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[/] [openrisc/] [trunk/] [gnu-stable/] [binutils-2.20.1/] [opcodes/] [lm32-desc.c] - Blame information for rev 205

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1 205 julius
/* CPU data for lm32.
2
 
3
THIS FILE IS MACHINE GENERATED WITH CGEN.
4
 
5
Copyright 1996-2009 Free Software Foundation, Inc.
6
 
7
This file is part of the GNU Binutils and/or GDB, the GNU debugger.
8
 
9
   This file is free software; you can redistribute it and/or modify
10
   it under the terms of the GNU General Public License as published by
11
   the Free Software Foundation; either version 3, or (at your option)
12
   any later version.
13
 
14
   It is distributed in the hope that it will be useful, but WITHOUT
15
   ANY WARRANTY; without even the implied warranty of MERCHANTABILITY
16
   or FITNESS FOR A PARTICULAR PURPOSE.  See the GNU General Public
17
   License for more details.
18
 
19
   You should have received a copy of the GNU General Public License along
20
   with this program; if not, write to the Free Software Foundation, Inc.,
21
   51 Franklin Street - Fifth Floor, Boston, MA 02110-1301, 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 "lm32-desc.h"
32
#include "lm32-opc.h"
33
#include "opintl.h"
34
#include "libiberty.h"
35
#include "xregex.h"
36
 
37
/* Attributes.  */
38
 
39
static const CGEN_ATTR_ENTRY bool_attr[] =
40
{
41
  { "#f", 0 },
42
  { "#t", 1 },
43
  { 0, 0 }
44
};
45
 
46
static const CGEN_ATTR_ENTRY MACH_attr[] ATTRIBUTE_UNUSED =
47
{
48
  { "base", MACH_BASE },
49
  { "lm32", MACH_LM32 },
50
  { "max", MACH_MAX },
51
  { 0, 0 }
52
};
53
 
54
static const CGEN_ATTR_ENTRY ISA_attr[] ATTRIBUTE_UNUSED =
55
{
56
  { "lm32", ISA_LM32 },
57
  { "max", ISA_MAX },
58
  { 0, 0 }
59
};
60
 
61
const CGEN_ATTR_TABLE lm32_cgen_ifield_attr_table[] =
62
{
63
  { "MACH", & MACH_attr[0], & MACH_attr[0] },
64
  { "VIRTUAL", &bool_attr[0], &bool_attr[0] },
65
  { "PCREL-ADDR", &bool_attr[0], &bool_attr[0] },
66
  { "ABS-ADDR", &bool_attr[0], &bool_attr[0] },
67
  { "RESERVED", &bool_attr[0], &bool_attr[0] },
68
  { "SIGN-OPT", &bool_attr[0], &bool_attr[0] },
69
  { "SIGNED", &bool_attr[0], &bool_attr[0] },
70
  { 0, 0, 0 }
71
};
72
 
73
const CGEN_ATTR_TABLE lm32_cgen_hardware_attr_table[] =
74
{
75
  { "MACH", & MACH_attr[0], & MACH_attr[0] },
76
  { "VIRTUAL", &bool_attr[0], &bool_attr[0] },
77
  { "CACHE-ADDR", &bool_attr[0], &bool_attr[0] },
78
  { "PC", &bool_attr[0], &bool_attr[0] },
79
  { "PROFILE", &bool_attr[0], &bool_attr[0] },
80
  { 0, 0, 0 }
81
};
82
 
83
const CGEN_ATTR_TABLE lm32_cgen_operand_attr_table[] =
84
{
85
  { "MACH", & MACH_attr[0], & MACH_attr[0] },
86
  { "VIRTUAL", &bool_attr[0], &bool_attr[0] },
87
  { "PCREL-ADDR", &bool_attr[0], &bool_attr[0] },
88
  { "ABS-ADDR", &bool_attr[0], &bool_attr[0] },
89
  { "SIGN-OPT", &bool_attr[0], &bool_attr[0] },
90
  { "SIGNED", &bool_attr[0], &bool_attr[0] },
91
  { "NEGATIVE", &bool_attr[0], &bool_attr[0] },
92
  { "RELAX", &bool_attr[0], &bool_attr[0] },
93
  { "SEM-ONLY", &bool_attr[0], &bool_attr[0] },
94
  { 0, 0, 0 }
95
};
96
 
97
const CGEN_ATTR_TABLE lm32_cgen_insn_attr_table[] =
98
{
99
  { "MACH", & MACH_attr[0], & MACH_attr[0] },
100
  { "ALIAS", &bool_attr[0], &bool_attr[0] },
101
  { "VIRTUAL", &bool_attr[0], &bool_attr[0] },
102
  { "UNCOND-CTI", &bool_attr[0], &bool_attr[0] },
103
  { "COND-CTI", &bool_attr[0], &bool_attr[0] },
104
  { "SKIP-CTI", &bool_attr[0], &bool_attr[0] },
105
  { "DELAY-SLOT", &bool_attr[0], &bool_attr[0] },
106
  { "RELAXABLE", &bool_attr[0], &bool_attr[0] },
107
  { "RELAXED", &bool_attr[0], &bool_attr[0] },
108
  { "NO-DIS", &bool_attr[0], &bool_attr[0] },
109
  { "PBB", &bool_attr[0], &bool_attr[0] },
110
  { 0, 0, 0 }
111
};
112
 
113
/* Instruction set variants.  */
114
 
115
static const CGEN_ISA lm32_cgen_isa_table[] = {
116
  { "lm32", 32, 32, 32, 32 },
117
  { 0, 0, 0, 0, 0 }
118
};
119
 
120
/* Machine variants.  */
121
 
122
static const CGEN_MACH lm32_cgen_mach_table[] = {
123
  { "lm32", "lm32", MACH_LM32, 0 },
124
  { 0, 0, 0, 0 }
125
};
126
 
127
static CGEN_KEYWORD_ENTRY lm32_cgen_opval_h_gr_entries[] =
128
{
129
  { "gp", 26, {0, {{{0, 0}}}}, 0, 0 },
130
  { "fp", 27, {0, {{{0, 0}}}}, 0, 0 },
131
  { "sp", 28, {0, {{{0, 0}}}}, 0, 0 },
132
  { "ra", 29, {0, {{{0, 0}}}}, 0, 0 },
133
  { "ea", 30, {0, {{{0, 0}}}}, 0, 0 },
134
  { "ba", 31, {0, {{{0, 0}}}}, 0, 0 },
135
  { "r0", 0, {0, {{{0, 0}}}}, 0, 0 },
136
  { "r1", 1, {0, {{{0, 0}}}}, 0, 0 },
137
  { "r2", 2, {0, {{{0, 0}}}}, 0, 0 },
138
  { "r3", 3, {0, {{{0, 0}}}}, 0, 0 },
139
  { "r4", 4, {0, {{{0, 0}}}}, 0, 0 },
140
  { "r5", 5, {0, {{{0, 0}}}}, 0, 0 },
141
  { "r6", 6, {0, {{{0, 0}}}}, 0, 0 },
142
  { "r7", 7, {0, {{{0, 0}}}}, 0, 0 },
143
  { "r8", 8, {0, {{{0, 0}}}}, 0, 0 },
144
  { "r9", 9, {0, {{{0, 0}}}}, 0, 0 },
145
  { "r10", 10, {0, {{{0, 0}}}}, 0, 0 },
146
  { "r11", 11, {0, {{{0, 0}}}}, 0, 0 },
147
  { "r12", 12, {0, {{{0, 0}}}}, 0, 0 },
148
  { "r13", 13, {0, {{{0, 0}}}}, 0, 0 },
149
  { "r14", 14, {0, {{{0, 0}}}}, 0, 0 },
150
  { "r15", 15, {0, {{{0, 0}}}}, 0, 0 },
151
  { "r16", 16, {0, {{{0, 0}}}}, 0, 0 },
152
  { "r17", 17, {0, {{{0, 0}}}}, 0, 0 },
153
  { "r18", 18, {0, {{{0, 0}}}}, 0, 0 },
154
  { "r19", 19, {0, {{{0, 0}}}}, 0, 0 },
155
  { "r20", 20, {0, {{{0, 0}}}}, 0, 0 },
156
  { "r21", 21, {0, {{{0, 0}}}}, 0, 0 },
157
  { "r22", 22, {0, {{{0, 0}}}}, 0, 0 },
158
  { "r23", 23, {0, {{{0, 0}}}}, 0, 0 },
159
  { "r24", 24, {0, {{{0, 0}}}}, 0, 0 },
160
  { "r25", 25, {0, {{{0, 0}}}}, 0, 0 },
161
  { "r26", 26, {0, {{{0, 0}}}}, 0, 0 },
162
  { "r27", 27, {0, {{{0, 0}}}}, 0, 0 },
163
  { "r28", 28, {0, {{{0, 0}}}}, 0, 0 },
164
  { "r29", 29, {0, {{{0, 0}}}}, 0, 0 },
165
  { "r30", 30, {0, {{{0, 0}}}}, 0, 0 },
166
  { "r31", 31, {0, {{{0, 0}}}}, 0, 0 }
167
};
168
 
