2010-06-16 Vincent Rivire <vincent.riviere@freesbee.fr>
[binutils.git] / opcodes / tic80-opc.c
blob70e38ec511f898f0b488584f2e4170fd4434c3cc
1 /* Opcode table for TI TMS320C80 (MVP).
2 Copyright 1996, 1997, 2000, 2005, 2007 Free Software Foundation, Inc.
4 This file is part of the GNU opcodes library.
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.
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.
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. */
21 #include <stdio.h>
22 #include "sysdep.h"
23 #include "opcode/tic80.h"
25 /* This file holds various tables for the TMS320C80 (MVP).
27 The opcode table is strictly constant data, so the compiler should
28 be able to put it in the .text section.
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.
34 The predefined register table maps from register names to register
35 values. */
38 /* Table of predefined symbol names, such as general purpose registers,
39 floating point registers, condition codes, control registers, and bit
40 numbers.
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.
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.
52 const struct predefined_symbol tic80_predefined_symbols[] =
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 },
216 const int tic80_num_predefined_symbols = sizeof (tic80_predefined_symbols) / sizeof (struct predefined_symbol);
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.
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.
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.
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.
236 tic80_symbol_to_value (name, symbol_class)
237 char *name;
238 int symbol_class;
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;
247 while (low <= high)
249 middle = (low + high) / 2;
250 cmp = strcasecmp (name, tic80_predefined_symbols[middle].name);
251 if (cmp < 0)
253 high = middle - 1;
255 else if (cmp > 0)
257 low = middle + 1;
259 else
261 pdsp = &tic80_predefined_symbols[middle];
262 if ((symbol_class == 0) || (symbol_class & PDS_VALUE (pdsp)))
264 rtnval = PDS_VALUE (pdsp);
266 /* For now we assume that there are no duplicate names */
267 break;
270 return (rtnval);
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. */
277 const char *
278 tic80_value_to_symbol (val, symbol_class)
279 int val;
280 int symbol_class;
282 const struct predefined_symbol *pdsp;
283 int ival;
284 char *name;
286 name = NULL;
287 for (pdsp = tic80_predefined_symbols;
288 pdsp < tic80_predefined_symbols + tic80_num_predefined_symbols;
289 pdsp++)
291 ival = PDS_VALUE (pdsp) & ~TIC80_OPERAND_MASK;
292 if (ival == val)
294 if ((symbol_class == 0) || (symbol_class & PDS_VALUE (pdsp)))
296 /* Found the desired match */
297 name = PDS_NAME (pdsp);
298 break;
302 return (name);
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. */
312 const struct predefined_symbol *
313 tic80_next_predefined_symbol (pdsp)
314 const struct predefined_symbol *pdsp;
316 if (pdsp == NULL)
318 pdsp = tic80_predefined_symbols;
320 else if (pdsp >= tic80_predefined_symbols &&
321 pdsp < tic80_predefined_symbols + tic80_num_predefined_symbols - 1)
323 pdsp++;
325 else
327 pdsp = NULL;
329 return (pdsp);
334 /* The operands table. The fields are:
336 bits, shift, insertion function, extraction function, flags
339 const struct tic80_operand tic80_operands[] =
342 /* The zero index is used to indicate the end of the list of operands. */
344 #define UNUSED (0)
345 { 0, 0, 0, 0, 0 },
347 /* Short signed immediate value in bits 14-0. */
349 #define SSI (UNUSED + 1)
350 { 15, 0, NULL, NULL, TIC80_OPERAND_SIGNED },
352 /* Short unsigned immediate value in bits 14-0 */
354 #define SUI (SSI + 1)
355 { 15, 0, NULL, NULL, 0 },
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. */
361 #define SUBF (SUI + 1)
362 { 15, 0, NULL, NULL, TIC80_OPERAND_BITFIELD },
364 /* Long signed immediate in following 32 bit word */
366 #define LSI (SUBF + 1)
367 { 32, 0, NULL, NULL, TIC80_OPERAND_SIGNED },
369 /* Long unsigned immediate in following 32 bit word */
371 #define LUI (LSI + 1)
372 { 32, 0, NULL, NULL, 0 },
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. */
378 #define LUBF (LUI + 1)
