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[deliverable/binutils-gdb.git] / opcodes / m32r-desc.c
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CommitLineData
1/* CPU data for m32r.
2
3THIS FILE IS MACHINE GENERATED WITH CGEN.
4
5Copyright 1996, 1997, 1998, 1999, 2000, 2001, 2002, 2003 Free Software Foundation, Inc.
6
7This file is part of the GNU Binutils and/or GDB, the GNU debugger.
8
9This program is free software; you can redistribute it and/or modify
10it under the terms of the GNU General Public License as published by
11the Free Software Foundation; either version 2, or (at your option)
12any later version.
13
14This program is distributed in the hope that it will be useful,
15but WITHOUT ANY WARRANTY; without even the implied warranty of
16MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
17GNU General Public License for more details.
18
19You should have received a copy of the GNU General Public License along
20with this program; if not, write to the Free Software Foundation, Inc.,
2159 Temple Place - Suite 330, Boston, MA 02111-1307, USA.
22
23*/
24
25#include "sysdep.h"
26#include <stdio.h>
27#include <stdarg.h>
28#include "ansidecl.h"
29#include "bfd.h"
30#include "symcat.h"
31#include "m32r-desc.h"
32#include "m32r-opc.h"
33#include "opintl.h"
34#include "libiberty.h"
35#include "xregex.h"
36
37/* Attributes. */
38
39static const CGEN_ATTR_ENTRY bool_attr[] =
40{
41 { "#f", 0 },
42 { "#t", 1 },
43 { 0, 0 }
44};
45
46static const CGEN_ATTR_ENTRY MACH_attr[] =
47{
48 { "base", MACH_BASE },
49 { "m32r", MACH_M32R },
50 { "m32rx", MACH_M32RX },
51 { "m32r2", MACH_M32R2 },
52 { "max", MACH_MAX },
53 { 0, 0 }
54};
55
56static const CGEN_ATTR_ENTRY ISA_attr[] =
57{
58 { "m32r", ISA_M32R },
59 { "max", ISA_MAX },
60 { 0, 0 }
61};
62
63static const CGEN_ATTR_ENTRY PIPE_attr[] =
64{
65 { "NONE", PIPE_NONE },
66 { "O", PIPE_O },
67 { "S", PIPE_S },
68 { "OS", PIPE_OS },
69 { "O_OS", PIPE_O_OS },
70 { 0, 0 }
71};
72
73const CGEN_ATTR_TABLE m32r_cgen_ifield_attr_table[] =
74{
75 { "MACH", & MACH_attr[0], & MACH_attr[0] },
76 { "VIRTUAL", &bool_attr[0], &bool_attr[0] },
77 { "PCREL-ADDR", &bool_attr[0], &bool_attr[0] },
78 { "ABS-ADDR", &bool_attr[0], &bool_attr[0] },
79 { "RESERVED", &bool_attr[0], &bool_attr[0] },
80 { "SIGN-OPT", &bool_attr[0], &bool_attr[0] },
81 { "SIGNED", &bool_attr[0], &bool_attr[0] },
82 { "RELOC", &bool_attr[0], &bool_attr[0] },
83 { 0, 0, 0 }
84};
85
86const CGEN_ATTR_TABLE m32r_cgen_hardware_attr_table[] =
87{
88 { "MACH", & MACH_attr[0], & MACH_attr[0] },
89 { "VIRTUAL", &bool_attr[0], &bool_attr[0] },
90 { "CACHE-ADDR", &bool_attr[0], &bool_attr[0] },
91 { "PC", &bool_attr[0], &bool_attr[0] },
92 { "PROFILE", &bool_attr[0], &bool_attr[0] },
93 { 0, 0, 0 }
94};
95
96const CGEN_ATTR_TABLE m32r_cgen_operand_attr_table[] =
97{
98 { "MACH", & MACH_attr[0], & MACH_attr[0] },
99 { "VIRTUAL", &bool_attr[0], &bool_attr[0] },
100 { "PCREL-ADDR", &bool_attr[0], &bool_attr[0] },
101 { "ABS-ADDR", &bool_attr[0], &bool_attr[0] },
102 { "SIGN-OPT", &bool_attr[0], &bool_attr[0] },
103 { "SIGNED", &bool_attr[0], &bool_attr[0] },
104 { "NEGATIVE", &bool_attr[0], &bool_attr[0] },
105 { "RELAX", &bool_attr[0], &bool_attr[0] },
106 { "SEM-ONLY", &bool_attr[0], &bool_attr[0] },
107 { "RELOC", &bool_attr[0], &bool_attr[0] },
108 { "HASH-PREFIX", &bool_attr[0], &bool_attr[0] },
109 { 0, 0, 0 }
110};
111
112const CGEN_ATTR_TABLE m32r_cgen_insn_attr_table[] =
113{
114 { "MACH", & MACH_attr[0], & MACH_attr[0] },
115 { "PIPE", & PIPE_attr[0], & PIPE_attr[0] },
116 { "ALIAS", &bool_attr[0], &bool_attr[0] },
117 { "VIRTUAL", &bool_attr[0], &bool_attr[0] },
118 { "UNCOND-CTI", &bool_attr[0], &bool_attr[0] },
119 { "COND-CTI", &bool_attr[0], &bool_attr[0] },
120 { "SKIP-CTI", &bool_attr[0], &bool_attr[0] },
121 { "DELAY-SLOT", &bool_attr[0], &bool_attr[0] },
122 { "RELAXABLE", &bool_attr[0], &bool_attr[0] },
123 { "RELAXED", &bool_attr[0], &bool_attr[0] },
124 { "NO-DIS", &bool_attr[0], &bool_attr[0] },
125 { "PBB", &bool_attr[0], &bool_attr[0] },
126 { "FILL-SLOT", &bool_attr[0], &bool_attr[0] },
127 { "SPECIAL", &bool_attr[0], &bool_attr[0] },
128 { "SPECIAL_M32R", &bool_attr[0], &bool_attr[0] },
129 { "SPECIAL_FLOAT", &bool_attr[0], &bool_attr[0] },
130 { 0, 0, 0 }
131};
132
133/* Instruction set variants. */
134
135static const CGEN_ISA m32r_cgen_isa_table[] = {
136 { "m32r", 32, 32, 16, 32 },
137 { 0, 0, 0, 0, 0 }
138};
139
140/* Machine variants. */
141
142static const CGEN_MACH m32r_cgen_mach_table[] = {
143 { "m32r", "m32r", MACH_M32R, 0 },
144 { "m32rx", "m32rx", MACH_M32RX, 0 },
145 { "m32r2", "m32r2", MACH_M32R2, 0 },
146 { 0, 0, 0, 0 }
147};
148
149static CGEN_KEYWORD_ENTRY m32r_cgen_opval_gr_names_entries[] =
150{
151 { "fp", 13, {0, {0}}, 0, 0 },
152 { "lr", 14, {0, {0}}, 0, 0 },
153 { "sp", 15, {0, {0}}, 0, 0 },
154 { "r0", 0, {0, {0}}, 0, 0 },
155 { "r1", 1, {0, {0}}, 0, 0 },
156 { "r2", 2, {0, {0}}, 0, 0 },
157 { "r3", 3, {0, {0}}, 0, 0 },
158 { "r4", 4, {0, {0}}, 0, 0 },
159 { "r5", 5, {0, {0}}, 0, 0 },
160 { "r6", 6, {0, {0}}, 0, 0 },
161 { "r7", 7, {0, {0}}, 0, 0 },
162 { "r8", 8, {0, {0}}, 0, 0 },
163 { "r9", 9, {0, {0}}, 0, 0 },
164 { "r10", 10, {0, {0}}, 0, 0 },
165 { "r11", 11, {0, {0}}, 0, 0 },
166 { "r12", 12, {0, {0}}, 0, 0 },
167 { "r13", 13, {0, {0}}, 0, 0 },
168 { "r14", 14, {0, {0}}, 0, 0 },
169 { "r15", 15, {0, {0}}, 0, 0 }
170};
171
172CGEN_KEYWORD m32r_cgen_opval_gr_names =
173{
174 & m32r_cgen_opval_gr_names_entries[0],
175 19,
176 0, 0, 0, 0, ""
177};
178
179static CGEN_KEYWORD_ENTRY m32r_cgen_opval_cr_names_entries[] =
180{
181 { "psw", 0, {0, {0}}, 0, 0 },
182 { "cbr", 1, {0, {0}}, 0, 0 },
183 { "spi", 2, {0, {0}}, 0, 0 },
184 { "spu", 3, {0, {0}}, 0, 0 },
185 { "bpc", 6, {0, {0}}, 0, 0 },
186 { "bbpsw", 8, {0, {0}}, 0, 0 },
187 { "bbpc", 14, {0, {0}}, 0, 0 },
188 { "evb", 5, {0, {0}}, 0, 0 },
189 { "cr0", 0, {0, {0}}, 0, 0 },