169
CGEN_KEYWORD lm32_cgen_opval_h_gr =
170
{
171
  & lm32_cgen_opval_h_gr_entries[0],
172
  38,
173
  0, 0, 0, 0, ""
174
};
175
 
176
static CGEN_KEYWORD_ENTRY lm32_cgen_opval_h_csr_entries[] =
177
{
178
  { "IE", 0, {0, {{{0, 0}}}}, 0, 0 },
179
  { "IM", 1, {0, {{{0, 0}}}}, 0, 0 },
180
  { "IP", 2, {0, {{{0, 0}}}}, 0, 0 },
181
  { "ICC", 3, {0, {{{0, 0}}}}, 0, 0 },
182
  { "DCC", 4, {0, {{{0, 0}}}}, 0, 0 },
183
  { "CC", 5, {0, {{{0, 0}}}}, 0, 0 },
184
  { "CFG", 6, {0, {{{0, 0}}}}, 0, 0 },
185
  { "EBA", 7, {0, {{{0, 0}}}}, 0, 0 },
186
  { "DC", 8, {0, {{{0, 0}}}}, 0, 0 },
187
  { "DEBA", 9, {0, {{{0, 0}}}}, 0, 0 },
188
  { "JTX", 14, {0, {{{0, 0}}}}, 0, 0 },
189
  { "JRX", 15, {0, {{{0, 0}}}}, 0, 0 },
190
  { "BP0", 16, {0, {{{0, 0}}}}, 0, 0 },
191
  { "BP1", 17, {0, {{{0, 0}}}}, 0, 0 },
192
  { "BP2", 18, {0, {{{0, 0}}}}, 0, 0 },
193
  { "BP3", 19, {0, {{{0, 0}}}}, 0, 0 },
194
  { "WP0", 24, {0, {{{0, 0}}}}, 0, 0 },
195
  { "WP1", 25, {0, {{{0, 0}}}}, 0, 0 },
196
  { "WP2", 26, {0, {{{0, 0}}}}, 0, 0 },
197
  { "WP3", 27, {0, {{{0, 0}}}}, 0, 0 }
198
};
199
 
200
CGEN_KEYWORD lm32_cgen_opval_h_csr =
201
{
202
  & lm32_cgen_opval_h_csr_entries[0],
203
  20,
204
  0, 0, 0, 0, ""
205
};
206
 
207
 
208
/* The hardware table.  */
209
 
210
#if defined (__STDC__) || defined (ALMOST_STDC) || defined (HAVE_STRINGIZE)
211
#define A(a) (1 << CGEN_HW_##a)
212
#else
213
#define A(a) (1 << CGEN_HW_/**/a)
214
#endif
215
 
216
const CGEN_HW_ENTRY lm32_cgen_hw_table[] =
217
{
218
  { "h-memory", HW_H_MEMORY, CGEN_ASM_NONE, 0, { 0, { { { (1<<MACH_BASE), 0 } } } } },
219
  { "h-sint", HW_H_SINT, CGEN_ASM_NONE, 0, { 0, { { { (1<<MACH_BASE), 0 } } } } },
220
  { "h-uint", HW_H_UINT, CGEN_ASM_NONE, 0, { 0, { { { (1<<MACH_BASE), 0 } } } } },
221
  { "h-addr", HW_H_ADDR, CGEN_ASM_NONE, 0, { 0, { { { (1<<MACH_BASE), 0 } } } } },
222
  { "h-iaddr", HW_H_IADDR, CGEN_ASM_NONE, 0, { 0, { { { (1<<MACH_BASE), 0 } } } } },
223
  { "h-pc", HW_H_PC, CGEN_ASM_NONE, 0, { 0|A(PC), { { { (1<<MACH_BASE), 0 } } } } },
224
  { "h-gr", HW_H_GR, CGEN_ASM_KEYWORD, (PTR) & lm32_cgen_opval_h_gr, { 0, { { { (1<<MACH_BASE), 0 } } } } },
225
  { "h-csr", HW_H_CSR, CGEN_ASM_KEYWORD, (PTR) & lm32_cgen_opval_h_csr, { 0, { { { (1<<MACH_BASE), 0 } } } } },
226
  { 0, 0, CGEN_ASM_NONE, 0, { 0, { { { (1<<MACH_BASE), 0 } } } } }
227
};
228
 
229
#undef A
230
 
231
 
232
/* The instruction field table.  */
233
 
234
#if defined (__STDC__) || defined (ALMOST_STDC) || defined (HAVE_STRINGIZE)
235
#define A(a) (1 << CGEN_IFLD_##a)
236
#else
237
#define A(a) (1 << CGEN_IFLD_/**/a)
238
#endif
239
 
