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[/] [openrisc/] [trunk/] [gnu-stable/] [binutils-2.20.1/] [opcodes/] [tic80-opc.c] - Blame information for rev 843

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/* Opcode table for TI TMS320C80 (MVP).
2
   Copyright 1996, 1997, 2000, 2005, 2007 Free Software Foundation, Inc.
3
 
4
   This file is part of the GNU opcodes library.
5
 
6
   This library is free software; you can redistribute it and/or modify
7
   it under the terms of the GNU General Public License as published by
8
   the Free Software Foundation; either version 3, or (at your option)
9
   any later version.
10
 
11
   It is distributed in the hope that it will be useful, but WITHOUT
12
   ANY WARRANTY; without even the implied warranty of MERCHANTABILITY
13
   or FITNESS FOR A PARTICULAR PURPOSE.  See the GNU General Public
14
   License for more details.
15
 
16
   You should have received a copy of the GNU General Public License
17
   along with this file; see the file COPYING.  If not, write to the
18
   Free Software Foundation, 51 Franklin Street - Fifth Floor, Boston,
19
   MA 02110-1301, USA.  */
20
 
21
#include <stdio.h>
22
#include "sysdep.h"
23
#include "opcode/tic80.h"
24
 
25
/* This file holds various tables for the TMS320C80 (MVP).
26
 
27
   The opcode table is strictly constant data, so the compiler should
28
   be able to put it in the .text section.
29
 
30
   This file also holds the operand table.  All knowledge about
31
   inserting operands into instructions and vice-versa is kept in this
32
   file.
33
 
34
   The predefined register table maps from register names to register
35
   values.  */
36
 
37
 
38
/* Table of predefined symbol names, such as general purpose registers,
39
   floating point registers, condition codes, control registers, and bit
40
   numbers.
41
 
42
   The table is sorted case independently by name so that it is suitable for
43
   searching via a binary search using a case independent comparison
44
   function.
45
 
46
   Note that the type of the symbol is stored in the upper bits of the value
47
   field, which allows the value and type to be passed around as a unit in a
48
   single int.  The types have to be masked off before using the numeric
49
   value as a number.
50
*/
51
 
52
const struct predefined_symbol tic80_predefined_symbols[] =
53
{
54
  { "a0",       TIC80_OPERAND_FPA | 0 },
55
  { "a1",       TIC80_OPERAND_FPA | 1 },
56
  { "alw.b",    TIC80_OPERAND_CC | 7 },
57
  { "alw.h",    TIC80_OPERAND_CC | 15 },
58
  { "alw.w",    TIC80_OPERAND_CC | 23 },
59
  { "ANASTAT",  TIC80_OPERAND_CR | 0x34 },
60
  { "BRK1",     TIC80_OPERAND_CR | 0x39 },
61
  { "BRK2",     TIC80_OPERAND_CR | 0x3A },
62
  { "CONFIG",   TIC80_OPERAND_CR | 2 },
63
  { "DLRU",     TIC80_OPERAND_CR | 0x500 },
64
  { "DTAG0",    TIC80_OPERAND_CR | 0x400 },
65
  { "DTAG1",    TIC80_OPERAND_CR | 0x401 },
66
  { "DTAG10",   TIC80_OPERAND_CR | 0x40A },
67
  { "DTAG11",   TIC80_OPERAND_CR | 0x40B },
68
  { "DTAG12",   TIC80_OPERAND_CR | 0x40C },
69
  { "DTAG13",   TIC80_OPERAND_CR | 0x40D },
70
  { "DTAG14",   TIC80_OPERAND_CR | 0x40E },
71
  { "DTAG15",   TIC80_OPERAND_CR | 0x40F },
72
  { "DTAG2",    TIC80_OPERAND_CR | 0x402 },
73
  { "DTAG3",    TIC80_OPERAND_CR | 0x403 },
74
  { "DTAG4",    TIC80_OPERAND_CR | 0x404 },
75
  { "DTAG5",    TIC80_OPERAND_CR | 0x405 },
76
  { "DTAG6",    TIC80_OPERAND_CR | 0x406 },
77
  { "DTAG7",    TIC80_OPERAND_CR | 0x407 },
78
  { "DTAG8",    TIC80_OPERAND_CR | 0x408 },
79
  { "DTAG9",    TIC80_OPERAND_CR | 0x409 },
80
  { "ECOMCNTL", TIC80_OPERAND_CR | 0x33 },
81
  { "EIP",      TIC80_OPERAND_CR | 1 },
82
  { "EPC",      TIC80_OPERAND_CR | 0 },
83
  { "eq.b",     TIC80_OPERAND_BITNUM  | 0 },
84
  { "eq.f",     TIC80_OPERAND_BITNUM  | 20 },
85
  { "eq.h",     TIC80_OPERAND_BITNUM  | 10 },
86
  { "eq.w",     TIC80_OPERAND_BITNUM  | 20 },
87
  { "eq0.b",    TIC80_OPERAND_CC | 2 },
88
  { "eq0.h",    TIC80_OPERAND_CC | 10 },
89
  { "eq0.w",    TIC80_OPERAND_CC | 18 },
90
  { "FLTADR",   TIC80_OPERAND_CR | 0x11 },
91
  { "FLTDTH",   TIC80_OPERAND_CR | 0x14 },
92
  { "FLTDTL",   TIC80_OPERAND_CR | 0x13 },
93
  { "FLTOP",    TIC80_OPERAND_CR | 0x10 },
94
  { "FLTTAG",   TIC80_OPERAND_CR | 0x12 },
95
  { "FPST",     TIC80_OPERAND_CR | 8 },
96
  { "ge.b",     TIC80_OPERAND_BITNUM  | 5 },
97
  { "ge.f",     TIC80_OPERAND_BITNUM  | 25 },
98
  { "ge.h",     TIC80_OPERAND_BITNUM  | 15 },
99
  { "ge.w",     TIC80_OPERAND_BITNUM  | 25 },
100
  { "ge0.b",    TIC80_OPERAND_CC | 3 },
101
  { "ge0.h",    TIC80_OPERAND_CC | 11 },
102
  { "ge0.w",    TIC80_OPERAND_CC | 19 },
103
  { "gt.b",     TIC80_OPERAND_BITNUM  | 2 },
104
  { "gt.f",     TIC80_OPERAND_BITNUM  | 22 },
105
  { "gt.h",     TIC80_OPERAND_BITNUM  | 12 },
106
  { "gt.w",     TIC80_OPERAND_BITNUM  | 22 },
107
  { "gt0.b",    TIC80_OPERAND_CC | 1 },
108
  { "gt0.h",    TIC80_OPERAND_CC | 9 },
109
  { "gt0.w",    TIC80_OPERAND_CC | 17 },
110
  { "hi.b",     TIC80_OPERAND_BITNUM  | 6 },
111
  { "hi.h",     TIC80_OPERAND_BITNUM  | 16 },
112
  { "hi.w",     TIC80_OPERAND_BITNUM  | 26 },
113
  { "hs.b",     TIC80_OPERAND_BITNUM  | 9 },
114
  { "hs.h",     TIC80_OPERAND_BITNUM  | 19 },
115
  { "hs.w",     TIC80_OPERAND_BITNUM  | 29 },
116
  { "ib.f",     TIC80_OPERAND_BITNUM  | 28 },
117
  { "IE",       TIC80_OPERAND_CR | 6 },
118
  { "ILRU",     TIC80_OPERAND_CR | 0x300 },
119
  { "in.f",     TIC80_OPERAND_BITNUM  | 27 },
120
  { "IN0P",     TIC80_OPERAND_CR | 0x4000 },
121
  { "IN1P",     TIC80_OPERAND_CR | 0x4001 },
122
  { "INTPEN",   TIC80_OPERAND_CR | 4 },
123
  { "ITAG0",    TIC80_OPERAND_CR | 0x200 },
124
  { "ITAG1",    TIC80_OPERAND_CR | 0x201 },
125
  { "ITAG10",   TIC80_OPERAND_CR | 0x20A },
126
  { "ITAG11",   TIC80_OPERAND_CR | 0x20B },
127
  { "ITAG12",   TIC80_OPERAND_CR | 0x20C },
128
  { "ITAG13",   TIC80_OPERAND_CR | 0x20D },
129
  { "ITAG14",   TIC80_OPERAND_CR | 0x20E },
130
  { "ITAG15",   TIC80_OPERAND_CR | 0x20F },
131
  { "ITAG2",    TIC80_OPERAND_CR | 0x202 },
132
  { "ITAG3",    TIC80_OPERAND_CR | 0x203 },
133
  { "ITAG4",    TIC80_OPERAND_CR | 0x204 },
134
  { "ITAG5",    TIC80_OPERAND_CR | 0x205 },
135
  { "ITAG6",    TIC80_OPERAND_CR | 0x206 },
136
  { "ITAG7",    TIC80_OPERAND_CR | 0x207 },
137
  { "ITAG8",    TIC80_OPERAND_CR | 0x208 },
138
  { "ITAG9",    TIC80_OPERAND_CR | 0x209 },
139
  { "le.b",     TIC80_OPERAND_BITNUM  | 3 },
140
  { "le.f",     TIC80_OPERAND_BITNUM  | 23 },
141
  { "le.h",     TIC80_OPERAND_BITNUM  | 13 },
142
  { "le.w",     TIC80_OPERAND_BITNUM  | 23 },
143
  { "le0.b",    TIC80_OPERAND_CC | 6 },
144
  { "le0.h",    TIC80_OPERAND_CC | 14 },
145
  { "le0.w",    TIC80_OPERAND_CC | 22 },
146
  { "lo.b",     TIC80_OPERAND_BITNUM  | 8 },
147
  { "lo.h",     TIC80_OPERAND_BITNUM  | 18 },
148
  { "lo.w",     TIC80_OPERAND_BITNUM  | 28 },
149
  { "ls.b",     TIC80_OPERAND_BITNUM  | 7 },
150
  { "ls.h",     TIC80_OPERAND_BITNUM  | 17 },
151
  { "ls.w",     TIC80_OPERAND_BITNUM  | 27 },
152
  { "lt.b",     TIC80_OPERAND_BITNUM  | 4 },
153
  { "lt.f",     TIC80_OPERAND_BITNUM  | 24 },
154
  { "lt.h",     TIC80_OPERAND_BITNUM  | 14 },
155
  { "lt.w",     TIC80_OPERAND_BITNUM  | 24 },
156
  { "lt0.b",    TIC80_OPERAND_CC | 4 },
157
  { "lt0.h",    TIC80_OPERAND_CC | 12 },
158
  { "lt0.w",    TIC80_OPERAND_CC | 20 },
159
  { "MIP",      TIC80_OPERAND_CR | 0x31 },
160
  { "MPC",      TIC80_OPERAND_CR | 0x30 },
161
  { "ne.b",     TIC80_OPERAND_BITNUM  | 1 },
162
  { "ne.f",     TIC80_OPERAND_BITNUM  | 21 },
163
  { "ne.h",     TIC80_OPERAND_BITNUM  | 11 },
164
  { "ne.w",     TIC80_OPERAND_BITNUM  | 21 },
165
  { "ne0.b",    TIC80_OPERAND_CC | 5 },
166
  { "ne0.h",    TIC80_OPERAND_CC | 13 },
167
  { "ne0.w",    TIC80_OPERAND_CC | 21 },
168
  { "nev.b",    TIC80_OPERAND_CC | 0 },
169
  { "nev.h",    TIC80_OPERAND_CC | 8 },
170
  { "nev.w",    TIC80_OPERAND_CC | 16 },
171
  { "ob.f",     TIC80_OPERAND_BITNUM  | 29 },
172
  { "or.f",     TIC80_OPERAND_BITNUM  | 31 },
173
  { "ou.f",     TIC80_OPERAND_BITNUM  | 26 },
174
  { "OUTP",     TIC80_OPERAND_CR | 0x4002 },
175
  { "PKTREQ",   TIC80_OPERAND_CR | 0xD },
176
  { "PPERROR",  TIC80_OPERAND_CR | 0xA },
177
  { "r0",       TIC80_OPERAND_GPR | 0 },
178
  { "r1",       TIC80_OPERAND_GPR | 1 },
179
  { "r10",      TIC80_OPERAND_GPR | 10 },
180
  { "r11",      TIC80_OPERAND_GPR | 11 },
181
  { "r12",      TIC80_OPERAND_GPR | 12 },
182
  { "r13",      TIC80_OPERAND_GPR | 13 },
183
  { "r14",      TIC80_OPERAND_GPR | 14 },
184
  { "r15",      TIC80_OPERAND_GPR | 15 },
185
  { "r16",      TIC80_OPERAND_GPR | 16 },
186
  { "r17",      TIC80_OPERAND_GPR | 17 },
187
  { "r18",      TIC80_OPERAND_GPR | 18 },
188
  { "r19",      TIC80_OPERAND_GPR | 19 },
189
  { "r2",       TIC80_OPERAND_GPR | 2 },
190
  { "r20",      TIC80_OPERAND_GPR | 20 },
191
  { "r21",      TIC80_OPERAND_GPR | 21 },
192
  { "r22",      TIC80_OPERAND_GPR | 22 },
193
  { "r23",      TIC80_OPERAND_GPR | 23 },
194
  { "r24",      TIC80_OPERAND_GPR | 24 },
195
  { "r25",      TIC80_OPERAND_GPR | 25 },
196
  { "r26",      TIC80_OPERAND_GPR | 26 },
197
  { "r27",      TIC80_OPERAND_GPR | 27 },
198
  { "r28",      TIC80_OPERAND_GPR | 28 },
199
  { "r29",      TIC80_OPERAND_GPR | 29 },
200
  { "r3",       TIC80_OPERAND_GPR | 3 },
201
  { "r30",      TIC80_OPERAND_GPR | 30 },
202
  { "r31",      TIC80_OPERAND_GPR | 31 },
203
  { "r4",       TIC80_OPERAND_GPR | 4 },
204
  { "r5",       TIC80_OPERAND_GPR | 5 },
205
  { "r6",       TIC80_OPERAND_GPR | 6 },
206
  { "r7",       TIC80_OPERAND_GPR | 7 },
207
  { "r8",       TIC80_OPERAND_GPR | 8 },
208
  { "r9",       TIC80_OPERAND_GPR | 9 },
209
  { "SYSSTK",   TIC80_OPERAND_CR | 0x20 },
210
  { "SYSTMP",   TIC80_OPERAND_CR | 0x21 },
211
  { "TCOUNT",   TIC80_OPERAND_CR | 0xE },
212
  { "TSCALE",   TIC80_OPERAND_CR | 0xF },
213
  { "uo.f",     TIC80_OPERAND_BITNUM  | 30 },
214
};
215
 