379 { 32, 0, NULL, NULL, TIC80_OPERAND_BITFIELD },
381 /* Single precision floating point immediate in following 32 bit
382 word. */
384 #define SPFI (LUBF + 1)
385 { 32, 0, NULL, NULL, TIC80_OPERAND_FLOAT },
387 /* Register in bits 4-0 */
389 #define REG_0 (SPFI + 1)
390 { 5, 0, NULL, NULL, TIC80_OPERAND_GPR },
392 /* Even register in bits 4-0 */
394 #define REG_0_E (REG_0 + 1)
395 { 5, 0, NULL, NULL, TIC80_OPERAND_GPR | TIC80_OPERAND_EVEN },
397 /* Register in bits 26-22 */
399 #define REG_22 (REG_0_E + 1)
400 { 5, 22, NULL, NULL, TIC80_OPERAND_GPR },
402 /* Even register in bits 26-22 */
404 #define REG_22_E (REG_22 + 1)
405 { 5, 22, NULL, NULL, TIC80_OPERAND_GPR | TIC80_OPERAND_EVEN },
407 /* Register in bits 31-27 */
409 #define REG_DEST (REG_22_E + 1)
410 { 5, 27, NULL, NULL, TIC80_OPERAND_GPR },
412 /* Even register in bits 31-27 */
414 #define REG_DEST_E (REG_DEST + 1)
415 { 5, 27, NULL, NULL, TIC80_OPERAND_GPR | TIC80_OPERAND_EVEN },
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. */
422 #define REG_FPA (REG_DEST_E + 1)
423 { 0, 0, NULL, NULL, TIC80_OPERAND_FPA },
425 /* Short signed PC word offset in bits 14-0 */
427 #define OFF_SS_PC (REG_FPA + 1)
428 { 15, 0, NULL, NULL, TIC80_OPERAND_PCREL | TIC80_OPERAND_SIGNED },
430 /* Long signed PC word offset in following 32 bit word */
432 #define OFF_SL_PC (OFF_SS_PC + 1)
433 { 32, 0, NULL, NULL, TIC80_OPERAND_PCREL | TIC80_OPERAND_SIGNED },
435 /* Short signed base relative byte offset in bits 14-0 */
437 #define OFF_SS_BR (OFF_SL_PC + 1)
438 { 15, 0, NULL, NULL, TIC80_OPERAND_BASEREL | TIC80_OPERAND_SIGNED },
440 /* Long signed base relative byte offset in following 32 bit word */
442 #define OFF_SL_BR (OFF_SS_BR + 1)
443 { 32, 0, NULL, NULL, TIC80_OPERAND_BASEREL | TIC80_OPERAND_SIGNED },
445 /* Long signed base relative byte offset in following 32 bit word
446 with optional ":s" modifier flag in bit 11 */
448 #define OFF_SL_BR_SCALED (OFF_SL_BR + 1)
449 { 32, 0, NULL, NULL, TIC80_OPERAND_BASEREL | TIC80_OPERAND_SIGNED | TIC80_OPERAND_SCALED },
451 /* BITNUM in bits 31-27 */
453 #define BITNUM (OFF_SL_BR_SCALED + 1)
454 { 5, 27, NULL, NULL, TIC80_OPERAND_BITNUM },
456 /* Condition code in bits 31-27 */
458 #define CC (BITNUM + 1)
459 { 5, 27, NULL, NULL, TIC80_OPERAND_CC },
461 /* Control register number in bits 14-0 */
463 #define CR_SI (CC + 1)
464 { 15, 0, NULL, NULL, TIC80_OPERAND_CR },
466 /* Control register number in next 32 bit word */
468 #define CR_LI (CR_SI + 1)
469 { 32, 0, NULL, NULL, TIC80_OPERAND_CR },
471 /* A base register in bits 26-22, enclosed in parens */
473 #define REG_BASE (CR_LI + 1)
474 { 5, 22, NULL, NULL, TIC80_OPERAND_GPR | TIC80_OPERAND_PARENS },
476 /* A base register in bits 26-22, enclosed in parens, with optional ":m"
477 flag in bit 17 (short immediate instructions only) */
479 #define REG_BASE_M_SI (REG_BASE + 1)
480 { 5, 22, NULL, NULL, TIC80_OPERAND_GPR | TIC80_OPERAND_PARENS | TIC80_OPERAND_M_SI },
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) */
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 },
488 /* Scaled register in bits 4-0, with optional ":s" modifier flag in bit 11 */
490 #define REG_SCALED (REG_BASE_M_LI + 1)
491 { 5, 0, NULL, NULL, TIC80_OPERAND_GPR | TIC80_OPERAND_SCALED },
493 /* Unsigned immediate in bits 4-0, used only for shift instructions */
495 #define ROTATE (REG_SCALED + 1)
496 { 5, 0, NULL, NULL, 0 },
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 },
504 const int tic80_num_operands = sizeof (tic80_operands)/sizeof(*tic80_operands);
507 /* Macros used to generate entries for the opcodes table. */
509 #define FIXME 0
511 /* Short-Immediate Format Instructions - basic opcode */
512 #define OP_SI(x) (((x) & 0x7F) << 15)
513 #define MASK_SI OP_SI(0x7F)
515 /* Long-Immediate Format Instructions - basic opcode */
516 #define OP_LI(x) (((x) & 0x3FF) << 12)
517 #define MASK_LI OP_LI(0x3FF)
519 /* Register Format Instructions - basic opcode */
520 #define OP_REG(x) OP_LI(x) /* For readability */
521 #define MASK_REG MASK_LI /* For readability */
523 /* The 'n' bit at bit 10 */
524 #define n(x) ((x) << 10)
526 /* The 'i' bit at bit 11 */