240
const CGEN_IFLD lm32_cgen_ifld_table[] =
241
{
242
  { LM32_F_NIL, "f-nil", 0, 0, 0, 0, { 0, { { { (1<<MACH_BASE), 0 } } } }  },
243
  { LM32_F_ANYOF, "f-anyof", 0, 0, 0, 0, { 0, { { { (1<<MACH_BASE), 0 } } } }  },
244
  { LM32_F_OPCODE, "f-opcode", 0, 32, 31, 6, { 0, { { { (1<<MACH_BASE), 0 } } } }  },
245
  { LM32_F_R0, "f-r0", 0, 32, 25, 5, { 0, { { { (1<<MACH_BASE), 0 } } } }  },
246
  { LM32_F_R1, "f-r1", 0, 32, 20, 5, { 0, { { { (1<<MACH_BASE), 0 } } } }  },
247
  { LM32_F_R2, "f-r2", 0, 32, 15, 5, { 0, { { { (1<<MACH_BASE), 0 } } } }  },
248
  { LM32_F_RESV0, "f-resv0", 0, 32, 10, 11, { 0|A(RESERVED), { { { (1<<MACH_BASE), 0 } } } }  },
249
  { LM32_F_SHIFT, "f-shift", 0, 32, 4, 5, { 0, { { { (1<<MACH_BASE), 0 } } } }  },
250
  { LM32_F_IMM, "f-imm", 0, 32, 15, 16, { 0, { { { (1<<MACH_BASE), 0 } } } }  },
251
  { LM32_F_UIMM, "f-uimm", 0, 32, 15, 16, { 0, { { { (1<<MACH_BASE), 0 } } } }  },
252
  { LM32_F_CSR, "f-csr", 0, 32, 25, 5, { 0, { { { (1<<MACH_BASE), 0 } } } }  },
253
  { LM32_F_USER, "f-user", 0, 32, 10, 11, { 0, { { { (1<<MACH_BASE), 0 } } } }  },
254
  { LM32_F_EXCEPTION, "f-exception", 0, 32, 25, 26, { 0, { { { (1<<MACH_BASE), 0 } } } }  },
255
  { LM32_F_BRANCH, "f-branch", 0, 32, 15, 16, { 0|A(PCREL_ADDR), { { { (1<<MACH_BASE), 0 } } } }  },
256
  { LM32_F_CALL, "f-call", 0, 32, 25, 26, { 0|A(PCREL_ADDR), { { { (1<<MACH_BASE), 0 } } } }  },
257
  { 0, 0, 0, 0, 0, 0, { 0, { { { (1<<MACH_BASE), 0 } } } } }
258
};
259
 
260
#undef A
261
 
262
 
263
 
264
/* multi ifield declarations */
265
 
266
 
267
 
268
/* multi ifield definitions */
269
 
270
 
271
/* The operand table.  */
272
 
273
#if defined (__STDC__) || defined (ALMOST_STDC) || defined (HAVE_STRINGIZE)
274
#define A(a) (1 << CGEN_OPERAND_##a)
275
#else
276
#define A(a) (1 << CGEN_OPERAND_/**/a)
277
#endif
278
#if defined (__STDC__) || defined (ALMOST_STDC) || defined (HAVE_STRINGIZE)
279
#define OPERAND(op) LM32_OPERAND_##op
280
#else
281
#define OPERAND(op) LM32_OPERAND_/**/op
282
#endif
283
 
284
const CGEN_OPERAND lm32_cgen_operand_table[] =
285
{
286
/* pc: program counter */
287
  { "pc", LM32_OPERAND_PC, HW_H_PC, 0, 0,
288
    { 0, { (const PTR) &lm32_cgen_ifld_table[LM32_F_NIL] } },
289
    { 0|A(SEM_ONLY), { { { (1<<MACH_BASE), 0 } } } }  },
290
/* r0: register 0 */
291
  { "r0", LM32_OPERAND_R0, HW_H_GR, 25, 5,
292
    { 0, { (const PTR) &lm32_cgen_ifld_table[LM32_F_R0] } },
293
    { 0, { { { (1<<MACH_BASE), 0 } } } }  },
294
/* r1: register 1 */
295
  { "r1", LM32_OPERAND_R1, HW_H_GR, 20, 5,
296
    { 0, { (const PTR) &lm32_cgen_ifld_table[LM32_F_R1] } },
297
    { 0, { { { (1<<MACH_BASE), 0 } } } }  },
298
/* r2: register 2 */
299
  { "r2", LM32_OPERAND_R2, HW_H_GR, 15, 5,
300
    { 0, { (const PTR) &lm32_cgen_ifld_table[LM32_F_R2] } },
301
    { 0, { { { (1<<MACH_BASE), 0 } } } }  },
302
/* shift: shift amout */
303
  { "shift", LM32_OPERAND_SHIFT, HW_H_UINT, 4, 5,
304
    { 0, { (const PTR) &lm32_cgen_ifld_table[LM32_F_SHIFT] } },
305
    { 0, { { { (1<<MACH_BASE), 0 } } } }  },
306
/* imm: signed immediate */
307
  { "imm", LM32_OPERAND_IMM, HW_H_SINT, 15, 16,
308
    { 0, { (const PTR) &lm32_cgen_ifld_table[LM32_F_IMM] } },
309
    { 0, { { { (1<<MACH_BASE), 0 } } } }  },
310
/* uimm: unsigned immediate */
311
  { "uimm", LM32_OPERAND_UIMM, HW_H_UINT, 15, 16,
312
    { 0, { (const PTR) &lm32_cgen_ifld_table[LM32_F_UIMM] } },
313
    { 0, { { { (1<<MACH_BASE), 0 } } } }  },
314
/* branch: branch offset */
315
  { "branch", LM32_OPERAND_BRANCH, HW_H_IADDR, 15, 16,
316
    { 0, { (const PTR) &lm32_cgen_ifld_table[LM32_F_BRANCH] } },
317
    { 0|A(PCREL_ADDR), { { { (1<<MACH_BASE), 0 } } } }  },
318
/* call: call offset */
319
  { "call", LM32_OPERAND_CALL, HW_H_IADDR, 25, 26,
320
    { 0, { (const PTR) &lm32_cgen_ifld_table[LM32_F_CALL] } },
321
    { 0|A(PCREL_ADDR), { { { (1<<MACH_BASE), 0 } } } }  },
322
/* csr: csr */
323
  { "csr", LM32_OPERAND_CSR, HW_H_CSR, 25, 5,
324
    { 0, { (const PTR) &lm32_cgen_ifld_table[LM32_F_CSR] } },
325
    { 0, { { { (1<<MACH_BASE), 0 } } } }  },
326
/* user: user */
327
  { "user", LM32_OPERAND_USER, HW_H_UINT, 10, 11,
328
    { 0, { (const PTR) &lm32_cgen_ifld_table[LM32_F_USER] } },
329
    { 0, { { { (1<<MACH_BASE), 0 } } } }  },
330
/* exception: exception */
331
  { "exception", LM32_OPERAND_EXCEPTION, HW_H_UINT, 25, 26,
332
    { 0, { (const PTR) &lm32_cgen_ifld_table[LM32_F_EXCEPTION] } },
333
    { 0, { { { (1<<MACH_BASE), 0 } } } }  },
334
/* hi16: high 16-bit immediate */
335
  { "hi16", LM32_OPERAND_HI16, HW_H_UINT, 15, 16,
336
    { 0, { (const PTR) &lm32_cgen_ifld_table[LM32_F_UIMM] } },
337
    { 0, { { { (1<<MACH_BASE), 0 } } } }  },
338
/* lo16: low 16-bit immediate */
339
  { "lo16", LM32_OPERAND_LO16, HW_H_UINT, 15, 16,
340
    { 0, { (const PTR) &lm32_cgen_ifld_table[LM32_F_UIMM] } },
341
    { 0, { { { (1<<MACH_BASE), 0 } } } }  },
342
/* gp16: gp relative 16-bit immediate */
343
  { "gp16", LM32_OPERAND_GP16, HW_H_SINT, 15, 16,
344
    { 0, { (const PTR) &lm32_cgen_ifld_table[LM32_F_IMM] } },
345
    { 0, { { { (1<<MACH_BASE), 0 } } } }  },
346
/* got16: got 16-bit immediate */
347
  { "got16", LM32_OPERAND_GOT16, HW_H_SINT, 15, 16,
348
    { 0, { (const PTR) &lm32_cgen_ifld_table[LM32_F_IMM] } },
349
    { 0, { { { (1<<MACH_BASE), 0 } } } }  },
350
/* gotoffhi16: got offset high 16-bit immediate */
351
  { "gotoffhi16", LM32_OPERAND_GOTOFFHI16, HW_H_SINT, 15, 16,
352
    { 0, { (const PTR) &lm32_cgen_ifld_table[LM32_F_IMM] } },
353
    { 0, { { { (1<<MACH_BASE), 0 } } } }  },
354
/* gotofflo16: got offset low 16-bit immediate */
355
  { "gotofflo16", LM32_OPERAND_GOTOFFLO16, HW_H_SINT, 15, 16,
356
    { 0, { (const PTR) &lm32_cgen_ifld_table[LM32_F_IMM] } },
357
    { 0, { { { (1<<MACH_BASE), 0 } } } }  },
358
/* sentinel */
359
  { 0, 0, 0, 0, 0,
360
    { 0, { (const PTR) 0 } },
361
    { 0, { { { (1<<MACH_BASE), 0 } } } } }
362
};
363
 