216
const int tic80_num_predefined_symbols = sizeof (tic80_predefined_symbols) / sizeof (struct predefined_symbol);
217
 
218
/* This function takes a predefined symbol name in NAME, symbol class
219
   in CLASS, and translates it to a numeric value, which it returns.
220
 
221
   If CLASS is zero, any symbol that matches NAME is translated.  If
222
   CLASS is non-zero, then only a symbol that has symbol_class CLASS is
223
   matched.
224
 
225
   If no translation is possible, it returns -1, a value not used by
226
   any predefined symbol. Note that the predefined symbol array is
227
   presorted case independently by name.
228
 
229
   This function is implemented with the assumption that there are no
230
   duplicate names in the predefined symbol array, which happens to be
231
   true at the moment.
232
 
233
 */
234
 
235
int
236
tic80_symbol_to_value (name, symbol_class)
237
     char *name;
238
     int symbol_class;
239
{
240
  const struct predefined_symbol *pdsp;
241
  int low = 0;
242
  int middle;
243
  int high = tic80_num_predefined_symbols - 1;
244
  int cmp;
245
  int rtnval = -1;
246
 
247
  while (low <= high)
248
    {
249
      middle = (low + high) / 2;
250
      cmp = strcasecmp (name, tic80_predefined_symbols[middle].name);
251
      if (cmp < 0)
252
        {
253
          high = middle - 1;
254
        }
255
      else if (cmp > 0)
256
        {
257
          low = middle + 1;
258
        }
259
      else
260
        {
261
          pdsp = &tic80_predefined_symbols[middle];
262
          if ((symbol_class == 0) || (symbol_class & PDS_VALUE (pdsp)))
263
            {
264
              rtnval = PDS_VALUE (pdsp);
265
            }
266
          /* For now we assume that there are no duplicate names */
267
          break;
268
        }
269
    }
270
  return (rtnval);
271
}
272
 
273
/* This function takes a value VAL and finds a matching predefined
274
   symbol that is in the operand symbol_class specified by CLASS.  If CLASS
275
   is zero, the first matching symbol is returned. */
276
 
277
const char *
278
tic80_value_to_symbol (val, symbol_class)
279
     int val;
280
     int symbol_class;
281
{
282
  const struct predefined_symbol *pdsp;
283
  int ival;
284
  char *name;
285
 
286
  name = NULL;
287
  for (pdsp = tic80_predefined_symbols;
288
       pdsp < tic80_predefined_symbols + tic80_num_predefined_symbols;
289
       pdsp++)
290
    {
291
      ival = PDS_VALUE (pdsp) & ~TIC80_OPERAND_MASK;
292
      if (ival == val)
293
        {
294
          if ((symbol_class == 0) || (symbol_class & PDS_VALUE (pdsp)))
295
            {
296
              /* Found the desired match */
297
              name = PDS_NAME (pdsp);
298
              break;
299
            }
300
        }
301
    }
302
  return (name);
303
}
304
 
305
/* This function returns a pointer to the next symbol in the predefined
306
   symbol table after PDSP, or NULL if PDSP points to the last symbol.  If
307
   PDSP is NULL, it returns the first symbol in the table.  Thus it can be
308
   used to walk through the table by first calling it with NULL and then
309
   calling it with each value it returned on the previous call, until it
310
   returns NULL. */
311
 
312
const struct predefined_symbol *
313
tic80_next_predefined_symbol (pdsp)
314
     const struct predefined_symbol *pdsp;
315
{
316
  if (pdsp == NULL)
317
    {
318
      pdsp = tic80_predefined_symbols;
319
    }
320
  else if (pdsp >= tic80_predefined_symbols &&
321
           pdsp < tic80_predefined_symbols + tic80_num_predefined_symbols - 1)
322
    {
323
      pdsp++;
324
    }
325
  else
326
    {
327
      pdsp = NULL;
328
    }
329
  return (pdsp);
330
}
331
 
332
 
333
 
334
/* The operands table.  The fields are:
335
 
336
        bits, shift, insertion function, extraction function, flags
337
 */
338
 
339
const struct tic80_operand tic80_operands[] =
340
{
341
 
342
  /* The zero index is used to indicate the end of the list of operands.  */
343
 
344
#define UNUSED (0)
345
  { 0, 0, 0, 0, 0 },
346
 
347
  /* Short signed immediate value in bits 14-0. */
348
 
349
#define SSI (UNUSED + 1)
350
  { 15, 0, NULL, NULL, TIC80_OPERAND_SIGNED },
351
 
352
  /* Short unsigned immediate value in bits 14-0 */
353
 
354
#define SUI (SSI + 1)
355
  { 15, 0, NULL, NULL, 0 },
356
 
357
  /* Short unsigned bitfield in bits 14-0.  We distinguish this
358
     from a regular unsigned immediate value only for the convenience
359
     of the disassembler and the user. */
360
 
361
#define SUBF (SUI + 1)
362
  { 15, 0, NULL, NULL, TIC80_OPERAND_BITFIELD },
363
 
364
  /* Long signed immediate in following 32 bit word */
365
 
366
#define LSI (SUBF + 1)
367
  { 32, 0, NULL, NULL, TIC80_OPERAND_SIGNED },
368
 
369
  /* Long unsigned immediate in following 32 bit word */
370
 
371
#define LUI (LSI + 1)
372
  { 32, 0, NULL, NULL, 0 },
373
 
374
  /* Long unsigned bitfield in following 32 bit word.  We distinguish
375
     this from a regular unsigned immediate value only for the
376
     convenience of the disassembler and the user. */
377
 
378
#define LUBF (LUI + 1)
379
  { 32, 0, NULL, NULL, TIC80_OPERAND_BITFIELD },
380
 
381
  /* Single precision floating point immediate in following 32 bit
382
     word. */
383
 
384
#define SPFI (LUBF + 1)
385
  { 32, 0, NULL, NULL, TIC80_OPERAND_FLOAT },
386
 
387
  /* Register in bits 4-0 */
388
 
389
#define REG_0 (SPFI + 1)
390
  { 5, 0, NULL, NULL, TIC80_OPERAND_GPR },
391
 
392
  /* Even register in bits 4-0 */
393
 
394
#define REG_0_E (REG_0 + 1)
395
  { 5, 0, NULL, NULL, TIC80_OPERAND_GPR | TIC80_OPERAND_EVEN },
396
 
397
  /* Register in bits 26-22 */
398
 
399
#define REG_22 (REG_0_E + 1)
400
  { 5, 22, NULL, NULL, TIC80_OPERAND_GPR },
401
 
402
  /* Even register in bits 26-22 */
403
 
404
#define REG_22_E (REG_22 + 1)
405
  { 5, 22, NULL, NULL, TIC80_OPERAND_GPR | TIC80_OPERAND_EVEN },
406
 
407
  /* Register in bits 31-27 */
408
 
409
#define REG_DEST (REG_22_E + 1)
410
  { 5, 27, NULL, NULL, TIC80_OPERAND_GPR },
411
 
412
  /* Even register in bits 31-27 */
413
 
414
#define REG_DEST_E (REG_DEST + 1)
415
  { 5, 27, NULL, NULL, TIC80_OPERAND_GPR | TIC80_OPERAND_EVEN },
416
 
417
  /* Floating point accumulator register (a0-a3) specified by bit 16 (MSB)
418
     and bit 11 (LSB) */
419
  /* FIXME!  Needs to use functions to insert and extract the register
420
     number in bits 16 and 11. */
421
 
422
#define REG_FPA (REG_DEST_E + 1)
423
  { 0, 0, NULL, NULL, TIC80_OPERAND_FPA },
424
 
425
  /* Short signed PC word offset in bits 14-0 */
426
 
427
#define OFF_SS_PC (REG_FPA + 1)
428
  { 15, 0, NULL, NULL, TIC80_OPERAND_PCREL | TIC80_OPERAND_SIGNED },
429
 
430
  /* Long signed PC word offset in following 32 bit word */
431
 
432
#define OFF_SL_PC (OFF_SS_PC + 1)
433
  { 32, 0, NULL, NULL, TIC80_OPERAND_PCREL | TIC80_OPERAND_SIGNED },
434
 
435
  /* Short signed base relative byte offset in bits 14-0 */
436
 
437
#define OFF_SS_BR (OFF_SL_PC + 1)
438
  { 15, 0, NULL, NULL, TIC80_OPERAND_BASEREL | TIC80_OPERAND_SIGNED },
439
 
440
  /* Long signed base relative byte offset in following 32 bit word */
441
 
442
#define OFF_SL_BR (OFF_SS_BR + 1)
443
  { 32, 0, NULL, NULL, TIC80_OPERAND_BASEREL | TIC80_OPERAND_SIGNED },
444
 
445
  /* Long signed base relative byte offset in following 32 bit word
446
     with optional ":s" modifier flag in bit 11 */
447
 
448
#define OFF_SL_BR_SCALED (OFF_SL_BR + 1)
449
  { 32, 0, NULL, NULL, TIC80_OPERAND_BASEREL | TIC80_OPERAND_SIGNED | TIC80_OPERAND_SCALED },
450
 
451
  /* BITNUM in bits 31-27 */
452
 
453
#define BITNUM (OFF_SL_BR_SCALED + 1)
454
  { 5, 27, NULL, NULL, TIC80_OPERAND_BITNUM },
455
 
456
  /* Condition code in bits 31-27 */
457
 
458
#define CC (BITNUM + 1)
459
  { 5, 27, NULL, NULL, TIC80_OPERAND_CC },
460
 
461
  /* Control register number in bits 14-0 */
462
 
463
#define CR_SI (CC + 1)
464
  { 15, 0, NULL, NULL, TIC80_OPERAND_CR },
465
 
466
  /* Control register number in next 32 bit word */
467
 
468
#define CR_LI (CR_SI + 1)
469
  { 32, 0, NULL, NULL, TIC80_OPERAND_CR },
470
 
471
  /* A base register in bits 26-22, enclosed in parens */
472
 
473
#define REG_BASE (CR_LI + 1)
474
  { 5, 22, NULL, NULL, TIC80_OPERAND_GPR | TIC80_OPERAND_PARENS },
475
 
476
  /* A base register in bits 26-22, enclosed in parens, with optional ":m"
477
     flag in bit 17 (short immediate instructions only) */
478
 
479
#define REG_BASE_M_SI (REG_BASE + 1)
480
  { 5, 22, NULL, NULL, TIC80_OPERAND_GPR | TIC80_OPERAND_PARENS | TIC80_OPERAND_M_SI },
481
 
482
  /* A base register in bits 26-22, enclosed in parens, with optional ":m"
483
   flag in bit 15 (long immediate and register instructions only) */
484
 
485
#define REG_BASE_M_LI (REG_BASE_M_SI + 1)
486
  { 5, 22, NULL, NULL, TIC80_OPERAND_GPR | TIC80_OPERAND_PARENS | TIC80_OPERAND_M_LI },
487
 
488
  /* Scaled register in bits 4-0, with optional ":s" modifier flag in bit 11 */
489
 
490
#define REG_SCALED (REG_BASE_M_LI + 1)
491
  { 5, 0, NULL, NULL, TIC80_OPERAND_GPR | TIC80_OPERAND_SCALED },
492
 
493
  /* Unsigned immediate in bits 4-0, used only for shift instructions */
494
 
495
#define ROTATE (REG_SCALED + 1)
496
  { 5, 0, NULL, NULL, 0 },
497
 
498
  /* Unsigned immediate in bits 9-5, used only for shift instructions */
499
#define ENDMASK (ROTATE + 1)
500
  { 5, 5, NULL, NULL, TIC80_OPERAND_ENDMASK },
501
 
502
};
503
 
504
const int tic80_num_operands = sizeof (tic80_operands)/sizeof(*tic80_operands);
505
 
506
 
507
/* Macros used to generate entries for the opcodes table. */
508
 
509
#define FIXME 0
510
 
511
/* Short-Immediate Format Instructions - basic opcode */
512
#define OP_SI(x)        (((x) & 0x7F) << 15)
513
#define MASK_SI         OP_SI(0x7F)
514
 
515
/* Long-Immediate Format Instructions - basic opcode */
516
#define OP_LI(x)        (((x) & 0x3FF) << 12)
517
#define MASK_LI         OP_LI(0x3FF)
518
 
519
/* Register Format Instructions - basic opcode */
520
#define OP_REG(x)       OP_LI(x)        /* For readability */
521
#define MASK_REG        MASK_LI         /* For readability */
522
 
523
/* The 'n' bit at bit 10 */
524
#define n(x)            ((x) << 10)
525
 
526
/* The 'i' bit at bit 11 */
527
#define i(x)            ((x) << 11)
528
 
529
/* The 'F' bit at bit 27 */
530
#define F(x)            ((x) << 27)
531
 
532
/* The 'E' bit at bit 27 */
533
#define E(x)            ((x) << 27)
534
 
535
/* The 'M' bit at bit 15 in register and long immediate opcodes */
536
#define M_REG(x)        ((x) << 15)
537
#define M_LI(x)         ((x) << 15)
538
 
539
/* The 'M' bit at bit 17 in short immediate opcodes */
540
#define M_SI(x)         ((x) << 17)
541
 
542
/* The 'SZ' field at bits 14-13 in register and long immediate opcodes */
543
#define SZ_REG(x)       ((x) << 13)
544
#define SZ_LI(x)        ((x) << 13)
545
 
546
/* The 'SZ' field at bits 16-15 in short immediate opcodes */
547
#define SZ_SI(x)        ((x) << 15)
548
 
549
/* The 'D' (direct external memory access) bit at bit 10 in long immediate
550
   and register opcodes. */
551
#define D(x)            ((x) << 10)
552
 
553
/* The 'S' (scale offset by data size) bit at bit 11 in long immediate
554
   and register opcodes. */
555
#define S(x)            ((x) << 11)
556
 
557
/* The 'PD' field at bits 10-9 in floating point instructions */
558
#define PD(x)           ((x) << 9)
559
 
560
/* The 'P2' field at bits 8-7 in floating point instructions */
561
#define P2(x)           ((x) << 7)
562
 
