FLAG_STRICT},
1545 { "cstw",	0x24001200, 0xfc001e00, "ucMt,5(s,b)", pa10, FLAG_STRICT},
1546 { "cstw",	0x24001200, 0xfc00d200, "ucmcCt,5(b)", pa11, FLAG_STRICT},
1547 { "cstw",	0x24001200, 0xfc001200, "ucmcCt,5(s,b)", pa11, FLAG_STRICT},
1548 { "cstd",	0x2c000200, 0xfc00de00, "ucXt,x(b)", pa10, FLAG_STRICT},
1549 { "cstd",	0x2c000200, 0xfc001e00, "ucXt,x(s,b)", pa10, FLAG_STRICT},
1550 { "cstd",	0x2c000200, 0xfc00d200, "ucxcCt,x(b)", pa11, FLAG_STRICT},
1551 { "cstd",	0x2c000200, 0xfc001200, "ucxcCt,x(s,b)", pa11, FLAG_STRICT},
1552 { "cstd",	0x2c001200, 0xfc00d200, "ucocCt,@(b)", pa20, FLAG_STRICT},
1553 { "cstd",	0x2c001200, 0xfc001200, "ucocCt,@(s,b)", pa20, FLAG_STRICT},
1554 { "cstd",	0x2c001200, 0xfc00de00, "ucMt,5(b)", pa10, FLAG_STRICT},
1555 { "cstd",	0x2c001200, 0xfc001e00, "ucMt,5(s,b)", pa10, FLAG_STRICT},
1556 { "cstd",	0x2c001200, 0xfc00d200, "ucmcCt,5(b)", pa11, FLAG_STRICT},
1557 { "cstd",	0x2c001200, 0xfc001200, "ucmcCt,5(s,b)", pa11, FLAG_STRICT},
1558 { "cldwx",	0x24000000, 0xfc00de00, "ucXx(b),t", pa10, FLAG_STRICT},
1559 { "cldwx",	0x24000000, 0xfc001e00, "ucXx(s,b),t", pa10, FLAG_STRICT},
1560 { "cldwx",	0x24000000, 0xfc00d200, "ucxccx(b),t", pa11, FLAG_STRICT},
1561 { "cldwx",	0x24000000, 0xfc001200, "ucxccx(s,b),t", pa11, FLAG_STRICT},
1562 { "cldwx",	0x24000000, 0xfc00de00, "ucXx(b),t", pa10, 0},
1563 { "cldwx",	0x24000000, 0xfc001e00, "ucXx(s,b),t", pa10, 0},
1564 { "clddx",	0x2c000000, 0xfc00de00, "ucXx(b),t", pa10, FLAG_STRICT},
1565 { "clddx",	0x2c000000, 0xfc001e00, "ucXx(s,b),t", pa10, FLAG_STRICT},
1566 { "clddx",	0x2c000000, 0xfc00d200, "ucxccx(b),t", pa11, FLAG_STRICT},
1567 { "clddx",	0x2c000000, 0xfc001200, "ucxccx(s,b),t", pa11, FLAG_STRICT},
1568 { "clddx",	0x2c000000, 0xfc00de00, "ucXx(b),t", pa10, 0},
1569 { "clddx",	0x2c000000, 0xfc001e00, "ucXx(s,b),t", pa10, 0},
1570 { "cstwx",	0x24000200, 0xfc00de00, "ucXt,x(b)", pa10, FLAG_STRICT},
1571 { "cstwx",	0x24000200, 0xfc001e00, "ucXt,x(s,b)", pa10, FLAG_STRICT},
1572 { "cstwx",	0x24000200, 0xfc00d200, "ucxcCt,x(b)", pa11, FLAG_STRICT},
1573 { "cstwx",	0x24000200, 0xfc001200, "ucxcCt,x(s,b)", pa11, FLAG_STRICT},
1574 { "cstwx",	0x24000200, 0xfc00de00, "ucXt,x(b)", pa10, 0},
1575 { "cstwx",	0x24000200, 0xfc001e00, "ucXt,x(s,b)", pa10, 0},
1576 { "cstdx",	0x2c000200, 0xfc00de00, "ucXt,x(b)", pa10, FLAG_STRICT},
1577 { "cstdx",	0x2c000200, 0xfc001e00, "ucXt,x(s,b)", pa10, FLAG_STRICT},
1578 { "cstdx",	0x2c000200, 0xfc00d200, "ucxcCt,x(b)", pa11, FLAG_STRICT},
1579 { "cstdx",	0x2c000200, 0xfc001200, "ucxcCt,x(s,b)", pa11, FLAG_STRICT},
1580 { "cstdx",	0x2c000200, 0xfc00de00, "ucXt,x(b)", pa10, 0},
1581 { "cstdx",	0x2c000200, 0xfc001e00, "ucXt,x(s,b)", pa10, 0},
1582 { "cldws",	0x24001000, 0xfc00de00, "ucM5(b),t", pa10, FLAG_STRICT},
1583 { "cldws",	0x24001000, 0xfc001e00, "ucM5(s,b),t", pa10, FLAG_STRICT},
1584 { "cldws",	0x24001000, 0xfc00d200, "ucmcc5(b),t", pa11, FLAG_STRICT},
1585 { "cldws",	0x24001000, 0xfc001200, "ucmcc5(s,b),t", pa11, FLAG_STRICT},
1586 { "cldws",	0x24001000, 0xfc00de00, "ucM5(b),t", pa10, 0},
1587 { "cldws",	0x24001000, 0xfc001e00, "ucM5(s,b),t", pa10, 0},
1588 { "cldds",	0x2c001000, 0xfc00de00, "ucM5(b),t", pa10, FLAG_STRICT},
1589 { "cldds",	0x2c001000, 0xfc001e00, "ucM5(s,b),t", pa10, FLAG_STRICT},
1590 { "cldds",	0x2c001000, 0xfc00d200, "ucmcc5(b),t", pa11, FLAG_STRICT},
1591 { "cldds",	0x2c001000, 0xfc001200, "ucmcc5(s,b),t", pa11, FLAG_STRICT},
1592 { "cldds",	0x2c001000, 0xfc00de00, "ucM5(b),t", pa10, 0},
1593 { "cldds",	0x2c001000, 0xfc001e00, "ucM5(s,b),t", pa10, 0},
1594 { "cstws",	0x24001200, 0xfc00de00, "ucMt,5(b)", pa10, FLAG_STRICT},
1595 { "cstws",	0x24001200, 0xfc001e00, "ucMt,5(s,b)", pa10, FLAG_STRICT},
1596 { "cstws",	0x24001200, 0xfc00d200, "ucmcCt,5(b)", pa11, FLAG_STRICT},
1597 { "cstws",	0x24001200, 0xfc001200, "ucmcCt,5(s,b)", pa11, FLAG_STRICT},
1598 { "cstws",	0x24001200, 0xfc00de00, "ucMt,5(b)", pa10, 0},
1599 { "cstws",	0x24001200, 0xfc001e00, "ucMt,5(s,b)", pa10, 0},
1600 { "cstds",	0x2c001200, 0xfc00de00, "ucMt,5(b)", pa10, FLAG_STRICT},
1601 { "cstds",	0x2c001200, 0xfc001e00, "ucMt,5(s,b)", pa10, FLAG_STRICT},
1602 { "cstds",	0x2c001200, 0xfc00d200, "ucmcCt,5(b)", pa11, FLAG_STRICT},
1603 { "cstds",	0x2c001200, 0xfc001200, "ucmcCt,5(s,b)", pa11, FLAG_STRICT},
1604 { "cstds",	0x2c001200, 0xfc00de00, "ucMt,5(b)", pa10, 0},
1605 { "cstds",	0x2c001200, 0xfc001e00, "ucMt,5(s,b)", pa10, 0},
1606 
1607 /* More pseudo instructions which must follow the main table.  */
1608 { "call",	0xe800f000, 0xfc1ffffd, "n(b)", pa20, FLAG_STRICT},
1609 { "call",	0xe800a000, 0xffe0e000, "nW", pa10, FLAG_STRICT},
1610 { "ret",	0xe840d000, 0xfffffffd, "n", pa20, FLAG_STRICT},
1611 
1612 /* Opcodes assigned to QEMU, used by SeaBIOS firmware and Linux kernel */
1613 { "HALT QEMU",	0xfffdead0, 0xfffffffd, "n", pa10, FLAG_STRICT},
1614 { "RESET QEMU",	0xfffdead1, 0xfffffffd, "n", pa10, FLAG_STRICT},
1615 { "RESTORE SHR",0xfffdead2, 0xfffffffd, "n", pa10, FLAG_STRICT},
1616 };
1617 
1618 #define NUMOPCODES ((sizeof pa_opcodes)/(sizeof pa_opcodes[0]))
1619 
1620 /* SKV 12/18/92. Added some denotations for various operands.  */
1621 
1622 #define PA_IMM11_AT_31 'i'
1623 #define PA_IMM14_AT_31 'j'
1624 #define PA_IMM21_AT_31 'k'