364
#undef A
365
 
366
 
367
/* The instruction table.  */
368
 
369
#define OP(field) CGEN_SYNTAX_MAKE_FIELD (OPERAND (field))
370
#if defined (__STDC__) || defined (ALMOST_STDC) || defined (HAVE_STRINGIZE)
371
#define A(a) (1 << CGEN_INSN_##a)
372
#else
373
#define A(a) (1 << CGEN_INSN_/**/a)
374
#endif
375
 
376
static const CGEN_IBASE lm32_cgen_insn_table[MAX_INSNS] =
377
{
378
  /* Special null first entry.
379
     A `num' value of zero is thus invalid.
380
     Also, the special `invalid' insn resides here.  */
381
  { 0, 0, 0, 0, { 0, { { { (1<<MACH_BASE), 0 } } } } },
382
/* add $r2,$r0,$r1 */
383
  {
384
    LM32_INSN_ADD, "add", "add", 32,
385
    { 0, { { { (1<<MACH_BASE), 0 } } } }
386
  },
387
/* addi $r1,$r0,$imm */
388
  {
389
    LM32_INSN_ADDI, "addi", "addi", 32,
390
    { 0, { { { (1<<MACH_BASE), 0 } } } }
391
  },
392
/* and $r2,$r0,$r1 */
393
  {
394
    LM32_INSN_AND, "and", "and", 32,
395
    { 0, { { { (1<<MACH_BASE), 0 } } } }
396
  },
397
/* andi $r1,$r0,$uimm */
398
  {
399
    LM32_INSN_ANDI, "andi", "andi", 32,
400
    { 0, { { { (1<<MACH_BASE), 0 } } } }
401
  },
402
/* andhi $r1,$r0,$hi16 */
403
  {
404
    LM32_INSN_ANDHII, "andhii", "andhi", 32,
405
    { 0, { { { (1<<MACH_BASE), 0 } } } }
406
  },
407
/* b $r0 */
408
  {
409
    LM32_INSN_B, "b", "b", 32,
410
    { 0|A(UNCOND_CTI), { { { (1<<MACH_BASE), 0 } } } }
411
  },
412
/* bi $call */
413
  {
414
    LM32_INSN_BI, "bi", "bi", 32,
415
    { 0|A(UNCOND_CTI), { { { (1<<MACH_BASE), 0 } } } }
416
  },
417
/* be $r0,$r1,$branch */
418
  {
419
    LM32_INSN_BE, "be", "be", 32,
420
    { 0|A(COND_CTI), { { { (1<<MACH_BASE), 0 } } } }
421
  },
422
/* bg $r0,$r1,$branch */
423
  {
424
    LM32_INSN_BG, "bg", "bg", 32,
425
    { 0|A(COND_CTI), { { { (1<<MACH_BASE), 0 } } } }
426
  },
427
/* bge $r0,$r1,$branch */
428
  {
429
    LM32_INSN_BGE, "bge", "bge", 32,
430
    { 0|A(COND_CTI), { { { (1<<MACH_BASE), 0 } } } }
431
  },
432
/* bgeu $r0,$r1,$branch */
433
  {
434
    LM32_INSN_BGEU, "bgeu", "bgeu", 32,
435
    { 0|A(COND_CTI), { { { (1<<MACH_BASE), 0 } } } }
436
  },
437
/* bgu $r0,$r1,$branch */
438
  {
439
    LM32_INSN_BGU, "bgu", "bgu", 32,
440
    { 0|A(COND_CTI), { { { (1<<MACH_BASE), 0 } } } }
441
  },
442
/* bne $r0,$r1,$branch */
443
  {
444
    LM32_INSN_BNE, "bne", "bne", 32,
445
    { 0|A(COND_CTI), { { { (1<<MACH_BASE), 0 } } } }
446
  },
447
/* call $r0 */
448
  {
449
    LM32_INSN_CALL, "call", "call", 32,
450
    { 0|A(UNCOND_CTI), { { { (1<<MACH_BASE), 0 } } } }
451
  },
452
/* calli $call */
453
  {
454
    LM32_INSN_CALLI, "calli", "calli", 32,
455
    { 0|A(UNCOND_CTI), { { { (1<<MACH_BASE), 0 } } } }
456
  },
457
/* cmpe $r2,$r0,$r1 */
458
  {
459
    LM32_INSN_CMPE, "cmpe", "cmpe", 32,
460
    { 0, { { { (1<<MACH_BASE), 0 } } } }
461
  },
462
/* cmpei $r1,$r0,$imm */
463
  {
464
    LM32_INSN_CMPEI, "cmpei", "cmpei", 32,
465
    { 0, { { { (1<<MACH_BASE), 0 } } } }
466
  },
467
/* cmpg $r2,$r0,$r1 */
468
  {
469
    LM32_INSN_CMPG, "cmpg", "cmpg", 32,
470
    { 0, { { { (1<<MACH_BASE), 0 } } } }
471
  },
472
/* cmpgi $r1,$r0,$imm */
473
  {
474
    LM32_INSN_CMPGI, "cmpgi", "cmpgi", 32,
475
    { 0, { { { (1<<MACH_BASE), 0 } } } }
476
  },
477
/* cmpge $r2,$r0,$r1 */
478
  {
479
    LM32_INSN_CMPGE, "cmpge", "cmpge", 32,
480
    { 0, { { { (1<<MACH_BASE), 0 } } } }
481
  },
482
/* cmpgei $r1,$r0,$imm */
483
  {
484
    LM32_INSN_CMPGEI, "cmpgei", "cmpgei", 32,
485
    { 0, { { { (1<<MACH_BASE), 0 } } } }
486
  },
487
/* cmpgeu $r2,$r0,$r1 */
488
  {
489
    LM32_INSN_CMPGEU, "cmpgeu", "cmpgeu", 32,
490
    { 0, { { { (1<<MACH_BASE), 0 } } } }
491
  },
492
/* cmpgeui $r1,$r0,$uimm */
493
  {
494
    LM32_INSN_CMPGEUI, "cmpgeui", "cmpgeui", 32,
495
    { 0, { { { (1<<MACH_BASE), 0 } } } }
496
  },
497
/* cmpgu $r2,$r0,$r1 */
498
  {
499
    LM32_INSN_CMPGU, "cmpgu", "cmpgu", 32,
500
    { 0, { { { (1<<MACH_BASE), 0 } } } }
501
  },
502
/* cmpgui $r1,$r0,$uimm */
503
  {
504
    LM32_INSN_CMPGUI, "cmpgui", "cmpgui", 32,
505
    { 0, { { { (1<<MACH_BASE), 0 } } } }
506
  },
507
/* cmpne $r2,$r0,$r1 */
508
  {
509
    LM32_INSN_CMPNE, "cmpne", "cmpne", 32,
510
    { 0, { { { (1<<MACH_BASE), 0 } } } }
511
  },
512
/* cmpnei $r1,$r0,$imm */
513
  {
514
    LM32_INSN_CMPNEI, "cmpnei", "cmpnei", 32,