563
/* The 'P1' field at bits 6-5 in floating point instructions */
564
#define P1(x)           ((x) << 5)
565
 
566
/* The 'a' field at bit 16 in vector instructions */
567
#define V_a1(x)         ((x) << 16)
568
 
569
/* The 'a' field at bit 11 in vector instructions */
570
#define V_a0(x)         ((x) << 11)
571
 
572
/* The 'm' field at bit 10 in vector instructions */
573
#define V_m(x)          ((x) << 10)
574
 
575
/* The 'S' field at bit 9 in vector instructions */
576
#define V_S(x)          ((x) << 9)
577
 
578
/* The 'Z' field at bit 8 in vector instructions */
579
#define V_Z(x)          ((x) << 8)
580
 
581
/* The 'p' field at bit 6 in vector instructions */
582
#define V_p(x)          ((x) << 6)
583
 
584
/* The opcode field at bits 21-17 for vector instructions */
585
#define OP_V(x)         ((x) << 17)
586
#define MASK_V          OP_V(0x1F)
587
 
588
 
589
/* The opcode table.  Formatted for better readability on a wide screen.  Also, all
590
 entries with the same mnemonic are sorted so that they are adjacent in the table,
591
 allowing the use of a hash table to locate the first of a sequence of opcodes that have
592
 a particular name.  The short immediate forms also come before the long immediate forms
593
 so that the assembler will pick the "best fit" for the size of the operand, except for
594
 the case of the PC relative forms, where the long forms come first and are the default
595
 forms. */
596
 
597
const struct tic80_opcode tic80_opcodes[] = {
598
 
599
  /* The "nop" instruction is really "rdcr 0,r0".  We put it first so that this
600
     specific bit pattern will get disassembled as a nop rather than an rdcr. The
601
     mask of all ones ensures that this will happen. */
602
 
603
  {"nop",       OP_SI(0x4),     ~0,              0,               {0}                      },
604
 
605
  /* The "br" instruction is really "bbz target,r0,31".  We put it first so that
606
     this specific bit pattern will get disassembled as a br rather than bbz. */
607
 
608
  {"br",        OP_SI(0x48),    0xFFFF8000,     0,       {OFF_SS_PC}     },
609
  {"br",        OP_LI(0x391),   0xFFFFF000,     0,       {OFF_SL_PC}     },
610
  {"br",        OP_REG(0x390),  0xFFFFF000,     0,       {REG_0}         },
611
  {"br.a",      OP_SI(0x49),    0xFFFF8000,     0,       {OFF_SS_PC}     },
612
  {"br.a",      OP_LI(0x393),   0xFFFFF000,     0,       {OFF_SL_PC}     },
613
  {"br.a",      OP_REG(0x392),  0xFFFFF000,     0,       {REG_0}         },
614
 
615
  /* Signed integer ADD */
616
 
617
  {"add",       OP_SI(0x58),    MASK_SI,        0,       {SSI, REG_22, REG_DEST}         },
618
  {"add",       OP_LI(0x3B1),   MASK_LI,        0,       {LSI, REG_22, REG_DEST}         },
619
  {"add",       OP_REG(0x3B0),  MASK_REG,       0,       {REG_0, REG_22, REG_DEST}       },
620
 
621
  /* Unsigned integer ADD */
622
 
623
  {"addu",      OP_SI(0x59),    MASK_SI,        0,       {SSI, REG_22, REG_DEST}         },
624
  {"addu",      OP_LI(0x3B3),   MASK_LI,        0,       {LSI, REG_22, REG_DEST}         },
625
  {"addu",      OP_REG(0x3B2),  MASK_REG,       0,       {REG_0, REG_22, REG_DEST}       },
626
 
627
  /* Bitwise AND */
628
 
629
  {"and",       OP_SI(0x11),    MASK_SI,        0,       {SUBF, REG_22, REG_DEST}        },
630
  {"and",       OP_LI(0x323),   MASK_LI,        0,       {LUBF, REG_22, REG_DEST}        },
631
  {"and",       OP_REG(0x322),  MASK_REG,       0,       {REG_0, REG_22, REG_DEST}       },
632
  {"and.tt",    OP_SI(0x11),    MASK_SI,        0,       {SUBF, REG_22, REG_DEST}        },
633
  {"and.tt",    OP_LI(0x323),   MASK_LI,        0,       {LUBF, REG_22, REG_DEST}        },
634
  {"and.tt",    OP_REG(0x322),  MASK_REG,       0,       {REG_0, REG_22, REG_DEST}       },
635
 
636
  /* Bitwise AND with ones complement of both sources */
637
 
638
  {"and.ff",    OP_SI(0x18),    MASK_SI,        0,       {SUBF, REG_22, REG_DEST}        },
639
  {"and.ff",    OP_LI(0x331),   MASK_LI,        0,       {LUBF, REG_22, REG_DEST}        },
640
  {"and.ff",    OP_REG(0x330),  MASK_REG,       0,       {REG_0, REG_22, REG_DEST}       },
641
 
642
  /* Bitwise AND with ones complement of source 1 */
643
 
644
  {"and.ft",    OP_SI(0x14),    MASK_SI,        0,       {SUBF, REG_22, REG_DEST}        },
645
  {"and.ft",    OP_LI(0x329),   MASK_LI,        0,       {LUBF, REG_22, REG_DEST}        },
646
  {"and.ft",    OP_REG(0x328),  MASK_REG,       0,       {REG_0, REG_22, REG_DEST}       },
647
 
648
  /* Bitwise AND with ones complement of source 2 */
649
 
650
  {"and.tf",    OP_SI(0x12),    MASK_SI,        0,       {SUBF, REG_22, REG_DEST}        },
651
  {"and.tf",    OP_LI(0x325),   MASK_LI,        0,       {LUBF, REG_22, REG_DEST}        },
652
  {"and.tf",    OP_REG(0x324),  MASK_REG,       0,       {REG_0, REG_22, REG_DEST}       },
653
 
654
  /* Branch Bit One - nonannulled */
655
 
656
  {"bbo",       OP_SI(0x4A),    MASK_SI,        0,       {OFF_SS_PC, REG_22, BITNUM}     },
657
  {"bbo",       OP_LI(0x395),   MASK_LI,        0,       {OFF_SL_PC, REG_22, BITNUM}     },
658
  {"bbo",       OP_REG(0x394),  MASK_REG,       0,       {REG_0, REG_22, BITNUM}         },
659
 
660
  /* Branch Bit One - annulled */
661
 
662
  {"bbo.a",     OP_SI(0x4B),    MASK_SI,        0,       {OFF_SS_PC, REG_22, BITNUM}     },
663
  {"bbo.a",     OP_LI(0x397),   MASK_LI,        0,       {OFF_SL_PC, REG_22, BITNUM}     },
664
  {"bbo.a",     OP_REG(0x396),  MASK_REG,       0,       {REG_0, REG_22, BITNUM}         },
665
 
666
  /* Branch Bit Zero - nonannulled */
667
 
668
  {"bbz",       OP_SI(0x48),    MASK_SI,        0,       {OFF_SS_PC, REG_22, BITNUM}     },
669
  {"bbz",       OP_LI(0x391),   MASK_LI,        0,       {OFF_SL_PC, REG_22, BITNUM}     },
670
  {"bbz",       OP_REG(0x390),  MASK_REG,       0,       {REG_0, REG_22, BITNUM}         },
671
 
672
  /* Branch Bit Zero - annulled */
673
 
674
  {"bbz.a",     OP_SI(0x49),    MASK_SI,        0,       {OFF_SS_PC, REG_22, BITNUM}     },
675
  {"bbz.a",     OP_LI(0x393),   MASK_LI,        0,       {OFF_SL_PC, REG_22, BITNUM}     },
676
  {"bbz.a",     OP_REG(0x392),  MASK_REG,       0,       {REG_0, REG_22, BITNUM}         },
677
 
678
  /* Branch Conditional - nonannulled */
679
 
680
  {"bcnd",      OP_SI(0x4C),    MASK_SI,        0,       {OFF_SS_PC, REG_22, CC} },
681
  {"bcnd",      OP_LI(0x399),   MASK_LI,        0,       {OFF_SL_PC, REG_22, CC} },
682
  {"bcnd",      OP_REG(0x398),  MASK_REG,       0,       {REG_0, REG_22, CC}     },
683
 
684
  /* Branch Conditional - annulled */
685
 
686
  {"bcnd.a",    OP_SI(0x4D),    MASK_SI,        0,       {OFF_SS_PC, REG_22, CC} },
687
  {"bcnd.a",    OP_LI(0x39B),   MASK_LI,        0,       {OFF_SL_PC, REG_22, CC} },
688
  {"bcnd.a",    OP_REG(0x39A),  MASK_REG,       0,       {REG_0, REG_22, CC}     },
689
 
690
  /* Branch Control Register */
691
 
692
  {"brcr",      OP_SI(0x6),     MASK_SI,        0,       {CR_SI} },
693
  {"brcr",      OP_LI(0x30D),   MASK_LI,        0,       {CR_LI} },
694
  {"brcr",      OP_REG(0x30C),  MASK_REG,       0,       {REG_0} },
695
 
696
  /* Branch and save return - nonannulled */
697
 
698
  {"bsr",       OP_SI(0x40),    MASK_SI,        0,       {OFF_SS_PC, REG_DEST}   },
699
  {"bsr",       OP_LI(0x381),   MASK_LI,        0,       {OFF_SL_PC, REG_DEST}   },
700
  {"bsr",       OP_REG(0x380),  MASK_REG,       0,       {REG_0, REG_DEST}       },
701
 
702
  /* Branch and save return - annulled */
703
 
704
  {"bsr.a",     OP_SI(0x41),    MASK_SI,        0,       {OFF_SS_PC, REG_DEST}   },
705
  {"bsr.a",     OP_LI(0x383),   MASK_LI,        0,       {OFF_SL_PC, REG_DEST}   },
706
  {"bsr.a",     OP_REG(0x382),  MASK_REG,       0,       {REG_0, REG_DEST}       },
707
 
708
  /* Send command */
709
 
710
  {"cmnd",      OP_SI(0x2),     MASK_SI,        0,       {SUI}   },
711
  {"cmnd",      OP_LI(0x305),   MASK_LI,        0,       {LUI}   },
712
  {"cmnd",      OP_REG(0x304),  MASK_REG,       0,       {REG_0} },
713
 
714
  /* Integer compare */
715
 
716
  {"cmp",       OP_SI(0x50),    MASK_SI,        0,       {SSI, REG_22, REG_DEST}         },
717
  {"cmp",       OP_LI(0x3A1),   MASK_LI,        0,       {LSI, REG_22, REG_DEST}         },
718
  {"cmp",       OP_REG(0x3A0),  MASK_REG,       0,       {REG_0, REG_22, REG_DEST}       },
719
 
720
  /* Flush data cache subblock - don't clear subblock preset flag */
721
 
722
  {"dcachec",   OP_SI(0x38),    F(1) | (MASK_SI  & ~M_SI(1)),                   0, {SSI, REG_BASE_M_SI}          },
723
  {"dcachec",   OP_LI(0x371),   F(1) | (MASK_LI  & ~M_LI(1))  | S(1) | D(1),    0, {LSI, REG_BASE_M_LI}          },
724
  {"dcachec",   OP_REG(0x370),  F(1) | (MASK_REG & ~M_REG(1)) | S(1) | D(1),    0, {REG_0, REG_BASE_M_LI}        },
725
 
726
  /* Flush data cache subblock - clear subblock preset flag */
727
 
728
  {"dcachef",   OP_SI(0x38)   | F(1),   F(1) | (MASK_SI  & ~M_SI(1)),                   0, {SSI, REG_BASE_M_SI}          },
729
  {"dcachef",   OP_LI(0x371)  | F(1),   F(1) | (MASK_LI  & ~M_LI(1))   | S(1) | D(1),   0, {LSI, REG_BASE_M_LI}          },
730
  {"dcachef",   OP_REG(0x370) | F(1),   F(1) | (MASK_REG & ~M_REG(1)) | S(1) | D(1),    0, {REG_0, REG_BASE_M_LI}        },
731
 
732
  /* Direct load signed data into register */
733
 
734
  {"dld",       OP_LI(0x345)  | D(1),   (MASK_LI  & ~M_REG(1)) | D(1),  0,       {OFF_SL_BR_SCALED, REG_BASE_M_LI, REG_DEST}     },
735
  {"dld",       OP_REG(0x344) | D(1),   (MASK_REG & ~M_REG(1)) | D(1),  0,       {REG_SCALED, REG_BASE_M_LI, REG_DEST}           },
736
  {"dld.b",     OP_LI(0x341)  | D(1),   (MASK_LI  & ~M_REG(1)) | D(1),  0,       {OFF_SL_BR_SCALED, REG_BASE_M_LI, REG_DEST}     },
737
  {"dld.b",     OP_REG(0x340) | D(1),   (MASK_REG & ~M_REG(1)) | D(1),  0,       {REG_SCALED, REG_BASE_M_LI, REG_DEST}           },
738
  {"dld.d",     OP_LI(0x347)  | D(1),   (MASK_LI  & ~M_REG(1)) | D(1),  0,       {OFF_SL_BR_SCALED, REG_BASE_M_LI, REG_DEST_E}   },
739
  {"dld.d",     OP_REG(0x346) | D(1),   (MASK_REG & ~M_REG(1)) | D(1),  0,       {REG_SCALED, REG_BASE_M_LI, REG_DEST_E}         },
740
  {"dld.h",     OP_LI(0x343)  | D(1),   (MASK_LI  & ~M_REG(1)) | D(1),  0,       {OFF_SL_BR_SCALED, REG_BASE_M_LI, REG_DEST}     },
741
  {"dld.h",     OP_REG(0x342) | D(1),   (MASK_REG & ~M_REG(1)) | D(1),  0,       {REG_SCALED, REG_BASE_M_LI, REG_DEST}           },
742
 