1625 #define PA_DISP12 'w'
1626 #define PA_DISP17 'W'
1627 
1628 #define N_HPPA_OPERAND_FORMATS 5
1629 
1630 /* Integer register names, indexed by the numbers which appear in the
1631    opcodes.  */
1632 static const char *const reg_names[] =
1633 {
1634   "flags", "r1", "rp", "r3", "r4", "r5", "r6", "r7", "r8", "r9",
1635   "r10", "r11", "r12", "r13", "r14", "r15", "r16", "r17", "r18", "r19",
1636   "r20", "r21", "r22", "r23", "r24", "r25", "r26", "dp", "ret0", "ret1",
1637   "sp", "r31"
1638 };
1639 
1640 /* Floating point register names, indexed by the numbers which appear in the
1641    opcodes.  */
1642 static const char *const fp_reg_names[] =
1643 {
1644   "fpsr", "fpe2", "fpe4", "fpe6",
1645   "fr4", "fr5", "fr6", "fr7", "fr8",
1646   "fr9", "fr10", "fr11", "fr12", "fr13", "fr14", "fr15",
1647   "fr16", "fr17", "fr18", "fr19", "fr20", "fr21", "fr22", "fr23",
1648   "fr24", "fr25", "fr26", "fr27", "fr28", "fr29", "fr30", "fr31"
1649 };
1650 
1651 typedef unsigned int CORE_ADDR;
1652 
1653 /* Get at various relevant fields of an instruction word.  */
1654 
1655 #define MASK_5  0x1f
1656 #define MASK_10 0x3ff
1657 #define MASK_11 0x7ff
1658 #define MASK_14 0x3fff
1659 #define MASK_16 0xffff
1660 #define MASK_21 0x1fffff
1661 
1662 /* These macros get bit fields using HP's numbering (MSB = 0).  */
1663 
1664 #define GET_FIELD(X, FROM, TO) \
1665   ((X) >> (31 - (TO)) & ((1 << ((TO) - (FROM) + 1)) - 1))
1666 
1667 #define GET_BIT(X, WHICH) \
1668   GET_FIELD (X, WHICH, WHICH)
1669 
1670 /* Some of these have been converted to 2-d arrays because they
1671    consume less storage this way.  If the maintenance becomes a
1672    problem, convert them back to const 1-d pointer arrays.  */
1673 static const char *const control_reg[] =
1674 {
1675   "rctr", "cr1", "cr2", "cr3", "cr4", "cr5", "cr6", "cr7",
1676   "pidr1", "pidr2", "ccr", "sar", "pidr3", "pidr4",
1677   "iva", "eiem", "itmr", "pcsq", "pcoq", "iir", "isr",
1678   "ior", "ipsw", "eirr", "tr0", "tr1", "tr2", "tr3",
1679   "tr4", "tr5", "tr6", "tr7"
1680 };
1681 
1682 static const char *const compare_cond_names[] =
1683 {
1684   "", ",=", ",<", ",<=", ",<<", ",<<=", ",sv", ",od",
1685   ",tr", ",<>", ",>=", ",>", ",>>=", ",>>", ",nsv", ",ev"
1686 };
1687 static const char *const compare_cond_64_names[] =
1688 {
1689   "", ",*=", ",*<", ",*<=", ",*<<", ",*<<=", ",*sv", ",*od",
1690   ",*tr", ",*<>", ",*>=", ",*>", ",*>>=", ",*>>", ",*nsv", ",*ev"
1691 };
1692 static const char *const cmpib_cond_64_names[] =
1693 {
1694   ",*<<", ",*=", ",*<", ",*<=", ",*>>=", ",*<>", ",*>=", ",*>"
1695 };
1696 static const char *const add_cond_names[] =
1697 {
1698   "", ",=", ",<", ",<=", ",nuv", ",znv", ",sv", ",od",
1699   ",tr", ",<>", ",>=", ",>", ",uv", ",vnz", ",nsv", ",ev"
1700 };
1701 static const char *const add_cond_64_names[] =
1702 {
1703   "", ",*=", ",*<", ",*<=", ",*nuv", ",*znv", ",*sv", ",*od",
1704   ",*tr", ",*<>", ",*>=", ",*>", ",*uv", ",*vnz", ",*nsv", ",*ev"
1705 };
1706 static const char *const wide_add_cond_names[] =
1707 {
1708   "", ",=", ",<", ",<=", ",nuv", ",*=", ",*<", ",*<=",
1709   ",tr", ",<>", ",>=", ",>", ",uv", ",*<>", ",*>=", ",*>"
1710 };
1711 static const char *const logical_cond_names[] =
1712 {
1713   "", ",=", ",<", ",<=", 0, 0, 0, ",od",
1714   ",tr", ",<>", ",>=", ",>", 0, 0, 0, ",ev"};
1715 static const char *const logical_cond_64_names[] =
1716 {
1717   "", ",*=", ",*<", ",*<=", 0, 0, 0, ",*od",
1718   ",*tr", ",*<>", ",*>=", ",*>", 0, 0, 0, ",*ev"};
1719 static const char *const unit_cond_names[] =
1720 {
1721   "", ",swz", ",sbz", ",shz", ",sdc", ",swc", ",sbc", ",shc",
1722   ",tr", ",nwz", ",nbz", ",nhz", ",ndc", ",nwc", ",nbc", ",nhc"
1723 };
1724 static const char *const unit_cond_64_names[] =
1725 {
1726   "", ",*swz", ",*sbz", ",*shz", ",*sdc", ",*swc", ",*sbc", ",*shc",
1727   ",*tr", ",*nwz", ",*nbz", ",*nhz", ",*ndc", ",*nwc", ",*nbc", ",*nhc"
1728 };
1729 static const char *const shift_cond_names[] =
1730 {
1731   "", ",=", ",<", ",od", ",tr", ",<>", ",>=", ",ev"
1732 };
1733 static const char *const shift_cond_64_names[] =
1734 {
1735   "", ",*=", ",*<", ",*od", ",*tr", ",*<>", ",*>=", ",*ev"
1736 };
1737 static const char *const bb_cond_64_names[] =
1738 {
1739   ",*<", ",*>="
1740 };
1741 static const char *const index_compl_names[] = {"", ",m", ",s", ",sm"};
1742 static const char *const short_ldst_compl_names[] = {"", ",ma", "", ",mb"};
1743 static const char *const short_bytes_compl_names[] =
1744 {
1745   "", ",b,m", ",e", ",e,m"
1746 };
1747 static const char *const float_format_names[] = {",sgl", ",dbl", "", ",quad"};
1748 static const char *const fcnv_fixed_names[] = {",w", ",dw", "", ",qw"};
1749 static const char *const fcnv_ufixed_names[] = {",uw", ",udw", "", ",uqw"};
1750 static const char *const float_comp_names[] =
1751 {
1752   ",false?", ",false", ",?", ",!<=>", ",=", ",=t", ",?=", ",!<>",
1753   ",!?>=", ",<", ",?<", ",!>=", ",!?>", ",<=", ",?<=", ",!>",
1754   ",!?<=", ",>", ",?>", ",!<=", ",!?<", ",>=", ",?>=", ",!<",
1755   ",!?=", ",<>", ",!=", ",!=t", ",!?", ",<=>", ",true?", ",true"
1756 };
1757 static const char *const signed_unsigned_names[] = {",u", ",s"};
1758 static const char *const mix_half_names[] = {",l", ",r"};