515
    { 0, { { { (1<<MACH_BASE), 0 } } } }
516
  },
517
/* divu $r2,$r0,$r1 */
518
  {
519
    LM32_INSN_DIVU, "divu", "divu", 32,
520
    { 0|A(UNCOND_CTI), { { { (1<<MACH_BASE), 0 } } } }
521
  },
522
/* lb $r1,($r0+$imm) */
523
  {
524
    LM32_INSN_LB, "lb", "lb", 32,
525
    { 0, { { { (1<<MACH_BASE), 0 } } } }
526
  },
527
/* lbu $r1,($r0+$imm) */
528
  {
529
    LM32_INSN_LBU, "lbu", "lbu", 32,
530
    { 0, { { { (1<<MACH_BASE), 0 } } } }
531
  },
532
/* lh $r1,($r0+$imm) */
533
  {
534
    LM32_INSN_LH, "lh", "lh", 32,
535
    { 0, { { { (1<<MACH_BASE), 0 } } } }
536
  },
537
/* lhu $r1,($r0+$imm) */
538
  {
539
    LM32_INSN_LHU, "lhu", "lhu", 32,
540
    { 0, { { { (1<<MACH_BASE), 0 } } } }
541
  },
542
/* lw $r1,($r0+$imm) */
543
  {
544
    LM32_INSN_LW, "lw", "lw", 32,
545
    { 0, { { { (1<<MACH_BASE), 0 } } } }
546
  },
547
/* modu $r2,$r0,$r1 */
548
  {
549
    LM32_INSN_MODU, "modu", "modu", 32,
550
    { 0|A(UNCOND_CTI), { { { (1<<MACH_BASE), 0 } } } }
551
  },
552
/* mul $r2,$r0,$r1 */
553
  {
554
    LM32_INSN_MUL, "mul", "mul", 32,
555
    { 0, { { { (1<<MACH_BASE), 0 } } } }
556
  },
557
/* muli $r1,$r0,$imm */
558
  {
559
    LM32_INSN_MULI, "muli", "muli", 32,
560
    { 0, { { { (1<<MACH_BASE), 0 } } } }
561
  },
562
/* nor $r2,$r0,$r1 */
563
  {
564
    LM32_INSN_NOR, "nor", "nor", 32,
565
    { 0, { { { (1<<MACH_BASE), 0 } } } }
566
  },
567
/* nori $r1,$r0,$uimm */
568
  {
569
    LM32_INSN_NORI, "nori", "nori", 32,
570
    { 0, { { { (1<<MACH_BASE), 0 } } } }
571
  },
572
/* or $r2,$r0,$r1 */
573
  {
574
    LM32_INSN_OR, "or", "or", 32,
575
    { 0, { { { (1<<MACH_BASE), 0 } } } }
576
  },
577
/* ori $r1,$r0,$lo16 */
578
  {
579
    LM32_INSN_ORI, "ori", "ori", 32,
580
    { 0, { { { (1<<MACH_BASE), 0 } } } }
581
  },
582
/* orhi $r1,$r0,$hi16 */
583
  {
584
    LM32_INSN_ORHII, "orhii", "orhi", 32,
585
    { 0, { { { (1<<MACH_BASE), 0 } } } }
586
  },
587
/* rcsr $r2,$csr */
588
  {
589
    LM32_INSN_RCSR, "rcsr", "rcsr", 32,
590
    { 0, { { { (1<<MACH_BASE), 0 } } } }
591
  },
592
/* sb ($r0+$imm),$r1 */
593
  {
594
    LM32_INSN_SB, "sb", "sb", 32,
595
    { 0, { { { (1<<MACH_BASE), 0 } } } }
596
  },
597
/* sextb $r2,$r0 */
598
  {
599
    LM32_INSN_SEXTB, "sextb", "sextb", 32,
600
    { 0, { { { (1<<MACH_BASE), 0 } } } }
601
  },
602
/* sexth $r2,$r0 */
603
  {
604
    LM32_INSN_SEXTH, "sexth", "sexth", 32,
605
    { 0, { { { (1<<MACH_BASE), 0 } } } }
606
  },
607
/* sh ($r0+$imm),$r1 */
608
  {
609
    LM32_INSN_SH, "sh", "sh", 32,
610
    { 0, { { { (1<<MACH_BASE), 0 } } } }
611
  },
612
/* sl $r2,$r0,$r1 */
613
  {
614
    LM32_INSN_SL, "sl", "sl", 32,
615
    { 0, { { { (1<<MACH_BASE), 0 } } } }
616
  },
617
/* sli $r1,$r0,$imm */
618
  {
619
    LM32_INSN_SLI, "sli", "sli", 32,
620
    { 0, { { { (1<<MACH_BASE), 0 } } } }
621
  },
622
/* sr $r2,$r0,$r1 */
623
  {
624
    LM32_INSN_SR, "sr", "sr", 32,
625
    { 0, { { { (1<<MACH_BASE), 0 } } } }
626
  },
627
/* sri $r1,$r0,$imm */
628
  {
629
    LM32_INSN_SRI, "sri", "sri", 32,
630
    { 0, { { { (1<<MACH_BASE), 0 } } } }
631
  },
632
/* sru $r2,$r0,$r1 */
633
  {
634
    LM32_INSN_SRU, "sru", "sru", 32,
635
    { 0, { { { (1<<MACH_BASE), 0 } } } }
636
  },
637
/* srui $r1,$r0,$imm */
638
  {
639
    LM32_INSN_SRUI, "srui", "srui", 32,
640
    { 0, { { { (1<<MACH_BASE), 0 } } } }
641
  },
642
/* sub $r2,$r0,$r1 */
643
  {
644
    LM32_INSN_SUB, "sub", "sub", 32,
645
    { 0, { { { (1<<MACH_BASE), 0 } } } }
646
  },
647
/* sw ($r0+$imm),$r1 */
648
  {
649
    LM32_INSN_SW, "sw", "sw", 32,
650
    { 0, { { { (1<<MACH_BASE), 0 } } } }
651
  },
652
/* user $r2,$r0,$r1,$user */
653
  {
654
    LM32_INSN_USER, "user", "user", 32,
655
    { 0, { { { (1<<MACH_BASE), 0 } } } }
656
  },
657
/* wcsr $csr,$r1 */
658
  {
659
    LM32_INSN_WCSR, "wcsr", "wcsr", 32,
660
    { 0, { { { (1<<MACH_BASE), 0 } } } }
661
  },
662
/* xor $r2,$r0,$r1 */
663
  {
664
    LM32_INSN_XOR, "xor", "xor", 32,
665
    { 0, { { { (1<<MACH_BASE), 0 } } } }
666
  },
667
/* xori $r1,$r0,$uimm */
668
  {
669
    LM32_INSN_XORI, "xori", "xori", 32,
670
    { 0, { { { (1<<MACH_BASE), 0 } } } }
671
  },
672
/* xnor $r2,$r0,$r1 */
673
  {
674
    LM32_INSN_XNOR, "xnor", "xnor", 32,
675
    { 0, { { { (1<<MACH_BASE), 0 } } } }