190 { "cr1", 1, {0, {0}}, 0, 0 },
191 { "cr2", 2, {0, {0}}, 0, 0 },
192 { "cr3", 3, {0, {0}}, 0, 0 },
193 { "cr4", 4, {0, {0}}, 0, 0 },
194 { "cr5", 5, {0, {0}}, 0, 0 },
195 { "cr6", 6, {0, {0}}, 0, 0 },
196 { "cr7", 7, {0, {0}}, 0, 0 },
197 { "cr8", 8, {0, {0}}, 0, 0 },
198 { "cr9", 9, {0, {0}}, 0, 0 },
199 { "cr10", 10, {0, {0}}, 0, 0 },
200 { "cr11", 11, {0, {0}}, 0, 0 },
201 { "cr12", 12, {0, {0}}, 0, 0 },
202 { "cr13", 13, {0, {0}}, 0, 0 },
203 { "cr14", 14, {0, {0}}, 0, 0 },
204 { "cr15", 15, {0, {0}}, 0, 0 }
205};
206
207CGEN_KEYWORD m32r_cgen_opval_cr_names =
208{
209 & m32r_cgen_opval_cr_names_entries[0],
210 24,
211 0, 0, 0, 0, ""
212};
213
214static CGEN_KEYWORD_ENTRY m32r_cgen_opval_h_accums_entries[] =
215{
216 { "a0", 0, {0, {0}}, 0, 0 },
217 { "a1", 1, {0, {0}}, 0, 0 }
218};
219
220CGEN_KEYWORD m32r_cgen_opval_h_accums =
221{
222 & m32r_cgen_opval_h_accums_entries[0],
223 2,
224 0, 0, 0, 0, ""
225};
226
227
228/* The hardware table. */
229
230#if defined (__STDC__) || defined (ALMOST_STDC) || defined (HAVE_STRINGIZE)
231#define A(a) (1 << CGEN_HW_##a)
232#else
233#define A(a) (1 << CGEN_HW_/**/a)
234#endif
235
236const CGEN_HW_ENTRY m32r_cgen_hw_table[] =
237{
238 { "h-memory", HW_H_MEMORY, CGEN_ASM_NONE, 0, { 0, { (1<<MACH_BASE) } } },
239 { "h-sint", HW_H_SINT, CGEN_ASM_NONE, 0, { 0, { (1<<MACH_BASE) } } },
240 { "h-uint", HW_H_UINT, CGEN_ASM_NONE, 0, { 0, { (1<<MACH_BASE) } } },
241 { "h-addr", HW_H_ADDR, CGEN_ASM_NONE, 0, { 0, { (1<<MACH_BASE) } } },
242 { "h-iaddr", HW_H_IADDR, CGEN_ASM_NONE, 0, { 0, { (1<<MACH_BASE) } } },
243 { "h-pc", HW_H_PC, CGEN_ASM_NONE, 0, { 0|A(PROFILE)|A(PC), { (1<<MACH_BASE) } } },
244 { "h-hi16", HW_H_HI16, CGEN_ASM_NONE, 0, { 0, { (1<<MACH_BASE) } } },
245 { "h-slo16", HW_H_SLO16, CGEN_ASM_NONE, 0, { 0, { (1<<MACH_BASE) } } },
246 { "h-ulo16", HW_H_ULO16, CGEN_ASM_NONE, 0, { 0, { (1<<MACH_BASE) } } },
247 { "h-gr", HW_H_GR, CGEN_ASM_KEYWORD, (PTR) & m32r_cgen_opval_gr_names, { 0|A(CACHE_ADDR)|A(PROFILE), { (1<<MACH_BASE) } } },
248 { "h-cr", HW_H_CR, CGEN_ASM_KEYWORD, (PTR) & m32r_cgen_opval_cr_names, { 0, { (1<<MACH_BASE) } } },
249 { "h-accum", HW_H_ACCUM, CGEN_ASM_NONE, 0, { 0, { (1<<MACH_BASE) } } },
250 { "h-accums", HW_H_ACCUMS, CGEN_ASM_KEYWORD, (PTR) & m32r_cgen_opval_h_accums, { 0, { (1<<MACH_M32RX)|(1<<MACH_M32R2) } } },
251 { "h-cond", HW_H_COND, CGEN_ASM_NONE, 0, { 0, { (1<<MACH_BASE) } } },
252 { "h-psw", HW_H_PSW, CGEN_ASM_NONE, 0, { 0, { (1<<MACH_BASE) } } },
253 { "h-bpsw", HW_H_BPSW, CGEN_ASM_NONE, 0, { 0, { (1<<MACH_BASE) } } },
254 { "h-bbpsw", HW_H_BBPSW, CGEN_ASM_NONE, 0, { 0, { (1<<MACH_BASE) } } },
255 { "h-lock", HW_H_LOCK, CGEN_ASM_NONE, 0, { 0, { (1<<MACH_BASE) } } },
256 { 0, 0, CGEN_ASM_NONE, 0, {0, {0}} }
257};
258
259#undef A
260
261
262/* The instruction field table. */
263
264#if defined (__STDC__) || defined (ALMOST_STDC) || defined (HAVE_STRINGIZE)
265#define A(a) (1 << CGEN_IFLD_##a)
266#else
267#define A(a) (1 << CGEN_IFLD_/**/a)
268#endif
269
270const CGEN_IFLD m32r_cgen_ifld_table[] =
271{
272 { M32R_F_NIL, "f-nil", 0, 0, 0, 0, { 0, { (1<<MACH_BASE) } } },
273 { M32R_F_ANYOF, "f-anyof", 0, 0, 0, 0, { 0, { (1<<MACH_BASE) } } },
274 { M32R_F_OP1, "f-op1", 0, 32, 0, 4, { 0, { (1<<MACH_BASE) } } },
275 { M32R_F_OP2, "f-op2", 0, 32, 8, 4, { 0, { (1<<MACH_BASE) } } },
276 { M32R_F_COND, "f-cond", 0, 32, 4, 4, { 0, { (1<<MACH_BASE) } } },
277 { M32R_F_R1, "f-r1", 0, 32, 4, 4, { 0, { (1<<MACH_BASE) } } },
278 { M32R_F_R2, "f-r2", 0, 32, 12, 4, { 0, { (1<<MACH_BASE) } } },
279 { M32R_F_SIMM8, "f-simm8", 0, 32, 8, 8, { 0, { (1<<MACH_BASE) } } },
280 { M32R_F_SIMM16, "f-simm16", 0, 32, 16, 16, { 0, { (1<<MACH_BASE) } } },
281 { M32R_F_SHIFT_OP2, "f-shift-op2", 0, 32, 8, 3, { 0, { (1<<MACH_BASE) } } },
282 { M32R_F_UIMM3, "f-uimm3", 0, 32, 5, 3, { 0, { (1<<MACH_BASE) } } },
283 { M32R_F_UIMM4, "f-uimm4", 0, 32, 12, 4, { 0, { (1<<MACH_BASE) } } },
284 { M32R_F_UIMM5, "f-uimm5", 0, 32, 11, 5, { 0, { (1<<MACH_BASE) } } },
285 { M32R_F_UIMM8, "f-uimm8", 0, 32, 8, 8, { 0, { (1<<MACH_BASE) } } },
286 { M32R_F_UIMM16, "f-uimm16", 0, 32, 16, 16, { 0, { (1<<MACH_BASE) } } },
287 { M32R_F_UIMM24, "f-uimm24", 0, 32, 8, 24, { 0|A(RELOC)|A(ABS_ADDR), { (1<<MACH_BASE) } } },
288 { M32R_F_HI16, "f-hi16", 0, 32, 16, 16, { 0|A(SIGN_OPT), { (1<<MACH_BASE) } } },
289 { M32R_F_DISP8, "f-disp8", 0, 32, 8, 8, { 0|A(RELOC)|A(PCREL_ADDR), { (1<<MACH_BASE) } } },
290 { M32R_F_DISP16, "f-disp16", 0, 32, 16, 16, { 0|A(RELOC)|A(PCREL_ADDR), { (1<<MACH_BASE) } } },
291 { M32R_F_DISP24, "f-disp24", 0, 32, 8, 24, { 0|A(RELOC)|A(PCREL_ADDR), { (1<<MACH_BASE) } } },
292 { M32R_F_OP23, "f-op23", 0, 32, 9, 3, { 0, { (1<<MACH_BASE) } } },
293 { M32R_F_OP3, "f-op3", 0, 32, 14, 2, { 0, { (1<<MACH_BASE) } } },
294 { M32R_F_ACC, "f-acc", 0, 32, 8, 1, { 0, { (1<<MACH_BASE) } } },
295 { M32R_F_ACCS, "f-accs", 0, 32, 12, 2, { 0, { (1<<MACH_BASE) } } },
296 { M32R_F_ACCD, "f-accd", 0, 32, 4, 2, { 0, { (1<<MACH_BASE) } } },
297 { M32R_F_BITS67, "f-bits67", 0, 32, 6, 2, { 0, { (1<<MACH_BASE) } } },
298 { M32R_F_BIT4, "f-bit4", 0, 32, 4, 1, { 0, { (1<<MACH_BASE) } } },
299 { M32R_F_BIT14, "f-bit14", 0, 32, 14, 1, { 0, { (1<<MACH_BASE) } } },
300 { M32R_F_IMM1, "f-imm1", 0, 32, 15, 1, { 0, { (1<<MACH_BASE) } } },
301 { 0, 0, 0, 0, 0, 0, {0, {0}} }
302};
303
304#undef A
305
306
307
308/* multi ifield declarations */
309
310
311
312/* multi ifield definitions */
313
314
315/* The operand table. */
316
317#if defined (__STDC__) || defined (ALMOST_STDC) || defined (HAVE_STRINGIZE)
318#define A(a) (1 << CGEN_OPERAND_##a)
319#else
320#define A(a) (1 << CGEN_OPERAND_/**/a)
321#endif
322#if defined (__STDC__) || defined (ALMOST_STDC) || defined (HAVE_STRINGIZE)
323#define OPERAND(op) M32R_OPERAND_##op
324#else
325#define OPERAND(op) M32R_OPERAND_/**/op
326#endif
327
328const CGEN_OPERAND m32r_cgen_operand_table[] =
329{
330/* pc: program counter */