527 #define i(x) ((x) << 11)
529 /* The 'F' bit at bit 27 */
530 #define F(x) ((x) << 27)
532 /* The 'E' bit at bit 27 */
533 #define E(x) ((x) << 27)
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)
539 /* The 'M' bit at bit 17 in short immediate opcodes */
540 #define M_SI(x) ((x) << 17)
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)
546 /* The 'SZ' field at bits 16-15 in short immediate opcodes */
547 #define SZ_SI(x) ((x) << 15)
549 /* The 'D' (direct external memory access) bit at bit 10 in long immediate
550 and register opcodes. */
551 #define D(x) ((x) << 10)
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)
557 /* The 'PD' field at bits 10-9 in floating point instructions */
558 #define PD(x) ((x) << 9)
560 /* The 'P2' field at bits 8-7 in floating point instructions */
561 #define P2(x) ((x) << 7)
563 /* The 'P1' field at bits 6-5 in floating point instructions */
564 #define P1(x) ((x) << 5)
566 /* The 'a' field at bit 16 in vector instructions */
567 #define V_a1(x) ((x) << 16)
569 /* The 'a' field at bit 11 in vector instructions */
570 #define V_a0(x) ((x) << 11)
572 /* The 'm' field at bit 10 in vector instructions */
573 #define V_m(x) ((x) << 10)
575 /* The 'S' field at bit 9 in vector instructions */
576 #define V_S(x) ((x) << 9)
578 /* The 'Z' field at bit 8 in vector instructions */
579 #define V_Z(x) ((x) << 8)
581 /* The 'p' field at bit 6 in vector instructions */
582 #define V_p(x) ((x) << 6)
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)
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. */
597 const struct tic80_opcode tic80_opcodes[] = {
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. */
603 {"nop", OP_SI(0x4), ~0, 0, {0} },
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. */
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} },
615 /* Signed integer ADD */
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} },
621 /* Unsigned integer ADD */
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} },
627 /* Bitwise AND */
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} },
636 /* Bitwise AND with ones complement of both sources */
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} },
642 /* Bitwise AND with ones complement of source 1 */
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} },
648 /* Bitwise AND with ones complement of source 2 */
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} },
654 /* Branch Bit One - nonannulled */
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} },
660 /* Branch Bit One - annulled */
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} },
666 /* Branch Bit Zero - nonannulled */
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} },
672 /* Branch Bit Zero - annulled */
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} },
678 /* Branch Conditional - nonannulled */
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} },
684 /* Branch Conditional - annulled */
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} },
690 /* Branch Control Register */
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} },
696 /* Branch and save return - nonannulled */
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} },
702 /* Branch and save return - annulled */
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} },
708 /* Send command */
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} },
714 /* Integer compare */
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} },
720 /* Flush data cache subblock - don't clear subblock preset flag */
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} },
726 /* Flush data cache subblock - clear subblock preset flag */
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} },
732 /* Direct load signed data into register */
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} },
743 /* Direct load unsigned data into register */
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} },
750 /* Direct store data into memory */
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} },
761 /* Emulation stop */
763 {"estop", OP_LI(0x3FC), MASK_LI, 0, {0} },
765 /* Emulation trap */