743
  /* Direct load unsigned data into register */
744
 
745
  {"dld.ub",    OP_LI(0x351)  | D(1),   (MASK_LI  &  ~M_REG(1)) | D(1), 0,       {OFF_SL_BR_SCALED, REG_BASE_M_LI, REG_DEST}     },
746
  {"dld.ub",    OP_REG(0x350) | D(1),   (MASK_REG & ~M_REG(1))  | D(1), 0,       {REG_SCALED, REG_BASE_M_LI, REG_DEST}           },
747
  {"dld.uh",    OP_LI(0x353)  | D(1),   (MASK_LI  &  ~M_REG(1)) | D(1), 0,       {OFF_SL_BR_SCALED, REG_BASE_M_LI, REG_DEST}     },
748
  {"dld.uh",    OP_REG(0x352) | D(1),   (MASK_REG & ~M_REG(1))  | D(1), 0,       {REG_SCALED, REG_BASE_M_LI, REG_DEST}           },
749
 
750
  /* Direct store data into memory */
751
 
752
  {"dst",       OP_LI(0x365)  | D(1),   (MASK_LI  & ~M_REG(1)) | D(1),  0,       {OFF_SL_BR_SCALED, REG_BASE_M_LI, REG_DEST}     },
753
  {"dst",       OP_REG(0x364) | D(1),   (MASK_REG & ~M_REG(1)) | D(1),  0,       {REG_SCALED, REG_BASE_M_LI, REG_DEST}           },
754
  {"dst.b",     OP_LI(0x361)  | D(1),   (MASK_LI  & ~M_REG(1)) | D(1),  0,       {OFF_SL_BR_SCALED, REG_BASE_M_LI, REG_DEST}     },
755
  {"dst.b",     OP_REG(0x360) | D(1),   (MASK_REG & ~M_REG(1)) | D(1),  0,       {REG_SCALED, REG_BASE_M_LI, REG_DEST}           },
756
  {"dst.d",     OP_LI(0x367)  | D(1),   (MASK_LI  & ~M_REG(1)) | D(1),  0,       {OFF_SL_BR_SCALED, REG_BASE_M_LI, REG_DEST_E}   },
757
  {"dst.d",     OP_REG(0x366) | D(1),   (MASK_REG & ~M_REG(1)) | D(1),  0,       {REG_SCALED, REG_BASE_M_LI, REG_DEST_E}         },
758
  {"dst.h",     OP_LI(0x363)  | D(1),   (MASK_LI  & ~M_REG(1)) | D(1),  0,       {OFF_SL_BR_SCALED, REG_BASE_M_LI, REG_DEST}     },
759
  {"dst.h",     OP_REG(0x362) | D(1),   (MASK_REG & ~M_REG(1)) | D(1),  0,       {REG_SCALED, REG_BASE_M_LI, REG_DEST}           },
760
 
761
  /* Emulation stop */
762
 
763
  {"estop",     OP_LI(0x3FC),   MASK_LI,        0,               {0}      },
764
 
765
  /* Emulation trap */
766
 
767
  {"etrap",     OP_SI(0x1)    | E(1),   MASK_SI  | E(1),        0,       {SUI}   },
768
  {"etrap",     OP_LI(0x303)  | E(1),   MASK_LI  | E(1),        0,       {LUI}   },
769
  {"etrap",     OP_REG(0x302) | E(1),   MASK_REG | E(1),        0,       {REG_0} },
770
 
771
  /* Floating-point addition */
772
 
773
  {"fadd.ddd",  OP_REG(0x3E0) | PD(1) | P2(1) | P1(1),  MASK_REG | PD(3) | P2(3) | P1(3), 0,      {REG_0_E, REG_22_E, REG_DEST_E}        },
774
  {"fadd.dsd",  OP_REG(0x3E0) | PD(1) | P2(0) | P1(1),   MASK_REG | PD(3) | P2(3) | P1(3), 0,      {REG_0_E, REG_22, REG_DEST_E}  },
775
  {"fadd.sdd",  OP_LI(0x3E1)  | PD(1) | P2(1) | P1(0),   MASK_LI  | PD(3) | P2(3) | P1(3), 0,      {SPFI, REG_22_E, REG_DEST_E}   },
776
  {"fadd.sdd",  OP_REG(0x3E0) | PD(1) | P2(1) | P1(0),   MASK_REG | PD(3) | P2(3) | P1(3), 0,      {REG_0, REG_22_E, REG_DEST_E}  },
777
  {"fadd.ssd",  OP_LI(0x3E1)  | PD(1) | P2(0) | P1(0),    MASK_LI  | PD(3) | P2(3) | P1(3), 0,      {SPFI, REG_22, REG_DEST_E}     },
778
  {"fadd.ssd",  OP_REG(0x3E0) | PD(1) | P2(0) | P1(0),    MASK_REG | PD(3) | P2(3) | P1(3), 0,      {REG_0, REG_22, REG_DEST_E}    },
779
  {"fadd.sss",  OP_LI(0x3E1)  | PD(0) | P2(0) | P1(0),     MASK_LI  | PD(3) | P2(3) | P1(3), 0,      {SPFI, REG_22, REG_DEST}       },
780
  {"fadd.sss",  OP_REG(0x3E0) | PD(0) | P2(0) | P1(0),     MASK_REG | PD(3) | P2(3) | P1(3), 0,      {REG_0, REG_22, REG_DEST}      },
781
 
782
  /* Floating point compare */
783
 
784
  {"fcmp.dd",   OP_REG(0x3EA) | PD(0) | P2(1) | P1(1),   MASK_REG | PD(3) | P2(3) | P1(3),  0,     {REG_0_E, REG_22_E, REG_DEST}  },
785
  {"fcmp.ds",   OP_REG(0x3EA) | PD(0) | P2(0) | P1(1),    MASK_REG | PD(3) | P2(3) | P1(3),  0,     {REG_0_E, REG_22, REG_DEST}    },
786
  {"fcmp.sd",   OP_LI(0x3EB)  | PD(0) | P2(1) | P1(0),    MASK_LI  | PD(3) | P2(3) | P1(3),  0,     {SPFI, REG_22_E, REG_DEST}     },
787
  {"fcmp.sd",   OP_REG(0x3EA) | PD(0) | P2(1) | P1(0),    MASK_REG | PD(3) | P2(3) | P1(3),  0,     {REG_0, REG_22_E, REG_DEST}    },
788
  {"fcmp.ss",   OP_LI(0x3EB)  | PD(0) | P2(0) | P1(0),     MASK_LI  | PD(3) | P2(3) | P1(3),  0,     {SPFI, REG_22, REG_DEST}       },
789
  {"fcmp.ss",   OP_REG(0x3EA) | PD(0) | P2(0) | P1(0),     MASK_REG | PD(3) | P2(3) | P1(3),  0,     {REG_0, REG_22, REG_DEST}      },
790
 
791
  /* Floating point divide */
792
 
793
  {"fdiv.ddd",  OP_REG(0x3E6) | PD(1) | P2(1) | P1(1),  MASK_REG | PD(3) | P2(3) | P1(3), 0,      {REG_0_E, REG_22_E, REG_DEST_E}        },
794
  {"fdiv.dsd",  OP_REG(0x3E6) | PD(1) | P2(0) | P1(1),   MASK_REG | PD(3) | P2(3) | P1(3), 0,      {REG_0_E, REG_22, REG_DEST_E}  },
795
  {"fdiv.sdd",  OP_LI(0x3E7)  | PD(1) | P2(1) | P1(0),   MASK_LI  | PD(3) | P2(3) | P1(3), 0,      {SPFI, REG_22_E, REG_DEST_E}   },
796
  {"fdiv.sdd",  OP_REG(0x3E6) | PD(1) | P2(1) | P1(0),   MASK_REG | PD(3) | P2(3) | P1(3), 0,      {REG_0, REG_22_E, REG_DEST_E}  },
797
  {"fdiv.ssd",  OP_LI(0x3E7)  | PD(1) | P2(0) | P1(0),    MASK_LI  | PD(3) | P2(3) | P1(3), 0,      {SPFI, REG_22, REG_DEST_E}     },
798
  {"fdiv.ssd",  OP_REG(0x3E6) | PD(1) | P2(0) | P1(0),    MASK_REG | PD(3) | P2(3) | P1(3), 0,      {REG_0, REG_22, REG_DEST_E}    },
799
  {"fdiv.sss",  OP_LI(0x3E7)  | PD(0) | P2(0) | P1(0),     MASK_LI  | PD(3) | P2(3) | P1(3), 0,      {SPFI, REG_22, REG_DEST}       },
800
  {"fdiv.sss",  OP_REG(0x3E6) | PD(0) | P2(0) | P1(0),     MASK_REG | PD(3) | P2(3) | P1(3), 0,      {REG_0, REG_22, REG_DEST}      },
801
 
802
  /* Floating point multiply */
803
 
804
  {"fmpy.ddd",  OP_REG(0x3E4) | PD(1) | P2(1) | P1(1),  MASK_REG | PD(3) | P2(3) | P1(3), 0,      {REG_0_E, REG_22_E, REG_DEST_E}        },
805
  {"fmpy.dsd",  OP_REG(0x3E4) | PD(1) | P2(0) | P1(1),   MASK_REG | PD(3) | P2(3) | P1(3), 0,      {REG_0_E, REG_22, REG_DEST_E}  },
806
  {"fmpy.iii",  OP_LI(0x3E5)  | PD(2) | P2(2) | P1(2),  MASK_LI  | PD(3) | P2(3) | P1(3), 0,      {LSI, REG_22, REG_DEST}        },
807
  {"fmpy.iii",  OP_REG(0x3E4) | PD(2) | P2(2) | P1(2),  MASK_REG | PD(3) | P2(3) | P1(3), 0,      {REG_0, REG_22, REG_DEST}      },
808
  {"fmpy.sdd",  OP_LI(0x3E5)  | PD(1) | P2(1) | P1(0),   MASK_LI  | PD(3) | P2(3) | P1(3), 0,      {SPFI, REG_22_E, REG_DEST_E}   },
809
  {"fmpy.sdd",  OP_REG(0x3E4) | PD(1) | P2(1) | P1(0),   MASK_REG | PD(3) | P2(3) | P1(3), 0,      {REG_0, REG_22_E, REG_DEST_E}  },
810
  {"fmpy.ssd",  OP_LI(0x3E5)  | PD(1) | P2(0) | P1(0),    MASK_LI  | PD(3) | P2(3) | P1(3), 0,      {SPFI, REG_22, REG_DEST_E}     },
811
  {"fmpy.ssd",  OP_REG(0x3E4) | PD(1) | P2(0) | P1(0),    MASK_REG | PD(3) | P2(3) | P1(3), 0,      {REG_0, REG_22, REG_DEST_E}    },
812
  {"fmpy.sss",  OP_LI(0x3E5)  | PD(0) | P2(0) | P1(0),     MASK_LI  | PD(3) | P2(3) | P1(3), 0,      {SPFI, REG_22, REG_DEST}       },
813
  {"fmpy.sss",  OP_REG(0x3E4) | PD(0) | P2(0) | P1(0),     MASK_REG | PD(3) | P2(3) | P1(3), 0,      {REG_0, REG_22, REG_DEST}      },
814
  {"fmpy.uuu",  OP_LI(0x3E5)  | PD(3) | P2(3) | P1(3),  MASK_LI  | PD(3) | P2(3) | P1(3), 0,      {LUI, REG_22, REG_DEST}        },
815
  {"fmpy.uuu",  OP_REG(0x3E4) | PD(3) | P2(3) | P1(3),  MASK_REG | PD(3) | P2(3) | P1(3), 0,      {REG_0, REG_22, REG_DEST}      },
816
 
817
  /* Convert/Round to Minus Infinity */
818
 
819
  {"frndm.dd",  OP_REG(0x3E8) | PD(1) | P2(3) | P1(1),  MASK_REG | PD(3) | P2(3) | P1(3), 0,      {REG_0_E, REG_DEST_E}  },
820
  {"frndm.di",  OP_REG(0x3E8) | PD(2) | P2(3) | P1(1),  MASK_REG | PD(3) | P2(3) | P1(3), 0,      {REG_0_E, REG_DEST}    },
821
  {"frndm.ds",  OP_REG(0x3E8) | PD(0) | P2(3) | P1(1),   MASK_REG | PD(3) | P2(3) | P1(3), 0,      {REG_0_E, REG_DEST}    },
822
  {"frndm.du",  OP_REG(0x3E8) | PD(3) | P2(3) | P1(1),  MASK_REG | PD(3) | P2(3) | P1(3), 0,      {REG_0_E, REG_DEST}    },
823
  {"frndm.id",  OP_LI(0x3E9)  | PD(1) | P2(3) | P1(2),  MASK_LI  | PD(3) | P2(3) | P1(3), 0,      {LSI, REG_DEST_E}      },
824
  {"frndm.id",  OP_REG(0x3E8) | PD(1) | P2(3) | P1(2),  MASK_REG | PD(3) | P2(3) | P1(3), 0,      {REG_0, REG_DEST_E}    },
825
  {"frndm.is",  OP_LI(0x3E9)  | PD(0) | P2(3) | P1(2),   MASK_LI  | PD(3) | P2(3) | P1(3), 0,      {LSI, REG_DEST}        },
826
  {"frndm.is",  OP_REG(0x3E8) | PD(0) | P2(3) | P1(2),   MASK_REG | PD(3) | P2(3) | P1(3), 0,      {REG_0, REG_DEST}      },
827
  {"frndm.sd",  OP_LI(0x3E9)  | PD(1) | P2(3) | P1(0),   MASK_LI  | PD(3) | P2(3) | P1(3), 0,      {SPFI, REG_DEST_E}     },
828
  {"frndm.sd",  OP_REG(0x3E8) | PD(1) | P2(3) | P1(0),   MASK_REG | PD(3) | P2(3) | P1(3), 0,      {REG_0, REG_DEST_E}    },
829
  {"frndm.si",  OP_LI(0x3E9)  | PD(2) | P2(3) | P1(0),   MASK_LI  | PD(3) | P2(3) | P1(3), 0,      {SPFI, REG_DEST}       },
830
  {"frndm.si",  OP_REG(0x3E8) | PD(2) | P2(3) | P1(0),   MASK_REG | PD(3) | P2(3) | P1(3), 0,      {REG_0, REG_DEST}      },
831
  {"frndm.ss",  OP_LI(0x3E9)  | PD(0) | P2(3) | P1(0),    MASK_LI  | PD(3) | P2(3) | P1(3), 0,      {SPFI, REG_DEST}       },
832
  {"frndm.ss",  OP_REG(0x3E8) | PD(0) | P2(3) | P1(0),    MASK_REG | PD(3) | P2(3) | P1(3), 0,      {REG_0, REG_DEST}      },
833
  {"frndm.su",  OP_LI(0x3E9)  | PD(3) | P2(3) | P1(0),   MASK_LI  | PD(3) | P2(3) | P1(3), 0,      {SPFI, REG_DEST}       },
834
  {"frndm.su",  OP_REG(0x3E8) | PD(3) | P2(3) | P1(0),   MASK_REG | PD(3) | P2(3) | P1(3), 0,      {REG_0, REG_DEST}      },
835
  {"frndm.ud",  OP_LI(0x3E9)  | PD(1) | P2(3) | P1(3),  MASK_LI  | PD(3) | P2(3) | P1(3), 0,      {LSI, REG_DEST_E}      },
836
  {"frndm.ud",  OP_REG(0x3E8) | PD(1) | P2(3) | P1(3),  MASK_REG | PD(3) | P2(3) | P1(3), 0,      {REG_0, REG_DEST_E}    },
837
  {"frndm.us",  OP_LI(0x3E9)  | PD(0) | P2(3) | P1(3),   MASK_LI  | PD(3) | P2(3) | P1(3), 0,      {LSI, REG_DEST}        },
838
  {"frndm.us",  OP_REG(0x3E8) | PD(0) | P2(3) | P1(3),   MASK_REG | PD(3) | P2(3) | P1(3), 0,      {REG_0, REG_DEST}      },
839
 