331 { "pc", M32R_OPERAND_PC, HW_H_PC, 0, 0,
332 { 0, { (const PTR) &m32r_cgen_ifld_table[M32R_F_NIL] } },
333 { 0|A(SEM_ONLY), { (1<<MACH_BASE) } } },
334/* sr: source register */
335 { "sr", M32R_OPERAND_SR, HW_H_GR, 12, 4,
336 { 0, { (const PTR) &m32r_cgen_ifld_table[M32R_F_R2] } },
337 { 0, { (1<<MACH_BASE) } } },
338/* dr: destination register */
339 { "dr", M32R_OPERAND_DR, HW_H_GR, 4, 4,
340 { 0, { (const PTR) &m32r_cgen_ifld_table[M32R_F_R1] } },
341 { 0, { (1<<MACH_BASE) } } },
342/* src1: source register 1 */
343 { "src1", M32R_OPERAND_SRC1, HW_H_GR, 4, 4,
344 { 0, { (const PTR) &m32r_cgen_ifld_table[M32R_F_R1] } },
345 { 0, { (1<<MACH_BASE) } } },
346/* src2: source register 2 */
347 { "src2", M32R_OPERAND_SRC2, HW_H_GR, 12, 4,
348 { 0, { (const PTR) &m32r_cgen_ifld_table[M32R_F_R2] } },
349 { 0, { (1<<MACH_BASE) } } },
350/* scr: source control register */
351 { "scr", M32R_OPERAND_SCR, HW_H_CR, 12, 4,
352 { 0, { (const PTR) &m32r_cgen_ifld_table[M32R_F_R2] } },
353 { 0, { (1<<MACH_BASE) } } },
354/* dcr: destination control register */
355 { "dcr", M32R_OPERAND_DCR, HW_H_CR, 4, 4,
356 { 0, { (const PTR) &m32r_cgen_ifld_table[M32R_F_R1] } },
357 { 0, { (1<<MACH_BASE) } } },
358/* simm8: 8 bit signed immediate */
359 { "simm8", M32R_OPERAND_SIMM8, HW_H_SINT, 8, 8,
360 { 0, { (const PTR) &m32r_cgen_ifld_table[M32R_F_SIMM8] } },
361 { 0|A(HASH_PREFIX), { (1<<MACH_BASE) } } },
362/* simm16: 16 bit signed immediate */
363 { "simm16", M32R_OPERAND_SIMM16, HW_H_SINT, 16, 16,
364 { 0, { (const PTR) &m32r_cgen_ifld_table[M32R_F_SIMM16] } },
365 { 0|A(HASH_PREFIX), { (1<<MACH_BASE) } } },
366/* uimm3: 3 bit unsigned number */
367 { "uimm3", M32R_OPERAND_UIMM3, HW_H_UINT, 5, 3,
368 { 0, { (const PTR) &m32r_cgen_ifld_table[M32R_F_UIMM3] } },
369 { 0|A(HASH_PREFIX), { (1<<MACH_BASE) } } },
370/* uimm4: 4 bit trap number */
371 { "uimm4", M32R_OPERAND_UIMM4, HW_H_UINT, 12, 4,
372 { 0, { (const PTR) &m32r_cgen_ifld_table[M32R_F_UIMM4] } },
373 { 0|A(HASH_PREFIX), { (1<<MACH_BASE) } } },
374/* uimm5: 5 bit shift count */
375 { "uimm5", M32R_OPERAND_UIMM5, HW_H_UINT, 11, 5,
376 { 0, { (const PTR) &m32r_cgen_ifld_table[M32R_F_UIMM5] } },
377 { 0|A(HASH_PREFIX), { (1<<MACH_BASE) } } },
378/* uimm8: 8 bit unsigned immediate */
379 { "uimm8", M32R_OPERAND_UIMM8, HW_H_UINT, 8, 8,
380 { 0, { (const PTR) &m32r_cgen_ifld_table[M32R_F_UIMM8] } },
381 { 0|A(HASH_PREFIX), { (1<<MACH_BASE) } } },
382/* uimm16: 16 bit unsigned immediate */
383 { "uimm16", M32R_OPERAND_UIMM16, HW_H_UINT, 16, 16,
384 { 0, { (const PTR) &m32r_cgen_ifld_table[M32R_F_UIMM16] } },
385 { 0|A(HASH_PREFIX), { (1<<MACH_BASE) } } },
386/* imm1: 1 bit immediate */
387 { "imm1", M32R_OPERAND_IMM1, HW_H_UINT, 15, 1,
388 { 0, { (const PTR) &m32r_cgen_ifld_table[M32R_F_IMM1] } },
389 { 0|A(HASH_PREFIX), { (1<<MACH_M32RX)|(1<<MACH_M32R2) } } },
390/* accd: accumulator destination register */
391 { "accd", M32R_OPERAND_ACCD, HW_H_ACCUMS, 4, 2,
392 { 0, { (const PTR) &m32r_cgen_ifld_table[M32R_F_ACCD] } },
393 { 0, { (1<<MACH_M32RX)|(1<<MACH_M32R2) } } },
394/* accs: accumulator source register */
395 { "accs", M32R_OPERAND_ACCS, HW_H_ACCUMS, 12, 2,
396 { 0, { (const PTR) &m32r_cgen_ifld_table[M32R_F_ACCS] } },
397 { 0, { (1<<MACH_M32RX)|(1<<MACH_M32R2) } } },
398/* acc: accumulator reg (d) */
399 { "acc", M32R_OPERAND_ACC, HW_H_ACCUMS, 8, 1,
400 { 0, { (const PTR) &m32r_cgen_ifld_table[M32R_F_ACC] } },
401 { 0, { (1<<MACH_M32RX)|(1<<MACH_M32R2) } } },
402/* hash: # prefix */
403 { "hash", M32R_OPERAND_HASH, HW_H_SINT, 0, 0,
404 { 0, { (const PTR) 0 } },
405 { 0, { (1<<MACH_BASE) } } },
406/* hi16: high 16 bit immediate, sign optional */
407 { "hi16", M32R_OPERAND_HI16, HW_H_HI16, 16, 16,
408 { 0, { (const PTR) &m32r_cgen_ifld_table[M32R_F_HI16] } },
409 { 0|A(SIGN_OPT), { (1<<MACH_BASE) } } },
410/* slo16: 16 bit signed immediate, for low() */
411 { "slo16", M32R_OPERAND_SLO16, HW_H_SLO16, 16, 16,
412 { 0, { (const PTR) &m32r_cgen_ifld_table[M32R_F_SIMM16] } },
413 { 0, { (1<<MACH_BASE) } } },
414/* ulo16: 16 bit unsigned immediate, for low() */
415 { "ulo16", M32R_OPERAND_ULO16, HW_H_ULO16, 16, 16,
416 { 0, { (const PTR) &m32r_cgen_ifld_table[M32R_F_UIMM16] } },
417 { 0, { (1<<MACH_BASE) } } },
418/* uimm24: 24 bit address */
419 { "uimm24", M32R_OPERAND_UIMM24, HW_H_ADDR, 8, 24,
420 { 0, { (const PTR) &m32r_cgen_ifld_table[M32R_F_UIMM24] } },
421 { 0|A(HASH_PREFIX)|A(RELOC)|A(ABS_ADDR), { (1<<MACH_BASE) } } },
422/* disp8: 8 bit displacement */
423 { "disp8", M32R_OPERAND_DISP8, HW_H_IADDR, 8, 8,
424 { 0, { (const PTR) &m32r_cgen_ifld_table[M32R_F_DISP8] } },
425 { 0|A(RELAX)|A(RELOC)|A(PCREL_ADDR), { (1<<MACH_BASE) } } },
426/* disp16: 16 bit displacement */
427 { "disp16", M32R_OPERAND_DISP16, HW_H_IADDR, 16, 16,
428 { 0, { (const PTR) &m32r_cgen_ifld_table[M32R_F_DISP16] } },
429 { 0|A(RELOC)|A(PCREL_ADDR), { (1<<MACH_BASE) } } },
430/* disp24: 24 bit displacement */
431 { "disp24", M32R_OPERAND_DISP24, HW_H_IADDR, 8, 24,
432 { 0, { (const PTR) &m32r_cgen_ifld_table[M32R_F_DISP24] } },
433 { 0|A(RELAX)|A(RELOC)|A(PCREL_ADDR), { (1<<MACH_BASE) } } },
434/* condbit: condition bit */
435 { "condbit", M32R_OPERAND_CONDBIT, HW_H_COND, 0, 0,
436 { 0, { (const PTR) 0 } },
437 { 0|A(SEM_ONLY), { (1<<MACH_BASE) } } },
438/* accum: accumulator */
439 { "accum", M32R_OPERAND_ACCUM, HW_H_ACCUM, 0, 0,
440 { 0, { (const PTR) 0 } },
441 { 0|A(SEM_ONLY), { (1<<MACH_BASE) } } },
442/* sentinel */
443 { 0, 0, 0, 0, 0,
444 { 0, { (const PTR) 0 } },
445 { 0, { 0 } } }
446};
447
448#undef A
449
450
451/* The instruction table. */
452
453#define OP(field) CGEN_SYNTAX_MAKE_FIELD (OPERAND (field))
454#if defined (__STDC__) || defined (ALMOST_STDC) || defined (HAVE_STRINGIZE)
455#define A(a) (1 << CGEN_INSN_##a)
456#else
457#define A(a) (1 << CGEN_INSN_/**/a)
458#endif
459
460static const CGEN_IBASE m32r_cgen_insn_table[MAX_INSNS] =
461{
462 /* Special null first entry.