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} },
771 /* Floating-point addition */
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} },
782 /* Floating point compare */
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} },
791 /* Floating point divide */
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} },
802 /* Floating point multiply */
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} },
817 /* Convert/Round to Minus Infinity */
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} },
840 /* Convert/Round to Nearest */
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} },
863 /* Convert/Round to Positive Infinity */
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} },
886 /* Convert/Round to Zero */
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} },
909 /* Floating point square root */
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} },
917 /* Floating point subtraction */
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} },
928 /* Illegal instructions */
930 {"illop0", OP_SI(0x0), MASK_SI, 0, {0} },
931 {"illopF", 0x1FF << 13, 0x1FF << 13, 0, {0} },
933 /* Jump and save return */
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} },
942 /* Load Signed Data Into Register */
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} },
957 /* Load Unsigned Data Into Register */
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} },
966 /* Leftmost one */
968 {"lmo", OP_LI(0x3F0), MASK_LI, 0, {REG_22, REG_DEST} },
970 /* Bitwise logical OR. Note that "or.tt" and "or" are the same instructions. */
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} },
988 /* Read Control Register */
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} },
994 /* Rightmost one */
996 {"rmo", OP_LI(0x3F2), MASK_LI, 0, {REG_22, REG_DEST} },
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. */
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} },
1025 /* Shift Register Left With Inverted Endmask */
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} },
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. */
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} },
1074 /* Shift Register Right With Inverted Endmask */
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} },
1093 /* Store Data into Memory */
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} },
1108 /* Signed Integer Subtract */
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} },
1114 /* Unsigned Integer Subtract */
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} },
1120 /* Write Control Register
1121 Is a special form of the "swcr" instruction so comes before it in the table. */
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} },
1127 /* Swap Control Register */
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} },
1133 /* Trap */
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} },
1139 /* Vector Floating-Point Add */
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} },
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. */
1153 /* Vector Floating-Point Multiply
1154 Note: If r0 is in the destination reg, then this is a "vector nop" instruction. */
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} },
1162 /* Vector Floating-Point Multiply and Subtract from Accumulator
1163 FIXME: See note above for vmac instruction */
1165 /* Vector Floating-Point Subtract Accumulator From Source
1166 FIXME: See note above for vmac instruction */
1168 /* Vector Round With Floating-Point Input
1169 FIXME: See note above for vmac instruction */
1171 /* Vector Round with Integer Input */
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}},
1182 /* Vector Floating-Point Subtract */
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} },
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. */
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} },
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. */
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} },
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} },
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} },
1216 const int tic80_num_opcodes = sizeof (tic80_opcodes) / sizeof (tic80_opcodes[0]);