840
  /* Convert/Round to Nearest */
841
 
842
  {"frndn.dd",  OP_REG(0x3E8) | PD(1) | P2(0) | P1(1),   MASK_REG | PD(3) | P2(3) | P1(3), 0,      {REG_0_E, REG_DEST_E}  },
843
  {"frndn.di",  OP_REG(0x3E8) | PD(2) | P2(0) | P1(1),   MASK_REG | PD(3) | P2(3) | P1(3), 0,      {REG_0_E, REG_DEST}    },
844
  {"frndn.ds",  OP_REG(0x3E8) | PD(0) | P2(0) | P1(1),    MASK_REG | PD(3) | P2(3) | P1(3), 0,      {REG_0_E, REG_DEST}    },
845
  {"frndn.du",  OP_REG(0x3E8) | PD(3) | P2(0) | P1(1),   MASK_REG | PD(3) | P2(3) | P1(3), 0,      {REG_0_E, REG_DEST}    },
846
  {"frndn.id",  OP_LI(0x3E9)  | PD(1) | P2(0) | P1(2),   MASK_LI  | PD(3) | P2(3) | P1(3), 0,      {LSI, REG_DEST_E}      },
847
  {"frndn.id",  OP_REG(0x3E8) | PD(1) | P2(0) | P1(2),   MASK_REG | PD(3) | P2(3) | P1(3), 0,      {REG_0, REG_DEST_E}    },
848
  {"frndn.is",  OP_LI(0x3E9)  | PD(0) | P2(0) | P1(2),    MASK_LI  | PD(3) | P2(3) | P1(3), 0,      {LSI, REG_DEST}        },
849
  {"frndn.is",  OP_REG(0x3E8) | PD(0) | P2(0) | P1(2),    MASK_REG | PD(3) | P2(3) | P1(3), 0,      {REG_0, REG_DEST}      },
850
  {"frndn.sd",  OP_LI(0x3E9)  | PD(1) | P2(0) | P1(0),    MASK_LI  | PD(3) | P2(3) | P1(3), 0,      {SPFI, REG_DEST_E}     },
851
  {"frndn.sd",  OP_REG(0x3E8) | PD(1) | P2(0) | P1(0),    MASK_REG | PD(3) | P2(3) | P1(3), 0,      {REG_0, REG_DEST_E}    },
852
  {"frndn.si",  OP_LI(0x3E9)  | PD(2) | P2(0) | P1(0),    MASK_LI  | PD(3) | P2(3) | P1(3), 0,      {SPFI, REG_DEST}       },
853
  {"frndn.si",  OP_REG(0x3E8) | PD(2) | P2(0) | P1(0),    MASK_REG | PD(3) | P2(3) | P1(3), 0,      {REG_0, REG_DEST}      },
854
  {"frndn.ss",  OP_LI(0x3E9)  | PD(0) | P2(0) | P1(0),     MASK_LI  | PD(3) | P2(3) | P1(3), 0,      {SPFI, REG_DEST}       },
855
  {"frndn.ss",  OP_REG(0x3E8) | PD(0) | P2(0) | P1(0),     MASK_REG | PD(3) | P2(3) | P1(3), 0,      {REG_0, REG_DEST}      },
856
  {"frndn.su",  OP_LI(0x3E9)  | PD(3) | P2(0) | P1(0),    MASK_LI  | PD(3) | P2(3) | P1(3), 0,      {SPFI, REG_DEST}       },
857
  {"frndn.su",  OP_REG(0x3E8) | PD(3) | P2(0) | P1(0),    MASK_REG | PD(3) | P2(3) | P1(3), 0,      {REG_0, REG_DEST}      },
858
  {"frndn.ud",  OP_LI(0x3E9)  | PD(1) | P2(0) | P1(3),   MASK_LI  | PD(3) | P2(3) | P1(3), 0,      {LSI, REG_DEST_E}      },
859
  {"frndn.ud",  OP_REG(0x3E8) | PD(1) | P2(0) | P1(3),   MASK_REG | PD(3) | P2(3) | P1(3), 0,      {REG_0, REG_DEST_E}    },
860
  {"frndn.us",  OP_LI(0x3E9)  | PD(0) | P2(0) | P1(3),    MASK_LI  | PD(3) | P2(3) | P1(3), 0,      {LSI, REG_DEST}        },
861
  {"frndn.us",  OP_REG(0x3E8) | PD(0) | P2(0) | P1(3),    MASK_REG | PD(3) | P2(3) | P1(3), 0,      {REG_0, REG_DEST}      },
862
 
863
  /* Convert/Round to Positive Infinity */
864
 
865
  {"frndp.dd",  OP_REG(0x3E8) | PD(1) | P2(2) | P1(1),  MASK_REG | PD(3) | P2(3) | P1(3), 0,      {REG_0_E, REG_DEST_E}  },
866
  {"frndp.di",  OP_REG(0x3E8) | PD(2) | P2(2) | P1(1),  MASK_REG | PD(3) | P2(3) | P1(3), 0,      {REG_0_E, REG_DEST}    },
867
  {"frndp.ds",  OP_REG(0x3E8) | PD(0) | P2(2) | P1(1),   MASK_REG | PD(3) | P2(3) | P1(3), 0,      {REG_0_E, REG_DEST}    },
868
  {"frndp.du",  OP_REG(0x3E8) | PD(3) | P2(2) | P1(1),  MASK_REG | PD(3) | P2(3) | P1(3), 0,      {REG_0_E, REG_DEST}    },
869
  {"frndp.id",  OP_LI(0x3E9)  | PD(1) | P2(2) | P1(2),  MASK_LI  | PD(3) | P2(3) | P1(3), 0,      {LSI, REG_DEST_E}      },
870
  {"frndp.id",  OP_REG(0x3E8) | PD(1) | P2(2) | P1(2),  MASK_REG | PD(3) | P2(3) | P1(3), 0,      {REG_0, REG_DEST_E}    },
871
  {"frndp.is",  OP_LI(0x3E9)  | PD(0) | P2(2) | P1(2),   MASK_LI  | PD(3) | P2(3) | P1(3), 0,      {LSI, REG_DEST}        },
872
  {"frndp.is",  OP_REG(0x3E8) | PD(0) | P2(2) | P1(2),   MASK_REG | PD(3) | P2(3) | P1(3), 0,      {REG_0, REG_DEST}      },
873
  {"frndp.sd",  OP_LI(0x3E9)  | PD(1) | P2(2) | P1(0),   MASK_LI  | PD(3) | P2(3) | P1(3), 0,      {SPFI, REG_DEST_E}     },
874
  {"frndp.sd",  OP_REG(0x3E8) | PD(1) | P2(2) | P1(0),   MASK_REG | PD(3) | P2(3) | P1(3), 0,      {REG_0, REG_DEST_E}    },
875
  {"frndp.si",  OP_LI(0x3E9)  | PD(2) | P2(2) | P1(0),   MASK_LI  | PD(3) | P2(3) | P1(3), 0,      {SPFI, REG_DEST}       },
876
  {"frndp.si",  OP_REG(0x3E8) | PD(2) | P2(2) | P1(0),   MASK_REG | PD(3) | P2(3) | P1(3), 0,      {REG_0, REG_DEST}      },
877
  {"frndp.ss",  OP_LI(0x3E9)  | PD(0) | P2(2) | P1(0),    MASK_LI  | PD(3) | P2(3) | P1(3), 0,      {SPFI, REG_DEST}       },
878
  {"frndp.ss",  OP_REG(0x3E8) | PD(0) | P2(2) | P1(0),    MASK_REG | PD(3) | P2(3) | P1(3), 0,      {REG_0, REG_DEST}      },
879
  {"frndp.su",  OP_LI(0x3E9)  | PD(3) | P2(2) | P1(0),   MASK_LI  | PD(3) | P2(3) | P1(3), 0,      {SPFI, REG_DEST}       },
880
  {"frndp.su",  OP_REG(0x3E8) | PD(3) | P2(2) | P1(0),   MASK_REG | PD(3) | P2(3) | P1(3), 0,      {REG_0, REG_DEST}      },
881
  {"frndp.ud",  OP_LI(0x3E9)  | PD(1) | P2(2) | P1(3),  MASK_LI  | PD(3) | P2(3) | P1(3), 0,      {LSI, REG_DEST_E}      },
882
  {"frndp.ud",  OP_REG(0x3E8) | PD(1) | P2(2) | P1(3),  MASK_REG | PD(3) | P2(3) | P1(3), 0,      {REG_0, REG_DEST_E}    },
883
  {"frndp.us",  OP_LI(0x3E9)  | PD(0) | P2(2) | P1(3),   MASK_LI  | PD(3) | P2(3) | P1(3), 0,      {LSI, REG_DEST}        },
884
  {"frndp.us",  OP_REG(0x3E8) | PD(0) | P2(2) | P1(3),   MASK_REG | PD(3) | P2(3) | P1(3), 0,      {REG_0, REG_DEST}      },
885
 
886
  /* Convert/Round to Zero */
887
 
888
  {"frndz.dd",  OP_REG(0x3E8) | PD(1) | P2(1) | P1(1),  MASK_REG | PD(3) | P2(3) | P1(3), 0,      {REG_0_E, REG_DEST_E}  },
889
  {"frndz.di",  OP_REG(0x3E8) | PD(2) | P2(1) | P1(1),  MASK_REG | PD(3) | P2(3) | P1(3), 0,      {REG_0_E, REG_DEST}    },
890
  {"frndz.ds",  OP_REG(0x3E8) | PD(0) | P2(1) | P1(1),   MASK_REG | PD(3) | P2(3) | P1(3), 0,      {REG_0_E, REG_DEST}    },
891
  {"frndz.du",  OP_REG(0x3E8) | PD(3) | P2(1) | P1(1),  MASK_REG | PD(3) | P2(3) | P1(3), 0,      {REG_0_E, REG_DEST}    },
892
  {"frndz.id",  OP_LI(0x3E9)  | PD(1) | P2(1) | P1(2),  MASK_LI  | PD(3) | P2(3) | P1(3), 0,      {LSI, REG_DEST_E}      },
893
  {"frndz.id",  OP_REG(0x3E8) | PD(1) | P2(1) | P1(2),  MASK_REG | PD(3) | P2(3) | P1(3), 0,      {REG_0, REG_DEST_E}    },
894
  {"frndz.is",  OP_LI(0x3E9)  | PD(0) | P2(1) | P1(2),   MASK_LI  | PD(3) | P2(3) | P1(3), 0,      {LSI, REG_DEST}        },
895
  {"frndz.is",  OP_REG(0x3E8) | PD(0) | P2(1) | P1(2),   MASK_REG | PD(3) | P2(3) | P1(3), 0,      {REG_0, REG_DEST}      },
896
  {"frndz.sd",  OP_LI(0x3E9)  | PD(1) | P2(1) | P1(0),   MASK_LI  | PD(3) | P2(3) | P1(3), 0,      {SPFI, REG_DEST_E}     },
897
  {"frndz.sd",  OP_REG(0x3E8) | PD(1) | P2(1) | P1(0),   MASK_REG | PD(3) | P2(3) | P1(3), 0,      {REG_0, REG_DEST_E}    },
898
  {"frndz.si",  OP_LI(0x3E9)  | PD(2) | P2(1) | P1(0),   MASK_LI  | PD(3) | P2(3) | P1(3), 0,      {SPFI, REG_DEST}       },
899
  {"frndz.si",  OP_REG(0x3E8) | PD(2) | P2(1) | P1(0),   MASK_REG | PD(3) | P2(3) | P1(3), 0,      {REG_0, REG_DEST}      },
900
  {"frndz.ss",  OP_LI(0x3E9)  | PD(0) | P2(1) | P1(0),    MASK_LI  | PD(3) | P2(3) | P1(3), 0,      {SPFI, REG_DEST}       },
901
  {"frndz.ss",  OP_REG(0x3E8) | PD(0) | P2(1) | P1(0),    MASK_REG | PD(3) | P2(3) | P1(3), 0,      {REG_0, REG_DEST}      },
902
  {"frndz.su",  OP_LI(0x3E9)  | PD(3) | P2(1) | P1(0),   MASK_LI  | PD(3) | P2(3) | P1(3), 0,      {SPFI, REG_DEST}       },
903
  {"frndz.su",  OP_REG(0x3E8) | PD(3) | P2(1) | P1(0),   MASK_REG | PD(3) | P2(3) | P1(3), 0,      {REG_0, REG_DEST}      },
904
  {"frndz.ud",  OP_LI(0x3E9)  | PD(1) | P2(1) | P1(3),  MASK_LI  | PD(3) | P2(3) | P1(3), 0,      {LSI, REG_DEST_E}      },
905
  {"frndz.ud",  OP_REG(0x3E8) | PD(1) | P2(1) | P1(3),  MASK_REG | PD(3) | P2(3) | P1(3), 0,      {REG_0, REG_DEST_E}    },
906
  {"frndz.us",  OP_LI(0x3E9)  | PD(0) | P2(1) | P1(3),   MASK_LI  | PD(3) | P2(3) | P1(3), 0,      {LSI, REG_DEST}        },
907
  {"frndz.us",  OP_REG(0x3E8) | PD(0) | P2(1) | P1(3),   MASK_REG | PD(3) | P2(3) | P1(3), 0,      {REG_0, REG_DEST}      },
908
 