463 A `num' value of zero is thus invalid.
464 Also, the special `invalid' insn resides here. */
465 { 0, 0, 0, 0, {0, {0}} },
466/* add $dr,$sr */
467 {
468 M32R_INSN_ADD, "add", "add", 16,
469 { 0, { (1<<MACH_BASE), PIPE_OS } }
470 },
471/* add3 $dr,$sr,$hash$slo16 */
472 {
473 M32R_INSN_ADD3, "add3", "add3", 32,
474 { 0, { (1<<MACH_BASE), PIPE_NONE } }
475 },
476/* and $dr,$sr */
477 {
478 M32R_INSN_AND, "and", "and", 16,
479 { 0, { (1<<MACH_BASE), PIPE_OS } }
480 },
481/* and3 $dr,$sr,$uimm16 */
482 {
483 M32R_INSN_AND3, "and3", "and3", 32,
484 { 0, { (1<<MACH_BASE), PIPE_NONE } }
485 },
486/* or $dr,$sr */
487 {
488 M32R_INSN_OR, "or", "or", 16,
489 { 0, { (1<<MACH_BASE), PIPE_OS } }
490 },
491/* or3 $dr,$sr,$hash$ulo16 */
492 {
493 M32R_INSN_OR3, "or3", "or3", 32,
494 { 0, { (1<<MACH_BASE), PIPE_NONE } }
495 },
496/* xor $dr,$sr */
497 {
498 M32R_INSN_XOR, "xor", "xor", 16,
499 { 0, { (1<<MACH_BASE), PIPE_OS } }
500 },
501/* xor3 $dr,$sr,$uimm16 */
502 {
503 M32R_INSN_XOR3, "xor3", "xor3", 32,
504 { 0, { (1<<MACH_BASE), PIPE_NONE } }
505 },
506/* addi $dr,$simm8 */
507 {
508 M32R_INSN_ADDI, "addi", "addi", 16,
509 { 0, { (1<<MACH_BASE), PIPE_OS } }
510 },
511/* addv $dr,$sr */
512 {
513 M32R_INSN_ADDV, "addv", "addv", 16,
514 { 0, { (1<<MACH_BASE), PIPE_OS } }
515 },
516/* addv3 $dr,$sr,$simm16 */
517 {
518 M32R_INSN_ADDV3, "addv3", "addv3", 32,
519 { 0, { (1<<MACH_BASE), PIPE_NONE } }
520 },
521/* addx $dr,$sr */
522 {
523 M32R_INSN_ADDX, "addx", "addx", 16,
524 { 0, { (1<<MACH_BASE), PIPE_OS } }
525 },
526/* bc.s $disp8 */
527 {
528 M32R_INSN_BC8, "bc8", "bc.s", 16,
529 { 0|A(COND_CTI), { (1<<MACH_BASE), PIPE_O } }
530 },
531/* bc.l $disp24 */
532 {
533 M32R_INSN_BC24, "bc24", "bc.l", 32,
534 { 0|A(COND_CTI), { (1<<MACH_BASE), PIPE_NONE } }
535 },
536/* beq $src1,$src2,$disp16 */
537 {
538 M32R_INSN_BEQ, "beq", "beq", 32,
539 { 0|A(COND_CTI), { (1<<MACH_BASE), PIPE_NONE } }
540 },
541/* beqz $src2,$disp16 */
542 {
543 M32R_INSN_BEQZ, "beqz", "beqz", 32,
544 { 0|A(COND_CTI), { (1<<MACH_BASE), PIPE_NONE } }
545 },
546/* bgez $src2,$disp16 */
547 {
548 M32R_INSN_BGEZ, "bgez", "bgez", 32,
549 { 0|A(COND_CTI), { (1<<MACH_BASE), PIPE_NONE } }
550 },
551/* bgtz $src2,$disp16 */
552 {
553 M32R_INSN_BGTZ, "bgtz", "bgtz", 32,
554 { 0|A(COND_CTI), { (1<<MACH_BASE), PIPE_NONE } }
555 },
556/* blez $src2,$disp16 */
557 {
558 M32R_INSN_BLEZ, "blez", "blez", 32,
559 { 0|A(COND_CTI), { (1<<MACH_BASE), PIPE_NONE } }
560 },
561/* bltz $src2,$disp16 */
562 {
563 M32R_INSN_BLTZ, "bltz", "bltz", 32,
564 { 0|A(COND_CTI), { (1<<MACH_BASE), PIPE_NONE } }
565 },
566/* bnez $src2,$disp16 */
567 {
568 M32R_INSN_BNEZ, "bnez", "bnez", 32,
569 { 0|A(COND_CTI), { (1<<MACH_BASE), PIPE_NONE } }
570 },
571/* bl.s $disp8 */
572 {
573 M32R_INSN_BL8, "bl8", "bl.s", 16,
574 { 0|A(FILL_SLOT)|A(UNCOND_CTI), { (1<<MACH_BASE), PIPE_O } }
575 },
576/* bl.l $disp24 */
577 {
578 M32R_INSN_BL24, "bl24", "bl.l", 32,
579 { 0|A(UNCOND_CTI), { (1<<MACH_BASE), PIPE_NONE } }
580 },
581/* bcl.s $disp8 */
582 {
583 M32R_INSN_BCL8, "bcl8", "bcl.s", 16,
584 { 0|A(FILL_SLOT)|A(COND_CTI), { (1<<MACH_M32RX)|(1<<MACH_M32R2), PIPE_O } }
585 },
586/* bcl.l $disp24 */
587 {
588 M32R_INSN_BCL24, "bcl24", "bcl.l", 32,
589 { 0|A(COND_CTI), { (1<<MACH_M32RX)|(1<<MACH_M32R2), PIPE_NONE } }
590 },
591/* bnc.s $disp8 */
592 {
593 M32R_INSN_BNC8, "bnc8", "bnc.s", 16,
594 { 0|A(COND_CTI), { (1<<MACH_BASE), PIPE_O } }
595 },
596/* bnc.l $disp24 */
597 {
598 M32R_INSN_BNC24, "bnc24", "bnc.l", 32,
599 { 0|A(COND_CTI), { (1<<MACH_BASE), PIPE_NONE } }
600 },
601/* bne $src1,$src2,$disp16 */
602 {
603 M32R_INSN_BNE, "bne", "bne", 32,
604 { 0|A(COND_CTI), { (1<<MACH_BASE), PIPE_NONE } }
605 },
606/* bra.s $disp8 */
607 {
608 M32R_INSN_BRA8, "bra8", "bra.s", 16,
609 { 0|A(FILL_SLOT)|A(UNCOND_CTI), { (1<<MACH_BASE), PIPE_O } }
610 },
611/* bra.l $disp24 */
612 {
613 M32R_INSN_BRA24, "bra24", "bra.l", 32,
614 { 0|A(UNCOND_CTI), { (1<<MACH_BASE), PIPE_NONE } }
615 },
616/* bncl.s $disp8 */
617 {
618 M32R_INSN_BNCL8, "bncl8", "bncl.s", 16,
619 { 0|A(FILL_SLOT)|A(COND_CTI), { (1<<MACH_M32RX)|(1<<MACH_M32R2), PIPE_O } }
620 },
621/* bncl.l $disp24 */
622 {
623 M32R_INSN_BNCL24, "bncl24", "bncl.l", 32,
624 { 0|A(COND_CTI), { (1<<MACH_M32RX)|(1<<MACH_M32R2), PIPE_NONE } }
625 },
626/* cmp $src1,$src2 */
627 {
628 M32R_INSN_CMP, "cmp", "cmp", 16,
629 { 0, { (1<<MACH_BASE), PIPE_OS } }
630 },
631/* cmpi $src2,$simm16 */
632 {
633 M32R_INSN_CMPI, "cmpi", "cmpi", 32,
634 { 0, { (1<<MACH_BASE), PIPE_NONE } }
635 },
636/* cmpu $src1,$src2 */
637 {
638 M32R_INSN_CMPU, "cmpu", "cmpu", 16,
639 { 0, { (1<<MACH_BASE), PIPE_OS } }
640 },
641/* cmpui $src2,$simm16 */
642 {
643 M32R_INSN_CMPUI, "cmpui", "cmpui", 32,
644 { 0, { (1<<MACH_BASE), PIPE_NONE } }
645 },
646/* cmpeq $src1,$src2 */
647 {
648 M32R_INSN_CMPEQ, "cmpeq", "cmpeq", 16,
649 { 0, { (1<<MACH_M32RX)|(1<<MACH_M32R2), PIPE_OS } }
650 },
651/* cmpz $src2 */
652 {
653 M32R_INSN_CMPZ, "cmpz", "cmpz", 16,
654 { 0, { (1<<MACH_M32RX)|(1<<MACH_M32R2), PIPE_OS } }
655 },
656/* div $dr,$sr */
657 {
658 M32R_INSN_DIV, "div", "div", 32,
659 { 0, { (1<<MACH_BASE), PIPE_NONE } }
660 },
661/* divu $dr,$sr */
662 {
663 M32R_INSN_DIVU, "divu", "divu", 32,
664 { 0, { (1<<MACH_BASE), PIPE_NONE } }
665 },
666/* rem $dr,$sr */
667 {
668 M32R_INSN_REM, "rem", "rem", 32,
669 { 0, { (1<<MACH_BASE), PIPE_NONE } }
670 },
671/* remu $dr,$sr */
672 {
673 M32R_INSN_REMU, "remu", "remu", 32,
674 { 0, { (1<<MACH_BASE), PIPE_NONE } }
675 },
676/* remh $dr,$sr */
677 {
678 M32R_INSN_REMH, "remh", "remh", 32,
679 { 0, { (1<<MACH_M32R2), PIPE_NONE } }
680 },
681/* remuh $dr,$sr */
682 {
683 M32R_INSN_REMUH, "remuh", "remuh", 32,
684 { 0, { (1<<MACH_M32R2), PIPE_NONE } }