1759 static const char *const saturation_names[] = {",us", ",ss", 0, ""};
1760 static const char *const read_write_names[] = {",r", ",w"};
1761 static const char *const add_compl_names[] = { 0, "", ",l", ",tsv" };
1762 
1763 /* For a bunch of different instructions form an index into a
1764    completer name table.  */
1765 #define GET_COMPL(insn) (GET_FIELD (insn, 26, 26) | \
1766 			 GET_FIELD (insn, 18, 18) << 1)
1767 
1768 #define GET_COND(insn) (GET_FIELD ((insn), 16, 18) + \
1769 			(GET_FIELD ((insn), 19, 19) ? 8 : 0))
1770 
1771 /* Utility function to print registers.  Put these first, so gcc's function
1772    inlining can do its stuff.  */
1773 
1774 #define fputs_filtered(STR,F)	(*info->fprintf_func) (info->stream, "%s", STR)
1775 
1776 static void
1777 fput_reg (unsigned reg, disassemble_info *info)
1778 {
1779   (*info->fprintf_func) (info->stream, "%s", reg ? reg_names[reg] : "r0");
1780 }
1781 
1782 static void
1783 fput_fp_reg (unsigned reg, disassemble_info *info)
1784 {
1785   (*info->fprintf_func) (info->stream, "%s", reg ? fp_reg_names[reg] : "fr0");
1786 }
1787 
1788 static void
1789 fput_fp_reg_r (unsigned reg, disassemble_info *info)
1790 {
1791   /* Special case floating point exception registers.  */
1792   if (reg < 4)
1793     (*info->fprintf_func) (info->stream, "fpe%d", reg * 2 + 1);
1794   else
1795     (*info->fprintf_func) (info->stream, "%sR", fp_reg_names[reg]);
1796 }
1797 
1798 static void
1799 fput_creg (unsigned reg, disassemble_info *info)
1800 {
1801   (*info->fprintf_func) (info->stream, "%s", control_reg[reg]);
1802 }
1803 
1804 /* Print constants with sign.  */
1805 
1806 static void
1807 fput_const (unsigned num, disassemble_info *info)
1808 {
1809   if ((int) num < 0)
1810     (*info->fprintf_func) (info->stream, "-%x", - (int) num);
1811   else
1812     (*info->fprintf_func) (info->stream, "%x", num);
1813 }
1814 
1815 /* Routines to extract various sized constants out of hppa
1816    instructions.  */
1817 
1818 /* Extract a 3-bit space register number from a be, ble, mtsp or mfsp.  */
1819 static int
1820 extract_3 (unsigned word)
1821 {
1822   return GET_FIELD (word, 18, 18) << 2 | GET_FIELD (word, 16, 17);
1823 }
1824 
1825 static int
1826 extract_5_load (unsigned word)
1827 {
1828   return low_sign_extend (word >> 16 & MASK_5, 5);
1829 }
1830 
1831 /* Extract the immediate field from a st{bhw}s instruction.  */
1832 
1833 static int
1834 extract_5_store (unsigned word)
1835 {
1836   return low_sign_extend (word & MASK_5, 5);
1837 }
1838 
1839 /* Extract the immediate field from a break instruction.  */
1840 
1841 static unsigned
1842 extract_5r_store (unsigned word)
1843 {
1844   return (word & MASK_5);
1845 }
1846 
1847 /* Extract the immediate field from a {sr}sm instruction.  */
1848 
1849 static unsigned
1850 extract_5R_store (unsigned word)
1851 {
1852   return (word >> 16 & MASK_5);
1853 }
1854 
1855 /* Extract the 10 bit immediate field from a {sr}sm instruction.  */
1856 
1857 static unsigned
1858 extract_10U_store (unsigned word)
1859 {
1860   return (word >> 16 & MASK_10);
1861 }
1862 
1863 /* Extract the immediate field from a bb instruction.  */
1864 
1865 static unsigned
1866 extract_5Q_store (unsigned word)
1867 {
1868   return (word >> 21 & MASK_5);
1869 }
1870 
1871 /* Extract an 11 bit immediate field.  */
1872 
1873 static int
1874 extract_11 (unsigned word)
1875 {
1876   return low_sign_extend (word & MASK_11, 11);
1877 }
1878 
1879 /* Extract a 14 bit immediate field.  */
1880 
1881 static int
1882 extract_14 (unsigned word)
1883 {
1884   return low_sign_extend (word & MASK_14, 14);
1885 }
1886 
1887 /* Extract a 16 bit immediate field (PA2.0 wide only).  */
1888 
1889 static int
1890 extract_16 (unsigned word)
1891 {
1892   int m15, m0, m1;
1893 
1894   m0 = GET_BIT (word, 16);
1895   m1 = GET_BIT (word, 17);
1896   m15 = GET_BIT (word, 31);
1897   word = (word >> 1) & 0x1fff;
1898   word = word | (m15 << 15) | ((m15 ^ m0) << 14) | ((m15 ^ m1) << 13);
1899   return sign_extend (word, 16);
1900 }
1901 
1902 /* Extract a 21 bit constant.  */
1903 
1904 static int
1905 extract_21 (unsigned word)
1906 {
1907   int val;
1908 
1909   word &= MASK_21;
1910   word <<= 11;
1911   val = GET_FIELD (word, 20, 20);
1912   val <<= 11;
1913   val |= GET_FIELD (word, 9, 19);
1914   val <<= 2;
1915   val |= GET_FIELD (word, 5, 6);
1916   val <<= 5;
1917   val |= GET_FIELD (word, 0, 4);
1918   val <<= 2;
1919   val |= GET_FIELD (word, 7, 8);
1920   return sign_extend (val, 21) << 11;
1921 }
1922 
1923 /* Extract a 12 bit constant from branch instructions.  */
1924 
1925 static int
1926 extract_12 (unsigned word)
1927 {
1928   return sign_extend (GET_FIELD (word, 19, 28)
1929 		      | GET_FIELD (word, 29, 29) << 10
1930 		      | (word & 0x1) << 11, 12) << 2;
1931 }
1932 
1933 /* Extract a 17 bit constant from branch instructions, returning the
1934    19 bit signed value.  */
1935 
1936 static int
1937 extract_17 (unsigned word)
1938 {
1939   return sign_extend (GET_FIELD (word, 19, 28)
1940 		      | GET_FIELD (word, 29, 29) << 10
1941 		      | GET_FIELD (word, 11, 15) << 11
1942 		      | (word & 0x1) << 16, 17) << 2;
1943 }
1944 