676
  },
677
/* xnori $r1,$r0,$uimm */
678
  {
679
    LM32_INSN_XNORI, "xnori", "xnori", 32,
680
    { 0, { { { (1<<MACH_BASE), 0 } } } }
681
  },
682
/* break */
683
  {
684
    LM32_INSN_BREAK, "break", "break", 32,
685
    { 0|A(UNCOND_CTI), { { { (1<<MACH_BASE), 0 } } } }
686
  },
687
/* scall */
688
  {
689
    LM32_INSN_SCALL, "scall", "scall", 32,
690
    { 0|A(UNCOND_CTI), { { { (1<<MACH_BASE), 0 } } } }
691
  },
692
/* bret */
693
  {
694
    -1, "bret", "bret", 32,
695
    { 0|A(ALIAS)|A(UNCOND_CTI), { { { (1<<MACH_BASE), 0 } } } }
696
  },
697
/* eret */
698
  {
699
    -1, "eret", "eret", 32,
700
    { 0|A(ALIAS)|A(UNCOND_CTI), { { { (1<<MACH_BASE), 0 } } } }
701
  },
702
/* ret */
703
  {
704
    -1, "ret", "ret", 32,
705
    { 0|A(ALIAS)|A(UNCOND_CTI), { { { (1<<MACH_BASE), 0 } } } }
706
  },
707
/* mv $r2,$r0 */
708
  {
709
    -1, "mv", "mv", 32,
710
    { 0|A(ALIAS), { { { (1<<MACH_BASE), 0 } } } }
711
  },
712
/* mvi $r1,$imm */
713
  {
714
    -1, "mvi", "mvi", 32,
715
    { 0|A(ALIAS), { { { (1<<MACH_BASE), 0 } } } }
716
  },
717
/* mvu $r1,$lo16 */
718
  {
719
    -1, "mvui", "mvu", 32,
720
    { 0|A(ALIAS), { { { (1<<MACH_BASE), 0 } } } }
721
  },
722
/* mvhi $r1,$hi16 */
723
  {
724
    -1, "mvhi", "mvhi", 32,
725
    { 0|A(ALIAS), { { { (1<<MACH_BASE), 0 } } } }
726
  },
727
/* mva $r1,$gp16 */
728
  {
729
    -1, "mva", "mva", 32,
730
    { 0|A(ALIAS), { { { (1<<MACH_BASE), 0 } } } }
731
  },
732
/* not $r2,$r0 */
733
  {
734
    -1, "not", "not", 32,
735
    { 0|A(ALIAS), { { { (1<<MACH_BASE), 0 } } } }
736
  },
737
/* nop */
738
  {
739
    -1, "nop", "nop", 32,
740
    { 0|A(ALIAS), { { { (1<<MACH_BASE), 0 } } } }
741
  },
742
/* lb $r1,$gp16 */
743
  {
744
    -1, "lbgprel", "lb", 32,
745
    { 0|A(ALIAS), { { { (1<<MACH_BASE), 0 } } } }
746
  },
747
/* lbu $r1,$gp16 */
748
  {
749
    -1, "lbugprel", "lbu", 32,
750
    { 0|A(ALIAS), { { { (1<<MACH_BASE), 0 } } } }
751
  },
752
/* lh $r1,$gp16 */
753
  {
754
    -1, "lhgprel", "lh", 32,
755
    { 0|A(ALIAS), { { { (1<<MACH_BASE), 0 } } } }
756
  },
757
/* lhu $r1,$gp16 */
758
  {
759
    -1, "lhugprel", "lhu", 32,
760
    { 0|A(ALIAS), { { { (1<<MACH_BASE), 0 } } } }
761
  },
762
/* lw $r1,$gp16 */
763
  {
764
    -1, "lwgprel", "lw", 32,
765
    { 0|A(ALIAS), { { { (1<<MACH_BASE), 0 } } } }
766
  },
767
/* sb $gp16,$r1 */
768
  {
769
    -1, "sbgprel", "sb", 32,
770
    { 0|A(ALIAS), { { { (1<<MACH_BASE), 0 } } } }
771
  },
772
/* sh $gp16,$r1 */
773
  {
774
    -1, "shgprel", "sh", 32,
775
    { 0|A(ALIAS), { { { (1<<MACH_BASE), 0 } } } }
776
  },
777
/* sw $gp16,$r1 */
778
  {
779
    -1, "swgprel", "sw", 32,
780
    { 0|A(ALIAS), { { { (1<<MACH_BASE), 0 } } } }
781
  },
782
/* lw $r1,(gp+$got16) */
783
  {
784
    -1, "lwgotrel", "lw", 32,
785
    { 0|A(ALIAS), { { { (1<<MACH_BASE), 0 } } } }
786
  },
787
/* orhi $r1,$r0,$gotoffhi16 */
788
  {
789
    -1, "orhigotoffi", "orhi", 32,
790
    { 0|A(ALIAS), { { { (1<<MACH_BASE), 0 } } } }
791
  },
792
/* addi $r1,$r0,$gotofflo16 */
793
  {
794
    -1, "addgotoff", "addi", 32,
795
    { 0|A(ALIAS), { { { (1<<MACH_BASE), 0 } } } }
796
  },
797
/* sw ($r0+$gotofflo16),$r1 */
798
  {
799
    -1, "swgotoff", "sw", 32,
800
    { 0|A(ALIAS), { { { (1<<MACH_BASE), 0 } } } }
801
  },
802
/* lw $r1,($r0+$gotofflo16) */
803
  {
804
    -1, "lwgotoff", "lw", 32,
805
    { 0|A(ALIAS), { { { (1<<MACH_BASE), 0 } } } }
806
  },
807
/* sh ($r0+$gotofflo16),$r1 */
808
  {
809
    -1, "shgotoff", "sh", 32,
810
    { 0|A(ALIAS), { { { (1<<MACH_BASE), 0 } } } }
811
  },
812
/* lh $r1,($r0+$gotofflo16) */
813
  {
814
    -1, "lhgotoff", "lh", 32,
815
    { 0|A(ALIAS), { { { (1<<MACH_BASE), 0 } } } }
816
  },
817
/* lhu $r1,($r0+$gotofflo16) */
818
  {
819
    -1, "lhugotoff", "lhu", 32,
820
    { 0|A(ALIAS), { { { (1<<MACH_BASE), 0 } } } }
821
  },
822
/* sb ($r0+$gotofflo16),$r1 */
823
  {
824
    -1, "sbgotoff", "sb", 32,
825
    { 0|A(ALIAS), { { { (1<<MACH_BASE), 0 } } } }
826
  },
827
/* lb $r1,($r0+$gotofflo16) */
828
  {
829
    -1, "lbgotoff", "lb", 32,
830
    { 0|A(ALIAS), { { { (1<<MACH_BASE), 0 } } } }
831
  },
832
/* lbu $r1,($r0+$gotofflo16) */
833
  {
834
    -1, "lbugotoff", "lbu", 32,
835
    { 0|A(ALIAS), { { { (1<<MACH_BASE), 0 } } } }
836
  },
837
};
838
 