685 },
686/* remb $dr,$sr */
687 {
688 M32R_INSN_REMB, "remb", "remb", 32,
689 { 0, { (1<<MACH_M32R2), PIPE_NONE } }
690 },
691/* remub $dr,$sr */
692 {
693 M32R_INSN_REMUB, "remub", "remub", 32,
694 { 0, { (1<<MACH_M32R2), PIPE_NONE } }
695 },
696/* divuh $dr,$sr */
697 {
698 M32R_INSN_DIVUH, "divuh", "divuh", 32,
699 { 0, { (1<<MACH_M32R2), PIPE_NONE } }
700 },
701/* divb $dr,$sr */
702 {
703 M32R_INSN_DIVB, "divb", "divb", 32,
704 { 0, { (1<<MACH_M32R2), PIPE_NONE } }
705 },
706/* divub $dr,$sr */
707 {
708 M32R_INSN_DIVUB, "divub", "divub", 32,
709 { 0, { (1<<MACH_M32R2), PIPE_NONE } }
710 },
711/* divh $dr,$sr */
712 {
713 M32R_INSN_DIVH, "divh", "divh", 32,
714 { 0, { (1<<MACH_M32RX)|(1<<MACH_M32R2), PIPE_NONE } }
715 },
716/* jc $sr */
717 {
718 M32R_INSN_JC, "jc", "jc", 16,
719 { 0|A(SPECIAL)|A(COND_CTI), { (1<<MACH_M32RX)|(1<<MACH_M32R2), PIPE_O } }
720 },
721/* jnc $sr */
722 {
723 M32R_INSN_JNC, "jnc", "jnc", 16,
724 { 0|A(SPECIAL)|A(COND_CTI), { (1<<MACH_M32RX)|(1<<MACH_M32R2), PIPE_O } }
725 },
726/* jl $sr */
727 {
728 M32R_INSN_JL, "jl", "jl", 16,
729 { 0|A(FILL_SLOT)|A(UNCOND_CTI), { (1<<MACH_BASE), PIPE_O } }
730 },
731/* jmp $sr */
732 {
733 M32R_INSN_JMP, "jmp", "jmp", 16,
734 { 0|A(UNCOND_CTI), { (1<<MACH_BASE), PIPE_O } }
735 },
736/* ld $dr,@$sr */
737 {
738 M32R_INSN_LD, "ld", "ld", 16,
739 { 0, { (1<<MACH_BASE), PIPE_O } }
740 },
741/* ld $dr,@($slo16,$sr) */
742 {
743 M32R_INSN_LD_D, "ld-d", "ld", 32,
744 { 0, { (1<<MACH_BASE), PIPE_NONE } }
745 },
746/* ldb $dr,@$sr */
747 {
748 M32R_INSN_LDB, "ldb", "ldb", 16,
749 { 0, { (1<<MACH_BASE), PIPE_O } }
750 },
751/* ldb $dr,@($slo16,$sr) */
752 {
753 M32R_INSN_LDB_D, "ldb-d", "ldb", 32,
754 { 0, { (1<<MACH_BASE), PIPE_NONE } }
755 },
756/* ldh $dr,@$sr */
757 {
758 M32R_INSN_LDH, "ldh", "ldh", 16,
759 { 0, { (1<<MACH_BASE), PIPE_O } }
760 },
761/* ldh $dr,@($slo16,$sr) */
762 {
763 M32R_INSN_LDH_D, "ldh-d", "ldh", 32,
764 { 0, { (1<<MACH_BASE), PIPE_NONE } }
765 },
766/* ldub $dr,@$sr */
767 {
768 M32R_INSN_LDUB, "ldub", "ldub", 16,
769 { 0, { (1<<MACH_BASE), PIPE_O } }
770 },
771/* ldub $dr,@($slo16,$sr) */
772 {
773 M32R_INSN_LDUB_D, "ldub-d", "ldub", 32,
774 { 0, { (1<<MACH_BASE), PIPE_NONE } }
775 },
776/* lduh $dr,@$sr */
777 {
778 M32R_INSN_LDUH, "lduh", "lduh", 16,
779 { 0, { (1<<MACH_BASE), PIPE_O } }
780 },
781/* lduh $dr,@($slo16,$sr) */
782 {
783 M32R_INSN_LDUH_D, "lduh-d", "lduh", 32,
784 { 0, { (1<<MACH_BASE), PIPE_NONE } }
785 },
786/* ld $dr,@$sr+ */
787 {
788 M32R_INSN_LD_PLUS, "ld-plus", "ld", 16,
789 { 0, { (1<<MACH_BASE), PIPE_O } }
790 },
791/* ld24 $dr,$uimm24 */
792 {
793 M32R_INSN_LD24, "ld24", "ld24", 32,
794 { 0, { (1<<MACH_BASE), PIPE_NONE } }
795 },
796/* ldi8 $dr,$simm8 */
797 {
798 M32R_INSN_LDI8, "ldi8", "ldi8", 16,
799 { 0, { (1<<MACH_BASE), PIPE_OS } }
800 },
801/* ldi16 $dr,$hash$slo16 */
802 {
803 M32R_INSN_LDI16, "ldi16", "ldi16", 32,
804 { 0, { (1<<MACH_BASE), PIPE_NONE } }
805 },
806/* lock $dr,@$sr */
807 {
808 M32R_INSN_LOCK, "lock", "lock", 16,
809 { 0, { (1<<MACH_BASE), PIPE_O } }
810 },
811/* machi $src1,$src2 */
812 {
813 M32R_INSN_MACHI, "machi", "machi", 16,
814 { 0, { (1<<MACH_M32R), PIPE_S } }
815 },
816/* machi $src1,$src2,$acc */
817 {
818 M32R_INSN_MACHI_A, "machi-a", "machi", 16,
819 { 0, { (1<<MACH_M32RX)|(1<<MACH_M32R2), PIPE_S } }
820 },
821/* maclo $src1,$src2 */
822 {
823 M32R_INSN_MACLO, "maclo", "maclo", 16,
824 { 0, { (1<<MACH_M32R), PIPE_S } }
825 },
826/* maclo $src1,$src2,$acc */
827 {
828 M32R_INSN_MACLO_A, "maclo-a", "maclo", 16,
829 { 0, { (1<<MACH_M32RX)|(1<<MACH_M32R2), PIPE_S } }
830 },
831/* macwhi $src1,$src2 */
832 {
833 M32R_INSN_MACWHI, "macwhi", "macwhi", 16,
834 { 0, { (1<<MACH_M32R), PIPE_S } }
835 },
836/* macwhi $src1,$src2,$acc */
837 {
838 M32R_INSN_MACWHI_A, "macwhi-a", "macwhi", 16,
839 { 0|A(SPECIAL), { (1<<MACH_M32RX)|(1<<MACH_M32R2), PIPE_S } }
840 },
841/* macwlo $src1,$src2 */
842 {
843 M32R_INSN_MACWLO, "macwlo", "macwlo", 16,
844 { 0, { (1<<MACH_M32R), PIPE_S } }
845 },
846/* macwlo $src1,$src2,$acc */
847 {
848 M32R_INSN_MACWLO_A, "macwlo-a", "macwlo", 16,
849 { 0|A(SPECIAL), { (1<<MACH_M32RX)|(1<<MACH_M32R2), PIPE_S } }
850 },
851/* mul $dr,$sr */
852 {
853 M32R_INSN_MUL, "mul", "mul", 16,
854 { 0, { (1<<MACH_BASE), PIPE_S } }
855 },
856/* mulhi $src1,$src2 */
857 {
858 M32R_INSN_MULHI, "mulhi", "mulhi", 16,
859 { 0, { (1<<MACH_M32R), PIPE_S } }
860 },
861/* mulhi $src1,$src2,$acc */
862 {
863 M32R_INSN_MULHI_A, "mulhi-a", "mulhi", 16,
864 { 0, { (1<<MACH_M32RX)|(1<<MACH_M32R2), PIPE_S } }
865 },
866/* mullo $src1,$src2 */
867 {
868 M32R_INSN_MULLO, "mullo", "mullo", 16,
869 { 0, { (1<<MACH_M32R), PIPE_S } }
870 },
871/* mullo $src1,$src2,$acc */
872 {
873 M32R_INSN_MULLO_A, "mullo-a", "mullo", 16,
874 { 0, { (1<<MACH_M32RX)|(1<<MACH_M32R2), PIPE_S } }
875 },
876/* mulwhi $src1,$src2 */
877 {
878 M32R_INSN_MULWHI, "mulwhi", "mulwhi", 16,
879 { 0, { (1<<MACH_M32R), PIPE_S } }
880 },
881/* mulwhi $src1,$src2,$acc */
882 {
883 M32R_INSN_MULWHI_A, "mulwhi-a", "mulwhi", 16,
884 { 0|A(SPECIAL), { (1<<MACH_M32RX)|(1<<MACH_M32R2), PIPE_S } }
885 },
886/* mulwlo $src1,$src2 */
887 {
888 M32R_INSN_MULWLO, "mulwlo", "mulwlo", 16,
889 { 0, { (1<<MACH_M32R), PIPE_S } }
890 },
891/* mulwlo $src1,$src2,$acc */
892 {
893 M32R_INSN_MULWLO_A, "mulwlo-a", "mulwlo", 16,
894 { 0|A(SPECIAL), { (1<<MACH_M32RX)|(1<<MACH_M32R2), PIPE_S } }
895 },
896/* mv $dr,$sr */
897 {
898 M32R_INSN_MV, "mv", "mv", 16,
899 { 0, { (1<<MACH_BASE), PIPE_OS } }
900 },
901/* mvfachi $dr */
902 {
903 M32R_INSN_MVFACHI, "mvfachi", "mvfachi", 16,
904 { 0, { (1<<MACH_M32R), PIPE_S } }
905 },
906/* mvfachi $dr,$accs */
907 {
908 M32R_INSN_MVFACHI_A, "mvfachi-a", "mvfachi", 16,