909
  /* Floating point square root */
910
 
911
  {"fsqrt.dd",  OP_REG(0x3EE) | PD(1) | P2(0) | P1(1),   MASK_REG | PD(3) | P2(3) | P1(3), 0,      {REG_0_E, REG_DEST_E}  },
912
  {"fsqrt.sd",  OP_LI(0x3EF)  | PD(1) | P2(0) | P1(0),    MASK_LI  | PD(3) | P2(3) | P1(3), 0,      {SPFI, REG_DEST_E}     },
913
  {"fsqrt.sd",  OP_REG(0x3EE) | PD(1) | P2(0) | P1(0),    MASK_REG | PD(3) | P2(3) | P1(3), 0,      {REG_0, REG_DEST_E}    },
914
  {"fsqrt.ss",  OP_LI(0x3EF)  | PD(0) | P2(0) | P1(0),     MASK_LI  | PD(3) | P2(3) | P1(3), 0,      {SPFI, REG_DEST}       },
915
  {"fsqrt.ss",  OP_REG(0x3EE) | PD(0) | P2(0) | P1(0),     MASK_REG | PD(3) | P2(3) | P1(3), 0,      {REG_0, REG_DEST}      },
916
 
917
  /* Floating point subtraction */
918
 
919
  { "fsub.ddd", OP_REG(0x3E2) | PD(1) | P2(1) | P1(1),  MASK_REG | PD(3) | P2(3) | P1(3), 0,      {REG_0_E, REG_22_E, REG_DEST_E}        },
920
  { "fsub.dsd", OP_REG(0x3E2) | PD(1) | P2(0) | P1(1),   MASK_REG | PD(3) | P2(3) | P1(3), 0,      {REG_0_E, REG_22, REG_DEST_E}  },
921
  { "fsub.sdd", OP_LI(0x3E3)  | PD(1) | P2(1) | P1(0),   MASK_LI  | PD(3) | P2(3) | P1(3), 0,      {SPFI, REG_22_E, REG_DEST_E}   },
922
  { "fsub.sdd", OP_REG(0x3E2) | PD(1) | P2(1) | P1(0),   MASK_REG | PD(3) | P2(3) | P1(3), 0,      {REG_0, REG_22_E, REG_DEST_E}  },
923
  { "fsub.ssd", OP_LI(0x3E3)  | PD(1) | P2(0) | P1(0),    MASK_LI  | PD(3) | P2(3) | P1(3), 0,      {SPFI, REG_22, REG_DEST_E}     },
924
  { "fsub.ssd", OP_REG(0x3E2) | PD(1) | P2(0) | P1(0),    MASK_REG | PD(3) | P2(3) | P1(3), 0,      {REG_0, REG_22, REG_DEST_E}    },
925
  { "fsub.sss", OP_LI(0x3E3)  | PD(0) | P2(0) | P1(0),     MASK_LI  | PD(3) | P2(3) | P1(3), 0,      {SPFI, REG_22, REG_DEST}       },
926
  { "fsub.sss", OP_REG(0x3E2) | PD(0) | P2(0) | P1(0),     MASK_REG | PD(3) | P2(3) | P1(3), 0,      {REG_0, REG_22, REG_DEST}      },
927
 
928
  /* Illegal instructions */
929
 
930
  {"illop0",    OP_SI(0x0),     MASK_SI,        0,       {0}      },
931
  {"illopF",    0x1FF << 13,    0x1FF << 13,    0,       {0}      },
932
 
933
  /* Jump and save return */
934
 
935
  {"jsr",       OP_SI(0x44),    MASK_SI,        0,       {OFF_SS_BR, REG_BASE, REG_DEST} },
936
  {"jsr",       OP_LI(0x389),   MASK_LI,        0,       {OFF_SL_BR, REG_BASE, REG_DEST} },
937
  {"jsr",       OP_REG(0x388),  MASK_REG,       0,       {REG_0, REG_BASE, REG_DEST}     },
938
  {"jsr.a",     OP_SI(0x45),    MASK_SI,        0,       {OFF_SS_BR, REG_BASE, REG_DEST} },
939
  {"jsr.a",     OP_LI(0x38B),   MASK_LI,        0,       {OFF_SL_BR, REG_BASE, REG_DEST} },
940
  {"jsr.a",     OP_REG(0x38A),  MASK_REG,       0,       {REG_0, REG_BASE, REG_DEST}     },
941
 
942
  /* Load Signed Data Into Register */
943
 
944
  {"ld",        OP_SI(0x22),            (MASK_SI  & ~M_SI(1)),          0,       {OFF_SS_BR, REG_BASE_M_SI, REG_DEST}            },
945
  {"ld",        OP_LI(0x345)  | D(0),    (MASK_LI  & ~M_REG(1)) | D(1),  0,       {OFF_SL_BR_SCALED, REG_BASE_M_LI, REG_DEST}     },
946
  {"ld",        OP_REG(0x344) | D(0),    (MASK_REG & ~M_REG(1)) | D(1),  0,       {REG_SCALED, REG_BASE_M_LI, REG_DEST}           },
947
  {"ld.b",      OP_SI(0x20),            (MASK_SI  & ~M_SI(1)),          0,       {OFF_SS_BR, REG_BASE_M_SI, REG_DEST}            },
948
  {"ld.b",      OP_LI(0x341)  | D(0),    (MASK_LI  & ~M_REG(1)) | D(1),  0,       {OFF_SL_BR_SCALED, REG_BASE_M_LI, REG_DEST}     },
949
  {"ld.b",      OP_REG(0x340) | D(0),    (MASK_REG & ~M_REG(1)) | D(1),  0,       {REG_SCALED, REG_BASE_M_LI, REG_DEST}           },
950
  {"ld.d",      OP_SI(0x23),            (MASK_SI  & ~M_SI(1)),          0,       {OFF_SS_BR, REG_BASE_M_SI, REG_DEST_E}          },
951
  {"ld.d",      OP_LI(0x347)  | D(0),    (MASK_LI  & ~M_REG(1)) | D(1),  0,       {OFF_SL_BR_SCALED, REG_BASE_M_LI, REG_DEST_E}   },
952
  {"ld.d",      OP_REG(0x346) | D(0),    (MASK_REG & ~M_REG(1)) | D(1),  0,       {REG_SCALED, REG_BASE_M_LI, REG_DEST_E}         },
953
  {"ld.h",      OP_SI(0x21),            (MASK_SI  & ~M_SI(1)),          0,       {OFF_SS_BR, REG_BASE_M_SI, REG_DEST}            },
954
  {"ld.h",      OP_LI(0x343)  | D(0),    (MASK_LI  & ~M_REG(1)) | D(1),  0,       {OFF_SL_BR_SCALED, REG_BASE_M_LI, REG_DEST}     },
955
  {"ld.h",      OP_REG(0x342) | D(0),    (MASK_REG & ~M_REG(1)) | D(1),  0,       {REG_SCALED, REG_BASE_M_LI, REG_DEST}           },
956
 
957
  /* Load Unsigned Data Into Register */
958
 
959
  {"ld.ub",     OP_SI(0x28),            (MASK_SI  & ~M_SI(1)),          0,       {OFF_SS_BR, REG_BASE_M_SI, REG_DEST}            },
960
  {"ld.ub",     OP_LI(0x351)  | D(0),    (MASK_LI  & ~M_REG(1)) | D(1),  0,       {OFF_SL_BR_SCALED, REG_BASE_M_LI, REG_DEST}     },
961
  {"ld.ub",     OP_REG(0x350) | D(0),    (MASK_REG & ~M_REG(1)) | D(1),  0,       {REG_SCALED, REG_BASE_M_LI, REG_DEST}           },
962
  {"ld.uh",     OP_SI(0x29),            (MASK_SI  & ~M_SI(1)),          0,       {OFF_SS_BR, REG_BASE_M_SI, REG_DEST}            },
963
  {"ld.uh",     OP_LI(0x353)  | D(0),    (MASK_LI  & ~M_REG(1)) | D(1),  0,       {OFF_SL_BR_SCALED, REG_BASE_M_LI, REG_DEST}     },
964
  {"ld.uh",     OP_REG(0x352) | D(0),    (MASK_REG & ~M_REG(1)) | D(1),  0,       {REG_SCALED, REG_BASE_M_LI, REG_DEST}           },
965
 
966
  /* Leftmost one */
967
 
968
  {"lmo",       OP_LI(0x3F0),   MASK_LI,        0,       {REG_22, REG_DEST}      },
969
 
970
  /* Bitwise logical OR.  Note that "or.tt" and "or" are the same instructions. */
971
 
972
  {"or.ff",     OP_SI(0x1E),    MASK_SI,        0,       {SUI, REG_22, REG_DEST}         },
973
  {"or.ff",     OP_LI(0x33D),   MASK_LI,        0,       {LUI, REG_22, REG_DEST}         },
974
  {"or.ff",     OP_REG(0x33C),  MASK_REG,       0,       {REG_0, REG_22, REG_DEST}       },
975
  {"or.ft",     OP_SI(0x1D),    MASK_SI,        0,       {SUI, REG_22, REG_DEST}         },
976
  {"or.ft",     OP_LI(0x33B),   MASK_LI,        0,       {LUI, REG_22, REG_DEST}         },
977
  {"or.ft",     OP_REG(0x33A),  MASK_REG,       0,       {REG_0, REG_22, REG_DEST}       },
978
  {"or.tf",     OP_SI(0x1B),    MASK_SI,        0,       {SUI, REG_22, REG_DEST}         },
979
  {"or.tf",     OP_LI(0x337),   MASK_LI,        0,       {LUI, REG_22, REG_DEST}         },
980
  {"or.tf",     OP_REG(0x336),  MASK_REG,       0,       {REG_0, REG_22, REG_DEST}       },
981
  {"or.tt",     OP_SI(0x17),    MASK_SI,        0,       {SUI, REG_22, REG_DEST}         },
982
  {"or.tt",     OP_LI(0x32F),   MASK_LI,        0,       {LUI, REG_22, REG_DEST}         },
983
  {"or.tt",     OP_REG(0x32E),  MASK_REG,       0,       {REG_0, REG_22, REG_DEST}       },
984
  {"or",        OP_SI(0x17),    MASK_SI,        0,       {SUI, REG_22, REG_DEST}         },
985
  {"or",        OP_LI(0x32F),   MASK_LI,        0,       {LUI, REG_22, REG_DEST}         },
986
  {"or",        OP_REG(0x32E),  MASK_REG,       0,       {REG_0, REG_22, REG_DEST}       },
987
 
988
  /* Read Control Register */
989
 
990
  {"rdcr",      OP_SI(0x4),     MASK_SI  | (0x1F << 22),        0,       {CR_SI, REG_DEST}       },
991
  {"rdcr",      OP_LI(0x309),   MASK_LI  | (0x1F << 22),        0,       {CR_LI, REG_DEST}       },
992
  {"rdcr",      OP_REG(0x308),  MASK_REG | (0x1F << 22),        0,       {REG_0, REG_DEST}       },
993
 
994
  /* Rightmost one */
995
 
996
  {"rmo",       OP_LI(0x3F2),   MASK_LI,        0,               {REG_22, REG_DEST}      },
997
 
998
  /* Shift Register Left - note that rotl, shl, and ins are all alternate names for one of the shift instructions.
999
     They appear prior to their sl equivalent so that they will be diassembled as the alternate name. */
1000
 
1001
 
1002
  {"ins",       OP_REG(0x31E) | i(0) | n(0),      MASK_REG | i(1) | n(1), 0,       {REG_0, ENDMASK, REG_22, REG_DEST}      },
1003
  {"ins",       OP_SI(0xF)    | i(0) | n(0),      MASK_SI  | i(1) | n(1), 0,       {ROTATE, ENDMASK, REG_22, REG_DEST}     },
1004
  {"rotl",      OP_REG(0x310) | i(0) | n(0),      MASK_REG | i(1) | n(1), 0,       {REG_0, ENDMASK, REG_22, REG_DEST}      },
1005
  {"rotl",      OP_SI(0x8)    | i(0) | n(0),      MASK_SI  | i(1) | n(1), 0,       {ROTATE, ENDMASK, REG_22, REG_DEST}     },
1006
  {"shl",       OP_REG(0x31C) | i(0) | n(0),      MASK_REG | i(1) | n(1), 0,       {REG_0, ENDMASK, REG_22, REG_DEST}      },
1007
  {"shl",       OP_SI(0xE)    | i(0) | n(0),      MASK_SI  | i(1) | n(1), 0,       {ROTATE, ENDMASK, REG_22, REG_DEST}     },
1008
  {"sl.dm",     OP_REG(0x312) | i(0) | n(0),      MASK_REG | i(1) | n(1), 0,       {REG_0, ENDMASK, REG_22, REG_DEST}      },
1009
  {"sl.dm",     OP_SI(0x9)    | i(0) | n(0),      MASK_SI  | i(1) | n(1), 0,       {ROTATE, ENDMASK, REG_22, REG_DEST}     },
1010
  {"sl.ds",     OP_REG(0x314) | i(0) | n(0),      MASK_REG | i(1) | n(1), 0,       {REG_0, ENDMASK, REG_22, REG_DEST}      },
1011
  {"sl.ds",     OP_SI(0xA)    | i(0) | n(0),      MASK_SI  | i(1) | n(1), 0,       {ROTATE, ENDMASK, REG_22, REG_DEST}     },
1012
  {"sl.dz",     OP_REG(0x310) | i(0) | n(0),      MASK_REG | i(1) | n(1), 0,       {REG_0, ENDMASK, REG_22, REG_DEST}      },
1013
  {"sl.dz",     OP_SI(0x8)    | i(0) | n(0),      MASK_SI  | i(1) | n(1), 0,       {ROTATE, ENDMASK, REG_22, REG_DEST}     },
1014
  {"sl.em",     OP_REG(0x318) | i(0) | n(0),      MASK_REG | i(1) | n(1), 0,       {REG_0, ENDMASK, REG_22, REG_DEST}      },
1015
  {"sl.em",     OP_SI(0xC)    | i(0) | n(0),      MASK_SI  | i(1) | n(1), 0,       {ROTATE, ENDMASK, REG_22, REG_DEST}     },
1016
  {"sl.es",     OP_REG(0x31A) | i(0) | n(0),      MASK_REG | i(1) | n(1), 0,       {REG_0, ENDMASK, REG_22, REG_DEST}      },
1017
  {"sl.es",     OP_SI(0xD)    | i(0) | n(0),      MASK_SI  | i(1) | n(1), 0,       {ROTATE, ENDMASK, REG_22, REG_DEST}     },
1018
  {"sl.ez",     OP_REG(0x316) | i(0) | n(0),      MASK_REG | i(1) | n(1), 0,       {REG_0, ENDMASK, REG_22, REG_DEST}      },
1019
  {"sl.ez",     OP_SI(0xB)    | i(0) | n(0),      MASK_SI  | i(1) | n(1), 0,       {ROTATE, ENDMASK, REG_22, REG_DEST}     },
1020
  {"sl.im",     OP_REG(0x31E) | i(0) | n(0),      MASK_REG | i(1) | n(1), 0,       {REG_0, ENDMASK, REG_22, REG_DEST}      },
1021
  {"sl.im",     OP_SI(0xF)    | i(0) | n(0),      MASK_SI  | i(1) | n(1), 0,       {ROTATE, ENDMASK, REG_22, REG_DEST}     },
1022
  {"sl.iz",     OP_REG(0x31C) | i(0) | n(0),      MASK_REG | i(1) | n(1), 0,       {REG_0, ENDMASK, REG_22, REG_DEST}      },
1023
  {"sl.iz",     OP_SI(0xE)    | i(0) | n(0),      MASK_SI  | i(1) | n(1), 0,       {ROTATE, ENDMASK, REG_22, REG_DEST}     },
1024
 