1945 static int
1946 extract_22 (unsigned word)
1947 {
1948   return sign_extend (GET_FIELD (word, 19, 28)
1949 		      | GET_FIELD (word, 29, 29) << 10
1950 		      | GET_FIELD (word, 11, 15) << 11
1951 		      | GET_FIELD (word, 6, 10) << 16
1952 		      | (word & 0x1) << 21, 22) << 2;
1953 }
1954 
1955 /* Print one instruction.  */
1956 
1957 int
1958 print_insn_hppa (bfd_vma memaddr, disassemble_info *info)
1959 {
1960   bfd_byte buffer[4];
1961   unsigned int insn, i;
1962 
1963   {
1964     int status =
1965       (*info->read_memory_func) (memaddr, buffer, sizeof (buffer), info);
1966     if (status != 0)
1967       {
1968 	(*info->memory_error_func) (status, memaddr, info);
1969 	return -1;
1970       }
1971   }
1972 
1973   insn = bfd_getb32 (buffer);
1974 
1975   if (info->show_opcodes) {
1976       info->fprintf_func(info->stream, " %02x %02x %02x %02x   ",
1977                          (insn >> 24) & 0xff, (insn >> 16) & 0xff,
1978                          (insn >>  8) & 0xff, insn & 0xff);
1979   }
1980 
1981   for (i = 0; i < NUMOPCODES; ++i)
1982     {
1983       const struct pa_opcode *opcode = &pa_opcodes[i];
1984 
1985       if ((insn & opcode->mask) == opcode->match)
1986 	{
1987 	  const char *s;
1988 #ifndef BFD64
1989 	  if (opcode->arch == pa20w)
1990 	    continue;
1991 #endif
1992 	  (*info->fprintf_func) (info->stream, "%s", opcode->name);
1993 
1994 	  if (!strchr ("cfCY?-+nHNZFIuv{", opcode->args[0]))
1995 	    (*info->fprintf_func) (info->stream, " ");
1996 	  for (s = opcode->args; *s != '\0'; ++s)
1997 	    {
1998 	      switch (*s)
1999 		{
2000 		case 'x':
2001 		  fput_reg (GET_FIELD (insn, 11, 15), info);
2002 		  break;
2003 		case 'a':
2004 		case 'b':
2005 		  fput_reg (GET_FIELD (insn, 6, 10), info);
2006 		  break;
2007 		case '^':
2008 		  fput_creg (GET_FIELD (insn, 6, 10), info);
2009 		  break;
2010 		case 't':
2011 		  fput_reg (GET_FIELD (insn, 27, 31), info);
2012 		  break;
2013 
2014 		  /* Handle floating point registers.  */
2015 		case 'f':
2016 		  switch (*++s)
2017 		    {
2018 		    case 't':
2019 		      fput_fp_reg (GET_FIELD (insn, 27, 31), info);
2020 		      break;
2021 		    case 'T':
2022 		      if (GET_FIELD (insn, 25, 25))
2023 			fput_fp_reg_r (GET_FIELD (insn, 27, 31), info);
2024 		      else
2025 			fput_fp_reg (GET_FIELD (insn, 27, 31), info);
2026 		      break;
2027 		    case 'a':
2028 		      if (GET_FIELD (insn, 25, 25))
2029 			fput_fp_reg_r (GET_FIELD (insn, 6, 10), info);
2030 		      else
2031 			fput_fp_reg (GET_FIELD (insn, 6, 10), info);
2032 		      break;
2033 
2034 		      /* 'fA' will not generate a space before the register
2035 			 name.  Normally that is fine.  Except that it
2036 			 causes problems with xmpyu which has no FP format
2037 			 completer.  */
2038 		    case 'X':
2039 		      fputs_filtered (" ", info);
2040 		      /* FALLTHRU */
2041 
2042 		    case 'A':
2043 		      if (GET_FIELD (insn, 24, 24))
2044 			fput_fp_reg_r (GET_FIELD (insn, 6, 10), info);
2045 		      else
2046 			fput_fp_reg (GET_FIELD (insn, 6, 10), info);
2047 		      break;
2048 		    case 'b':
2049 		      if (GET_FIELD (insn, 25, 25))
2050 			fput_fp_reg_r (GET_FIELD (insn, 11, 15), info);
2051 		      else
2052 			fput_fp_reg (GET_FIELD (insn, 11, 15), info);
2053 		      break;
2054 		    case 'B':
2055 		      if (GET_FIELD (insn, 19, 19))
2056 			fput_fp_reg_r (GET_FIELD (insn, 11, 15), info);
2057 		      else
2058 			fput_fp_reg (GET_FIELD (insn, 11, 15), info);
2059 		      break;
2060 		    case 'C':
2061 		      {
2062 			int reg = GET_FIELD (insn, 21, 22);
2063 			reg |= GET_FIELD (insn, 16, 18) << 2;
2064 			if (GET_FIELD (insn, 23, 23) != 0)
2065 			  fput_fp_reg_r (reg, info);
2066 			else
2067 			  fput_fp_reg (reg, info);
2068 			break;
2069 		      }
2070 		    case 'i':
2071 		      {
2072 			int reg = GET_FIELD (insn, 6, 10);
2073 
2074 			reg |= (GET_FIELD (insn, 26, 26) << 4);
2075 			fput_fp_reg (reg, info);
2076 			break;
2077 		      }
2078 		    case 'j':
2079 		      {
2080 			int reg = GET_FIELD (insn, 11, 15);
2081 
2082 			reg |= (GET_FIELD (insn, 26, 26) << 4);
2083 			fput_fp_reg (reg, info);
2084 			break;
2085 		      }
2086 		    case 'k':
2087 		      {
2088 			int reg = GET_FIELD (insn, 27, 31);
2089 
2090 			reg |= (GET_FIELD (insn, 26, 26) << 4);
2091 			fput_fp_reg (reg, info);
2092 			break;
2093 		      }
2094 		    case 'l':
2095 		      {
2096 			int reg = GET_FIELD (insn, 21, 25);
2097 
2098 			reg |= (GET_FIELD (insn, 26, 26) << 4);
2099 			fput_fp_reg (reg, info);
2100 			break;
2101 		      }
2102 		    case 'm':
2103 		      {
2104 			int reg = GET_FIELD (insn, 16, 20);
2105 
2106 			reg |= (GET_FIELD (insn, 26, 26) << 4);
2107 			fput_fp_reg (reg, info);
2108 			break;
2109 		      }
2110 
2111 		      /* 'fe' will not generate a space before the register
2112 			 name.  Normally that is fine.  Except that it
2113 			 causes problems with fstw fe,y(b) which has no FP
2114 			 format completer.  */
2115 		    case 'E':
2116 		      fputs_filtered (" ", info);
2117 		      /* FALLTHRU */
2118 
2119 		    case 'e':
2120 		      if (GET_FIELD (insn, 30, 30))
2121 			fput_fp_reg_r (GET_FIELD (insn, 11, 15), info);