909 { 0, { (1<<MACH_M32RX)|(1<<MACH_M32R2), PIPE_S } }
910 },
911/* mvfaclo $dr */
912 {
913 M32R_INSN_MVFACLO, "mvfaclo", "mvfaclo", 16,
914 { 0, { (1<<MACH_M32R), PIPE_S } }
915 },
916/* mvfaclo $dr,$accs */
917 {
918 M32R_INSN_MVFACLO_A, "mvfaclo-a", "mvfaclo", 16,
919 { 0, { (1<<MACH_M32RX)|(1<<MACH_M32R2), PIPE_S } }
920 },
921/* mvfacmi $dr */
922 {
923 M32R_INSN_MVFACMI, "mvfacmi", "mvfacmi", 16,
924 { 0, { (1<<MACH_M32R), PIPE_S } }
925 },
926/* mvfacmi $dr,$accs */
927 {
928 M32R_INSN_MVFACMI_A, "mvfacmi-a", "mvfacmi", 16,
929 { 0, { (1<<MACH_M32RX)|(1<<MACH_M32R2), PIPE_S } }
930 },
931/* mvfc $dr,$scr */
932 {
933 M32R_INSN_MVFC, "mvfc", "mvfc", 16,
934 { 0, { (1<<MACH_BASE), PIPE_O } }
935 },
936/* mvtachi $src1 */
937 {
938 M32R_INSN_MVTACHI, "mvtachi", "mvtachi", 16,
939 { 0, { (1<<MACH_M32R), PIPE_S } }
940 },
941/* mvtachi $src1,$accs */
942 {
943 M32R_INSN_MVTACHI_A, "mvtachi-a", "mvtachi", 16,
944 { 0, { (1<<MACH_M32RX)|(1<<MACH_M32R2), PIPE_S } }
945 },
946/* mvtaclo $src1 */
947 {
948 M32R_INSN_MVTACLO, "mvtaclo", "mvtaclo", 16,
949 { 0, { (1<<MACH_M32R), PIPE_S } }
950 },
951/* mvtaclo $src1,$accs */
952 {
953 M32R_INSN_MVTACLO_A, "mvtaclo-a", "mvtaclo", 16,
954 { 0, { (1<<MACH_M32RX)|(1<<MACH_M32R2), PIPE_S } }
955 },
956/* mvtc $sr,$dcr */
957 {
958 M32R_INSN_MVTC, "mvtc", "mvtc", 16,
959 { 0, { (1<<MACH_BASE), PIPE_O } }
960 },
961/* neg $dr,$sr */
962 {
963 M32R_INSN_NEG, "neg", "neg", 16,
964 { 0, { (1<<MACH_BASE), PIPE_OS } }
965 },
966/* nop */
967 {
968 M32R_INSN_NOP, "nop", "nop", 16,
969 { 0, { (1<<MACH_BASE), PIPE_OS } }
970 },
971/* not $dr,$sr */
972 {
973 M32R_INSN_NOT, "not", "not", 16,
974 { 0, { (1<<MACH_BASE), PIPE_OS } }
975 },
976/* rac */
977 {
978 M32R_INSN_RAC, "rac", "rac", 16,
979 { 0, { (1<<MACH_M32R), PIPE_S } }
980 },
981/* rac $accd,$accs,$imm1 */
982 {
983 M32R_INSN_RAC_DSI, "rac-dsi", "rac", 16,
984 { 0, { (1<<MACH_M32RX)|(1<<MACH_M32R2), PIPE_S } }
985 },
986/* rach */
987 {
988 M32R_INSN_RACH, "rach", "rach", 16,
989 { 0, { (1<<MACH_M32R), PIPE_S } }
990 },
991/* rach $accd,$accs,$imm1 */
992 {
993 M32R_INSN_RACH_DSI, "rach-dsi", "rach", 16,
994 { 0, { (1<<MACH_M32RX)|(1<<MACH_M32R2), PIPE_S } }
995 },
996/* rte */
997 {
998 M32R_INSN_RTE, "rte", "rte", 16,
999 { 0|A(UNCOND_CTI), { (1<<MACH_BASE), PIPE_O } }
1000 },
1001/* seth $dr,$hash$hi16 */
1002 {
1003 M32R_INSN_SETH, "seth", "seth", 32,
1004 { 0, { (1<<MACH_BASE), PIPE_NONE } }
1005 },
1006/* sll $dr,$sr */
1007 {
1008 M32R_INSN_SLL, "sll", "sll", 16,
1009 { 0, { (1<<MACH_BASE), PIPE_O_OS } }
1010 },
1011/* sll3 $dr,$sr,$simm16 */
1012 {
1013 M32R_INSN_SLL3, "sll3", "sll3", 32,
1014 { 0, { (1<<MACH_BASE), PIPE_NONE } }
1015 },
1016/* slli $dr,$uimm5 */
1017 {
1018 M32R_INSN_SLLI, "slli", "slli", 16,
1019 { 0, { (1<<MACH_BASE), PIPE_O_OS } }
1020 },
1021/* sra $dr,$sr */
1022 {
1023 M32R_INSN_SRA, "sra", "sra", 16,
1024 { 0, { (1<<MACH_BASE), PIPE_O_OS } }
1025 },
1026/* sra3 $dr,$sr,$simm16 */
1027 {
1028 M32R_INSN_SRA3, "sra3", "sra3", 32,
1029 { 0, { (1<<MACH_BASE), PIPE_NONE } }
1030 },
1031/* srai $dr,$uimm5 */
1032 {
1033 M32R_INSN_SRAI, "srai", "srai", 16,
1034 { 0, { (1<<MACH_BASE), PIPE_O_OS } }
1035 },
1036/* srl $dr,$sr */
1037 {
1038 M32R_INSN_SRL, "srl", "srl", 16,
1039 { 0, { (1<<MACH_BASE), PIPE_O_OS } }
1040 },
1041/* srl3 $dr,$sr,$simm16 */
1042 {
1043 M32R_INSN_SRL3, "srl3", "srl3", 32,
1044 { 0, { (1<<MACH_BASE), PIPE_NONE } }
1045 },
1046/* srli $dr,$uimm5 */
1047 {
1048 M32R_INSN_SRLI, "srli", "srli", 16,
1049 { 0, { (1<<MACH_BASE), PIPE_O_OS } }
1050 },
1051/* st $src1,@$src2 */
1052 {
1053 M32R_INSN_ST, "st", "st", 16,
1054 { 0, { (1<<MACH_BASE), PIPE_O } }
1055 },
1056/* st $src1,@($slo16,$src2) */
1057 {
1058 M32R_INSN_ST_D, "st-d", "st", 32,
1059 { 0, { (1<<MACH_BASE), PIPE_NONE } }
1060 },
1061/* stb $src1,@$src2 */
1062 {
1063 M32R_INSN_STB, "stb", "stb", 16,
1064 { 0, { (1<<MACH_BASE), PIPE_O } }
1065 },
1066/* stb $src1,@($slo16,$src2) */
1067 {
1068 M32R_INSN_STB_D, "stb-d", "stb", 32,
1069 { 0, { (1<<MACH_BASE), PIPE_NONE } }
1070 },
1071/* sth $src1,@$src2 */
1072 {
1073 M32R_INSN_STH, "sth", "sth", 16,
1074 { 0, { (1<<MACH_BASE), PIPE_O } }
1075 },
1076/* sth $src1,@($slo16,$src2) */
1077 {
1078 M32R_INSN_STH_D, "sth-d", "sth", 32,
1079 { 0, { (1<<MACH_BASE), PIPE_NONE } }
1080 },
1081/* st $src1,@+$src2 */
1082 {
1083 M32R_INSN_ST_PLUS, "st-plus", "st", 16,
1084 { 0, { (1<<MACH_BASE), PIPE_O } }
1085 },
1086/* sth $src1,@$src2+ */
1087 {
1088 M32R_INSN_STH_PLUS, "sth-plus", "sth", 16,
1089 { 0|A(SPECIAL), { (1<<MACH_M32RX)|(1<<MACH_M32R2), PIPE_O } }
1090 },
1091/* stb $src1,@$src2+ */
1092 {
1093 M32R_INSN_STB_PLUS, "stb-plus", "stb", 16,
1094 { 0|A(SPECIAL), { (1<<MACH_M32RX)|(1<<MACH_M32R2), PIPE_O } }
1095 },
1096/* st $src1,@-$src2 */
1097 {
1098 M32R_INSN_ST_MINUS, "st-minus", "st", 16,
1099 { 0, { (1<<MACH_BASE), PIPE_O } }
1100 },
1101/* sub $dr,$sr */
1102 {
1103 M32R_INSN_SUB, "sub", "sub", 16,
1104 { 0, { (1<<MACH_BASE), PIPE_OS } }
1105 },
1106/* subv $dr,$sr */
1107 {
1108 M32R_INSN_SUBV, "subv", "subv", 16,
1109 { 0, { (1<<MACH_BASE), PIPE_OS } }
1110 },
1111/* subx $dr,$sr */
1112 {
1113 M32R_INSN_SUBX, "subx", "subx", 16,
1114 { 0, { (1<<MACH_BASE), PIPE_OS } }
1115 },
1116/* trap $uimm4 */
1117 {
1118 M32R_INSN_TRAP, "trap", "trap", 16,
1119 { 0|A(FILL_SLOT)|A(UNCOND_CTI), { (1<<MACH_BASE), PIPE_O } }
1120 },
1121/* unlock $src1,@$src2 */
1122 {
1123 M32R_INSN_UNLOCK, "unlock", "unlock", 16,
1124 { 0, { (1<<MACH_BASE), PIPE_O } }
1125 },
1126/* satb $dr,$sr */
1127 {
1128 M32R_INSN_SATB, "satb", "satb", 32,
1129 { 0, { (1<<MACH_M32RX)|(1<<MACH_M32R2), PIPE_NONE } }
1130 },
1131/* sath $dr,$sr */
1132 {
1133 M32R_INSN_SATH, "sath", "sath", 32,