1025
  /* Shift Register Left With Inverted Endmask */
1026
 
1027
  {"sli.dm",    OP_REG(0x312) | i(1) | n(0),     MASK_REG | i(1) | n(1), 0,       {REG_0, ENDMASK, REG_22, REG_DEST}      },
1028
  {"sli.dm",    OP_SI(0x9)    | i(1) | n(0),     MASK_SI  | i(1) | n(1), 0,       {ROTATE, ENDMASK, REG_22, REG_DEST}     },
1029
  {"sli.ds",    OP_REG(0x314) | i(1) | n(0),     MASK_REG | i(1) | n(1), 0,       {REG_0, ENDMASK, REG_22, REG_DEST}      },
1030
  {"sli.ds",    OP_SI(0xA)    | i(1) | n(0),     MASK_SI  | i(1) | n(1), 0,       {ROTATE, ENDMASK, REG_22, REG_DEST}     },
1031
  {"sli.dz",    OP_REG(0x310) | i(1) | n(0),     MASK_REG | i(1) | n(1), 0,       {REG_0, ENDMASK, REG_22, REG_DEST}      },
1032
  {"sli.dz",    OP_SI(0x8)    | i(1) | n(0),     MASK_SI  | i(1) | n(1), 0,       {ROTATE, ENDMASK, REG_22, REG_DEST}     },
1033
  {"sli.em",    OP_REG(0x318) | i(1) | n(0),     MASK_REG | i(1) | n(1), 0,       {REG_0, ENDMASK, REG_22, REG_DEST}      },
1034
  {"sli.em",    OP_SI(0xC)    | i(1) | n(0),     MASK_SI  | i(1) | n(1), 0,       {ROTATE, ENDMASK, REG_22, REG_DEST}     },
1035
  {"sli.es",    OP_REG(0x31A) | i(1) | n(0),     MASK_REG | i(1) | n(1), 0,       {REG_0, ENDMASK, REG_22, REG_DEST}      },
1036
  {"sli.es",    OP_SI(0xD)    | i(1) | n(0),     MASK_SI  | i(1) | n(1), 0,       {ROTATE, ENDMASK, REG_22, REG_DEST}     },
1037
  {"sli.ez",    OP_REG(0x316) | i(1) | n(0),     MASK_REG | i(1) | n(1), 0,       {REG_0, ENDMASK, REG_22, REG_DEST}      },
1038
  {"sli.ez",    OP_SI(0xB)    | i(1) | n(0),     MASK_SI  | i(1) | n(1), 0,       {ROTATE, ENDMASK, REG_22, REG_DEST}     },
1039
  {"sli.im",    OP_REG(0x31E) | i(1) | n(0),     MASK_REG | i(1) | n(1), 0,       {REG_0, ENDMASK, REG_22, REG_DEST}      },
1040
  {"sli.im",    OP_SI(0xF)    | i(1) | n(0),     MASK_SI  | i(1) | n(1), 0,       {ROTATE, ENDMASK, REG_22, REG_DEST}     },
1041
  {"sli.iz",    OP_REG(0x31C) | i(1) | n(0),     MASK_REG | i(1) | n(1), 0,       {REG_0, ENDMASK, REG_22, REG_DEST}      },
1042
  {"sli.iz",    OP_SI(0xE)    | i(1) | n(0),     MASK_SI  | i(1) | n(1), 0,       {ROTATE, ENDMASK, REG_22, REG_DEST}     },
1043
 
1044
  /* Shift Register Right - note that exts, extu, rotr, sra, and srl are all alternate names for one of the shift instructions.
1045
     They appear prior to their sr equivalent so that they will be diassembled as the alternate name. */
1046
 
1047
  {"exts",      OP_REG(0x314) | i(0) | n(1),     MASK_REG | i(1) | n(1), 0,       {REG_0, ENDMASK, REG_22, REG_DEST}      },
1048
  {"exts",      OP_SI(0xA)    | i(0) | n(1),     MASK_SI  | i(1) | n(1), 0,       {ROTATE, ENDMASK, REG_22, REG_DEST}     },
1049
  {"extu",      OP_REG(0x310) | i(0) | n(1),     MASK_REG | i(1) | n(1), 0,       {REG_0, ENDMASK, REG_22, REG_DEST}      },
1050
  {"extu",      OP_SI(0x8)    | i(0) | n(1),     MASK_SI  | i(1) | n(1), 0,       {ROTATE, ENDMASK, REG_22, REG_DEST}     },
1051
  {"rotr",      OP_REG(0x310) | i(0) | n(1),     MASK_REG | i(1) | n(1), 0,       {REG_0, ENDMASK, REG_22, REG_DEST}      },
1052
  {"rotr",      OP_SI(0x8)    | i(0) | n(1),     MASK_SI  | i(1) | n(1), 0,       {ROTATE, ENDMASK, REG_22, REG_DEST}     },
1053
  {"sra",       OP_REG(0x31A) | i(0) | n(1),     MASK_REG | i(1) | n(1), 0,       {REG_0, ENDMASK, REG_22, REG_DEST}      },
1054
  {"sra",       OP_SI(0xD)    | i(0) | n(1),     MASK_SI  | i(1) | n(1), 0,       {ROTATE, ENDMASK, REG_22, REG_DEST}     },
1055
  {"srl",       OP_REG(0x316) | i(0) | n(1),     MASK_REG | i(1) | n(1), 0,       {REG_0, ENDMASK, REG_22, REG_DEST}      },
1056
  {"srl",       OP_SI(0xB)    | i(0) | n(1),     MASK_SI  | i(1) | n(1), 0,       {ROTATE, ENDMASK, REG_22, REG_DEST}     },
1057
  {"sr.dm",     OP_REG(0x312) | i(0) | n(1),     MASK_REG | i(1) | n(1), 0,       {REG_0, ENDMASK, REG_22, REG_DEST}      },
1058
  {"sr.dm",     OP_SI(0x9)    | i(0) | n(1),     MASK_SI  | i(1) | n(1), 0,       {ROTATE, ENDMASK, REG_22, REG_DEST}     },
1059
  {"sr.ds",     OP_REG(0x314) | i(0) | n(1),     MASK_REG | i(1) | n(1), 0,       {REG_0, ENDMASK, REG_22, REG_DEST}      },
1060
  {"sr.ds",     OP_SI(0xA)    | i(0) | n(1),     MASK_SI  | i(1) | n(1), 0,       {ROTATE, ENDMASK, REG_22, REG_DEST}     },
1061
  {"sr.dz",     OP_REG(0x310) | i(0) | n(1),     MASK_REG | i(1) | n(1), 0,       {REG_0, ENDMASK, REG_22, REG_DEST}      },
1062
  {"sr.dz",     OP_SI(0x8)    | i(0) | n(1),     MASK_SI  | i(1) | n(1), 0,       {ROTATE, ENDMASK, REG_22, REG_DEST}     },
1063
  {"sr.em",     OP_REG(0x318) | i(0) | n(1),     MASK_REG | i(1) | n(1), 0,       {REG_0, ENDMASK, REG_22, REG_DEST}      },
1064
  {"sr.em",     OP_SI(0xC)    | i(0) | n(1),     MASK_SI  | i(1) | n(1), 0,       {ROTATE, ENDMASK, REG_22, REG_DEST}     },
1065
  {"sr.es",     OP_REG(0x31A) | i(0) | n(1),     MASK_REG | i(1) | n(1), 0,       {REG_0, ENDMASK, REG_22, REG_DEST}      },
1066
  {"sr.es",     OP_SI(0xD)    | i(0) | n(1),     MASK_SI  | i(1) | n(1), 0,       {ROTATE, ENDMASK, REG_22, REG_DEST}     },
1067
  {"sr.ez",     OP_REG(0x316) | i(0) | n(1),     MASK_REG | i(1) | n(1), 0,       {REG_0, ENDMASK, REG_22, REG_DEST}      },
1068
  {"sr.ez",     OP_SI(0xB)    | i(0) | n(1),     MASK_SI  | i(1) | n(1), 0,       {ROTATE, ENDMASK, REG_22, REG_DEST}     },
1069
  {"sr.im",     OP_REG(0x31E) | i(0) | n(1),     MASK_REG | i(1) | n(1), 0,       {REG_0, ENDMASK, REG_22, REG_DEST}      },
1070
  {"sr.im",     OP_SI(0xF)    | i(0) | n(1),     MASK_SI  | i(1) | n(1), 0,       {ROTATE, ENDMASK, REG_22, REG_DEST}     },
1071
  {"sr.iz",     OP_REG(0x31C) | i(0) | n(1),     MASK_REG | i(1) | n(1), 0,       {REG_0, ENDMASK, REG_22, REG_DEST}      },
1072
  {"sr.iz",     OP_SI(0xE)    | i(0) | n(1),     MASK_SI  | i(1) | n(1), 0,       {ROTATE, ENDMASK, REG_22, REG_DEST}     },
1073
 
1074
  /* Shift Register Right With Inverted Endmask */
1075
 
1076
  {"sri.dm",    OP_REG(0x312) | i(1) | n(1),    MASK_REG | i(1) | n(1), 0,       {REG_0, ENDMASK, REG_22, REG_DEST}      },
1077
  {"sri.dm",    OP_SI(0x9)    | i(1) | n(1),    MASK_SI  | i(1) | n(1), 0,       {ROTATE, ENDMASK, REG_22, REG_DEST}     },
1078
  {"sri.ds",    OP_REG(0x314) | i(1) | n(1),    MASK_REG | i(1) | n(1), 0,       {REG_0, ENDMASK, REG_22, REG_DEST}      },
1079
  {"sri.ds",    OP_SI(0xA)    | i(1) | n(1),    MASK_SI  | i(1) | n(1), 0,       {ROTATE, ENDMASK, REG_22, REG_DEST}     },
1080
  {"sri.dz",    OP_REG(0x310) | i(1) | n(1),    MASK_REG | i(1) | n(1), 0,       {REG_0, ENDMASK, REG_22, REG_DEST}      },
1081
  {"sri.dz",    OP_SI(0x8)    | i(1) | n(1),    MASK_SI  | i(1) | n(1), 0,       {ROTATE, ENDMASK, REG_22, REG_DEST}     },
1082
  {"sri.em",    OP_REG(0x318) | i(1) | n(1),    MASK_REG | i(1) | n(1), 0,       {REG_0, ENDMASK, REG_22, REG_DEST}      },
1083
  {"sri.em",    OP_SI(0xC)    | i(1) | n(1),    MASK_SI  | i(1) | n(1), 0,       {ROTATE, ENDMASK, REG_22, REG_DEST}     },
1084
  {"sri.es",    OP_REG(0x31A) | i(1) | n(1),    MASK_REG | i(1) | n(1), 0,       {REG_0, ENDMASK, REG_22, REG_DEST}      },
1085
  {"sri.es",    OP_SI(0xD)    | i(1) | n(1),    MASK_SI  | i(1) | n(1), 0,       {ROTATE, ENDMASK, REG_22, REG_DEST}     },
1086
  {"sri.ez",    OP_REG(0x316) | i(1) | n(1),    MASK_REG | i(1) | n(1), 0,       {REG_0, ENDMASK, REG_22, REG_DEST}      },
1087
  {"sri.ez",    OP_SI(0xB)    | i(1) | n(1),    MASK_SI  | i(1) | n(1), 0,       {ROTATE, ENDMASK, REG_22, REG_DEST}     },
1088
  {"sri.im",    OP_REG(0x31E) | i(1) | n(1),    MASK_REG | i(1) | n(1), 0,       {REG_0, ENDMASK, REG_22, REG_DEST}      },
1089
  {"sri.im",    OP_SI(0xF)    | i(1) | n(1),    MASK_SI  | i(1) | n(1), 0,       {ROTATE, ENDMASK, REG_22, REG_DEST}     },
1090
  {"sri.iz",    OP_REG(0x31C) | i(1) | n(1),    MASK_REG | i(1) | n(1), 0,       {REG_0, ENDMASK, REG_22, REG_DEST}      },
1091
  {"sri.iz",    OP_SI(0xE)    | i(1) | n(1),    MASK_SI  | i(1) | n(1), 0,       {ROTATE, ENDMASK, REG_22, REG_DEST}     },
1092
 