2122 		      else
2123 			fput_fp_reg (GET_FIELD (insn, 11, 15), info);
2124 		      break;
2125 		    case 'x':
2126 		      fput_fp_reg (GET_FIELD (insn, 11, 15), info);
2127 		      break;
2128 		    }
2129 		  break;
2130 
2131 		case '5':
2132 		  fput_const (extract_5_load (insn), info);
2133 		  break;
2134 		case 's':
2135 		  {
2136 		    int space = GET_FIELD (insn, 16, 17);
2137 		    /* Zero means implicit addressing, not use of sr0.  */
2138 		    if (space != 0)
2139 		      (*info->fprintf_func) (info->stream, "sr%d", space);
2140 		  }
2141 		  break;
2142 
2143 		case 'S':
2144 		  (*info->fprintf_func) (info->stream, "sr%d",
2145 					 extract_3 (insn));
2146 		  break;
2147 
2148 		  /* Handle completers.  */
2149 		case 'c':
2150 		  switch (*++s)
2151 		    {
2152 		    case 'x':
2153 		      (*info->fprintf_func)
2154 			(info->stream, "%s",
2155 			 index_compl_names[GET_COMPL (insn)]);
2156 		      break;
2157 		    case 'X':
2158 		      (*info->fprintf_func)
2159 			(info->stream, "%s ",
2160 			 index_compl_names[GET_COMPL (insn)]);
2161 		      break;
2162 		    case 'm':
2163 		      (*info->fprintf_func)
2164 			(info->stream, "%s",
2165 			 short_ldst_compl_names[GET_COMPL (insn)]);
2166 		      break;
2167 		    case 'M':
2168 		      (*info->fprintf_func)
2169 			(info->stream, "%s ",
2170 			 short_ldst_compl_names[GET_COMPL (insn)]);
2171 		      break;
2172 		    case 'A':
2173 		      (*info->fprintf_func)
2174 			(info->stream, "%s ",
2175 			 short_bytes_compl_names[GET_COMPL (insn)]);
2176 		      break;
2177 		    case 's':
2178 		      (*info->fprintf_func)
2179 			(info->stream, "%s",
2180 			 short_bytes_compl_names[GET_COMPL (insn)]);
2181 		      break;
2182 		    case 'c':
2183 		    case 'C':
2184 		      switch (GET_FIELD (insn, 20, 21))
2185 			{
2186 			case 1:
2187 			  (*info->fprintf_func) (info->stream, ",bc ");
2188 			  break;
2189 			case 2:
2190 			  (*info->fprintf_func) (info->stream, ",sl ");
2191 			  break;
2192 			default:
2193 			  (*info->fprintf_func) (info->stream, " ");
2194 			}
2195 		      break;
2196 		    case 'd':
2197 		      switch (GET_FIELD (insn, 20, 21))
2198 			{
2199 			case 1:
2200 			  (*info->fprintf_func) (info->stream, ",co ");
2201 			  break;
2202 			default:
2203 			  (*info->fprintf_func) (info->stream, " ");
2204 			}
2205 		      break;
2206 		    case 'o':
2207 		      (*info->fprintf_func) (info->stream, ",o");
2208 		      break;
2209 		    case 'g':
2210 		      (*info->fprintf_func) (info->stream, ",gate");
2211 		      break;
2212 		    case 'p':
2213 		      (*info->fprintf_func) (info->stream, ",l,push");
2214 		      break;
2215 		    case 'P':
2216 		      (*info->fprintf_func) (info->stream, ",pop");
2217 		      break;
2218 		    case 'l':
2219 		    case 'L':
2220 		      (*info->fprintf_func) (info->stream, ",l");
2221 		      break;
2222 		    case 'w':
2223 		      (*info->fprintf_func)
2224 			(info->stream, "%s ",
2225 			 read_write_names[GET_FIELD (insn, 25, 25)]);
2226 		      break;
2227 		    case 'W':
2228 		      (*info->fprintf_func) (info->stream, ",w ");
2229 		      break;
2230 		    case 'r':
2231 		      if (GET_FIELD (insn, 23, 26) == 5)
2232 			(*info->fprintf_func) (info->stream, ",r");
2233 		      break;
2234 		    case 'Z':
2235 		      if (GET_FIELD (insn, 26, 26))
2236 			(*info->fprintf_func) (info->stream, ",m ");
2237 		      else
2238 			(*info->fprintf_func) (info->stream, " ");
2239 		      break;
2240 		    case 'i':
2241 		      if (GET_FIELD (insn, 25, 25))
2242 			(*info->fprintf_func) (info->stream, ",i");
2243 		      break;
2244 		    case 'z':
2245 		      if (!GET_FIELD (insn, 21, 21))
2246 			(*info->fprintf_func) (info->stream, ",z");
2247 		      break;
2248 		    case 'a':
2249 		      (*info->fprintf_func)
2250 			(info->stream, "%s",
2251 			 add_compl_names[GET_FIELD (insn, 20, 21)]);
2252 		      break;
2253 		    case 'Y':
2254 		      (*info->fprintf_func)
2255 			(info->stream, ",dc%s",
2256 			 add_compl_names[GET_FIELD (insn, 20, 21)]);
2257 		      break;
2258 		    case 'y':
2259 		      (*info->fprintf_func)
2260 			(info->stream, ",c%s",
2261 			 add_compl_names[GET_FIELD (insn, 20, 21)]);
2262 		      break;
2263 		    case 'v':
2264 		      if (GET_FIELD (insn, 20, 20))
2265 			(*info->fprintf_func) (info->stream, ",tsv");
2266 		      break;
2267 		    case 't':
2268 		      (*info->fprintf_func) (info->stream, ",tc");
2269 		      if (GET_FIELD (insn, 20, 20))
2270 			(*info->fprintf_func) (info->stream, ",tsv");
2271 		      break;
2272 		    case 'B':
2273 		      (*info->fprintf_func) (info->stream, ",db");
2274 		      if (GET_FIELD (insn, 20, 20))
2275 			(*info->fprintf_func) (info->stream, ",tsv");
2276 		      break;
2277 		    case 'b':
2278 		      (*info->fprintf_func) (info->stream, ",b");
2279 		      if (GET_FIELD (insn, 20, 20))
2280 			(*info->fprintf_func) (info->stream, ",tsv");
2281 		      break;
2282 		    case 'T':
2283 		      if (GET_FIELD (insn, 25, 25))
2284 			(*info->fprintf_func) (info->stream, ",tc");
2285 		      break;
2286 		    case 'S':
2287 		      /* EXTRD/W has a following condition.  */
2288 		      if (*(s + 1) == '?')