1134 { 0, { (1<<MACH_M32RX)|(1<<MACH_M32R2), PIPE_NONE } }
1135 },
1136/* sat $dr,$sr */
1137 {
1138 M32R_INSN_SAT, "sat", "sat", 32,
1139 { 0|A(SPECIAL), { (1<<MACH_M32RX)|(1<<MACH_M32R2), PIPE_NONE } }
1140 },
1141/* pcmpbz $src2 */
1142 {
1143 M32R_INSN_PCMPBZ, "pcmpbz", "pcmpbz", 16,
1144 { 0|A(SPECIAL), { (1<<MACH_M32RX)|(1<<MACH_M32R2), PIPE_OS } }
1145 },
1146/* sadd */
1147 {
1148 M32R_INSN_SADD, "sadd", "sadd", 16,
1149 { 0, { (1<<MACH_M32RX)|(1<<MACH_M32R2), PIPE_S } }
1150 },
1151/* macwu1 $src1,$src2 */
1152 {
1153 M32R_INSN_MACWU1, "macwu1", "macwu1", 16,
1154 { 0, { (1<<MACH_M32RX)|(1<<MACH_M32R2), PIPE_S } }
1155 },
1156/* msblo $src1,$src2 */
1157 {
1158 M32R_INSN_MSBLO, "msblo", "msblo", 16,
1159 { 0, { (1<<MACH_M32RX)|(1<<MACH_M32R2), PIPE_S } }
1160 },
1161/* mulwu1 $src1,$src2 */
1162 {
1163 M32R_INSN_MULWU1, "mulwu1", "mulwu1", 16,
1164 { 0, { (1<<MACH_M32RX)|(1<<MACH_M32R2), PIPE_S } }
1165 },
1166/* maclh1 $src1,$src2 */
1167 {
1168 M32R_INSN_MACLH1, "maclh1", "maclh1", 16,
1169 { 0, { (1<<MACH_M32RX)|(1<<MACH_M32R2), PIPE_S } }
1170 },
1171/* sc */
1172 {
1173 M32R_INSN_SC, "sc", "sc", 16,
1174 { 0|A(SPECIAL)|A(SKIP_CTI), { (1<<MACH_M32RX)|(1<<MACH_M32R2), PIPE_O } }
1175 },
1176/* snc */
1177 {
1178 M32R_INSN_SNC, "snc", "snc", 16,
1179 { 0|A(SPECIAL)|A(SKIP_CTI), { (1<<MACH_M32RX)|(1<<MACH_M32R2), PIPE_O } }
1180 },
1181/* clrpsw $uimm8 */
1182 {
1183 M32R_INSN_CLRPSW, "clrpsw", "clrpsw", 16,
1184 { 0|A(SPECIAL_M32R), { (1<<MACH_BASE), PIPE_O } }
1185 },
1186/* setpsw $uimm8 */
1187 {
1188 M32R_INSN_SETPSW, "setpsw", "setpsw", 16,
1189 { 0|A(SPECIAL_M32R), { (1<<MACH_BASE), PIPE_O } }
1190 },
1191/* bset $uimm3,@($slo16,$sr) */
1192 {
1193 M32R_INSN_BSET, "bset", "bset", 32,
1194 { 0|A(SPECIAL_M32R), { (1<<MACH_BASE), PIPE_NONE } }
1195 },
1196/* bclr $uimm3,@($slo16,$sr) */
1197 {
1198 M32R_INSN_BCLR, "bclr", "bclr", 32,
1199 { 0|A(SPECIAL_M32R), { (1<<MACH_BASE), PIPE_NONE } }
1200 },
1201/* btst $uimm3,$sr */
1202 {
1203 M32R_INSN_BTST, "btst", "btst", 16,
1204 { 0|A(SPECIAL_M32R), { (1<<MACH_BASE), PIPE_O } }
1205 },
1206};
1207
1208#undef OP
1209#undef A
1210
1211/* Initialize anything needed to be done once, before any cpu_open call. */
1212static void init_tables PARAMS ((void));
1213
1214static void
1215init_tables ()
1216{
1217}
1218
1219static const CGEN_MACH * lookup_mach_via_bfd_name
1220 PARAMS ((const CGEN_MACH *, const char *));
1221static void build_hw_table PARAMS ((CGEN_CPU_TABLE *));
1222static void build_ifield_table PARAMS ((CGEN_CPU_TABLE *));
1223static void build_operand_table PARAMS ((CGEN_CPU_TABLE *));
1224static void build_insn_table PARAMS ((CGEN_CPU_TABLE *));
1225static void m32r_cgen_rebuild_tables PARAMS ((CGEN_CPU_TABLE *));
1226
1227/* Subroutine of m32r_cgen_cpu_open to look up a mach via its bfd name. */
1228
1229static const CGEN_MACH *
1230lookup_mach_via_bfd_name (table, name)
1231 const CGEN_MACH *table;
1232 const char *name;
1233{
1234 while (table->name)
1235 {
1236 if (strcmp (name, table->bfd_name) == 0)
1237 return table;
1238 ++table;
1239 }
1240 abort ();
1241}
1242
1243/* Subroutine of m32r_cgen_cpu_open to build the hardware table. */
1244
1245static void
1246build_hw_table (cd)
1247 CGEN_CPU_TABLE *cd;
1248{
1249 int i;
1250 int machs = cd->machs;
1251 const CGEN_HW_ENTRY *init = & m32r_cgen_hw_table[0];
1252 /* MAX_HW is only an upper bound on the number of selected entries.
1253 However each entry is indexed by it's enum so there can be holes in
1254 the table. */
1255 const CGEN_HW_ENTRY **selected =
1256 (const CGEN_HW_ENTRY **) xmalloc (MAX_HW * sizeof (CGEN_HW_ENTRY *));
1257
1258 cd->hw_table.init_entries = init;
1259 cd->hw_table.entry_size = sizeof (CGEN_HW_ENTRY);
1260 memset (selected, 0, MAX_HW * sizeof (CGEN_HW_ENTRY *));
1261 /* ??? For now we just use machs to determine which ones we want. */
1262 for (i = 0; init[i].name != NULL; ++i)
1263 if (CGEN_HW_ATTR_VALUE (&init[i], CGEN_HW_MACH)
1264 & machs)
1265 selected[init[i].type] = &init[i];
1266 cd->hw_table.entries = selected;
1267 cd->hw_table.num_entries = MAX_HW;
1268}
1269
1270/* Subroutine of m32r_cgen_cpu_open to build the hardware table. */
1271
1272static void
1273build_ifield_table (cd)
1274 CGEN_CPU_TABLE *cd;
1275{
1276 cd->ifld_table = & m32r_cgen_ifld_table[0];
1277}
1278
1279/* Subroutine of m32r_cgen_cpu_open to build the hardware table. */
1280
1281static void
1282build_operand_table (cd)
1283 CGEN_CPU_TABLE *cd;
1284{
1285 int i;
1286 int machs = cd->machs;
1287 const CGEN_OPERAND *init = & m32r_cgen_operand_table[0];
1288 /* MAX_OPERANDS is only an upper bound on the number of selected entries.
1289 However each entry is indexed by it's enum so there can be holes in
1290 the table. */
1291 const CGEN_OPERAND **selected =
1292 (const CGEN_OPERAND **) xmalloc (MAX_OPERANDS * sizeof (CGEN_OPERAND *));
1293
1294 cd->operand_table.init_entries = init;
1295 cd->operand_table.entry_size = sizeof (CGEN_OPERAND);
1296 memset (selected, 0, MAX_OPERANDS * sizeof (CGEN_OPERAND *));
1297 /* ??? For now we just use mach to determine which ones we want. */
1298 for (i = 0; init[i].name != NULL; ++i)
1299 if (CGEN_OPERAND_ATTR_VALUE (&init[i], CGEN_OPERAND_MACH)
1300 & machs)
1301 selected[init[i].type] = &init[i];
1302 cd->operand_table.entries = selected;
1303 cd->operand_table.num_entries = MAX_OPERANDS;
1304}
1305
1306/* Subroutine of m32r_cgen_cpu_open to build the hardware table.
1307 ??? This could leave out insns not supported by the specified mach/isa,
1308 but that would cause errors like "foo only supported by bar" to become
1309 "unknown insn", so for now we include all insns and require the app to
1310 do the checking later.