1093
  /* Store Data into Memory */
1094
 
1095
  {"st",        OP_SI(0x32),            (MASK_SI  & ~M_SI(1)),          0,       {OFF_SS_BR, REG_BASE_M_SI, REG_DEST}            },
1096
  {"st",        OP_LI(0x365)  | D(0),    (MASK_LI  & ~M_REG(1)) | D(1),  0,       {OFF_SL_BR_SCALED, REG_BASE_M_LI, REG_DEST}     },
1097
  {"st",        OP_REG(0x364) | D(0),    (MASK_REG & ~M_REG(1)) | D(1),  0,       {REG_SCALED, REG_BASE_M_LI, REG_DEST}           },
1098
  {"st.b",      OP_SI(0x30),            (MASK_SI  & ~M_SI(1)),          0,       {OFF_SS_BR, REG_BASE_M_SI, REG_DEST}            },
1099
  {"st.b",      OP_LI(0x361)  | D(0),    (MASK_LI  & ~M_REG(1)) | D(1),  0,       {OFF_SL_BR_SCALED, REG_BASE_M_LI, REG_DEST}     },
1100
  {"st.b",      OP_REG(0x360) | D(0),    (MASK_REG & ~M_REG(1)) | D(1),  0,       {REG_SCALED, REG_BASE_M_LI, REG_DEST}           },
1101
  {"st.d",      OP_SI(0x33),            (MASK_SI  & ~M_SI(1)),          0,       {OFF_SS_BR, REG_BASE_M_SI, REG_DEST_E}          },
1102
  {"st.d",      OP_LI(0x367)  | D(0),    (MASK_LI  & ~M_REG(1)) | D(1),  0,       {OFF_SL_BR_SCALED, REG_BASE_M_LI, REG_DEST_E}   },
1103
  {"st.d",      OP_REG(0x366) | D(0),    (MASK_REG & ~M_REG(1)) | D(1),  0,       {REG_SCALED, REG_BASE_M_LI, REG_DEST_E}         },
1104
  {"st.h",      OP_SI(0x31),            (MASK_SI  & ~M_SI(1)),          0,       {OFF_SS_BR, REG_BASE_M_SI, REG_DEST}            },
1105
  {"st.h",      OP_LI(0x363)  | D(0),    (MASK_LI  & ~M_REG(1)) | D(1),  0,       {OFF_SL_BR_SCALED, REG_BASE_M_LI, REG_DEST}     },
1106
  {"st.h",      OP_REG(0x362) | D(0),    (MASK_REG & ~M_REG(1)) | D(1),  0,       {REG_SCALED, REG_BASE_M_LI, REG_DEST}           },
1107
 
1108
  /* Signed Integer Subtract */
1109
 
1110
  {"sub",       OP_SI(0x5A),    MASK_SI,        0,       {SSI, REG_22, REG_DEST}         },
1111
  {"sub",       OP_LI(0x3B5),   MASK_LI,        0,       {LSI, REG_22, REG_DEST}         },
1112
  {"sub",       OP_REG(0x3B4),  MASK_REG,       0,       {REG_0, REG_22, REG_DEST}       },
1113
 
1114
  /* Unsigned Integer Subtract */
1115
 
1116
  {"subu",      OP_SI(0x5B),    MASK_SI,        0,       {SSI, REG_22, REG_DEST}         },
1117
  {"subu",      OP_LI(0x3B7),   MASK_LI,        0,       {LSI, REG_22, REG_DEST}         },
1118
  {"subu",      OP_REG(0x3B6),  MASK_REG,       0,       {REG_0, REG_22, REG_DEST}       },
1119
 
1120
  /* Write Control Register
1121
     Is a special form of the "swcr" instruction so comes before it in the table. */
1122
 
1123
  {"wrcr",      OP_SI(0x5),     MASK_SI | (0x1F << 27),         0,       {CR_SI, REG_22} },
1124
  {"wrcr",      OP_LI(0x30B),   MASK_LI | (0x1F << 27),         0,       {CR_LI, REG_22} },
1125
  {"wrcr",      OP_REG(0x30A),  MASK_REG | (0x1F << 27),        0,       {REG_0, REG_22} },
1126
 
1127
  /* Swap Control Register */
1128
 
1129
  {"swcr",      OP_SI(0x5),     MASK_SI,        0,       {CR_SI, REG_22, REG_DEST}       },
1130
  {"swcr",      OP_LI(0x30B),   MASK_LI,        0,       {CR_LI, REG_22, REG_DEST}       },
1131
  {"swcr",      OP_REG(0x30A),  MASK_REG,       0,       {REG_0, REG_22, REG_DEST}       },
1132
 
1133
  /* Trap */
1134
 
1135
  {"trap",      OP_SI(0x1)    | E(0),    MASK_SI  | E(1),        0,       {SUI}   },
1136
  {"trap",      OP_LI(0x303)  | E(0),    MASK_LI  | E(1),        0,       {LUI}   },
1137
  {"trap",      OP_REG(0x302) | E(0),    MASK_REG | E(1),        0,       {REG_0} },
1138
 
1139
  /* Vector Floating-Point Add */
1140
 
1141
  {"vadd.dd",   OP_REG(0x3C0) | P2(1) | P1(1),  MASK_REG | V_a1(1) | P2(1) | P1(1),     TIC80_VECTOR,   {REG_0_E, REG_22_E, REG_22_E}   },
1142
  {"vadd.sd",   OP_LI(0x3C1)  | P2(1) | P1(0),   MASK_LI  | V_a1(1) | P2(1) | P1(1),     TIC80_VECTOR,   {SPFI, REG_22_E, REG_22_E}      },
1143
  {"vadd.sd",   OP_REG(0x3C0) | P2(1) | P1(0),   MASK_REG | V_a1(1) | P2(1) | P1(1),     TIC80_VECTOR,   {REG_0, REG_22_E, REG_22_E}     },
1144
  {"vadd.ss",   OP_LI(0x3C1)  | P2(0) | P1(0),    MASK_LI  | V_a1(1) | P2(1) | P1(1),     TIC80_VECTOR,   {SPFI, REG_22, REG_22}  },
1145
  {"vadd.ss",   OP_REG(0x3C0) | P2(0) | P1(0),    MASK_REG | V_a1(1) | P2(1) | P1(1),     TIC80_VECTOR,   {REG_0, REG_22, REG_22} },
1146
 
1147
  /* Vector Floating-Point Multiply and Add to Accumulator FIXME! This is not yet fully implemented.
1148
   From the documentation there appears to be no way to tell the difference between the opcodes for
1149
   instructions that have register destinations and instructions that have accumulator destinations.
1150
   Further investigation is necessary.  Since this isn't critical to getting a TIC80 toolchain up
1151
   and running, it is defered until later. */
1152
 
1153
  /* Vector Floating-Point Multiply
1154
   Note: If r0 is in the destination reg, then this is a "vector nop" instruction. */
1155
 
1156
  {"vmpy.dd",   OP_REG(0x3C4) | P2(1) | P1(1),  MASK_REG | V_a1(1) | P2(1) | P1(1),     TIC80_VECTOR | TIC80_NO_R0_DEST, {REG_0_E, REG_22_E, REG_22_E} },
1157
  {"vmpy.sd",   OP_LI(0x3C5)  | P2(1) | P1(0),   MASK_LI  | V_a1(1) | P2(1) | P1(1),     TIC80_VECTOR | TIC80_NO_R0_DEST, {SPFI, REG_22_E, REG_22_E}     },
1158
  {"vmpy.sd",   OP_REG(0x3C4) | P2(1) | P1(0),   MASK_REG | V_a1(1) | P2(1) | P1(1),     TIC80_VECTOR | TIC80_NO_R0_DEST, {REG_0, REG_22_E, REG_22_E} },
1159
  {"vmpy.ss",   OP_LI(0x3C5)  | P2(0) | P1(0),    MASK_LI  | V_a1(1) | P2(1) | P1(1),     TIC80_VECTOR | TIC80_NO_R0_DEST, {SPFI, REG_22, REG_22} },
1160
  {"vmpy.ss",   OP_REG(0x3C4) | P2(0) | P1(0),    MASK_REG | V_a1(1) | P2(1) | P1(1),     TIC80_VECTOR | TIC80_NO_R0_DEST, {REG_0, REG_22, REG_22} },
1161
 
1162
  /* Vector Floating-Point Multiply and Subtract from Accumulator
1163
     FIXME: See note above for vmac instruction */
1164
 
1165
  /* Vector Floating-Point Subtract Accumulator From Source
1166
     FIXME: See note above for vmac instruction */
1167
 
1168
  /* Vector Round With Floating-Point Input
1169
     FIXME: See note above for vmac instruction */
1170
 
1171
  /* Vector Round with Integer Input */
1172
 
1173
  {"vrnd.id",   OP_LI (0x3CB)  | P2(1) | P1(0),  MASK_LI  | V_a0(1) | V_Z(1) | P2(1) | P1(1),    TIC80_VECTOR, {LSI, REG_22_E}},
1174
  {"vrnd.id",   OP_REG (0x3CA) | P2(1) | P1(0),  MASK_REG | V_a0(1) | V_Z(1) | P2(1) | P1(1),    TIC80_VECTOR, {REG_0, REG_22_E}},
1175
  {"vrnd.is",   OP_LI (0x3CB)  | P2(0) | P1(0),   MASK_LI  | V_a0(1) | V_Z(1) | P2(1) | P1(1),    TIC80_VECTOR, {LSI, REG_22}},
1176
  {"vrnd.is",   OP_REG (0x3CA) | P2(0) | P1(0),   MASK_REG | V_a0(1) | V_Z(1) | P2(1) | P1(1),    TIC80_VECTOR, {REG_0, REG_22}},
1177
  {"vrnd.ud",   OP_LI (0x3CB)  | P2(1) | P1(1), MASK_LI  | V_a0(1) | V_Z(1) | P2(1) | P1(1),    TIC80_VECTOR, {LUI, REG_22_E}},
1178
  {"vrnd.ud",   OP_REG (0x3CA) | P2(1) | P1(1), MASK_REG | V_a0(1) | V_Z(1) | P2(1) | P1(1),    TIC80_VECTOR, {REG_0, REG_22_E}},
1179
  {"vrnd.us",   OP_LI (0x3CB)  | P2(0) | P1(1),  MASK_LI  | V_a0(1) | V_Z(1) | P2(1) | P1(1),    TIC80_VECTOR, {LUI, REG_22}},
1180
  {"vrnd.us",   OP_REG (0x3CA) | P2(0) | P1(1),  MASK_REG | V_a0(1) | V_Z(1) | P2(1) | P1(1),    TIC80_VECTOR, {REG_0, REG_22}},
1181
 
1182
  /* Vector Floating-Point Subtract */
1183
 
1184
  {"vsub.dd",   OP_REG(0x3C2) | P2(1) | P1(1),  MASK_REG | V_a1(1) | P2(1) | P1(1),     TIC80_VECTOR,   {REG_0_E, REG_22_E, REG_22_E}   },
1185
  {"vsub.sd",   OP_LI(0x3C3)  | P2(1) | P1(0),   MASK_LI  | V_a1(1) | P2(1) | P1(1),     TIC80_VECTOR,   {SPFI, REG_22_E, REG_22_E}      },
1186
  {"vsub.sd",   OP_REG(0x3C2) | P2(1) | P1(0),   MASK_REG | V_a1(1) | P2(1) | P1(1),     TIC80_VECTOR,   {REG_0, REG_22_E, REG_22_E}     },
1187
  {"vsub.ss",   OP_LI(0x3C3)  | P2(0) | P1(0),    MASK_LI  | V_a1(1) | P2(1) | P1(1),     TIC80_VECTOR,   {SPFI, REG_22, REG_22}  },
1188
  {"vsub.ss",   OP_REG(0x3C2) | P2(0) | P1(0),    MASK_REG | V_a1(1) | P2(1) | P1(1),     TIC80_VECTOR,   {REG_0, REG_22, REG_22} },
1189
 
1190
  /* Vector Load Data Into Register - Note that the vector load/store instructions come after the other
1191
   vector instructions so that the disassembler will always print the load/store instruction second for
1192
   vector instructions that have two instructions in the same opcode. */
1193
 
1194
  {"vld0.d",    OP_V(0x1E) | V_m(1) | V_S(1) | V_p(0),   MASK_V | V_m(1) | V_S(1) | V_p(1),      TIC80_VECTOR, {REG_DEST_E} },
1195
  {"vld0.s",    OP_V(0x1E) | V_m(1) | V_S(0) | V_p(0),    MASK_V | V_m(1) | V_S(1) | V_p(1),      TIC80_VECTOR, {REG_DEST} },
1196
  {"vld1.d",    OP_V(0x1E) | V_m(1) | V_S(1) | V_p(1),  MASK_V | V_m(1) | V_S(1) | V_p(1),      TIC80_VECTOR, {REG_DEST_E} },
1197
  {"vld1.s",    OP_V(0x1E) | V_m(1) | V_S(0) | V_p(1),   MASK_V | V_m(1) | V_S(1) | V_p(1),      TIC80_VECTOR, {REG_DEST} },
1198
 
1199
  /* Vector Store Data Into Memory - Note that the vector load/store instructions come after the other
1200
   vector instructions so that the disassembler will always print the load/store instruction second for
1201
   vector instructions that have two instructions in the same opcode. */
1202
 
1203
  {"vst.d",     OP_V(0x1E) | V_m(0) | V_S(1) | V_p(1),   MASK_V | V_m(1) | V_S(1) | V_p(1),      TIC80_VECTOR, {REG_DEST_E} },
1204
  {"vst.s",     OP_V(0x1E) | V_m(0) | V_S(0) | V_p(1),    MASK_V | V_m(1) | V_S(1) | V_p(1),      TIC80_VECTOR, {REG_DEST} },
1205
 
1206
  {"xnor",      OP_SI(0x19),    MASK_SI,        0,       {SUBF, REG_22, REG_DEST} },
1207
  {"xnor",      OP_LI(0x333),   MASK_LI,        0,       {LUBF, REG_22, REG_DEST} },
1208
  {"xnor",      OP_REG(0x332),  MASK_REG,       0,       {REG_0, REG_22, REG_DEST} },
1209
 
1210
  {"xor",       OP_SI(0x16),    MASK_SI,        0,       {SUBF, REG_22, REG_DEST} },
1211
  {"xor",       OP_LI(0x32D),   MASK_LI,        0,       {LUBF, REG_22, REG_DEST} },
1212
  {"xor",       OP_REG(0x32C),  MASK_REG,       0,       {REG_0, REG_22, REG_DEST} },
1213
 
1214
};
1215
 
1216
const int tic80_num_opcodes = sizeof (tic80_opcodes) / sizeof (tic80_opcodes[0]);

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