2289 			(*info->fprintf_func)
2290 			  (info->stream, "%s",
2291 			   signed_unsigned_names[GET_FIELD (insn, 21, 21)]);
2292 		      else
2293 			(*info->fprintf_func)
2294 			  (info->stream, "%s ",
2295 			   signed_unsigned_names[GET_FIELD (insn, 21, 21)]);
2296 		      break;
2297 		    case 'h':
2298 		      (*info->fprintf_func)
2299 			(info->stream, "%s",
2300 			 mix_half_names[GET_FIELD (insn, 17, 17)]);
2301 		      break;
2302 		    case 'H':
2303 		      (*info->fprintf_func)
2304 			(info->stream, "%s ",
2305 			 saturation_names[GET_FIELD (insn, 24, 25)]);
2306 		      break;
2307 		    case '*':
2308 		      (*info->fprintf_func)
2309 			(info->stream, ",%d%d%d%d ",
2310 			 GET_FIELD (insn, 17, 18), GET_FIELD (insn, 20, 21),
2311 			 GET_FIELD (insn, 22, 23), GET_FIELD (insn, 24, 25));
2312 		      break;
2313 
2314 		    case 'q':
2315 		      {
2316 			int m, a;
2317 
2318 			m = GET_FIELD (insn, 28, 28);
2319 			a = GET_FIELD (insn, 29, 29);
2320 
2321 			if (m && !a)
2322 			  fputs_filtered (",ma ", info);
2323 			else if (m && a)
2324 			  fputs_filtered (",mb ", info);
2325 			else
2326 			  fputs_filtered (" ", info);
2327 			break;
2328 		      }
2329 
2330 		    case 'J':
2331 		      {
2332 			int opc = GET_FIELD (insn, 0, 5);
2333 
2334 			if (opc == 0x16 || opc == 0x1e)
2335 			  {
2336 			    if (GET_FIELD (insn, 29, 29) == 0)
2337 			      fputs_filtered (",ma ", info);
2338 			    else
2339 			      fputs_filtered (",mb ", info);
2340 			  }
2341 			else
2342 			  fputs_filtered (" ", info);
2343 			break;
2344 		      }
2345 
2346 		    case 'e':
2347 		      {
2348 			int opc = GET_FIELD (insn, 0, 5);
2349 
2350 			if (opc == 0x13 || opc == 0x1b)
2351 			  {
2352 			    if (GET_FIELD (insn, 18, 18) == 1)
2353 			      fputs_filtered (",mb ", info);
2354 			    else
2355 			      fputs_filtered (",ma ", info);
2356 			  }
2357 			else if (opc == 0x17 || opc == 0x1f)
2358 			  {
2359 			    if (GET_FIELD (insn, 31, 31) == 1)
2360 			      fputs_filtered (",ma ", info);
2361 			    else
2362 			      fputs_filtered (",mb ", info);
2363 			  }
2364 			else
2365 			  fputs_filtered (" ", info);
2366 
2367 			break;
2368 		      }
2369 		    }
2370 		  break;
2371 
2372 		  /* Handle conditions.  */
2373 		case '?':
2374 		  {
2375 		    s++;
2376 		    switch (*s)
2377 		      {
2378 		      case 'f':
2379 			(*info->fprintf_func)
2380 			  (info->stream, "%s ",
2381 			   float_comp_names[GET_FIELD (insn, 27, 31)]);
2382 			break;
2383 
2384 			/* These four conditions are for the set of instructions
2385 			   which distinguish true/false conditions by opcode
2386 			   rather than by the 'f' bit (sigh): comb, comib,
2387 			   addb, addib.  */
2388 		      case 't':
2389 			fputs_filtered
2390 			  (compare_cond_names[GET_FIELD (insn, 16, 18)], info);
2391 			break;
2392 		      case 'n':
2393 			fputs_filtered
2394 			  (compare_cond_names[GET_FIELD (insn, 16, 18)
2395 					      + GET_FIELD (insn, 4, 4) * 8],
2396 			   info);
2397 			break;
2398 		      case 'N':
2399 			fputs_filtered
2400 			  (compare_cond_64_names[GET_FIELD (insn, 16, 18)
2401 						 + GET_FIELD (insn, 2, 2) * 8],
2402 			   info);
2403 			break;
2404 		      case 'Q':
2405 			fputs_filtered
2406 			  (cmpib_cond_64_names[GET_FIELD (insn, 16, 18)],
2407 			   info);
2408 			break;
2409 		      case '@':
2410 			fputs_filtered
2411 			  (add_cond_names[GET_FIELD (insn, 16, 18)
2412 					  + GET_FIELD (insn, 4, 4) * 8],
2413 			   info);
2414 			break;
2415 		      case 's':
2416 			(*info->fprintf_func)
2417 			  (info->stream, "%s ",
2418 			   compare_cond_names[GET_COND (insn)]);
2419 			break;
2420 		      case 'S':
2421 			(*info->fprintf_func)
2422 			  (info->stream, "%s ",
2423 			   compare_cond_64_names[GET_COND (insn)]);
2424 			break;
2425 		      case 'a':
2426 			(*info->fprintf_func)
2427 			  (info->stream, "%s ",
2428 			   add_cond_names[GET_COND (insn)]);
2429 			break;
2430 		      case 'A':
2431 			(*info->fprintf_func)
2432 			  (info->stream, "%s ",
2433 			   add_cond_64_names[GET_COND (insn)]);
2434 			break;
2435 		      case 'd':
2436 			(*info->fprintf_func)
2437 			  (info->stream, "%s",
2438 			   add_cond_names[GET_FIELD (insn, 16, 18)]);
2439 			break;
2440 
2441 		      case 'W':
2442 			(*info->fprintf_func)
2443 			  (info->stream, "%s",
2444 			   wide_add_cond_names[GET_FIELD (insn, 16, 18) +
2445 					       GET_FIELD (insn, 4, 4) * 8]);
2446 			break;
2447 
2448 		      case 'l':
2449 			(*info->fprintf_func)
2450 			  (info->stream, "%s ",
2451 			   logical_cond_names[GET_COND (insn)]);
2452 			break;
2453 		      case 'L':
2454 			(*info->fprintf_func)
2455 			  (info->stream, "%s ",
2456 			   logical_cond_64_names[GET_COND (insn)]);
2457 			break;
2458 		      case 'u':
2459 			(*info->fprintf_func)
2460 			  (info->stream, "%s ",
2461 			   unit_cond_names[GET_COND (insn)]);
2462 			break;
2463 		      case 'U':
2464 			(*info->fprintf_func)
2465 			  (info->stream, "%s ",
2466 			   unit_cond_64_names[GET_COND (insn)]);
2467 			break;
2468 		      case 'y':
2469 		      case 'x':
2470 		      case 'b':
2471 			(*info->fprintf_func)
2472 			  (info->stream, "%s",
2473 			   shift_cond_names[GET_FIELD (insn, 16, 18)]);
2474 
2475 			/* If the next character in args is 'n', it will handle
2476 			   putting out the space.  */
2477 			if (s[1] != 'n')
2478 			  (*info->fprintf_func) (info->stream, " ");
2479 			break;
2480 		      case 'X':
2481 			(*info->fprintf_func)
2482 			  (info->stream, "%s ",
2483 			   shift_cond_64_names[GET_FIELD (insn, 16, 18)]);