839
#undef OP
840
#undef A
841
 
842
/* Initialize anything needed to be done once, before any cpu_open call.  */
843
 
844
static void
845
init_tables (void)
846
{
847
}
848
 
849
static const CGEN_MACH * lookup_mach_via_bfd_name (const CGEN_MACH *, const char *);
850
static void build_hw_table      (CGEN_CPU_TABLE *);
851
static void build_ifield_table  (CGEN_CPU_TABLE *);
852
static void build_operand_table (CGEN_CPU_TABLE *);
853
static void build_insn_table    (CGEN_CPU_TABLE *);
854
static void lm32_cgen_rebuild_tables (CGEN_CPU_TABLE *);
855
 
856
/* Subroutine of lm32_cgen_cpu_open to look up a mach via its bfd name.  */
857
 
858
static const CGEN_MACH *
859
lookup_mach_via_bfd_name (const CGEN_MACH *table, const char *name)
860
{
861
  while (table->name)
862
    {
863
      if (strcmp (name, table->bfd_name) == 0)
864
        return table;
865
      ++table;
866
    }
867
  abort ();
868
}
869
 
870
/* Subroutine of lm32_cgen_cpu_open to build the hardware table.  */
871
 
872
static void
873
build_hw_table (CGEN_CPU_TABLE *cd)
874
{
875
  int i;
876
  int machs = cd->machs;
877
  const CGEN_HW_ENTRY *init = & lm32_cgen_hw_table[0];
878
  /* MAX_HW is only an upper bound on the number of selected entries.
879
     However each entry is indexed by it's enum so there can be holes in
880
     the table.  */
881
  const CGEN_HW_ENTRY **selected =
882
    (const CGEN_HW_ENTRY **) xmalloc (MAX_HW * sizeof (CGEN_HW_ENTRY *));
883
 
884
  cd->hw_table.init_entries = init;
885
  cd->hw_table.entry_size = sizeof (CGEN_HW_ENTRY);
886
  memset (selected, 0, MAX_HW * sizeof (CGEN_HW_ENTRY *));
887
  /* ??? For now we just use machs to determine which ones we want.  */
888
  for (i = 0; init[i].name != NULL; ++i)
889
    if (CGEN_HW_ATTR_VALUE (&init[i], CGEN_HW_MACH)
890
        & machs)
891
      selected[init[i].type] = &init[i];
892
  cd->hw_table.entries = selected;
893
  cd->hw_table.num_entries = MAX_HW;
894
}
895
 
896
/* Subroutine of lm32_cgen_cpu_open to build the hardware table.  */
897
 
898
static void
899
build_ifield_table (CGEN_CPU_TABLE *cd)
900
{
901
  cd->ifld_table = & lm32_cgen_ifld_table[0];
902
}
903
 
904
/* Subroutine of lm32_cgen_cpu_open to build the hardware table.  */
905
 
906
static void
907
build_operand_table (CGEN_CPU_TABLE *cd)
908
{
909
  int i;
910
  int machs = cd->machs;
911
  const CGEN_OPERAND *init = & lm32_cgen_operand_table[0];
912
  /* MAX_OPERANDS is only an upper bound on the number of selected entries.
913
     However each entry is indexed by it's enum so there can be holes in
914
     the table.  */
915
  const CGEN_OPERAND **selected = xmalloc (MAX_OPERANDS * sizeof (* selected));
916
 
917
  cd->operand_table.init_entries = init;
918
  cd->operand_table.entry_size = sizeof (CGEN_OPERAND);
919
  memset (selected, 0, MAX_OPERANDS * sizeof (CGEN_OPERAND *));
920
  /* ??? For now we just use mach to determine which ones we want.  */
921
  for (i = 0; init[i].name != NULL; ++i)
922
    if (CGEN_OPERAND_ATTR_VALUE (&init[i], CGEN_OPERAND_MACH)
923
        & machs)
924
      selected[init[i].type] = &init[i];
925
  cd->operand_table.entries = selected;
926
  cd->operand_table.num_entries = MAX_OPERANDS;
927
}
928
 
929
/* Subroutine of lm32_cgen_cpu_open to build the hardware table.
930
   ??? This could leave out insns not supported by the specified mach/isa,
931
   but that would cause errors like "foo only supported by bar" to become
932
   "unknown insn", so for now we include all insns and require the app to
933
   do the checking later.
934
   ??? On the other hand, parsing of such insns may require their hardware or
935
   operand elements to be in the table [which they mightn't be].  */
936
 
937
static void
938
build_insn_table (CGEN_CPU_TABLE *cd)
939
{
940
  int i;
941
  const CGEN_IBASE *ib = & lm32_cgen_insn_table[0];
942
  CGEN_INSN *insns = xmalloc (MAX_INSNS * sizeof (CGEN_INSN));
943
 
944
  memset (insns, 0, MAX_INSNS * sizeof (CGEN_INSN));
945
  for (i = 0; i < MAX_INSNS; ++i)
946
    insns[i].base = &ib[i];
947
  cd->insn_table.init_entries = insns;
948
  cd->insn_table.entry_size = sizeof (CGEN_IBASE);
949
  cd->insn_table.num_init_entries = MAX_INSNS;
950
}
951
 
952
/* Subroutine of lm32_cgen_cpu_open to rebuild the tables.  */
953
 
954
static void
955
lm32_cgen_rebuild_tables (CGEN_CPU_TABLE *cd)
956
{
957
  int i;
958
  CGEN_BITSET *isas = cd->isas;
959
  unsigned int machs = cd->machs;
960
 
961
  cd->int_insn_p = CGEN_INT_INSN_P;
962
 
963
  /* Data derived from the isa spec.  */
964
#define UNSET (CGEN_SIZE_UNKNOWN + 1)
965
  cd->default_insn_bitsize = UNSET;
966
  cd->base_insn_bitsize = UNSET;
967
  cd->min_insn_bitsize = 65535; /* Some ridiculously big number.  */
968
  cd->max_insn_bitsize = 0;
969
  for (i = 0; i < MAX_ISAS; ++i)
970
    if (cgen_bitset_contains (isas, i))
971
      {
972
        const CGEN_ISA *isa = & lm32_cgen_isa_table[i];
973
 
974
        /* Default insn sizes of all selected isas must be
975
           equal or we set the result to 0, meaning "unknown".  */
976
        if (cd->default_insn_bitsize == UNSET)
977
          cd->default_insn_bitsize = isa->default_insn_bitsize;
978
        else if (isa->default_insn_bitsize == cd->default_insn_bitsize)
979
          ; /* This is ok.  */
980
        else
981
          cd->default_insn_bitsize = CGEN_SIZE_UNKNOWN;
982
 
983
        /* Base insn sizes of all selected isas must be equal
984
           or we set the result to 0, meaning "unknown".  */
985
        if (cd->base_insn_bitsize == UNSET)
986
          cd->base_insn_bitsize = isa->base_insn_bitsize;
987
        else if (isa->base_insn_bitsize == cd->base_insn_bitsize)
988
          ; /* This is ok.  */
989
        else
990
          cd->base_insn_bitsize = CGEN_SIZE_UNKNOWN;
991
 
992
        /* Set min,max insn sizes.  */
993
        if (isa->min_insn_bitsize < cd->min_insn_bitsize)
994
          cd->min_insn_bitsize = isa->min_insn_bitsize;
995
        if (isa->max_insn_bitsize > cd->max_insn_bitsize)
996
          cd->max_insn_bitsize = isa->max_insn_bitsize;
997
      }
998
 
999
  /* Data derived from the mach spec.  */
1000
  for (i = 0; i < MAX_MACHS; ++i)
1001
    if (((1 << i) & machs) != 0)
1002
      {
1003
        const CGEN_MACH *mach = & lm32_cgen_mach_table[i];
1004
 
1005
        if (mach->insn_chunk_bitsize != 0)
1006
        {
1007
          if (cd->insn_chunk_bitsize != 0 && cd->insn_chunk_bitsize != mach->insn_chunk_bitsize)
1008
            {
1009
              fprintf (stderr, "lm32_cgen_rebuild_tables: conflicting insn-chunk-bitsize values: `%d' vs. `%d'\n",
1010
                       cd->insn_chunk_bitsize, mach->insn_chunk_bitsize);
1011
              abort ();
1012
            }
1013
 