1311 ??? On the other hand, parsing of such insns may require their hardware or
1312 operand elements to be in the table [which they mightn't be]. */
1313
1314static void
1315build_insn_table (cd)
1316 CGEN_CPU_TABLE *cd;
1317{
1318 int i;
1319 const CGEN_IBASE *ib = & m32r_cgen_insn_table[0];
1320 CGEN_INSN *insns = (CGEN_INSN *) xmalloc (MAX_INSNS * sizeof (CGEN_INSN));
1321
1322 memset (insns, 0, MAX_INSNS * sizeof (CGEN_INSN));
1323 for (i = 0; i < MAX_INSNS; ++i)
1324 insns[i].base = &ib[i];
1325 cd->insn_table.init_entries = insns;
1326 cd->insn_table.entry_size = sizeof (CGEN_IBASE);
1327 cd->insn_table.num_init_entries = MAX_INSNS;
1328}
1329
1330/* Subroutine of m32r_cgen_cpu_open to rebuild the tables. */
1331
1332static void
1333m32r_cgen_rebuild_tables (cd)
1334 CGEN_CPU_TABLE *cd;
1335{
1336 int i;
1337 unsigned int isas = cd->isas;
1338 unsigned int machs = cd->machs;
1339
1340 cd->int_insn_p = CGEN_INT_INSN_P;
1341
1342 /* Data derived from the isa spec. */
1343#define UNSET (CGEN_SIZE_UNKNOWN + 1)
1344 cd->default_insn_bitsize = UNSET;
1345 cd->base_insn_bitsize = UNSET;
1346 cd->min_insn_bitsize = 65535; /* some ridiculously big number */
1347 cd->max_insn_bitsize = 0;
1348 for (i = 0; i < MAX_ISAS; ++i)
1349 if (((1 << i) & isas) != 0)
1350 {
1351 const CGEN_ISA *isa = & m32r_cgen_isa_table[i];
1352
1353 /* Default insn sizes of all selected isas must be
1354 equal or we set the result to 0, meaning "unknown". */
1355 if (cd->default_insn_bitsize == UNSET)
1356 cd->default_insn_bitsize = isa->default_insn_bitsize;
1357 else if (isa->default_insn_bitsize == cd->default_insn_bitsize)
1358 ; /* this is ok */
1359 else
1360 cd->default_insn_bitsize = CGEN_SIZE_UNKNOWN;
1361
1362 /* Base insn sizes of all selected isas must be equal
1363 or we set the result to 0, meaning "unknown". */
1364 if (cd->base_insn_bitsize == UNSET)
1365 cd->base_insn_bitsize = isa->base_insn_bitsize;
1366 else if (isa->base_insn_bitsize == cd->base_insn_bitsize)
1367 ; /* this is ok */
1368 else
1369 cd->base_insn_bitsize = CGEN_SIZE_UNKNOWN;
1370
1371 /* Set min,max insn sizes. */
1372 if (isa->min_insn_bitsize < cd->min_insn_bitsize)
1373 cd->min_insn_bitsize = isa->min_insn_bitsize;
1374 if (isa->max_insn_bitsize > cd->max_insn_bitsize)
1375 cd->max_insn_bitsize = isa->max_insn_bitsize;
1376 }
1377
1378 /* Data derived from the mach spec. */
1379 for (i = 0; i < MAX_MACHS; ++i)
1380 if (((1 << i) & machs) != 0)
1381 {
1382 const CGEN_MACH *mach = & m32r_cgen_mach_table[i];
1383
1384 if (mach->insn_chunk_bitsize != 0)
1385 {
1386 if (cd->insn_chunk_bitsize != 0 && cd->insn_chunk_bitsize != mach->insn_chunk_bitsize)
1387 {
1388 fprintf (stderr, "m32r_cgen_rebuild_tables: conflicting insn-chunk-bitsize values: `%d' vs. `%d'\n",
1389 cd->insn_chunk_bitsize, mach->insn_chunk_bitsize);
1390 abort ();
1391 }
1392
1393 cd->insn_chunk_bitsize = mach->insn_chunk_bitsize;
1394 }
1395 }
1396
1397 /* Determine which hw elements are used by MACH. */
1398 build_hw_table (cd);
1399
1400 /* Build the ifield table. */
1401 build_ifield_table (cd);
1402
1403 /* Determine which operands are used by MACH/ISA. */
1404 build_operand_table (cd);
1405
1406 /* Build the instruction table. */
1407 build_insn_table (cd);
1408}
1409
1410/* Initialize a cpu table and return a descriptor.
1411 It's much like opening a file, and must be the first function called.
1412 The arguments are a set of (type/value) pairs, terminated with
1413 CGEN_CPU_OPEN_END.
1414
1415 Currently supported values:
1416 CGEN_CPU_OPEN_ISAS: bitmap of values in enum isa_attr
1417 CGEN_CPU_OPEN_MACHS: bitmap of values in enum mach_attr
1418 CGEN_CPU_OPEN_BFDMACH: specify 1 mach using bfd name
1419 CGEN_CPU_OPEN_ENDIAN: specify endian choice
1420 CGEN_CPU_OPEN_END: terminates arguments
1421
1422 ??? Simultaneous multiple isas might not make sense, but it's not (yet)
1423 precluded.
1424
1425 ??? We only support ISO C stdargs here, not K&R.
1426 Laziness, plus experiment to see if anything requires K&R - eventually
1427 K&R will no longer be supported - e.g. GDB is currently trying this. */
1428
1429CGEN_CPU_DESC
1430m32r_cgen_cpu_open (enum cgen_cpu_open_arg arg_type, ...)
1431{
1432 CGEN_CPU_TABLE *cd = (CGEN_CPU_TABLE *) xmalloc (sizeof (CGEN_CPU_TABLE));
1433 static int init_p;
1434 unsigned int isas = 0; /* 0 = "unspecified" */
1435 unsigned int machs = 0; /* 0 = "unspecified" */
1436 enum cgen_endian endian = CGEN_ENDIAN_UNKNOWN;
1437 va_list ap;
1438
1439 if (! init_p)
1440 {
1441 init_tables ();
1442 init_p = 1;
1443 }
1444
1445 memset (cd, 0, sizeof (*cd));
1446
1447 va_start (ap, arg_type);
1448 while (arg_type != CGEN_CPU_OPEN_END)
1449 {
1450 switch (arg_type)
1451 {
1452 case CGEN_CPU_OPEN_ISAS :
1453 isas = va_arg (ap, unsigned int);
1454 break;
1455 case CGEN_CPU_OPEN_MACHS :
1456 machs = va_arg (ap, unsigned int);
1457 break;
1458 case CGEN_CPU_OPEN_BFDMACH :
1459 {
1460 const char *name = va_arg (ap, const char *);
1461 const CGEN_MACH *mach =
1462 lookup_mach_via_bfd_name (m32r_cgen_mach_table, name);
1463
1464 machs |= 1 << mach->num;
1465 break;
1466 }
1467 case CGEN_CPU_OPEN_ENDIAN :
1468 endian = va_arg (ap, enum cgen_endian);
1469 break;
1470 default :
1471 fprintf (stderr, "m32r_cgen_cpu_open: unsupported argument `%d'\n",
1472 arg_type);
1473 abort (); /* ??? return NULL? */
1474 }
1475 arg_type = va_arg (ap, enum cgen_cpu_open_arg);
1476 }
1477 va_end (ap);
1478
1479 /* mach unspecified means "all" */
1480 if (machs == 0)
1481 machs = (1 << MAX_MACHS) - 1;
1482 /* base mach is always selected */
1483 machs |= 1;
1484 /* isa unspecified means "all" */
1485 if (isas == 0)
1486 isas = (1 << MAX_ISAS) - 1;
1487 if (endian == CGEN_ENDIAN_UNKNOWN)
1488 {
1489 /* ??? If target has only one, could have a default. */
1490 fprintf (stderr, "m32r_cgen_cpu_open: no endianness specified\n");
1491 abort ();
1492 }
1493
1494 cd->isas = isas;
1495 cd->machs = machs;
1496 cd->endian = endian;
1497 /* FIXME: for the sparc case we can determine insn-endianness statically.
1498 The worry here is where both data and insn endian can be independently
1499 chosen, in which case this function will need another argument.
1500 Actually, will want to allow for more arguments in the future anyway. */
1501 cd->insn_endian = endian;
1502
1503 /* Table (re)builder. */
1504 cd->rebuild_tables = m32r_cgen_rebuild_tables;
1505 m32r_cgen_rebuild_tables (cd);
1506
1507 /* Default to not allowing signed overflow. */
1508 cd->signed_overflow_ok_p = 0;
1509
1510 return (CGEN_CPU_DESC) cd;
1511}
1512
1513/* Cover fn to m32r_cgen_cpu_open to handle the simple case of 1 isa, 1 mach.
1514 MACH_NAME is the bfd name of the mach. */
1515
1516CGEN_CPU_DESC
1517m32r_cgen_cpu_open_1 (mach_name, endian)
1518 const char *mach_name;
1519 enum cgen_endian endian;
1520{
1521 return m32r_cgen_cpu_open (CGEN_CPU_OPEN_BFDMACH, mach_name,
1522 CGEN_CPU_OPEN_ENDIAN, endian,
1523 CGEN_CPU_OPEN_END);
1524}
1525
1526/* Close a cpu table.
1527 ??? This can live in a machine independent file, but there's currently
1528 no place to put this file (there's no libcgen). libopcodes is the wrong
1529 place as some simulator ports use this but they don't use libopcodes. */
1530
1531void
1532m32r_cgen_cpu_close (cd)
1533 CGEN_CPU_DESC cd;
1534{
1535 unsigned int i;
1536 const CGEN_INSN *insns;
1537
1538 if (cd->macro_insn_table.init_entries)
1539 {
1540 insns = cd->macro_insn_table.init_entries;
1541 for (i = 0; i < cd->macro_insn_table.num_init_entries; ++i, ++insns)
1542 {
1543 if (CGEN_INSN_RX ((insns)))
1544 regfree (CGEN_INSN_RX (insns));
1545 }
1546 }
1547
1548 if (cd->insn_table.init_entries)
1549 {
1550 insns = cd->insn_table.init_entries;
1551 for (i = 0; i < cd->insn_table.num_init_entries; ++i, ++insns)
1552 {
1553 if (CGEN_INSN_RX (insns))
1554 regfree (CGEN_INSN_RX (insns));
1555 }
1556 }
1557
1558
1559
1560 if (cd->macro_insn_table.init_entries)
1561 free ((CGEN_INSN *) cd->macro_insn_table.init_entries);
1562
1563 if (cd->insn_table.init_entries)
1564 free ((CGEN_INSN *) cd->insn_table.init_entries);
1565
1566 if (cd->hw_table.entries)
1567 free ((CGEN_HW_ENTRY *) cd->hw_table.entries);
1568
1569 if (cd->operand_table.entries)
1570 free ((CGEN_HW_ENTRY *) cd->operand_table.entries);
1571
1572 free (cd);
1573}
1574
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