2484 			break;
2485 		      case 'B':
2486 			(*info->fprintf_func)
2487 			  (info->stream, "%s",
2488 			   bb_cond_64_names[GET_FIELD (insn, 16, 16)]);
2489 
2490 			/* If the next character in args is 'n', it will handle
2491 			   putting out the space.  */
2492 			if (s[1] != 'n')
2493 			  (*info->fprintf_func) (info->stream, " ");
2494 			break;
2495 		      }
2496 		    break;
2497 		  }
2498 
2499 		case 'V':
2500 		  fput_const (extract_5_store (insn), info);
2501 		  break;
2502 		case 'r':
2503 		  fput_const (extract_5r_store (insn), info);
2504 		  break;
2505 		case 'R':
2506 		  fput_const (extract_5R_store (insn), info);
2507 		  break;
2508 		case 'U':
2509 		  fput_const (extract_10U_store (insn), info);
2510 		  break;
2511 		case 'B':
2512 		case 'Q':
2513 		  fput_const (extract_5Q_store (insn), info);
2514 		  break;
2515 		case 'i':
2516 		  fput_const (extract_11 (insn), info);
2517 		  break;
2518 		case 'j':
2519 		  fput_const (extract_14 (insn), info);
2520 		  break;
2521 		case 'k':
2522 		  fputs_filtered ("L%", info);
2523 		  fput_const (extract_21 (insn), info);
2524 		  break;
2525 		case '<':
2526 		case 'l':
2527 		  /* 16-bit long disp., PA2.0 wide only.  */
2528 		  fput_const (extract_16 (insn), info);
2529 		  break;
2530 		case 'n':
2531 		  if (insn & 0x2)
2532 		    (*info->fprintf_func) (info->stream, ",n ");
2533 		  else
2534 		    (*info->fprintf_func) (info->stream, " ");
2535 		  break;
2536 		case 'N':
2537 		  if ((insn & 0x20) && s[1])
2538 		    (*info->fprintf_func) (info->stream, ",n ");
2539 		  else if (insn & 0x20)
2540 		    (*info->fprintf_func) (info->stream, ",n");
2541 		  else if (s[1])
2542 		    (*info->fprintf_func) (info->stream, " ");
2543 		  break;
2544 		case 'w':
2545 		  (*info->print_address_func)
2546 		    (memaddr + 8 + extract_12 (insn), info);
2547 		  break;
2548 		case 'W':
2549 		  /* 17 bit PC-relative branch.  */
2550 		  (*info->print_address_func)
2551 		    ((memaddr + 8 + extract_17 (insn)), info);
2552 		  break;
2553 		case 'z':
2554 		  /* 17 bit displacement.  This is an offset from a register
2555 		     so it gets disasssembled as just a number, not any sort
2556 		     of address.  */
2557 		  fput_const (extract_17 (insn), info);
2558 		  break;
2559 
2560 		case 'Z':
2561 		  /* addil %r1 implicit output.  */
2562 		  fputs_filtered ("r1", info);
2563 		  break;
2564 
2565 		case 'Y':
2566 		  /* be,l %sr0,%r31 implicit output.  */
2567 		  fputs_filtered ("sr0,r31", info);
2568 		  break;
2569 
2570 		case '@':
2571 		  (*info->fprintf_func) (info->stream, "0");
2572 		  break;
2573 
2574 		case '.':
2575 		  (*info->fprintf_func) (info->stream, "%d",
2576 					 GET_FIELD (insn, 24, 25));
2577 		  break;
2578 		case '*':
2579 		  (*info->fprintf_func) (info->stream, "%d",
2580 					 GET_FIELD (insn, 22, 25));
2581 		  break;
2582 		case '!':
2583 		  fputs_filtered ("sar", info);
2584 		  break;
2585 		case 'p':
2586 		  (*info->fprintf_func) (info->stream, "%d",
2587 					 31 - GET_FIELD (insn, 22, 26));
2588 		  break;
2589 		case '~':
2590 		  {
2591 		    int num;
2592 		    num = GET_FIELD (insn, 20, 20) << 5;
2593 		    num |= GET_FIELD (insn, 22, 26);
2594 		    (*info->fprintf_func) (info->stream, "%d", 63 - num);
2595 		    break;
2596 		  }
2597 		case 'P':
2598 		  (*info->fprintf_func) (info->stream, "%d",
2599 					 GET_FIELD (insn, 22, 26));
2600 		  break;
2601 		case 'q':
2602 		  {
2603 		    int num;
2604 		    num = GET_FIELD (insn, 20, 20) << 5;
2605 		    num |= GET_FIELD (insn, 22, 26);
2606 		    (*info->fprintf_func) (info->stream, "%d", num);
2607 		    break;
2608 		  }
2609 		case 'T':
2610 		  (*info->fprintf_func) (info->stream, "%d",
2611 					 32 - GET_FIELD (insn, 27, 31));
2612 		  break;
2613 		case '%':
2614 		  {
2615 		    int num;
2616 		    num = (GET_FIELD (insn, 23, 23) + 1) * 32;
2617 		    num -= GET_FIELD (insn, 27, 31);
2618 		    (*info->fprintf_func) (info->stream, "%d", num);
2619 		    break;
2620 		  }
2621 		case '|':
2622 		  {
2623 		    int num;
2624 		    num = (GET_FIELD (insn, 19, 19) + 1) * 32;
2625 		    num -= GET_FIELD (insn, 27, 31);
2626 		    (*info->fprintf_func) (info->stream, "%d", num);
2627 		    break;
2628 		  }
2629 		case '$':
2630 		  fput_const (GET_FIELD (insn, 20, 28), info);
2631 		  break;
2632 		case 'A':
2633 		  fput_const (GET_FIELD (insn, 6, 18), info);
2634 		  break;
2635 		case 'D':
2636 		  fput_const (GET_FIELD (insn, 6, 31), info);
2637 		  break;
2638 		case 'v':
2639 		  (*info->fprintf_func) (info->stream, ",%d",
2640 					 GET_FIELD (insn, 23, 25));
2641 		  break;
2642 		case 'O':
2643 		  fput_const ((GET_FIELD (insn, 6,20) << 5 |
2644 			       GET_FIELD (insn, 27, 31)), info);
2645 		  break;
2646 		case 'o':
2647 		  fput_const (GET_FIELD (insn, 6, 20), info);
2648 		  break;
2649 		case '2':
2650 		  fput_const ((GET_FIELD (insn, 6, 22) << 5 |
2651 			       GET_FIELD (insn, 27, 31)), info);
2652 		  break;
2653 		case '1':
2654 		  fput_const ((GET_FIELD (insn, 11, 20) << 5 |
2655 			       GET_FIELD (insn, 27, 31)), info);
2656 		  break;
2657 		case '0':
2658 		  fput_const ((GET_FIELD (insn, 16, 20) << 5 |
2659 			       GET_FIELD (insn, 27, 31)), info);
2660 		  break;
2661 		case 'u':
2662 		  (*info->fprintf_func) (info->stream, ",%d",
2663 					 GET_FIELD (insn, 23, 25));
2664 		  break;
2665 		case 'F':
2666 		  /* If no destination completer and not before a completer
2667 		     for fcmp, need a space here.  */
2668 		  if (s[1] == 'G' || s[1] == '?')