1014
          cd->insn_chunk_bitsize = mach->insn_chunk_bitsize;
1015
        }
1016
      }
1017
 
1018
  /* Determine which hw elements are used by MACH.  */
1019
  build_hw_table (cd);
1020
 
1021
  /* Build the ifield table.  */
1022
  build_ifield_table (cd);
1023
 
1024
  /* Determine which operands are used by MACH/ISA.  */
1025
  build_operand_table (cd);
1026
 
1027
  /* Build the instruction table.  */
1028
  build_insn_table (cd);
1029
}
1030
 
1031
/* Initialize a cpu table and return a descriptor.
1032
   It's much like opening a file, and must be the first function called.
1033
   The arguments are a set of (type/value) pairs, terminated with
1034
   CGEN_CPU_OPEN_END.
1035
 
1036
   Currently supported values:
1037
   CGEN_CPU_OPEN_ISAS:    bitmap of values in enum isa_attr
1038
   CGEN_CPU_OPEN_MACHS:   bitmap of values in enum mach_attr
1039
   CGEN_CPU_OPEN_BFDMACH: specify 1 mach using bfd name
1040
   CGEN_CPU_OPEN_ENDIAN:  specify endian choice
1041
   CGEN_CPU_OPEN_END:     terminates arguments
1042
 
1043
   ??? Simultaneous multiple isas might not make sense, but it's not (yet)
1044
   precluded.
1045
 
1046
   ??? We only support ISO C stdargs here, not K&R.
1047
   Laziness, plus experiment to see if anything requires K&R - eventually
1048
   K&R will no longer be supported - e.g. GDB is currently trying this.  */
1049
 
1050
CGEN_CPU_DESC
1051
lm32_cgen_cpu_open (enum cgen_cpu_open_arg arg_type, ...)
1052
{
1053
  CGEN_CPU_TABLE *cd = (CGEN_CPU_TABLE *) xmalloc (sizeof (CGEN_CPU_TABLE));
1054
  static int init_p;
1055
  CGEN_BITSET *isas = 0;  /* 0 = "unspecified" */
1056
  unsigned int machs = 0; /* 0 = "unspecified" */
1057
  enum cgen_endian endian = CGEN_ENDIAN_UNKNOWN;
1058
  va_list ap;
1059
 
1060
  if (! init_p)
1061
    {
1062
      init_tables ();
1063
      init_p = 1;
1064
    }
1065
 
1066
  memset (cd, 0, sizeof (*cd));
1067
 
1068
  va_start (ap, arg_type);
1069
  while (arg_type != CGEN_CPU_OPEN_END)
1070
    {
1071
      switch (arg_type)
1072
        {
1073
        case CGEN_CPU_OPEN_ISAS :
1074
          isas = va_arg (ap, CGEN_BITSET *);
1075
          break;
1076
        case CGEN_CPU_OPEN_MACHS :
1077
          machs = va_arg (ap, unsigned int);
1078
          break;
1079
        case CGEN_CPU_OPEN_BFDMACH :
1080
          {
1081
            const char *name = va_arg (ap, const char *);
1082
            const CGEN_MACH *mach =
1083
              lookup_mach_via_bfd_name (lm32_cgen_mach_table, name);
1084
 
1085
            machs |= 1 << mach->num;
1086
            break;
1087
          }
1088
        case CGEN_CPU_OPEN_ENDIAN :
1089
          endian = va_arg (ap, enum cgen_endian);
1090
          break;
1091
        default :
1092
          fprintf (stderr, "lm32_cgen_cpu_open: unsupported argument `%d'\n",
1093
                   arg_type);
1094
          abort (); /* ??? return NULL? */
1095
        }
1096
      arg_type = va_arg (ap, enum cgen_cpu_open_arg);
1097
    }
1098
  va_end (ap);
1099
 
1100
  /* Mach unspecified means "all".  */
1101
  if (machs == 0)
1102
    machs = (1 << MAX_MACHS) - 1;
1103
  /* Base mach is always selected.  */
1104
  machs |= 1;
1105
  if (endian == CGEN_ENDIAN_UNKNOWN)
1106
    {
1107
      /* ??? If target has only one, could have a default.  */
1108
      fprintf (stderr, "lm32_cgen_cpu_open: no endianness specified\n");
1109
      abort ();
1110
    }
1111
 
1112
  cd->isas = cgen_bitset_copy (isas);
1113
  cd->machs = machs;
1114
  cd->endian = endian;
1115
  /* FIXME: for the sparc case we can determine insn-endianness statically.
1116
     The worry here is where both data and insn endian can be independently
1117
     chosen, in which case this function will need another argument.
1118
     Actually, will want to allow for more arguments in the future anyway.  */
1119
  cd->insn_endian = endian;
1120
 
1121
  /* Table (re)builder.  */
1122
  cd->rebuild_tables = lm32_cgen_rebuild_tables;
1123
  lm32_cgen_rebuild_tables (cd);
1124
 
1125
  /* Default to not allowing signed overflow.  */
1126
  cd->signed_overflow_ok_p = 0;
1127
 
1128
  return (CGEN_CPU_DESC) cd;
1129
}
1130
 
1131
/* Cover fn to lm32_cgen_cpu_open to handle the simple case of 1 isa, 1 mach.
1132
   MACH_NAME is the bfd name of the mach.  */
1133
 
1134
CGEN_CPU_DESC
1135
lm32_cgen_cpu_open_1 (const char *mach_name, enum cgen_endian endian)
1136
{
1137
  return lm32_cgen_cpu_open (CGEN_CPU_OPEN_BFDMACH, mach_name,
1138
                               CGEN_CPU_OPEN_ENDIAN, endian,
1139
                               CGEN_CPU_OPEN_END);
1140
}
1141
 
1142
/* Close a cpu table.
1143
   ??? This can live in a machine independent file, but there's currently
1144
   no place to put this file (there's no libcgen).  libopcodes is the wrong
1145
   place as some simulator ports use this but they don't use libopcodes.  */
1146
 
1147
void
1148
lm32_cgen_cpu_close (CGEN_CPU_DESC cd)
1149
{
1150
  unsigned int i;
1151
  const CGEN_INSN *insns;
1152
 
1153
  if (cd->macro_insn_table.init_entries)
1154
    {
1155
      insns = cd->macro_insn_table.init_entries;
1156
      for (i = 0; i < cd->macro_insn_table.num_init_entries; ++i, ++insns)
1157
        if (CGEN_INSN_RX ((insns)))
1158
          regfree (CGEN_INSN_RX (insns));
1159
    }
1160
 
1161
  if (cd->insn_table.init_entries)
1162
    {
1163
      insns = cd->insn_table.init_entries;
1164
      for (i = 0; i < cd->insn_table.num_init_entries; ++i, ++insns)
1165
        if (CGEN_INSN_RX (insns))
1166
          regfree (CGEN_INSN_RX (insns));
1167
    }
1168
 
1169
  if (cd->macro_insn_table.init_entries)
1170
    free ((CGEN_INSN *) cd->macro_insn_table.init_entries);
1171
 
1172
  if (cd->insn_table.init_entries)
1173
    free ((CGEN_INSN *) cd->insn_table.init_entries);
1174
 
1175
  if (cd->hw_table.entries)
1176
    free ((CGEN_HW_ENTRY *) cd->hw_table.entries);
1177
 
1178
  if (cd->operand_table.entries)
1179
    free ((CGEN_HW_ENTRY *) cd->operand_table.entries);
1180
 
1181
  free (cd);
1182
}
1183
 

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