2669 		    fputs_filtered
2670 		      (float_format_names[GET_FIELD (insn, 19, 20)], info);
2671 		  else
2672 		    (*info->fprintf_func)
2673 		      (info->stream, "%s ",
2674 		       float_format_names[GET_FIELD (insn, 19, 20)]);
2675 		  break;
2676 		case 'G':
2677 		  (*info->fprintf_func)
2678 		    (info->stream, "%s ",
2679 		     float_format_names[GET_FIELD (insn, 17, 18)]);
2680 		  break;
2681 		case 'H':
2682 		  if (GET_FIELD (insn, 26, 26) == 1)
2683 		    (*info->fprintf_func) (info->stream, "%s ",
2684 					   float_format_names[0]);
2685 		  else
2686 		    (*info->fprintf_func) (info->stream, "%s ",
2687 					   float_format_names[1]);
2688 		  break;
2689 		case 'I':
2690 		  /* If no destination completer and not before a completer
2691 		     for fcmp, need a space here.  */
2692 		  if (s[1] == '?')
2693 		    fputs_filtered
2694 		      (float_format_names[GET_FIELD (insn, 20, 20)], info);
2695 		  else
2696 		    (*info->fprintf_func)
2697 		      (info->stream, "%s ",
2698 		       float_format_names[GET_FIELD (insn, 20, 20)]);
2699 		  break;
2700 
2701 		case 'J':
2702 		  fput_const (extract_14 (insn), info);
2703 		  break;
2704 
2705 		case '#':
2706 		  {
2707 		    int sign = GET_FIELD (insn, 31, 31);
2708 		    int imm10 = GET_FIELD (insn, 18, 27);
2709 		    int disp;
2710 
2711 		    if (sign)
2712 		      disp = (-1 << 10) | imm10;
2713 		    else
2714 		      disp = imm10;
2715 
2716 		    disp <<= 3;
2717 		    fput_const (disp, info);
2718 		    break;
2719 		  }
2720 		case 'K':
2721 		case 'd':
2722 		  {
2723 		    int sign = GET_FIELD (insn, 31, 31);
2724 		    int imm11 = GET_FIELD (insn, 18, 28);
2725 		    int disp;
2726 
2727 		    if (sign)
2728 		      disp = (-1 << 11) | imm11;
2729 		    else
2730 		      disp = imm11;
2731 
2732 		    disp <<= 2;
2733 		    fput_const (disp, info);
2734 		    break;
2735 		  }
2736 
2737 		case '>':
2738 		case 'y':
2739 		  {
2740 		    /* 16-bit long disp., PA2.0 wide only.  */
2741 		    int disp = extract_16 (insn);
2742 		    disp &= ~3;
2743 		    fput_const (disp, info);
2744 		    break;
2745 		  }
2746 
2747 		case '&':
2748 		  {
2749 		    /* 16-bit long disp., PA2.0 wide only.  */
2750 		    int disp = extract_16 (insn);
2751 		    disp &= ~7;
2752 		    fput_const (disp, info);
2753 		    break;
2754 		  }
2755 
2756 		case '_':
2757 		  break; /* Dealt with by '{' */
2758 
2759 		case '{':
2760 		  {
2761 		    int sub = GET_FIELD (insn, 14, 16);
2762 		    int df = GET_FIELD (insn, 17, 18);
2763 		    int sf = GET_FIELD (insn, 19, 20);
2764 		    const char * const * source = float_format_names;
2765 		    const char * const * dest = float_format_names;
2766 		    const char *t = "";
2767 
2768 		    if (sub == 4)
2769 		      {
2770 			fputs_filtered (",UND ", info);
2771 			break;
2772 		      }
2773 		    if ((sub & 3) == 3)
2774 		      t = ",t";
2775 		    if ((sub & 3) == 1)
2776 		      source = sub & 4 ? fcnv_ufixed_names : fcnv_fixed_names;
2777 		    if (sub & 2)
2778 		      dest = sub & 4 ? fcnv_ufixed_names : fcnv_fixed_names;
2779 
2780 		    (*info->fprintf_func) (info->stream, "%s%s%s ",
2781 					   t, source[sf], dest[df]);
2782 		    break;
2783 		  }
2784 
2785 		case 'm':
2786 		  {
2787 		    int y = GET_FIELD (insn, 16, 18);
2788 
2789 		    if (y != 1)
2790 		      fput_const ((y ^ 1) - 1, info);
2791 		  }
2792 		  break;
2793 
2794 		case 'h':
2795 		  {
2796 		    int cbit;
2797 
2798 		    cbit = GET_FIELD (insn, 16, 18);
2799 
2800 		    if (cbit > 0)
2801 		      (*info->fprintf_func) (info->stream, ",%d", cbit - 1);
2802 		    break;
2803 		  }
2804 
2805 		case '=':
2806 		  {
2807 		    int cond = GET_FIELD (insn, 27, 31);
2808 
2809 		    switch (cond)
2810 		      {
2811 		      case  0: fputs_filtered (" ", info); break;
2812 		      case  1: fputs_filtered ("acc ", info); break;
2813 		      case  2: fputs_filtered ("rej ", info); break;
2814 		      case  5: fputs_filtered ("acc8 ", info); break;
2815 		      case  6: fputs_filtered ("rej8 ", info); break;
2816 		      case  9: fputs_filtered ("acc6 ", info); break;
2817 		      case 13: fputs_filtered ("acc4 ", info); break;
2818 		      case 17: fputs_filtered ("acc2 ", info); break;
2819 		      default: break;
2820 		      }
2821 		    break;
2822 		  }
2823 
2824 		case 'X':
2825 		  (*info->print_address_func)
2826 		    (memaddr + 8 + extract_22 (insn), info);
2827 		  break;
2828 		case 'L':
2829 		  fputs_filtered (",rp", info);
2830 		  break;
2831 		default:
2832 		  (*info->fprintf_func) (info->stream, "%c", *s);
2833 		  break;
2834 		}
2835 	    }
2836 	  return sizeof (insn);
2837 	}
2838     }
2839   info->fprintf_func(info->stream, "<unknown>");
2840   return sizeof (insn);
2841 }
2842